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INTRODUCTION

A troubleshooting procedure consists of systematic testing designed to identify and correct a problem. Technicians must gather information and utilize tests to identify problems and develop appro-priate solutions. Following established troubleshooting procedures ensures that problems are identified and quickly cor-rected to minimize equipment and pro-duction downtime. Consistent practices also generate consistent measurements for more accurate comparison and track-ing over time.

DC voltage to be applied during an insula-tion resistance test.

In order to obtain meaningful insula-tion resistance measurements, the techni-cian should carefully examine the system under test. The best results are achieved when the following conditions are met: • The system or equipment is taken out

of service and disconnected from all other circuits, switches, capacitors, overcurrent protection devices, and circuit breakers. Ensure that the mea-surements are not affected by leakage current through switches and overcur-rent protective devices.

• The temperature of the conductor is above the dew point of the ambient air. When this is not the case, a moisture coating will form on the insulation surface, and, in some cases will be absorbed by the material.

• The surface of the conductor is free of hydrocarbons and other foreign matter that can become conductive in humid conditions.

• Applied voltage is not higher than the system capacity. When testing low-voltage systems, too much low-voltage can overstress or damage insulation. • The system under test has been

complete-ly discharged to the ground. The ground-ing discharge time should be about five times the testing charge time.

TROUBLESHOOTING OF

ELECTRIC MOTORS

Insulation resistance testing is performed when troubleshooting electric motors and related equipment. IEEE Standard 43-2000, Recommended Practice for Testing Insulation Resistance of Rotating Machines, recommends the insulation test voltage to apply, based on winding rating, and minimum acceptable values for electric motor windings. The IEEE also provides typical guidelines for For accurate low-resistance measurements when using a DMM, insulation multimeter, or megohmmeter, the resistance of the test leads is subtracted from the total resistance. Typical test lead resistance is between 0.2 Ω and 0.5 Ω.

• The effect of temperature is consid-ered. Since insulation resistance is inversely proportional to insulation temperature (resistance goes down as temperature goes up), the recorded readings are altered by changes in the temperature of the insulating mate-rial. It is recommended that tests be performed at a standard conductor temperature of 68°F (20°C).

When comparing readings to 68°F base temperature, double the resistance for every 18°F (10°C) above 68°F or halve the resistance for every 18°F be-low 68°F in temperature. For example, a 1 MΩ resistance at 104°F (40°C) will translate to 4 MΩ resistance at 68°F (20°C).

To measure the temperature of motor windings, use a noncontact temperature probe connected to a digital multimeter (DMM) or an infrared thermometer.

See Figure 3-1.

Several different types of insulation resistance tests are performed when troubleshooting electric motors. These tests include an insulation spot test, a dielectric absorption test, and an insula-tion step voltage test.

Insulation Spot Test

An insulation spot test is an insulation resistance test that can be used to verify the condition of the insulation over the life of the motor. See Figure 3-2.

A spot test should be performed at reg-ular intervals (every six months, for ex-ample) to track the changes in insulation integrity. The test should also be performed after a motor is serviced. The test measure-ment data can be recorded on a test graph over time.

To perform an insulation spot test, apply the following procedure: 1. Connect a megohmmeter to measure

the resistance of each winding lead to ground. Record the readings after 60 sec.

2. Discharge the motor windings.

An insulation multimeter can be used to check insulation integrity between commutator segments prior to rewinding.

Although insulating materials in practical use can be solid, liquid, or gas, resistance measurements generally refer to solid insulation. Factors that affect insulation resistance measurements are the nonuni-formity of the material, the time period the sample is energized, the magnitude and polarity of the voltage, the time required for the charge to build, material decay, and specimen contour.

Siemens NONCONTACT TEMPERATURE MEASUREMENT

INFRARED THERMOMETER Siemens INFRARED THERMOMETER NONCONTACT TEMPERATURE PROBE 1 mV DISPLAY FOR EACH °F OR °C DMM

NONCONTACT TEMPERATURE PROBE

Figure 3-1. To measure the temperature of motor windings, use a noncontact temperature probe connected to a DMM or an infrared thermometer.

Interpret the results of the test graph to determine the condition of the insula-tion. See Figure 3-3. Point A represents the motor insulation condition when the motor was placed in service. Point B represents the effects of aging, contamina-tion, etc., on the motor insulation. Point C represents motor insulation failure. Point D represents the motor insulation

1 3 2 TO GROUND TO GROUND T1 T4 T5 T8 5 k TO MEASURE RESISTANCE READING ON GRAPH GROUND AND RECORDOF EACH WINDING TO CONNECT MEGOHMMETER

REPEAT STEPS 1 AND 2 EVERY SIX MONTHS MOTOR WINDINGSDISCHARGE

, 5 W RESISTOR

MEGOHMMETER

TEST

INSULATION SPOT TEST

condition after being rewound. Record the lowest meter reading on an insulation spot test graph if all readings are above the minimum acceptable resistance. Ser-vice the motor if a reading does not meet the minimum acceptable resistance. The lowest reading is used because a motor is only as good as its weakest point.

Figure 3-2. An insulation spot test is a test that checks motor insulation over the life of the motor.

Dielectric Absorption Test

A dielectric absorption test is an insula-tion resistance test that checks the absorp-tion characteristics of wet or contaminated insulation. The test is performed over a 10 min period. See Figure 3-4.

To perform a dielectric absorption test, apply the following procedure:

1. Connect a megohmmeter to measure the resistance of each winding lead to ground. Record the lowest meter reading on a dielectric absorption test graph if all readings are above the minimum acceptable resistance. Record the readings every 10 sec for the first minute and every minute thereafter for 10 min.

2. Discharge the motor windings.

D C B A YEAR 1000 500 100 50 10 5 4 3 2 1 0 5 RESISTANCE (IN M ) MOTOR PLACED

IN SERVICE EFFECTS OF AGING,

CONDITION AFTER BEING REWOUND

MOTOR INSULATION FAILURE

CONTAMINATION, ETC.

INSULATION SPOT TEST GRAPH

Figure 3-3. Insulation spot test measurement data is recorded on a test graph over time.

Megohmmeters can be used for testing defective motor winding insulation.

1 2 TO GROUND TO GROUND OF EACH WINDING TO TO MEASURE RESISTANCE CONNECT MEGOHMMETER GROUND AND RECORD READING ON GRAPH WINDINGS MOTOR DISCHARGE T3 T2 T1 T4 T5 T6 T9 T8 T7 RESISTOR5 k , 5 W MEGOHMMETER TEST

DIELECTRIC ABSORPTION TEST

Interpret the results of the test graph to determine the condition of the insulation.

See Figure 3-5. The slope of the curve

indicates the condition of the insulation. Good insulation (curve A) indicates a continual increase in resistance. Moist or cracked insulation (curve B) shows a relatively constant resistance. Service the motor if a reading does not meet the minimum acceptable resistance.

A polarization index is the ratio of the insulation resistance of a machine wind-ing calculated by uswind-ing values obtained from a 10 min measurement divided by

Figure 3-4. A dielectric absorption test is a test that checks the absorption characteristics of wet or contaminated insulation.

a 1 min measurement. The polarization index is an indication of the condition of the insulation. A low polarization index (typically 1.5 or lower) indicates exces-sive moisture or contamination. Different insulation classes will have different mini-mum acceptable polarization index values.

See Figure 3-6. Insulation classes

are based on the continuous operating temperature of the application. For ex-ample, Class A insulation has a maxi-mum operating temperature of 212°F, Class B, 248°F, Class F, 293°F, and Class H, 329°F.

For example, if the 1 min reading of Class B insulation is 80 MΩ and the 10 min reading is 90 MΩ, the polarization index is 1.125 (90 MΩ ÷ 80 MΩ = 1.125). The polarization index is lower than the minimum accepted values because the insulation contains excessive moisture or contamination.

Insulation Step Voltage Test

An insulation step voltage test is a test that creates electrical stress on internal insula-tion cracks to reveal aging or damage not found during other motor insulation tests. This test is done by testing the insulation at two or more voltages and comparing the results. The insulation step voltage

5 1 ) M NI( 10 50 100 500 1000 E C N A T SI S E R

TIME (IN MINUTES)

2 3 4 5 6 7 8 9 10 (MOIST OR CRACKED CURVE B INSULATION) CURVE A (GOOD INSULATION)

DIELECTRIC ABSORPTION TEST GRAPH

Insulation Index Value

Class A 1.5 Class B 2.0 Class F 2.0 Class H 2.0 MINIMUM ACCEPTABLE POLARIZATION INDEX VALUES

Figure 3-5. Dielectric absorption test measurement data is recorded on a test graph over time.

Figure 3-6. Different insulation classes will have different minimum acceptable polarization index values.

IEEE Standard 43-2000, Recommended Practice for Testing Insulation Resistance of Rotating Machinery, covers measurement of polarization index testing.

test is performed only after an insulation spot test. See Figure 3-7.

To perform an insulation step voltage test, apply the following procedure: 1. Set the megohmmeter to 500 V and

connect to measure the resistance of each winding lead to ground. Take each resistance reading after 60 sec. Record the lowest reading.

2. Place the meter lead on the winding that has the lowest reading.

4 3 2 1 TO GROUND DISCHARGE THE MOTOR WINDINGS T1 T2 T3 INCREASE METER SETTING BY 500 V; RECORD READING ON GRAPH AFTER 60 SECONDS LOWEST READING ON WINDING WITH PLACE METER LEAD

SET MEGOHMMETER TO 500 V AND MEASURE RESISTANCE OF EACH WINDING TO GROUND

TEST

FUNCTIONUPSCROLLDOWNENTER IR PORT ON/ OFF 00k 0 0M G V 0G T 00G T M k 00M M 000V500V 2500V TO GROUND 5 k , 5 W RESISTOR

INSULATION STEP VOLTAGE TEST

Figure 3-7. An insulation step voltage test is a test that creates electrical stress on internal insulation cracks to reveal aging or damage not found during other motor insulation tests.

3. Increase the megohmmeter setting by increments of 500 V starting at 1000 V and ending at the high-end voltage for a range of motors within the system. Record each reading after 60 sec.

4. Discharge the motor windings. Interpret the results of the test to determine the condition of the insula-tion. See Figure 3-8. The resistance of good insulation that is thoroughly dry

(curve A) remains approximately the same at different voltage levels. The resistance of deteriorated insulation (curve B) decreases substantially at different volt-age levels.

The larger the insulation surface, the lower the insulation resistance. The greater the supply voltage to the motor, the thicker the insulation requirements. A 50 HP, 230 V motor requires the same insulation as a 1 HP, 230 V motor. 5 1 ) M NI( 10 50 100 500 1000 E C N A T SI S E R VOLTAGE (IN kV) 2 3 4 5 CURVE A (DRY INSULATION) CURVE B (DETERIORATED INSULATION)

INSULATION STEP VOLTAGE TEST GRAPH

Figure 3-8. Insulation step voltage test measurement data is recorded on a test graph over time.

TROUBLESHOOTING CABLE

AND WIRE INSTALLATIONS

When troubleshooting cable and wire installations, they should be disconnected from panels and machinery to keep them isolated. The conductors should be tested against each other and against ground.

See Figure 3-9.

Cables and wires should be tested and maintained on a three-year cycle at a minimum. Insulation resistance tests should be performed more frequently for those systems that show deterioration of insulation material. When performing insulation tests on wire and cable, apply the following procedure:

1. Inspect exposed sections of cables and wires for physical damage. Replace or repair sections that exhibit damage. Caution: A megohmmeter uses very high

voltages during insulation resistance test-ing (up to 5000 V). Always follow recom-mended procedures and safety rules. After performing insulation resistance tests with a megohmmeter, connect the device being tested to ground through a 5 kW, 5 W resis-tor if the megohmmeter does not include a discharge function.

2. Inspect cables and wires for proper grounding, cable support, and termi-nation. Terminate those sections that are not properly terminated.

3. If cables and wires are properly terminated, verify that neutrals and grounds are properly terminated for operation of protective devices. 4. Perform an insulation resistance

test on each conductor in the cable. Apply 1000 VDC for 1 min (one-minute insulation resistance test) to low voltage cables (1 kV or less) and use a megohmmeter, or insulation multimeter (IMM) to measure the insulation resistance. (Use a hipot tester to perform a DC hipot test on cables ranging from 1 kV to 69 kV.)

Low-Voltage Cables

A cable length test should be performed on newly installed low-voltage cables. Knowing the actual length of low-voltage cables is required because low-voltage cables, like all conductors, have resistance that reduces the amount of power passing through them. The greater the length of a cable, the greater the power reduction (at-tenuation) created by the cable. Because the signals are transmitted at low power, any reduction in power caused by a cable must be kept to a minimum.

TEST CABLE INSULATION METAL CONDUIT CONDUCTORS CONDUCTOR INSULATION

TROUBLESHOOTING CABLE AND WIRE INSTALLATIONS

Figure 3-9. When troubleshooting cable and wire installations, the conductors should be tested against each other and against ground.

Cable length testers measure the length of cables and also indicate the distance to a cable fault by accessing the end of a cable with two or more conductors.

TROUBLESHOOTING

ELECTRICAL SWITCHGEAR

AND SWITCHBOARDS

Electrical switchgear and switchboards are freestanding assemblies of metal- enclosed sections containing circuit breakers and/or fused disconnect switch-es. They also contain bus bars, cable termination points, backup protection devices, and various forms of controls and instrumentation. Switchgear or

switch-OUTDOOR FEEDER BUSWAY 480 V FROM UTILITY FEEDER BUSWAY 480 V 480 V 480 V 480 V 480 V MOTOR STARTER PANELBOARD PANELBOARD 120 V 120 V TRANSFORMER TRANSFORMER PANELBOARD

SWITCHGEAR POWER DISTRIBUTION

SWITCHGEAR/ SWITCHBOARD

boards are used to distribute utility power via busways to transformers, panelboards, and motor starters. See Figure 3-10. An assembly may be part of a load center, substation, or distribution board.

Switchgear and related assemblies should be tested and maintained at a mini-mum of once a year. Inspections should be performed more frequently if equipment is in an environment that has excessive dirt or moisture. Per plant procedures and manufacturers recommendations, the best

Figure 3-10. Switchgear or switchboards are used to distribute utility power via busways to transformers, panelboards, and motor starters.

results are achieved when the following actions are applied:

• Inspect electrical sections of switch-gear for damage. Repair or replace damaged sections.

• Inspect all bus connections for high resistance by using an insulation mul-timeter. Repair or replace sections that are not in compliance.

• Inspect insulation material for physi-cal damage or contaminated surfaces. Clean or repair any insulation that is not in compliance.

• Perform insulation resistance tests on each bus section, phase-to-phase, and phase-to-ground by using a megohm-meter or insulation multimegohm-meter. Typical switchgear insulation resistance values range from 50 MΩ to 20,000 MΩ. In-sulation resistance values that are less than the equipment manufacturer’s recommended minimum resistance value should be investigated for ad-ditional problems.

• Always perform tests on deenergized equipment.

TROUBLESHOOTING

MISCELLANEOUS

ELECTRICAL DEVICES

Miscellaneous equipment includes such equipment as portable electrical devices, double-insulated tools, extension cords, transformers, and any electrical device that receives power through a separate power conductor. Insulation resistance testing is performed on such equipment as part of regular maintenance programs as well as for standard OSHA and NEC® _compliance.

Although standard insulation resis-tance specifications can be applied when troubleshooting most motors and other electrical devices, certain situations re-quire higher resistance specifications to be applied. Most stated specifications list the maximum amount of acceptable leak-age current and not the actual resistance. For example, a 3-wire handheld electri-cal appliance or tool must be insulated enough to allow no more than 0.75 mA (0.00075 A) of leakage current to flow through the exposed parts to ground.

Typical resistance values are one-third higher than the 1 MΩ per 1 kV industry standard. Medical equipment and electri-cal devices rated as “double-insulated” have much higher insulation ratings than ordinary equipment. Miscellaneous equipment includes two-prong Cat-egory II power cord devices, three-prong Category I power cord devices, and dry-type transformers.

Insulation resistance values vary with tem-perature and the amount of moisture in the insulation. The temperature and humidity should be recorded at the time the insulation test readings are taken.

Two-Prong Category II Power

Cord Devices

A two-prong Category II power cord device is a device that has only two con-ductors extending from it, one hot and one neutral. Two-prong devices do not have a third ground (green wire) prong on the power cord. Certain two-prong devices are classified as double-insulated.

A double-insulated device is an elec-trical product designed so that a single ground fault cannot cause a dangerous

electrical shock through any exposed sections of the product that could come in contact with an electrician. Double-insulated devices include not only the standard insulation used on conductors but also extra insulating material between the energized parts of the device and the parts that can be contacted.

When troubleshooting these devices for insulation resistance, leakage current is measured from the exposed metal parts to ground. See Figure 3-11. To test a two-prong Category II power cord device for insulation resistance, apply the following procedures:

1. If the device has no exposed metal, wrap metal foil on the exposed plastic parts (such as the handles). The metal foil simulates a wet hand contacting the electrical device. 2. Ensure that the electrical device

being tested is not plugged into a power source.

3. Connect the ground test lead to the metal foil wrap on the tool under test.

4. Connect the voltage test lead to the neutral (larger) blade on the tool’s power cord.

5. Use the insulation resistance tester to supply the test voltage.

6. Measure the amount of leakage cur-rent in mA and record the readings. Typical specified maximum leakage current for a double-insulated, two-prong Category II device is typically 0.25 mA (0.00025 A).

When leakage current exceeds the specified limit, a three-prong power cord must be used. The ground (green) wire is added to carry the leakage current to ground by providing a low

impedance (resistance) path from all non-current-carrying parts to earth ground. Equipment used in the medical field will have an even lower acceptable maximum leakage current limit.

Three-Prong Category I Power

Cord Devices

A three-prong Category I power cord de-vice is a device that has three conductors extending from it, one hot, one neutral, and one ground. Any leakage current will flow through the ground (green) conductor back to ground during normal operation. The ground conductor prevents the exposed metal parts of the electrical device from becoming energized to the point of causing an electrical shock.

See Figure 3-12. To test a three-prong

Category I power cord device for insu-lation resistance, apply the following procedure:

1. Ensure that the electrical device be-ing tested is not plugged into a power source.

2. Connect the ground test lead to a metal portion of the equipment under test, such as a motor housing.

3. Connect the voltage test lead to the neutral (larger) blade on the tool’s power cord.

4. Measure the amount of leakage current in mA and record the readings. The more power a load requires, the larger the amount of current flow. For example, a 10 HP motor draws approximately 28 A when wired for 230 V. A 20 HP motor draws ap-proximately 54 A when wired for 230 V.

MICROAMPERES DC 0 1 2 3 4 5 KILOVOLTS DC 0 3 6 9 1215 01.5 34.5 67.5 EXT INST

CAL CAL CAL

OUT STABILIZATION 15 KV MEGOHMMETER IN MULTIPLIER I I II MULTIPLIER I I II VOLTAGE CONTROL 120 V CAUTION HIGH VOLTAGE I 0 20 40 60 80 100 OFF OFF OUTPUT AC ON OUTPUT ON MICROAMPERES DC 0 1 2 3 4 5 VOLTAGE CONTROL SET ON 100

MEASURE AMOUNT OF LEAKAGE CURRENT AND RECORD READING. (0.25 mA MAXIMUM LEAKAGE CURRENT ALLOWED)

USE INSULATION RESISTANCE TESTER TO SUPPLY TEST VOLTAGE

TWO-PRONG POWER CORD HIPOT TESTER PLASTIC HOUSED TOOL REQUIRES METAL FOIL WRAP

CONNECT GROUND TEST LEAD TO METAL FOIL WRAP CATEGORY II ELECTRICAL DEVICE DOUBLE-INSULATED ELECTRICAL DEVICE WITHOUT GROUND 6 1

DEVICE NOT PLUGGED INTO POWER SOURCE 2

5 CONNECT VOLTAGE TEST LEAD TO NEUTRAL PRONG 4 3

TWO-PRONG CATEGORY II POWER CORD DEVICES

Figure 3-11. A two-prong Category II power cord device has only two conductors extending from the device, one hot and one neutral, and does not have a third ground prong on the power cord.

MICROAMPERES DC 0 1 2 3 4 5 KILOVOLTS DC 0 3 6 9 12 15 0 1.53_{4.5 6 7.5} EXT INST

CAL CAL CAL

OUT STABILIZATION 15 KV MEGOHMMETER IN MULTIPLIER I I II MULTIPLIER I I II VOLTAGE CONTROL 120 V CAUTION HIGH VOLTAGE I 0 20 40 60 80 100 OFF OFF OUTPUT AC ON OUTPUT ON MICROAMPERES DC 0 1 2 3 4 5

VOLTAGE CONTROL SET ON 100

CATEGORY I ELECTRICAL DEVICE

MEASURE AMOUNT OF LEAKAGE CURRENT AND RECORD READING (3.5 mA MAXIMUM LEAKAGE CURRENT ALLOWED)

4

GROUND PRONG

CONNECT GROUND TEST LEAD TO METAL PORTION OF EQUIPMENT UNDER TEST

ELECTRICAL DEVICE WITH GROUND PLUG

2 CONNECT VOLTAGE TEST LEAD TO NEUTRAL PRONG 3 ELECTRICAL DEVICE THREE-PRONG POWER CORD NOT PLUGGED INTO POWER SOURCE

1

THREE-PRONG CATEGORY I POWER CORD DEVICES

HIPOT TESTER

Figure 3-12. A three-prong Category I power cord device has three conductors extending from the device, one hot, one neutral, and one ground (green wire).

The typical specified maximum leak-age current for a three-prong category I device is typically 0.75 mA (0.00075 A) for handheld electrical devices such as disc grinders, and 3.5 mA (0.0035 A) for non-handheld electrical devices such as floor buffers, electric motors, small drill presses, and air compressors.

A reference multimeter can be used to take resistance measurements from 2 Ω to 20 MΩ, as well as more accurate voltage, current, and temperature measurements than a standard handheld meter.

a nonconducting material, such as varnish or a high-temperature polymer, and then formed into a core that reduces electrical losses. Dry-type transformer maintenance and testing should be performed and recorded, starting with the initial instal-lation of the transformer.

An IMM set to measure resistance can be used to check for open circuits in coils, short circuits between primary and sec-ondary coils, or coils shorted to the core without power applied to the transformer.

See Figure 3-13.

Open Circuits in Coils. The resistance

of each coil is checked with a DMM. The winding is open and the transformer is bad if any of the coils show an infinite resistance reading. Note that very low resistance readings do not indicate a short, but rather the resistance of the wire.

Short Circuits between Primary and Secondary Coils. A check for short

cir-cuits should be made between the primary and secondary coils of the transformer. Checking for short circuits between the primary and secondary coils should be performed with a megohmmeter.

Autotransformers are used in starting rotating machinery such as synchronous and induction motors.

Dry-Type Transformers

A dry-type transformer is a transformer that uses a non-liquid material for in-sulation. Dry-type transformers can be constructed as either toroidal (doughnut-shaped) or laminated. Toroidal transform-ers typically have copper wire wrapped around a cylindrical core so the magnetic flux within the coil does not leak out, has good coil efficiency, and has little effect on other components. Laminated trans-formers contain laminated-steel cores. The steel laminations are insulated with General Electric Company

NORMAL RESISTANCE READING INDICATES GOOD COIL IMM SECONDARY WIRES SECONDARY WIRES SECONDARY WIRES

OPEN CIRCUITS IN COILS

PRIMARY

WIRES TRANSFORMER

IMM

SHORT CIRCUIT BETWEEN PRIMARY AND SECONDARY COILS

PRIMARY WIRES

TRANSFORMER

IMM

COILS SHORTED TO CORE

TESTING TRANSFORMERS

PRIMARY WIRES

TRANSFORMER

INFINITE READING WHEN CHECKING FOR SHORT BETWEEN COILS INDICATES NOT SHORTED TO EACH OTHER

INFINITE READING WHEN CHECKING FOR SHORT BETWEEN WINDING AND BODY INDICATES GOOD TRANSFORMER

Figure 3-13. An IMM set to measure resistance can be used to check for open circuits in coils. When testing for short circuits between primary and secondary coils, or for coils shorted to the core without power applied to the transformer, use the insulation test function of the IMM.

Coils Shorted to Core. A resistance

check is made from each transformer coil to the core of the transformer. All coils should show an infinite resistance reading to the core. The transformer should not be used if a resistance is shown between any coil and the core.

Transformer Maintenance.

Trans-former manufacturers provide recom-mended maintenance procedures and schedules for their equipment, but the actual performance of a specific trans-former should determine the frequency of the maintenance and troubleshooting to be performed.

The majority of transformer failures are caused by poor maintenance. Trans-formers should be tested and maintenance performed at least once annually. When performing insulation resistance tests on dry-type transformers, apply the follow-ing procedures:

1. Visually inspect for physical dam-age: cracked insulation, defective wiring, tightness of connections, and dirt/moisture on the coil.

2. Verify proper core and equipment grounding.

3. Use a megohmmeter or insulation multimeter to perform insulation resistance tests on winding to wind-ing or windwind-ings to ground. Per-form insulation resistance tests for each winding.

Typical transformer insulation re-sistance values range from 500 MΩ to 25,000 MΩ. See Figure 3-14. Insulation resistance test readings for transformer windings should be within 1% of adjacent windings. TRANSFORMER INSULATION RESISTANCE VALUES 0 - 600 1000 500 601 - 5000 2500 5000 5001 - 15,000 5000 * in VAC † _{in VDC} ‡ in MΩ 25,000 Minimum Insulation Resistance‡ Minimum Test Voltage† Transformer Coil Rating*

Figure 3-14. Typical transformer insulation resistance values range from 500 MΩ to 25,000 MΩ.

When inspecting small (600 V or less) dry-type transformers, apply the follow-ing procedures:

1. Visually inspect for physical dam-age: cracked insulation, defective wiring, tightness of connections, and dirt/moisture on the coil.

2. Verify proper core and equipment grounding.

3. Clean the unit prior to making any tests.

4. Use a megohmmeter or insulation multimeter to perform insulation resistance tests on winding to wind-ing or windwind-ings to ground. Per-form insulation resistance tests for each winding.

To help prevent electrical problems that cause equipment damage, neutral conductors should be the same size as, or larger than, hot conductors.