1. UNIT 5 : HIGH VOLTAGE TESTING AND INSULATION COORDINATION
5.1 NEED FOR HIGH VOLTAGE TESTS
Verify the name plate details
Confirm the design specifications
Dr M A Panneerselvam, Professor, Anna University

2. 5.2 CLASSIFICATION OF HIGH VOLTAGE TESTS
Ascertain the maximum withstand values (capacity)
Research and development of insulating materials
5.2 CLASSIFICATION OF HIGH VOLTAGE TESTS
High voltage tests can be classified under various heads
Dr M A Panneerselvam, Professor, Anna University

3. Dr M A Panneerselvam, Professor, Anna University
as given under:
5.2.1 Based on the type of tests:
Type tests
Routine tests
Special tests
Acceptance tests
Dr M A Panneerselvam, Professor, Anna University

4. Dr M A Panneerselvam, Professor, Anna University
Type tests are tests conducted on a randomly selected sample out of a given lot , confirming to the same rating and specification , and manufactured over a given period of time. These tests are conducted by a neutral authority
Dr M A Panneerselvam, Professor, Anna University

5. Dr M A Panneerselvam, Professor, Anna University
and witnessed by both manufacturer and customer.
Routine tests are conducted on all piece of equipment generally by manufactures in their own premises.
Dr M A Panneerselvam, Professor, Anna University

6. Dr M A Panneerselvam, Professor, Anna University
Special tests are certain tests conducted only on the request of customer otherwise these tests are not conducted normally.( Ex. Impulse test including chopped waves on transformers) .
Dr M A Panneerselvam, Professor, Anna University

7. Dr M A Panneerselvam, Professor, Anna University
Acceptance tests are tests conducted at the customer’s premises during receipt of consignment (equipment). The customer may specify any test for this purpose.
Dr M A Panneerselvam, Professor, Anna University

8. Dr M A Panneerselvam, Professor, Anna University
5.2.2 Based on the nature of voltages:
DC voltage test
AC voltage test
Impulse voltage/Impulse current test
Switching surge test
Dr M A Panneerselvam, Professor, Anna University

9. Dr M A Panneerselvam, Professor, Anna University
5.2.3 Based on the nature of breakdown:
Withstand tests
Flashover/Sparkover tests
Puncture tests
Dr M A Panneerselvam, Professor, Anna University

10. Dr M A Panneerselvam, Professor, Anna University
5.2.4 Based on the environment:
Dry tests
Wet tests
Dr M A Panneerselvam, Professor, Anna University

11. 5.3 ELECTRICAL EQUIPMENT CONSIDERED FOR TESTING
Power transformers ,distribution transformers, instrument transformers,reactors , etc.,
Protective devices like circuit breakers, lightning arresters , etc.,
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12. Dr M A Panneerselvam, Professor, Anna University
Porcelain insulators and other types of insulators
Cables , capacitors and other dielectric materials and
Busducts(isolated and 3 phase busducts) and other sundry equipment.
Dr M A Panneerselvam, Professor, Anna University

13. 5.4 STANDARD HIGH VOLTAGE TESTS
Out of all the equipment listed above, Power transformers , Distribution transformers ,Lightning arresters , Circuit breakers, Line insulators and Power cables form the major components of a power system.
Dr M A Panneerselvam, Professor, Anna University

14. Dr M A Panneerselvam, Professor, Anna University
The high voltage tests conducted in general on the above equipment are classified as follows:
5.4.1 Direct voltage tests:
Tests on cables and other dielectric materials.
Dr M A Panneerselvam, Professor, Anna University

15. Dr M A Panneerselvam, Professor, Anna University
5.4.2 Power frequency tests:
Induced overvoltage test and separate source voltage withstand test on power transformers, one minute withstand / flashover test under dry and wet conditions , puncture test on insulators
Dr M A Panneerselvam, Professor, Anna University

16. Dr M A Panneerselvam, Professor, Anna University
power frequency sparkover test on lightning arresters and dry and wet withstand tests on circuit breakers.
5.4.3 Impulse voltage tests:
Withstand test on power transformers, Impulse sparkover test and front of wave impulse
Dr M A Panneerselvam, Professor, Anna University

17. Dr M A Panneerselvam, Professor, Anna University
sparkover test(V-T curve) on lightning arresters, withstand/ flashover tests on insulators and isolators and withstand/flashover tests on bus ducts.
5.4.4 Switching surge tests : Withstand tests on power transformers, insulators, lightning arresters , circuit breakers , etc.,
Dr M A Panneerselvam, Professor, Anna University

18. Dr M A Panneerselvam, Professor, Anna University
All the tests mentioned above can be grouped under two heads ,viz.,(1) Tests conducted on external insulation and (2) Tests conducted on internal insulation of electrical equipment.
Dr M A Panneerselvam, Professor, Anna University

19. Dr M A Panneerselvam, Professor, Anna University
As the tests conducted are large in numbers and are on different type of equipment , it is not possible to give the meaning of all the terminology adopted and they can be easily verified from the relevant standards.
Dr M A Panneerselvam, Professor, Anna University

20. Dr M A Panneerselvam, Professor, Anna University
Depending upon the country in which the equipment is going to be installed it can be tested as per the standards of that country. (Ex., Indian standard, British standard, NEMA standard etc.,)
Dr M A Panneerselvam, Professor, Anna University

21. 5.5 LIST OF IMPORTANT INDIAN STANDARDS USED IN HIGH VOLTAGE TESTING
Method for high voltage measurement by means of sphere gaps (one sphere earthed ) :IS
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22. Dr M A Panneerselvam, Professor, Anna University
2)Method of high voltage testing-Part I : General definitions and test requirements : IS 2071(Part I)-1974
3) Method of high voltage testing – Part II:Test procedures :IS 2071(Part II) 1974
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23. Dr M A Panneerselvam, Professor, Anna University
4) Method of high voltage testing-Part III: Measuring devices:IS 2071(Part III)1976
5) Specification for power transformers-Part III :Insulation levels and dielectric tests : IS 2026(Part III) -1981
Dr M A Panneerselvam, Professor, Anna University

24. Dr M A Panneerselvam, Professor, Anna University
6) Specification for lightning arresters for alternating current systems-Part I :Non linear type lightning arrester : IS 3070 (Part I )
7) Specification for alternating current circuit breakers - Part II : IS 2516 (Part II/ Sec.2)
Dr M A Panneerselvam, Professor, Anna University

25. Dr M A Panneerselvam, Professor, Anna University
8) Direct voltage tests on cables: IS -698.
(Cables are generally tested with DC voltages to avoid heavy charging currents and loading of generator)
Dr M A Panneerselvam, Professor, Anna University

26. Dr M A Panneerselvam, Professor, Anna University
When specific standard is not available for testing of newly developed equipment the tests can be conducted in general agreement with existing standards based on the type of test and the nature of insulation.
Dr M A Panneerselvam, Professor, Anna University

27. 5.6 GENERAL REQUIREMENTS OF HIGH VOLTAGE TESTING
Prior to starting of the actual test on a given equipment there are certain important prerequisites and details to be looked into , viz,
Dr M A Panneerselvam, Professor, Anna University

28. Dr M A Panneerselvam, Professor, Anna University
(1) Arrangement of test object (2) Conditioning of test object and (3) Correction factors for atmospheric conditions ( air density and humidity).
5.6.1 Arrangement of test object:
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29. Dr M A Panneerselvam, Professor, Anna University
Clearance to extraneous structures and general disposition of the object , viz, height above ground level , the arrangement of high voltage lead etc. is of importance. If the clearance to extraneous structures is at least 1.5 times
Dr M A Panneerselvam, Professor, Anna University

30. Dr M A Panneerselvam, Professor, Anna University
the flashover distance between the electrodes of the test object it is found to be sufficient.
5.6.2 Conditioning of test object:
Depending upon the requirements of testing ,the tests are conducted under dry or wet
Dr M A Panneerselvam, Professor, Anna University

31. Dr M A Panneerselvam, Professor, Anna University
conditions. The rain conditions are simulated using spray of water through nozzles falling on the test object at angle of 45 0 to the vertical axis. The characteristics of the spray for tests with alternating voltages are given in the following slide.
Dr M A Panneerselvam, Professor, Anna University

32. ARRANGEMENT FOR WATER SPRAY DURING WET TEST
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33. Dr M A Panneerselvam, Professor, Anna University
Average precipitation rate for measurement of vertical component = 3 ± 10 % mm/min
Limit for individual measurement = 3 ± 25 % mm/min
Resistivity of collected water = 100 ± 10 % ohm-m
Dr M A Panneerselvam, Professor, Anna University

34. Dr M A Panneerselvam, Professor, Anna University
Duration of wet withstand test = 60 sec.
The characteristics of water spray for switching surge test for voltages above 500 kV are :
Vertical component = 1 to 1.5 mm/min. and Horizontal
Dr M A Panneerselvam, Professor, Anna University

35. Dr M A Panneerselvam, Professor, Anna University
component = 1 to 1.5 mm/min.
Limit for individual measurements = 0.5 to 2.0 mm/min
Resistivity of water=100± 15 % ohm-m.
Dr M A Panneerselvam, Professor, Anna University

36. Dr M A Panneerselvam, Professor, Anna University
5.6.3 Atmospheric correction factors:
As the high voltage tests are invariably conducted at conditions other than standard temperature, pressure and humidity the voltage values should be multiplied by
Dr M A Panneerselvam, Professor, Anna University

37. Dr M A Panneerselvam, Professor, Anna University
atmospheric correction factors, viz,
Air density correction factor , kd
Humidity correction factor , kh
Standard atmospheric conditions (STP) are : Temperature = 20 0 C , Pressure = 760 mm of Hg. (1013 millibars) and absolute humidity
Dr M A Panneerselvam, Professor, Anna University

38. Dr M A Panneerselvam, Professor, Anna University
=11 gm/m3.
For tests conducted on external insulations the voltage at room temp. V(RTP) is related to V(STP) as below:
V (RTP) = V (STP) kd/kh
In case of sphere gap test, only air
Dr M A Panneerselvam, Professor, Anna University

39. Dr M A Panneerselvam, Professor, Anna University
density correction factor is applied and the humidity correction factor is not applied. Air density factor ‘ d ‘ is given by, d = b / 273+ td Here ‘b’ is pressure in millibars and ‘ td ‘ is the dry bulb temp. 0C
Dr M A Panneerselvam, Professor, Anna University

40. Dr M A Panneerselvam, Professor, Anna University
When pressure is given in mm-Hg , d = b/ 273+ td
The table in next slide, gives the values air density correction factor for the calculated value air density factor ‘d’.
Dr M A Panneerselvam, Professor, Anna University

41. TABLE SHOWING AIR DENSITY CORRECTION FACTOR AND AIR DENSITY FACTOR
Note : FOR CHENNAI WEATHER CONDITIONS AIR DENSITY CORRECTION FACTOR IS EQUAL TO AIR DENSITY FACTOR
Dr M A Panneerselvam, Professor, Anna University

42. Humidity correction factor(kh):
COMPUTATION OF ABSOLUTE HUMIDITY FROM DRY AND WET BULB THERMOMETER TEMPERTURES
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43. Dr M A Panneerselvam, Professor, Anna University
HUMIDITY CORRECTION FACTORS
Dr M A Panneerselvam, Professor, Anna University

44. Dr M A Panneerselvam, Professor, Anna University
Calibration of Impulse Generator:
Calibration means getting the relationship between the input charging voltage and output voltage of the Impulse Generator for a given connected load.
Dr M A Panneerselvam, Professor, Anna University

45. Dr M A Panneerselvam, Professor, Anna University
Let us take testing of insulators for use in 132 kV system : The maximum system voltage is132 x 1.1 = 145 kV .
Assuming the system is effectively earthed the Power frequency withstand voltage level = 230 kV and the impulse voltage withstand level = 550 kV.
Dr M A Panneerselvam, Professor, Anna University

46. Dr M A Panneerselvam, Professor, Anna University
To test the insulator for an impulse voltage of 550 kV we should know the corresponding input charging level of the Impulse Generator and hence we do the calibration of the generator.
Dr M A Panneerselvam, Professor, Anna University

47. Dr M A Panneerselvam, Professor, Anna University
The calibration is generally done at a voltage of 50 to 75 % of the test voltage.
In this case since the test voltage is 550 kV the calibration is done at a level of 275 kV to 413 kV.
Let the Impulse Generator has 6 stages with a charging voltage of
Dr M A Panneerselvam, Professor, Anna University

48. Dr M A Panneerselvam, Professor, Anna University
200 kV. When the generator is connected for full series the output voltage of the generator is approximately 200 x 6 = 1200 kV. The test object is connected to the Impulse Generator as shown in the next slide.
Dr M A Panneerselvam, Professor, Anna University

49. Dr M A Panneerselvam, Professor, Anna University
MULTISTAGE IMPULSE GENERATOR CONNECTED TO POTENTIAL DIVIDER, MEASURING SPHERES AND LOAD
Dr M A Panneerselvam, Professor, Anna University

50. Dr M A Panneerselvam, Professor, Anna University
As the calibration has to be done at about 275 kV and referring to sphere gap standard , for 50 cm dia. spheres , a gap set for 15 cm the disruptive discharge voltage is 374 kV (which is 68 % of the test level) at STP for positive impulse.
Dr M A Panneerselvam, Professor, Anna University

51. Dr M A Panneerselvam, Professor, Anna University
Let us assume the following atmospheric conditions during the testing:
Dry bulb temp. = 30 deg. C , Wet bulb temp. = 24 deg. C and Pressure = 758 mm of Hg.
Dr M A Panneerselvam, Professor, Anna University

52. Dr M A Panneerselvam, Professor, Anna University
The air density factor = 0.386x758 / = 0.965
For Chennai weather conditions Air density correction factor = Air density factor , kd.
Dr M A Panneerselvam, Professor, Anna University

53. Dr M A Panneerselvam, Professor, Anna University
Hence, the disruptive discharge voltage for a gap setting of 15 cm for 50 cm dia. spheres = 374 x kd
= 374 x = 361 kV ( Note: Humidity correction is not applied for sphere gaps).
Dr M A Panneerselvam, Professor, Anna University

54. Dr M A Panneerselvam, Professor, Anna University
To get an output voltage of 361 kV , the charging level to the first stage of the Impulse Generator is approximately = 361 / 6 = 61 kV. Starting from a charging voltage of 55 kV to 65 kV, the 50 % disruptive discharge voltage for
Dr M A Panneerselvam, Professor, Anna University

55. Dr M A Panneerselvam, Professor, Anna University
this setting is obtained using average or up and down method. Let the 50 % disruptive discharge voltage so obtained is 63 kV. That is, a charging voltage of 63 kV gives an output voltage of 361 kV at RTP conditions.
Dr M A Panneerselvam, Professor, Anna University

56. Dr M A Panneerselvam, Professor, Anna University
Before the calibration procedure starts it is important to check the wave form of the impulse voltage and if it is not as per specification the parameters (R1 and R2)are changed to get the proper wave shape of 1 .2 / 50 μs.
Dr M A Panneerselvam, Professor, Anna University

57. Dr M A Panneerselvam, Professor, Anna University
Once the calibration is over , the test voltage levels to be applied at RTP conditions are calculated. i.e.,
V(RTP) = V(STP) x kd/kh
Humidity correction factor is obtained from the dry bulb
Dr M A Panneerselvam, Professor, Anna University

58. Dr M A Panneerselvam, Professor, Anna University
and wet bulb temperatures.
For td = 30 deg.C and tw= 24 deg.C the humidity is obtained from the graph as gm/m3 . From another graph the humidity correction factor for power frequency, positive and
Dr M A Panneerselvam, Professor, Anna University

59. Dr M A Panneerselvam, Professor, Anna University
negative impulses are obtained as 0.910, and respectively.
Hence the positive impulse to be applied at (RTP) conditions = 550 x / = 571 kV and for negative impulse =550x0.965 / = 565 kV
Dr M A Panneerselvam, Professor, Anna University

60. Dr M A Panneerselvam, Professor, Anna University
For power frequency tests, the cascaded transformer is calibrated and the relation between the input voltage and the output voltage is obtained.
The power frequency withstand
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61. Dr M A Panneerselvam, Professor, Anna University
level at STP for 145 kV insulator is 230 kV (RMS) The test voltage to be applied at RTP conditions =230 x / = 244 kV (RMS).
Dr M A Panneerselvam, Professor, Anna University

62. Dr M A Panneerselvam, Professor, Anna University
5.7 TESTS ON EXTERNAL INSULATIONS(WITHSTAND/ PUNCTURE/FLASHOVER TESTS UNDER DRY/WET CONDITIONS)
5.7.1 DC voltage tests: The voltage should be applied to the test object starting with a low value
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63. Dr M A Panneerselvam, Professor, Anna University
to prevent overvoltage due to switching transient but not so slowly as to cause unnecessary stress on the test object. The voltage is maintained for a specific time (as per standards) and then rapidly reduced. The
Dr M A Panneerselvam, Professor, Anna University

64. Dr M A Panneerselvam, Professor, Anna University
test object is supposed to have withstood the test if no discharge occurs.To obtain the disruptive discharge voltage , the voltage is raised as described above till the disruptive discharge occurs and the level is noted.
Dr M A Panneerselvam, Professor, Anna University

65. Dr M A Panneerselvam, Professor, Anna University
5.7.2 AC voltage tests:
The voltage should be applied as specified earlier (under DC test). The requirements during voltage application are generally met if the rate of rise above 75% of the test voltage is about 2 % per second. It should be maintained
Dr M A Panneerselvam, Professor, Anna University

66. Dr M A Panneerselvam, Professor, Anna University
for specified time (generally 60 sec.) and then rapidly decreased. The test object is supposed to have withstood the test if there is no disruptive discharge. For wet tests water spray as per specification should be used.
Dr M A Panneerselvam, Professor, Anna University

67. Dr M A Panneerselvam, Professor, Anna University
The voltage is increased further to obtain the disruptive discharge level.
5.7.3 Impulse voltage tests: Generally 15 impulses of the rated withstand voltage and of specified wave shape and polarity
Dr M A Panneerselvam, Professor, Anna University

68. Dr M A Panneerselvam, Professor, Anna University
are applied. The test object is supposed to have withstood if no disruptive discharge occurs in the non self restoring insulation and not more than one disruptive discharge occur in self restoring insulation. In addition the
Dr M A Panneerselvam, Professor, Anna University

69. Dr M A Panneerselvam, Professor, Anna University
oscillograms of the applied voltages are recorded and there should be no difference between the first and the fifteenth impulse and both should be exactly identical and look one and the same.
Dr M A Panneerselvam, Professor, Anna University

70. Dr M A Panneerselvam, Professor, Anna University
5.7.4 Switching surge tests:
As the system voltage increases beyond 400 kV, switching surge magnitude increases and becomes more severe. The general wave shape for the test is 250/2500 microseconds. The test
Dr M A Panneerselvam, Professor, Anna University

71. Dr M A Panneerselvam, Professor, Anna University
procedure for switching surges is the same as that of lightning impulse tests. Depending upon the particular type of equipment tested the wave shapes vary and 200/2000 microseconds or /3000 microseconds waves are used.
Dr M A Panneerselvam, Professor, Anna University

72. Dr M A Panneerselvam, Professor, Anna University
The impulse , switching surge and power frequency test voltage levels for testing equipment at different system voltages are given in the next slide.
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73. Dr M A Panneerselvam, Professor, Anna University

74. WITHSTAND LEVELS FOR SYSTEM VOLTAGES < 245 kV
POWER FREQUENCY AND IMPULSE TEST VOLTAGE
WITHSTAND LEVELS FOR SYSTEM VOLTAGES < 245 kV
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75. Dr M A Panneerselvam, Professor, Anna University
INSULATION LEVELS FOR SYSTEM VOLTAGES > 245 kV
Dr M A Panneerselvam, Professor, Anna University

76. SPECIMEN OSCILLOGRAMS TAKEN DURING IMPULSE TEST ON 11 kV INSULATOR
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77. Dr M A Panneerselvam, Professor, Anna University
5.8 POWER FREQUENCY / IMPULSE VOLTAGE WITHSTAND/FLASHOVER TESTS ON THREE PHASE CIRCUIT BREAKERS / ISOLATORS
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78. Dr M A Panneerselvam, Professor, Anna University
5.8.1 Modes of connections :
High voltage tests on 3 phase circuit breakers / isolators are conducted by connecting them in 5 different modes as given below:
With breaker/isolator contacts closed:
Dr M A Panneerselvam, Professor, Anna University

79. Dr M A Panneerselvam, Professor, Anna University
Mode 1 : Phase ‘RY’ connected together and earthed with frame and high voltage applied to ‘B’pahase.
Mode 2: Phase ‘YB’ connected together and earthed with frame and high voltage applied to ‘R’ phase.
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80. Dr M A Panneerselvam, Professor, Anna University
Mode 3: Phase ‘BR’ connected together and earthed with frame and high voltage applied to ‘Y’ phase.
With breaker / isolator contacts open:
Mode 4: One side of each pole connected together and earthed
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81. Dr M A Panneerselvam, Professor, Anna University
and the other side of the poles connected together and applied with high voltage.The frame is isolated.
Mode 5: Same as ‘Mode 4’ but high voltage lead and earth connections inter changed.
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82. Dr M A Panneerselvam, Professor, Anna University
TESTING OF 3 PHASE CIRCUIT BREAKER / ISOLATOR
Dr M A Panneerselvam, Professor, Anna University

83. OSCILLOGRAMS TAKEN DURING IMPULSE TEST ON 11 kV AIR BREAK SWITCH
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84. TESTING OF 3 PHASE 230 kV DISCONNECTING SWITCH
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85. TESTING OF 500 kV DISCONNECT SWITCH
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86. Dr M A Panneerselvam, Professor, Anna University
5.9 IMPULSE VOLTAGE WITHSTAND TEST(INCLUDING CHOPPED WAVES) ON POWER TRANSFORMERS / DISTRIBUTION TRANSFORMERS
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87. Dr M A Panneerselvam, Professor, Anna University
5.9.1 introduction :
In case of power transformers both primary and secondary windings are subjected to impulse test as both the windings are HV windings. They are exposed to open atmosphere and hit by lightning strokes (Ex. 66 kV/ 11 kV).
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88. Dr M A Panneerselvam, Professor, Anna University
But, the distribution transformers are subjected to impulse test only on high voltage winding. The low voltage winding is generally connected to distribution network and are not likely to be hit by lightning (Ex.11 kV/ 420 V).
Dr M A Panneerselvam, Professor, Anna University

89. IMPULSE TESTING OF 3 PHASE TRANSFORMER
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90. Dr M A Panneerselvam, Professor, Anna University
Unless and otherwise stated , impulse test on transformers are conducted generally with negative polarity impulse.
The sequence of voltage applications given below:
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91. Dr M A Panneerselvam, Professor, Anna University
One full wave at reduced BIL recorded with lesser time base.
(ii) One full wave at reduced BIL(same as (i)) recorded with higher time base.
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92. Dr M A Panneerselvam, Professor, Anna University
(iii) One full wave at 100 % BIL recorded with higher time base.
(iv) One chopped wave at reduced BIL recorded with lesser time base..
Dr M A Panneerselvam, Professor, Anna University

93. Dr M A Panneerselvam, Professor, Anna University
(v) & (vi) Two chopped waves at 100 % BIL recorded with lesser time base.
(vii)&(viii) Two full waves at 100 % BIL recorded with higher time base
Dr M A Panneerselvam, Professor, Anna University

94. TYPICAL OSCILLOGRMS TAKEN DURING IMPULSE TEST ON TRANSFORMER
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95. TYPICAL OSCILLOGRMS TAKEN DURING IMPULSE TEST ON TRANSFORMER
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96. 100kVA, 11kV/433V three phase Distribution Transformer
Oscillograms taken during the impulse voltage withstand test on
100kVA, 11kV/433V three phase Distribution Transformer
Plate 1 : Reduced BIL waves (56.25kV at STP) recorded on 10s / division.
100% BIL waves (75kV at STP) recorded on 10s / division
Plate 2 : Reduced chopped wave (60kV at STP) recorded on one s./division
Plate 3 : First 100% chopped waves (75kV at STP) recorded on one s./division
Second 100% chopped waves (75kV at STP) recorded on one s./div.
Plate 4 :100% BIL waves (75kV at STP) recorded on 10s / division % BIL waves (75kV at STP) recorded on 10s / division
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97. Dr M A Panneerselvam, Professor, Anna University
OSCILLOGRAMS TAKEN DURING IMPULSE VOLTAGE WITHSTAND TEST ON 250kVA, 11kV/433V, THREE PHASE DISTRIBUTION TRANSFORMER PHASE A
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98. Dr M A Panneerselvam, Professor, Anna University
PHASE B
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99. Dr M A Panneerselvam, Professor, Anna University
PHASE C
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100. Dr M A Panneerselvam, Professor, Anna University
5.10 FAILURE REPORTS
Case 1 : 100kVA, 11kV/433V Al WOUND TRANSFORMER
(shows the progressing failure in the winding insulation)
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101. Dr M A Panneerselvam, Professor, Anna University
Case II : 315kVA, 22kV/433 V Cu wound three phase distribution transformer
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102. Dr M A Panneerselvam, Professor, Anna University
Case iii : 22kV metering Unit (CT)
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103. Dr M A Panneerselvam, Professor, Anna University
Case iv : 12KV, 630A, 20KA, SF6 Load Break Fault Make switch
FIRST AND FIFTEENTH POSITIVE AND NEGATIVE IMPULSE VOLTAGES APPLIED AT 75 KV IN MODE I TO MODE IV.
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104. 5.10 INSULATION COORDINATION
Insulation Coordination is the correlation of the characteristics of the protective devices and the equipment connected in the power system
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105. Dr M A Panneerselvam, Professor, Anna University
such that the equipment and the system are well protected by the protective devices in the event of excessive over voltages.
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106. Dr M A Panneerselvam, Professor, Anna University
Fixing of BIL for power system operating at 132 kV:
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107. Dr M A Panneerselvam, Professor, Anna University
Let us first consider that the system is not effectively earthed, in which case the coefficient of earthing (COE) is unity.
The rating of the lightning arrester is chosen as 132 x 1 = 132 kV
Dr M A Panneerselvam, Professor, Anna University

108. Dr M A Panneerselvam, Professor, Anna University
The discharge voltage for this rating of the arrester = 132 x 3 (taken from arrester manual)= 396 kV.
Allowing 40 % excess for reflection and refraction at the terminal end, the voltage at the transformer terminal = 396 x 1.4 = 555 kV.
Dr M A Panneerselvam, Professor, Anna University

109. Dr M A Panneerselvam, Professor, Anna University
Further allowing a margin of about 60 kV the insulation level becomes = = 615 kV
Choosing the next slab in the insulation level, the BIL is selected as 650 kV.
Dr M A Panneerselvam, Professor, Anna University

110. Dr M A Panneerselvam, Professor, Anna University
Let us now assume the system to be an effectively earthed system, for which the COE is taken as less than 75 % Working on the same line as earlier, the rating of the lightning arrester is chosen as 132x0.75 = 99 kV.
Dr M A Panneerselvam, Professor, Anna University

111. Dr M A Panneerselvam, Professor, Anna University
The residual voltage for this rating from the arrester manual = 99 x 3 = 297 kV . Allowing 40 % excess for reflection and refraction , the voltage at the transformer terminal rises to = 297 x 1.4 = 416 kV.
Dr M A Panneerselvam, Professor, Anna University

112. Dr M A Panneerselvam, Professor, Anna University
Allowing a margin of 60 kV , insulation level becomes = = 476 kV
Choosing the higher slab of insulation the BIL is selected as kV.
This level is known as reduced BIL.
Dr M A Panneerselvam, Professor, Anna University

113. Dr M A Panneerselvam, Professor, Anna University
Hence, it is seen that as the system becomes effectively earthed the insulation level is reduced resulting in great saving of insulation and cost.
Dr M A Panneerselvam, Professor, Anna University