MEC&F Expert Engineers : UNDERGROUND EXPLOSIONS AND FIRES IN HARTFORD & WEST HARTFORD, CONNECTICUT

Sunday, April 5, 2015

UNDERGROUND EXPLOSIONS AND FIRES IN HARTFORD & WEST HARTFORD, CONNECTICUT









APRIL 5, 2015




HARTFORD, CONN. (WTNH)

An underground electrical issue has left thousands of Eversource customers without power in Hartford and West Hartford. At one point, more than 8,000 customers were without power. That number has come down.

Eversource says the outages happened Sunday right around midnight along Farmington Avenue in Hartford. There was an electrical problem inside an underground utility vault. It caused a small explosion and then a fire.

Crews have been on scene since the issue happened trying to fix the problem and restore power to the thousands of customer that are impacted. At last check, Eversource says the issue may not be fixed until 7 p.m. Sunday.

As crews work on the problem, Farmington Avenue is shutdown near Sisson Avenue.


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HOW DO UNDERGROUND AND ABOVEGROUND ELECTRIC TRANSFORMERS EXPLODE






Electrical transformers transfer energy between circuits, switching energy from one voltage to another. But when flooded with too much electricity, the sudden surge can cause a transformer explosion. As transformers detect an energy spike, they're programmed to turn off, but it can take up to 60 milliseconds for the shutdown. However fast those milliseconds may seem, they still may be too slow to stop the electrical overload.

A chamber full of several gallons of mineral oil keeps the circuits cool, but given too much electricity, the circuits fry and melt, failing in a shower of sparks and setting the mineral oil aflame. Mineral oil, in turn, combusts explosively and rockets transformer scything into the air.

All it takes is a trigger, a corroded or faulty wire, and the circuits surge will get ahead of the breaker--and in New York City, the previous day's snowstorm could have done the trick. Underground electric systems often suffer problems after heavy snowfall, says Bob McGee, a spokesperson for Con Ed. While salting streets may make vehicles and pedestrians safer, the salt can create hazardous conditions for underground electrical systems--salt that slips through manholes can corrode wires. 

If any arcing failure occurs within an oil-impregnated-paper (OIP) bushing, it frequently results in an explosive failure, causing arcing in the air, an oil spill and a major oil fire. This is not the case with resin-impregnated polymer insulator bushings.

Manhattan houses 35,000 underground and 47,000 overhead transformers for its 10 million residents, and of those 82,000, about 35 fail every year, McGee says. A failure doesn't always equate to a fire or explosion either; in fact, in the steadily decreasing number of failures per year, such an explosion is rare.
Cable terminations failures in air- or oil-filled cable boxes also result in a high percentage of transformer fires. The typical scenario with oil-filled cable boxes is the initiation of an arcing fault in or at the cable termination. The pressure buildup from the arc ruptures the cable box explosively, ignites oil in or from the cable box, which continues and escalates as it gets fueled by oil spilling from the conservator or the main tank.

Mechanical forces on the cables from the explosive pressure forces and the fault current will often cause breakage of the bushings, and the oil spilling from the broken bushings will then be ignited by the arc.

Though the snowstorm may have had something to do with the incident, it will take time to analyze just what went wrong. If it turns out the salt from the snowstorm wasn't to blame, it may have been an older transformer. These can explode when their insulating materials begin to fail. This happens as cellulose and oil absorb water over time and degrade cellulose's ability to insulate, triggering an explosion.

The U.S. expanded its electrical infrastructure in the 1950s and '60s, and now, most older transformers have met or are nearing the end of their operational lives of between thirty to forty years.