NETA World WR22_FINAL

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MEASURING 
PARTIAL 
DISCHARGE
ON MEDIUM- 
VOLTAGE CABLES
W
IN
TE
R
20
22
ISSN 2167-3594 NETA WORLD JOURNAL PRINT
ISSN 2167-3586 NETA WORLD JOURNAL ONLINE
ON-LINE CABLE PD TESTING PAGE 56
ACCEPTANCE AND MAINTENANCE 
TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES PAGE 64
DETECTING PARTIAL DISCHARGE 
ON MEDIUM-VOLTAGE CABLE 
ACCESSORIES PAGE 76
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56
COVER STORY
 46 Measuring Partial Discharge 
 on Medium-Voltage Cables
Jason Aaron and Joseph Aguirre, Megger
Measuring partial discharge (PD) activity is a 
diagnostic method used to evaluate insulation quality. 
Paired with other cable tests, it can identify defects 
before a fault occurs, reducing maintenance, repair, and 
replacement costs.
 56 On-Line Cable PD Testing 
William G. Higinbotham, EA Technology, LLC
This article explores the theory, benefits, and pitfalls 
of on-line PD testing and shows the value of the 
methodology as a proven and practical method to reduce 
the impact of future cable failures.
 64 Detecting Partial Discharge 
 on Medium-Voltage Cable 
 Accessories
Michel Trepanier and Claude Tremblay, Hydro-Quebec; 
Lionel Reynaud, Hydro-Quebec Research Institute; and 
Mathieu Lachance, OMICRON electronics Canada
In-service failures lead to loss of revenue, increased 
expenditures for repairs, and potential damage to other 
power apparatus due to increased stress during a fault. 
Learn how Hydro-Quebec implemented a multi-level 
evaluation system to achieve safety, economic, and 
service goals.
 76 Acceptance and Maintenance 
 Testing for Medium-Voltage 
 Electrical Power Cables – Part 1
Tom Sandri, Protec Equipment Resources
Part 1 of 3 describes the evolution of testing methods 
and philosophies over the past 30-plus years and 
explains the use, advantages, and limitations of each 
technique.
IN THIS ISSUE WINTER2022 · VOLUME 44 , NO. 4
64
46
TABLE OF CONTENTS
INSIGHTS AND INSPIRATION
 8 Wyatt Hamrick: Curiosity and Commitment 
IN EVERY ISSUE
 7 President’s Desk
Recognizing Your Dedication
Eric Beckman, National Field Services 
NETA President
 14 NFPA 70E and NETA
A Game of Inches: Understanding Dimensions 
in NFPA 70E
Ron Widup, Shermco Industries
 20 Relay Column
Condition Monitoring: Generator Stator 
Ground Capacitance
Steven Turner, Arizona Public Service Company 
 26 In the Field
Medium-Voltage Cable Installation Issues
Mose Ramieh, CBS Field Services 
 33 Safety Corner
Programs, Policies, Manuals, Procedures, and Training
Paul Chamberlain, American Electrical Testing Co. LLC
 38 Tech Quiz 
Off-Line Partial Discharge Cable Testing
Virginia Balitski, Magna IV Engineering 
 40 Tech Tips
Ground Enhancements: An Answer to Difficult 
Grounding Situations
Jeff Jowett, Megger
INDUSTRY TOPICS
 86 Microgrids in Practice
Mayfield Renewables
 94 Photovoltaic Power Systems and Ground-Fault 
 Protection on the Service Entrance Disconnect
John Wiles, Retired
 100 Using the Three Rs to Reduce the Environmental 
 Impact of SF6 Gas
Lina Encinias and Corey Ratza, DILO Company, Inc.
CAP CORNER
 108 Advancements in the Industry
Operational Technology Cyber Threats Are on the Rise
Bryan J. Gwyn and Sagar S. Singam, Doble Engineering Company
 114 CAP Spotlight
Group CBS: People, Technology, and Uptime
NETA NEWS
 116 NETA Welcomes New Accredited Company — 
 Electro Test LLC
 118 NETA Activities Update
SPECIFICATIONS AND STANDARDS
 120 ANSI/NETA Standards Update
 122 NFPA 70B Update
David Huffman, Power Systems Testing Company
IMPORTANT LISTS
 125 NETA Accredited Companies
 134 Advertiser List
40 94 108
Tom Sandri
Director of
Technical Services
Live Instructor-Led
People taking this class for the first time
are required by the 70E 2021 standard to 
take it “live”. Whether online or in-person, 
to be compliant, there must be interaction
and engagement with an instructor. 
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Reduces Travel Time and Costs
Minimize workers’ time away from the office; 
eliminate the cost of travel and per-diems.
High Level of Instruction
Train with Tom Sandri, well-known in the 
electrical testing industry with over 30 years 
of experience. Tom was certified by a committee 
member and writer for the 70E certification.
or visit
ProtecEquip.com/QEW
FOR MORE INFORMATION
Scan the QR Code below with your phone’s
camera and click the link that appears
NFPA 70E Training
Get Your Workers Certified to the 2021 Standard!
Electrical Safety for the Qualified Worker training is aimed at qualified electrical workers to help them build capabilities, 
knowledge and safe work practices when working around energized electrical systems. Protec Equipment Resources now 
offers a live online instructor-led 2.5 day course that meets the NFPA 70E ® 2021 standard for electrical safety in the work-
place!
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NETA Officers
president: Eric Beckman, National Field Services
first vice president: Bob Sheppard, Premier Power Maintenance
second vice president: Dan Hook, CBS Field Services
secretary: Chasen Tedder, Hampton Tedder Technical Services 
treasurer: John White, Sigma Six Solutions, Inc.
NETA Board of Directors
Virginia Balitski (Magna IV Engineering)
Ken Bassett (Potomac Testing, Inc.)
Eric Beckman (National Field Services)
Scott Blizard (American Electrical Testing Co., Inc.)
Jim Cialdea (CE Power Engineered Services, LLC)
Leif Hoegberg (Electrical Reliability Services)
Dan Hook (CBS Field Services)
David Huffman (Power Systems Testing)
Chasen Tedder, Hampton Tedder Technical Services
Ron Widup (Shermco Industries)
non-voting board member
Lorne Gara (Shermco Industries)
John White (Sigma Six Solutions)
NETA World Staff
technical editors: Roderic L. Hageman, Tim Cotter
assistant technical editors: Jim Cialdea, Dan Hook, 
Dave Huffman, Bob Sheppard
associate editor: Resa Pickel
managing editor: Carla Kalogeridis
copy editor: Beverly Sturtevant
design and production: Moon Design
NETA Committee Chairs
conference: Ron Widup; membership: Ken Bassett; 
promotions/marketing: Scott Blizard; safety: Scott Blizard; 
technical: Lorne Gara; technical exam: Dan Hook; 
continuing technical development: David Huffman; 
training: Bob Sheppard; finance: John White; 
nominations: Dave Huffman; alliance program: Jim Cialdea; 
association development: Ken Bassett
© Copyright 2022, NETA
NOTICE AND DISCLAIMER
NETA World is published quarterly by the InterNational Electrical Testing Association. 
Opinions, views and conclusions expressed in articles herein are those of the authors and not 
necessarily those of NETA. Publication herein does not constitute or imply endorsement of 
any opinion, product, or service by NETA, its directors, officers, members, employees or 
agents (herein “NETA”).
All technical data in this publication reflects the experience of individuals using specific tools, 
products, equipment and components under specific conditions and circumstances which mayto a million ohm-
centimeters (Ω-cm). Indeed, on the low end 
of this scale, simply driving an 8- or 10-foot 
rod may be sufficient. But for more difficult 
soil types and local conditions, reaching 
specification may be a real challenge.
GROUNDING MATERIALS
The first line of defense is the grounding electrode 
— the metal that is installed in the earth to 
which the grounding conductor or conductors 
are attached. Fault current, it is hoped, will 
find this the path of least resistance in going to 
ground and back to the utility that generated it 
or, in the case of lightning, equilibrium with the 
clouds. This is obviously preferable to traveling 
through equipment — or worse, people. Putting 
more metal in the earth is the most common 
remedy. The more contact the electrode has with 
NETAWorld • 41GROUND ENHANCEMENTS: AN ANSWER TO DIFFICULT GROUNDING SITUATIONS
TECH TIPS
the surrounding soil, the lower the resistance. 
Imagine a mob of people escaping a building fire; 
two doors are better than one.
Two general methods of getting more metal 
into the earth are to a) go deeper or b) laterally 
expand the size of the grid. There are practical 
arguments on both sides, but overall, going 
deeper is preferable…especially if you hit water 
table. Of course, water is a good conductor, 
and water table can provide a constant low-
resistance path. The water table can drop over 
time, however, so periodic maintenance checks 
of the rod’s resistance must be taken (Figure 1). 
The major disadvantage to deep-driven rods 
is that they are comparatively expensive. 
They can be installed by coupling additional 
rods and driving the electrode deeper, but in 
more difficult hard-ground terrain, it may be 
necessary to drill a bore hole and backfill it 
with a conductive material around the rod.
An alternative to a deep-driven rod is to expand 
the electrode laterally. The easiest way to do 
this is to add more rods, not coupled on top of 
each other as in deep-driven, but expanded into 
an interconnected parallel grid. Additional rods 
should always be spaced at least as far apart as 
they are deep. This is so their electrical fields 
do not overlap and cause the two to begin 
performing as a single rod. This defeats the 
purpose of the added rod. 
Generally, a second rod will decrease the 
resistance by about 40%. After that, though, it’s 
not so easy. Additional rods yield progressively 
smaller decrements until the exercise becomes 
counterproductive. Nonetheless, it is common 
practice to continually drive and test until spec 
is achieved.
Metallic grounding meshes or horizontal bars 
welded into a grid can also be used. These 
may be useful in areas of shallow bedrock 
where extensive excavation is prohibitive. But 
in cold climates, be sure any such structures 
can be buried below the frost line. Freezing 
immobilizes the dissipation of fault currents 
just as it does in a car battery.
OTHER MATERIALS
Thus far we’ve examined making the electrode 
larger or driving it deeper. These are the most 
common methods of grounding an electrical 
system to meet an imposed specification. But 
with the enormous variability of soil resistivity 
and local conditions, these methods can 
be challenged and may not be adequate. A 
number of specializations have been devised 
to meet the worst of conditions. One has 
already been mentioned: drilling a bore hole 
Figure 1: Maintenance Testing a Ground Rod
42 • WINTER 2022 GROUND ENHANCEMENTS: AN ANSWER TO DIFFICULT GROUNDING SITUATIONS
TECH TIPS
for a deep-driven rod and backfilling it with 
conductive material. 
One of the most widely used materials is 
bentonite. Named for its discovery near Ft. 
Benton, Montana, bentonite is a mined material 
formed by the weathering of volcanic ash in 
seawater. It has the useful property of holding 
water molecules in a lattice structure that retards 
desiccation (unlike moisture in soil), which 
thereby maintains the grounding electrode in a 
steady and favorable environment for passage of 
current. Under severe conditions, bentonite may 
develop cracks and recede from the electrode, so 
synthetic variants are also available. 
Ground enhancement material composed 
of Portland cement and a carbon-based 
conductive material (commonly known as 
GEM) is also widely used.
Improved materials for surrounding or 
encasing a ground electrode have more recently 
been developed. These appear on the market 
under various trade names, each with its own 
formulation aimed at promoting conductivity 
while retarding desiccation, cracking, and 
reduced contact with the electrode. 
A representative formulation is based on 
natural clay, not carbon-based, and with neutral 
pH so as not to corrode the electrode even 
under prolonged contact. These materials can 
be hygroscopic, capturing moisture from the 
surrounding soil and holding it in a conductive 
lattice. A resistivity of 0.6 Ω/m is characteristic. 
Such materials can exhibit a capacitive effect 
in absorbing the high rise time of lightning 
strikes. A representative specification is 
1,682 V/688 A for 500 ms. An NSF Standard 
60 rating indicates to inspectors that the 
material is in conformance with environmental 
protection regulations. Systems have been 
known to remain effective for 50 years. Theft 
reduction is an added benefit, as the hardened 
conductive material makes extraction difficult.
CHEMICAL TREATMENTS
The soil itself can be chemically treated. 
Lowering the resistivity around the ground 
rod will promote current flow and lower 
the resistance of the rod to surrounding 
soil, possibly bringing it within the desired 
specification. Common materials are 
magnesium sulfate, copper sulfate, and rock 
salt. They can be applied in a trench dug 
around the electrode (Figure 2). 
But there are caveats. Rain and other weather 
conditions will slowly leach away the applied 
materials, so they must be regularly assessed 
and replenished. Depending on the porosity 
of the soil and amount of rainfall, it could be 
years before the treatment needs to be replaced. 
Figure 2: Application of Grounding Materials
NETAWorld • 43GROUND ENHANCEMENTS: AN ANSWER TO DIFFICULT GROUNDING SITUATIONS
TECH TIPS
Chemical treatments can also attack the 
electrode; magnesium sulfate is the least 
corrosive. Soluble sulfates can also attack 
concrete, so it must be kept away from 
building foundations. This poses a potential 
problem with lightning protection, where a 
short, straight path directly into the earth is 
most effective. EPA and local environmental 
regulations must also be considered. Industry 
standard parameters are covered in IEC 
Standard 62561-7, Part 7: Regulations for 
Earthing Enhancing Compounds.
ELECTROLYTIC GROUNDING 
SYSTEMS
Also in use are electrolytic grounding systems, 
where the rod itself is an active part of its 
environment. Hollow rods with breather 
holes extract moisture from the environment, 
convert it to salt water to provide greater 
conductivity, and gradually leach it into the 
surrounding environment to create a constant 
low-resistance path into the soil (Figure 3). 
More than replenishing soil moisture, the 
system creates electrolytic roots that further 
enhance the capability of the electrode to 
dissipate dangerous fault currents safely. 
These systems are available as vertical rods for 
deep-driven electrodes and L-shaped rods for 
shallow bedrock where deep-driven electrodes 
would be cost prohibitive.
SOFTWARE SOLUTIONS
A more efficient and less time-consuming 
method is to design the system beforehand 
using dedicated software. Some are available at 
no charge from companies offering grounding 
materials such as rods and meshes. A four-
terminal ground tester is needed to measure 
the resistivity of the local soil. The data will 
be entered in the software, along with the 
resistance value the grid must meet, plus a few 
qualifying questions. The software will then 
design and display an appropriate system: x 
numberof rods laid out in a pattern. 
CONCLUSION
With the enormous range of earth types and 
soil resistivities alluded to in the beginning 
Figure 3: Specialized Rods Extract Moisture from the Environment
TECH TIPS
accommodations in designing and installing 
the electrode. Don’t just drive a rod and walk 
away. Take a resistivity measurement first, and 
hope that it’s low. 
REFERENCE
XIT Grounding. Product Catalog, Version 
2022V1, 2022. Accessed at https://vfclp.com/
lyncole/.
Jeffrey R. Jowett is a Senior Applications 
Engineer for Megger in Valley Forge, 
Pennsylvania, serving the manufacturing 
lines of Biddle, Megger, and Multi-
Amp for electrical test and measurement 
instrumentation. He holds a BS in biology 
and chemistry from Ursinus College. He 
was employed for 22 years with James G. Biddle Co., which 
became Biddle Instruments and is now Megger.
of this article, any given site may or may not 
require heroic efforts to install an effective 
ground. However, such instances are not 
uncommon. 
Many common soil conditions preclude simply 
driving a rod. For example, coastal loams such as 
those found along the Atlantic seaboard tend to 
be forgiving, but rocky and mountainous soils 
often call for more elaborate systems. Sandy 
soils such as in deserts and along seashores 
are also difficult. Grains of sand tend to have 
microscopic air pockets that do not conduct 
well. Sand does not retain water well and, in the 
passage to greater depths, electrolytic minerals 
that aid current flow get washed away.
Therefore, poor grounding conditions are 
not at all uncommon and may call for special 
https://vfclp.com/lyncole/
https://vfclp.com/lyncole/
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46 • WINTER 2022
COVER STORY
NETAWorld • 47
COVER STORY
MEASURING PARTIAL DISCHARGE ON MEDIUM VOLTAGE CABLES
BY JASON AARON and JOSEPH AGUIRRE, Megger
Partial discharge (PD) testing is a form of diagnostic testing for 
power cable systems. PD testing of medium- and high-voltage cable 
applications is beneficial when paired with other cable tests including 
very-low frequency (VLF) and tan delta (TD) tests. Partial discharge 
testing is another way to judge a cable’s insulation vitality or ability to 
endure electrical stress. Utilizing PD as an off-line testing technique 
can identify problematic defects long before a fault situation would 
create an in-service outage. 
In addition to using partial discharge testing for 
condition-based maintenance testing for aged 
cables, it can be used for acceptance testing and 
commissioning. It is possible to considerably 
reduce the costs of maintenance and network 
renewal with the help of cable diagnostic 
techniques. More informed decisions eliminate 
unnecessary cable repairs or renewals, which 
leads to an increase in a cable’s life expectancy. 
Conducting a PD test during commissioning 
and acceptance can help find defects before 
the cable is placed in service, which will also 
increase reliability and verify the workmanship 
of the cable installation. 
Another means of locating PD is continuous 
on-line monitoring, which can be established 
to provide advanced warning that a cable’s 
MEASURING PARTIAL 
DISCHARGE ON 
MEDIUM-VOLTAGE 
CABLES
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48 • WINTER 2022 MEASURING PARTIAL DISCHARGE ON MEDIUM VOLTAGE CABLES
COVER STORY
insulation is deteriorating while in service. 
Off-line PD resolves many of on-line PD’s 
limitations; however, this method requires the 
cable to be de-energized and removed from 
service during a scheduled outage. It can also 
be used as a quality check in a forced outage 
situation after repairs are performed and before 
the cable is placed back into service.
OFF-LINE PD TESTING
When using off-line PD testing, a separate 
power supply is coupled to the cable under 
test. Thus, the PD test can be accomplished at 
various levels of rated voltage (Uo) from 0.5 to 
1.7 times on aged cables and up to 2 times on 
new cables. Uo refers to the voltage magnitude 
as a multiple of the rated operating voltage in 
reference to the phase to ground voltage. PD 
should not occur below the operating voltage 
of the cable. Before testing can commence, a 
calibration measurement must be conducted 
using a known apparent charge, typically 
starting at 1 nC (nanocoulomb). The coulomb 
magnitude can be adjusted to determine a 
suitable bandwidth, which is dependent on 
the overall length of the cable. This ensures 
reproducible measurements and a reliable 
evaluation of comparable data. 
A disturbance level or background noise 
measurement should also be taken to give 
a baseline of the PD measuring circuit. The 
partial discharge testing procedure should start 
at 0.5 times Uo and rise by 0.1 to 0.2 until 
PD is discovered. This is referred to as the 
partial discharge inception voltage (PDIV). 
If the PDIV is close to operating voltage or 
Uo, this would cause immediate concern 
for replacement or repair, as necessary. Once 
the PDIV is achieved, the voltage should 
be decreased until the partial discharge has 
been extinguished, known as PDEV. The 
measurement of PDEV is critical as it will 
determine whether partial discharge will 
occur on the cable under normal operating 
conditions if an over-voltage condition arises, 
thus leading to the situation where PD activity 
is continuously working to degrade the cable’s 
insulation. The effects can only be reversed 
if the cable is de-energized and returned to 
service. 
In contrast, if the cables do not display PD up 
to the maximum applied voltage, the testing 
can be increased to ensure no partial discharges 
occur. If PD has begun at a lower interval of 
1.1 or 1.2 Uo, the specimen can be placed in 
service, but the critical state must be noted for 
future replacement or repairs. 
PD testing requires an AC waveform to 
function, for example, power frequency 
(60 Hz, 50 Hz) or very-low-frequency (VLF). 
Various VLF waveforms are used in cable 
testing, including VLF sinusoidal, VLF cosine 
rectangular (CR), and damped ac (DAC). 
VLF sinusoidal and cosine rectangular are 
continuous waveforms, while DAC is a 
decaying waveform consisting of discreet pulses 
that may have significant time between pulses 
on longer cables due to the increased capacitive 
load.
PARTIAL DISCHARGE IN 
CABLES
The measurement of partial discharge (PD) 
activity is a diagnostic method used to evaluate 
insulation quality. These measurements can be 
performed on cables, switchgear, transformers, 
or other types of electrical power equipment. 
Partial discharges are localized electrical 
discharges or sparks that can occur between Figure 1: Typical Shielded Cable Construction
NETAWorld • 49MEASURING PARTIAL DISCHARGE ON MEDIUM VOLTAGE CABLES
COVER STORY
conductors, such as the conductor and metallic 
sheath of a typical power cable (Figure 1), when 
the electrical insulation begins to deteriorate. 
However, these defects are not severe enough to 
bridge the insulation material to cause a short 
circuit condition to fail the cable.
PD activity is typically the first indicator of 
insulation deterioration within an insulation 
system. This is especially true for cables and 
cable joints (splices) where 89% and 91% 
of failures, respectively,are attributed to 
breakdown of the insulation per IEEE Gold 
Book, Table 36. The measurement of this 
activity can be analyzed to determine the type, 
magnitude, location, and applied voltage. 
These results can be used to “predict with a 
high level of confidence that a given cable is in 
very poor condition and is likely to fail in the 
near future.” (IEEE 400.3)
CABLE DEFECTS
Three types of defects are typically found 
in power cables: void, surface, and corona 
discharges. 
Void discharges (Figure 2) occur when a cavity 
is present in solid insulation. 
Surface discharges (Figure 3) are seen when 
PD events occur on the surface or interfaces of 
surfaces where there is physical damage. While 
there are many sources of surface PD, some 
examples are deep cuts where two layers of a 
cable meet due to poor workmanship such as 
on the semiconducting and insulating layers 
or improper positioning of stress relief at a 
termination or splice.
Corona discharges (Figure 4) occur when 
the electrical field of an energized conductor 
exceeds the dielectric strength of a gas creating 
a partial discharge. These types of discharges 
can be seen in a cable where sharp edges exist 
due to workmanship errors while installing a 
termination or splice. Another instance where 
a cable may experience corona discharges is 
in an air-filled void. In this case, the electrical 
stress will cause partial discharges across the air 
within the void. 
These deformities can exist for many reasons 
(Figure 5). However, they usually form when 
existing water trees convert to conductive 
electrical trees and begin to destroy a cable’s 
insulation. 
Figure 2: Equivalent Circuit of Dielectric with Void
Figure 3: Surface Discharge 
Figure 4: Corona Discharge Model
50 • WINTER 2022 MEASURING PARTIAL DISCHARGE ON MEDIUM VOLTAGE CABLES
COVER STORY
and peak voltages; however, it is slowed down 
to 0.1  Hz. This waveform is recognized for 
VLF withstand testing per IEEE 400.2. VLF 
sinusoidal is a prolonged changing wave that 
takes 10,000  ms or 10 seconds to produce 
one entire cycle or a polarity crossover every 
5,000 ms (about 5 seconds). 
VLF Cosine Rectangular 
A more advanced form of PD testing requires 
VLF cosine rectangular (CR) to be comparable 
to VLF sinusoidal. However, it does not have a 
rms voltage; instead, it only uses peak voltage. 
It may look identical to a square wave, but it 
is not a simple square wave. CR maintains a 
5-second DC hold followed by a sinusoidal 
transition into a 5-second hold of the opposite 
DC polarity. These back-and-forth transitions 
continue for the entirety of the test. The 
DC holds for a very short time and does not 
damage the cable’s insulation as continuous 
DC testing does because the polarity interval is 
brief, thus emulating an AC sinewave with only 
5 seconds +/- peak voltages. 
During PD testing, the CR transition uses 
the cable’s capacitance and a fixed inductor 
within the test equipment to create a resonance 
circuit. When the polarity transitions occur, 
The difference of potential within the void 
causes a point of concentrated electrical stress 
(Figure 6) that will continually deteriorate the 
dielectric strength of the insulation until it 
reaches total failure. 
APPLIED WAVEFORMS FOR 
PD MEASUREMENTS
Utilizing these off-line PD wave shapes for 
testing the VLF sinusoidal waveform can also 
be used as an initial wave shape for finding PD. 
VLF Sinusoidal 
VLF sinusoidal imitates the same wave shape 
as line frequency (50 Hz, 60 Hz), having rms 
Figure 5: Common Cable Defects
Figure 6: Electrical Field Distribution
COVER STORY
the circuit resonates one-half cycle applying a 
diode to stop the polarity switch. VLF cosine 
rectangular polarity reversal is in the range of 
16 ms to 1.6 ms, being similar to the polarity 
crossover of 60 Hz at 8.3 ms or 50 Hz at 10 ms. 
It therefore produces a considerably closer 
transition to line frequency than 5,000  ms 
(about 5 seconds) VLF sinusoidal waveform 
that is 1,000 times slower. 
Damped AC
Another advanced technique is damped AC, 
which sets up a resonance circuit similar to 
CR. However, DAC allows the voltage to 
exponentially decay through resistive losses of 
the circuit. It gives DAC a frequency closer to 
that of line frequency range (30 to 300 hz). The 
greater the frequency, the greater the probability 
that PD could be measured and the lower the 
PDIV can be. The voltage that is produced is 
only on the cable for a very short duration 
and uses a fluctuating waveform for only a few 
hundred milliseconds, making DAC the gentlest 
waveform for off-line PD testing of cables. 
VLF cosine rectangular and damped AC have 
polarity changes closer to line frequency than 
VLF sinusoidal. This increases the likelihood 
of finding PD in the cable. Solely utilizing VLF 
sinusoidal for PD testing may not represent the 
actual condition of the cable when testing. 
PDIV and PDEV
Partial discharge inception voltage (PDIV) is 
the voltage at which partial discharge activity 
begins to occur within a defect. PDIV is 
found by slowly raising the test voltage until 
PD activity is seen at any point along the 
cable, whether it be mid-span, a termination, 
or a splice point. This information is critical 
to understanding the quality of a cable’s 
insulation. As of this article, the PDIV 
thresholds established by U.S. standards do 
not provide criteria for partial discharge field 
measurements of in-service cables. Despite 
the absence of this criteria, this value should 
be measured and recorded to compare to 


52 • WINTER 2022 MEASURING PARTIAL DISCHARGE ON MEDIUM VOLTAGE CABLES
COVER STORY
future field measurements. Reduced PDIV 
in comparison to previous tests should be 
followed by further investigation to determine 
the insulation quality of a cable. 
Partial discharge extinguish voltage (PDEV) is 
the voltage level at which PD activity is no longer 
active in the test specimen. This is determined 
by gradually lowering the applied voltage once 
PDIV is discovered to a voltage magnitude 
where partial discharges are not measured. As 
with PDIV, field testing criteria has not been 
established per U.S. standards; however, it is 
important to note the applied voltage at the 
point of PDEV. Although established thresholds 
are not provided for field testing, the PDEV 
values set forth for factory testing can be used to 
make general decisions regarding the condition 
of power cables. For separable connectors (IEEE 
386), partial discharge activity should extinguish 
at 1.3 times above the rated voltage of the cable. 
Respectively, for cable joints (IEEE 404) and 
terminations (IEEE 48), the PDEV threshold is 
1.5 times the cable’s rated voltage. 
PARTIAL DISCHARGE 
ACTIVITY CHARACTERISTICS
Localization
Localization (Figure 7) is a valuable benefit 
to partial discharge testing. This can help 
determine the distance and location to a source 
of partial discharge in a cable. 
PD Localization Mapping 
PD localization mapping (Figure 8) gives the 
engineer or technician a visual indication 
of the distance to a defect and the discharge 
magnitude. These results can be compared to 
the physical layout of the cable to help pinpoint 
weak areas of a cable. 
The test set-up prior to taking any 
measurements is a key component to ensuring 
the distance found in the test results is accurate. 
The velocity factor or propagation of velocity 
must be properly selected for the type of cable 
being tested. 
PD Activity Magnitude
Partial discharge magnitude is measured in 
coulombs. This is typically found in the range 
of picocoulombs (pC) or nanocoulombs 
(nC). Generally, any measurement seen above 
100  pC is considered a cause for concern. 
However, this is dependent upon other 
factors, such as the insulation type of the cable 
being tested, the service age of the cable, and 
environmental conditions at the time ofthe 
test. Results of elevated partial discharge levels 
should be followed by further investigation to Figure 8: Localization Map of Partial Discharge
Figure 7: Partial Discharge Localization Measurement
COVER STORY
determine the source of the PD activity. The 
benefit of partial discharge testing is maximized 
when included with other types of cable tests as 
a part of a cable maintenance program. 
Benefits and Limitations
One of the greatest benefits of measuring 
partial discharge on cables is the ability to 
make maintenance decisions based on the 
actual condition of the cable. The presence 
of PD activity will be the first indication of 
deterioration of the insulation system within a 
cable. This allows the end user to address these 
problems before the cable reaches the point of 
total failure. This can help avoid unexpected 
system outages, thus improving cable reliability. 
Another significant benefit of partial discharge 
testing on cables is the localization of cable 
defects. Analysis of the results allows the 
engineer or technician to determine a specific 
source of PD activity within a cable, such as 
a termination or cable joint (splice). Cable 
defects are located through generated high-
frequency pulses that are propagated in both 
directions. During the measurement, the 
system uses the incoming signals to identify the 
directly incoming PD pulses and the respective 
reflections, as was seen in Figure 7. 
Cable age and neutral conductor condition are 
two characteristics that may significantly affect 
the ability to localize PD activity on a cable. 
Damaged or corroded neutral conductors could 
make it exceedingly difficult or impossible to 
properly localize PD activity within a cable. 
In cases where the user has difficulty localizing 
the source of partial discharges, the neutral 
conductor should be inspected and tested. 
One specific example of an application that 
creates a major challenge for localization is 
tape-shielded cables. As these types of cables 
age, corrosion forms between half-overlapped 
spiraling conductive layers. The presence of 
this oxidation creates an attenuating effect 
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54 • WINTER 2022 MEASURING PARTIAL DISCHARGE ON MEDIUM VOLTAGE CABLES
COVER STORY
[3] “Guidelines to Perform On-Line Partial 
Discharge Measurements in Underground 
Power Cable,” Rugged Monitoring. 
Accessed 22-Sep-2022 at: https://www.
ruggedmonitoring.com/blog/guidelines-
to-perform-on-line-partial-discharge-
measurements-in-underground-power-cable/5
e58add9cde096000141a77e. 
[4] J. Perkel and J. C. Hernandez-Mejia. 
NEETRAC, Atlanta, GA, 2016. 
[5] D. Götz, F. Petzold, H. Putter, S. 
Markalous, and M. Stephan. “Localized 
PRPD Pattern for Defect Recognition on 
MV and HV Cables,” 2016 IEEE/PES 
Transmission and Distribution Conference 
and Exposition (T&D), 2016, pp. 1-4, doi: 
10.1109/TDC.2016.752005.
Jason Aaron has been an Applications 
Engineer with Megger’s Technical Support 
Group since 2020. He enlisted in the US 
Marine Corp right after high school and 
was trained as an Aircraft Technician. 
After 10 years of service, he worked for 
Shermco for 8 years performing start-up, 
maintenance, and commissioning of electrical power systems 
and substations while earning Level 4 NETA certification. He 
is an IEEE member focusing in the areas of circuit breaker 
primary current injection techniques and cable testing, 
diagnostics, and fault location.
Joseph Aguirre is an Application Engineer 
at Megger. He specializes in cable testing, 
diagnostics, and fault location techniques 
as well as testing of all substation apparatus. 
Joseph trains end users on the theory and 
proper use of various pieces of high-voltage 
testing equipment. He has worked as a 
maintenance technician, a crew foreman for utility substation 
maintenance and construction, and as a NETA Certified 
Technician providing commissioning and maintenance on all 
substation apparatus and industrial electrical equipment before 
joining Megger. Joseph earned a BS in industrial technology at 
the University of Texas Permian Basin and is working toward a 
graduate degree in energy business and an MBA.
that interferes with the high-frequency pulses 
applied to localize the PD activity. 
CONCLUSION
There are numerous choices for the frequency 
and waveform that is applied during an off-
line partial discharge test. Testing at a power 
frequency of 50 or 60  Hz matches operating 
conditions, but this requires an exceptionally 
large power supply and is not practical for most 
field conditions. Testing at lower frequencies 
such as 0.1  Hz reduces the need for using a 
large power supply and allows the use of a 
much smaller, field-friendly unit. Testing can 
be accomplished utilizing sinusoidal, cosine-
rectangular, or damped AC waveforms. The 
choice of cosine-rectangular or damped 
AC more closely replicates testing at power 
frequency. These frequencies are experienced 
during the polarity changes that take place 
throughout the test where the change in voltage 
with respect to time occurs at a rate similar to 
power frequency. Therefore, testing with cosine-
rectangular or damped AC provides the benefit 
of a smaller test unit while still sustaining the 
means for an effective measurement. 
REFERENCES
[1] IEEE. IEEE Std. 493-1997, IEEE 
Recommended Practice for the Design 
of Reliable Industrial and Commercial 
Power Systems (Gold Book), pp.1-
464, 31 August 1998, doi: 10.1109/
IEEESTD.1998.89291.
[2] D. Gowda and A. Desai. “Modeling of 
Partial Discharge (PD) for Solid Insulation 
with Void and Building a Hardware Setup 
to Measure Partial Discharge,” Biennial 
International Conference on Power and 
Energy Systems: Towards Sustainable Energy, 
2016.
https://www.ruggedmonitoring.com/blog/guidelines-to-perform-on-line-partial-discharge-measurements-in-underground-power-cable/5e58add9cde096000141a77e
https://www.ruggedmonitoring.com/blog/guidelines-to-perform-on-line-partial-discharge-measurements-in-underground-power-cable/5e58add9cde096000141a77e
https://www.ruggedmonitoring.com/blog/guidelines-to-perform-on-line-partial-discharge-measurements-in-underground-power-cable/5e58add9cde096000141a77e
https://www.ruggedmonitoring.com/blog/guidelines-to-perform-on-line-partial-discharge-measurements-in-underground-power-cable/5e58add9cde096000141a77e
https://www.ruggedmonitoring.com/blog/guidelines-to-perform-on-line-partial-discharge-measurements-in-underground-power-cable/5e58add9cde096000141a77e
56 • WINTER 2022 ON-LINE CABLE PD TESTING
BY WILL IAM G. HIGINBOTHAM, EA Technology
Imagine this: A new hyper-scale data center is built in rural New Jersey. 
It has more than 100 25 KV cables. Six months into operation, a cable 
termination fails catastrophically, and the forensic investigation determines 
that termination workmanship was lacking. Partial discharge caused 
tracking, and the cable flashed over. But that’s not the nightmare scenario. 
The nightmare scenario is that the same team of jointers terminated all 
100 cables, and the owner has no idea if they are all on the edge of failing 
or if this was the only bad cable. 
The owner is left with three options of how 
they might respond to the crisis: 
 1. Shut the data center down for weeks or 
longer and test every cable.
 2. Bury their heads in the sand and hope 
they have no more failures.
 3. Test all the cables on-line to identify any 
suspect cables for further study.
By examining the theory behind on-line 
testing, this article will show that the third 
option is the only solution that is both proven 
and practical at reducing the impact of 
additional bad terminations down the road. 
HISTORY
In previousarticles, we have covered how 
medium-voltage cables — and specifically 
MV cable terminations — are one of the least 
reliable parts of any power system. Any time 
you introduce the possibility of human error 
into a closed system, you increase the risk of 
detrimental outcomes. 
Cable failures are caused by subpar 
workmanship at the terminations two-
thirds of the time. This is due to a variety of 
reasons, including the fact that doing a field 
termination is a technically challenging job 
in a less-than-ideal situation. Minor mistakes 
can result in hidden problems that may not 
manifest themselves until years later.
Traditionally, cable testing occurs in two 
different forms over the life of the cable: pre-
commissioning testing and maintenance 
testing. 
 1. Pre-commissioning tests include 
conductor resistance, insulation 
resistance, dielectric withstand, tan-delta, 
and shield continuity. Occasionally, off-
line VLF-based partial discharge testing is 
done.
 2. Maintenance testing is performed to 
find problems that can occur or worsen 
over time. In highly critical applications 
ON-LINE CABLE 
PD TESTING
FEATURE
NETAWorld • 57ON-LINE CABLE PD TESTING
FEATURE
where cables can be temporarily removed 
from service, the same tests performed at 
commissioning are performed again at 
slightly reduced values to avoid stressing 
the cables. While this testing does identify 
concerns, it is disruptive. 
As technology has developed, on-line main-
tenance testing has emerged as the ideal first 
line of defense in cable maintenance. On-line 
maintenance testing is ideal because it does 
not impact operations and is therefore much 
less disruptive and less expensive. Clearly, not 
all pre-commissioning tests can be done on-
line, so there is a tradeoff, but on-line testing 
can provide information that allows further 
investigation to be more strategic. On-line 
testing is typically limited to:
• Conductor resistance is an incredibly 
important piece of information to have. 
High resistance can result in failure quite 
quickly. High resistance is usually a result 
of poor termination crimping or shear-bolt 
installation and can worsen over time. This 
is easily detected on-line using infrared 
(IR). Using IR to inspect terminations 
can detect temperature rise due to high 
resistance. This type of testing is widely 
used at all voltages.
• On-line partial discharge (PD) testing can 
find insulation problems that exist upon 
initial energization as well as those that 
have developed or worsened over time. 
This article takes a closer look at on-line 
PD testing.
Using a Parabolic Ultrasonic Setector on Pad-Mount Cable Terminations
58 • WINTER 2022 ON-LINE CABLE PD TESTING
FEATURE
THEORY
Although not widely known, PD in cables is 
a well-understood phenomenon that can lead 
to failure at any time. In a power system, if the 
voltage applied (KV/mm) exceeds a section 
of the insulation’s ability to withstand it, a 
discharge occurs. If the problem is the entire 
insulation system, a total catastrophic discharge 
occurs. If it’s only part of the insulation, a much 
smaller, short-duration, low-energy discharge 
occurs. This discharge damages the insulation 
further and will lead to a full discharge if left 
untreated. Detecting partial discharge can 
allow the asset to be repaired before it fails 
completely causing loss of load.
If the insulation system is completely 
homogeneous, the voltage field distribution is 
perfectly even and the only discharge that can 
occur is a total flashover. If the insulation is 
not homogeneous — by that, I mean part of it 
has higher or lower permittivity — the voltage 
distribution will not be even. This can occur 
due to inclusion in the insulation, damage to 
the insulation during installation, or improper 
use/construction of terminations to control 
the electrical field as it transitions out of the 
cable insulation at connection points on the 
equipment. A higher concentration of voltage 
stress can occur on a smaller, and potentially 
weaker, part of the insulation. This section with 
higher stress can then discharge and be damaged. 
An example of this can be seen in Figure 1, 
which shows the distribution of voltage across 
an insulator with an air-filled void. This void is 
exposed to a higher-voltage gradient due to the 
air having lower relative permittivity than the 
XLPE insulation. If the high-voltage gradient 
exceeds the withstand of air, partial discharge 
will occur across the void. The problem is 
compounded by air having a lower dielectric 
strength than XPLE.
TOOLS
Thankfully, partial discharge occurring within 
the insulation or termination of a cable can be 
detected with a variety of on-line tests: 
• Ultrasonic testing. PD near the surface 
of a cable termination causes air- and 
structure-borne ultrasonic energy to be 
released.
• High-frequency current transformer 
(HFCT) testing. Partial discharge can 
Figure 1: Field Distribution with a Void
NETAWorld • 59ON-LINE CABLE PD TESTING
FEATURE
induce currents down the shield and the 
cable conductor at higher frequency than 
the power signals. By attaching an HFCT 
to the ground shield of a cable, these 
signals can be identified and monitored. 
• Transient earth voltage (TEV) testing. 
PD currents cause transient voltage 
spikes on grounded surfaces such as cable 
compartment doors and cable sheaths. 
These can be picked up by measuring for 
voltage transients on the cabinet doors. 
• UHF radio detection. PD causes 
cable terminations to emit broadband 
UHF spikes. Outdoor terminations are 
unshielded, and these emissions can be 
detected.
Any tool used for cable testing should be 
capable of multiple techniques and must 
also be synchronized to the power system 
frequency for higher selectivity. It must include 
algorithms to filter and discriminate PD in the 
presence of noise.
PRACTICAL ISSUES
A variety of issues can limit the ability to find PD 
in cables, but the two most prominent are access 
to shield ground straps and conducted noise. 
In European-type switchgear, cables are 
terminated such that the ground straps from 
the shields are outside the HV compartment. 
In U.S. ANSI-style switchgear, the straps are 
entirely inside the HV compartment. This makes 
application of the HFCT difficult. Permanently 
installing the HFCT inside the compartment or 
bringing the grounds straps outside are the most 
practical solutions. Cables on riser poles are 
easier since they tend to have exposed grounds.
Noise can play a major role in PD detectability. 
Highly noisy cables like those attached to 
inverters or electric arc furnaces can be difficult 
to test. Temporarily removing the noise source 
may be necessary. Test equipment has a variety 
of tools to reduce the impact of noise but there 
are practical limitations.
LIMITATIONS AND PITFALLS
Additional limitations and potential pitfalls 
must be considered when running on-line tests.
• The best on-line HFCT test can see 
only as far as the next point where the 
shield is grounded. If you have a cable 
where every splice or manhole location 
is grounded, you will have to test at each 
ground location.
• Ideally, you want to test on every 
ground of each phase conductor 
separately. Physically, ground 
connections may make that impossible. A 
test on the combined ground is possible 
but it typically has reduced sensitivity. 
Figure 2 shows a test on a single phase.
Figure 2: Single-Phase Ground Test — No Filter
60 • WINTER 2022 ON-LINE CABLE PD TESTING
FEATURE
Ultrasonic testing of terminations is very useful 
but well-sealed compartments or outdoor 
terminations can be a challenge. Contact sensors 
and ultrasonic dishes can solve these problems.
HFCT testing works well on concentric neutral 
and tape-shielded cables in good condition. 
However, if a cable has corrosion in the tape shield 
overlap, the shield goes from being a continuous, 
low-impedance path to a long helical coil. Thiswill present higher resistance and much higher 
impedance to the PD current pulses. This can 
dramatically shorten the PD detection distance.
Figure 3 shows the same test on combined 
grounds with no filtering. The noise is much 
greater and hides the PD on the combined 
ground.
Figure 4 shows the same combined test with 
some noise filtering applied. The PD is visible, 
but still not as clean as Figure 2.
TEV testing directly on the sheath of the cable 
near the termination is a great way to find PD 
but armored or buried cables can limit the 
ability to do that test.
Figure 3: Combined Ground Test — No Filter
Figure 4: Combined Ground Test with Filtering
NETAWorld • 61ON-LINE CABLE PD TESTING
FEATURE
CASE 
STUDY
CASE 
STUDY
1
2
A cable in Saudi Arabia was scanned using an HFCT. Not only was PD present, but the results 
were so clean the tester could determine the distance to the source. A buried splice was found 
and confirmed with TEV testing. Once the joint was replaced, the TEV reading showed no PD, 
confirming the fix. Figure 5 shows the phase-resolved plot and the waveforms that allowed the 
location to be mapped.
Figure 5: HFCT Results from Defective Buried Joint
A cable that was only 12 months old was scanned using HFCT and TEV. Where there should 
have been no PD, there were massive readings. The termination was disassembled and a shield 
and spring were found to be missing. Once corrected and re-energized, the TEV showed a 
significant drop in level but the PD was not completely gone. Time to look for more damage! 
Figure 6 shows HFCT and TEV readings.
Figure 6: A) HFCT and B) TEV Readings of Bad Termination
A B
62 • WINTER 2022 ON-LINE CABLE PD TESTING
FEATURE
A high-voltage asset owner in central Canada has numerous terminations 
on substation structures. Contamination is building up unevenly on the 
terminations. This operator is very proactive and periodically does PD 
surveys of indoor and outdoor assets as part of their regular preventative maintenance.
One of the scanned terminations returned very-high levels of ultrasonic energy. The phase-
resolved plots show typical PD results. The source is frequency locked to the power system, and 
the impulses are occurring twice a cycle, half a cycle apart. The levels are approaching 40 dBuV, 
which is very high. ANSI/NETA MTS 2019 calls for immediate action on levels greater than 
6 dBuV. Figure 7 shows the phase-resolved plot and the contaminated termination.
CASE 
STUDY 3
Figure 7: A) Phase-Resolved Plot and B) Contaminated Termination
During the next scheduled outage, the insulators were cleaned and then rescanned. The 
ultrasonic energy was gone, proving that the discharge was a result of the contamination. Figure 
8 shows the phase-resolved plot and termination after thorough cleaning.
Figure 8: A) Phase-Resolved Plot and B) Termination After Cleaning
 
A
A
B
B
FEATURE
William G. Higinbotham has been 
president of EA Technology LLC since 
2013. His responsibilities involve general 
management of the company, including 
EA Technology activities in North and 
South America. William is also responsible 
for sales, service, support, and training 
on partial discharge instruments and condition-based 
asset management. He is the author or co-author of several 
industry papers. Previously, William was Vice President of 
RFL Electronics Inc.’s Research and Development Engineering 
Group, where his responsibilities included new product 
development, manufacturing engineering, and technical 
support. He is an IEEE Senior Member and is active in the 
IEEE Power Systems Relaying Committee. He has co-authored 
a number of IEEE standards in the field of power system 
protection and communication and holds one patent in this 
area. William received a BS in computer/electrical engineering 
from Rutgers, the State University of New Jersey’s School of 
Engineering, and worked in the biomedical engineering field 
for five years prior to joining RFL.
Industrial Electric Testing, Inc.
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Testing
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• Power Factor Studies 
11321 West Distribution Avenue • Jacksonville, Florida 32256 • (904) 260-8378
201 NW 1st Avenue • Hallandale, Florida 33009 • (954) 456-7020
64 • WINTER 2022 DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
BY MICHEL TRÉPANIER and CLAUDE TREMBLAY, Hydro-Quebec; 
L IONEL REYNAUD, Hydro-Quebec Research Institute; 
and MATHIEU LACHANCE, OMICRON electronics Canada 
Hydro-Quebec (HQ) is a major Canadian utility that manages the 
generation, transmission, and distribution of electricity to more than 
3.8 million customers. Its distribution network includes over 12,000 
km (7,456 miles) of medium-voltage underground distribution cables 
and more than 600,000 accessories — each with potential for failure.
Medium-voltage (MV) underground cable 
systems are a critical part of the distribution 
network of many electric utilities. Like 
any other power apparatus, insulation in 
underground MV cable systems ages over 
time. In North America, a large number of 
underground cross-linked polyethylene (XLPE) 
cables were installed in the 1970s and 1980s 
with a reported design life in the range of 30 
to 40 years.[1] Today, utilities are faced with 
underground distribution systems that are 
theoretically either at the end of or past their 
design life. 
RELIABILITY CHALLENGES
The reliability of the electric grid has always 
been a topic of interest. In-service failures lead 
to loss of revenue, increase in expenditures for 
repairs, and potential damage to other power 
apparatus due to increased stress during the 
fault. Furthermore, public and personal safety 
can be compromised, especially when these 
failures occur in underground vaults and 
manholes in densely populated urban areas.
Replacing every piece of equipment and 
accessory that has reached its theoretical design 
service life is not an option for economical and 
practical reasons:
 1. Newly introduced technologies can lead 
to higher risk of infant failures. 
 2. Each specimen ages at a different 
rate depending on the operating and 
environmental conditions. 
Therefore, maintenance and diagnostic tests 
are common practice to assess the health of 
power system critical assets. This can rapidly 
become challenging for utilities where available 
manpower and/or funding might not be available 
to periodically test every electrical component. 
DETECTING PARTIAL 
DISCHARGE ON 
MEDIUM-VOLTAGE 
CABLE ACCESSORIES 
FEATURE
NETAWorld • 65DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
The costs and constraints associated with 
replacing a network accessory are significant. 
The planning, work preparation, maneuvers to 
isolate the problematic equipment, execution of 
the work, and restoration can easily generate costs 
of tens of thousands of dollars — and this for an 
accessory worth only a few hundred dollars.
This situation becomes all the more significant 
when the problem is associated with a complete 
set of accessories, or worse, when the quality, 
precision, or methodology of the tests carried 
out by the manufacturer is not adequate. 
A utility can quickly face a major problem 
when several hundred or thousands of faulty 
accessories are installed in the network before 
noticing the problem and determining itssource and nature.
In 2005, Hydro-Quebec reported that most 
of the in-service failures in its underground 
distribution network occurred at cable joints. 
A common cause of deterioration in those cable 
accessories was partial discharges.[2] 
This article shows how HQ has implemented a 
thorough inspection procedure to decrease the 
rate of failure in their underground distribution 
network. Among other tools, a multi-level PD 
detection approach was adopted to minimize 
the expertise required onsite. Several case 
studies are used to show the advantage of such 
an inspection procedure for an underground 
system.
PARTIAL DISCHARGE 
THEORY 
The theory of partial discharges is very 
complex, and a complete description is beyond 
the scope of this article. However, a basic 
understanding of the phenomenon is helpful 
from this point onward.
PHOTO: © ISTOCKPHOTO.COM/PORTFOLIO/BENNYPAQ
66 • WINTER 2022 DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
A partial discharge (PD) is a localized dielectric 
breakdown of a small portion of an insulation 
system under electrical stress. PD can occur 
when the local electric field exceeds the local 
dielectric strength at a given location within 
or on the surface of an energized object. Each 
PD event will generate a current pulse. At its 
origin, if the discharge occurs in atmospheric 
air, this pulse has a rise time of just a few 
nanoseconds. It contains a theoretical constant 
broad frequency spectrum from DC to up to 
several hundred megahertz (MHz). Therefore, 
PD can be detected using various technologies.
IEC 60270[3] is a normative document that 
defines the broad lines of PD measurements 
in many electrical devices. It specifies the 
test circuit, type of sensors, and measured 
frequency range and designates apparent charge 
(in picocoulombs) as the unit to quantify 
PD activity. Figure 1 shows an example of a 
typical PD measurement circuit according to 
IEC 60270.
IEC  60270 is primarily applicable for PD 
measurement performed in controlled 
environments, such as a factory or laboratory, 
where interferences can be easily mitigated. PD 
measurements that comply with IEC  60270 
are commonly referred to as conventional PD 
measurements. 
When measuring PD in the field, it can be 
challenging to comply with every IEC  60270 
requirement. Space restrictions, a high level of 
interference, and the difficulty of performing a 
valid calibration are among the most common 
reasons other techniques are used. These are often 
defined as unconventional PD measurements and 
are described in IEC 62478.[4]
One example of such a measurement is the 
use of an antenna as a sensor. The antenna is 
installed on the surface or near the equipment 
and captures part of the energy from the 
electromagnetic wave generated by the 
discharge activity. In this case, many factors 
influence the measured quantity; therefore, 
the assessment usually focuses on whether PD 
activity is detected rather than quantification 
of the discharges. A simplified schematic of 
unconventional PD measurement performed 
using an antenna is shown in Figure 2.
INSPECTION AT 
HYDRO-QUEBEC 
UNDERGROUND SYSTEM
Over the years, HQ has become a leader 
in online problem detection. Predictive 
maintenance to ensure safe access to 
underground facilities was introduced in 1996 
Ca
Ck
Zm
ZHV
HV
Z
Ca
Ck
Zm
CD
MI
high-voltage supply
high-voltage filter (optional)
test object
coupling capacitor
measuring impedance
coupling device
PD measuring instrument
where,
CD
MI
Figure 1: PD Measurement Circuit 
According to IEC 60270
Figure 2: UHF PD Detection Using an Antenna-Type Sensor
Test
object
Test
object Antenna
MI
NETAWorld • 67DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
in an exploratory manner. Now, 25 years 
later, HQ has a mature and sophisticated 
preventive inspection program that makes it 
possible to target any potential anomaly of an 
accessory before an in-service failure occurs. 
It also provides workers with safe access to 
underground facilities. 
Every vault or manhole should be inspected 
once every six years, and 30 HQ teams are 
dedicated to this inspection program, which 
represents an annual inspection of more 
than 100,000 accessories in 12,000 vaults or 
manholes. Every manhole inspected with no 
anomaly is given an access validity period of 
one year. In addition to these inspections, 
several hundred repairs per year must be made 
in manholes that do not earn this validity 
period and therefore require emergency 
inspection.
A manhole inspection has four phases (Figure 3): 
 1. Measure potentially harmful and 
combustible gases.
 2. Use thermographic measurement of 
low- and medium-voltage components to 
identify hot spots.
 3. Measure PD on medium-voltage 
accessories. 
 4. Integrate a 360-degree photo into an 
interactive 3D experience tool to help 
to plan, visualize, and evaluate events 
such as a virtual tour of underground 
installations, optimization of work 
preparation, evaluation of the degradation 
of the vault, and new line routing with 
fewer field visits. 
Depending on the test to be performed 
(infrared or 360-degree imaging), the device 
is fixed at the end of a pole, which is lowered 
inside the structure. The cameras are connected 
by cable to a computer in the thermograph 
truck. An operator handles the cameras, views 
the infrared images, and detects hot spots. 
Hydro-Quebec has developed diagnostic software 
to evaluate the performance of splice connection, 
i.e., the internal temperature of each accessory and 
the current at which the maximum temperature 
will be reached given the type of splice, cable size, 
and ambient temperature (Figure 4).
PD measurements are complementary to the 
thermographic inspection. If no anomaly is 
• Harmful and combustible gases
• Low-voltage equipment
• Medium-voltage equipment
• Medium-voltage equipment
• Civil infrastructure
• Projects evaluation
360º Imaging
PD Measurement
Thermography
Gases detection
Figure 3: Inspection Program Phases
68 • WINTER 2022 DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
Dielectric
losses
Interfacial 
issues
140
∆
(ºC
)
Current (A)
120 No immediate action, inspection good for 1 year.
Accessibility to the manhole is prohibited when the
component is energized. Splice replacement is required.
No immediate action, inspection good for
1 year. Additional verification durring access.
100
80
60
40
20
0
0 200 400 600
Overheating
connections
detected by thermography, PD measurement is 
completed on all medium-voltage components 
present inside the underground vault. Online 
PD measurements made during HQ’s 
maintenance program are non-conventional 
PD measurements, which means that only the 
presence of PD in an accessory is measured, not 
its charge in picoCoulombs.[4] 
A PD sniffer[5][6][7] has been specifically designed 
for use by non-expert workers as a first-level 
safety tool. It can recognize a PD signal in a fully 
automatic manner without any interpretation. 
Currently, the PD sniffer is being gradually 
replaced by a PD alarm,[8][9] a new, lighter, less 
expensive tool (Figure 5).
The PD alarm is able to detect the inversion of 
polarity of a PD (Figure 6) produced between 
the two antennas at an operating range below 
30 MHz and centered around 18 MHz.[10] This 
low band frequency allows the use of standard 
Figure 4: Automatic Evaluation of a Splice Performance
Figure 5: PD Alarm Mobile Unit
FEATURE
PD probes
Green light
indicating absence
of a PD between
the 2 probes
PD Location
No PD One probe is moved upwards : PD detection
Red light
indicating
presence of a PD
between the
2 probes
Figure 6: PD Detection Performed with the PD Alarm Tool
and cheaper electronics for all necessary 
treatments. The development of antennas is 
also one of the keys to success.
When potential partial discharge is detected by a 
thermographer,he leaves the manhole and calls 
the technical team of engineers for validation. 
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FEATURE
An engineer then uses the advanced partial 
discharge analyzer (PDA)[2][11] to confirm or 
deny the presence of PD.
CASE STUDIES
Over the years, PD measurements have enabled 
Hydro-Quebec to detect dielectric anomalies 
on underground accessories that were aging 
as well as on accessories newly installed in the 
network. This helped avoid worker exposure 
to imminent risk as well as breakdowns and 
associated costs by removing these problematic 
accessories before an in-service failure occurred.
Most cases are caused by improper assembly; a 
minority are caused by manufacturing issues. 
However, manufacturing issues can have greater 
negative impact on the network. Although 
factory tests are carried out by manufacturers of 
electrical distribution products, a dielectric fault is 
sometimes detected on the accessory installed in 
the network. These cases are the most interesting 
because they are the subject of a more in-depth 
analysis. Here are several examples of problematic 
accessories that had passed manufacturers’ tests 
and had been installed in a network.
Case Study I: 600 A Molded 
Busbars
600 A molded busbars were installed by HQ 
linemen in vaults to interconnect molded fuses 
and transformers (Figure 7). They are also part 
of a multi-channel solid dielectric switchgear 
deployed on Hydro-Quebec’s network.Figure 7: Molded Busbar in Vault
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NETAWorld • 71DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
Using the PD sniffer tool, HQ thermographers 
noticed probable PD on molded busbars 
recently installed in vaults, and an expert 
engineer confirmed the presence of PD with 
the PDA system. He also used the new PD 
alarm tool, which indicated the presence of PD. 
After removal, phase-resolved partial discharge 
(PRPD) analysis done on the defective units 
(Figure 8) clearly shows the presence of PD.
At almost the same time, the test engineer 
in charge of testing all new equipment prior 
to being installed in the field measured and 
confirmed PD on a multi-channel dielectric 
switchgear. During some open-close operations 
on the switchgear, the test engineer was able to 
determine that the PD was coming from the 
bus work of the apparatus, but he could not 
determine which component of the bus work 
was defective. To finalize his analysis, the test 
engineer used the new PD alarm tool to locate 
the defective part of the bus work: a 600  A 
molded busbar.
Following this event, Hydro-Quebec measured 
PD on new accessories from this manufacturer 
and confirmed the presence of PD activity on 
a high percentage of the analyzed accessories. 
Based on the PRPD analysis of the tested 
molded busbars, the test engineer suspected 
that the PD was created by porosity in the 
insulation material. X-ray images were taken 
on three defective molded busbars, and the 
verdict was the same: There were porosities 
in the insulation at one end of the molded 
busbar (Figure 9). The manufacturer analyzed 
and dissected the returned units and came to 
the same conclusion. Corrective actions in the 
molding and PD testing process were then 
taken by the manufacturer.
Additional Case Studies 
The sequence of events in the following cases is 
the same as in the previous section:
• Workers detected the presence of PD on 
an accessory installed in the field using 
the PD sniffer or PD alarm.
• The presence of PD was confirmed by the 
technical support team using the PDA.
• The defective accessory was removed from 
the underground system and replaced.
Figure 8: PRPD Analysis on Molded Busbar
Figure 9: X-ray images showed porosities in the insulation material at 
one end of the molded busbar.
72 • WINTER 2022 DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
• When several identical cases were detected, 
PRPD analysis was done in a laboratory.
• Sometimes an X-ray scan of the accessory 
was done.
• A report on the origin of PD was written.
• If it was a manufacturing problem, the 
conclusions were sent to the manufacturer 
so corrective actions could be taken.
Figure 10: Cavity in a Separable Cable Joint
Cavity
Cavities
Figure 11: Air Gaps in Submersible Epoxy Isolated Fuse
Capacitive Plug of a 
Separable Cable Joint
In 2011, we observed the presence of PD 
activity on more than 15 newly installed 
accessories. Hydro-Quebec has more than 
55,000 units of this type of accessory 
distributed in more than 3,500 underground 
structures.
Problems A faulty area of the molding was located at the capacitive socket. X-ray images showed 
that some space was not filled by the insulating material (Figure 10). The manufacturer 
had changed some molds, and its factory test procedure did not detect the problematic 
components.
Corrective 
Actions
Hydro-Quebec informed the manufacturer of the problem associated with the molding of 
this type of accessory and returned all its separable cable joints from the same lot to the 
manufacturer. The manufacturer corrected the molding issue and testing procedures for 
these components.
Submersible Epoxy Isolated Fuse
This electrical device is used to provide protection for a submersible transformer in the event of 
an overload or internal failure. HQ has approximately 2,000 fuses of this type installed in over 
500 underground structures.
Problems PD was caused by air gaps (Figure 11) inside the silicone filling, which is used to fill the 
void at the interface of three materials: brass, fiberglass, and epoxy. 
Corrective 
Actions
Hydro-Quebec replaced the fuses with the highest levels of PD. Several tests were per-
formed to determine whether it was safe for workers to be near these components. It was 
concluded that, due to its location, PD activity does not deteriorate the epoxy insulation.
CASE 1
CASE 2
Air gaps in silicone filling
NETAWorld • 73DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
Cap for 
Grounding Device
This component is 
installed on pad-mounted 
switches and is used to 
isolate the grounding 
device.
Problems PD was caused by porosity in the insulation material and poor bonding between the 
semiconductor and the insulation material (Figure 12).
Corrective 
Actions
During PD factory tests, the grounding cap was temporally installed and maintained 
using a hydraulic press. The test-bench assembly applied non-uniform pressure to the 
components and did not reflect the in-service condition. When the manufacturer was 
informed, the test bench was adjusted to properly detect anomalies.
 
CASE 3 Bounding
Porosity
zone
Figure 12: Cap for Grounding Device, Porosity, and Bounding
T-Elbow on Medium-Voltage Switches
This connection accessory called deadbreak elbow is mainly used to connect an underground 
cable to a switchgear.
Problems Several components of this type installed on the network 
showed PD activity. The problematic components were 
removed and investigated.It was found that the PD was 
caused by bad contact between the semiconductor and the 
lug (Figure 13).
Corrective 
Actions
Manufacturing tests were made with a connector bigger 
than the actual connector used in service. The connector 
used in-service did not make proper contact and generated 
PD activity. The manufacturer adjusted his test bench and 
was able to detect accessories that were out of tolerance.
Figure 13: Surface Contact Problem with a T-Elbow
CASE 4
74 • WINTER 2022 DETECTING PARTIAL DISCHARGE ON MEDIUM-VOLTAGE CABLE ACCESSORIES 
FEATURE
CONCLUSION
Hydro-Quebec’s maintenance program achieves 
several targets. The first of these targets is the 
health and safety of employees and the public. 
By removing potentially dangerous accessories 
from the network prior to their failure, HQ 
raises its safety criteria to a high level. It is a 
priority for the company.
The second target is economic. The maintenance 
program reduces in-service failures. Performing 
a repair after an in-service failure is at least two 
and a half times more expensive than replacing 
an accessory after an inspection. In addition, 
when corrective actions are planned, there is 
little or no service interruption.
The third target is to ensure quality service and 
continue monitoring best practices. This quality 
assurance has repercussions on manufacturers 
since they are notified on certain issues, 
allowing them to improve their processes. 
Approximately 500 anomalies are detected each 
year by thermography and 100 anomalies by 
detection of PD. Since the beginning of the 
maintenance program, the number of anomalies 
has greatly decreased (Figure 14). 
REFERENCES
[1] “Diagnostic Testing of Underground 
Cable Systems,” Cable Diagnostic Focused 
Initiative, DOE Award No. DE-FC02-
04CH11237, Dec. 2010. 
[2] D. Fournier et al. “Detection, Localization 
and Interpretation of Partial Discharge in 
the Underground Distribution Network 
at Hydro-Quebec,” CIRED 2005 — 18th 
International Conference and Exhibition on 
Electricity Distribution, Turin, Italy, 2005, 
pp. 1-4, doi: 10.1049/cp:20050961.
[3] International Electrotechnical 
Commission. IEC 60270, High-Voltage 
Test Techniques —Partial Discharge 
Measurements, Edition 3.1.
[4] International Electrotechnical 
Commission. IEC TS 62478-2016, High-
Voltage Test Techniques — Measurement of 
Partial Discharges by Electromagnetic and 
Acoustic Methods, Edition 1.0.
[5] F. Léonard et al. “Partial Discharge (PD) 
Sniffer for Worker Safety in Underground 
Vaults,” Acts of the CIRED Conference, 2011.
[6] L. Reynaud, D. Pineau, M. Charette. 
“Partial Discharge (PD) Automatic 
Diagnosis Tool for Worker Safety in 
Underground Vaults, Jicable’11 Conference, 
Versailles, France, 2011.
[7] F. Léonard. “Dynamic Clustering 
of Transient Signals,” United States 
Patent Application Publication, US 
2014/0100821 A1.
[8] L. Reynaud, D. Pineau, M. Charette, M. 
Trépanier. “PD Alarm — Lightweight 
Automated Diagnostic Device for Online 
Detection and Location of Partial Discharges 
on Non-Shielded Accessories of a Medium-
Voltage Distribution Network,” Jicable’19 
Conference, Versailles, France, 2019.
[9] L. Reynaud, M. Trépanier, D. Pineau, 
M. Charette. “PD Alarm Tool for Online 
Detection of Partial Discharges in 
Medium-Voltage Accessories: Technology 
and Case Studies,” Acts of the DOBLE 
Conference, Boston, MA, USA, 2020.
[10] D. Pineau, L. Reynaud, M. Charrette. 
“Détecteur de Décharge Partielle et 
Méthode Associée,”United States Patent 
0297-PCT-US ; Canada Patent Pending 
0297-PCT-CA, 2019.
[11] D. Fournier et al. “Detection, Localization 
and Interpretation of Partial Discharge,” 
United States Patent US 8,126,664 B2, 
2012.
Figure 14: Number of Anomalies vs. Years
500
400
2000
300
200
100
0
2005 2010
Dielectric
Anomalies
2015 2020
PD Resistive
FEATURE
Michel Trépanier worked in the 
Underground Distribution Division 
of Hydro-Quebec (HQ) in Montréal, 
Canada, from 2006–2009 as a Technical 
Support Engineer for the inspection teams 
in predictive maintenance, location, 
and analysis of underground faults. In 
2010, he joined the Underground Distribution Standards 
Department, where he specializes in thermal inspection, partial 
discharge analysis, and characterization of medium-voltage 
electrical accessories. He contributed to several expertise and 
innovation projects at the Hydro-Quebec Research Institute. 
Michel obtained his engineering degree in electrical energy 
and electrical networks at École de Technologie Supérieure de 
Montréal in 2005. 
Claude Tremblay is an Electrical Engineer 
with more than 25 years of experience in 
engineering and project management at 
Hydro-Quebec. Since 2010, he has been 
actively involved in standards development 
for Hydro-Quebec and the Canadian 
Standards Association. Claude presently 
leads a team that provides technical support to his organization’s 
project planners and linemen. He specializes in conventional PD 
testing on medium-voltage equipment and accessories. Claude 
graduated from Sherbrooke University and is a licensed member 
of the Ordre des ingénieurs du Quebec. 
Lionel Reynaud has been involved in 
research and development of numerous 
control and monitoring systems at the 
Hydro-Quebec Research Institute (IREQ) 
in Varennes, Canada, since 1998. Since 
2003, Lionel has specialized in problems 
related to cables and accessories at Hydro-
Quebec’s underground medium-voltage distribution network. 
As Project Manager, he led the deployment of tools for fault 
location and partial discharge detection. Lionel obtained a 
University Technological Diploma in electrical engineering and 
industrial computing and an MS in computer systems at the 
Higher Institute of Aeronautics and Space in Toulouse, France.
Mathieu Lachance joined OMICRON 
electronics Canada Corp. in 2019 and 
presently holds the position of Regional 
Application Specialist for rotating machines 
and partial discharges. Matthieu previously 
worked as a test engineer in the fields of 
partial discharges and high voltage. He 
received a BS in electrical engineering from Université Laval 
in 2014. 
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76 • WINTER 2022 ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
BY THOMAS SANDRI, Protec Equipment Resources
As time progresses and a cable system ages, the system’s bulk dielectric 
strength degrades. During this aging process, artifacts such as water trees, 
delamination, voids, and shield corrosion raise the local stress placed 
on the cable during normal operation. The exact way in which the 
strength of a device degrades will depend upon many factors including 
voltage, thermal stresses, maintenance practices, system age, cable system 
technology and materials, and environment.
For years, high-voltage direct current (DC) testing 
had been the traditionally accepted method for 
judging the serviceability of medium-voltage 
cables. DC high-potential tests have worked well 
for conducting dielectric strength and condition 
assessment tests on paper insulated lead covered 
(PILC) cable. When cable materials began to 
change and plastic insulated cables were first 
introduced in the 1960s, little was known about 
the overall aging characteristics of the new 
materials, and DC therefore continued to be the 
preferred method of testing.
As time moved on, plastic insulated cables 
became more abundant, and as they aged, 
they began showing effects of service age. DC 
continued to be the dominant test, but concerns 
began to grow over the effectiveness of this test. 
In the early 1990s, reports began to surface 
indicating thatDC high-potential testing could 
be to blame for latent damage experienced by 
extruded medium-voltage cable insulation.
As insulation materials continue to change and 
improve and as reliability demands grow, testing 
ACCEPTANCE AND 
MAINTENANCE TESTING 
FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER 
CABLES — PART 1 OF 3
FEATURE
NETAWorld • 77ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
methods have been developed that provide a 
better indication of the integrity of cables, 
splices, and terminations. To use these methods 
effectively, the operator must understand the 
mechanisms of aging and failure in cable 
systems. It is also important to understand 
testing techniques and have the ability to 
diagnose test results. It is equally important 
for trained personnel to be thoroughly familiar 
with the fundamentals of power cable design, 
operation, and maintenance. 
This article reviews the evolution of testing 
methods and philosophies over the past 30-
plus years. The intended application of each 
technique along with the advantages and 
limitations of the technique will be reviewed 
providing the knowledge necessary to develop 
an effective cable testing program.
SIX BASIC LAYERS OF MV 
CABLE CONSTRUCTION
In a typical medium-voltage cable, copper or 
aluminum wires (either stranded or solid) are used 
as conductors (Figure 1). These conductors are 
covered with an extruded polymeric stress-control 
layer made of semi-conductive compounds, often 
referred to as the conductor shield. The insulation 
layer immediately surrounds and is fully bonded 
with the conductor shield. An insulation shield 
encases the insulation and, in some cases, may be 
composed of the same semi-conductive material 
as the conductor shield. The copper neutral wires 
or tape are wound around the insulation shield 
and are usually covered with a thermoplastic 
polyethylene jacket for mechanical protection 
from the external environment and to reduce 
moisture intrusion into the cable, all of which can 
cause premature cable failure.
PHOTO: © HTTPS://WWW.SHUTTERSTOCK.COM/G/SB7
Figure 1: Medium-Voltage Cable Layers
78 • WINTER 2022 ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
Conductor Strand Types
Various conductor strand types are commonly 
used in cable construction. The various types 
provide advantages in certain applications by 
either reducing the diameter of the cable or by 
lowering total AC resistance for a given cross-
sectional area of conducting material. 
• Concentric strand. A concentric 
stranded conductor (Figure 2) consists of 
a central wire or core surrounded by one 
or more layers of helically laid wires. Each 
layer after the first has six more wires than 
the preceding layer. In compact stranding, 
each layer is usually applied in a direction 
opposite to that of the layer under it.
Figure 2: Concentric Strand
• Sector conductor. A sector conductor 
(Figure 3) is a stranded conductor with a 
cross-section in approximately the shape of 
a sector of a circle. A multiple-conductor 
insulated cable with sector conductors has 
a smaller diameter than the corresponding 
cable with round conductors.
Figure 3: Sector Conductor
• Segmental conductor. A segmental 
conductor (Figure 4) is a round, 
stranded conductor composed of three 
or four sectors slightly insulated from 
one another. This construction has the 
advantage of lower AC resistance due to 
increased surface area and skin effect.
Figure 4: Segmental Conductor
• Compact strand. A compact stranded 
conductor (Figure 5) is a round or sector 
conductor having all layers stranded 
in the same direction and rolled to a 
predetermined ideal shape. The finished 
conductor is smooth on the surface and 
contains practically no interstices or air 
spaces. This results in a smaller diameter.
Figure 5: Compact Strand
Conductor Shield
The cable conductors are covered with an 
extruded polymeric stress-control layer made 
of semi-conductive compounds, often referred 
to as the conductor shield (Figure 6). The 
conductor shield isolates the cable insulation 
from any air surrounding the conductor 
strands. This is very important since air gaps 
will lead to ionization and partial discharge 
activity that will prematurely fail the insulation.
Insulation Materials
Comparing the dielectric losses of various 
insulation types (Table 1), we can see 
that polyethylene (PE) and cross-linked 
polyethylene (XLPE) offer the lowest dielectric 
losses. Paper/oil (PILC) has low to medium 
dielectric losses and ethylene propylene rubber 
(EPR) offers the highest dielectric losses. This 
comparison of materials also shows that PE and 
XLPE have sensitivity to water contamination 
NETAWorld • 79ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
(treeing) while EPR offers relatively low 
sensitivity to water contamination. 
An understanding of the insulation material 
plays a key factor in the testing of cable and 
analysis of test results. When testing hybrid or 
mixed circuits, insulation with higher dielectric 
loss may mask the true condition of the cable 
section with lower dielectric losses.
Insulation Shield
The insulation shield encases the insulation 
and, in some cases, may be composed of 
the same semi-conductive material as the 
conductor shield (Figure 7). It serves a similar 
purpose as the conductor shield and shields the 
insulation from air that might cause ionization 
and partial discharge activity.
The purposes of the insulation shield are to:
• Obtain symmetrical radial stress 
distribution within the insulation.
• Eliminate tangential and longitudinal 
stresses on the surface of the insulation.
• Exclude from the dielectric field those 
materials such as braids, tapes, and fillers 
that are not intended as insulation.
• Protect the cables from induced or direct 
over-voltages. Shields do this by making 
the surge impedance uniform along the 
length of the cable and by helping to 
attenuate surge potentials.
Cable Shielding
Medium- and high-voltage power cables 
in circuits over 2,000  volts usually have a 
shield layer of copper or aluminum tape or 
conducting polymer. If an unshielded insulated 
cable is in contact with earth or a grounded 
object, the electrostatic field around the 
conductor will be concentrated at the contact 
point, resulting in corona discharge and 
eventual destruction of the insulation. Leakage 
Table 1: Insulation Materials Insulation Shield
Material Advantages Disadvantages
Polyethylene (PE) • Lowest dielectric losses
• High initial dielectric strength
• Highly sensitive to water treeing
• Material breaks down at high temperatures
Cross-linked 
Polyethylene (XLPE)
• Low dielectric losses
• Improved material properties at high temperatures
• Does not melt but thermal expansion occurs
• Medium sensitivity to water treeing (although some 
XLPE polymers are water tree resistant)
Ethylene Propylene 
Rubber 
(EPR)
• Increased flexibility
• Reduced thermal expansion (relative to XLPE)
• Low sensitivity to water treeing
• Medium–high dielectric losses
• Requires inorganic filler/additive
Paper / Oil
(PILC)
• Low to medium dielectric losses
• Not harmed by high potential DC testing
• Known history of reliability
• High weight
• High cost
• Requires hydraulic pressure/pumps for insulating 
fluid
• Difficult to repair
• Degrades with moisture
Figure 6: Conductor Shield
Figure 7: Insulation Shield
80 • WINTER 2022 ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
current and capacitive current through the 
insulation present a danger of electrical shock. 
The grounded shield equalizes electrical stress 
around the conductor and diverts any leakage 
current to ground. Stress-relief cones should be 
applied at the shield ends, especially for cables 
operating at moreor may not be fully reported and over which NETA has neither exercised nor reserved control. 
Such data has not been independently tested or otherwise verified by NETA.
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NETAWorld • 7
As so many parts of the world face challenges due to extreme weather and 
geological events, I want to take a moment to recognize electrical workers and 
their families. As we all have learned, the electrical infrastructure is quite 
possibly the most essential part of our life these days. We tend to forget that we 
can’t accomplish many of the things we are accustomed to doing — or even the 
basic activities of life — without safe and reliable power. 
Our technicians, electricians, and engineers put themselves in potential harm’s way every day 
to restore essential services. Adhering to various state, agency, and government regulations 
while maintaining safe work practices has and continues to be a challenge, and I commend 
the perseverance and dedication of all of those involved. It is truly a testament to how 
diligent and generous the people in our critical industry really are.
In this issue of NETA World, we take a look at some of the specific requirements for safely 
and effectively commissioning, testing, and maintaining cables, especially at a time when 
testing methods are under constant pressure to keep up with technology. 
PowerTest 2023 will be at the Rosen Shingle Creek in Orlando, Florida, on 
March 8–12, 2023. You can still take advantage of early bird pricing, so don’t delay.
Plan ahead and always put safety first. 
 
Eric Beckman, PE, President 
InterNational Electrical Testing Association 
PRESIDENT’S DESK
PRESIDENT’S DESK
RECOGNIZING YOUR DEDICATION
8 • WINTER 2022 WYATT HAMRICK: CURIOSITY AND COMMITMENT 
INSIGHTS & INSPIRATION
Thirty-one years into his career, Potomac Testing 
Project Manager Wyatt Hamrick says he is humbled 
by the lessons he has learned, but also proud of the 
many achievements and fond memories his career 
has provided.
With 10 years of service in the U.S. Army and 21 
years of electrical testing experience under his belt, 
Hamrick says his own deep curiosity — which led his younger self to 
disassemble countless gifts to learn more about electricity — was the 
beginning of his approach to his work as a NETA Level 4 Technician. 
From there, his mentors, his efforts to gain as much knowledge as possible, 
and a very positive employment experience at Potomac Testing eventually 
led to a transition to his current position as a project manager and a love 
for his profession. Hamrick also holds a BS in management of technology 
from Athens State University and is a Master Electrician. 
Here, Hamrick describes his journey and shares 
his focus on how we must continuously adapt 
our safety practices for fast-paced multiphase 
projects.
NWJ: What attracted you to electrical 
testing?
Hamrick: For as long as my memory 
serves, I have always had a deep curiosity 
and amazement about electricity. If you 
were anything like me as a child, you should 
immediately call to thank and/or apologize to 
all those who nurtured your inquisitive nature. 
All through my early years, I disassembled 
countless birthday and Christmas gifts in an 
effort to learn more about electricity. I realize 
now that those early days of destruction 
ultimately led to building the foundation for 
my career in electrical testing. For me, electrical 
testing provides a dynamic space to understand 
and test many of the truths and mysteries of 
electricity. 
NWJ: How long have you been in the field, 
and how did you get started? 
Hamrick: I have been in the field for as long 
as I can remember, starting as an electrician’s 
helper for my dad. This early insight into 
WYATT HAMRICK:
CURIOSITY AND 
COMMITMENT 
WYATT HAMRICK
NETAWorld • 9WYATT HAMRICK: CURIOSITY AND COMMITMENT 
INSIGHTS & INSPIRATION
the trade encouraged me to pursue various 
courses in electricity and electronics during 
high school, then trade schools and colleges, 
followed by extensive military training. To date, 
my professional career totals approximately 
31 years. My first 10 years was spent with the 
U.S. Army as a HAWK Missile System Radar 
Technician, then as a Prime Power Technician. 
I am fortunate that my last 21 years have been 
spent with my current employer, Potomac 
Testing. 
NWJ: How did you get to your current 
position? 
Hamrick: Clearly, I must have lingered too 
long near the management side of too many 
projects. Project management was definitely 
a long-term consideration and a goal I set 
along with Potomac Testing leadership before 
transitioning to the office, but my formative 
years helped create a strong belief in me that my 
place was in the field. This belief allowed me to 
focus my efforts on gaining as much knowledge 
as possible, similar to those experienced senior 
technicians who blazed the trail before me. 
Although I tried like hell, I was never able to 
surpass my greatest mentors because as I grew, 
they did, as well. Somewhere along the way, 
my growth and development narrowed the gap 
between my roles as a field technician and project 
manager and eventually led to a natural transition 
to my current position as a project manager. 
NWJ: Who has influenced or mentored you 
along the way? 
Hamrick: This is a very abbreviated list! 
Most importantly, my parents, for seeing 
and supporting my pursuits and interests. 
Next, several military instructors, but one 
in particular comes to mind as an important 
influencer. While I have long since forgotten 
his name, this instructor’s motivational words 
continue to impact my life, and remain with 
me to this day:
“This is your job. 
Know your job. 
No one should ever have to do your job for you.” 
That may seem simple, but it has stuck with 
me for almost three decades. The list of NETA 
technicians who have mentored and influenced 
me is too long to list here, but I want to give 
a special shout out to Bryan Hunter, Craig 
Biggs, and Steve Meader. Thank you! I am 
also extremely grateful that Ken Bassett took 
a chance on me and created an environment 
that to this day provides positive, never-ending 
challenges and puzzles to solve.
10 • WINTER 2022 WYATT HAMRICK: CURIOSITY AND COMMITMENT 
INSIGHTS & INSPIRATION
NWJ: What about this work keeps you 
committed to the profession?
Hamrick: I have a healthy fascination 
with all the ways electricity can be used 
and misused. Most of all, and I’m speakingthan 2 kV to earth.
Several different types of shields are commonly 
used for medium-voltage cable applications. 
These shielding styles include:
• Tape-shielded (also called ribbon-
shielded). Tape shields (Figure 8) 
over ethylene propylene rubber (EPR) 
insulation have been a favored power cable 
construction for years. The way the tape is 
wrapped can deliver significant reliability 
and performance benefits. The overlap of 
the tape windings is a key design feature 
in helical-tape construction. The Insulated 
Cable Engineers Association (ICEA) 
recommends a minimum tape overlap 
of 10%. However, extra overlap delivers 
increased short-circuit capacity and better 
mechanical reliability. 
Figure 8: Tape-Shielded Cable
 Caution should be taken during 
installation of this style cable. If a tape-
shielded cable is bent too sharply or pulled 
around bends with too much tension, the 
tape windings may separate, and the tape 
can buckle when the cable straightens out. 
The buckling can damage the underlying 
insulation shield. In a conduit, the damage 
is invisible, and even in a cable tray, the 
cable jacket may conceal the condition. 
What’s worse, most electrical proof tests 
performed in the field will not reveal this 
kind of damage. 
• Wire-shielded (also called concentric 
neutral). This cable offers the same 
construction as tape-shielded cable 
except for the different metallic shield 
layer (Figure 9). It is often considered 
interchangeable with tape-shielded cable 
and is very common in utility applications. 
When concentric neutral cables are 
specified, the concentric neutrals must 
be manufactured in accordance with the 
Insulated Cable Engineers Association 
(ICEA) standards. These wires must meet 
ASTM B3 for uncoated wires or ASTM 
B33 for coated wires.
 These wires are applied directly over the 
nonmetallic insulation shield with a layer 
of not less than six or more than ten times 
the diameter of the concentric wires.
Figure 9: Wire-Shielded Cable
• UniShield® (a registered trademark of 
BICC Cables). Note the “Uni” in the 
name, which refers to the outer three 
layers being combined into a single layer: 
insulation shield, which also functions 
as a jacket, with metallic drain wires 
imbedded into the jacket to form a single 
functional layer (Figure 10). 
Figure 10: UniShield Cable
• PILC, paper-insulated, lead-
covered cable. The paper insulation is 
impregnated with oil which must be kept 
contained within the cable by use of a 
lead jacket (Figure 11). 
Figure 11: Paper-Insulated Lead-
Covered Cable
NETAWorld • 81ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
CABLE AGING
A power cable fails when local electrical stresses 
are greater than the local dielectric strength 
of the dielectric material(s). Reliability and 
the rate of failure of the whole cabling system 
depend on the difference between the local 
stress at any given point in the system and 
the local strength at that point. Failure of 
the dielectric results in an electrical puncture 
or flashover at the location of the degraded 
dielectric. This flashover can occur between 
two dielectric surfaces, such as cable insulation 
and joint insulation, or it can occur as an 
external flashover at the cable terminations. A 
cable failure can occur because of the normally 
applied 50/60 Hz voltage or during a transient 
voltage such as lightning or switching surges.
As time progresses and the cable system ages, 
the bulk dielectric strength degrades. The main 
aging factor of extruded dielectric cable is 
electrical, although under abnormal situations, 
thermal aging can be significant. The electrical 
aging mechanisms — partial discharge, 
electrical treeing, water treeing, and charge 
injection — occur at contaminants, defects, 
protrusions, and voids and thus tend to be 
localized.
Looking at specific mechanisms, excessive 
electrical stress or bulk deterioration of the 
insulation can occur because of:
Manufacturing Imperfections
• Voids
• Contaminants in insulations
• Poor application of shield material
• Protrusions on the shields
• Poor application of jackets
Poor Workmanship
• Cuts
• Contamination
• Missing applied components or 
connections
• Misalignment of accessories
Aggressive Environment
• Chemical attack
• Transformer oil leaks
• Floods
• Petrochemical spills
• Neutral corrosion
Wet Environment
• Bowtie trees
• Vented water trees
• High rates of corrosion
• Can reduce dielectric properties
Overheating
• Excessive conductor current for a given 
environment and operating condition 
(global) 
• Proximity to other cable circuits for short 
distances (local)
Mechanical
• Damage during transportation, typically 
localized
• Excessive pulling tensions or sidewall 
bearing pressures, either localized or 
global
• Damage from dig-ins, typically localized
Water Ingress
• Normal migration through polymeric 
materials
• Breaks in seals or metallic sheaths
Water Trees
Water trees, sometimes called electrochemical 
trees, have basic characteristics different than 
electrical trees. Electrical trees are characterized 
by the occurrence of partial discharge and 
require high electric stress to initiate, then 
rapidly lead to catastrophic dielectric failure. 
Water trees can be initiated at much lower 
dielectric stress and grow very slowly. These 
trees are associated with no measurable partial 
discharge and can completely bridge the 
insulation from conductor to shield without 
dielectric breakdown. Although breakdown 
does not occur, dielectric strength is greatly 
reduced. This is particularly true with regards 
to the direct current (DC) breakdown value.
Water tree degradation is a major problem for 
medium-voltage extruded dielectric cables, 
particularly service-aged XLPE cables. It is 
82 • WINTER 2022 ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
perhaps the worst degradation process of the 
polymeric insulation that contributes to the 
failure of the cable.
Water trees are formed and grow in the presence 
of moisture, impurities or contamination and 
the electric field over time. There are generally 
two types of water trees (Figure 12): bow-tie 
trees and vented trees.
Bow-tie trees are water trees that grow from the 
insulation outwards towards the surfaces of the 
insulation. These trees grow in the direction of 
the electric field in both directions, towards the 
two electrodes. Bow-tie trees have faster initial 
growth rate compared to vented trees. Bow-
tie trees are, however, not capable of growing 
to large sizes and usually do not grow to a 
size significant enough to cause failure of  the 
insulation.
Vented trees are water trees that grow from 
the surface of the polymer inwards into the 
insulation system. These trees will also grow in 
the direction of the electric field. Vented trees 
have a lower initial growth rate compared to 
bow-tie trees; however, vented trees can grow 
right through the entire insulation thickness.
Electrical Trees
The cumulative effect of partial discharges 
within solid dielectrics is the formation of 
numerous, branching partially conducting 
discharge channels, a process called electrical 
treeing (Figure 13). Repetitive discharge events 
cause irreversible mechanical and chemical 
deterioration of the insulating material. 
Damage is caused by the energy dissipated by 
high-energy electrons or ions, ultraviolet light 
from the discharges, ozone attacking the void 
walls, and cracking as the chemical breakdown 
processes liberate gases at high pressure.
The chemical transformation of the dielectric 
also tends to increase the electrical conductivity 
of the dielectric material surrounding the voids. 
This increases electrical stress in the unaffected 
gap region, accelerating the breakdown process.
CABLE TESTING OPTIONS
The Insulated Conductor Committee of the IEEE 
Power & Energy Society has divided testmethods 
or philosophies into two fundamental categories: 
Type 1 field tests and Type 2 field tests.
Type 1 tests are intended to detect defects in 
the insulation of the cable system to improve 
service reliability after the defective part is 
removed and appropriate repairs are performed. 
The following tests are usually achieved by 
applying moderately increased voltages across 
the insulation for a prescribed duration of time. 
Such tests are categorized as pass/fail.
• Insulation resistance (under voltage)
• DC high potential: IEEE Std. 400.1, 
Guide for Field Testing of Laminated 
Dielectric, Shielded Power Cable Systems 
rated 5 KV and Above with High Direct 
Current Voltage and IEEE Std. 400.5, 
IEEE Guide for Field Testing of DC 
Shielded Power Cable Systems Rated 5 kV 
Figure 12: Types of Water Trees
Figure 13: Electrical Tree
NETAWorld • 83ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
and Above with High Direct Current Test 
Voltages
• VLF high potential: IEEE Std. 400.2, 
Guide for Field Testing of Shielded Power 
Cable Systems Using Very Low Frequency
• High potential power frequency: typically 
considered a factory test and not a field test
Type 2 tests are intended to provide indications 
that the insulation system has deteriorated, 
hence, termed diagnostic tests:
• Dissipation factor (tan delta) testing: 
IEEE Std. 400.2, Guide for Field Testing 
of Shielded Power Cable Systems Using Very 
Low Frequency (VLF)
• Partial Discharge: IEEE Std. 400.3, 
Guide for Partial Discharge Testing of 
Shielded Power Cable Systems in a Field 
Environment
• Damped alternating current: IEEE Std. 
400.4, IEEE Guide for Field Testing of 
Shielded Power Cable Systems Rated 5 
kV and Above with Damped Alternating 
Current (DAC) Voltage
• Isothermal relaxation current test
• Return voltage
IEEE further categorizes cable testing into three 
areas: 
 1. Installation tests. Field tests conducted 
after cable installation is complete, but 
before splicing or terminating occurs. The 
test is intended to detect shipping, storage, 
or installation damage.
 2. Acceptance tests. Field tests made after 
cable system installation, splicing, and 
terminations are completed, but before 
the cable system is placed in normal 
service. The tests are intended to further 
detect installation damage and to show 
any gross defects or errors in installation of 
the various system components. 
 3. Maintenance tests. Field tests made 
during the operating life of a cable system. 
They are intended to detect deterioration 
of the system and to check the 
serviceability so that suitable maintenance 
procedures can be initiated.
UNDER VOLTAGE TESTING 
WITH DIRECT CURRENT 
Under voltage tests performed with direct 
current (DC) are typically performed with a 
test set referred to as a megohmmeter. Since 
these tests use voltages under the rating of 
the insulation being tested, the test is a non-
destructive test and does not produce any of 
the ill effects associated with high-voltage DC 
testing that we will discuss later in this article. 
The traditional insulation resistance test is the 
simplest way to gain an overall indication of 
the condition of the insulation. Although the 
insulation resistance (IR) test can be applied 
as a simple Type 1 or go/no-go test, it can 
also be used to give more extensive diagnostic 
information. Type 2 or diagnostic insulation 
tests electrically stimulate the insulation and 
measure the response of the insulation to that 
stimulus. Depending on that response, we can 
draw some conclusions about the condition or 
heath of the insulation.
The test current in the body of the cable 
insulation can be split into three components: 
• Capacitive current is initially large but 
goes to zero as the test piece is charged. 
• Polarization current is caused by charges 
in the insulation material moving under 
the effect of the electric field or by 
molecular di-poles lining themselves 
up with the applied field (orientation 
polarization). It is greatly affected by 
moisture or contamination in the 
insulation, as the water molecule has 
additional orientation polarization. This 
process takes much longer than capacitive 
charging. 
• Steady leakage current through the 
insulation, which is usually represented 
by a very-high resistor in parallel with the 
capacitance of the insulation. 
Spot Test
The spot reading test is the simplest of all 
insulation tests. Test voltage is applied for a 
short but specific period of time (typically 
1–2 minutes) as any capacitive charging 
84 • WINTER 2022 ACCEPTANCE AND MAINTENANCE TESTING FOR MEDIUM-VOLTAGE 
ELECTRICAL POWER CABLES — PART 1 OF 3
FEATURE
current will usually have decayed by this time. 
A reading is then taken. On longer cables 
offering increased capacitance, the time for the 
capacitive charging current may be significantly 
increased. The reading can then be compared 
to the minimum installation specifications. 
Spot readings can be performed as part of an 
inspection or as part of troubleshooting and 
can be used as a simple good/bad indicator. 
Spot test readings can also be trended against 
previously obtained values. However, insulation 
resistance is highly temperature dependent, 
and thus the results should be corrected to a 
standard temperature.
If the insulation resistance reading is high and 
the reading increases or remains steady during 
the test, the insulation is in good condition. As 
the capacitance current and absorption current 
decreases, insulation resistance increases. If the 
insulation resistance reading decreases during 
the test, the cable insulation is probably wet or 
otherwise in bad condition. If the final value 
of resistance is low (or the current is high), the 
cable insulation is in poor condition.
Time Resistance Test (Polarization 
Index/Dielectric Absorption)
A valuable property of insulation is that 
insulation charges during a test. The polar 
DC field applied by the megohmmeter causes 
realignment of the insulating material on the 
molecular level, as dipoles orient themselves 
with the field. This movement of charge 
constitutes a current. Its value as a diagnostic 
indicator is based on two opposing factors: 
The current dies away as the structure reaches 
its final orientation, while leakage promoted 
by deterioration passes a comparatively large, 
constant current. The net result is that leakage 
current is relatively small in good insulation, 
and resistance rises dramatically as charging 
goes to completion. This changing resistance 
provides diagnostic information related to 
the degree of degradation of the insulation 
(Figure 14). Deteriorated insulation will pass 
relatively large amounts of leakage current at 
a constant rate for the applied voltage. This 
will flood out the charging effect and will 
show little-to-no change in resistance value. 
Time-resistance test methods take advantage 
of this charging effect. Graphing the resistance 
reading at time intervals from initiation of 
the test yields a smooth rising curve for good 
insulation, but a flat graph for deteriorated 
insulation. The ultimate simplification of this 
technique is represented by the polarization 
index (PI) and dielectric absorption (DA) 
tests, which requires only two readings and a 
simple division. When performing the PI test, 
the one-minute reading is divided into the ten-
minute reading to provide a ratio. In DA, the 
time values are typically 30 seconds and 60 
seconds. Obviously, a low ratio indicates little 
change, hence poor insulation, while a high 
ratio indicates the opposite. 
Discharge-Based Insulation Tests
A range of techniques that look at the 
response of the insulation during its discharge 
have emerged. These tests all target the 
polarization behavior of the insulation 
because, as mentioned earlier in this article, 
this property is sensitive to moisture in 
the insulation. Since all three componentsof current are present during the charging 
phase of an insulation test, the determination 
of polarization or absorption current is 
hampered by the presence of the capacitive 
and leakage currents. The discharge phase of 
the test, however, can more rapidly remove 
Moisture and dirt
may be present
(B)
Insulation
probably
OK
(A)
M
eg
ao
hm
s
Time0 10 min.
Figure 14: Polarization Index Test
FEATURE
ACCEPTANCE AND MAINTENANCE TESTING 
FOR MEDIUM-VOLTAGE ELECTRICAL POWER 
CABLES — PART 1 OF 3
these effects, providing the possibility of 
interpreting the degree of polarization of the 
insulation and relating this to moisture and 
other polarization effects.
Isothermal Relaxation Current Test 
(IRC Test)
This test was developed for testing service-aged 
medium-voltage cables and grew as a response 
to problems associated with DC high potential 
testing of plastic cables. The early installed base 
of these cables from the 1960s and early 1980s 
is particularly problematic. 
The IRC test uses a 1 kV test voltage for 30 
minutes to polarize the dielectric. The polymer 
polarization traps charge at specific discrete 
energy levels, and during the discharge process, 
these energy levels give rise to different time 
constants in the discharge current. The major 
use of the effect in the IRC test is to look for 
the time constant associated with water trees 
in degraded cross-linked polyethylene (XLPE) 
cable material. The relaxation current occurring 
after the capacitance has been discharged is 
digitized for processing in PC-based software.
The software processing is based on a modelling 
technique that converts the current into charge 
and plots this charge against time. The total 
charge plot is then treated as a composite of 
standard shapes whose time constants are fitted 
to the composite curve by iteration. Cable 
aging is identified by the relative values of the 
time constants. The test was initially developed 
using artificially aged cable and has now been 
applied to operational XLPE cables.
SUMMARY
In Part 1 of our three-part series on acceptance 
and maintenance testing for medium-voltage 
electrical power cables, we reviewed cable 
construction and cable aging characteristics and 
started our discussion on cable testing options 
and philosophies. In Part 2 of this article, we 
will move away from under voltage testing and 
explore high potential testing techniques. 
Thomas Sandri is Director of Technical 
Services at Protec Equipment Resources, 
where his responsibilities include the design 
and development of learning courses. He 
has been active in the field of electrical 
power and telecommunications for over 35 years. During his 
career, Tom has developed numerous training aids and training 
courses, has been published in various industry guides, and has 
conducted seminars domestically and internationally. Thomas 
supports a wide range of electrical and telecommunication 
maintenance application disciplines. He has been directly 
involved with and supported test and measurement applications 
for over 25 years and is considered an authority in application 
disciplines including insulation system analysis, medium- and 
high-voltage cable, and partial discharge analysis, as well as 
battery and DC systems testing and maintenance. Tom received 
a BSEE from Thomas Edison University in Trenton, New 
Jersey.
ELECTRICAL TESTING
LEADING EDGE
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CONTACT US TODAY • 24 HOUR SERVICE
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86 • WINTER 2022 MICROGRIDS IN PRACTICE
BY MAYFIELD RENEWABLES
The majority of the U.S. electric grid was built in the early 20th century. 
It was initially designed for the one-way transfer of electricity from 
large fossil-fuel power plants directly to consumers. The grid of that era 
delivered power from rural areas, where power was generated, to cities, 
where much of it was consumed. 
Much has changed in the energy landscape, 
especially over the last 10–15 years, with the 
accelerated adoption of variable renewable 
energy sources (VREs) and distributed energy 
resources (DERs) such as rooftop solar and 
electric vehicles. These newfound energy flows 
are much more complex than the existing grid 
was designed to handle, and redesigning our 
electric infrastructure will require significant 
innovation and investment.
As we shift toward rapid, widespread expansion 
of VREs, the grid is evolving to become more 
responsive. Integrated advanced control systems 
and other digital technologies work with 
existing equipment to respond more quickly 
and accurately to electricity supply and demand 
changes. But the scale of these solutions has not 
met the scale of the problem — yet. 
Alternatively, some of the world’s electrical 
systems are pivoting to decentralize, 
decarbonize, and democratize driven by 
the need to lower electricity costs, improve 
resiliency and reliability, reduce CO2 emissions, 
and expand access to electricity. Microgrids, in 
particular, have emerged as flexible, scalable 
solutions that can integrate and manage the 
many distributed VREs required to meet many 
of the world’s climate goals. 
MICROGRIDS 
IN PRACTICE
INDUSTRY TOPICS
NETAWorld • 87MICROGRIDS IN PRACTICE
WHAT IS A MICROGRID?
The term “microgrid” is not well understood. 
If you ask five people to describe a microgrid, 
you will likely get five different answers. For 
our purposes, we will use the Department of 
Energy’s definition:
A group of interconnected loads and distributed 
energy resources within clearly defined electrical 
boundaries that acts as a single controllable entity 
with respect to the grid. A microgrid can connect 
and disconnect from the grid to enable it to 
operate in grid-connected and island mode.
This definition specifies three distinct 
differences from a standard macrogrid: 
 1. An easily identifiable boundary from the 
rest of the grid
 2. Resources within the microgrid 
controlled together
 3. Microgrid function whether connected to 
the larger grid or not
HOW IS A 
MICROGRID BUILT?             
A microgrid can be broken down into three key 
components: generation, load (demand), and 
storage, all within the same controlled network 
(Figure 1). 
The microgrid must have at least one generation 
source to meet onsite electrical demand. 
Historically, fast-starting, robust diesel generators 
have been the dominant power generation sources 
INDUSTRY TOPICS
Figure 1: Microgrid Components
SO
UR
CE
: M
AY
FI
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ES
88 • WINTER 2022
for most microgrids. But with the falling cost of 
solar PV and energy storage, many microgrid 
developers are either skipping the diesel generator 
entirely or reducing its fuel burn by installing 
a solar-plus-storage system. An energy storage 
system (ESS), like a fossil-fuel generator, can 
respond quickly to changes in demand. Unlike a 
generator, the ESS does not need to burn costly, 
dirty fuel while idling around the clock.
Beyond generation and storage components, 
sophisticated control systems act as the brains 
of a microgrid. A typical control system includes 
many distributed controllers and sensors 
and a central supervisory control and data 
acquisition (SCADA) system to collect data 
and distribute instructions. The software behind 
the controls can balance the load by increasing 
generation or decreasing demand elsewhereon 
the microgrid, maximizing renewable energy 
usage and minimizing other electricity costs. 
Microgrids also contain many of the same 
critical components required for the standard 
grid, such as transformers, inverters, switchgear, 
and protective devices, but scaled down to the 
appropriate size for the system.
WHAT ARE SOME 
MICROGRID APPLICATIONS?
Microgrid development is a force multiplier for 
grid reliability, resiliency, security, and control. 
As more microgrids go online, the existing grid 
gets broken into smaller components that can 
be added together or isolated on demand.
The existing grid connects homes, businesses, 
and other buildings to central power sources. 
This interconnectedness has one major 
downside: Everyone is affected when part of 
the grid goes down. A microgrid generally 
operates while connected to the grid, but 
more importantly, it can also decouple itself 
and operate on its own using local energy 
generation in times of crisis like storms, power 
outages, or even peak-rate periods. This ability 
to become an energy island is useful for many 
applications, including:
• Emergency backup. Microgrids can 
become electrically isolated from the rest 
of the grid in the event of an outage while 
continuing to produce and use electricity 
onsite.
• Energy independence. A microgrid can 
connect to a local resource that is too 
small or unreliable for traditional grid 
use, allowing communities to be more 
energy independent and, in some cases, 
more environmentally friendly.
• Extended islanding. A microgrid can 
be powered by distributed generators, 
batteries, or renewable generation 
resources like solar modules. Depending 
on how it’s fueled and how the connected 
load controls are managed, a microgrid 
may be able to run on its own for weeks 
at a time or even indefinitely. The system 
can be designed with any specific period 
of autonomy. 
As microgrid deployment becomes more 
common, understanding what they are, how 
they are built, and how they can be used will 
become increasingly important. 
BENEFITS OF MICROGRIDS
In addition to being flexible and scalable, 
microgrids provide additional benefits.
Ease of Connection for Efficient, 
Low-Cost, Clean Energy
The microgrid manager (e.g., local energy 
management system) can balance generation from 
non-controllable renewable power sources, such 
as solar, with distributed controllable generation, 
such as natural-gas-fueled combustion turbines. 
They can also use stationary energy storage 
and the batteries in electric vehicles to balance 
production and usage within the microgrid.
Improved Operational Efficiency 
and Stability of Regional Grid
When sited strategically within the electricity 
system, microgrids help reduce or manage 
electricity demand and alleviate grid congestion, 
thereby lowering electricity prices and reducing 
peak power requirements. In this manner, 
microgrids may support system reliability, 
improve system efficiency, and help delay or 
avoid investment in new electric capacity.
MICROGRIDS IN PRACTICE
INDUSTRY TOPICS
https://www.mayfield.energy/blog/why-designing-a-resilient-solar-plus-system-requires-a-resilient-team
https://www.mayfield.energy/blog/why-designing-a-resilient-solar-plus-system-requires-a-resilient-team
https://www.mayfield.energy/blog/why-designing-a-resilient-solar-plus-system-requires-a-resilient-team
NETAWorld • 89
Provide Ancillary Grid Services: 
Energy Storage or Spare Capacity
A microgrid in grid-connected operation can 
provide frequency control support, voltage control 
support, congestion management, reduced grid 
losses, and improved power quality. Usually, some 
kind of energy storage system is used to provide 
these services to the regional grid, but the microgrid 
can be used as either a load or a generator, if 
needed, and in some places can actually be 
financially compensated for ancillary services.
CHALLENGES FACING 
MICROGRIDS
The evolution of microgrid technology presents 
new challenges.
Lack of Geographical Diversity, 
Inertia to Compensate for 
Variability in Generation
Microgrids lack geographical diversity, so relative 
variability, like increased demand or reduced 
generation from weather, will have a much 
larger impact on the system’s performance. 
Most microgrid generating sources also lack the 
inertia used by large synchronous generators 
on the macrogrid for frequency and demand 
response. Energy storage in the microgrid can 
help alleviate the effects of variability, but this is 
also part of the reason for staying connected to 
the larger regional grid.
Increased Equipment Costs, 
Energy Losses
Extra protective devices can add up to as much 
as 50% of the total microgrid cost, depending 
heavily on local regulations and the microgrid 
design. Microgrids give up the economy of 
scale that is so advantageous to the macrogrid. 
Additionally, DC-AC conversion can waste more 
than 15% of total energy produced, depending 
on the number of inverters in the design. Some of 
this energy loss is compensated for by the lack of 
transmission distance required, but should still be 
taken into consideration in any microgrid.
Remaining Legal and Regulatory 
Questions
Microgrids face three types of legal hurdles: 
 1. Laws that prohibit or limit specific activities
MICROGRIDS IN PRACTICE
INDUSTRY TOPICS
 2. Laws that increase the cost of doing 
business
 3. Uncertainty, including the risk that new 
laws will be implemented to regulate 
microgrids and impose restrictions or 
costs not anticipated at the time of 
development or construction
Finally, a number of regulatory questions 
remain before the widespread adoption of 
microgrids is even possible:
• Should microgrids count as “utilities” and 
be subject to state/federal regulation?
• Will microgrids be subject to consumer 
protection laws like utilities?
• If not a utility, what are the laws for 
buying/selling excess electricity and other 
ancillary services?
• Who determines minimum, maximum, 
and appropriate size for microgrids?
• Who is responsible for operating and 
maintaining a microgrid?
REAL-WORLD EXAMPLES
The benefits often greatly outweigh any 
potential risks involved with the microgrid, 
so what are some real-world examples where 
microgrids have proven to be beneficial? 
• During wildfire season, many of the 
power outages in California are planned 
outages. A microgrid is a solution to many 
homeowners’ power problems by enabling 
them to produce and store their own power 
via solar panels and batteries and disconnect 
from the main grid, staying totally self-
sufficient until the main grid is back online. 
• When Hurricane Maria tore through 
Puerto Rico in 2017 causing the longest 
power outage in U.S. history, microgrids 
would have been much easier to restore, 
especially to hospitals and emergency 
responders. In fact, one of the major 
benefits of a microgrid is that it can extend 
beyond a single house or building and 
create a tiny electricity-isolated island 
within a community. A perfect example of 
this would be a microgrid between a fire 
90 • WINTER 2022
department, a school, and a senior center 
for emergencies, or even between multiple 
resorts on an island community.
• The University of California San Diego 
(UCSD) microgrid now powers a campus 
that covers 1,200 acres and serves a 
community of about 45,000 faculty 
and students living and working in 450 
buildings. Two high-efficiency 13  MW 
natural gas turbines, a 3 MW network of 
solar resources, a 2.8 MW fuel cell, and a 
2.5 MW advanced energy storage system 
allow the university to generate about 85% 
of its own energy at about half the price 
utility power would cost. The microgrid 
earns money for USCD by helping the 
utility meet peak demand by reducing 
campus loads upon request. They also 
generate a high excess of electricity from 
the PV array, so that local energy costs go 
negative to around minus 2¢/kWh during 
midday.
• A heat wave and storms led to poweroutages that affected hundreds of 
thousands of New York and New Jersey 
electricity customers during June 2019. 
Through it all, Home Depot stores in the 
New York area remained open thanks to 
microgrids that provided all of the critical 
power needs for each store during their 
MICROGRIDS IN PRACTICE
outages and eliminated the need for any 
back-up generators. With a combination 
of solar PV, fuel cells, and other energy 
storage on their microgrids, Home Depot 
has been able to meet sustainability 
initiatives in New York and elsewhere. This 
supports the retailer’s goal to ensure that 
stores remain available to the communities 
they serve in the event of a natural disaster 
or grid power failure.  
There are pros and cons for microgrids, but 
a microgrid can be a great solution for many 
applications. The next section discusses the 
stages of a microgrid design, how to make it a 
successful project, and some of the challenges 
of developing a microgrid.  
MICROGRID MODELING 
SOFTWARE 
Many variables affect the overall results of the 
microgrid, including site-specific weather and 
infrastructure data that will determine the total 
output potential. From that data, estimated 
total output, along with local utility rates and 
available incentives, can be used to help calculate 
the economic benefits. Finally, economic 
feasibility, along with any other standards for 
the microgrid’s performance (load response, 
resiliency, energy arbitrage, etc.) can be used to 
calculate a more comprehensive picture of the 
microgrid’s potential benefits (Figure 2).
INDUSTRY TOPICS
Figure 2: Steps to Modeling Renewable Energy
Weather Data
Costs
System Specs
Compensation
Results
Annual, Monthly, and Hourly Output, 
Capacity Factor, LCOE, NPV, Payback, Revenue
System Losses
Financing
Electricity 
Production
Incentives
+
+
+
+ +
=
=
https://www.mayfield.energy/blog/microgrids-part-3-microgrid-modeling-software
https://www.mayfield.energy/blog/microgrids-part-3-microgrid-modeling-software
NETAWorld • 91MICROGRIDS IN PRACTICE
A number of microgrid modeling software 
packages to simulate the success of a microgrid 
in a given location are available. They range 
from free online academic tools to paid 
downloads, and they offer a variety of different 
features. 
KEY SOFTWARE FEATURES
Obviously, there are many options out there 
for microgrid modeling. So how can you 
differentiate these software solutions and find 
the best one for your business? Several key 
features can be used to distinguish them from 
each other based on the needs of your business 
and your clients.
• Price. Price will always be something 
to keep in mind for your business, but 
it shouldn’t be the first or only thing 
you consider. While paid licenses like 
INDUSTRY TOPICS
Features
SAM Reopt DER_VET HOMER XENDEE
Resiliency Studies
Peak-Shaving/Load-Response
Reliability/Coverage Probability
Energy Arbitrage Modeling
P50/P90 Analysis
Easy, Complete Reporting
Site-Specific Weather Data
System Optimization
Web-Based Software
Free/Open-Source
Utility Rates/Incentive Included
Traditional Generation (diesel, gas, coal, etc.)
Available Financial Models
SAM Reopt DER_VET HOMER XENDEE
Residential & Commercial (behind-the-meter)
Residential & Commercial (front-of-meter)
Power Purchase Agreements (PPAs)
Available Renewable Resources
SAM Reopt DER_VET HOMER XENDEE
Solar PV
Battery Storage
Thermal Storage
Wind
Hydropower
Solar Water Heating
Fuel Cells
Geothermal Power
EV Charging
Table 1: Microgrid Modeling Software Comparison
92 • WINTER 2022 MICROGRIDS IN PRACTICE
HOMER or XENDEE definitely have 
more advanced user interfaces, others still 
yield the same quality of results for free, 
but may be less intuitive to use or contain 
fewer reporting features. Cost will vary 
greatly depending on the number of users 
in your organization, and a single license 
for your resident microgrid expert could 
more than pay for itself.
• Modeling capabilities. There are a 
number of different performance measures 
and reports that can be used to define the 
feasibility of a microgrid, so you will need 
to ensure your software can handle the 
analyses your clients are most interested in. 
Some of the available reports in microgrid 
software include system resiliency studies, 
energy arbitrage modeling, peak-shaving 
or load-response analyses, probability 
of exceedance analysis (P50/P90), and 
reliability/coverage probability reports. 
The reports generated by some programs 
are good enough to send straight to the 
client, but others will require you to take 
some tables and figures and create your 
own customer-facing report. 
• Utility tariffs/complex rate analysis. 
Presumably, the most important part of 
any microgrid modeling for your clients 
will be the economic analysis, including 
total system cost and potential savings after 
construction. In most modeling software 
packages, you can at least manually enter 
utility tariffs/rates and incentives, but this 
information isn’t always readily available. 
The paid programs typically include this 
information in the software, making 
it much easier to accurately model the 
financial side of the microgrid, beyond just 
upfront system costs, especially for those 
with less experience with utility rules and 
regulations.
• Ease of use. Finally, ease of use could 
be the biggest priority to your business, 
especially if your team has limited 
experience or expertise with microgrids. 
Some programs focus more on the 
technical side, some more on the user 
experience, but at the end of the day, 
your team members need to be able to 
use it accurately and efficiently. While all 
the programs above offer user manuals 
and video tutorials, paid software often 
offers training sessions or one-on-one 
consultations to help you get the most out 
of the software. 
Microgrids are definitely an up-and-coming 
technology, and some more advanced training 
in microgrid modeling and design could help 
prepare your team for the future of renewables.
CONCLUSION
As you can see, there are plenty of free and paid 
options for modeling microgrids. The user 
interfaces and features vary greatly between the 
various platforms, but for most businesses, it 
comes down to a combination of four factors: 
 1. Price
 2. Modeling capabilities
 3. Rates/tariffs/incentives
 4. Ease of use 
Beginning designers may find the paid software 
easier to get the hang of, but some of the less 
complicated microgrid designs and reports can 
be done just as effectively and efficiently with 
free software. Ultimately, all of these modeling 
software programs can elevate your business 
and help sell projects to current and future 
clients. It will be up to you to decide between 
price and performance. 
Mayfield Renewables is a team of solar + storage experts that 
offers many microgrid development services, including feasibility 
studies, component selection and sizing, and full permit set 
development. 
INDUSTRY TOPICS
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94 • WINTER 2022 PHOTOVOLTAIC POWER SYSTEMS AND GROUND-FAULT 
PROTECTION ON THE SERVICE ENTRANCE DISCONNECT 
INDUSTRY TOPICS
BY JOHN WILES, Retired
There are no one-size-fits-all solutions to the ground fault-protected main 
circuit breaker issue. Diligent attention to the requirements in the NEC 
— NFPA 70 and the equipment in the existing installation is required.
The 2020 National Electrical Code (NEC – 
NFPA 70) in Section 230.95 Ground-Fault 
Protection of Equipment requires ground-
fault protection of equipment for solidly 
grounded wye services of more than 150PHOTOVOLTAIC POWER 
SYSTEMS AND GROUND-FAULT
PROTECTION ON THE
SERVICE ENTRANCE 
DISCONNECT 
Photo 1: Large Panelboard in a Commercial Building Providing Several 
Potential Load-Side Connection Points 
volts but not exceeding 1,000 volts phase 
to phase. While this type of service is not 
common in residential/dwelling services, it is 
quite common in medium-size commercial 
electrical installations such as schools, big-box 
stores, and supermarkets. Load-side PV system 
connections (705.12) are attractive in these 
situations because the large panelboards/load 
centers offer a relatively easy method of making 
the connection (Photo 1). 
However, Section 705.32 must be addressed, 
and other factors should be investigated before 
the decision is made to make a load-side PV 
connection.
THE BASICS
A major consideration revolves around the 
common use of a main circuit breaker that 
is equipped with a GFP accessory. Circuit 
breakers are manufactured with numerous 
optional accessories, including (depending on 
manufacturer and model) shunt trips, auxiliary 
switches, remote indicators, power operation, 
adjustable trips, and ground-fault protection 
(GFP) trip mechanisms (Photo 2). 
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NETAWorld • 95PHOTOVOLTAIC POWER SYSTEMS AND GROUND-FAULT 
PROTECTION ON THE SERVICE ENTRANCE DISCONNECT 
INDUSTRY TOPICS
While UL Standard 489 requires tests to 
evaluate the backfeeding of the basic circuit 
breaker, most of the accessories are not 
evaluated for backfeeding. In fact, backfeeding 
may have no effect on many of these 
accessories, and specific testing for backfeeding 
may be unnecessary.
However, older and possibly some current 
ground-fault trip mechanisms may be damaged 
if the circuit breaker has voltages on both line 
and load terminals after the circuit breaker has 
been opened by a ground-fault trip. UL Safety 
Standard 489 for molded-case circuit breaker 
testing does not evaluate the GFP accessory 
on backfed GFP main circuit breakers in a 
manner that subjects the ground-fault device 
to the conditions it would experience in a 
utility-interactive PV system or possibly even 
in a parallel-connected generator installation 
where line and load terminals are both 
energized during and after a ground-fault 
trip. PV inverters responding to internal anti-
islanding software may have energized outputs 
up to two seconds after the AC utility power 
is removed from the inverter output. These 
PV inverter-energized load-side terminals on 
the main circuit breaker may cause the GFP 
trip mechanism to be destroyed if that trip 
mechanism is connected to and receives power 
from the main circuit breaker load-side output 
terminals. In normal operation with no PV, 
when a ground-fault event occurs, the opening 
COURTESY JOHN WILES
Photo 2: 1,200-Amp Circuit Breaker with 
Ground Fault Protection
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Typical School Carport
INDUSTRY TOPICS
circuit breaker immediately removes the power 
source for that GFP trip mechanism, and no 
damage will occur.
Circuit breaker manufacturers should be 
evaluating all accessories supplied with their 
circuit breakers for operation under all possible 
application configurations. However, utility-
interactive inverter installations are a relatively 
new application, and PV inverters are being 
applied to electrical installations that may be 
decades old.
Discussions with technical support personnel 
at circuit breaker manufacturers indicate that 
most new designs use a current transformer 
to power the GFP device and that the current 
transformer does not respond to any potential 
voltages on the load terminals of a tripped-
open main circuit breaker. The GFP device, 
powered by the current transformer, should 
not be damaged by backfeeding or by inverter 
supplied voltages on the output terminals of a 
tripped open main circuit breaker.
However, there is some confusion and 
uncertainty about older GFP/circuit breaker 
designs that have been installed widely and may 
still be found in older buildings.
LOOKING DEEPER
Load-Side Connections Where 
a GFP-Protected Main Circuit 
Breaker Is Involved
Section 705.32 requires a supply-side 
connection of a PV system where a Section 
230.95 ground-fault protected main service 
disconnect is involved, but the exception allows 
load-side PV connections with requirements 
for ground-fault protection of the loads from 
all ground-fault sources. 
If the circuit breaker manufacturer (design 
engineer) will sign a statement that the specific 
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NETAWorld • 97PHOTOVOLTAIC POWER SYSTEMS AND GROUND-FAULT 
PROTECTION ON THE SERVICE ENTRANCE DISCONNECT 
INDUSTRY TOPICS
main circuit breaker with GFP accessory 
by part number and model number will 
not be damaged under PV inverter backfed 
conditions (line and load terminals energized 
at the same time during and after the GFP 
device trips the circuit breaker), then it appears 
that backfeeding that circuit breaker may be 
acceptable and a load-side PV connection may 
be possible. Bulletins and information from 
sales departments are sometimes insufficient to 
make a safe determination.
After determining that the main circuit 
breaker/GFP is suitable, the issue of protecting 
the load circuits or feeders during ground-
fault conditions from all sources, utility, 
and PV must be addressed (705.32 EX). An 
engineering analysis would be required that 
shows how and where ground-fault currents 
are sourced. What impedances are involved in 
the utility source and the PV source, and how 
much current can each supply under varying 
types of ground faults? Ground faults are not 
always hard, low-resistance faults and may be 
arcing faults of varying impedances. Suppose 
the PV system provides enough ground-fault 
current to prevent the main circuit breaker 
GFP from tripping. How is the ground fault 
contained or interrupted?
Some manufacturers and installers are wary 
of connecting some sort of GFP device to the 
inverter output because this is a non-standard 
connection, and any ground faults detected 
might only be those originating between the 
device (usually a backfed circuit breaker) and 
the inverter, not ground faults occurring in load 
circuits. This would occur if a GFPE circuit 
breaker were to be used in an AC inverter 
combining panel since that circuit breaker would 
normally sense ground-fault currents only toward 
the inverter from the circuit breaker location.
Several manufacturers offer a main circuit 
breaker GFP that can take inputs from multiple 
ground-fault sources like a dual-utility feeder 
system. But these would be found in limited, 
special instances where there are multiple utility 
sources, and they may not be useable to meet 
NEC requirements in the PV applications.
Photo 3: PV System Mounted on School Carport
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98 • WINTER 2022 PHOTOVOLTAIC POWER SYSTEMS AND GROUND-FAULT 
PROTECTION ON THE SERVICE ENTRANCE DISCONNECT 
INDUSTRY TOPICS
old, discontinued main circuit breakers with 
GFP accessories was difficult, if not impossible. 
As previously mentioned, the large 1,000-amp-
plus panelboard/load centers in these schools 
presented an attractive location to make a 
load-side PV connection. However, exhaustive 
investigations on the numerous existing school 
electrical systems by two separate professional 
engineers experienced in the NEC requirements 
and installations of PV systems of this size on 
the large GFP protected services resulted in 
both utilities opting for supply-side connection 
of the PV system on every school. And in more 
than a few cases, a transformer was requiredto 
match the PV inverter output voltage to the 
higher service voltage.
Before connecting a PV system that will 
backfeed a GFP main service disconnect or 
circuit breaker, the following steps should be 
followed. There may be others.
 1. Accurately determine that any and all 
ground-fault protection devices installed 
where they may be exposed to backfeed 
currents are suitable for operation in a 
backfed manner with a utility-interactive 
PV inverter.
 2. Select an appropriate GFP device(s) 
that can be connected to the inverter(s) 
outputs to control ground-fault currents 
flowing in load circuits from those 
sources.
 3. Make an engineering assessment of the 
magnitudes of the potential and available 
fault currents from both utility and 
PV sources to the load circuits being 
protected. Circuit impedance calculations 
under fault-current levels for all sources 
and the load impedance should be made.
 4. Determine the proper setting for all 
adjustable-trip ground-fault protection 
devices that will ensure that the load 
circuits and feeders are protected from all 
ground-fault current sources.
 5. The installed system should be tested while 
the GFP circuit breaker is being back-
fed with a PV inverter by activating the 
internal ground-fault trip circuit test. That 
test should be conducted twice to ensure 
Other Considerations
The NEC requirements in 705.32 and 
705.12(B) might appear to restrict the PV 
to always be 20% or less of the main circuit 
breaker rating, and the main GFP circuit 
breaker will always trip on a ground fault, but 
what was the GFP trip setting? On a 1,200-
amp GFP circuit breaker, the GFP adjustable 
trip setting might be from about 200 amps to 
1,200  amps of fault current. For a load with 
multiple ground-fault current sources (at least 
one from the utility and one or more from 
current-limited utility-interactive PV inverters), 
what would the proper trip settings be for each 
ground-fault device?
Under the 2017 NEC and 2020 NEC, the 
120% allowance in 705.12(B)(2) may apply 
to the installation. But it may not. A relatively 
large PV system with a small main circuit 
breaker on a large busbar could meet either the 
120% or the 100% allowance.
The 2020 NEC still has the basic requirement 
for ground fault protection in 705.32. If a 
supply-side PV connection is elected, the new 
Section 705.11(E) will apply. This section has 
been interpreted as requiring ground-fault 
protection for PV circuits and PV equipment 
when they are connected to services rated at 
1,000  amps or more. This requirement would 
mean that a properly rated backfed circuit 
breaker with a ground-fault accessory be used 
as the PV system disconnect at the point of 
connection to the service conductors.
Historical Perspective
About 15 years ago, two PV-progressive electric 
utilities headquartered in Phoenix, Arizona, 
(Arizona Public Service and Salt River Project) 
decided to put medium-size PV systems 
(18–60  kW) on numerous schools in their 
respective service territories (see opening photo 
and Photo 3). 
These schools typically had services that met 
the NEC 230.95 requirements and were 
equipped with ground-fault protected main 
circuit breakers. Some were brand-new schools, 
while many were quite old. Getting data on 
INDUSTRY TOPICS
that the ground fault mechanism or device 
was not damaged during the first test.
Supply Side Connection
In many cases, it may be easier and safer to 
implement a supply-side (of the main GFP 
circuit breaker) PV connection as allowed 
by 705.12(A) (2017 NEC) or 705.11 (2020 
NEC).
SUMMARY
The requirements of the NEC are stringent 
but can be met. There are no one-size-fits-all 
solutions to the ground fault-protected main 
circuit breaker issue. Diligent attention to the 
requirements in the NEC and the equipment in 
the existing installation is required.
The NEC requirements continue to evolve as new 
subsystems and equipment bring increased safety 
to PV installations while reducing or eliminating 
the requirements of the recent past. 
John Wiles is retired from the Southwest 
Technology Development Institute at New 
Mexico State University, but as a temporary 
employee in his previous position, he devotes 
25 percent of his time to PV activities.
Reprinted with permission from IAEI 
News Magazine, July/August 2022. An online version is 
available at https://wp.me/pa0pa5-66o.
https://wp.me/pa0pa5-66o
100 • WINTER 2022 USING THE THREE Rs TO REDUCE THE ENVIRONMENTAL IMPACT OF SF6 GAS
INDUSTRY TOPICS
BY L INA ENCINIAS and COREY RATZA, DILO Company, Inc.
The ability of SF₆ to recombine after arcing events — combined with 
the fact that it is chemically inert, non-toxic in its pure state, non-
flammable, and very-high density — makes it an excellent di-electric gas, 
and sulfur hexafluoride has been used as an insulating medium in the 
electrical industry since the 1950s. 
SF6 GAS ENVIRONMENTAL 
IMPACT
SF₆ is a man-made gas that does not naturally 
occur in large quantities. In 1997, the Kyoto 
Protocol (Global Warming Treaty) listed 
SF₆ gas as one of the six greenhouse gases that 
should be controlled by reducing emissions or 
eliminating its use. The Global Warming 
Potential (GWP) of a gas measures the amount 
of energy the emissions of 1 ton of that gas 
will absorb relative to 1 ton of carbon dioxide 
(CO2). Gases with a higher GWP contribute 
more significantly to climate change.
SF₆ gas has been identified as the most potent 
greenhouse gas, surpassing others such as 
carbon dioxide and methane. Over the span of 
a 100-year period, SF₆  is 22,800  times more 
effective at trapping infrared radiation than an 
equivalent amount of CO₂. SF₆ gas is also very 
stable, and it accumulates in the atmosphere in 
an essentially undegraded state, thus having an 
atmospheric lifetime of 3,200 years. Therefore, 
even a small amount of SF₆  emitted into the 
atmosphere can have a significant impact on 
global climate change. 
Despite regulations and efforts to decrease 
SF₆  emissions, the amount of SF₆  in the 
atmosphere steadily  increased  worldwide 
since 1998. There are  several uses for sulfur 
hexafluoride, but it is most used as an 
insulating gas for electrical switchgear in 
the transmission and distribution of power 
industry. The industry is seeking alternatives 
to SF₆ due to its high GWP. However, federal 
regulations do not currently prohibit the 
purchase of new SF₆ switchgear, and most 
states do not have their own regulations 
restricting SF₆ gas.
USING THE THREE Rs 
TO REDUCE THE 
ENVIRONMENTAL 
IMPACT OF SF6 GAS
NETAWorld • 101USING THE THREE Rs TO REDUCE THE ENVIRONMENTAL IMPACT OF SF6 GAS
INDUSTRY TOPICS
The market for SF₆ gas is expected to grow to 
USD 309.8 million1 and the global installed 
base of SF₆ equipment is expected to grow 
by 75% by 20302 despite the availability of 
alternative solutions and data on how harmful 
SF₆ emissions are to the environment. The 
transmission and distribution industry is 
responsible for about 80% of SF₆ emissions, 
but utilizing the Three Rs of responsible SF₆ 
gas handling in addition to SF₆ reconditioning 
can help significantly reduce the industry’s 
environmental footprint. 
THREE Rs: RE-USE, 
RECOVER, RECYCLE
Ideally, SF₆ should be used in a closed-loop 
cycle and never be emitted into the atmosphere. 
Unfortunately, we know this is not always the 
case. The most common causes of emissions in 
the T&D industry are production of virgin SF₆ 
gas, faulty or leaking gas insulated equipment 
(GIE), and improper gas handling methods 
and human error. The Three Rs address these 
common emission causes and help to prevent 
SF₆ from entering the atmosphere. 
RE-USE (AND CHOOSE TO 
DITCH) VIRGIN SF6 GAS
The benefits of re-using SF₆ gas instead of 
purchasing virgin SF₆ gas include reduced 
environmental impact, cost savings, and 
increased reliability of product sourcing. Any 
contaminants that occur while SF₆ gas is in 
use due to the intrusion of air,moisture, or 
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102 • WINTER 2022 USING THE THREE Rs TO REDUCE THE ENVIRONMENTAL IMPACT OF SF6 GAS
INDUSTRY TOPICS
generation of arc byproducts can be removed 
with the proper filtration and separation 
process. SF₆ gas can be reconditioned to a like-
new state that meets or exceeds IEC standards 
even after being exposed to an arcing event, 
moisture, and/or other contaminants and is 
approved for use within the T&D industry.
Environmental Impact 
of Virgin Gas
The production of virgin SF₆ gas is a major 
source of emissions. The  International Panel 
on Climate Change’s 2019 Guidelines for 
National Greenhouse Gas Inventories estimates 
that 0.03 kg to 0.08 kg of SF₆ gas is emitted 
to the atmosphere per every 1 kg (2.2  lbs) of 
SF₆  gas produced.3 In fact, producing virgin 
SF₆  gas can create 12.5 or more times the 
emissions than reconditioning or recycling 
SF₆ gas for re-use.
One way to curb emissions while using 
SF₆  gas is to switch from purchasing virgin 
gas to using reconditioned gas. A large and 
growing stockpile of SF₆  gas is already in 
circulation in North America. From an 
environmental perspective, reconditioning 
gas helps us lower the carbon footprint by 
removing the need to produce more SF₆ gas. 
Additionally, utilizing SF₆ gas already in the 
United States helps reduce emissions created 
by the manufacturing and shipping of virgin 
gas from overseas. 
Increased Reliability and 
Decreased Cost
It is important to recognize that the major 
shareholders of manufacturing virgin SF₆ gas 
come from industrial gas production plants 
outside of North America. Virgin SF₆  gas 
production was ceased in the United States 
with the greenhouse gas emission reduction 
targets instituted by the Environmental 
Protection Agency. Therefore, any virgin 
SF₆  gas purchased in the United States is 
imported from Eastern Europe, Russia, or 
Asia where the gas is produced. Given current 
supply chain issues and increased demand, 
virgin SF₆ gas has never been more expensive 
or difficult to source. 
Reconditioned SF₆ gas can be sourced 
from vendors within the United States, 
decreasing shipping costs and delays. The 
SF₆  reconditioning practice ensures a 
readily available supply for the power and 
utility sectors and eliminates the need and 
environmental impact of importing virgin 
product from other continents. 
An additional advantage for sourcing 
reconditioned SF₆  is cost savings. Virgin gas 
typically costs double what reconditioned 
SF₆  gas costs. Technological advances in 
the filtration and separation process make 
it possible for reconditioned SF₆  to meet or 
exceed federal and international industry 
standards, all at a lower cost, and this cost 
savings does not compromise the quality of the 
gas.
From a technological view, there are no 
significant differences in the makeup of 
engineered virgin SF₆  and reconditioned 
SF₆  that has undergone a cryogenic process 
to remove by-products. Furthermore, 
reconditioned SF₆  gas can be purchased 
at significantly lower cost than virgin gas 
while simultaneously supporting American 
businesses. 
Table 1: Comparison of Emission Rates for Virgin, Reconditioned, and Recycled SF₆ Gas
Weight of SF6 Gas Type of SF6 Gas Emission Dependent on Process
45.36 kg (~100 lbs) Virgin SF6 Gas 3.6 kg (30lbs) to 36.3 kg (80 lbs)
45.36 kg (~100 lbs) Reconditioned (95% to =/>99.0% Purity) =/filter. 
• Particle filter. The particle filter traps any 
solid particles in the SF₆ gas as it passes 
through the filter. These particles may 
include solid decomposition material from 
SF₆ gas by-products that would damage the 
GIE and gas handling equipment. Particle 
filters have a 100% capture rate of particles 
≥1.0 µm. 
• Activated charcoal. The high surface area 
of activated charcoal along with high bulk 
density and particle size distribution allow 
it to remove organic compounds such as oil 
from SF₆ gas. The activated charcoal filter is 
not a standard part of a recovery system but 
can be used externally if gas analysis shows 
that oil is present as a contaminant. 
Most recovery systems include aluminum oxide, 
molecular sieve desiccant, and particle filters. Using 
a pre-filter provides extra filtration to protect the 
recovery system from any contaminants present 
in the gas and makes the recycling process more 
efficient by providing extra filtration. 
It may take multiple passes through the recovery 
system and pre-filter to recycle the gas to meet IEC 
standards for re-use. If you do not see a significant 
improvement in gas quality after filtration, your 
filters could be saturated and will likely need to 
be cleaned or replaced. Please note that cleaning 
may require PPE and special handling processes 
that require specific training or certifications (i.e., a 
respirator program). If the IEC standard for re-use 
cannot be met or exceeded, the SF₆ gas will have to 
be sent for reconditioning. 
Reconditioning SF6 Gas 
In some cases, SF₆  gas may need to be 
reconditioned to remove vapors prior to 
being re-introduced into the supply stream. 
Reconditioning is a process that occurs after 
the Three Rs are used to separate SF₆  gas 
from other vapors (N2, O2, CF4). The 
reconditioning process requires special 
equipment and handling procedures that 
ensure as close to zero emissions as possible. 
An SF₆ gas separator uses a three-stage cryogenic 
process to recondition SF₆ gas to a guaranteed 
99% purity and less than 99.5 ppmV moisture. 
In short, reconditioning is a cryogenic process 
that is combined with filtration and high 
pressure through an emission-free process. The 
end goal is to meet or exceed the standards set 
by CIGRE, IEEE, ASTME, and IEC. When the 
process is followed correctly, the standards can 
easily be exceeded and the gas can be returned to 
the market for re-use.
CONCLUSION
SF₆ gas is an extremely effective di-electric 
gas that contributes significantly to global 
INDUSTRY TOPICS
warming when emitted to the atmosphere due 
to its high GWP. Data shows that using SF₆ gas 
and switchgear will grow by 2030 despite the 
known environmental impact of SF₆ gas and the 
availability of alternatives. By utilizing the Three 
Rs (Re-use, Recovery, and Recycling) along with 
SF₆ reconditioning, the T&D industry can 
significantly reduce its environmental footprint 
while continuing to use the gas. 
REFERENCES
1. Grand View Research. Sulfur Hexafluoride 
Market Size, Share: Industry Report. 
Available at https://www.grandviewresearch.
com/industry-analysis/sulfur-hexafluoride-sf6-
market.
2. McGrath, Matt. “Climate Change: Electrical 
Industry’s ‘Dirty Secret’ Boosts Warming.” 
September 2019. Available at https://www.
bbc.com/news/science-environment-49567197.
3. IPCC. Refinement to the 2006 IPCC 
Guidelines for National Greenhouse Gas 
Inventories. May 2019. Available at https://
www.ipcc.ch/report/2019-refinement-to-the-
2006-ipcc-guidelines-for-national-greenhouse-
gas-inventories/.
Corey Ratza is the Sales Director for 
DILO Company, Inc. With over a decade 
of dedication to DILO Company Inc., 
Corey has experience with the professional 
development and management of the sales 
and marketing team, strategic sales and 
marketing campaigns, and cross-department 
collaboration.  Corey’s mechanical, technical, and marketing 
background supports his leadership and accountability of DILO’s 
brand stewardship. Corey serves as an integral advisor for new 
product and service development and works to garner and 
maximize new market segments and business growth. 
Lina Encinias is the Marketing and 
Training Manager for DILO Company, 
Inc. and is passionate about DILO’s slogan 
“ONE VISION. ZERO EMISSIONS.” 
Lina helps spread awareness on preventing 
SF6 emissions, regulations, and responsible 
gas handling through the DILO Blog, the 
Annual SF6 Gas Management Seminar, and industry trainings. 
THE PREMIER ELECTRICAL MAINTENANCE AND SAFETY CONFERENCE
March 8 – 12, 2023
Rosen Shingle Creek | Orlando, Florida
POWERTEST.ORG | 888.300.6382OFFERING IN-PERSON AND VIRTUAL ATTENDANCE OPTIONS
HOSTED BY
Promote your products and services to a valuable audience of key industry 
decision-makers while increasing brand visibility. 
https://www.grandviewresearch.com/industry-analysis/sulfur-hexafluoride-sf6-market
https://www.grandviewresearch.com/industry-analysis/sulfur-hexafluoride-sf6-market
https://www.grandviewresearch.com/industry-analysis/sulfur-hexafluoride-sf6-market
https://www.bbc.com/news/science-environment-49567197
https://www.bbc.com/news/science-environment-49567197
https://www.ipcc.ch/report/2019-refinement-to-the-2006-ipcc-guidelines-for-national-greenhouse-gas-inventories/
https://www.ipcc.ch/report/2019-refinement-to-the-2006-ipcc-guidelines-for-national-greenhouse-gas-inventories/
https://www.ipcc.ch/report/2019-refinement-to-the-2006-ipcc-guidelines-for-national-greenhouse-gas-inventories/
https://www.ipcc.ch/report/2019-refinement-to-the-2006-ipcc-guidelines-for-national-greenhouse-gas-inventories/
NETA Acceptance Testing
 
NETA Maintenance Testing
Regular testing, inspection and corrective services 
minimizing costly interruptions.
 
Commissioning & Startup
Start-up testing, commissioning, acceptance testing, 
breaker repair and maintenance, and 24-hour 
 
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Electrical Training
Live webinar, on-demand, in-person and custom 
safety and technical skills training.
 
Emergency Response
 
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Natural Disaster Recovery
Servicing the Gulf Coast and 
beyond to repair equipment 
and systems damaged by 
hurricanes and storms.
© Saber Power Services, LLC. 2022. All rights reserved. 
 
Saber Power Field Services is a NETA Accredited Company serving the electric 
utility, petrochemical, municipal, industrial/commercial, renewable and oil and 
gas industries. 
Quality, customer satisfaction and electrical safety set us apart from our 
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Saber Knows 
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108 • WINTER 2022 OPERATIONAL TECHNOLOGY CYBER THREATS ARE ON THE RISE
ADVANCEMENTS IN INDUSTRY
BY BRYAN J. GWYN and SAGAR S. SINGAM, Doble Engineering Company
Critical infrastructure security is in the national spotlight.[1] According 
to the 2022 State of Operational Technology and Cybersecurity Report, 
organizations throughout the world’s OT security initiatives are making 
inadequate progress toward comprehensive protection of ICS and 
SCADA systems in the relatively new world of connected OT.[2] The 
Biden administration recently issued a national security memorandum 
that sets baseline cybersecurity goals and practices to protect the grid. The 
order also encourages the deployment of advanced technology for threat 
visibility, detection, monitoring, and response.
OPERATIONAL 
TECHNOLOGY 
CYBER THREATS 
ARE ON THE RISE
NETAWorld • 109OPERATIONAL TECHNOLOGY CYBER THREATS ARE ON THE RISE
ADVANCEMENTS IN INDUSTRY
Power and utility companies play a starring role 
in safeguarding the nation’s infrastructure. Asorganizations double down on compliance and 
technology, there are several things to consider 
amidst a rapidly evolving cybersecurity 
landscape.
CONFIDENTIALITY–
INTEGRITY–AVAILABILITY 
(CIA) TRIAD 
The CIA Triad is a data security concept. It 
directs a company’s data security efforts and 
helps lay out a strong security foundation. 
In fact, including these ideas in any security 
program is ideal. The three pillars of security 
architecture are:
Confidentiality 
In today’s world, it is critical for people to 
protect their sensitive private information from 
unauthorized access. Protecting confidentiality 
necessitates the ability to define and enforce 
specific levels of access to information. In some 
cases, this entails categorizing information 
into different collections based on who needs 
access to the information and how sensitive 
the data is — the amount of damage suffered 
if confidentiality is breached. Access control 
lists, volume and file encryption, and Unix file 
permissions are some of the most used methods 
for managing confidentiality.
Integrity 
The “I” in the CIA triad represents data 
integrity. This critical component of the 
CIA Triad is intended to prevent data from 
being deleted or modified by unauthorized 
parties. For example, online buyers demand 
accurate product and pricing information and 
assurances that the quantity, cost, availability, 
and other information will not change after 
they make their order. Data integrity safeguards 
include encryption, hashing, digital signatures, 
and digital certificates.
Availability 
The availability of your data is the focus 
of this stage — the third in the CIA Triad. 
High-availability systems are computing 
resources with architectures specifically 
designed to increase availability. The most 
well-known attack that jeopardizes availability 
is called a denial-of-service attack, in which a 
system, website, or web-based application’s 
performance is purposely and maliciously 
compromised or the system is rendered 
inaccessible. The breakdown of hardware or 
software, power outages, natural catastrophes, 
and human error are other possible risks to 
availability. The information must be protected 
and made available when needed, which 
requires that authentication procedures, access 
routes, and systems all function effectively.PH
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110 • WINTER 2022 OPERATIONAL TECHNOLOGY CYBER THREATS ARE ON THE RISE
ADVANCEMENTS IN INDUSTRY
The CIA Triad is all about information and data 
security. But the first thing to note in Figure 1 
is that, in general, IT and OT risk management 
priorities differ. IT prioritizes confidentiality, 
while OT prioritizes availability, followed 
by integrity and confidentiality (A-I-C). It 
is critical for every business to identify these 
priorities since they determine the overall 
security defensive systems of the organization.
OT SECURITY GOVERNANCE[3] 
The federal government has issued many 
executive orders in the past to strengthen the 
cybersecurity posture of vital infrastructure. 
President Biden most recently signed Executive 
Order 14028 Improving the Nation’s 
Cybersecurity in May 2021 to protect critical 
infrastructure.[4] This directive focuses on 
modernizing cybersecurity requirements such 
as data encryption at rest and in transit, a 
zero-trust architecture, and the deployment of 
multifactor authentication and data encryption 
within a certain timeframe. 
This demonstrates that even today, having a 
basic security foundation such as the NIST 
Cybersecurity Framework (CSF), which went 
into force nearly a decade ago, is vital for critical 
infrastructure organizations. The NIST CSF 
consists of a framework core, profiles, and 
implementation tiers. While the core functions of 
the NIST CSF include categories, subcategories, 
and informative references, we will focus on the 
first two core components shown in Figure 2 of 
this framework from a 1,000-foot perspective.
Asset management, a comprehensive inventory 
of all OT assets, is one of the essential core 
components of an OT asset database — not 
only hardware, but also a comprehensive view 
of the data, personnel, devices, systems, and 
facilities that enable the organization to meet 
its objectives. They must be identified, and 
their importance in business objectives and 
risk management must be clearly established. 
Database management software can bridge the 
divide between competing IT and OT priorities. 
Look for a relational database architecture that 
will support a central data warehouse structured 
for universal interfacing to external systems. 
Bringing such a system on-line will integrate 
OT data into a hub where asset management 
and work management will intersect. 
Connecting dataflows emanating from 
different sources enables OT teams to have the 
data integrity, availability, and confidentiality 
they prioritize while critical elements related 
to human performance and network security 
remain intact for IT intents and purposes. The 
Confidentiality
Integrity
Priority
#1
#2
#3Availability
IT OT
Availability
Integrity
Confidentiality
Identity
Protect
DetectRespond
Recover
Confidentiality
Integrity
Priority
#1
#2
#3Availability
IT OT
Availability
Integrity
Confidentiality
Identity
Protect
DetectRespond
Recover
Figure 1: CIA Triad Priorities
Figure 2: NIST Cybersecurity Framework
ADVANCEMENTS IN INDUSTRY
ideal OT database management system will 
accept user authentications developed in the 
IT domain, which complements the corporate 
cybersecurity measures put in place for user 
(and device) password management. This 
assures data security and integrity as well. 
After identifying and categorizing your assets, 
you should take proactive measures to safeguard 
them from internal and external cyber threats. 
Security maintenance rules and practices, 
including software patch management and 
whitelisting, must be created and implemented 
for the NIST CSF’s Protect component.
INVEST IN TRANSIENT 
CYBER ASSET SECURITY 
AND PATCH MANAGEMENT
Remote field devices can present major security 
risks. Transient cyber assets (TCAs) such as 
tablets, asset testing laptops, and protective 
relays are often disconnected from the main 
network, making them a prime channel for 
spreading malware. Given that TCAs regularly 
contact critical assets, they’re a top security 
threat if not secured properly. Speed is of the 
essence when it comes to cybersecurity. 
However, securing your assets shouldn’t hold 
productivity back. Look for systems you can tailor 
to secure the work processes that need defenses 
the most and streamline procedures from the field 
to the office. Tapping patch management software 
that easily shows the patch updates available to 
TCAs enables you to quickly select the updates 
you want and automatically downloads those 
installers to TCAs to be installed during remote 
updates. Patch management systems should also 
monitor, send alerts, and report on security risks, 
keeping you in a constant state of vigilance.
STAY PREPARED AND 
PROACTIVE
Cyber threats are fast moving and unpredictable. 
Utilities need to be armed and ready with the 
right tools and processes. While advanced 
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ADVANCEMENTS IN INDUSTRY
technology for threat identification and 
management is currently strongly encouraged by 
the Biden administration, it could soon become a 
requirement. 
REFERENCES
1. Fortinet. 2022 State of Operational 
TechnologyNETA-wide, I love doing good work with 
smart people who give a damn. Our skills, 
experience, and training allow us to perform 
meaningful work. 
NWJ: Describe one of your best 
workdays…what happened? 
Hamrick: It was a one-day outage to 
troubleshoot and repair a defective transfer 
scheme. The customer had no historical 
knowledge nor associated drawings of 
the equipment. A highly respected senior 
technician and I were tasked to investigate, 
test, reverse engineer, repair, and sketch an 
old and somewhat complicated system. By 
understanding and trusting each other’s 
technical abilities, we were able to divide the 
problem and attack it from multiple directions. 
We poured ourselves into this effort, and as a 
result, found and successfully corrected several 
mis-wired and defective components. 
Although the customer was happy, only the two 
us knew and could fully appreciate the level of 
achievement we experienced. In short, the best 
workdays include teamwork with people you 
like and respect, taking on difficult tasks, and 
achieving desired goals.
NWJ: Share the story of a day that didn’t go 
as planned. How did you respond and what 
did you learn?
Hamrick: Many days have not gone as 
planned, but the project that stands out for me 
was an assessment of an industrial complex after 
a hurricane decimated a community. This task 
was originally slated for 10 days of assessment 
but quickly developed into a six-week recovery 
and repair project. 
Our team was not prepared for many aspects 
of this project, especially for the physical and 
mental suffering of those we were working 
for. To start the project, our only available 
lodging was an RV that was not equipped 
with electricity, running water, or laundry 
appliances. The client’s site had sustained 
flood waters in the lower levels of the facility 
and significant rainwater intrusion in the 
upper levels. The various products in this 
facility — plus God knows what from the 
streets — had mixed and infiltrated much 
of the electrical distribution. The situation 
was tragic, and the working conditions were 
abysmal. 
On Day 11, I took a long drive out of the 
disaster area searching for an open store that 
could provide me with fresh underwear and 
other normal creature comforts. With those 
essentials obtained, I returned to finish project. 
How did I respond? I followed the advice of 
my beautiful wife, who was at home with our 
infant and toddler. Paula’s advice was, “Suck 
it up, Buttercup. Do what you do best, and 
hurry home.” We not only achieved, but far 
surpassed the expectations of our customer. 
What I learned about planning for disaster 
recovery assignments was to over-plan for your 
provisions and build and support your home 
team. 
NWJ: What energy trend do you think will 
affect your work in the future?
Hamrick: The increased need to expand 
our nation’s power grids and generation 
plants will have a huge effect on our future 
work. Additionally, the ever-expanding 
interconnectivity of devices and systems will 
continue to affect everything we do. NETA 
technicians will continue to be an essential 
piece of the security and reliability requirements 
surrounding these delicate systems.
NWJ: As an industry, what do you think 
should be our No. 1 priority over the next year? 
Hamrick: Our No. 1 priority must 
always be legitimate safety practices. Of 
increasing concern to me is how we must 
continuously adapt our safety practices for 
INSIGHTS & INSPIRATION
fast-paced multiphase projects. Our electrical 
testing industry has definitely made great 
advancements in safety over the last couple of 
decades, but we are not alone in this overall 
industry. Project timelines and milestones 
remain constant, regardless of growing supply-
chain shortages and associated delays. These 
delays invariably lead to schedule compression 
while simultaneously introducing hazardous 
conditions to our job sites that were not 
previously a concern. 
To continue safely, we must demand proper 
communications from those working around 
us, as well as strict enforcement of hazard 
analysis and lockout/tagout procedures. 
Additionally, we must constantly verify and 
test our means of protection. Perhaps the most 
vital key to maintaining safety on these types 
of projects is a vigilant site leader who is in 
constant communication with all parties at all 
times. Finally, all team members must know 
that they are fully empowered and expected 
to stop work if these communications are not 
occurring or our safety protocols are being 
infringed upon. 
NWJ: If you were talking to a young person 
interested in knowing more about being an 
electrical testing technician, how would you 
describe the job, and what advice would you 
give them? 
Hamrick: Our profession is a great career 
choice with excellent pay and benefits. You 
will need to continually assess your current 
understanding of our craft and test what you 
know to be true. Ask many questions; learn 
new and old products, software, and methods; 
and study literature written by those who have 
explored those gaps before you.
We are in high demand due to our 
professionalism, specialized training, and 
experience. In our lifetime, I see no end for the 
need for our services. Our work has meaning, 
INSIGHTS & INSPIRATION
and you should never be bored working in this 
every-changing industry. 
At first, most new technicians will be rightfully 
fearful. They typically will not do anything 
without proper instruction and confirmation 
of their safety. Eventually, after many years 
in the field, technicians will have learned or 
experienced enough near-misses for safety to 
be deeply impressed upon their consciousness. 
Be extra concerned during the in-between 
years. Although you should never trust your 
safety to anyone, a second set of eyes is always 
encouraged. They may save your life one day. 
NWJ: Is there anything else you’d like to 
share?
Hamrick: I hope that all NETA techs enjoy 
their profession. I have truly enjoyed this career 
and time has flown by. I am humbled by the 
lessons I have learned, but also very proud of 
the many achievements and fond memories 
this career has provided.
The motto I took from the US Army Corp of 
Engineers was “Essayons!” This explanation of 
that motto (with just a few word swaps) explains 
the drive of the best NETA Technicians and the 
wider NETA team.
“The U.S. Army Engineer Regimental motto 
is  ‘Essayons!’ It is French for ‘Let us try.’ This isn’t 
a sympathetic, half-hearted try. It’s a statement of 
confidence, almost as if to say, ‘Where others failed, 
we will succeed.’” 
I wanted to be an engineer because I wanted 
to succeed where others hadn’t yet. I wanted 
a diverse mission set that required me to be 
physically fit and mentally sharp. Now, I’m just 
trying to make a difference. 
BURLINGTON
ELECTRICAL
TESTING CO., LLC
AROUND THE CLOCK 
RESPONSE SERVING THE 
POWER INDUSTRY
BET is an independent third-party testing firm with more than 50 years of 
experience serving industrial, commercial, and institutional facilities’ low- to 
high-voltage electrical testing and maintenance needs, including:
• Acceptance Testing & Commissioning
• Switchgear Reliability Testing
• Protective Relay Setting
• Transformer Repair
• Transformer Oil Analysis
• Circuit Breaker Retrofits
• Battery Bank Testing
• Cable Fault Locating
• Meter Calibration
• Motor Testing & Surge Analysis
• Infrared & Ultrasonic Inspections
• Load Survey & Analysis
• Coordination & Short Circuit Studies
• Arc Flash Hazard Analysis
For scheduling call 215-826-9400 
or email sales@betest.com
Visit us at www.betest.com
C
M
Y
CM
MY
CY
CMY
K
14 • WINTER 2022 NFPA 70E, 2024 EDITION: SECOND DRAFT MEETING 
THE NFPA 70E AND NETA
BY RON WIDUP, Shermco Industries
In late August 2022, the NFPA 70E Technical Committee met for the 
Second Draft meeting related to the revision of what will be the 2024 
edition of NFPA 70E, Standard forand Cybersecurity Report. 
Accessed at https://www.fortinet.com/content/
dam/fortinet/assets/analyst-reports/report-
2022-ot-cybersecurity.pdf. 
2. Whitehouse.gov. National Security 
Memorandum on Improving Cybersecurity 
for Critical Infrastructure Control 
Systems, 2021. Accessed at https://www.
whitehouse.gov/briefing-room/statements-
releases/2021/07/28/national-security-
memorandum-on-improving-cybersecurity-
for-critical-infrastructure-control-systems/.
3. G. Meghan. What is the NIST Cybersecurity 
Framework? Verve Blog, 2022. Accessed 
at https://verveindustrial.com/resources/blog/
what-is-the-nist-cybersecurity-framework/.
4. Whitehouse.gov. Executive Order on 
Improving the Nation’s Cybersecurity, 2021. 
Accessed at https://www.whitehouse.gov/briefing-
room/presidential-actions/2021/05/12/executive-
order-on-improving-the-nations-cybersecurity/.
Bryan J. Gwyn is Senior Director of 
Solutions at Doble, with over 30 years of 
international experience in electric utility 
transmission and distribution protection 
and control and telecommunication 
engineering, operations and management. 
Leading a team of global subject matter 
experts, he is responsible for the development of protection, 
asset management, monitoring, and security solutions. Bryan 
received his BEng (Hons) in electrical and electronic engineering 
and his PhD at City University, London. He is a Chartered 
Engineer and a Senior Member of IEEE.
Sagar S. Singam is a Senior Cyber 
Security Engineer at Doble with more 
than 8 years of expertise in industrial and 
IT cybersecurity architecture. He obtained 
his MS in information assurance and 
cybersecurity from Regis University. 
6605 W. WT Harris Blvd. Suite F • Charlotte NC 28269 | 13 Jenkins Court • Mauldin, SC 29662 | 9481 Industrial Center Drive, Suite 5 • Ladson, SC 29456
704.573.0420 • 844-383-8617 • 704.573.3693 (fax) • www.powerproducts.biz
Acceptance and Maintenance Testing
Commissioning
Circuit Breaker Repair and Retrofit
Infrared Scanning
MV Cable Terminations and Testing
Commissioning and Load Bank Testing
of UPS, Generators, and ATS
RETROFITTED BREAKER
https://www.fortinet.com/content/dam/fortinet/assets/analyst-reports/report-2022-ot-cybersecurity.pdf
https://www.fortinet.com/content/dam/fortinet/assets/analyst-reports/report-2022-ot-cybersecurity.pdf
https://www.fortinet.com/content/dam/fortinet/assets/analyst-reports/report-2022-ot-cybersecurity.pdf
https://www.whitehouse.gov/briefing-room/statements-releases/2021/07/28/national-security-memorandum-on-improving-cybersecurity-for-critical-infrastructure-control-systems/
https://www.whitehouse.gov/briefing-room/statements-releases/2021/07/28/national-security-memorandum-on-improving-cybersecurity-for-critical-infrastructure-control-systems/
https://www.whitehouse.gov/briefing-room/statements-releases/2021/07/28/national-security-memorandum-on-improving-cybersecurity-for-critical-infrastructure-control-systems/
https://www.whitehouse.gov/briefing-room/statements-releases/2021/07/28/national-security-memorandum-on-improving-cybersecurity-for-critical-infrastructure-control-systems/
https://www.whitehouse.gov/briefing-room/statements-releases/2021/07/28/national-security-memorandum-on-improving-cybersecurity-for-critical-infrastructure-control-systems/
https://verveindustrial.com/resources/blog/what-is-the-nist-cybersecurity-framework/
https://verveindustrial.com/resources/blog/what-is-the-nist-cybersecurity-framework/
https://www.whitehouse.gov/briefing-room/presidential-actions/2021/05/12/executive-order-on-improving-the-nations-cybersecurity/
https://www.whitehouse.gov/briefing-room/presidential-actions/2021/05/12/executive-order-on-improving-the-nations-cybersecurity/
https://www.whitehouse.gov/briefing-room/presidential-actions/2021/05/12/executive-order-on-improving-the-nations-cybersecurity/
REAL WORLD LEARNING AT YOUR FINGERTIPS.
Introducing NETA Series III Handbooks
We’ve got answers.
Discover page after page of comprehensive, component-specific, technical resources for 
training and reference purposes. Over 200 of the very best articles from NETA World 
Journal and technical presentations from NETA’s PowerTest conferences. 
To order, please visit netaworld.org or call 888.300.6382
114 • WINTER 2022 GROUP CBS: PEOPLE, TECHNOLOGY, AND UPTIME
NETA CAP SPOTLIGHT
NETA’s Corporate Alliance Partners (CAPs) are 
a group of industry-leading companies that have 
joined forces with NETA to work together toward 
a common aim: improving quality, safety, and 
electrical system reliability.
Here, our continuing CAP Spotlight series talks 
to President Ashley Ledbetter about the thought 
leadership and subject-matter expertise of Group CBS.
NW: What are the biggest challenges facing 
your company right now?
Ledbetter: The most important assets we 
have are human assets. We can’t be successful 
without good people. Fortunately, we’ve always 
excelled at retaining our talent, but to produce, 
repair, or service the best electrical power 
distribution equipment for the world, we need 
to continue to grow. Our employees will be key 
to achieving that goal because, while we have 
many great ideas and plans, we’ll need fresh 
perspectives and creative approaches to move 
those innovative ideas forward. 
NW: What are the biggest challenges facing 
your customers? 
Ledbetter: Maximizing uptime is a 
continual goal for our customers. The challenge 
is building effective and efficient maintenance 
programs that align with their values and vision 
while keeping their workers and customers 
safe. Coupled with that, our customers must 
be able to find the critical equipment they need 
to keep operations going. These are the areas 
where Group CBS excels. In today’s supply 
chain, Group CBS is one of the few vendors an 
electrical customer can call in the middle of the 
night for essential equipment and service. We 
are proud to serve as that dependable resource 
for our customers.
NW: Which industry trends are you keeping 
an eye on? 
Ledbetter: One of the trends we’re watching 
closely is the evolving relationship between 
companies and employees. It is changing, and 
the key to navigating it will be finding the 
balance between achieving our corporate goals 
and simultaneously supporting the individual 
growth of each employee. 
NW: Which new technologies affecting the 
industry are changing the way you work? 
Ledbetter: Technology is advancing at a 
breakneck pace, and it’s exciting — from the 
internet and video meetings changing our 
ASHLEY LEDBETTER
GROUP CBS:
PEOPLE, TECHNOLOGY, 
AND UPTIME
NETAWorld • 115GROUP CBS: PEOPLE, TECHNOLOGY, AND UPTIME
NETA CAP SPOTLIGHT
day-to-day work environment to advanced 
electronics and testing systems revolutionizing 
work in the field, such as using portable 
magnetrons to test a vacuum interrupter on site. 
NW: What do you predict will impact your 
business most in the near future? 
Ledbetter: One thing that is likely to impact 
our business is the workforce — attracting 
and retaining stellar talent. It is the most 
important aspect of our business — and that 
of our customers — today and tomorrow. To 
help support our customers in that endeavor 
as power distribution equipment in the field 
continues to age, we’re dedicated to developing 
and providing life extension solutions and other 
innovations to help customers keep the power 
flowing while preparing for future growth. 
NW: Is this a good time to be in the electrical 
power testing business?
Ledbetter: Absolutely. Electric power is 
an essential resource. However, as we are all 
aware, the average age of installed equipment 
continues to increase. Testing is the only way 
to monitor the health of power distribution 
systems. With that in mind, electrical testing 
is and will remain an essential need for today’s 
world. 
NW: If you could change one thing about 
how your business operates, what would it be? 
Ledbetter: Helping our customers to be 
safer, more efficient, and moresuccessful is our 
number-one goal, but sometimes the inherent 
silos in our industry stand in the way. If we can 
break down the walls between Group CBS and 
its customers, we can truly be a trusted partner, 
not just a vendor. Our mutual success depends 
on it. 
NW: What advice do you have for young 
people entering the field? 
Ledbetter: My recommendation for new 
entrants into the field is to be ready for change. 
It doesn’t happen overnight, but it’s coming. 
New opportunities, disciplines, and specialties 
are on the horizon. For example, while test data 
improves every year, the expertise necessary to 
put the data into perspective is still evolving. 
Prepare for these eventualities and be ready for 
tomorrow’s opportunity. 
NW: How important is mentoring in the 
electrical testing field and why? 
Ledbetter: The value of mentoring cannot 
be overstated. Tribal expertise passed down 
person to person fills the gaps between 
theoretical knowledge and real-world 
experience. Technology and empirical data 
are important, but they can’t take the place of 
relationships.
NW: What strategies will keep professionals 
growing and learning? 
Ledbetter: After many years or even 
decades in a particular industry, one must 
never be complacent. Resist the urge to rest 
on your laurels, and never think you know it 
all. There is always something new to learn, 
experience, or do — even if it’s outside your 
comfort zone. 
Group CBS Team Dinner
116 • WINTER 2022 NETA WELCOMES NEW ACCREDITED COMPANY — ELECTRO TEST LLC
Electro Test LLC was founded in 2018 when 
Brad Helminen decided there were enough 
opportunities and an open market for 
NETA testing in Oahu and the surrounding 
Hawaiian Islands. Younger brother Jared 
decided he would also try his hand at running 
a business, and he and his family followed 
NETA WELCOMES NEW ACCREDITED 
COMPANY — ELECTRO TEST
Jesse, Jared, and Brad Helminen and Clifford Fa
Brad to the North Shore of Oahu to start the 
new testing company. 
Brad and Jared were immediately involved 
in several projects that required NETA 
Certified Technicians and engineers because 
the complexity of some control systems was 
beyond the skill level of most electricians living 
in Hawaii. Jared and Brad built a reputation at 
several facilities on Oahu and the Outer Islands 
when people had electrical issues needing 
work and acceptance testing on new facilities. 
The Army Corps added Electro Test to a list 
of approved vendors, and all of the military 
installations began communicating with Electro 
Test when they had testing or troubleshooting 
needs. Since 2018, Brad, Jared, and the Electro 
Test crew have been involved in the start-up of 
new wind-farm substations, pumping stations, 
and several military installations. 
Electro Test now has a permanent home in 
the center of the Island of Oahu in Wahiawa, 
Hawaii, that includes a large industrial shop 
with space to test off-site breakers and electrical 
devices. 
“Electrical safety and testing standards in 
Hawaii have lagged behind mainland standards 
for decades,” notes Brad Helminen. “We are 
confident that Electro Test’s presence in Hawaii 
will help these industries keep pace with the 
modern world in the years to come.”
Brad and Jared Helminen are Electrical 
Engineers with degrees from Michigan 
Technological University. Jared is a licensed 
Professional Engineer in Michigan and Hawaii 
and has been a Level 3 NETA Technician 
since 2011. Brad holds a Master Electrician 
License and has been a Level 3 Certified NETA 
Technician since 2009. Clifford Fa, a former 
car mechanic who worked with mechanical 
and electrical systems, was brought on board 
in October 2020 for his skills with everything 
mechanical. Jesse Helminen, the youngest 
brother, joined the team full-time after a 
six-month internship in May 2021. Jesse 
also holds a BS in electrical engineering from 
Michigan Technological University. 
“NETA welcomes Electro Test LLC as a NETA 
Accredited Company,” says Eric Beckman, PE, 
President of National Field Services Inc. and 
current NETA President. “NETA Accredited 
Companies help advance the electrical power 
systems industry and ensure the safety and 
reliability of the electrical power system. Achieving 
NETA accreditation requires dedication and 
persistence, and we congratulate Electro Test on 
achieving this milestone event.” 
BULLOCK BREAKERS
BB
475 Annandale Blvd • Annandale • Minnesota 55302
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118 • WINTER 2022 NETA ACTIVITIES UPDATE
NAMO COMMITTEE — 
U.S. ARMY PRIME POWER 
SCHOOL GRADUATION
August 25, 2022 
Fort Leonard Wood, Missouri 
Dave Kreger, member 
of the NETA NAMO 
Committee, attended 
the Prime Power School 
graduation in August. 
While there, Dave handed 
out certificates to the 
graduates and facilitated discussions regarding 
the NETA NAMO Program. 
NETA BOARD AND MEMBER MEETINGS
September 15–16, 2022 
Louisville, Kentucky
NETA’s fall board and member meetings held in Louisville, Kentucky, focused on association 
development, membership, PowerTest updates, certification, and standards development. The board 
meeting focused on budget and program initiatives for the upcoming fiscal year. A representative 
from the Kentucky Department of Labor facilitated a discussion regarding apprenticeship programs 
and fielded questions as to the concept of a NETA apprenticeship program. 
NETA ACTIVITIES UPDATE
ORDER NOW
Visit NETAWORLD.ORG 
or call 888.300.6382
NEW EDITION
120 • WINTER 2022 ANSI/NETA STANDARDS UPDATE
SPECIFICATIONS AND STANDARDS ACTIVITY
ANSI/NETA MTS–2019 
REVISION IN PROCESS 
A standards revision is in process for ANSI/NETA–2019, 
Standard for Maintenance Testing Specifications for Electrical 
Power Equipment and Systems to be released in March 2023. 
The initial ballot and public comment period ended on 
August 29, 2022. The Standards Review Council will review 
all comments for consideration by the end of October. A 
second ballot is scheduled for issue on November 11, 2022. 
The revised edition of ANSI/NETA MTS is scheduled to 
debut at PowerTest 2023 in Orlando, Florida.
ANSI/NETA MTS contains specifications for suggested field 
tests and inspections to assess the suitability for continued 
service and reliability of electrical power equipment and 
ANSI/NETA STANDARDS UPDATE
2021
STANDARD FORACCEPTANCE
TESTING SPECIFICATIONS
FOR ELECTRICAL POWER EQUIPMENT & SYSTEMS
ANSI/NETA ATS-2021
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STANDARDS
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ELECTRICAL
COMMISSIONING SPECIFICATIONS
FOR ELECTRICAL POWER EQUIPMENT & SYSTEMS
REVISION
SCHEDULED
REVISION
IN PROCESS
NETAWorld • 121ANSI/NETA STANDARDS UPDATE
SPECIFICATIONS AND STANDARDS ACTIVITY
systems. The purpose of these specifications is to assure that 
tested electrical equipment and systems are operational and 
within applicable standards and manufacturers’ tolerances, 
and that the equipment and systems are suitable for continued 
service. ANSI/NETA MTS–2019 revisions include online 
partial discharge survey for switchgear, frequency of power 
systems studies, frequency of maintenance matrix, and more. 
ANSI/NETA MTS–2019 is available for purchase at the 
NETA Bookstore at www.netaworld.org.
ANSI/NETA ECS–2020 
NEXT REVISION SCHEDULED 
ANSI/NETA ECS, Standard for Electrical Commissioning 
of Electrical Power Equipment & Systems, will be revised 
followingthe American National Standard process. The 
next edition of the standard is scheduled to begin the 
American National Standard revision process in 2023, 
with a scheduled release in 2024. ANSI/NETA ECS–2020 
supersedes the 2015 Edition.
ANSI/NETA ECS describes the systematic process of 
documenting and placing into service newly installed or 
retrofitted electrical power equipment and systems. This 
document shall be used in conjunction with the most recent 
edition of ANSI/NETA ATS, Standard for Acceptance Testing 
Specifications for Electrical Power Equipment & Systems. 
The individual electrical components shall be subjected to 
factory and field tests, as required, to validate the individual 
components. It is not the intent of these specifications 
to provide comprehensive details on the commissioning 
of mechanical equipment, mechanical instrumentation 
systems, and related components. 
The ANSI/NETA ECS–2020 Edition includes updates 
to the commissioning process, as well as inspection and 
commissioning procedures as it relates to low- and medium-
voltage systems.
Voltage classes addressed include:
• Low-voltage systems (less than 1,000 volts)
• Medium-voltage systems (greater than 1,000 volts and 
less than 100,000 volts)
• High-voltage and extra-high-voltage systems (greater 
than 100 kV and less than 1,000 kV)
References:
• ASHRAE, ANSI/NETA ATS, NECA, NFPA 70E, 
OSHA, GSA Building Commissioning Guide
ANSI/NETA ATS–2021 
LATEST EDITION
ANSI/NETA ATS, Standard for Acceptance Testing 
Specifications for Electrical Power Equipment & Systems, 
2021 Edition, completed an American National Standard 
revision process and was published in the spring of 2021. 
ANSI/NETA ATS covers suggested field tests and 
inspections for assessing the suitability for initial 
energization of electrical power equipment and systems. 
The purpose of these specifications is to assure that tested 
electrical equipment and systems are operational, are 
within applicable standards and manufacturers’ tolerances, 
and are installed in accordance with design specifications. 
ANSI/NETA ATS-2021 new content includes arc energy 
reduction system testing and an update to the partial 
discharge survey for switchgear. ANSI/NETA ATS-2021 
is available for purchase at the NETA Bookstore at www.
netaworld.org.
ANSI/NETA ETT–2022 
LATEST EDITION
ANSI/NETA ETT, Standard for Certification of Electrical 
Testing Technicians, completed the American National 
Standard revision process. ANSI administrative approval 
was granted January 7, 2022. The new edition was released 
at PowerTest in March 2022 and supersedes the 2018 
edition. 
ANSI/NETA ETT establishes minimum requirements 
for qualifications, certification, training, and experience 
for the electrical testing technician. It provides criteria for 
documenting qualifications for certification and details the 
minimum qualifications for an independent and impartial 
certifying body to certify electrical testing technicians. 
PARTICIPATION
Comments and suggestions on any of the standards 
are always welcome and should be directed to NETA. 
To learn more about the NETA standards review 
and revision process, to purchase these standards, 
or to get involved, please visit www.netaworld.org or 
contact the NETA office at 888-300-6382.
http://www.netaworld.org
http://www.netaworld.org
http://www.netaworld.org
http://www.netaworld.org
SPECIFICATIONS AND STANDARDS ACTIVITY
BY DAVID HUFFMAN, Power Systems Testing Company
The NFPA 70B Committee met via online 
video calls to review the public inputs on the 
Second Draft. This meeting was held between 
April 25–29 2022. Several task groups held 
side meetings — some late at night and others 
very early in the morning — to complete the 
proposed responses to each input. 
Balloting for the Second Draft 70B closed on 
August 16, 2022. The report on balloting will 
be issued November 2, 2022. The committee 
will be scheduling meetings after this time. 
The Motions Committee Report (NITMAM) 
will close on November 30, 2022. A report on 
this will be posted January 11, 2023. Although 
there are no scheduled meetings at this time, I 
anticipate a meeting sometime in the spring or 
summer of 2023. 
David Huffman has been with Power 
Systems Testing, a NETA Accredited 
Company, since January 1988 and is 
currently CEO. He graduated from 
California State University, Fresno, and is a 
licensed Professional Electrical Engineer in 
the state of California as well as a NETA 
Level IV Certified Technician. David is a member of the NETA 
Board of Directors, NETA’s Principal Representative to the 
NFPA 70B Committee, and serves as a member of various 
NETA committees. 
NFPA 70B UPDATE
PowerSystemsTesting.1-2_NETA.WI15.indd 1 10/21/15 9:16 AM
A N S W E R S
No. 138
ANSWERS
1. a. A localized electrical discharge that 
only partially bridges the insulation. 
These PD events generate a current pulse. 
During off-line PD cable testing, the 
current pulses are sensed and plotted by 
the PD measuring instrument. These 
measurements are then analyzed to 
determine issues within the cable. 
TECH QUIZ ANSWERS
2. d. a & b. PD testing requires a shielded 
cable for proper uniform voltage 
application across the cable insulation. 
3. d. All of the above. All of these may be 
reasons the cable is not suitable for off-line 
PD testing. The cable might be too long for 
the PD signal to travel the length of the cable; 
excessive electrical noise may interfere with 
the ability to detect PD; and resistive shield 
connections might result in attenuation.
E A S T E R N H I G H V O L T A G E , I N C . AREAS OF EXPERTISE
PREVENTATIVE ELECTRICAL MAINTENANCE
PROGRAMS
DATA CENTERS, COMMERICAL HIGH RISES,
CRITICAL ENVIRONMENTS & FINANCIAL
INSTITUTIONS
DEVELOPMENT & UPDATES OF ELECTRICAL
SINGLE LINE DIAGRAMS
EMERGENCY GENERATOR & PARALLELING
SWITCHGEAR TESTING 
SITE SPECIFIC SAFETY & TECHNICAL TRAINING 
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INFRARED SCANNING
ACCEPTANCE TESTING 
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TECH QUIZ ANSWERS
4. c. PD measuring instrument, VLF 
hipot, and a parallel coupling capacitor. 
The VLF hipot is used to apply the AC 
waveform. Then, partial discharge is 
recorded as high-frequency signals through 
the coupling capacitor circuit into the PD 
measuring instrument.
5. b. Pico-coulombs (pC). The apparent 
charge of a PD event is typically measured 
in Picocoulombs.
6. b. No. The PD measuring instrument will 
record high-frequency signals, which could 
also include electrical noise or corona 
discharges. Once the data recording has 
been completed, the data must be reviewed 
to categorize it and determine whether 
there are any concerning PD data points. 
Upper and lower recording limits can 
be set during calibration to record the 
most advantageous spectrum to capture 
concerning PD data.
For more information about NETA and the Industry Alliance Partner 
program, please visit netaworld.org
Share your perspective with the industry when 
you become an Industry Alliance Partner.
DISCOVER AN ALL-NEW 
WAY TO PARTNER WITH NETA
NETAWorld • 125NETA ACCREDITED COMPANIES
ABM Electrical Power Services, LLC
720 S Rochester
Suite A
Ontario, CA 91761-8177
(301) 397-3500
www.abmpowerservice.abm.com
ABM Electrical Power Services, LLC
6541 Meridien Dr
Suite 113
Raleigh, NC 27616
(919) 877-1008
brandon.davis@abm.com
www.abmpowerservice.abm.com
Brandon Davis
ABM Electrical Power Services, LLC
2631 S. Roosevelt St
Tempe, AZ 85282
(602) 722-2423
ABM Electrical Power Services, LLC
3600 Woodpark Blvd Ste G
Charlotte, NC 28206-4210
(704) 273-6257
ABM Electrical Power Services, LLC
6940 Koll Center Pkwy Suite# 100
Pleasanton, CA 94566
(408) 466-6920
ABM Electrical Power Services, LLC
9800 E Geddes Ave Unit A-150
Englewood, CO 80112-9306
(303) 524-6560
ABM Electrical Power Services, LLC
3585 CorporateCourt
San Diego, CA 92123-1844
(858) 754-7963
ABM Electrical Power Services, LLC
1005 Windward Ridge Pkwy
Alpharetta, GA 30005
(770) 521-7550
www.abmpowerservice.abm.com
ABM Electrical Power Services, LLC
4221 Freidrich Lane Suite 170
Austin, TX 78744
(210) 347-9481
ABM Electrical Power Services, LLC
11719 NE 95th St. Ste H
Vancouver, WA 98682
(360) 713-9513
Paul.McKinley@abm.com
www.abmpowerservice.abm.com
Paul McKinley
ABM Electrical Power Solutions
4390 Parliament Place
Suite S
Lanham, MD 20706
(240) 487-1900
www.abmpowersolution.abm.com
ABM Electrical Power Solutions
3700 Commerce Dr # 901-903
Baltimore, MD 21227-1642
(410) 247-3300
www.abmpowersolution.abm.com
ABM Electrical Power Solutions
317 Commerce Park Drive
Cranberry Township, PA 16066-6407
(724) 772-4638
ABM Electrical Power Solutions
814 Greenbrier Cir Ste E
Chesapeake, VA 23320-2643
(757) 364-6145
keone.castleberry@abm.com
www.abmpowersolution.abm.com
Keone Castleberry
ABM Electrical Power Solutions
1817 O’Brien Road
Columbus, OH 43228
(724) 772-4638
www.abmpowersolution.abm.com
Absolute Testing Services, Inc.
8100 West Little York
Houston, TX 77040
(832) 467-4446
ap@absolutetesting.com
www.absolutetesting.com
Accessible Consulting Engineers, Inc.
1269 Pomona Rd Ste 111
Corona, CA 92882-7158
(951) 808-1040
info@acetesting.com
www.acetesting.com
Advanced Electrical Services
4999 - 43rd St. NE
Unit 143
Calgary, AB T2B 3N4
(403) 697-3747
accounting@aes-ab.com
Advanced Electrical Services
9958 - 67 Ave
Edmonton, AB T6E 0P5
(403) 697-3747
www.aes-ab.com
Advanced Testing Systems
15 Trowbridge Dr
Bethel, CT 06801-2858
(203) 743-2001
pmaccarthy@advtest.com
www.advtest.com
Pat McCarthy
A&F Electrical Testing, Inc.
80 Lake Ave S Ste 10
Nesconset, NY 11767-1017
(631) 584-5625
kchilton@afelectricaltesting.com
www.afelectricaltesting.com
A&F Electrical Testing, Inc.
80 Broad St Fl 5
New York, NY 10004-2257
(631) 584-5625
afelectricaltesting@afelectricaltesting.com
www.afelectricaltesting.com
Florence Chilton
Alpha Relay and Protection Testing, LLC
2625 Overland Ave Unit A
Billings, MT 59102
(406) 671-7227
zfettig@arptco.com
www.arptco.com
Zeb Fettig
American Electrical Testing Co., LLC
25 Forbes Boulevard
Suite 1
Foxboro, MA 02035
(781) 821-0121
www.aetco.us
Jason Briggs
American Electrical Testing Co., LLC
5540 Memorial Rd
Allentown, PA 18104
(484) 538-2272
jmunley@aetco.us
www.aetco.us
American Electrical Testing Co., LLC
34 Clover Dr
South Windsor, CT 06074-2931
(860) 648-1013
jpoulin@aetco.us
www.aetco.us
Gerald Poulin
American Electrical Testing Co., LLC
76 Cain Dr
Brentwood, NY 11717-1265
(631) 617-5330
bfernandez@aetco.us
www.aetco.us
Billy Fernandez
American Electrical Testing Co., LLC
91 Fulton St., Unit 4
Boonton, NJ 07005-1060
(973) 316-1180
jsomol@aetco.us
www.aetco.us
Jeff Somol
AMP Quality Energy Services, LLC
352 Turney Ridge Rd
Somerville, AL 35670
(256) 513-8255
brian@ampqes.com
Brian Rodgers
AMP Quality Energy Services, LLC
41 Peabody Street
Nashville, TN 37210
(629) 213-4855
Nick Tunstill
Apparatus Testing and Engineering
11300 Sanders Dr
Suite 29
Rancho Cordova, CA 95742-6822
(916) 853-6280
jcarr@apparatustesting.com
www.apparatustesting.com
Jerry Carr
Apparatus Testing and Engineering
7083 Commerce Cir Ste H
Pleasanton, CA 94588-8017
(916) 853-6280
jcarr@apparatustesting.com
www.apparatustesting.com
Jerry Carr
Applied Engineering Concepts
894 N Fair Oaks Ave.
Pasadena, CA 91103
(626) 389-2108
michel.c@aec-us.com
www.aec-us.com
Michel Castonguay
Applied Engineering Concepts
9235 Activity Road
San Diego, CA 92126
(619) 822-1106
michel.c@aec-us.com
www.aec-us.com
Michel Castonguay
ARM CAMCO, LLC
667 Industrial Park Road
Ebensburg, PA 15931
(814) 472-7980
acct@armcamco.net
Sam Morello
BEC Testing
50 Gazza Blvd
Farmingdale, NY 11735-1402
(631) 393-6800
ddevlin@banaelectric.com
www.bectesting.com
Blue Runner Switchgear Testing, LLC
924 Highway 98 East
Suite C-200
Destin, FL 32541
(270) 590-4974
cneitzel@bluerunnerswitchgear.com
www.bluerunnerswitchgear.com
Chris Neitzel
Burlington Electrical Testing Co., LLC
300 Cedar Ave
Croydon, PA 19021-6051
(215) 826-9400
waltc@betest.com
www.betest.com
Dan Calderbank
Burlington Electrical Testing Co., LLC
846 Waterford Drive
Delran, NJ 08075
(609) 267-4126
Capitol Area Testing, Inc.
P.O. Box 259
Suite 614
Crownsville, MD 21032
(757) 650-0740
carl@capitolareatesting.com
www.capitolareatesting.com
Carl VanHooijdonk
NETA ACCREDITED COMPANIES Setting the Standard
126 • WINTER 2022 NETA ACCREDITED COMPANIES
NETA ACCREDITED COMPANIES Setting the Standard
CBS Field Services
14311 29th St E
Sumner, WA 98390-9690
(253) 891-1995
dhook@groupcbs.com 
www.cbsfieldservices.com 
Dan Hook
CBS Field Services
12794 Currie Court
Livonia, MI 48150
(810) 720-2280
CBS Field Services
5680 S 32nd St
Phoenix, AZ 85040-3832
(602) 426-1667
www.cbsfieldservices.com 
CBS Field Services
3676 W California Ave Ste C106
Salt Lake City, UT 84104-6533
(888) 395-2021
www.cbsfieldservices.com 
CBS Field Services
4510 NE 68th Dr Unit 122
Vancouver, WA 98661-1261
(888) 395-2021
www.cbsfieldservices.com 
Jason Carlson
CBS Field Services
5505 Daniels St.
Chino, CA 91710
(602) 426-1667
Matt Wallace
CBS Field Services
620 Meadow Ln.
Los Alamos, NM 87547
(505) 469-1661
CBS Field Services
5385 Gateway Boulevard #19-21
Lakeland, FL 33811
(810) 720-2280
CBS Field Services
1313 Jewel Street
Nashville, TN 37207
mramieh@cbsfieldservices.com
www.cbsfieldservices.com
Mose Ramieh III
CE Power Engineered Services, LLC
4040 Rev Drive
Cincinnati, OH 45232
(800) 434-0415
info@cepower.net
CE Power Engineered Services, LLC
11620 Crossroads Cir
Middle River, MD 21220-2874
(410) 344-0300
Steve.Pieroski@qualusmail.com
Steve Pieroski
CE Power Engineered Services, LLC
480 Cave Rd
Nashville, TN 37210-2302
(615) 882-9455
dave.mitchell@cepower.net
www.cepower.net
Dave Mitchell
CE Power Engineered Services, LLC
4089 Landisville Rd.
Doylestown, PA 18902
(215) 364-5333
Allison.Schultz@qualusmail.com
CE Power Engineered Services, LLC
40 Washington St
Westborough, MA 01581-1088
(508) 881-3911
matthew.robinson@qualusmail.com
www.cepower.net
Matthew Robinson
CE Power Engineered Services, LLC
9200 75th Avenue N
Brooklyn Park, MN 55428
(877) 968-0281
James.Karpowicz@qualusmail.com
www.cepower.net
James Karpowicz
CE Power Engineered Services, LLC
72 Sanford Drive
Gorham, ME 04038
(800) 649-6314
www.cepower.net
CE Power Engineered Services, LLC
8490 Seward Rd.
Fairfield, OH 45011
(800) 434-0415
info@cepower.net
www.cepower.net
CE Power Engineered Services, LLC
1803 Taylor Ave.
Louisville, KY 40213
(800) 434-0415
Eric.croner@cepower.net
www.cepower.net
Eric Croner
CE Power Engineered Services, LLC
1200 W. West Maple Rd.
Walled Lake, MI 48390
(810) 229-6628
www.cepower.net
Ryan Wiegand
CE Power Engineered Services, LLC
10840 Murdock Drive
Knoxville, TN 37932
(800) 434-0415
don.williams@cepower.net
www.cepower.net
Don Williams
CE Power Engineered Services, LLC
3496 E. 83rd Place
Merrillville, IN 46410
(219) 942-2346
lucas.gallagher@cepower.net
www.cepower.net
Lucas Gallagher
CE Power Engineered Services, LLC
1260 Industrial Park
Eveleth, MN 55734
(218) 744-4200
Kip Kennedy
CE Power Engineered Services, LLC
401 Independence Pkwy S
La Porte, TX 77571
(361) 443-7714
Dusty Nations
CE Power Solutions of Florida, LLC
3502 Riga Blvd., Suite C
Tampa, FL 33619
(866) 439-2992
robert.bordas@cepowersol.com
www.cepowersol.com
Robert Bordas
CE Power Solutions of Florida, LLC
3801 SW 47th Avenue Suite 505
Davie, FL 33314
(866) 439-2992
robert.bordas@cepowersol.com
www.cepowersol.com
Robert Bordas
Control Power Concepts
3065 E. Post Road
Las Vegas, NV 89120
(702) 448-7833
jtravis@ctrlpwr.com
www.controlpowerconcepts.com
Eastern High Voltage, Inc.
11A S Gold Dr
Robbinsville, NJ 08691-1685
(609) 890-8300
bobwilson@easternhighvoltage.com
www.easternhighvoltage.com
Robert Wilson
Electek Power Services, Inc.
870 Confederation Street
Sarnia, ON N7T2E5
(519) 383-0333
kgadsby@electek.ca
https://electek.ca/
Kathy GadsbyELECT, P.C.
375 E. Third Street
Wendell, NC 27591
(919) 365-9775
btyndall@elect-pc.com
www.elect-pc.com
Barry W. Tyndall
Electrical & Electronic Controls
6149 Hunter Rd
Ooltewah, TN 37363-8762
(423) 344-7666
eecontrols@comcast.net
Michael Hughes
Electrical Energy Experts, LLC
W129N10818 Washington Dr
Germantown, WI 53022-4446
(262) 255-5222
mhanek@electricalenergyexperts.com
www.electricalenergyexperts.com
Michael Hanek
Electrical Energy Experts, LLC
815 Commerce Dr.
Oak Brook, IL 60523
(847) 875-5611
Michael Hanek
Electrical Engineering & Service Co., Inc.
289 Centre St.
Holbrook, MA 02343
(781) 767-9988
jcipolla@eescousa.com
www.eescousa.com
Joe Cipolla
Electrical Equipment Upgrading, Inc.
21 Telfair Pl
Savannah, GA 31415-9518
(912) 232-7402
kmiller@eeu-inc.com
www.eeu-inc.com
Kevin Miller
Electrical Reliability Services
610 Executive Campus Dr
Westerville, OH 43082-8870
(877) 468-6384
info@electricalreliability.com
www.electricalreliability.com
Electrical Reliability Services
5909 Sea Lion Pl Ste C
Carlsbad, CA 92010-6634
(858) 695-9551
www.electricalreliability.com
Electrical Reliability Services
1057 Doniphan Park Cir Ste A
El Paso, TX 79922-1329
(915) 587-9440
www.electricalreliability.com
Electrical Reliability Services
6900 Koll Center Pkwy Ste 415
Pleasanton, CA 94566-3119
(925) 485-3400
www.electricalreliability.com
Electrical Reliability Services
8500 Washington St NE Ste A6
Albuquerque, NM 87113-1861
(505) 822-0237
www.electricalreliability.com
Electrical Reliability Services
2275 Northwest Pkwy SE Ste 180
Marietta, GA 30067-9319
(770) 541-6600
www.electricalreliability.com
Electrical Reliability Services
12130 Mora Drive
Unit 1
Santa Fe Springs, CA 90670
(562) 236-9555
www.electricalreliability.com
Electrical Reliability Services
400 NW Capital Dr
Lees Summit, MO 64086-4723
(816) 525-7156
www.electricalreliability.com
Electrical Reliability Services
7100 Broadway Ste 7E
Denver, CO 80221-2900
(303) 427-8809
www.electricalreliability.com
NETAWorld • 127NETA ACCREDITED COMPANIES
Electrical Reliability Services
2222 W Valley Hwy N Ste 160
Auburn, WA 98001-1655
(253) 736-6010
www.electricalreliability.com
Electrical Reliability Services
221 E. Willis Road, Suite 3
Chandler, AZ 85286
(480) 966-4568
www.electricalreliability.com
Electrical Reliability Services
1380 Greg St. Ste. 216
Sparks, NV 89431-6070
(775) 746-4466
www.electricalreliability.com
Electrical Reliability Services
11000 Metro Pkwy Ste 30
Fort Myers, FL 33966-1244
(239) 693-7100
www.electricalreliability.com
Electrical Reliability Services
245 Hood Road
Sulphur, LA 70665-8747
(337) 583-2411
wayne.beaver@vertivco.com
www.electricalreliability.com
Electrical Reliability Services
9736 South Sandy Pkwy 500 West
Sandy, UT 84070
(801) 561-0987
www.electricalreliability.com
Electrical Reliability Services
6351 Hinson Street, Suite A
Las Vegas, NV 89118-6851
(702) 597-0020
www.electricalreliability.com
Electrical Reliability Services
36572 Luke Drive
Geismar, LA 70734
(225) 647-0732
www.electricalreliability.com
Electrical Reliability Services
9636 Saint Vincent Ave Unit A
Shreveport, LA 71106-7127
(318) 869-4244
Electrical Reliability Services
1426 Sens Rd. Ste. #5
La Porte, TX 77571-9656
(281) 241-2800
www.electricalreliability.com
Electrical Reliability Services
9753 S. 140th Street, Suite 109
Omaha, NE 68138
(402) 861-9168
Electrical Reliability Services
190 E. Stacy Road
306 #374
Allen, TX 75002
(972) 788-0979
Electrical Reliability Services
4833 Berewick Town Ctr Drive
Ste E-207
Charlotte, NC 28278
(704) 583-4794
Electrical Reliability Services
324 S. Wilmington St.
Ste 299
Raleigh, NC 27601
(919) 807-0995
Electrical Reliability Services
13720 Old St. Augustine Rd.
Ste. 8 #289
Jacksonville, FL 32258
(904) 292-9779
Electrical Reliability Services
3049 Old Hwy 52
Suite A-106
Moncks Corner, SC 29461
(239) 693-7100
Hugh McKee
Electrical Reliability Services
4099 SE International Way Ste 201
Milwaukie, OR 97222-8853
(503) 653-6781
www.electricalreliability.com
Electrical Testing and Maintenance Corp.
3673 Cherry Rd Ste 101
Memphis, TN 38118-6313
(901) 566-5557
r.gregory@etmcorp.net
www.etmcorp.net
Ron Gregory
Electrical Testing, Inc.
2671 Cedartown Hwy SE
Rome, GA 30161-3894
(706) 234-7623
clifton@electricaltestinginc.com
www.electricaltestinginc.com
Electrical Testing Solutions
2909 Greenhill Ct
Oshkosh, WI 54904-9769
(920) 420-2986
tmachado@electricaltestingsolutions.com
www.electricaltestingsolutions.com/
Tito Machado
Electric Power Systems, Inc.
21 Millpark Ct
Maryland Heights, MO 63043-3536
(314) 890-9999
STL@epsii.com
www.epsii.com
James Vaughn
Electric Power Systems, Inc.
11211 E. Arapahoe Rd
Ste 108
Centennial, CO 80112
(720) 857-7273
den@epsii.com
www.epsii.com
Mike Benitez
Electric Power Systems, Inc.
120 Turner Road
Salem, VA 24153-5120
(540) 375-0084
rnk@epsii.com
www.epsii.com
Richard Kessler
Electric Power Systems, Inc.
1090 Montour West Ind Park
Coraopolis, PA 15108-9307
(412) 276-4559
PIT@epsii.com
www.epsii.com
Jon Rapuk
Electric Power Systems, Inc.
4300 NE 34th Street
Kansas City, MO 64117
(816) 241-9990
KAN@epsii.com
www.epsii.com
Rodrigo Lallana
Electric Power Systems, Inc.
1230 N Hobson St.
Suite 101
Gilbert, AZ 85233
(480) 633-1490
PHX@epsii.com
www.epsii.com
Mike Benitez
Electric Power Systems, Inc.
915 Holt Ave Unit 9
Manchester, NH 03109-5606
(603) 657-7371
MAN@epsii.com
www.epsii.com
Sam Bossee
Electric Power Systems, Inc.
3806 Caboose Place
Sanford, FL 32771
(407) 578-6424
ORL@epsii.com
www.epsii.com
Justin McGinn
Electric Power Systems, Inc.
1129 E Highway 30
Gonzales, LA 70737-4759
(225) 644-0150
BAT@epsii.com
www.epsii.com
Josh Galaz
Electric Power Systems, Inc.
684 Melrose Avenue
Nashville, TN 37211-3121
(615) 834-0999
NSH@epsii.com
www.epsii.com
James Vaughn
Electric Power Systems, Inc.
2888 Nationwide Parkway
2nd Floor
Brunswick, OH 44212
(330) 460-3706
CLE@epsii.com
www.epsii.com
Jon Rapuk
Electric Power Systems, Inc.
54 Eisenhower Lane North
Lombard, IL 60148
(815) 577-9515
CHI@epsii.com
www.epsii.com
George Bratkiv
Electric Power Systems, Inc.
1330 Industrial Blvd.
Suite 300
Sugar Land, TX 77478
(713) 644-5400
HOU@epsii.com
www.epsii.com
Electric Power Systems, Inc.
1361 Glory Rd
Green Bay, WI 54304-5640
(920) 632-7929
info@energisinc.com
www.energisinc.com
Electric Power Systems, Inc.
11861 Longsdorf St
Riverview, MI 48193-4250
(734) 282-3311
DET@epsii.com
www.epsii.com
Greg Eakins
Electric Power Systems, Inc.
4416 Anaheim Ave. NE
Albuquerque, NM 87113
(505) 792-7761
ABQ@epsii.com
www.epsii.com
Mike Benitez
Electric Power Systems, Inc.
3209 Gresham Lake Rd.
Suite 155
Raleigh, NC 27615
(919) 322-2670
RAL@epsii.com
www.epsii.com
Yigitcan Unludag
Electric Power Systems, Inc.
4216 N. Pecos Road, Suite 108
North Las Vegas, NV 89115
(702) 815-1342
LAS@epsii.com
www.epsii.com
NETA ACCREDITED COMPANIES Setting the Standard
128 • WINTER 2022 NETA ACCREDITED COMPANIES
NETA ACCREDITED COMPANIES Setting the Standard
Electric Power Systems, Inc.
9835 Carroll Centre Rd
Suite 103
San Diego, CA 91126
(858) 566-6317
SAN@epsii.com
www.epsii.com
Electric Power Systems, Inc.
6679 Peachtree Industrial Dr.
Suite H
Norcross, GA 30092
(770) 416-0684
ATL@epsii.com
www.epsii.com
Justin McGinn
Electric Power Systems, Inc.
1051 Technology Park Dr.
Glen Allen, VA 23059
(804) 526-6794
RIC@epsii.com
www.epsii.com
Electric Power Systems, Inc.
7169 East 87th St.
Indianapolis, IN 46256
(317) 941-7502
IND@epsii.com
www.epsii.com
Ben Hocking
Electric Power Systems, Inc.
7308 Aspen Lane North
Suite 160
Brooklyn Park, MN 55428
(763) 315-3520
MIN@epsii.com
www.epsii.com
Paul Cervantez
Electric Power Systems, Inc.
140 Lakefront Drive
Cockeysville, MD 21030
(443) 689-2220
WDC@epsii.com
www.epsii.com
Jon Rapuk
Electric Power Systems, Inc.
675 N. Glenville Dr, Ste 125
Richardson, TX 75081
(214) 821-3311
Electric Power Systems, Inc.
11912 NE 95th St. Suite 306
Vancouver, WA 98682
(855) 459-4377
VAN@epsii.com
www.epsii.com
Anthony Asciutto
Electric Power Systems,Inc.
Padre Mariano
272, Of. 602
Providencia, Santiago,  
Electric Power Systems, Inc.
9860 Windisch Road
West Chester, OH 45069
(513) 644-2098
Aaron Galley
Electric Power Systems, Inc.
5653 Stoneridge Drive
Suite 108
Pleasanton, CA 94588
(415) 683-7789
Mike Bloomfield
Electric Power Systems, Inc.
1780 E. McFadden
Suite 112
Santa Ana, CA 92705
(714) 714-7226
Reynaldo Perez
Electric Power Systems, Inc.
1612 Poole Blvd
Yuba City, CA 95993
(530) 755-3123
Jim Wolfgram
Electro Test, LLC
401 N. Cane Street
Unit A-4
Wahiawa, HI 96786
(808) 321-2028
bhelminen@electrotest.pro
www.electrotest.pro
Brad Helminen
Elemco Services, Inc.
228 Merrick Rd
Lynbrook, NY 11563-2622
(631) 589-6343
courtney@elemco.com
www.elemco.com
Courtney Gallo
EnerG Test, LLC
206 Gale Lane
Kennett Square, PA 19348
(484) 731-0200
info@energtest.com
www.energtest.com
EPS Technology
37 Ozick Dr.
Durham, CT 06422
(203) 679-0145
www.eps-technology.com
ESR Electrical Services
425 S. 48th Street
Suite 114
Tempe, AZ 85281
(661) 644-2430
jacob@esreliability.com
Jacob Webb
ESR Electrical Services
5009 Pacific Hwy East, Unit 13
Fife, WA 98424
(800) 342-4560
chuck@esreliability.com
Charles Duncan III
ESR Electrical Services
3204 NE 13th Place
Hillsboro, OR 97124
(800) 342-4560
chuck@esreliability.com
Charles Duncan III
ESR Electrical Services
1737 NE 8th Street
Hermiston, OR 97838
(800) 342-4560
chuck@esreliability.com
Charles Duncan III
ESR Electrical Services
23421 Spicebush Terrace
Ashburn, VA 20148
(800) 342-4560
jacob@esreliability.com
Jacob Webb
Giga Electrical & Technical Services, Inc.
5926 E. Washington Boulevard
Commerce, CA 90040
(323) 255-5894
gigaelectrical@gmail.com
www.gigaelectrical-ca.com/
Hermin Machacon
Grubb Engineering, Inc.
2727 North Saint Mary’s St.
San Antonio, TX 78212
(210) 658-7250
rgrubb@grubbengineering.com
www.grubbengineering.com
Robert Grubb
Halco Testing Services
5773 Venice Boulevard
Los Angeles, CA 90019
(323) 933-9431
accounting@halco.net
www.halcotestingservices.com
Don Genutis
Hampton Tedder Technical Services
4563 State St
Montclair, CA 91763-6129
(909) 628-1256
chasen.tedder@hamptontedder.com
www.httstesting.com
Chasen Tedder
Hampton Tedder Technical Services
3747 W Roanoke Ave
Phoenix, AZ 85009-1359
(480) 967-7765
www.httstesting.com
Linc McNitt
Hampton Tedder Technical Services
4113 Wagon Trail Ave.
Las Vegas, NV 89118
(702) 452-9200
www.httstesting.com
Roger Cates
High Energy Electrical Testing, Inc.
5042 Industrial Road, Unit D
Farmingdale, NJ 07727
(732) 938-2275
judylee@highenergyelectric.com
www.highenergyelectric.com
High Voltage Maintenance Corp.
5100 Energy Dr
Dayton, OH 45414-3525
(937) 278-0811
www.hvmcorp.com
High Voltage Maintenance Corp.
24 Walpole Park S
Walpole, MA 02081-2541
(508) 668-9205
www.hvmcorp.com
High Voltage Maintenance Corp.
1052 Greenwood Springs Rd.
Suite E
Greenwood, IN 46143
(317) 322-2055
www.hvmcorp.com
High Voltage Maintenance Corp.
355 Vista Park Dr
Pittsburgh, PA 15205-1206
(412) 747-0550
www.hvmcorp.com
High Voltage Maintenance Corp.
8787 Tyler Blvd.
Mentor, OH 44061
(440) 951-2706
www.hvmcorp.com
Greg Barlett
High Voltage Maintenance Corp.
24371 Catherine Industrial Dr 
Suite 207
Novi, MI 48375-2422
(248) 305-5596
www.hvmcorp.com
High Voltage Maintenance Corp.
3000 S Calhoun Rd
New Berlin, WI 53151-3549
(262) 784-3660
www.hvmcorp.com
High Voltage Maintenance Corp.
1 Penn Plaza
Suite 500
New York, NY 10119
(718) 239-0359
www.hvmcorp.com
High Voltage Maintenance Corp.
29 Diana Court
Cheshire, CT 06410
(203) 949-2650
www.hvmcorp.com
Peter Dobrowolski
High Voltage Maintenance Corp.
941 Busse Rd
Elk Grove Village, IL 60007-2400
(847) 640-0005
High Voltage Maintenance Corp.
7380 Coca Cola Drive
Suite 112-113
Hanover, MD 21076
(410) 279-0798
www.hvmcorp.com
Jeff Gyurasics
High Voltage Maintenance Corp.
10704 Electron Drive
Louisville, KY 40299
(859) 371-5355
NETAWorld • 129NETA ACCREDITED COMPANIES
High Voltage Maintenance Corp.
1 Penn Plaza, Suite 1500
New York, NY 10119
(718) 239-0359
New York Area Service Center
High Voltage Maintenance Corp.
Cincinnati/Kentucky
Area Satellite Office
(859) 371-5355
Hood Patterson & Dewar, Inc.
850 Center Way
Norcross, GA 30071
(770) 453-1415
info@hoodpd.com
https://hoodpd.com/
Brandon Sedgwick
Hood Patterson & Dewar, Inc.
15924 Midway Road
Addison, TX 75001
(214) 461-0760
info@hoodpd.com
https://hoodpd.com/
Hood Patterson & Dewar, Inc.
4511 Daly Dr.
Suite 1
Chantilly, VA 20151
(571) 299-6773
info@hoodpd.com
https://hoodpd.com/
Hood Patterson & Dewar, Inc.
1531 Hunt Club Blvd
Suite 200
Gallatin, TN 37066
(615) 527-7084
info@hoodpd.com
https://hoodpd.com/
Industrial Electric Testing, Inc.
11321 Distribution Ave W
Jacksonville, FL 32256-2746
(904) 260-8378
gbenzenberg@bellsouth.net
www.industrialelectrictesting.com
Gary Benzenberg
Industrial Electric Testing, Inc.
201 NW 1st Ave
Hallandale Beach, FL 33009-4029
(954) 456-7020
gbenzenberg@bellsouth.net
www.industrialelectrictesting.com
Gary Benzenberg
Industrial Tests, Inc.
4021 Alvis Ct Ste 1
Rocklin, CA 95677-4031
(916) 296-1200
greg@indtest.com
www.industrialtests.com
Greg Poole
Infra-Red Building and Power Service, Inc.
152 Centre St
Holbrook, MA 02343-1011
(781) 767-0888
Tom.McDonald@infraredbps.com
www.infraredbps.com
Thomas McDonald Sr.
JET Electrical Testing, LLC
100 Lenox Drive
Suite 100
Lawrenceville, NJ 08648
(609) 285-2800
jvasta@jetelectricaltesting.com
jetelectricaltesting.com
Joe Vasta
J.G. Electrical Testing Corporation
3092 Shafto Road
Suite 13
Tinton Falls, NJ 07753
(732) 217-1908
h.trinkowsky@jgelectricaltesting.com
www.jgelectricaltesting.com
KT Industries, Inc.
3203 Fletcher Drive
Los Angeles, CA 90065
(323) 255-7143
eric@kti.la
ktiengineering.com
Eric Vaca
Magna IV Engineering
1103 Parsons Rd. SW
Edmonton, AB T6X 0X2
(780) 462-3111
info@magnaiv.com
www.magnaiv.com
Virginia Balitski
Magna IV Engineering
141 Fox Cresent
Fort McMurray, AB T9K 0C1
(780) 791-3122
info@magnaiv.com
Ryan Morgan
Magna IV Engineering
3124 Millar Ave.
Saskatoon, SK S7K 5Y2
(306) 713-2167
info.saskatoon@magnaiv.com
Adam Jaques
Magna IV Engineering
96 Inverness Dr E Ste R
Englewood, CO 80112-5311
(303) 799-1273
info.denver@magnaiv.com
Kevin Halma
Magna IV Engineering
Avenida del Condor sur #590
Oficina 601
Huechuraba 8580676
+(56) -2-26552600 
info.santiago@magnaiv.com
Harvey Mendoza
Magna IV Engineering
Unit 110, 19188 94th Avenue
Surrey, BC V4N 4X8
(604) 421-8020
info.vancouver@magnaiv.com
Rob Caya
Magna IV Engineering
Suite 200, 688 Heritage Dr. SE
Calgary, AB T2H 1M6
(403) 723-0575
info.calgary@magnaiv.com
Morgan MacDonnell
Magna IV Engineering
4407 Halik Street Building E
Suite 300
Pearland, TX 77581
(346) 221-2165
info.houston@magnaiv.com
www.magnaiv.com
Aric Proskurniak
Magna IV Engineering
10947 92 Ave
Grande Prairie, AB T8V 3J3
1.800.462.3157
info.grandeprairie@magnaiv.com
Matthew Britton
Magna IV Engineering
531 Coster St.
Bronx, NY 10474
(800) 462-3157
Info.newyork@magnaiv.com
Donald Orbin
Midwest Engineering Consultants, Ltd.
2500 36th Ave
Moline, IL 61265-6954
(309) 764-1561
m-moorehead@midwestengr.com
www.Midwestengr.com
Monte Moorehead
M&L Power Systems, Inc.
109 White Oak Ln Ste 82
Old Bridge, NJ 08857-1980
(732) 679-1800
milind@mlpower.com
www.mlpower.com
Milind Bagle
MTA Electrical Engineers
350 Pauma Place
Escondido, CA 92029
(760) 658-6098
tim@mtaee.com
https://mtaee.com/
Timothy G. Shaw
National Field Services
651 Franklin
Lewisville, TX 75057-2301
(972) 420-0157
eric.beckman@natlfield.com
www.natlfield.com
Eric Beckman
National Field Services
1760 W. Walker Street
Suite 100
League City, TX 77573
(800) 420-0157
don.haas@natlfield.com
Donald Haas
National Field Services
1405 United Drive
Suite 113-115
San Marcos, TX 78666
(800) 420-0157
matt.lacoss@natlfield.com
www.natlfield.com
Matthew LaCoss
National Field Services
3711 Regulus Ave.
Las Vegas, NV 89102
(888) 296-0625
www.natlfield.com
Joe Laning
National Field Services
2900 Vassar St. #114
Reno, NV 89502
(775) 410-0430
Joe.Laning@IEMworldwide.comwww.natlfield.com
Joe Laning
National Field Services
21818 S. Wiliminton Ave #409
Carson, CA 90810
(310) 549-5673
Joe.Laning@IEMworldwide.com
Joe Laning
National Field Services
1331 Baltimore Street
Longview, WA 98632
(360) 425-8700
Steve Warren
North Central Electric, Inc.
69 Midway Ave
Hulmeville, PA 19047-5827
(215) 945-7632
bjmessina@ncetest.com
www.ncetest.com
Robert Messina
Orbis Engineering Field Services Ltd.
#300, 9404 - 41st Ave.
Edmonton, AB T6E 6G8
(780) 988-1455
accountspayable@orbisengineering.net
www.orbisengineering.net
Orbis Engineering Field Services Ltd.
#228 - 18 Royal Vista Link NW
Calgary, AB T3R 0K4
(403) 374-0051
Amin Kassam
Orbis Engineering Field Services Ltd.
Badajoz #45, Piso 17
Las Condes, Santiago
+56 2 29402343
framos@orbisengineering.net
Felipe Ramos
Pace Technologies, Inc.
9604 - 41 Avenue NW
Edmonton, AB T6E 6G9
(780) 450-0404
www.pacetechnologies.com
NETA ACCREDITED COMPANIES Setting the Standard
130 • WINTER 2022 NETA ACCREDITED COMPANIES
NETA ACCREDITED COMPANIES Setting the Standard
Pace Technologies, Inc.
#10, 883 McCurdy Place
Kelowna, BC V1X 8C8
(250) 712-0091
Pace Technologies, Inc.
110-7685 56 St. SE
Calgary, AB T2C 5S7
(780) 450-0404
mcollins@pacetechologies.com
Micah Collins
Pacific Power Testing, Inc.
14280 Doolittle Dr
San Leandro, CA 94577-5542
(510) 351-8811
steve@pacificpowertesting.com
www.pacificpowertesting.com
Steve Emmert
Phasor Engineering
Sabaneta Industrial Park #216
Mercedita 00715
(787) 844-9366 
rcastro@phasorinc.com
www.phasorinc.com
Rafael Castro
Potomac Testing
1610 Professional Blvd Ste A
Crofton, MD 21114-2051
(301) 352-1930
kbassett@potomactesting.com
www.potomactesting.com
Ken Bassett
Potomac Testing
1991 Woodslee Dr
Troy, MI 48083-2236
(248) 689-8980
www.potomactesting.com
Potomac Testing
12342 Hancock St
Carmel, IN 46032-5807
(317) 853-6795
Potomac Testing
1130 MacArthur Rd.
Jeffersonville, OH 43128
Power Engineering Services, Inc.
9179 Shadow Creek Ln
Converse, TX 78109-2041
(210) 590-6214
pes@pe-svcs.com
www.pe-svcs.com
Power Engineering Services, Inc.
4041 Ellis Road Suite 100
Friendswood, TX 77546
(832) 451-9876
jhill@pe-svcs.com
www.pe-svcs.com
Jase Hill
Power Engineering Services, Inc.
1001 Doris Lane
Suite E
Cedar Park, TX 78613
(254) 410-9299
jlord@pe-svcs.com
www.pe-svcs.com
Jason Lord
Power Products & Solutions, LLC
6605 W WT Harris Blvd
Suite F
Charlotte, NC 28269
(704) 573-0420 x12 
adis.talovic@powerproducts.biz
www.powerproducts.biz
Adis Talovic
Power Products & Solutions, LLC
13 Jenkins Ct
Mauldin, SC 29662-2414
(800) 328-7382
raymond.pesaturo@powerproducts.biz
www.powerproducts.biz
Raymond Pesaturo
Power Products & Solutions, LLC
9481 Industrial Center Dr.
Unit 5
Ladson, SC 29456
(844) 383-8617
www.powerproducts.biz
Power Solutions Group, Ltd.
425 W Kerr Rd
Tipp City, OH 45371-2843
(937) 506-8444
bwilloughby@powersolutionsgroup.com
www.powersolutionsgroup.com
Barry Willoughby
Power Solutions Group, Ltd.
251 Outerbelt St.
Columbus, OH 43213
(614) 310-8018
sspohn@powersolutionsgroup.com
www.powersolutionsgroup.com
Power Solutions Group, Ltd.
5115 Old Greenville Highway
Liberty, SC 29657
(864) 540-8434
fcrawford@powersolutionsgroup.com
www.powersolutionsgroup.com
Anthony Crawford
Power Solutions Group, Ltd.
172 B-Industrial Dr.
Clarksville, TN 37040
(931) 572-8591
Chris Brown
Power System Professionals, Inc.
429 Clinton Ave
Roseville, CA 95678
(866) 642-3129
jburmeister@powerpros.net
James Burmeister
Power Systems Testing Co.
4688 W Jennifer Ave Ste 108
Fresno, CA 93722-6418
(559) 275-2171 ext 15 
dave@pstcpower.com
www.powersystemstesting.com
David Huffman
Power Systems Testing Co.
600 S Grand Ave Ste 113
Santa Ana, CA 92705-4152
(714) 542-6089
www.powersystemstesting.com
Power Systems Testing Co.
6736 Preston Ave Ste E
Livermore, CA 94551-8521
(510) 783-5096
www.powersystemstesting.com
Power Test, Inc.
2220 Hwy 49
Harrisburg, NC 28075-7506
(704) 200-8311
rich@powertestinc.com
www.powertestinc.com
Praetorian Power Protection, LLC
PO Box 3366
Lynnwood, WA 98046
(206) 612-6367
MChislett@praetorianpower.com
Michael Chislett
Precision Testing Group
5475 Highway 86 Unit 1
Elizabeth, CO 80107-7451
(303) 621-2776
office@precisiontestinggroup.com
www.precisiontestinggroup.com
Premier Power Maintenance Corporation
4035 Championship Drive
Indianapolis, IN 46268
(317) 879-0660
bob.sheppard@premierpower.us
Premier Power Maintenance Corporation
2725 Jason Rd
Ashland, KY 41102-7756
(606) 929-5969
jay.milstead@premierpower.us
www.premierpowermaintenance.com
Jay Milstead
Premier Power Maintenance Corporation
3066 Finley Island Cir NW
Decatur, AL 35601-8800
(256) 355-1444
johnnie.mcclung@premierpower.us
www.premierpowermaintenance.com
Johnnie McClung
Premier Power Maintenance Corporation
7262 Kensington Rd.
Brighton, MI 48116
(517) 715-9997
steve.monte@premierpower.us
Steve Monte
Premier Power Maintenance Corporation
1901 Oakcrest Ave., Suite 6
Saint Paul, MN 55113
(612) 430-0209
Zac.mrdgenovich@premierpower.us
Zac Mrdjenovich
Premier Power Maintenance Corporation
119 Rochester Dr.
Louisville, KY 40214
(256) 200-6833
Jeremiah.evans@premierpower.us
Jeremiah Evans
QP Testing, LLC
2200 Ellis Rd
New Lenox, IL 60451
(815) 724-2216
spioppo@qp-testing.com
Steve Pioppo
RESA Power Service
50613 Varsity Ct.
Wixom, MI 48393
(248) 313-6868
lester.mcmanaway@resapower.com
www.resapower.com
RESA Power Service
3890 Pheasant Ridge Dr. NE
Suite 170
Blaine, MN 55449
(763) 784-4040
Michael.mavetz@resapower.com
www.resapower.com
Mike Mavetz
RESA Power Service
6148 Tim Crews Rd
Macclenny, FL 32063-4036
(904) 653-1900
mark.chapman@resapower.com
Mark Chapman
RESA Power Service
4540 Boyce Parkway
Cleveland, OH 44224
(800) 264-1549
garth.paul@resapower.com
www.resapower.com
Garth Paul
RESA Power Service
19621 Solar Circle, 101
Parker, CO 80134
(303) 781-2560
john.leusink@resapower.com
John Leusink
RESA Power Service
40 Oliver Terrace
Shelton, CT 06484-5336
(800) 272-7711
adam.stevens@resapower.com
Adam Stevens
RESA Power Service
13837 Bettencourt Street
Cerritos, CA 90703
(800) 996-9975
bryan.larkin@resapower.com
www.resapower.com
Bryan Larkin
RESA Power Service
2300 Zanker Road
Suite D
San Jose, CA 95131
(800) 576-7372
bryan.larkin@resapower.com
www.resapower.com
NETAWorld • 131NETA ACCREDITED COMPANIES
RESA Power Service
1401 Mercantile Court
Plant City, FL 33563
(813) 752-6550
matt.rice@resapower.com
www.resapower.com
Matt Rice
RESA Power Service
6268 Route 31
Cicero, NY 13039
(315) 699-5563
art.mcmanus@resapower.com
Art McManus
RESA Power Service
#181-1999 Savage Road,
Vancouver, BC V6V OA5
(604) 303-9770
ralph.schmoor@resapower.com
Ralph Schmoor
RESA Power Service
3190 Holmgren Way
Green Bay, WI 54304
(920) 639-0742
kevin.carr@resapower.com
Kevin Carr
RESA Power Service
4552 Happy Valley Rd
Cave City, KY 42127
(612) 930-8365
matthew.stewart@resapower.com
Matthew Stewart
RESA Power Service
1010 N. Plaza Drive
Visalia, CA 93291
(559) 651-0141
sean.broderick@resapower.com
Sean Broderick
RESA Power Service
2443 W. 12th St. Suite #3
Tempe, AZ 85281
(480) 730-8871
brandon.carrasco@resapower.com
Brandon Carrasco
REV Engineering Ltd.
3236 - 50 Avenue SE
Calgary, AB T2B 3A3
(403) 287-0198
rdavidson@reveng.ca
www.reveng.ca
Jason Molstad
Rondar Inc.
333 Centennial Parkway North
Hamilton, ON L8E2X6
(905) 561-2808
rshaikh@rondar.com
www.rondar.com
Rajeel Shaikh
Rondar Inc.
9-160 Konrad Crescent
Markham, ON L3R9T9
(905) 943-7640
Saber Power Field Services, LLC
9841 Saber Power Ln
Rosharon, TX 77583-5188
(713) 222-9102
mtummins@saberpower.com
www.saberpowerfieldservices.com
Mitchell Tummins
Saber Power Field Services, LLC
9006 Western View
Helotes, TX 78023
(210) 444-9514
jnorsworthy@saberpower.com
www.saberpowerfieldservices.com
Jacob Norsworthy
Saber Power Field Services, LLC
4205 Longhorn Dr.
Alvarado, TX 76009
(682) 518-3676
buck.bilnoski@saberpower.com
www.saberpowerfieldservices.com
Wesley Osborne
Saber Power Field Services, LLC
433 Sun Belt Dr. SuiteC
Corpus Christi, TX 78408
(361) 452-1695
jnorsworthy@saberpower.com
www.saberpowerfieldservices.com
Jacob Norsworthy
Saber Power Field Services, LLC
6097 Old Jefferson Hwy
Geismar, LA 70734
(877) 912-9102
dreinmuller@saberpower.com
www.saberpowerfieldservices.com
Daniel Reinmuller
Saber Power Field Services, LLC
9672 IH-10
Orange, TX 77632
(346) 335-7011
wayne.rice@saberpower.com
www.saberpowerfieldservices.com
Wayne Rice
Saber Power Field Services, LLC
2611 S. County Road 1206
Midland, TX 79706
(877) 912-9102
jnorsworthy@saberpower.com
Jacob Norsworthy
Scott Testing, Inc.
245 Whitehead Rd
Hamilton, NJ 08619
(609) 689-3400
rsorbello@scotttesting.com
www.scotttesting.com
Russ Sorbello
Sentinel Power Services, Inc.
7517 E Pine St
Tulsa, OK 74115-5729
(918) 359-0350
vigneshpn@sentfs.com
www.sentfs.com
Vignesh Palanichamy
Shermco Industries
2425 E Pioneer Dr
Irving, TX 75061-8919
(972) 793-5523
info@shermco.com
www.shermco.com
Shermco Industries
112 Industrial Drive
Minooka, IL 60447-9557
(815) 467-5577
info@shermco.com
Shermco Industries
233 Faithfull Cr.
Saskatoon, SK S7K 8H7
(306) 955-8131
www.shermco.com
Shermco Industries
2231 E Jones Ave Ste A
Phoenix, AZ 85040-1475
(602) 438-7500
info@shermco.com
Shermco Industries
1711 Hawkeye Dr.
Hiawatha, IA 52233
(319) 377-3377
info@shermco.com
www.shermco.com
Shermco Industries
1705 Hur Industrial Blvd
Cedar Park, TX 78613-7229
(512) 267-4800
info@shermco.com
www.shermco.com
Shermco Industries
7015-8 St NE
Calgary, AB T2E 8A2
(403) 769-9300
www.shermco.com
Shermco Industries
5145 Beaver Dr
Johnston, IA 50131
(515) 265-3377
info@shermco.com
www.shermco.com
Shermco Industries
4510 South 86th East Ave.
Tulsa, OK 74145
(918) 234-2300
info@shermco.com
www.shermco.com
Shermco Industries
1375 Church Avenue
Winnipeg, MB R2X 2T7
(204) 925-4022
www.shermco.com
Shermco Industries
1033 Kearns Crescent
RM of Sherwood, SK S4K 0A2
(306) 949-8131
Shermco Industries
33002 FM 2004
Angleton, TX 77515-8157
(979) 848-1406
info@shermco.com
www.shermco.com
Shermco Industries
1355 Central Parkway S #700
San Antonio, TX 78232
(210) 392-9175
info@shermco.com
www.shermco.com
Shermco Industries
3731 - 98 Street
Edmonton, AB T6E 5N2
(780) 436-8831
www.shermco.com
Shermco Industries
417 Commerce Street
Tallmadge, OH 44278
(614) 836-8556
info@shermco.com
Shermco Industries
3807 S Sam Houston Pkwy W
Houston, TX 77053
(281) 835-3633
info@shermco.com
Shermco Industries
7050 S.109th Ave
La Vista, NE 68128
(402) 933-8988
info@shermco.com
Shermco Industries
1301 Hailey St.
Sweetwater, TX 79556
(325) 236-9900
info@shermco.com
www.shermco.com
Shermco Industries
2901 Turtle Creek Dr.
Port Arthur, TX 77642
(409) 853-4316
info@shermco.com
www.shermco.com
Shermco Industries
5145 NW Beaver Dr.
Johnston, IA 50131
(515) 265-3377
info@shermco.com
www.shermco.com
Shermco Industries
998 E. Berwood Ave.
Saint Paul, MN 55110
(651) 484-5533
info@shermco.com
www.shermco.com
Shermco Industries
37666 Amrhein Rd
Livonia, MI 48150
(734) 744-4594
NETA ACCREDITED COMPANIES Setting the Standard
132 • WINTER 2022 NETA ACCREDITED COMPANIES
NETA ACCREDITED COMPANIES Setting the Standard
Shermco Industries
2080 West Kenny Drive
Gonzales, LA 70737
(225) 647-9301
info@shermco.com
Shermco Industries
7136 Weddington Rd #128
Concord, NC 28027
(910) 568-1053
info@shermco.com
Shermco Industries
9475 Old Hwy 43
Creola, AL 36525
(251) 679-3224
info@shermco.com
Shermco Industries
5211 Linbar Dr. Suite 507
Nashville, TN 37211
(615) 928-1182
info@shermco.com
Aaron Andrews
Shermco Industries
#307-2999 Underhill Ave
Burnaby, BC V5A 3C2
(972) 793-5523
Brad Wager
Shermco Industries
1411 Twin Oaks Street
Wichita Falls, TX 76302
(972) 793-5523
Trey Ingram
Shermco Industries
11800 Jordy Rd.
Midland, TX 79707
(972) 793-5523
Trey Ingram
Shermco Industries
6551 S Revere Parkway
Suite 275
Centennial, CO 80111
(877) 456-1342
www.shermco.com
Shermco Industries
2970 Calcasieu Industrial Dr.
Suite 100
Sulphur, LA 70665
(337) 287-9024
Richard Landry
Sigma C Power Services, LLC
200 Friberg Parkway, Ste 3000B
Westborough, MA 01581
617-938-3912
jim@sig-c.com
Jim Cialdea
Sigma Six Solutions, Inc.
2200 W Valley Hwy N Ste 100
Auburn, WA 98001-1654
(253) 333-9730
jwhite@sigmasix.com
www.sigmasix.com
John White
Sigma Six Solutions, Inc.
www.sigmasix.com
Quincy, WA 98848
(253) 333-9730
Chris Morgan
Southern New England Electrical Testing, LLC
3 Buel St Ste 4
Wallingford, CT 06492-2395
(203) 269-8778
www.sneet.org
John Stratton
Star Electrical Services 
& General Supplies, Inc.
PO Box 814
Las Piedras, PR 00771
(787) 716-0925
ahernandez@starelectricalpr.com
www.starelectricalpr.com
Aberlardo Hernandez
Taifa Engineering Ltd.
9734-27 Ave NW
Edmonton, AB T6N 1B2
(780) 405-4608
fsteyn@taifaengineering.com
Taurus Power & Controls, Inc.
9999 SW Avery St
Tualatin, OR 97062-9517
(503) 692-9004
powertest@tauruspower.com
www.tauruspower.com
Rob Bulfinch
Taurus Power & Controls, Inc.
8714 South 222nd St. STE A
Kent, WA 98031
(425) 656-4170
powertest@tauruspower.com
www.taruspower.com
TAW Technical Field Services, Inc.
5070 Swindell Rd
Lakeland, FL 33810-7804
(863) 686-5667
www.tawinc.com
Tidal Power Services, LLC
4211 Chance Ln
Rosharon, TX 77583-4384
(281) 710-9150
monty.janak@tidalpowerservices.com
www.tidalpowerservices.com
Monty Janak
Tidal Power Services, LLC
8184 Highway 44 Ste 105
Gonzales, LA 70737-8183
(225) 644-8170
darryn.kimbroug@tpsgse.com
www.tidalpowerservices.com
Darryn Kimbrough
Tidal Power Services, LLC
1056 Mosswood Dr
Sulphur, LA 70665-9508
(337) 558-5457
rich.mcbride@tidalpowerservices.com
www.tidalpowerservices.com
Rich McBride
Tidal Power Services, LLC
1806 Delmar Drive
Victoria, TX 77901
(281) 710-9150
kelly.grahmann@tps03.com
Kelly Grahmann
Tony Demaria Electric, Inc.
131 W F St
Wilmington, CA 90744-5533
(310) 816-3130
neno@tdeinc.com
www.tdeinc.com
Neno Pasic
Utilities Instrumentation Service, Inc.
2290 Bishop Cir E
Dexter, MI 48130-1564
(734) 424-1200
gary.walls@UIScorp.com
www.uiscorp.com
Gary Walls
Utilities Instrumentation Service - Ohio, LLC
998 Dimco Way
Centerville, OH 45458
(937) 439-9660
www.uiscorp.com
Utility Service Corporation
PO Box 1471
Huntsville, AL 35807
(256) 837-8400
accounting@utilserv.com
www.utilserv.com
Accounts Payable
VISTAM, Inc.
2375 Walnut Ave
Signal Hill, CA 90755
(562) 912-7779
ulyses@vistam.com
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134 • WINTER 2022 ADVERTISERS
INDEPENDENT NETA 
ACCREDITED COMPANIES
Absolute Testing Services Inc. . . . . . . . . . . . . . . . . . . 93
American Electrical Testing Co.  . . . . . . . . . . . . . . . . 37
Apparatus Testing and Engineering . . . . . . . . . . . . . 11
Burlington Electrical Testing . . . . . . . . . . . . . . . . . . 12
Eastern High Voltage . . . . . . . . . . . . . . . . . . . . . . . 123
Electrical Energy Experts, Inc. . . . . . . . . . . . . . . . . . 99
Elemco Services Inc. . . . . . . . . . . . . . . . . . . . . . . . . 85
EnerG Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Industrial Electric Testing, Inc. . . . . . . . . . . . . . . . . . 63
JET Electrical Testing . . . . . . . . . . . . . . . . . . . . . . . . 39
North Central Electric, Inc. . . . . . . . . . . . . . . . . . . . 51
Potomac Testing, Inc. . . . . . . . . . . . . . . . . . . . . . . . . 13
Power Products & Solutions, Inc. . . . . . . . . . . . . . . 112
Power Systems Testing Co. . . .. . . . . . . . . . . . . . . . 122
Saber Power Field Services, LLC . . . . . . . . . . . . . . . 107
Scott Testing Inc.  . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Shermco Industries . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Taurus Power & Controls Inc. . . . . . . . . . . . . . . . . . 99
Tony DeMaria Electric, Inc.  . . . . . . . . . . . . . . . . . . 34
ADVERTISERS
MANUFACTURERS AND 
OTHER SERVICE PROVIDERS 
AEMC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
Aero Tech Laboratories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
BCS Switchgear . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
Belyea Company . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
Bullock Breakers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
Doble Engineering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111
ETI Precision . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
HV Diagnostics, Inc. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
High Voltage Electric Service, Inc. . . . . . . . . . . . . . . . . . . . . . 51
High Voltage Inc. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
Intellirent . . . . . . . . . . . . . . . . . . . . . . . . . . . Inside Front Cover
National Switchgear . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133
NETA ANSI/NETA ETT . . . . . . . . . . . . . . . . . . . . . . . . . . 119
NETA Alliance Partnership . . . . . . . . . . . . . . . . . . . . . . . . . . 32
NETA Handbook Series III . . . . . . . . . . . . . . . . . . . . . . . . . 113
NETA Industry Alliance . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124
NETA PowerTest 2023 Register Now . . . . . . . . . . . . . . . . . . . 53
NETA PowerTest 2023 Call for Exhibitors . . . . . . . . . . . . . . . 75
NETA PowerTest 2023 Call for Sponsors . . . . . . . . . . . . . . 106
OMICRON electronics Corp, USA . . . . . . . . . . . . . Back Cover
Protec Equipment Resources . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Raytech USA Inc. . . . . . . . . . . . . . . . . . . . . . . Inside Back Cover
Sertec Relay Services . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Team UIS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Technitrol, Inc. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Thyritronics, Inc. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
Utility Relay Company . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
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AD22039-RST-NETA-8.5x11in-ENU.indd 1AD22039-RST-NETA-8.5x11in-ENU.indd 1 9/13/2022 10:22:08 AM9/13/2022 10:22:08 AMElectrical Safety in the Workplace.
This was the step in the revision process where 
the 70E Technical Committee meets to review 
Public Comments as well as NFPA Correlating 
Committee comments related to proposed 
changes to the standard. The NFPA consensus 
process is very thorough, allowing full public 
input and comment on committee actions.
As a reminder, the standards revision process 
is generally a four-step process, and NFPA 
provides a summary.
Step One: Public Input 
Following the publication of the current 
edition of an NFPA standard, the development 
of the next edition begins, starting with the 
acceptance of Public Input for changes to the 
document. 
After receiving input from the public, a First 
Draft meeting of the Technical Committee is 
held, and the committee considers the input 
and provides a response. The responses are 
balloted, and a report of the ballot and any 
committee comments is published in the form 
NFPA 70E, 
2024 EDITION: 
SECOND DRAFT 
MEETING 
Figure 1: NFPA Standards Process COURTESY OF NFPA
NETAWorld • 15NFPA 70E, 2024 EDITION: SECOND DRAFT MEETING 
THE NFPA 70E AND NETA
of a First Draft report. This is the beginning of 
change to what will become the newly formed 
standard content. 
Step Two: Public Comment 
After the first draft report is published, anyone 
may submit a Public Comment in the form of 
suggested text on the First Draft. From here, 
the Technical Committee calls a Second Draft 
meeting to review any suggested comments 
from the public. These actions are recorded 
and balloted by the Technical Committee, and 
a Second Draft report is generated for review 
by the public.
*Note: This is where we currently are in the NFPA 
70E, 2024 Edition, revision process.
Step Three: NFPA 
Technical Meeting
Following completion of the Public Input 
and Public Comment stages, there is further 
opportunity for debate and discussion of 
any unresolved issues at the NFPA Technical 
Meeting held during the NFPA Conference & 
Expo each June. The next meeting will be held 
in Las Vegas, June 19–23, 2023.
Prior to the meeting, if someone still has 
an issue they want to bring forth, they must 
file a notice of intent to make a motion or 
NITMAM.
A NITMAM is a proposed amending motion for 
NFPA membership consideration and debate at 
PHOTO: WWW.SHUTTERSTOCK.COM/G/VIBLY
16 • WINTER 2022 NFPA 70E, 2024 EDITION: SECOND DRAFT MEETING 
THE NFPA 70E AND NETA
the NFPA Technical Meeting. These motions are 
attempts to amend the committee’s recommended 
text published as the Second Draft.
Allowable motions include:
• Motions to accept Public Comments in 
whole or in part
• Motions to reject a Second Revision 
(change accepted by the committee) in 
whole or part
• Motions to accept committee comments 
in whole or in part
• Motions to reject a Second Revision 
(change accepted by the committee) in 
whole or part and can include the related 
portions of First Revisions
In addition, under certain specified instances, 
motions can be made to return an entire NFPA 
Standard to the committee. If successful, the 
Standard will not be issued and will be returned 
to the committee to continue its work.
Step Four: Council Appeals and 
Issuance of Standard
One of the primary responsibilities of the 
NFPA Standards Council, as the overseer of the 
NFPA standards development process, is to act 
as the issuer of NFPA standards.
The Standards Council considers any appeals 
that have been made, and after deciding all 
appeals related to a standard, the Standards 
Council, if appropriate, proceeds to issue the 
document as an official NFPA standard. 
The new NFPA standard becomes effective 20 
days after the Standards Council’s action of 
issuance. In the case of NFPA 70E, that most 
likely will be in July 2023.
An important note: When NFPA 70E is issued 
and an effective date is determined, this is the 
date at which the standard is applicable and will 
supersede all previous editions. Because it is a work 
practices document, the effective date of the new 
standard constitutes the rules and requirements 
going forward, so it’s important to understand any 
changes that were made to the new standard.
HIGHLIGHTS OF THE 
SECOND DRAFT MEETING
Several hundred Public Comments were 
processed during the recent Second Draft 
meeting. Some were technical; some were related 
to structure in accordance with NFPA’s Style 
Manual; some were directed to the Technical 
Committee by NFPA’s Correlating Committee.
All of them received thorough review, 
analysis, and discussion, which reinforces 
the effectiveness of the consensus process, 
ultimately leading to the production of the 
revised standard.
Global Change: Electric Shock
To ensure consistent use of the term and as a 
global change, any time* the word “shock” was 
used, we added the word “electric” in front of it.
* There are two terms — “hearing protection 
boundary” and “lung protection boundary” 
— where the definitions use “shock” in a 
Figure 2: Electric Shock
NETAWorld • 17NFPA 70E, 2024 EDITION: SECOND DRAFT MEETING 
THE NFPA 70E AND NETA
different context, i.e., “shock wave.” These 
were not changed.
Section No. 90.5(C) Explanatory 
Material
A sentence was added to 90.5(C) to clarify the 
use of other standards as a reference:
Unless the standard reference includes a date, the 
reference is to be considered as the latest edition of 
the standard.
Point being, unless indicated otherwise, always 
consider the latest edition of any referenced 
standard when using the 70E!
Article 100 Definitions: Electrically 
Safe Work Condition
In one of the most important definitions in the 
standard, a slight change was made with regard 
to terminology around testing for the absence 
of voltage. The words “to verify” were replaced 
with “for” to be consistent with how the process 
of establishing and verifying an electrical safe 
work condition is described in120.6(7). It is a 
small, but important, change! 
Electrically Safe Work Condition. 
A state in which an electrical conductor or circuit 
part has been disconnected from energized parts, 
locked/tagged in accordance with established 
standards, tested to verify for the absence of 
voltage, and, if necessary, temporarily grounded 
for personnel protection.
Article 100 Definitions: 
Boundaries Abound
There are five boundary definitions to be aware 
of:
 1. Arc flash boundary
 2. Hearing protection boundary*
 3. Limited approach boundary
 4. Lung protection boundary*
 5. Restricted approach boundary
*The hearing and lung protection boundaries 
are referenced in Article 360, Safety-Related 
Requirements for Capacitors.
Article 105 Application of Safety-
Related Work Practices and 
Procedures
Besides adding the words “Application of ” 
to the title, the purpose of Section 105 was 
updated to the following:
105.2 Purpose. 
These practices and procedures are intended to 
provide for employee safety reduce the risk for 
employees relative to electrical hazards in the 
workplace.
Figure 3: Absence of Voltage
18 • WINTER 2022 NFPA 70E, 2024 EDITION: SECOND DRAFT MEETING 
THE NFPA 70E AND NETA
Simply put — to save lives and avoid injury! 
NFPA 70E is a resource to help companies 
and employees reduce exposure to risks and 
reduce occupational injuries and fatalities. 
It was created to provide a document that 
meets Occupational Safety and Health 
Administration (OSHA) requirements and is 
entirely consistent with the NEC and other 
applicable publications.
NFPA 70E is a great resource to keep your 
employees safe as we deal with the hazards 
of electricity. So buy the new edition when it 
comes out and familiarize yourself with the 
words and terms, new and existing, of this very 
important safety standard.
And before you work on it — turn it off!
Ron Widup is the Vice Chairman, Board 
of Directors, and Senior Advisor, Technical 
Services for Shermco Industries and has 
been with Shermco since 1983. He is a 
member of the NETA Boardof Directors 
and Standards Review Council; a Principal 
member of the Technical Committee on 
Standard for Electrical Safety in the Workplace (NFPA 70E); 
Principal member of the National Electrical Code (NFPA 
70) Code Panel 11; Principal member and Chairman of the 
Technical Committee on Standard for Competency of Third-
Party Evaluation Bodies (NFPA 790); Principal member and 
Chairman of the Technical Committee on Recommended 
Practice and Procedures for Unlabeled Electrical Equipment 
Evaluation (NFPA 791); a member of the Technical 
Committee Recommended Practice for Electrical Equipment 
Maintenance (NFPA 70B); and Vice Chair for IEEE Std. 
3007.3, Recommended Practice for Electrical Safety in 
Industrial and Commercial Power Systems. He is a member 
of the Texas State Technical College System (TSTC) Board 
of Regents, a NETA Certified Level 4 Senior Test Technician, 
State of Texas Journeyman Electrician, a member of the IEEE 
Standards Association, an Inspector Member of the International 
Association of Electrical Inspectors, and an NFPA Certified 
Electrical Safety Compliance Professional (CESCP).
This update was made so that describing 
the purpose of the standard in terms of risk 
reduction is consistent with the risk assessment 
and control requirements of the document.
Section 110.4(A) Electrical Safety 
Training (1) Qualified Person
Text was deleted in this section as the wording 
was redundant. 
(b) A person shall be permitted to be qualified for 
some equipment or tasks and not others.
Section 250.2 Maintenance 
Requirements for Personal Safety 
and Protective Equipment
The term “hot sticks,” which arguably is a slang 
term, was clarified, and the term “live line 
tools” is used throughout the standard. 
(2) Hot sticks (live line tools)
The addition of “live line tools” was added to 
include the correct technical term.
NEC STYLE MANUAL 
COMPLIANCE
There were many revisions to the standard 
to correct wording and terminology so that 
it complies with 2020 NEC Style Manual. 
It is important that sentence structure and 
organization is consistent between NFPA 
standards, and many editorial corrections were 
made to the 2024 edition to comply with the 
Style Manual.
SUMMARY: WHY DO WE 
CARE ABOUT NFPA 70E?
Many subject matter experts and volunteers 
work to develop consensus standards, and the 
rules, procedures, and guidance outlined in 
NFPA 70E are very purposeful and structured, 
allowing for public input and change. But why 
do we care?
www.shermco.com l 888-SHERMCO
The largest NETA Accredited technical group 
in the industry, that never compromises safety.
One Line. One Company.
As North America’s largest independent electrical testing company, our 
most important Company core value should come as no surprise: assuring 
the safety of our people and our customer’s people. First and foremost.
Our service technicians are NETA-certified and trained to comply and 
understand electrical safety standards and regulations such as OSHA, 
NFPA 70E, CSA Z462, and other international guidelines. Our entire 
staff including technicians, engineers, administrators and management is 
involved and responsible for the safety of our co-workers, our customers, 
our contractors as well as our friends and families.
Our expertise goes well beyond that of most service companies. From 
new construction to maintenance services, acceptance testing and 
commissioning to power studies and rotating machinery service and repair, 
if it’s in the electrical power system, up and down the line, Shermco does it.
20 • WINTER 2022 CONDITION MONITORING: GENERATOR STATOR GROUND CAPACITANCE
RELAY COLUMN
BY STEVEN TURNER, Arizona Public Service
This article demonstrates how to use numerical generator protection 
relay profile capability to measure the stator ground capacitance of a 
large combustion turbine generator. The measurements are taken when 
the generator is on-line and running at full speed while the generator 
breaker is open (no load), and again during startup as the exported power 
increases. 
The stator capacitance-to-ground (Figure 1) is 
indicative of conductive moisture and dirt in 
and around the stator insulation system. The 
apparent conductive surface area of winding 
insulation grows as contaminants build up. 
CONDITION MONITORING: 
GENERATOR STATOR 
GROUND CAPACITANCE
Crf
Crf
Crf
Crf
Rotor
Frame
Csr
Csr
Csr
Csf
Csf
Csf
Stator
Winding
+
–
+
VG3 ITIT
IR IC
IT
Cg/2 + CX 3V03/3
Cg/2
VN3 ZN
VN3 3RNpri
–
+
–
+
–
Figure 1: Stator Winding Capacitance-to-Ground
The value of the variable plate can be measured 
and trended over time as the change in stator 
capacitance-to-ground (Cg). 
Compare the initial (baseline) measurement 
to future recorded values. A significant rise in 
magnitude may indicate one of the following 
conditions:
• Internal contamination
• Moisture infiltration
• Problem with the circuit cables connected 
to the machine
THIRD HARMONIC 
VOLTAGE
Generators produce varying amounts of 
third harmonic voltage in addition to the 
fundamental. The stator winding pitch — the 
distance between the two sides of each loop 
relative to the distance between the rotor poles 
— influences the amount of third harmonic 
voltage produced. The amount of third 
harmonic voltage generated by the machine 
also varies with loading. Changes in both real 
and reactive power alter the amount of third 
harmonic voltage produced.
NETAWorld • 21CONDITION MONITORING: GENERATOR STATOR GROUND CAPACITANCE
RELAY COLUMN
Figure 2 illustrates the third harmonic circuit 
for a large unit connected generator that is 
high-impedance grounded. The generator step-
up (GSU) transformer low-side delta winding 
provides third harmonic isolation from the 
transmission system. Note that it is assumed 
the low-side generator breaker is open and the 
machine is running at full speed (that is, no 
load) for the purpose of the calculations.
The distributed Cg is represented as an 
equivalent pi-section divided between the 
system and neutral sides of the stator windings. 
The system side has additional external 
capacitance (Cx) from the surge capacitor, 
isophase bus, and auxiliary transformer. 
Note that only the capacitance of the surge 
capacitor is considered on the system side for 
the following calculations since it is assumed 
that the low-side generator breaker is open. The 
neutral resistor (RN) is reflected to the primary.
3V03 and VN3 are measured by the generator 
relay, while VG3 is calculated using those two 
values. Note that the terms 3V03 and 3V0Z3 
are used interchangeably.
VG3 ≡ Total third harmonic voltage (source)
3V03 ≡ Third harmonic voltage drop across 
terminal capacitance
VN3 ≡ Third harmonic voltage drop across ZN
Third Harmonic Voltage Profile
Figure 3 shows the third harmonic voltage 
profile captured by the generator protection 
relay during startup.
Table 1: Third Harmonic Voltage Profile
LOAD PF 3V0Z3M VN3M VG3M |3V0Z3| arg(3V0Z3) |VN3| arg(VN3) VG3M P
MW LEAD/LAG V Pri V Pri V Pri V sec degrees V sec degrees V Pri MW
NO LOAD NA 157.5 90.5 143 1.26 145.5 1.358 147.8 143 0
17 0.9449 116.5 109.9 148.8 0.932 -179 1.649 178.5 148.8 17
60.6 0.9962 217.5 201.1 273.6 1.793 -117.3 3.016 -123.9 275.4 60.6
63.3 0.9965 226.3 208 283.4 1.811 -114.5 3.12 -121.6 283.1 63.3
89.7 0.9973 280.9 252.6 346.2 2.247 -96.5 3.788 -104.4 345.5 89.7
90.2 0.9981 286.1 252.9 348.3 2.289 -96.6 3.794 -104.8 347.6 90.2
106.7 0.9985 313.1 276.3 380.7 2.505 -87.9 4.144 -96.2 379.9 106.7
145.5 0.9998 366.5 314.6 436.7 2.932 -73 4.718 -81.5 435.8 145.5
148.5 0.9989 374.9 317.7 442.6 2.999 -70.7 4.765 -79.2 441.7 148.5
149 0.9948 371.5 318.8 444.1 3.009 -69.2 4.781 -78 443.1 149
Crf
Crf
Crf
Crf
Rotor
Frame
Csr
Csr
Csr
Csf
Csf
Csf
Stator
Winding
+
–
+
VG3 ITIT
IR IC
IT
Cg/2 + CX 3V03/3
Cg/2
VN3 ZN
VN3 3RNpri
–
+
–
+
–
Figure 2: Stator Winding Capacitance-to-Ground
Figure 3: Third Harmonic Voltage Profile Captured During Startup22 • WINTER 2022 CONDITION MONITORING: GENERATOR STATOR GROUND CAPACITANCE
RELAY COLUMN
Table 1 shows the third harmonic voltage 
profile captured by the generator protection 
relay during a startup.
CALCULATIONS
Figure 4 represents the total third harmonic 
current flow through the neutral impedance 
ZN, which is the parallel combination of the 
neutral resistor RN and stator capacitance-to-
ground (Cg/2). IT is the total current while IR is 
the resistive component and IC is the capacitive 
component.
Next, calculate the third harmonic neutral voltage VN3 dropped across the neutral grounding 
resistor (NGR) and stator capacitance-to-ground:
Figure 4: Third Harmonic Neutral Circuit
Crf
Crf
Crf
Crf
Rotor
Frame
Csr
Csr
Csr
Csf
Csf
Csf
Stator
Winding
+
–
+
VG3 ITIT
IR IC
IT
Cg/2 + CX 3V03/3
Cg/2
VN3 ZN
VN3 3RNpri
–
+
–
+
–
First, calculate the circuit impedance to solve 
for Cg:
(neutral side reactance)
(system side reactance)
(third harmonic frequency)
(surge capacitance)
RNpri = NG
2•RN
NG = Grounding transformer turns ratio (66.67)
[1]
[2]
NETAWorld • 23CONDITION MONITORING: GENERATOR STATOR GROUND CAPACITANCE
RELAY COLUMN
Equation [3] solves for Cg, the stator capacitance-to-ground.
RN = Neutral grounding resistor (0.25 W)
RNpri = (66.67)2•(0.25 Ω) = 1111.222 Ω primary
Set equations [1] and [2] equal and solve for ZCg.
[3]
RELAY COLUMN
CONCLUSION
This article demonstrates how to use a 
numerical generator protection relay profile 
capability to measure the stator ground 
capacitance of a large combustion turbine 
generator. Increases in the measurement over 
time are indicative of contamination buildup 
that provide guidance on when maintenance 
should be performed. 
Steve Turner is in charge of system protection 
for the Fossil Generation Department 
at Arizona Public Service Company in 
Phoenix. Steve worked as a consultant for 
two years, and held positions at Beckwith 
Electric Company, GEC Alstom, SEL, and 
Duke Energy, where he developed the first 
patent for double-ended fault location on overhead high-voltage 
transmission lines and was in charge of maintenance standards 
in the transmission department for protective relaying. Steve has 
BSEE and MSEE degrees from Virginia Tech University. Steve is 
an IEEE Senior Member and a member of the IEEE PSRC, and 
has presented at numerous conferences.
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26 • WINTER 2022 MEDIUM-VOLTAGE CABLE INSTALLATION ISSUES
IN THE FIELD
BY MOSE RAMIEH, CBS Field Services
Properly installed and maintained medium-voltage cable is 
highly reliable, and when properly installed, there is little or 
no maintenance to be performed. Yes, you should keep the 
terminations clean, and yes, you can perform a periodic VLF with 
tan delta or partial discharge test to trend degradation over the years. 
However, in my experience, the No. 1 reason cables fail is poor 
installation practices. Many factors that can impact the quality 
of cable installation come into play.
WORKING AROUND 
DESIGN OF THE GEAR 
I still remember one of the first medium-voltage 
cable faults I cleaned up. It was at a hospital that 
had recently modified the system to add a new 
medium-voltage air switch lineup. The installation 
was in an existing room and required that the 
conductors enter the switches from the top of the 
gear. While top-entry gear is nothing new, in this 
situation, the switchgear as built and delivered to 
the site was designed to be bottom-fed. 
Now, who was to blame for this design issue 
isn’t relevant to the story, but what happened 
next was that a well-intentioned electrical 
contractor found a way around (or should I 
say through) the switchgear design issue. They 
decided to route the medium-voltage cables 
between the switchgear bus to the termination 
point at the bottom of the switch (see my 
wonderful sketch in Figure 1).
MEDIUM-
VOLTAGE CABLE 
INSTALLATION 
ISSUES
Figure 1: Sketch of Bottom-Fed Switch
NETAWorld • 27MEDIUM-VOLTAGE CABLE INSTALLATION ISSUES
IN THE FIELD
The problem with this solution is that it places 
a grounded plane (the cable’s shield) near the 
energized bus work. To further illustrate the 
contractor’s misconception, when I asked why 
he thought it was acceptable to route the cable 
in this manner, his response was, “Well, isn’t 
that insulated cable rated for the voltage?” 
Where was the NETA testing company in this 
situation, you might be asking. 
A couple of things to consider:
 1. Technicians commonly show up to test 
cables and nothing else. If this is the task, 
their vision of the remainder of the power 
system might not be in focus. They have a 
blind spot to other portions of the system.
 2. Were the cables routed through the 
bus before or after the test? If they 
were routed in that manner at the time 
of testing, then we could argue that 
the technician should have caught this 
glaring issue. Of course, that assumes the 
technician knows enough about cable 
construction and that he or she notifies 
the contractor of the issue and stands firm 
against energizing the system.
 3. Finally, there is the all-too-human factor 
of “doing the best we can to make it 
work.” It’s well-intentioned, tragically 
flawed, and easier than suffering the 
consequences of stopping the job to find 
a better solution — at least until the cable 
causes a switchgear failure.
Another equipment design issue that can create 
challenges in making proper terminations 
is pad-mounted equipment that limits the 
distance between the concrete floor and the 
connection point. This leads to a choice of 
working in an uncomfortable, hunched-over 
body position or pulling the cable outside the 
enclosure where additional length (slack) then 
must be routed and wrapped back into the 
gear. This creates problems with bend radius 
and ensuring that the slack remains clear of 
Figure 2: Metering Cabinet 
28 • WINTER 2022 MEDIUM-VOLTAGE CABLE INSTALLATION ISSUES
IN THE FIELD
energized components as noted in the previous 
example.
The pad-mounted utility metering cabinet 
in Figure 2 is an example of a challenging 
situation I faced in Florida. While there seemed 
to be plenty of room to make the cables up, it 
proved very difficult to route the 750 MCM 
cable to the various termination points from 
the conduit entries. Had the designer of the 
installation been aware of this challenge, a 
trough could have been built/formed under the 
switch (Figure 3) allowing more movement and 
easier sweeps of this very stiff cable. 
Figure 4 is another example of a poorly 
designed plan for how cables would be 
terminated. Note that there is literally zero 
room to make the Pfister terminations required 
on this piece of gear. I wish I knew how this 
cable was finally terminated, but I leftthis 
project long before the cables were completed.
MANAGING EXTRA CABLE 
LENGTH
There is also the “let’s leave some slack in case 
I make a mistake in my cable cutbacks” issue. 
While cable terminators are human and do 
make mistakes, they should be skilled (if not 
certified) craftsmen in this specialized talent. 
This craftmanship extends to being able to 
plan their work and foresee and manage the 
challenges in varied installation situations. To 
be clear, leaving some slack is a fine plan, so 
long as it doesn’t create issues with managing 
the extra cable. The pad mount transformer in 
Figure 5 is a perfect example of extra slack gone 
horribly wrong.
INSTALLATION PRACTICES
One of the worst installations I’ve even seen 
was at a chemical plant that was adding 
additional capacity. Our team was hired by 
the electrical contractor to test the new cable 
installations. Our initial test of the cables 
indicated a termination issue. The issue was 
sufficiently bad to trip the VLF test set before 
getting to the withstand voltage. This was 
followed by an uncomfortable conversation 
with the contractor that they were going to 
need to pull new cable to correct the issue.
As with any failed cable test, the first thing 
to check is the cutbacks of the cable made 
during the process of installing terminations. 
Removing terminations costs money and time, 
and if you are wrong, you can expect you will 
be asked to pay for those losses. In this case, 
Figure 3: Trough Offering Additional Space 
to Turn and Route Cables
Figure 4: No Room for Terminations
NETAWorld • 29MEDIUM-VOLTAGE CABLE INSTALLATION ISSUES
IN THE FIELD
we were not wrong. Figure 6 clearly shows the 
poor installation made by an inexperienced and 
rushed electrician. 
Note that this photo was taken after surgically 
removing the terminations to avoid any 
alteration of what we discovered. The defects 
were numerous and included:
• Poor cutbacks 
• Deep cuts into the cable installation at 
the semi-con cutback
• Failure to install the constant tension 
spring, which allowed the braided shield 
to be pulled out of place toward the cable 
lug when the core was removed from the 
stress cone
Admittedly, it is rare to find a cable this poorly 
constructed, but I assure you that it can and 
does happen. 
WATER INTRUSION IN THE 
CONDUCTOR
Another rare installation issue technicians need 
to be aware of involves outdoor terminations, 
which are typically connected to pole-mounted 
cutout switches with mechanical lugs. An 
inexperienced terminator who is not provided 
with all the proper materials may leave bare 
conductors exposed for installation into the lug 
(Figure 7). On the surface, you may not see an 
issue with this practice, but consider that this 
Figure 5: Excessive Slack
Figure 6: Exceptionally Poor Cutbacks
30 • WINTER 2022 MEDIUM-VOLTAGE CABLE INSTALLATION ISSUES
IN THE FIELD
Figure 7: Cable Allowing Water Intrusion
Figure 8: Mismatched Ground Shields
outdoor installation is exposed to rain. Over 
the course of time, rain will migrate into the 
cable conductor.
The water will build up and create a water 
column going up the pole, and this water 
column is capable of building up enough 
pressure to push loadbreak elbows off their 
bushings at the pad-mounted equipment that 
is often located at the other end. 
Another situation I encountered was on 
a deadbreak connection. A similar bare 
conductor installation at the pole pushed water 
into the deadbreak. When the water froze, it 
expanded the deadbreak to the point that it 
failed catastrophically.
ADDING NEW CABLES 
TO AN EXISTING 
INSTALLATION
In a recent situation, new cables were added 
to connect an existing switch to a new switch 
being installed in an expansion. The old 
termination required a longer cutback to the 
cable shield than the new termination. On the 
surface, it didn’t seem like a big issue. However, 
this mismatch of the ground shield (Figure 
8) placed a grounded point adjacent to the 
unshielded portion of the existing cable.
Over time, the ground shield on the new 
cables will create electrical stresses that 
could eventually cause a failure of the 
existing cable. The solution to this issue is 
to modify the new cable cutbacks so that the 
shield grounds are at the same position (red 
arrow). The additional exposed insulation 
this change creates in the new cable can then 
be wrapped with silicon splicing tape (blue 
arrow) to complete the moisture barrier at 
the end of the cable. 
CONCLUSION
If you want to create reliable medium-voltage 
cable systems, learn from these life lessons: 
• Never allow medium-voltage cable to be 
adjacent to energized components.
• Avoid excessive slack in cable systems.
IN THE FIELD
• Plan ahead for cable sweep and bend 
radius management.
• Trust your test equipment. 
• Properly install terminations in 
accordance with the manufacturer’s 
instructions.
And as Dad always said, “Keep it clean, read 
the instructions, measure twice, and keep it 
clean.” 
Mose Ramieh is Vice President, Business 
Development at CBS Field Services. A 
former Navy man, Texas Longhorn, Vlogger, 
CrossFit enthusiast, and slow-cigar-smoking 
champion, Mose has been in the electrical 
testing industry for 24 years. He is a Level 
IV NETA Technician with an eye for 
simplicity and utilizing the KISS principle in the execution of 
acceptance and maintenance testing. Over the years, he has held 
positions at four companies ranging from field service technician, 
operations, sales, business development, and company owner. To 
this day, he claims he is on call 24/7/365 to assist anyone with 
an electrical challenge. That includes you, so be sure to connect 
with him on the socials.
 
• Full Member of the InterNational Electrical Testing Association (NETA)
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NETAWorld • 33PROGRAMS, POLICIES, MANUALS, PROCEDURES, AND TRAINING
SAFETY CORNER
BY PAUL CHAMBERLAIN, American Electrical Testing Co.
Several regulatory agencies direct which documents are required 
when performing a company’s tasks. In some cases, federal and state 
requirements must be adhered to for the same task or hazard.For 
example, in the United States, the U.S. Environmental Protection 
Agency (US EPA) and state environmental agencies such as the 
Massachusetts Department of Environmental Protection (MA DEP) 
regulate potential environmental impacts that can occur during 
performance of a task. For workplace safety, requirements are handed 
down from the U.S. Department of Labor (DOL) and its sub-
department, the Occupational Safety and Health Administration 
(OSHA). Canada has its own version of OSHA — the Canadian 
Centre for Occupational Health and Safety, or CCOHS. 
PROGRAMS, POLICIES, 
MANUALS, PROCEDURES, 
AND TRAINING
PHOTO: © ISTOCKPHOTO.COM/PORTFOLIO/NATTAWITK
SAFETY CORNER
Currently, 22 U.S. states have their own state-
approved occupational safety agency with 
regulatory oversight over private business:
GUIDELINES
OSHA provides guides for developing safety 
programs. The format depends on whether the 
requirement is applicable to the specific work 
being performed. These guides can be found 
on the OSHA.gov website: https://www.osha.
gov/employers. Canadian employers regulated 
by CCOHS can find guidelines and samples at 
https://www.ccohs.ca/topics/legislation/programs/.
Before developing a program, policy, plan, 
or procedure — and the training that goes 
with them — it is important for a company 
to know the scope of work and where the 
work will occur, as the requirements change 
depending on work location. For example, 
U.S. work performed in a construction setting 
might not have the same requirements as 
work performed in a general industry setting. 
Additionally, not all OSHA requirements are 
applicable to a specific setting. For example, 
if the company performs entry into enclosed 
• Alaska
• Arizona
• California
• Hawaii
• Indiana
• Iowa
• Kentucky
• Maryland
• Michigan
• Minnesota
• Nevada
• New Mexico
• North Carolina
• Oregon
• Puerto Rico
• South Carolina
• Tennessee
• Utah
• Vermont
• Virginia
• Washington
• Wyoming
This article explores the typical safety 
documents required to comply with U.S. 
federal OSHA standards. Every company 
should familiarize itself with these requirements 
and comply with any other regulations that 
apply to their business.
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NETAWorld • 35PROGRAMS, POLICIES, MANUALS, PROCEDURES, AND TRAINING
SAFETY CORNER
spaces only, but does not enter into confined 
spaces that require a permit, the program 
should indicate that and training must include 
that information. The program would not 
need to cover entry into permit-requiring 
confined spaces, even though enclosed and 
confined spaces are found in the same OSHA 
regulation.
JOB HAZARD ANALYSIS
A job hazard analysis (JHA) is an important tool 
to analyze the work to be performed and the 
hazards associated with each step in performing 
the work. Companies should take the time 
to create JHAs to better understand which 
hazards their employees will encounter. In 
some instances, such as in construction, a JHA 
is required per OSHA. JHAs can be known 
by other names, such as a job safety analysis 
(JSA) or even just a hazard analysis (HA), but 
they all have essentially the same outcome: 
identification of known hazards associated 
with completion of a task. Pre-job briefs, if 
detailed enough, can be a suitable substitute 
for a JHA. To view a sample OSHA JHA, visit 
https://bit.ly/3fuz7Vf.
Once a JHA has been completed, known 
hazards will be identified. The completed 
JHA should be reviewed with all personnel 
performing the work. Once a hazard is 
identified, the appropriate OSHA or CCOHS 
regulation can aid in creating a program, policy, 
procedure, or training.
POLICIES
Policies can be short, sweet, and to the point. 
Think of these as a description sheet for a task 
or hazard. They are a position statement on 
how a company will address an issue, whether 
it is safety, environmental, procedural, or 
even human resource-related. It is usually not 
heavily detailed, but can be if the topic can 
be covered succinctly, and it references other 
pertinent information. For example, a policy 
for respiratory protection might only state 
when wearing a respirator would be necessary 
and that the company provides the respirator 
and training. If a topic requires greater detail, 
it is usually fully documented in a procedure or 
program. Policies outline who and when but are 
not detailed when it comes to how the work is 
accomplished. Policies may also refer to what 
can occur should a task not be completed as 
required.
PROGRAMS
Programs are designed for extensive detail. Think 
of a program as a detailed instruction sheet, 
including all components necessary for the work. 
A program highlights the requirements as set 
forth by the regulatory agency and reviews the 
training necessary prior to beginning the task. 
It gets into the specifics of who, what, where, 
when, why, and how. The program references 
the documents (i.e., inspection forms) required 
to comply with the regulations.
Programs are fairly extensive, and often 
mimic a regulation line for line to ensure 
compliance. For example, a program states 
what employees are required to do, where 
they can find information on performing 
the task, and how to remain in compliance 
with requirements. It also reviews what 
the company is required to perform to 
maintain compliance with the regulation. 
Each applicable hazard usually has its 
own program. To continue the example, a 
respiratory protection program details the 
training, which areas require a respirator, 
how to determine whether a respirator is 
required, how to select the type of respirator, 
how to maintain a respirator, medical 
clearances necessary for use, and even how 
an employee is issued a respirator.
PROCEDURES
Procedures are very task-oriented. Think of 
a procedure as a detailed step within a set of 
instructions that is very specific for each task 
performed. It references requirements as stated 
in programs, and give physical direction on 
how a task is to be performed line for line. It 
also generally discusses the hazards associated 
with each step of performing the task. 
Continuing the example again, a procedure 
would detail how to maintain a respirator. 
The program will state that a respirator is to 
be cleaned daily, but the procedure will tell 
https://bit.ly/3fuz7Vf
36 • WINTER 2022 PROGRAMS, POLICIES, MANUALS, PROCEDURES, AND TRAINING
SAFETY CORNER
the employee in specific detail how to properly 
clean the respirator.
MANUALS
Think of these as a general overview. A manual 
is usually designed as a reference for a program. 
A manual contains only the information 
pertinent to how an employee is to comply 
with all of the company’s requirements. In 
some cases, a company may replace individual 
programs with a manual, essentially making 
the manual a collection of programs — each 
chapter becoming its own program. This 
depends on how much information is being 
relayed. If the chapter is extensive, or the 
regulation the company is attempting to 
comply with contains requirements that do 
not apply to all of the company’s tasks, then 
it would make sense to summarize only the 
information critical to how the company will 
comply. A separate program would be created 
detailing the specifics of what is required for 
compliance, what is not, and why. Continuing 
the previousexample, if the employee is 
required to use a new respirator, a manual may 
just tell them where to obtain one. Details as 
far as types used or any requirements for type 
used would be contained in the program.
TRAINING
Training must cover all information the employee 
needs to know to reduce or mitigate the hazard 
while performing the task. The employee is not 
required to review the applicable program, but 
some companies choose to perform training in 
this manner. Since a program is written to reflect 
the relevant regulation, this can be pretty boring. 
Because of this, some companies choose to train 
using other methods, such as presentations, 
videos, or even just on-the-job (OJT) training. 
However, the company must ensure the employee 
is competent to perform the task before they 
perform the task. In some cases, competency 
must be observed and refreshed on a regular 
basis, depending on the regulatory requirement. 
To document competency, a company can use 
quizzes or tests or even simple sign-off sheets 
indicating that the employee reviewed and 
understood the information. No matter how 
training is conducted, this documentation must 
be completed and maintained on file so long as 
the employee works at that company.
CONCLUSION
Companies must comply with many 
requirements, and there are many ways to go 
about complying with those regulations. But 
no matter how a company chooses to comply, 
it cannot avoid the eventual paperwork and 
documents that must be created to reach 
and maintain compliance. A JHA is a good 
starting point for determining which hazards 
are present when performing a job. Once you 
have identified the hazard, you can more easily 
identify the regulation created to mitigate 
the hazard. Once a company fully complies 
with the regulation and informs the employee 
of those requirements, it will go a long way 
to preventing injuries. After all, knowledge 
is power, and the more an employee knows 
about a hazard and how to mitigate it, the less 
likely it is for an employee to be injured by 
that hazard. 
Paul Chamberlain has been the Safety 
Manager for American Electrical Testing 
Co. LLC since 2009. He has been in the 
safety field since 1998, working for various 
companies and in various industries. Paul 
received a BS from the Massachusetts 
Maritime Academy. 
_ 11 
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10/5/17 11:44AM I I-
38 • WINTER 2022 TECH QUIZ
TECH QUIZ
OFF-LINE PARTIAL DISCHARGE 
CABLE TESTING
BY VIRGINIA BALITSKI, Magna IV Engineering
NETA Certified Technicians must continually adjust to advancing technology and 
diagnostic testing techniques. Over the years, cable testing has advanced to where 
multiple testing methods can be selected. 
After careful consideration of system requirements, a site owner may choose off-line 
partial discharge (PD) testing as one of their cable testing methods. This quiz looks 
at some details on partial discharge testing of cables.
1. What is partial discharge?
a. A localized electrical discharge that only 
partially bridges the insulation
b. Complete loss of a voltage signal 
c. A low-frequency (0.1Hz) failure
d. Severe arcing that exists inside insulators 
that is usually detected by IR scanning 
2. Which of the following cables are suitable 
for off-line PD testing?
a. 3-conductor tape-shielded cable
b. 1-conductor concentric neutral cable 
c. Non-shielded cable
d. a & b
3. What other limitations might make off-
line PD testing of a cable not feasible?
a. Cable length 
b. Electrical noise on site
c. Resistive shield connections at the 
termination
d. All of the above
4. What are the typical test set components of 
an off-line PD test set?
a. PD measuring instrument, 60Hz hipot, 
and series capacitor
b. PD measuring instrument only
c. PD measuring instrument, VLF hipot, 
and a parallel coupling capacitor
d. PD measuring instrument, DC hipot, 
and a parallel resistor
No. 138
See answers on page 123.
5. What units are usually used to quantify PD 
activity? 
a. Micro-amps
b. Pico-coulombs
c. Giga-ohms
d. Ampere-hour
6. Do all data points from off-line testing 
indicate PD activity? 
a. Yes. The analyzer is filtered for high-
frequency signals, so any data is 
concerning. 
b. No. High-frequency signals are 
recorded, including electrical noise and 
corona discharges. 
c. No. You will almost always receive 
mostly corona discharge signals, and 
only major issues will make it through.
d. Yes. Any concerning PD will produce a 
vast number of data points. 
Virginia Balitski, CET, Manager – 
Training and Development, has worked 
for Magna IV Engineering since 2006. 
Virginia started her career as a Field 
Service Technologist and has achieved 
NETA level 4 Senior Technician 
Certification. She has since dedicated her 
time to the advancement of training and safety in the electrical 
industry. Virginia is a Certified Engineering Technologist 
through ASET – The Association of Science & Engineering 
Technology Professionals of Alberta. She serves on NETA’s Board 
of Directors, is the current Vice-Chair of CSA Z462, Workplace 
Electrical Safety, and is a member of the NFPA 70E, Electrical 
Safety in the Workplace Technical Committee. 
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40 • WINTER 2022 GROUND ENHANCEMENTS: AN ANSWER TO DIFFICULT GROUNDING SITUATIONS
TECH TIPS
BY JEFF JOWETT, Megger
As part of the electrification of a facility, it is commonly thought that 
merely connecting the system to a driven ground rod means that the 
building is grounded. It’s not that simple. By pure luck, such an approach 
may indeed work. But the considerable value of the building, the 
efficiency of operation, the wealth of information and knowledge that is 
stored and transferred, and most of all the safety of personnel should not 
be left to luck.
Considerable variables are involved in 
establishing a good ground — that is to say, 
a ground of sufficiently low resistance so that 
the electrical system will operate at desirable 
or specified levels of efficiency and safety. To 
put it into perspective, the majority of electrical 
work is done on copper, a well-known quantity 
in terms of specifications and properties. Even 
GROUND 
ENHANCEMENTS: 
AN ANSWER TO DIFFICULT 
GROUNDING SITUATIONS
Table 1: Typical Soil Resistivity
Soil
Resistivity 
Ohm-cm (Range)
Surface soils, loam, etc. 100 – 5,000
Clay 200 – 10,000
Sand and gravel 5,000 – 100,000
Surface limestone 10,000 – 1,000,000
Shales 500 – 10,000
Sandstone 2,000 – 200,000
Granites, basalts, etc. 100,000
Decomposed gneisses 5,000 – 50,000
Slates, etc. 1,000 – 10,000
insulating materials, though much more varied 
than copper, are composed of well-known 
formulae. 
By contrast, soil resistivities (Table 1) can range 
in value from a few hundred