j_p_c
Electrical
- Sep 6, 2018
- 19
Hi All,
Thanks in advance for your thoughts. I post once every few years or so, but read often. Application is in North America.
We had a brand new 72 kV dry-type cast epoxy resin voltage transformer fail catastrophically recently. No personnel were harmed, but easily could have been. Collateral damage to surrounding yard equipment was significant, leading to a long down time period for the client.
In discussion w. other industry colleagues, I've now been hearing of other epoxy type VTs that have failed in a dramatic fashion --> heavy, far flung projectiles.
We were unable to determine the root cause of the failure, so I wanted to reach out to the ET community to see if any one else has seen this, or has done or found research on the matter.
The voltage transformers were installed as a replacement to oil filled CVTs (functioning perfectly well) to meet a utility specification for two secondary voltage winding ratings that would meet their revenue meter input voltage required rating (115V instead of 69V), it was a straightforward replacement with the utility specifying the unit as one of their standards.
After initial energization (~2h) one of the phases began to boil off its resin and smoke, and within minutes exploded catastrophically.
Before energization, all three units tested well under NETA site acceptance criteria (insulation resistance, ratio, winding resistance, secondary burden) and the accompanying comprehensive factory results were all excellent. Power factor testing did not give intelligible results, this was expected as per the manufacturer for this dry type insulation system. We did not do an induced (from the secondary) voltage test of the primary, as it is an optional test. An applied (withstand) voltage test of the primary was not possible as the neutral was insulated to ground.
A potential influencing factor is that it was discovered during startup that the instrument secondary neutral ground wire had been lifted by the contractor and not fully replaced, they had signed off on tighten and tug tests and then went in to address a deficiency and tape the ground connection green, and it seems had disconnected the wire to tape it and replace it, rather than just taping in place. The unlanded ground was found because the line relays were indicating mild imbalance in the measured secondary voltages (off by ~15%), once the circuit was isolated, and the wire landed voltages sprang back to expected nominal. The mild imbalance was measured both at the relay HMI, and via handheld meter, phase to cabinet ground.
Notes:
- the H2 bonding jumper to ground was properly
- VTs are wye grounded-wye grounded, and on the utility line side of customer delta high side transformer winding. Utility is solidly grounded from their end.
- identical replacement VT units are now installed and the customer is back up and running again
- the other two units that were installed next to the failed one were fully factory re-tested and passed well.
- no fusing on the VT primaries
- line relays detected a steady reduction in failed VT phase voltage (indicating a steady increase in ratio) over the course of 5-10 minutes, before tripping the load end at 0.8 pu (not the utility end unfortunately), total failure was 5-10 mins after that.
- the after effect look of the VT is similar to that shown in this paper:
So, if you've read to this point, thanks! Any and all insights/experiences as to the general application and reliability of epoxy resin type instrument transformers, especially at 72kV are appreciated. Any further insights as to our particular failure mode are also appreciated. I can imagine that a turn to turn fault that was too small to come out through winding resistance and turns ratio tests could eventually progress through heating to a winding failure. I can also imagine scenarios where a turn-turn fault leading to an arcing ground fault, and possibly a transient overvoltage on the secondary (thinking of the ungrounded neutral here) could also lead to a failure of this kind. This latter imagining would be a good dose of bad luck consisting of a double contingency of turn to turn fault AND an unlanded neutral ground.
JPC
Thanks in advance for your thoughts. I post once every few years or so, but read often. Application is in North America.
We had a brand new 72 kV dry-type cast epoxy resin voltage transformer fail catastrophically recently. No personnel were harmed, but easily could have been. Collateral damage to surrounding yard equipment was significant, leading to a long down time period for the client.
In discussion w. other industry colleagues, I've now been hearing of other epoxy type VTs that have failed in a dramatic fashion --> heavy, far flung projectiles.
We were unable to determine the root cause of the failure, so I wanted to reach out to the ET community to see if any one else has seen this, or has done or found research on the matter.
The voltage transformers were installed as a replacement to oil filled CVTs (functioning perfectly well) to meet a utility specification for two secondary voltage winding ratings that would meet their revenue meter input voltage required rating (115V instead of 69V), it was a straightforward replacement with the utility specifying the unit as one of their standards.
After initial energization (~2h) one of the phases began to boil off its resin and smoke, and within minutes exploded catastrophically.
Before energization, all three units tested well under NETA site acceptance criteria (insulation resistance, ratio, winding resistance, secondary burden) and the accompanying comprehensive factory results were all excellent. Power factor testing did not give intelligible results, this was expected as per the manufacturer for this dry type insulation system. We did not do an induced (from the secondary) voltage test of the primary, as it is an optional test. An applied (withstand) voltage test of the primary was not possible as the neutral was insulated to ground.
A potential influencing factor is that it was discovered during startup that the instrument secondary neutral ground wire had been lifted by the contractor and not fully replaced, they had signed off on tighten and tug tests and then went in to address a deficiency and tape the ground connection green, and it seems had disconnected the wire to tape it and replace it, rather than just taping in place. The unlanded ground was found because the line relays were indicating mild imbalance in the measured secondary voltages (off by ~15%), once the circuit was isolated, and the wire landed voltages sprang back to expected nominal. The mild imbalance was measured both at the relay HMI, and via handheld meter, phase to cabinet ground.
Notes:
- the H2 bonding jumper to ground was properly
- VTs are wye grounded-wye grounded, and on the utility line side of customer delta high side transformer winding. Utility is solidly grounded from their end.
- identical replacement VT units are now installed and the customer is back up and running again
- the other two units that were installed next to the failed one were fully factory re-tested and passed well.
- no fusing on the VT primaries
- line relays detected a steady reduction in failed VT phase voltage (indicating a steady increase in ratio) over the course of 5-10 minutes, before tripping the load end at 0.8 pu (not the utility end unfortunately), total failure was 5-10 mins after that.
- the after effect look of the VT is similar to that shown in this paper:
So, if you've read to this point, thanks! Any and all insights/experiences as to the general application and reliability of epoxy resin type instrument transformers, especially at 72kV are appreciated. Any further insights as to our particular failure mode are also appreciated. I can imagine that a turn to turn fault that was too small to come out through winding resistance and turns ratio tests could eventually progress through heating to a winding failure. I can also imagine scenarios where a turn-turn fault leading to an arcing ground fault, and possibly a transient overvoltage on the secondary (thinking of the ungrounded neutral here) could also lead to a failure of this kind. This latter imagining would be a good dose of bad luck consisting of a double contingency of turn to turn fault AND an unlanded neutral ground.
JPC