SolaHD Product Guide: DOE 2016 Energy Efficient Transformers Manuals & Guides

UNDERSTANDING THE DOE 2016 IMPACT:
ENERGY EFFICIENT TRANSFORMERS PRODUCT GUIDE

POWER CONVERSION AND PROTECTION

SolaHD is at work for you on the facility oor, service entrance, branch panel, power distribution points and point of use
applications. Our products power the most demanding applications and can be used in conjunction or alone to ensure
controlled, reliable power to any part of the factory oor or machinery.

Industrial Power Conversion and Protection

Power Conditioning Surge Suppression Transformers Power Supplies UPS

Service Entrance X X

Branch Panels X X

Networks X X X X

Large Machinery X X X X X

Process Rooms X X X

PLC’s &

Industrial PC’s

Ethernet &

Communications

DeviceNet X X X

Motion Control X X

Drives X X X

Analog I/O X X

X X X X X

X X X

Page 2

TABLE OF CONTENTS

Energy Efficiency Legislation for Distribution Transformers 4

Higher Energy Efficiencies 5

SolaHD Family of Transformers 6

Selection steps 7

Overcurrent protection 8

Primary fuse recommendations 10

Primary and secondary overcurrents 11

General purpose transformers 12

Low temperature rise transformers 16

K-factor transformers 19

Electrical connections 21

Transformer design 24

Specification guide 25

Broadest range of transformers 26

Glossary 27

Page 3

ENERGY EFFICIENCY LEGISLATION FOR DISTRIBUTION TRANSFORMERS

The Impact on Transformers

As the world’s largest energy consumer, the United States uses 3.7 trillion
kilo-watt-hours per year of power. Even with the recent surge in energy
prices and a greater awareness of the need to protect the environment, this
number will continue to increase until consumers and businesses see the
benefits of choosing more energy efficient product designs.

Congress, understanding that people can be financially enticed to change
behaviors and business practices, created new legislation. According to the
legislation, pertaining to low voltage dry-type distribution transformers,
the responsibility has been placed on the transformer manufacturers to
comply or face civil penalties. This will ensure that all new and replacement
transformers will meet the new efficiency requirements by removing the
option of using a lower efficiency unit.

Distribution Transformers manufactured after January 1, 2016 shall meet
specific energy efficiency requirements. The requirements are based on a
specification developed by the National Electrical Manufacturers Association
(NEMA) with assistance from transformer manufacturers and the U.S.
Department of Energy (DOE). DOE’s CFR (Code of Federal Regulations)
title 10 part 431 was published in the Federal Register Vol. 78, No. 75, also
referred to as DOE 2016.

The term Distribution Transformer is clearly defined in the Federal Rule
and specific exclusions are provided for some types of transformers.
The exclusions only apply to designs where compliance would not be
economically justifiable or would be technically difficult to accomplish. If in
practice some of these exclusions are abused, the law will be modified to
prevent such abuse. DOE 2016 defines the term “distribution transformers”

as any transformer which:

• Has an input voltage of 34.5 kV or less

• Has an output voltage of 600 V or less

• Is rated for operation at a frequency of 60 Hz

• Has a capacity of 10 kVA to 2500 kVA for liquid-immersed units and 15
kVA to 2500 kVA for dry-type units

The following special purpose transformers are excluded from the definition
of “distribution transformers” and are, therefore, not required to meet the

energy efficiency standards at this time:

• Autotransformers

• Drive (isolation) transformers

• Grounding transformers

• Machine-tool (control) transformers

• Non-ventilated transformers

• Rectifier transformers

• Regulating transformers

• Sealed transformers

• Special-impedance transformers

• Testing transformers

• Transformer with tap range of 20 percent or more

• Uninterruptible power supply transformers

• Welding transformers

Product lines affected by the new requirements include; Low Voltage
General Purpose (LVGP) transformers (ventilated units only), K-factor,
and Low Temperature rise units. Non-compliant designs in these product
categories became obsolete effective 12/31/15. Any units produced on or
before that date can still be shipped and used by customers. All standard
units in SolaHD’s product line which are non-compliant with the new Federal
Rule will be replaced with a new compliant design.

A majority of the units affected are included in this brochure. Custom
units affected by the rule will be replaced on a case-by-case basis using
the Custom Transformer Quote Request process. While the compliant
transformers will add to the cost of construction and maintenance projects,
the end user will save this cost over the life of the transformer.

It was a goal of the U.S. Department of Energy (DOE) to improve the energy
efficiency of distribution transformers. They have the legal authority to
define efficiency levels and enforce compliance. In addition, environmentally
conscious consumers and individuals also recognize that buying a higher
energy efficiency transformer will have both a financial and environmental
impact in the coming years.

The DOE has worked over the last few years to established new and more
stringent energy efficiency levels for distribution transformers. The law
went into effect January 1, 2016 making these new levels mandatory.
This new law primarily affects three-phase efficiency levels. Single phase
levels will remain the same. Please refer to the table on page 5 for the
efficiency levels which apply to the low-voltage dry-type transformers that
SolaHD manufactures; these are distribution transformers that include
low temperature rise, K-Factor and general purpose. There are additional
distribution transformers affected. Those are defined in the DOE’s CFR
(Code of Federal Regulations) title 10, part 431 (also known as DOE 10 CFR
p431). It was published in the Federal Register Vol. 78, No. 75.

How SolaHD is Supporting this Legislation and Our Customers.

It is important to note that the mandated energy efficiency levels were
hovering around 98-99%, depending on the type of transformer and
ratings. This means that any further efficiency improvements become more
challenging to achieve. Typically they will require more and/or better core
and conductor materials. In most cases, this will directly impact the cost of
the transformer. However, there is an economic benefit to offset the higher
initial transformer costs overtime. SolaHD has made every effort to optimize
our DOE 2016 designs to minimize cost impacts, but expect prices to be
higher throughout the transformer industry.

The end result of the new legislation is a lower environmental impact and a
cost savings derived from decreased energy use for our customers. SolaHD
supports this change, and the environmental benefits our society will receive
as a result. SolaHD has a long tradition as a high quality, U.S. manufacturer of
low voltage general purpose distribution transformers. We are proud to offer

transformers that meet the most stringent energy efficiency requirements

today, and are in a position that supports the new DOE 2016 higher
efficiency designs for our valued partners and customers.

Page 4

HIGHER ENERGY EFFICIENCIES

The Impact on Hevi-Duty Transformers

Benefiting from Higher Energy Efficiencies

Increasing the energy efficiency of a transformer allows the unit to operate
at the same level of power with less energy being wasted in the process. This
has a large impact on the consumption and distribution of energy because
the reduction in energy usage improves the nation’s energy independence,
reduces environmental impacts, lessens infrastructure investment, and
protects and strengthens the economy.

Decreasing usage through reduced waste by just .03% over the next 20
years cuts the need for new power generation by 60 to 66 million kw. That
drop would eliminate the need for construction of 11 new 400-megawatt
power plants by 2038. Electrical power generation accounts for 35% of all
U.S. emissions of carbon dioxide, 75% of sulfur dioxide and 38% of nitrogen
oxides. With higher-efficiency transformers, the country will see reduced
emissions of CO2, NOx and Hg of 678.8 Mt, 187.7 kt, and 6.48 t over the
next 30 years. Curbing energy imports also bolsters the U.S. economy by
reducing the current $65 billion trade deficit and mitigating fuel prices
through decreased demand.

As your full-range provider of power conversion and power quality related
products, SolaHD has been engineering and producing energy efficient
transformers to meet the market demands.

Our experienced engineers provide the best performing, most cost-effective
designs on the market. The SolaHD transformers are optimized to meet DOE
2016 limits for load losses calculated to 35% of the name plate rating, yet are
the same compact size and footprint as its’ conventional 150˚C rise units.

DOE 2016 Energy Efficiency Levels

Note: Efciency testing is done at 35% loading.

Single-Phase Three-Phase

kVA Eff % kVA Eff %

15 97.7 15 97.89
25 98 30 98.23

37.5 98.2 45 98.4
50 98.3 75 98.6
75 98.5 112.5 98.74

100 98.6 150 98.83
167 98.7 225 98.94

All units in this brochure meet or exceed the required DOE 2016 efficiency
levels. On the surface the absolute change seems insignificant, however the

reduction in lost energy is dramatic when you consider that almost all of the

energy consumed goes through at least one distribution transformer.

The example pictured in Figure 1 shows the differences in efficiency for the
old standard model compared to the compliant model. At 35% load, the
absolute difference in efficiency is only 1.7%. However, that represents a 52%
reduction in wasted energy. Taking that 52% reduction in wasted energy and
multiplying it across all the energy consumed results in substantial savings.

Figure 1: 75 kVA Transformer Efficiency

Non – Compliant

DOE 2016

300 99.02

500 99.14

Some general effects of the legislation:

A transformer under normal operation is always on, thus making any energy
efficiency improvements more significant over an extended period of time.
This means that customers will be rewarded in two ways:

1. They are reducing greenhouse gas emissions and there is an economic
payback through reduced energy costs overtime. Considering the life
expectancy of a transformer and the fact that the transformer will be on
24 hours a day, 7 days a week for the next 25-30 years, even small energy
efficiency improvements will pay dividends over the life of the transformer.

2. It will generate less heat. In many cases this translates into lower costs
to cool the environment in which they are utilized equating into more
savings not easily identified in calculations. (Note: Transformers on
average are at 35% loading).

Page 5

Some effects of the legislation on SolaHD:

• 600 Volt class 60 Hz, dry type general purpose, 3-phase 15-500 kVA

• Losses will be reduced approximately 30%, majority in the core

• Part numbers are
— General Distribution and Low Rise: ET Series will become E Series

i.e. ET2H45S becomes E2H45S

— K-Factor: 3HXXT Series will become KXXE Series

i.e. 3H4T2H15S becomes K4E2H15S

• Enclosure sizes are not changing

• Not affected: Single phase 600 Volt class will remain at EPACT 2005
(previously TP-1) levels and are now referred to as DOE 2016 levels.

SolaHD FAMILY OF TRANSFORMERS

SolaHD offers a broad range of transformers to meet many applications. These dry-type transformers are offered
encapsulated, ventilated or non-ventilated, 600 Volt Class, isolation type, single and three phase, through 500 kVA. Indoor
and outdoor models are available.

Applications

Transformers are useful where the available voltage must be changed to
accommodate the voltage required by the load. For many electrical circuits,
the National Electrical Code (NEC) requires a separately derived neutral
secondary connection provided by Delta-Wye connected transformers.

Typical applications include:

• Apartment Buildings

• Commercial Buildings

• High Rise Buildings

• Hospitals

• Industrial Plants

• Institutional Buildings

• Office Buildings

• Schools

• Shopping Centers

General purpose transformers can be located close to the load. No vaults
are required for installation and no long, expensive feeder lines are needed.
Common applications include inductive and resistive loads such as motors,
lighting and heating.

SolaHD general purpose transformers are manufactured to meet applicable
industry standards, are Listed in accordance with UL 506 and UL 1561
specifications and are classified as isolation transformers. The family of

transformers includes:

General Purpose

These industry workhorses feature dry type construction and are classified as
isolation transformers.

Low Temperature Rise

Lower thermal stress on transformer insulation increases useful life.

K-Fac tor

Designed to reduce the heating effects of harmonic currents created by solid
state loads.

Copper Wound

SolaHD general purpose transformers have standard aluminum coil
windings. As an option, copper windings are available.

Design Style

W D

H

Style 1 - Ventilated

Page 6

SELECTION STEPS

To manually select a transformer:

Find the electrical load requirements.

This information is available from the equipment manufacturer and is typically listed on the nameplate of the equipment.

These are:

1. Load operating voltage.

2. Load frequency (expressed in Hz).

3. Determine load size - usually expressed in kVA, amperage or horsepower.

4. Is the load designed to operate on single phase or three phase power?

Know the supply voltage conditions:

1. Available source voltage.

2. Available source frequency (a transformer will not change frequency. The frequency of the supply voltage and the needed load voltage must be equal).

3. Number of phases on power source.

Determine the transformer kVA rating:

1. If the load is expressed in kVA, select the appropriate transformer from the following selection charts (make sure the selected transformer’s kVA rating is
equal to or greater than the required load kVA).

kVA (1Ø) =

2. If the load is expressed in amperage, use either the appropriate kVA formula listed below or the appropriate sizing chart on the next page.

kVA (3Ø) =

3. If the load is expressed in wattage, either utilize the formula below to convert to kVA or refer to the equipment nameplate to obtain amperage
requirement.

kVA =

4. If the load is a motor and expressed in horsepower, refer to the motor horsepower charts on the next page.

(1000 x Power Factor of the load)

Volts x Amps

1000

Volts x Amps x 1.732

1000

Wattage

Some sizes may require an optional weather shield (order separately) for outdoor use.

kVA

Rating

SINGLE PHASE: FULL LOAD CURRENT CHART THREE PHASE: FULL LOAD CURRENT CHART

0.05 0.42 0.24 0.21 0.18 0.1 0.08 3 — 8.3 7.2 — 3.6 2.9

0.075 0.63 0.36 0.31 0.27 0.16 0.13 6 — 16.7 14.4 — 7.2 5.8

0.1 0.83 0.48 0.42 0.36 0.21 0.17 9 — 25 21.7 — 10.8 8.7

0.15 1.3 0.72 0.63 0.54 0.31 0.25 15 — 41.6 36.1 — 18 14.4

0.25 2.1 1.2 1 0.9 0.52 0.42 30 — 83.3 72.2 — 36.1 28.9

0.5 4.2 2.4 2.1 1.8 1.4 0.83 45 — 125 108.3 — 54.1 43.3

0.75 6.3 3.6 3.1 2.7 1.6 1.3 75 — 208.2 180.4 — 90.2 72.2

1.5 12.5 7.2 6.3 5.4 3.1 2.5 150 — 416 361 — 180 144

7.5 62.5 36.1 31.3 27.1 15.6 12.5

10 83.3 48.1 41.7 36.1 20.8 16.7
15 125 72.1 62.5 54.2 31.3 25
25 208.3 120.2 104.2 90.3 52.1 41.7

37.5 312.5 180.3 156.3 135.4 78.1 62.5

50 416.7 240.4 208.3 180.5 104.2 83.3

75 625 361 313 271 156 125
100 833 481 417 361 208 167
167 1392 803 696 603 348 278
200 1667 962 833 722 417 333
250 2083 1202 1042 903 521 417

120 V 208 V 240 V 277 V 480 V 600 V

Amperes Amperes

1 8.3 4.8 4.2 3.6 2.1 1.7 112.5 — 312 271 — 135 108

2 16.7 9.6 8.3 7.2 4.2 3.3 225 — 625 541 — 271 217
3 25 14.4 12.5 10.8 6.3 5 300 — 833 722 — 361 289
5 41.7 24 20.8 18.1 10.4 8.3 500 — 1388 1203 — 601 481

kVA

Rating

120 V 208 V 240 V 277 V 480 V 600 V

Page 7

SELECTION STEPS

Special Considerations:

Three things to keep in mind for AC, Motor Horsepower Amperage:

1. Motor horsepower charts are based on 1800 RPM squirrel cage induction motors. If using another type of motor, check running amperage against the
chart and adjust as necessary.

2. Increase required transformer kVAby 20% if motors are started more than once per hour.

3. If your motor service factor is greater than 1, proportionally increase full load amperage. (i.e. – if service factor is 1.10, increase full load amperage by
10%).

Are there any special application considerations?

A. For ambient conditions over 40°C, derate the transformer nameplate kVA by 8% for each 10°C above 40°C.
B. For high altitude applications, derate the transformer nameplate kVA by 0.3% for every 330 feet over 3300 feet above sea level. This assures proper

transformer convection cooling.

C. Some applications may require a transformer design that limits the BTU output of the unit at full load or a design to withstand and mitigate specific

electrical anomalies.

Horse

Power

SINGLE PHASE MOTOR CHART: AC, MOTOR HORSEPOWER AMPERAGE THREE PHASE MOTOR CHART: AC, MOTOR HORSEPOWER AMPERAGE

1-1/2 20 11 10 5 4 2.4 3 5 — 16.7 15.2 7.6 6.1 6.3 9

115 V 208 V 230 V 460 V 575 V

1/6 4.4 2.4 2.2 1.1 0.9 0.53 0.75 1/2 — 2.2 2 1 0.8 0.9 3
1/4 5.8 3.2 2.9 1.4 1.2 0.7 0.75 3/4 — 3.1 2.8 1.4 1.1 1.2 3

1/3 7.2 4 3.6 1.8 1.4 0.87 1 1 — 4 3.6 1.8 1.4 1.5 3

1/2 9.8 5.4 4.9 2.5 2 1.2 1.5 1-1/2 — 5.7 5.2 2.6 2.1 2.1 3
3/4 13.8 7.6 6.9 3.5 2.8 1.7 2 2 — 7.5 6.8 3.4 2.7 2.7 3

1 16 8.8 8 4 3.2 1.9 2 3 — 10.7 9.6 4.8 3.9 3.8 6

2 24 13.2 12 6 4.8 2.9 3 7½ — 24 22 11 9 9.2 15
3 34 18.7 17 8.5 6.8 4.1 5 10 — 31 28 14 11 11.2 15
5 56 30.8 28 14 11.2 6.7 7.5 15 — 46 42 21 17 16.6 30

7.5 80 44 40 21 16 9.6 10 20 — 59 54 27 22 21.6 30
10 100 55 50 26 20 12 15 25 — 75 68 34 27 26.6 30

Mini

Tfmr.

kVA

Std.

NEMA

kVA
Size

Horse

Power

115 V 208 V 230 V 460 V 575 V

30 — 88 80 40 32 32.4 45
40 — 114 104 52 41 43.2 45
50 — 143 130 65 52 52 75
60 — 170 154 77 62 64 75

75 — 211 192 96 77 80 112.5
100 — 273 248 124 99 103 112.5
125 — 342 312 156 125 130 150
150 — 396 360 180 144 150 150
200 — 528 480 240 192 200 225

Mini

Tfmr.

kVA

Std.

NEMA

kVA
Size

Page 8

OVERCURRENT PROTECTION

Fusing and circuit breaker protection.

How to overcurrent protect 600 Volt class transformers and associated wiring per NEC 450.3 (B), NEC 240.3 and NEC 240.6 (A).

1. Primary protection only is required if the transformer is single-phase
and the secondary has only two wires. Overcurrent protection rating
and location are below.

Primary Current Overcurrent Protection Rating Primary Current Overcurrent Protection Rating

2.2 Less than 2 amps 300% maximum 2.2 Less than 2 amps 300% maximum

2 to 9 amps 167% maximum 2 to 9 amps 167% maximum

9 amps or more

3. Primary and secondary protection is required if the transformer has
more than two wires on the secondary circuit.

125% of rated primary current

(or next highest standard rating)

2. If the branch circuit feeding the transformer has overcurrent
protection to meet the individual protection requirements in
Example 1, then individual transformer protection is not required.

9 amps or more

4. If the branch circuit feeding the transformer has overcurrent
protection to meet the individual primary overcurrent protection
requirements in Example 3, then individual primary protection is not
required. Secondary OCP is required as shown below.

125% of rated primary current

(or next highest standard rating)

Primary Current Secondary Current

250% primary current Less than 9 amps 167% maximum 250% primary current Less than 9 amps 167% maximum

Not more than 250% 9 amps or more

Page 9

Overcurrent

Protection Rating

125% (or next higher

standard rating)

Primary Current Secondary Current

Not more than 250% 9 amps or more

Overcurrent

Protection Rating

125% (or next higher

standard rating)

PRIMARY FUSE RECOMMENDATIONS

Recommended fuse sizes per UL 508 and NEC 450.3 (B), NEC 430.72 and commercially available type fuses.

Primary Voltage

Vin 120 200 208 220 230 240 277 440 460 480 550 575 600

VA

50 1.25 (2) .75 (1.25) .6 (1.13) .6 (1.13) .6 (1) .6 (1) .5 (.8) .3 (.5) .3 (.5) .3 (.5) .25 (.4) .25 (.4) .25 (.4)

75 1.8 (3) 1.13 (1.8) 1 (1.8) 1 (1.6) .8 (1.6) .8 (1.5) .8 (1.25) .5 (.8) .4 (.8) .4 (.75) .4 (.6) .3 (.6) .3 (.6)

100 2.5 (4) 1.5 (2.5) 1.4 (2.25) 1.25 (2.25) 1.25 (2) 1.25 (2) 1 (1.8) .6 (1.13) .6 (1) .6 (1) .5 (.8) .5 (.8) .5 (.8)

150 3.5 (6.25) 2.25 (3.5) 2 (3.5) 2 (3.2) 1.8 (3.2) 1.8 (3) 1.6 (2.5) 1 (1.6) .8 (1.6) .8 (1.5) .8 (1.25) .75 (1.25) .75 (1.25)

200 5 (8) 3 (5) 2.8 (4.5) 2.5 (4.5) 2.5 (4) 2.5 (4) 2 (3.5) 1.25 (2.25) 1.25 (2) 1.25 (2) 1 (1.8) 1 (1.5) 1 (1.6)

250 3 (5) 3.5 (6.25) 3.5 (6) 3.2 (5.6) 3.2 (5) 3 (5) 2.5 (4.5) 1.6 (2.8) 1.6 (2.5) 1.5 (2.5) 1.25 (2.25) 1.25 (2) 1.25 (2)

300 4 (6.25) 4.5 (7.5) 4 (7) 4 (6.25) 3.5 (6.25) 3.5 (6.25) 3.2 (5) 2 (3.2) 1.8 (3.2) 1.8 (3) 1.6 (2.5) 1.5 (2.5) 1.5 (2.5)

350 4.5 (7) 5 (8) 5 (8) 4.5 (7.5) 4.5 (7.5) 4 (7) 3.5 (6.25) 2.25 (3.5) 2.25 (3.5) 2 (3.5) 1.8 (3) 1.8 (3) 1.75 (2.5)

500 6.25 (10) 4 (6.25) 4 (6) 3.5 (5.6) 3.5 (5) 3 (5) 5 (9) 3.2 (5.6) 3.2 (5) 3 (5) 2.5 (4.5) 2.5 (4) 2.5 (4)

750 10 (15) 6.25 (9) 6 (9) 5.6 (8) 5 (8) 5 (7.5) 8 (12) 5 (8) 4.5 (8) 4.5 (7.5) 4 (6.25) 3.5 (6.25) 3.5 (6.25)

1000 12 (20) 8 (12) 8 (12) 7.5 (10) 7 (10) 6.25 (10) 10 (17.5) 3.5 (5.6) 3.6 (5) 3 (5) 5 (9) 5 (8) 5 (8)

1500 17.5 (30) 12 (15) 12 (15) 10 (15) 10 (15) 10 (15) 15 (25) 5.6 (8) 5 (8) 5 (7.5) 4.5 (6.25) 4.5 (6.25) 4.5 (6.25)

2000 25 (40) 15 (25) 15 (20) 15 (20) 12 (20) 12 (20) 20 (35) 7.5 (10) 7 (10) 6.25 (10) 6 (9) 5.6 (8) 5 (8)

3000 35 (60) 20 (35) 20 (35) 17.5 (30) 17.5 (30) 20 (30) 35 (50) 10 (15) 10 (15) 10 (15) 9 (12) 8 (12) 8 (12)

5000 60 (100) 35 (60) 30 (60) 30 (50) 30 (50) 30 (50) 60 (90) 15 (25) 15 (25) 15 (25) 12 (20) 12 (20) 12 (20)

7500 80 (150) 50 (90) 45 (90) 45 (80) 45 (80) 40 (70) 90 (125) 25 (40) 25 (40) 20 (35) 20 (30)

10K 110 (200) 70 (125) 60 (110) 60 (110) 60 (110) 60 (100) 110 (175) 30 (50) 30 (50) 30 (50) 25 (45)

15K 175 (300) 100 (175) 90 (175) 90 (150) 90 (150) 80 (150) 175 (250) 45 (80) 45 (80) 40 (70) 35 (60)

25K 300 (500) 175 (300) 150 (300) 150 (250) 150 (250) 150 (250) 90 (250) 60 (70) 70 (125) 70 (125) 60 (110)

37K 200 (350) 100 (175) 80 (150)

50K 300 (500) 150 (250) 110 (200)

75K 400 (750) 200 (350) 175 (300)

100K 600 (1000) 300 (500) 225 (400)

167K 900 (1600) 450 (850) 350 (650)

Fuse = I times 300% next size smaller if primary current is less than 2 amp. No secondary fusing required.
(Fuse) = (I*500%) next size smaller if used for a motor control circuit per NEC 430.72 (C) (4).

Fuse = I times 167% next size smaller if primary current is less than 9 amp. No secondary fusing required.
(Fuse) = (I times 250%) next size smaller if primary current is less than 9 Amps. Secondary fusing is required see chart for size.

Fuse = I times 125% next size higher if primary current is 9 amp. or higher. No secondary fusing required.
(Fuse) = (I times 250%) next size smaller if primary current is 9 Amps. or higher. Secondary fusing is required see chart for size.

Page 10

PRIMARY AND SECONDARY OVERCURRENTS

Primary Overcurrent Protection

A transformer has all the same component parts as a motor, and like a motor, exhibits an inrush when energized. This inrush current is dependent upon where
in the sine wave the transformer was last turned off in relation to the point of the sinewave you are when you energize the transformer. Although transformer
inrush could run up to 30 to 35 times full load current under no load, it typically is the same as a motor, about 6 to 8 times normal running current. For this
reason it is important to use a dual element slow blow type fuse, the same type of fuse you would use with a motor. If using a circuit breaker, select a breaker
with a time delay, again the same type you would use with a motor. If the time delay is not sufficient, you may experience “nuisance tripping” – a condition
where the breaker trips when energizing the transformer but it functions properly after it is re-started.

Secondary Overcurrent Protection

Overcurrent devices are used between the output terminals of the transformer and the load for three reasons:

1. Protect the transformer from load electrical anomalies.

2. Since short circuit current is minimized, a smaller gauge wire may be used between the transformer and the load.

3. Per NEC, a larger primary fuse may be used to reduce nuisance tripping.

Secondary Fuse Recommendations

Secondary Voltage

V

OUT

VA Secondary Time Delay Dual Element Slow-Blow Fuse

50 3.2 0.75 0.6 0.6 0.3 0.3 0.3

75 5 1.125 1 1 0.5 0.5 0.5

100 6.25 1.5 1.4 1.25 0.75 0.6 0.6

150 10 2.25 2 2 1.13 1 1

200 12 3 2.8 2.5 1.5 1.4 1.25

250 15 3.5 3.5 3.2 1.8 1.8 1.6

300 20 4.5 4 4 2.25 2 2

350 20 5 5 4.5 2.5 2.5 2.25

500 30 7.5 7 6.25 3.5 3.5 3.2

750 40 10 10 10 5.6 5 5

1000 12 12 12 7 7 6.25

1500 17.5 17.5 17.5 10 10 10

2000 25 25 25 12 12 12

3000 35 35 35 17.5 17.5 17.5

5000 60 60 60 30 30 30

7500 90 90 80 45 45 40

10K 125 110 110 60 60 60

15K 175 175 175 90 90 80

25K 300 300 300 150 150 150

37.5K 400 200

50K 600 300

75K 800 400

100K 1200 600

167K 1800 900

24 110 115 120 220 230 240

Page 11

Fuse = I times 167% next size smaller if sec

Fuse = I times 125% next size smaller if secondary

GENERAL PURPOSE

Energy efcient dry-type transformers 600 Volt Class, isolation type, single and three phase, 15 kVA through 500 kVA. Indoor
and outdoor models available.

Accessories and Optional Design Styles

• Electrostatic shield for quality power

• Wall mounting brackets (500 lbs maximum) (Item WB1C)

• Weather Shields (UL Listed/NEMA Type 3R)

• Stainless Steel Enclosures

• Totally enclosed non-ventilated designs (TENV) (Non UL) *

• Open core and coil designs (UL Recognized)

• Copper Wound designs

• Low temperature designs

Features

• Energy Efficient Compliant to DOE 2016

• UL Listed/NEMA Type 3R ventilated outdoor enclosures when used
with optional weather shields (order separately)

• UL Class 220°C insulation system, 150°C temperature rise under

full load

• Terminal board connections and spacious wiring compartment

• Panel enclosure design reduces labor time. Wiring diagram on inside

front cover

• High efficiency for low cost operation

• Single and three phase availability

• Fast delivery

• 10 year limited warranty

Certifications and Compliances

•

: E25872

- UL 1561

Primary Voltage Selection Tables: Single Phase

kVA

15 ES5H15S WS-15

25 ES5H25S WS-15

37.5 ES5H37S WS-17

50 ES5H50S WS-17

75 ES5H75S WS-09

100 ES5H100S WS-09

167 ES5H167S WS-16

kVA

Catalog

Number

Catalog

Number

Type 3R
Weather
Shield 

Type 3R
Weather
Shield 

Height

in (mm)

28 (711) 16 (406) 16 (406) 210 (95) 1 1 62.5/31.3 125/62.5

28 (711) 16 (406) 16 (406) 245 (111) 1 1 104/52.1 208/104

31 (787) 18 (457) 18 (457) 340 (154) 1 1 156/78 313/156

31 (787) 18 (457) 18 (457) 415 (188) 1 1 208/104 416/208

44 (1118) 23 (584) 21 (533) 610 (277) 1 1 313/156 625/313

44 (1118) 23 (584) 21 (533) 705 (320) 1 1 417/208 833/417

46 (1168) 26 (660) 24 (610) 980 (445) 1 1 695/348 1392/695

Height

in (mm)

Group 2 – 120/208/240/277 Volt Primary, 120/240 Secondary, 60 Hz

15 ES12H15S WS-15

25 ES12H25S WS-15

28 (711) 16 (406) 16 (406) 215 (98) 1 2 54.2 125/62.5

28 (711) 16 (406) 16 (406) 250 (113) 1 2 90.3 208/104

Width

in (mm)

Group 1: 240 x 480 Volt Primary, 120/240 Secondary, 60 Hz

Width

in (mm)

Depth

in (mm)

Depth

in (mm)

Approx. Ship

Weight lbs (kg)

Approx. Ship

Weight lbs (kg)

Design

Style 

Design

Style 

Elec

Conn 

Elec

Conn 

Primary

Amps

Primary

Amps

@ 277 V

Secondary

Amps

Secondary

Amps

Notes:

 Weather shields (set of two) must be ordered separately.
 Design Styles and Electrical Connections can be found at the end of the Ventilated Distribution Transformers section.

* Not all optional designs are

listed. Contact Technical Services.

Page 12

GENERAL PURPOSE

Energy efcient dry-type transformers 600 Volt Class, isolation type, single and three phase, 15 kVA through 500 kVA. Indoor
and outdoor models available.

Selection Tables: Three Phase

kVA

15

30

45

75

112.5 E2H112S WS-30

150 E2H150S WS-10

225 E2H225S WS-11

300 E2H300S WS-11

500 E2H500S WS-12

15

30

45

75

112.5 E5H112S WS-30

150 E5H150S WS-10

225 E5H225S WS-11

300 E5H300S WS-11

500 E5H500S WS-12

Catalog

Number

E2H15 

E2H15S

E2H30 

E2H30S

E2H45 

E2H45S

E2H75 

E2H75S

E5H15 

E5H15S

E5H30 

E5H30S

E5H45 

E5H45S

E5H75 

E5H75S

Type 3R
Weather
Shield 

WS-02

WS-14

WS-14

WS-30

Group B: 480 Volt Δ Primary, 240 Volt Δ, Secondary with reduced capacity center tap , 60 Hz

WS-02

WS-14

WS-14

WS-30

Height

in (mm)

Group A: 480 Volt Δ Primary, 208/120 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 221 (100) 1 5 18.1 41.7

28 (711) 23 (584) 16 (406) 310 (141) 1 5 36.1 83.4

28 (711) 23 (584) 16 (406) 387 (176) 1 5 54.2 125

34 (864) 28 (711) 22 (559) 678 (308) 1 5 90.3 208

34 (864) 28 (711) 22 (559) 794 (360) 1 5 135 313

44 (1118) 33 (838) 21 (533) 1005 (456) 1 5 181 417

46 (1168) 36 (914) 24 (610) 1368 (621) 1 5 271 625

46 (1168) 36 (914) 24 (6010) 1479 (671) 1 5 361 834

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 5 602 1390

23 (584) 18 (457) 14 (356) 221 (100) 1 6 18.1 36.1

28 (711) 23 (584) 16 (406) 322 (146) 1 6 36.1 72.3

28 (711) 23 (584) 16 (406) 387 (176) 1 6 54.2 108

34 (864) 28 (711) 22 (559) 678 (308) 1 6 90.3 181

34 (864) 28 (711) 22 (559) 792 (359) 1 6 135 271

44 (1118) 33 (838) 21 (533) 1009 (458) 1 6 181 361

46 (1168) 36 (914) 24 (610) 1367 (620) 1 6 271 542

46 (1168) 36 (914) 24 (610) 1478 (670) 1 6 361 723

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 6 602 1204

Width

in (mm)

Depth

in (mm)

Approx. Ship

Weight lbs (kg)

Design

Style 

Elec

Conn 

Primary

Amps

Secondary

Amps

Notes:

 Weather shields (set of two) must be ordered separately.
 Design Styles and Electrical Connections can be found at the end of the Ventilated Distribution Transformers section.

 Unshielded model.
 Refer to Capacity of Center Tap in Center Tap Delta Transformers at the beginning of this section.

Page 13

GENERAL PURPOSE

Energy efcient dry-type transformers 600 Volt Class, isolation type, single and three phase, 15 kVA through 500 kVA. Indoor
and outdoor models available.

Selection Tables: Three Phase

kVA

15 E81H15S WS-02

30 E81H30S WS-14

45 E81H45S WS-14

75 E81H75S WS-30

112.5 E81H112S WS-30

150 E81H150S WS-10

225 E81H225S WS-11

300 E81H300S WS-11

500 E81H500S WS-12

15 E84H15S WS-02

30 E84H30S WS-14

45 E84H45S WS-14

75 E84H75S WS-30

112.5 E84H112S WS-30

150 E84H150S WS-10

15 E3H15S WS-02

30 E3H30S WS-14

45 E3H45S WS-14

75 E3H75S WS-30

112.5 E3H112S WS-30

150 E3H150S WS-10

15

30

45

75

112.5

150

Catalog

Number

E6H15S

E6H30S

E6H45S

E6H75S

E6H112S

E6H150S

Type 3R
Weather

Shield 

WS-02

WS-14

WS-14

WS-30

WS-30

WS-10

Height

in (mm)

Group C: 480 Volt Δ Primary, 480Y/277 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 220 (100) 1 8 18.1 18.1

28 (711) 23 (584) 16 (406) 322 (146) 1 8 36.1 36.1

28 (711) 23 (584) 16 (406) 387 (176) 1 8 54.2 54.2

34 (864) 28 (711) 22 (559) 679 (308) 1 8 90.3 90.3

34 (864) 28 (711) 22 (559) 791 (359) 1 8 135 135

44 (1118) 33 (838) 21 (533) 1001 (454) 1 8 181 181

46 (1168) 36 (914) 24 (610) 1377 (625) 1 8 271 271

46 (1168) 36 (914) 24 (6010) 1497 (679) 1 8 361 361

65 (1651) 45 (1143) 35 (889) 2456 (1114) 1 8 602 602

Group D: 208 Volt Δ Primary, 480Y/277 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 220 (100) 1 10 41.7 18.1

28 (711) 23 (584) 16 (406) 320 (145) 1 10 83.4 36.1

28 (711) 23 (584) 16 (406) 390 (177) 1 10 125 54.2

34 (864) 28 (711) 22 (559) 680 (308) 1 10 208 90.3

34 (864) 28 (711) 22 (559) 799 (362) 1 10 313 135

44 (1118) 33 (838) 21 (533) 1000 (454) 1 10 417 181

Group E: 208 Volt Δ Primary, 208Y/120 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 222 (101) 1 9 41.7 41.7

28 (711) 23 (584) 16 (406) 320 (145) 1 9 83.4 83.4

28 (711) 23 (584) 16 (406) 390 (177) 1 9 125 125

34 (864) 28 (711) 22 (559) 679 (308) 1 9 208 208

34 (864) 28 (711) 22 (559) 801 (363) 1 9 313 313

44 (1118) 33 (838) 21 (533) 1004 (455) 1 9 416 416

Group F: 240 Volt Δ Primary, 208Y/120 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 220 (100)

28 (711) 23 (584) 16 (406) 311 (141)

28 (711) 23 (584) 16 (406) 392 (178)

34 (864) 28 (711) 22 (559) 678 (308)

34 (864) 28 (711) 22 (559) 799 (362)

44 (1118) 33 (838) 21 (533) 1005 (456)

Width

in (mm)

Depth

in (mm)

Approx. Ship

Weight lbs (kg)

Design

Style 

Elec

Conn 

1 11 36.1 41.7

1 11 72.3 83.4

1 11 108 125

1 11 181 208

1 11 271 313

1 11 361 417

Primary

Amps

Secondary

Amps

Notes:

 Weather shields (set of two) must be ordered separately.
 Design Styles and Electrical Connections can be found at the end of the Ventilated Distribution Transformers section.

Page 14

GENERAL PURPOSE

Energy efcient dry-type transformers 600 Volt Class, isolation type, single and three phase, 15 kVA through 500 kVA. Indoor
and outdoor models available.

Selection Tables: Three Phase

kVA

15 E85H15S WS-02

30 E85H30S WS-14

45 E85H45S WS-14

75 E85H75S WS-30

112.5 E85H112S WS-30

150 E85H150S WS-10

15 E79H15S WS-02

30 E79H30S WS-14

45 E79H45S WS-14

75 E79H75S WS-30

112.5 E79H112S WS-30

150 E79H150S WS-10

15 E2H15SCU WS-02

30 E2H30SCU WS-14

45 E2H45SCU WS-14

75 E2H75SCU WS-30

112.5 E2H112SCU WS-30

150 E2H150SCU WS-10

225 E2H225SCU WS-11

300 E2H300SCU WS-11

500 E2H500SCU WS-12

Catalog

Number

Type 3R
Weather

Shield 

Height

in (mm)

Group G: 240 Volt Δ Primary, 480Y/277 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 221 (100) 1 12 36.1 18.1

28 (711) 23 (584) 16 (406) 322 (146) 1 12 72.3 36.1

28 (711) 23 (584) 16 (406) 392 (178) 1 12 108 54.2

34 (864) 28 (711) 22 (559) 682 (309) 1 12 181 90.3

34 (864) 28 (711) 22 (559) 798 (362) 1 12 271 135

44 (1118) 33 (838) 21 (533) 1001 (454) 1 12 361 181

Group J: 480 Volt Δ Primary, 380Y/220 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 220 (100) 1 7 18.1 22.8

28 (711) 23 (584) 16 (406) 320 (145) 1 7 36.1 45.6

28 (711) 23 (584) 16 (406) 387 (176) 1 7 54.2 68.4

34 (864) 28 (711) 22 (559) 678 (308) 1 7 90.3 114

34 (864) 28 (711) 22 (559) 797 (362) 1 7 135.3 170.9

44 (1118) 33 (838) 21 (533) 1011 (459) 1 7 180.4 227.9

Group K: 480 Volt Δ Primary, 208Y/120 Secondary, 60 Hz, Copper-Wound

23 (584) 18 (457) 14 (356) 255 (116) 1 5 18.1 41.7

28 (711) 23 (584) 16 (406) 349 (158) 1 5 36.1 83.4

28 (711) 23 (584) 16 (406) 455 (206) 1 5 54.2 125

34 (864) 28 (711) 22 (559) 781 (354) 1 5 90.3 208

34 (864) 28 (711) 22 (559) 923 (419) 1 5 135 313

44 (1118) 33 (838) 21 (533) 1154 (523) 1 5 181 417

46 (1168) 36 (914) 24 (610) 1539 (698) 1 5 271 625

46 (1168) 36 (914) 24 (610) 1662 (754) 1 5 361 834

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 5 602 1390

Width

in (mm)

Depth

in (mm)

Approx. Ship

Weight lbs (kg)

Design

Style 

Elec

Conn 

Primary

Amps

Secondary

Amps

Notes:

 Weather shields (set of two) must be ordered separately.
 Design Styles and Electrical Connections can be found at the end of the Ventilated Distribution Transformers section.

Page 15

LOW TEMPERATURE RISE

SolaHD low temperature rise transformers feature a 220°C insulation system and temperature rise of only 80°C or 115°C
under full nameplate load. Reduction in temperature rise increases reliability.

The 35°C thermal reserve on 115°C rise units and 70°C reserve on 80°C
rise units definitely mean higher reliability. The extra benefit is being able
to operate either of these transformers as a 150°C rise unit and have a
short term overload capacity of 15-30% without compromising normal life
expectancy (See Figure 1 below).

Low temperature rise transformers are designed for any critical application
requiring extra overload capability and cooler operating temperatures.
All are available with either a 115°C or 80°C thermal rise and a Class 220°C
insulation system.

Features

• Energy Efficient Compliant to DOE 2016

• Extra thermal reserve

Accessories and Optional Design Styles

• Energy Efficient Compliant to DOE 2016

• Wall mounting brackets (500 lbs maximum) (Item WB1C)

• Weather Shields (UL Listed/NEMA Type 3R)

• Stainless Steel Enclosures

• Totally enclosed non-ventilated designs (TENV) (Non UL) *

• Open core and coil designs (UL Recognized)

• Copper Wound designs

Certifications and Compliances

•

: E25872

- UL 1561

Figure 1

+220 °C (+428 °F)

+185 °C (+365 °F)

+150 °C (+302 °F)

+70 °C (+158 °F)

+40 °C (+104 °F)

Ambient Temperature Allowance

0 ºC (+32 °F)

Temperature Rise Under

Full Load

+150 °C (+302 °F)

Coil Hot Spot Allowance

+30 °C (+86 °F)

+40 °C (+104 °F)

Rise Unit

+150 °C (+302 °F)

Thermal Reserve

+35 °C (+95 °F)

Temperature Rise Under

Full Load

+115 °C (+239 °F)

Coil Hot Spot Allowance

+30 °C (+86 °F)

Ambient Temperature Allowance

+40 °C (+104 °F)

Rise Unit

+115 °C (+239 °F)

Thermal Reserve

+70 ºC (+158 °F)

Temperature Rise Under

Full Load

+80 °C (+176 °F)

Coil Hot Spot Allowance

+30 °C (+86 °F)

Ambient Temperature Allowance

+40 °C (+104 °F)

Rise Unit

+80 °C (+176 °F)

Page 16

LOW TEMPERATURE RISE

SolaHD low temperature rise transformers feature a 220°C insulation system and temperature rise of only 80°C or 115°C
under full nameplate load. Reduction in temperature rise increases reliability.

Selection Tables: Low Temperature Rise, Single Phase, 80°C Rise

kVA

15 ES5HB15S WS-15

25 ES5HB25S WS-17

37.5 ES5HB37S WS-17

50 ES5HB50S WS-09

75 ES5HB75S WS-09

100 ES5HB100S WS-16

Selection Tables: Low Temperature Rise, Three Phase, 80°C Rise

kVA

15 E2HB15S WS-14

30 E2HB30S WS-14

45 E2HB45S WS-30

75 E2HB75S WS-30

112.5 E2HB112S WS-10

150 E2HB150S WS-11

225 E2HB225S WS-11

300 E2HB300S WS-12

15 E5HB15S WS-14

30 E5HB30S WS-14

45 E5HB45S WS-30

75 E5HB75S WS-30

112.5 E5HB112S WS-10

150 E5HB150S WS-11

225 E5HB225S WS-11

300 E5HB300S WS-12

Catalog

Number

80°C Rise

Catalog

Number

80°C Rise

Type 3R
Weather
Shield 

Type 3R
Weather
Shield 

Group B: 480 Δ Primary, 240 Δ Secondary with 120V Reduced Capacity Center Tap , 80°C Rise

Height

in (mm)

Group 1: 240 x 480 Volt Primary, 120/240 Secondary, 60 Hz, 80°C Rise

28 (711) 16 (406) 16 (406) 265 (120) 1 1 62.5/31.3 125/62.5

31 (787) 18 (457) 18 (457) 340 (154) 1 1 104/52.1 208/104

31 (787) 18 (457) 18 (457) 425 (193) 1 1 156/78 313/156

44 (1118) 23 (584) 21 (533) 655 (297) 1 1 208/104 416/208

44 (1118) 23 (584) 21 (533) 750 (340) 1 1 313/156 625/313

46 (1168) 26 (660) 24 (610) 980 (445) 1 1 417/208 833/417

Height

in (mm)

Group A: 480 Δ Primary, 208Y/120 Secondary, 60 Hz, 80°C Rise

28 (711) 23 (584) 16 (406) 310 (141) 1 5 18.1 41.7

28 (711) 23 (584) 16 (406) 387 (176) 1 5 36.1 83.4

34 (864) 28 (711) 22 (559) 678 (308) 1 5 54.2 125

34 (864) 28 (711) 22 (559) 794 (360) 1 5 90.3 208

44 (1118) 33 (838) 21 (533) 1005 (456) 1 5 135 313

46 (1168) 36 (914) 24 (610) 1368 (621) 1 5 181 417

46 (1168) 36 (914) 24 (610) 1479 (671) 1 5 271 625

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 5 361 834

28 (711) 23 (584) 16 (406) 322 (146) 1 6 18.1 36.1

28 (711) 23 (584) 16 (406) 387 (176) 1 6 36.1 72.3

34 (864) 28 (711) 22 (559) 678 (308) 1 6 54.2 108

34 (864) 28 (711) 22 (559) 792 (359) 1 6 90.3 181

44 (1118) 33 (838) 21 (533) 1009 (458) 1 6 135 271

46 (1168) 36 (914) 24 (610) 1367 (620) 1 6 181 361

46 (1168) 36 (914) 24 (610) 1478 (670) 1 6 271 542

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 6 361 723

Width

in (mm)

Width

in (mm)

Depth

in (mm)

Depth

in (mm)

Approx. Ship

Weight lbs (kg)

Approx. Ship

Weight lbs (kg)

Design

Style 

Design

Style 

Elec

Conn 

Elec

Conn 

Primary

Amps

Primary

Amps

Secondary

Secondary

Amps

Amps

Notes:

 Weather shields (set of two) must be ordered separately.
 Design Styles and Electrical Connections can be found at the end of the Ventilated Distribution Transformers section.
 Refer to Capacity of Center Tap in Center Tap Delta Transformers at the beginning of this section.

Page 17

LOW TEMPERATURE RISE

SolaHD low temperature rise transformers feature a 220°C insulation system and temperature rise of only 80°C or 115°C
under full nameplate load. Reduction in temperature rise increases reliability.

Selection Tables: Low Temperature Rise, Single Phase, 115°C Rise

kVA

15 ES5HF15S WS-15

25 ES5HF25S WS-15

37.5 ES5HF37S WS-17

50 ES5HF50S WS-17

75 ES5HF75S WS-09

100 ES5HF100S WS-09

Selection Tables: Low Temperature Rise, Three Phase, 115°C Rise

kVA

15 E2HF15S WS-02

30 E2HF30S WS-14

45 E2HF45S WS-14

75 E2HF75S WS-30

112.5 E2HF112S WS-30

150 E2HF150S WS-10

225 E2HF225S WS-11

300 E2HF300S WS-11

15 E5HF15S WS-02

30 E5HF30S WS-14

45 E5HF45S WS-14

75 E5HF75S WS-30

112.5 E5HF112S WS-30

150 E5HF150S WS-10

225 E5HF225S WS-11

300 E5HF300S WS-11

Catalog

Number

115°C Rise

Catalog

Number

115°C Rise

Type 3R
Weather
Shield 

Type 3R
Weather
Shield 

Group B: 480 Volt Δ Primary, 240 Volt Δ, Secondary with reduced capacity center tap, 60 Hz, 80°C Rise

Height

in (mm)

Group 1: 240 x 480 Volt Primary, 120/240 Secondary, 60 Hz, 115°C Rise

28 (711) 16 (406) 16 (406) 210 (95) 1 1 62.5/31.3 125/62.5

28 (711) 16 (406) 16 (406) 245 (111) 1 1 104/52.1 208/104

31 (787) 18 (457) 18 (457) 340 (154) 1 1 156/78 313/156

31(787) 18(457) 18 (457) 425 (193) 1 1 208/104 416/208

44 (1118) 23 (584) 21 (533) 610 (277) 1 1 313/156 625/313

44 (1118) 23 (584) 21 (533) 750 (340) 1 1 417/208 833/417

Height

in (mm)

Group A: 480 Δ Primary, 208Y/120 Secondary, 60 Hz, 115°C Rise

23 (584) 18 (457) 14 (356) 222 (101)

28 (711) 23 (584) 16 (406) 307 (139)

28 (711) 23 (584) 16 (406) 378 (171)

34 (864) 28 (711) 22 (559) 672 (305)

34 (864) 28 (711) 22 (559) 794 (360)

44 (1118) 33 (838) 21 (533) 1002 (454)

46 (1168) 36 (914) 24 (610) 1393 (632)

46 (1168) 36 (914) 24 (610) 1519 (689)

23 (584) 18 (457) 14 (356) 224 (102) 1 6 18.1 36.1

28 (711) 23 (584) 16 (406) 307 (139) 1 6 36.1 72.3

28 (711) 23 (584) 16 (406) 378 (171) 1 6 54.2 108

34 (864) 28 (711) 22 (559) 668 (303) 1 6 90.3 181

34 (864) 28 (711) 22 (559) 794 (360) 1 6 135 271

44 (1118) 33 (838) 21 (533) 1002 (454) 1 6 181 361

46 (1168) 36 (914) 24 (610) 1393 (632) 1 6 271 542

46 (1168) 36 (914) 24 (610) 1519 (689) 1 6 361 723

Width

in (mm)

Width

in (mm)

Depth

in (mm)

Depth

in (mm)

Approx. Ship

Weight lbs (kg)

Approx. Ship

Weight lbs (kg)

Design

Style 

Design

Style 

Elec

Conn 

Elec

Conn 

1 5 18.1 41.7

1 5 36.1 83.4

1 5 54.2 125

1 5 90.3 208

1 5 135 313

1 5 181 417

1 5 271 625

1 5 361 834

Primary

Amps

Primary

Amps

Secondary

Secondary

Amps

Amps

Notes:

 Weather shields (set of two) must be ordered separately.
 Design Styles and Electrical Connections can be found at the end of the Ventilated Distribution Transformers section.

Page 18

K-FACTOR

K-Factor transformers are designed to reduce the heating effects of harmonic currents created by loads like those shown in
Chart A. The K-Factor rating is an index of the transformer’s ability to withstand harmonic content while operating within the
temperature limits of its insulating system. SolaHD K-Factor transformers have UL ratings of K-4, K-13, and K-20.

The SolaHD K-Factor design is a specialized transformer that offers these
benefits:

• Conductors capable of carrying the harmonic currents of non-linear
loads without exceeding the temperature rating of the insulation
system.

• A transformer design that takes into account the increase in naturally

occurring “stray” losses caused by non-linear loads. These losses cause
standard transformers to dramatically overheat and substantially
shorten design life.

• A core and coil design that manages the DC flux caused by triplen
harmonics. As these harmonics increase, they cause additional current
to circulate in the delta winding. This produces a DC flux in the core
which leads to core saturation, voltage instability and overheating.

Features

• Energy Efficient Compliant to DOE 2016

• Conductors to carry harmonics of a K-rated load without exceeding
insulation temperature ratings

• UL 1561 Listed up to K-20 rated protection

• Rated temperature rise of 150°C, 220°C insulation

• Shielded for quality power

• Basic design takes “stray losses” into account and
functions within safe operating temperatures

• Core and coil design engineered to manage the zero sequence flux
caused by triplen harmonics

• Provides 100% rated current without overheating the windings or
saturating the core

Accessories and Optional Design Styles

• Wall mounting brackets (500 lbs maximum) (Item WB1C)

• Weather Shields (UL Listed/NEMA Type 3R)

• Totally enclosed non-ventilated designs (TENV) (Non UL) *

• Low temperature rise units available

• Open core and coil designs (UL Recognized)

• Copper Wound designs

• Alternate voltages

Certifications and Compliances

•

: E25872

- UL 1561

Chart A: Typical Load K-Factors

Load K-Fac tor

Electric discharge lighting K-4

UPS with optional input filter K-4

Welders K-4

Induction heating equipment K-4

PLCs and solid state controls K-4

Telecommunications equipment (e.g.. PBX) K-13

UPS without input filtering K-13

Multiwire receptacle circuits in general care areas of
health care facilities and classrooms of schools, etc.

Multi-wire receptacle circuits supplying inspection or
testing equipment on an assembly or production line

Mainframe computer loads K-20

Solid state motor drives (variable speed drives) K-20

Reprinted with permission from EDI Magazine.

K-13

K-13

* Not all optional designs are UL Listed. Contact Technical Services.

Page 19

K-FACTOR

K-Factor transformers are designed to reduce the heating effects of harmonic currents created by loads like those shown in
Chart A. The K-Factor rating is an index of the transformer’s ability to withstand harmonic content while operating within the
temperature limits of its insulating system. SolaHD K-Factor transformers have UL ratings of K-4, K-13, and K-20.

Selection Tables: Three Phase

kVA

15 K4E2H15S WS-02

30 K4E2H30S WS-14

45 K4E2H45S WS-14

75 K4E2H75S WS-30

112.5 K4E2H112S WS-30

150 K4E2H150S WS-10

225 K4E2H225S WS-11

300 K4E2H300S WS-11

500 K4E2H500S WS-12

15

30

45

75

112.5

150

225

300

15 K20E2H15S WS-14

30 K20E2H30S WS-14

45 K20E2H45S WS-30

75 K20E2H75S WS-30

112.5 K20E2H112S WS-10

150 K20E2H150S WS-11

225 K20E2H225S WS-11

300 K20E2H300S WS-12

Catalog

Number

K13E2H15S

K13E2H30S

K13E2H45S

K13E2H75S

K13E2H112S

K13E2H150S

K13E2H225S

K13E2H300S

Type 3R

Weather

Shield 

WS-14

WS-14

WS-30

WS-30

WS-10

WS-11

WS-11

WS-12

Height

in (mm)

Group A: K-4 Rated 480 Δ Primary, 208Y/120 Secondary, 60 Hz

23 (584) 18 (457) 14 (356) 221 (100) 1 5 18.1 41.7

28 (711) 23 (584) 16 (406) 310 (141) 1 5 36.1 83.4

28 (711) 23 (584) 16 (406) 387 (176) 1 5 54.2 125

34 (864) 28 (711) 22 (559) 678 (308) 1 5 90.3 208

34 (864) 28 (711) 22 (559) 794 (360) 1 5 135 313

44 (1118) 33 (838) 21 (533) 1005 (456) 1 5 181 417

46 (1168) 36 (914) 24 (610) 1368 (621) 1 5 271 625

46 (1168) 36 (914) 24 (610) 1479 (671) 1 5 361 834

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 5 602 1390

Group B: K-13 Rated 480 Δ Primary, 208Y/120 Secondary, 60 Hz

28 (711) 23 (584) 16 (406) 310 (141) 1 5 18.1 41.7

28 (711) 23 (584) 16 (406) 387 (176) 1 5 36.1 83.4

34 (864) 28 (711) 22 (559) 678 (308) 1 5 54.2 125

34 (864) 28 (711) 22 (559) 794 (360) 1 5 90.3 208

44 (1118) 33 (838) 21 (533) 1005 (456) 1 5 135 313

46 (1168) 36 (914) 24 (610) 1368 (621) 1 5 181 417

46 (1168) 36 (914) 24 (610) 1479 (671) 1 5 271 625

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 5 361 834

Group C: K-20 Rated 480 Δ Primary, 208Y/120 Secondary, 60 Hz

28 (711) 23 (584) 16 (406) 310 (141) 1 5 18.1 41.7

28 (711) 23 (584) 16 (406) 387 (176) 1 5 36.1 83.4

34 (864) 28 (711) 22 (559) 678 (308) 1 5 54.2 125

34 (864) 28 (711) 22 (559) 794 (360) 1 5 90.3 208

44 (1118) 33 (838) 21 (533) 1005 (456) 1 5 135 313

46 (1168) 36 (914) 24 (610) 1368 (621) 1 5 181 417

46 (1168) 36 (914) 24 (610) 1479 (671) 1 5 271 625

65 (1651) 45 (1143) 35 (889) 2457 (1114) 1 5 361 834

Width

in (mm)

Depth

in (mm)

Approx. Ship

Weight lbs (kg)

Design

Style 

Elec

Conn 

Primary

Amps

Secondary

Amps

Notes:

 Weather shields (set of two) must be ordered separately.
 Design Styles and Electrical Connections can be found at the end of the Ventilated Distribution Transformers section.

Page 20

SHIELD

X1

ELECTRICAL CONNECTIONS

Single Phase

ES5 Series

1

240 x 480 Volt Primary

120/240 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

H1 H2

5

7

3

1 2 4

X1

X3

6

8

X2 X4

SHIELD

Primary Voltage Interconnect Connect Lines to

Secondary Voltage Interconnect Connect Lines to

504 1 to 2 H1 & H2

492 2 to 3 H1 & H2

480 3 to 4 H1 & H2

468 4 to 5 H1 & H2

456 5 to 6 H1 & H2

444 6 to 7 H1 & H2

432 7 to 8 H1 & H2

252 H1 to 2 H2 to 1 H1 & H2

240 H1 to 4 H2 to 3 H1 & H2

228 H1 to 6 H2 to 5 H1 & H2

216 H1 to 8 H2 to 7 H1 & H2

240 X2 to X3 X1 & X4

120-0-120

X2 to X3 X2 to

120 X1 to X3 X2 to X4 X1 & X4

X1-X2-X4

ES12 Series

2

120/208/240/277 Volt

Primary

120/240 Volt Secondary

Taps: None

H1 H2

5

3

1 2 4

X3

X2 X4

6

Primary Voltage Interconnect Connect Lines to

277 1 to 2 H1 & H2

240 3 to 4 H1 & H2

208 5 to 6 H1 & H2

120 H1 to 4 H2 to 3 H1 & H2

Secondary Voltage Interconnect Connect Lines to

240 X2 to X3 X1 & X4

120-0-120

X2 to X3 X2 to

X1-X2-X4

120 X1 to X3 X2 to X4 X1 & X4

Page 21

SHIELD

H1

X0

H1

X3

X0

X0

X0

H1

X0

ELECTRICAL CONNECTIONS

Three Phase

E2 and Kxx Series

X2

X6

X2

X3

H3

H3

X3

X3

SHIELD

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

*

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

*

5

480 Δ Volt Primary

208Y/120 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

* Shield available in electrostatically shielded units only.

E5 Series

6

480 Δ Volt Primary

240 Δ W/120 CT Volt

Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

* Shield available in electrostatically shielded units only.

H1

7654321 7654321 7654321

X0

X1

H1 H2

7654321 7654321 7654321

X6

X1

H2

H2

H3

X2

H2

H3

X2

X1

X1

Primary Voltage Secondary Voltage

1 504

2 492

3 480

4 468

208 120

5 456

6 444

7 432

Primary Voltage Secondary Voltage

1 504

2 492

3 480

4 468

240 120

5 456

6 444

7 432

E79 Series

7

480 Δ Volt Primary

380/220 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

E81 Series

8

480 Δ Volt Primary

480Y/277 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

H1

7654321 7654321 7654321

X1

H1

H1

7654321 7654321 7654321

X1

H2

X2

H2

X1

H3

H2

X2

H2

X1

H3

H3

X2

X3

H3

X2

X3

SHIELD

X3

SHIELD

X3

Primary Voltage H1-H2-H3 Secondary Voltage

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

1 504

2 492

3 480

4 468

380 220

5 456

6 444

7 432

Primary Voltage H1-H2-H3 Secondary Voltage

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

1 504

2 492

3 480

4 468

480 277

5 456

6 444

7 432

Page 22

H1

X0

X0

H0

SHIELD

X1

X0

SHIELD

H1

X1

SHIELD

ELECTRICAL CONNECTIONS

Three Phase

E3 Series

9

208 Δ Volt Primary

208Y/120 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

E84 Series

10

208 Δ Volt Primary

480Y/277 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

H1

7654321 7654321 7654321

X1

X1

7654321 7654321 7654321

H1 H2

H2

X2

H2

X1

H3

X2

X2

H1

X3

H3

X2

X3

X3

H2

H0

H3

SHIELD

X3

H3

Primary Voltage H1-H2-H3 Secondary Voltage

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

Primary Voltage H1-H2-H3 Secondary Voltage

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

1 218

2 213

3 208

4 203

5 198

6 192

7 187

1 218

2 213

3 208

4 203

5 198

6 192

7 187

208 120

480 277

E6 Series

11

240 Δ Volt Primary

208Y/120 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

E85 Series

12

240 Δ Volt Primary

480Y/277 Volt Secondary

Taps: 2, 2-1/2% FCAN
4, 2-1/2% FCBN

H1

7654321 7654321 7654321

X1

X1

7654321 7654321 7654321

H0

H1 H2

H2

H2

H3

X2

X2

X3

X2

H1

X1

H2

H3

X2

X3

H0

X0

H3

Primary Voltage H1-H2-H3 Secondary Voltage

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

1 252

2 246

3 240

X3

4 234

208 120

5 288

6 222

7 216

X3

Primary Voltage H1-H2-H3 Secondary Voltage

@ Ta p Voltage X1, X2, X3 X0- X1, X2, X3

1 252

2 246

3 240

H3

4 234

480 277

5 288

6 222

7 216

Page 23

TRANSFORMER DESIGN

UL-3R Enclosure

(add optional weather shield)

High impact
powder paint finish

Remove bolts for
interior access,
front or rear.

Shielded for

quality power

Coils

Easily accessed

tap connections.

Flexible Ground Strap
(included but not shown)

Vibration and sound
dampening pad.

Fiberglass terminal board
relieves cable stress.

Enclosure bottom designed for
ventilation and optional rodent
protection.

Easy to read wiring

diagram inside front cover.

Page 24

SPECIFICATION GUIDE

Low Voltage, General Purpose, Dry Type Transformers (600 Volt Class) - 15 kVA and larger

General

• Single and three phase distribution transformers (600 Volt and below)

• Provide and install, as referenced on the electrical plans, enclosed dry
type transformers as manufactured by SolaHD or approved equal.

Standards

• Transformers must be listed by Underwriters Laboratory, certified with
Canadian Standards Association and designed, constructed and rated in
accordance with NEMA ST 20 and applicable IEEE & OSHA specifications.

Construction — Cores

• All transformer cores shall be constructed of low loss, high quality,
electrical grade laminate steel. By design, the flux density is to be
kept well below the saturation level to reduce audible sound level and
minimize core losses. The core volume shall allow operation at 10%above
rated primary voltage at no load without exceeding the temperature rise
of the unit.

Construction — Coils

• Coil conductors shall be either aluminum or copper and must be
continuous. The entire core and coil assembly shall be impregnated with
a thermal setting varnish and cured to reduce hot spots in the coils and
seal out moisture. Coils with exposed magnet wire will not be acceptable.
Transformers shall have common core construction.

•

ansformers shall incorporate a faraday (electrostatic) shield between

All tr
primary and secondary windings for the attenuation of voltage spikes,
line noise and voltage transients.

• Transformers shall be provided with six 2.5% full capacity taps – two
above and four below primary rated voltage.

• General purpose transformers are classified as isolation transformers.

Enclosures

• Transformer enclosures shall be constructed of heavygauge sheet
steel and coated with a grey powder paint finish (ANSI 61). Ventilated
transformer enclosures shall be UL/NEMA Type 1 rated and UL/NEMA
Type 3R rated for outdoor use with the addition of a weather shield. This
information must be listed on the transformer nameplate.

• Maximum transformer enclosure temperature will not exceed 65°C rise
above a 40°C ambient under full load.

• Transformers must have vibration isolators located between the core
and coil assembly and the transformer enclosure to reduce audible
sound levels caused from magnetostriction of the transformer core. No
externally located vibration dampening pads shall be used as they tend to
increase audible noise. Ventilated transformers are to be floor mounted
to aconcrete pad.

The tr

•

ansformer enclosure must be grounded by the installer in

accordance with the latest edition of the National Electric Code and any

local codes or ordinances.

Performance

• Audible sound levels will not exceed limits established in NEMA ST20:

o 50 kVA

10 t

51 to 150 kVA
151 to 300 kVA
301 to 500 kVA

ransformers, 15 kVA to 500 kVA, shall incorporate a UL recognized 220°C

• T
insulation system and exhibit a maximum 150°C temperature rise above a
maximum ambient of 40°C under full load.

Warranty

• Transformers are warranted against material, performance and
workmanship defects for a period of ten (10) years from date of
manufacture with the provision for an additional two (2) years.

45 db
50 db
55 db
60 db

Page 25

BROADEST RANGE OF TRANSFORMERS

SolaHD is pleased to offer the broadest range of transformers on the market including many custom designs. If you can't find what you are looking for, please
fill out the information below and submit to our Technical Services Group at solahd.technicalservices@emerson.com. We are happy to provide a quote on a
custom transformer if available.

Information is required prior to quotation being issued | Email this form to solahd.technicalservices@emerson.com or fax to (800) 538-6545.

Information in bold is REQUIRED prior to quotation being issued. Date:

Customer Information

Distributor: _________________________________________________________ Representative: _______________________________________________________

Contact: ____________________________________________________________ Contact: _____________________________________________________________

Account Number: ____________________________________________________ Phone: _______________________________________________________________

Phone: ______________________________________________________________ Fax: _________________________________________________________________

Fax: _________________________________________________________________ Email: _______________________________________________________________

Email: _______________________________________________________________ Job/Project Name: ____________________________________________________

City/State: __________________________________________________________

1: Specifications

1A: Size

 15  25  30  37.5  45  50  75  100  112.5  150  167  225  300  500

 kVA  VA

1B: Quantity

_______________ Number of Units  One Time Buy  Annual Usage _______________ Frequency of Purchase

1C: Temperature Rise (Check One)

 80°C  115°C  150°C

1C: Check all that apply

 Three Phase  Single Phase  LVGP

 50 Hz  60 Hz (Standard)  K-Factor 13

 Copper Windings  Aluminum Windings (Standard)  K-Factor 20  SCR Drive Isolation

 No Electrostatic Shield  Other: _____________________________________________________________

1D: Enclosure Type — Check all that apply

VENTILATED:

ENCLOSED (NON-UL):  TENV  TENV (SS)

ENCAPSULATED:  NEMA 3R  NEMA 3R (SS)  NEMA 4/12 (SS)  NEMA 4X (SS)

(SS) Stainless Steel Grade:  Standard (304)  Optional (316)

Hazardous Location Class 1, Division 2:  No  Yes (UL Certified)

1E: Other

Please specify _________________________________________________________________________________________________________________________________

 ICE  HSZ Series  Other: ______________________________________________________________________________________________________

 120  208  240  480  600  Other: _________  120  208  240  480  600  Other: _________

Tap s:  Standard: _________________  Other: _________ If Three-Phase:  Delta (Standard)  Wye

If Three-Phase:  Delta (Standard)

 UL  CSA or cULus  CE  Other: ____________________

Please quote a Catalog or Design Number :  Similar to (must note changes above): _______________________  Exactly Like: _________________________

Does this request pertain to a bid specification?:  No  Yes

End User/Contractor: ___________________________________________________ Competition: __________________________________________________________

Competitor's Part Number : _____________________________________________ Competitor's Price : ____________________________________________________

Target End User's Price : _________________________________________________ Distributor Margin: _____________________________________________________

 Open Coil (Top Terminated
Standard (UL Recognized)

4: Primary Voltage 5: Secondary Voltage

8: Competitive Data — Must be completed for special pricing considerations

 NEMA 1  NEMA 1 (SS)  NEMA 3R (WSXX)  NEMA 3R (SS)

3: Industrial Control Transformers

6: Agency Certification

7: Additional Information

 DOE 2016 (≥15kVA ventilated
distribution transformers only)

Page 26

GLOSSARY

AC (Alternating Current)

Current that reverses direction in response to voltage that is changing
polarity.

Attenuation

Decrease in signal voltage or power.

CE Mark (Conformité Européenne)

A marking that shows the product meets the fundamental safety, health,
environmental and consumer protection requirements of the European
Community.

Common-Mode Noise

Noise that occurs between the current carrying conductors and ground.

CVT (Constant Voltage Transformer)

A power conditioner that provides a stable and regulated sinewave output
voltage.

Continuous Duty

The service requirement that demands operation at a constant load for an
indefinite period of time.

Control Transformer

Usually referred to as an Industrial Control transformer. Designed for good
voltage regulation characteristics when low power factor and /or large
inrush currents are drawn (5 to 15 times normal).

CSA

Canadian Standard Association.

DC (Direct Current)

Current that flows in only one direction.

Derating

The specified reduction in an operating parameter to improve reliability.

DOE 2016

Department of Energy (DOE). DOE’s CFR (Code of Federal Regulations)
title 10 part 431 was published in the Federal Register Vol. 78, No. 75,
published April 18, 2013. Effectivity date for legislation on distribution
transformers: 01/01/2016.

Dynamic Load Regulation

The ratio of change in output voltage to change in load current.

Eddy Currents

Additional currents caused by a magnetic field.

Efficiency

A measure of energy loss in a circuit.

EMC (Electromagnetic Compatibility)

A directive necessary to get the CE Mark, which shows the electrical device
will not create high levels of EMI and will not fail due to normal levels of EMI.

Encapsulated

Method of sealing a device with epoxy to resist environmental effects.

EPACT 2005

Energy Policy Act of 2005.

Energy Star

Department of Energy program promoting energy efficient appliances and
apparatus (does not apply to distribution transformers).

Force Air Cooled

A means of accelerating heat dissipation to lower the temperature rise of
an electrical device.

Frequency (Hertz)

Cycles per second.

Harmonics Distortion

The distortion of the AC waveform due to the addition of sine waves of

different frequencies being added to the AC voltage.

Input Voltage Range

The high and low input voltage limits within which a device meets its
specifications.

kVA Rating

A measurement of apparent power. 1 kVA = 1000 VA.

KW Rating (kilowatts)

A measurement of real power delivered to a load 1 KW = 1000 VA x Power
Fac tor.

Line Regulation

The change in output voltage due to a variation in input voltage.

Load Regulation

The change in output voltage due to a variation in load.

Noise/Electrical Noise

Also called electromagnetic interference, or EMI. Unwanted electrical
signals that produce undesirable effects and otherwise disrupt the control
system circuits.

Output Current Limiting

An output protection feature which limits the output current to a
predetermined value in order to prevent damage to the device under
overload conditions.

Output Voltage

The nominal value of the voltage at the output terminals of a device.

PE (Protective Earthing)

The incoming earthing conductor provided by the utility.

Rated Output Current

The continuous load current that a device was designed to provide.

Short-Circuit Protection

A feature which protects the device from a short-circuit so that the device
will not be damaged.

Thermal Protection

An internal safeguard circuit that shuts down the unit in the event of excess
internal temperatures.

THD (Total Harmonic Distortion)

The ratio of the harmonic content to the fundamental frequency expressed
as a percent of the fundamental.

Transformer

An electrical device that changes AC voltage from one level to another.

UL (Underwriters Laboratories)

Acronym for Underwriters Laboratories tested.

UL Recognized

Designation given to components that when used properly in an end
product are deemed to be safe.

UL Listed

Designation given to products ready for end use.

VA (Voltamp)

A measure of power. 1000 VA = 1 kVA.

Page 27

SolaHD is our premium line of power
conversion and power quality products
under Appleton Group, a business unit of
Emerson Industrial Automation. SolaHD
offers industrial grade products that help
increase machine availability and ensure
data reliability while bringing greater
exibility to the design of your machines and
production line. SolaHD products improve
efciency, productivity and longevity in the
most demanding industrial environments.

Emerson Industrial Automation brings

integrated manufacturing solutions

to diverse industries worldwide. Our
comprehensive product line, extensive
experience, world class engineering and
global presence enable us to implement

solutions that give our customers the

competitive edge.

For over 150 years, our electrical product
brands have been providing a rich tradition
of long term, practical, high quality
solutions with applications ranging from
the construction and safe operation of
petrochemical and process plants to
providing quality power that precisely
controls automotive robotic production.

Engineers, distributors, contractors,

electricians and site maintenance

professionals around the world trust
Emerson Industrial Automation brands to
make electrical installations safer, more
productive and more reliable.

Appleton Group is organized into three
focused businesses that provide distributors
and end users expert knowledge and
excellent service.

ELECTRICAL CONSTRUCTION MATERIALS

This group is made up of the Appleton,
Nutsteel and O-Z/Gedney brands, offering
a broad range of electrical products
including conduit and cable ttings,
plugs and receptacles, enclosures and
controls, conduit bodies and industrial
and hazardous lighting. Whether the
application is hazardous location, industrial
or commercial, the electrical construction
materials group has the products to meet
your needs.

POWER QUALITY SOLUTIONS

The SolaHD brand offers the broadest
power quality line, including uninterruptible
power supplies, power conditioners, voltage
regulators, shielded transformers, surge
protection devices and power supplies.

HEATING CABLE SYSTEMS

This group is made up of the EasyHeat
and Nelson brands, offering a broad range
of electrical heating cable products for
residential, commercial and industrial
applications.

Asia/Pacic
+ 65.6891.7600

Australia

+ 61.3.9721.0348

Brazil – São Paulo/SP
+ 55.11.2122.5777

Brazil – Camaçari/BA
+ 55.71.3496.4427

Canada

+ 1.888.765.2226

China

+ 86.21.3418.3888

Europe
+ 33.3.2254.2759

Mexico/Latin America
+ 52.55.5809.5049

Middle East/Africa/India

+ 971.4.881.8100

Appleton Grp LLC

9377 W. Higgins Road

Rosemont, IL 60018

1.800.377.4384

solahd.com

Appleton Grp LLC d/b/a Appleton Group. The SolaHD and Emerson logos are registered in the U.S. Patent and Trademark Ofce.
EasyHeat, Inc. is a wholly owned subsidiary of Appleton Grp LLC. All other product or service names are the property of their registered owners.
© 2015, Appleton Grp LLC. All rights reserved.

The Emerson logo is a trademark and a service mark of Emerson Electric Co. ©2015, Emerson Electric Co.