500KV BUSHINGS FAILURES AND BUSHING OIL SAMPLING PROGRAM. Mike Lau BC Hydro

500KV BUSHINGS FAILURES AND BUSHING OIL SAMPLING PROGRAM Mike Lau BC Hydro ABSTRACT In June 2001, a 500KV bushing ( CGE, type U ) failed and resulted in a catastrophic failure of a generator step-up transformer in one of our major generating facility. Moisture ingress was the primary suspected cause of failure. Since then, an oil sampling program on bushings was launched and a high percentage of bushings were found to have either high moisture and/or high combustible gases. One 230KV ( CGE Type F ) bushing was found to have high combustible gases and subsequent investigation revealed heavy tracking on the innermost Herkolite cylinder. A few other 500KV bushings ( Bushing Company Type 500HA67B ) was found to have moisture ingress through the top filling plugs. Amidst all these bushing testing and change-out activities, another 500KV ( A hybrid unit -- ABB Type O plus C and CGE Type U ) bushing failed while in service on a relatively new ( in service in 1994 ) shunt reactor in November, 2001. Two months later, another 500KV ( similar hybrid unit ) bushing on the same shunt reactor also failed and resulted a huge fire which burnt for hours. Investigation on the failures of these hybrid bushings continues at the time of writing and no firm conclusion on the cause of failures can be drawn. This paper provides some details on the bushing failures and oil sample results. INTRODUCTION Small oil volume apparatus, such as oil-filled current transformers, potential transformers and bushings contain small amount of oil which could be easily contaminated and greatly reduce its insulation integrity. The failures of these apparatus are usually explosive with ensuing fires and detrimental to both equipment and personnel. Until recently, in BC Hydro, except for Doble testing, no other routine testing are specified for these apparatus. Oil samples had been taken from some makes of CT s in the past but only for diagnostic purposes and oil sampling was certainly not a routine maintenance task. However, with recent failures of 500KV bushings and poor test results on oil samples taken from other bushings, the current maintenance practices on bushings needed to be re-examined. BACKGROUND Failure of a 500KV CGE Type U Bushing ( Note : Not to be confused with GE Type U ) In June 2001, at the G.M. Shrum Generating Station, one 500KV bushing on one of the unit transformer, T4C, failed violently with all the porcelain ( both above and below the mounting flange ) blew up into pieces the size of a fist. Oil was drained out of the conservator tank through the bushing and fires started 1

both on top and at the bottom of the tank. Fortunately, the sprinkler systems operated ( the heat was so intense that the sprinkler system for the adjacent bank also operated) and cooled down the adjacent equipment allowing the fire crew put out the fire eventually. An internal explosion was evident from the bulging and welding cracks on the tank. There were severe damages internally that the transformer was scraped. (Photos 1,2,3, and 4). Investigation of the failed bushing confirmed a dielectric failure with the paper insulation punctured through from the center draw rod, at a location about one third of the way down from the top terminal, to the grounded capacitance tap. While the construction of the CGE Type U bushings ( manufactured by Canadian General Electric in Guelph, Ontario )was different from that of a GE type U ( ie no herring-bone inking process ), we were surprised to see the capacitance layers were made up of paper coated with some semi-conductive graphite like material. Smears of this material was evident in many places ( Photo 5 ). The subject bushing was Doble tested in Oct 1998 and both C1 and C2 insulation power factors were good. No definite cause of failure was determined and external moisture ingress was the primary suspected cause. INITIAL OIL SAMPLING PROGRAM Prior to the above bushing failure incident, oil samples were rarely taken from small oil volume apparatus including oil-filled bushings. After the incident, it was decided that additional information on the condition of the bushings is needed and a small scale oil sampling program was launched. Oil samples were taken from all other 500KV bushings in GM Shrum Generating Station. The results was very alarming: Of a total of 41 other bushings (of different manufacturers including CGE, Bushing Company, and Toshiba ), 11 bushings (27%) were found to have either unacceptable DGA results or unacceptable high moisture content. The results are included in Appendix 1. Further investigation on those bushings with unacceptable results were carried out and detailed below. INVESTIGATION OF BUSHING PROBLEMS Of the 11 bushings that there found bad, 8 were found to have high moisture content ( 23ppm to 72 ppm ); 3 were found to have abnormal amount of combustible gases. All 11 bushings were removed from services for further investigation and dryout. A. High Moisture Content A1. The GMS T4A bushing ( CGE Type U, with 62 ppm of H2O ) was removed from service and sent to Powertech Lab for partial discharge ( PD ) test. It failed the PD test. The unit was subsequently drained, dried out extensively with high vacuum and heat, refilled under vacuum. Subsequently, it passed the PD test and returned to service without incident. A2. Other CGE Type U bushings found to have high moisture content, such as GMS T1B ( 23 ppm ), T12A ( 52 ppm ), and T14A ( 62 ppm ), were all similarly dried out extensively with heat and high vacuum, tested, and returned to service without incident. 2

A3. GMS T8C ( with 65 ppm of H2O ) and T9C ( with 72 ppm of H2O ) were both Bushing Company bushings, Cat # ART-500HA67B. The location and the likely causes of moisture ingress have been identified: With reference to Figure 1, moisture was found getting inside the bushings through the small oil filling plugs (Item 10) located on the top of the expansion metal can (Item13) and inside the terminal cap (Item 1). The underside surface of the oil filling plugs were found to be rusty and the surfaces inside of the terminal caps were coated with white powdery material indicating signs of moisture ingress. Further investigation revealed that the moisture somehow managed to penetrate three layers of protection; namely ; the outer gasket seal for the terminal caps ( gaskets found to be brittle and cracked ); the inner gasket seal ( gasket found to be in reasonably good order, but the caps were not seating squarely due to the ends of some helical coils improperly protruding outside of their threaded holes ), and finally the sealing washers of the oil filling plugs ( washers found missing completely! ). Other Bushing Company bushings were checked but so far none was found to have a similar problem. The two bushings were also dried out, tested, and returned to service without incident. B. Abnormal amount of combustible gases B1. GMS T10B was found to have high combustible gases ( but only 1 ppm of C2H2 ). This CGE Type U bushing was removed from service and sent to Powertech Labs for testing. Surprisingly, it passed the PD test. However, there is a significant difference in the Dissipation Factor measured before (0.49%) and after ( 0.74%) the AC withstand test. Further investigation is pending, and the bushing will not be returned to service B2. GMS T7B and GMS T7C Both have high combustible gases including a fair amount of C2H2 ( 62 and 60 ppm respectively ). These two bushing were Doble tested prior to their removal from the transformer. The Doble test results are enclosed in Appendix 2. It was reported that on the GMS T7C bushing, oil was dripping out of the capacitance tap continuously when the cap was removed. The oil was black and had a burnt smell to it. This bushing failed the PD test miserably. These two bushings, together with a third one from another station (WSN T4A), which also has high combustible gases ( 3005 ppm of C2H2 ), will be returned to the manufacturer in UK for investigation and possible refurbishment. B3. A 230 KV bushing, CGE Type F bushing at Rosedale Substation, (ROS T1A Low Voltage bushing), was found to have high combustible gases. It was immediately removed from service. The bushing was subsequently dismantled for examination. Heavy tracking was found on the bottom end of the innermost Herkolite cylinder. See Photo 6. This bushing was scraped. EXPANDED BUSHING OIL SAMPLING PROGRAM Encouraged with the success of the oil sampling program, the program has been extended to include other 500 KV bushings in all our generating stations and in some critical transmission stations. 3

MORE FAILURES OF 500KV BUSHINGS As if we don t have enough bushing problems, in November 2001, another 500 KV bushing failed on a shunt reactor at Kelly Lake Substation ( KLY 5RX5 ). The reactor is a relatively new 3-phase 135 MVAR unit put in service in 1994. Dark oil and burnt paper sprayed out from the joints between sections of the porcelain. No porcelain were broken and no significant damages to the reactor. The bushing was replaced with a new spare. All the bushings as well as the reactor were Doble tested satisfactory and the unit was returned to service in early December 2001. Two months later, in the mid-night hours of 26 February 2002, another 500 KV bushing on the same shunt reactor failed explosively and resulted a huge fire which burnt for 4-5 hours. It destroyed the adjacent new spare bushing, a surge arrestor and caused significant damages to the adjacent circuit breaker.( see photo 7 ). These two failed bushings were hybrid units made with ABB condenser core ( with semi-conductive capacitance layers ) and other CGE Type U components. A type problem was suspected and consequently, two other similar 500 KV shunt reactors were removed from service pending further investigation. CONCLUSION Failures of small oil volume apparatus, such as bushings, are often explosive with ensuing fires, and are indeed great threats to personnel and equipment. On-line monitoring equipment are readily available to monitor the integrity of bushings by means of unbalanced neutral current, leakage current, power factor etc. However, it would be difficult, if not impossible, to justify economically, on-line monitoring equipment on every bushing. As demonstrated in this paper, oil testing for DGA and moisture content prove to be a good compliment to other routine testing to provide additional information on the integrity of bushings. It would also be desirable that a guide or a standard be established for the acceptable gas level limits and interpretation of the DGA results. 4

Photo 1 : GMS Generator Step up Transformer banks Photo 2: Overview of faulted bushing on GMS T4C 5

Photo 3 : GMS T4C Overview of faulted bushing 6

Photo 4 : GMS T4 C Removal of faulted bushing 7

Photo 5 : GMS T4C Bushing Tracking on semi-conductive paper Photo 6 : CGE Type F bushing : Tracking on ht e innermost Herkolite cylinder 8

Photo 7; KLY 5RX5 Failure of ABB/CGE hybrid bushing. 9

FIGURE 1: VIEW OF BUSHING COMPANY BUSHING TOP ASSEMBLY 10

APPENDIX 1 DISSOLVED GAS IN OIL RESULTS IN BUSHINGS STN UNIT PH DATE C2H2 C2H4 C2H6 CH4 CO CO2 H2 H2O N2 O2 VOLUME GMS T1 B 20-Jul-01 < 1 2 15 600 1348 81 23 91308 4775 9.81% GMS T1 C 20-Jul-01 < < 2 10 704 1107 123 10 97893 2116 10.20% GMS T1 A 11-Oct-01 < 20 45 17 315 1357 382 4 65714 351 6.82% GMS T2 A 06-Oct-01 < < 15 6 39 1019 5 8 78300 4704 8.41% GMS T2 B 06-Oct-01 < 1 10 7 45 1126 6 7 81282 3224 8.57% GMS T2 C 06-Oct-01 < < 10 9 80 1443 31 4 85336 270 8.72% GMS T3 A 06-Oct-01 < < 11 7 71 1737 14 46 74533 2730 7.91% GMS T3 B 06-Oct-01 < < 10 6 57 1341 5 6 80362 2624 8.44% GMS T3 C 06-Oct-01 < 2 58 27 214 1898 15 25 57074 1935 6.12% GMS T4 B 04-Jul-01 < < 1 9 597 1173 116 3 80684 1729 8.43% GMS T4 A 04-Jul-01 < 3 2 9 568 4828 27 62 76905 3537 8.59% GMS T5 C 04-Oct-01 < 1 4 8 90 2589 3 9 75005 1617 7.93% GMS T5 A 04-Oct-01 < < 6 8 73 1055 2 7 70142 2615 7.39% GMS T5 B 04-Oct-01 < 1 4 10 145 1756 38 8 79320 402 8.17% GMS T6 B 18-Sep-01 < 13 6 3 106 1598 25 5 60017 24002 8.58% GMS T6 A 18-Sep-01 < 2 56 66 238 2393 3 7 37855 7439 4.81% GMS T6 C 18-Sep-01 < 14 7 21 556 2620 145 3 62248 1984 6.76% GMS T7 B 05-Sep-01 62 1862 302 790 932 6413 407 4 58684 6843 7.63% GMS T7 C 05-Sep-01 60 367 115 276 259 1128 853 5 54601 383 5.80% GMS T7 A 05-Sep-01 < 1 15 25 219 757 442 3 66739 6088 7.43% GMS T8 C 22-Sep-01 < 2 16 31 337 1530 404 65 58803 2531 6.37% GMS T8 B 22-Sep-01 < 1 34 49 94 479 314 4 49937 572 5.15% GMS T8 A 22-Sep-01 2 6 47 32 78 854 298 5 48412 1744 5.15% GMS T9 A 22-Sep-01 < 4 64 40 162 1118 265 8 79732 706 8.21% GMS T9 C 22-Sep-01 < 4 31 30 221 1335 894 72 65444 853 6.88% GMS T9 B 22-Sep-01 < 7 49 28 359 3263 35 13 79760 4358 8.79% GMS T10 A 15-Aug-01 < 2 2 12 931 1915 12 5 53334 3185 5.94% GMS T10 B 15-Aug-01 1 263 216 638 800 5993 1172 6 57785 905 6.78% GMS T10 C 15-Aug-01 < 2 5 27 585 1733 44 7 90869 1196 9.45% GMS T11 C 26-Aug-01 < 1 1 4 405 632 71 9 64862 2489 6.85% GMS T11 A 26-Aug-01 < 1 1 5 588 903 144 10 71113 1257 7.40% GMS T11 B 26-Aug-01 < 2 1 3 334 573 70 7 41533 1753 4.43% GMS T12 A 30-Aug-01 < 1 1 4 488 2910 94 52 64272 2465 7.02% GMS T12 C 30-Aug-01 < 2 2 3 427 1981 127 11 69358 1691 7.36% GMS T12 B 30-Aug-01 < 1 1 6 538 638 72 10 57308 1310 5.99% GMS T13 A 30-Oct-01 < < 1 5 448 474 54 2 55436 1300 5.77% GMS T13 B 30-Oct-01 < 1 3 6 483 1571 51 3 84235 1610 8.80% GMS T13 C 30-Oct-01 < < 2 5 243 444 24 4 65088 3709 6.95% GMS T14 A 14-Nov-01 < 2 3 6 815 2216 68 62 84741 1007 8.89% GMS T14 B 14-Nov-01 < 2 2 10 1181 3085 12 4 64593 7670 7.66% GMS T14 C 14-Nov-01 < 2 2 6 786 2240 71 3 81460 3632 8.82% ROS T1-X A 22-Oct-01 2096 1583 293 845 495 4425 854 64 84398 9755 10.47% WSN T2 A 14-Nov-01 3005 2681 307 1579 189 433 5520 3 46993 7498 6.82% 11

Appendix 2 a Doble test result of GMS T7B bushing Company : BC Hydro Test Date: Sep 30 2001 Division: NORTHERN (PA) Location: GMS (G.M. SHRUM) Special ID: 2-4230 CCT Desig: T7-B Mfr: Pi Yr Mfr: 1970 Serial #: WT 1632-1 Ph : 1 Cfg: 1-PHASE kv : 512.5/13.8 MVA:44.6 / 59.8 / 80.0 // Tanktype: SEALED- CONSER Coolant: OIL Air temp: 14 C Apparatus temp: 12 C RH:26% Weather: PTCLDY Bushing Tests C1 Nameplate Data Test Results Bush Mfr Type S/N Cap(pF) %PF kv %PF Cap(pF) RTG ------------------------------------------------- -------------------- ----- H1 BUSH 506 10.0 0.50 507.80 G 1.0 0.52 508 D C2 Nameplate Data Test Results Bush Mfr Type S/N Cap(pF) %PF kv %PF Cap(pF) RTG ------------------------------------------------- -------------------- ----- H1 BUSH 8300 1.0 0.47 9107 I 12

Appendix 2b Doble test results of GMS T7C bushing Company : BC Hydro Test Date: Sep 30 2001 Division: NORTHERN (PA) Location: GMS (G.M. SHRUM) Special ID: 2-4229 CCT Desig: T7-C Mfr: Pi Yr Mfr: 1970 Serial #: WT 1633-1 Ph : 1 Cfg: 1-PHASE kv : 512.5/13.8 MVA:44.6 / 59.8 / 80.0 // Tanktype: SEALED- CONSER Coolant: OIL Air temp: 15 C Apparatus temp: 12 C RH:50% Weather: PTCLDY Bushing Tests C1 Nameplate Data Test Results Bush Mfr Type S/N Cap(pF) %PF kv %PF Cap(pF) RTG ------------------------------------------------- -------------------- ----- H1 Bush OTHER 5BBf9972 501 0048 10.0 0.53 515.70 D I 1.0 0.54 515.90 D I C2 Nameplate Data Test Results Bush Mfr Type S/N Cap(pF) %PF kv %PF Cap(pF) RTG ------------------------------------------------- -------------------- ----- H1 Bush OTHER 5BBf9972 9100 1.0 0.48 8900 G I 13