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The photo to the left will link you to an amazing video (~1.5 Mb) of a ½ million volt switch failing to interrupt the arc when operating. Special thanks to Old Crow for hosting this popular video. If you are interested in some light technical analysis of what you are looking at, see the text below this photo. |
I was not given the details of this
clip when it was sent to me. However, a couple of
days ago, I
received an e-mail from the person actually running the video camera.
He basically
confirmed my analysis of the switch operation and a few other details.
Based on what I do know about the equipment
in the video, what I see, and now what
has been reported
to me first hand, I offer the following info:
The video was
taken at Eldorado Substation in Boulder City, NV. The file is called
Lugo because
this switch and shunt reactor are on the line that goes to Lugo.
This
one is clearly a 500KV (I can tell
by the size) three-phase switch, probably rated at
about 2000 amps of normal current
carrying capability. 500 KV refers to the phase-
to-phase voltage. Divide by 1.732
to get the phase-to-ground voltage (289 KV).
This type of switch typically is used
at one end of a transmission line, in some cases in
conjunction with or instead of a circuit
breaker for a variety of different configuration
reasons that vary greatly from one
utility to the other. Or, it may be used to connect a
large transformer to the system.
In this case, the switch is being used
to connect a special kind of transformer. The 3
single-phase transformers can be seen
behind the truck. I say transformer, but as you
can see, they have leads going in,
but not coming out. These are actually single winding
inductors connected from phase to
ground and are commonly called "shunt reactors."
These inductors are installed to offset
the capacitive effects of un-loaded transmission
lines, When a long 500 KV or 765 KV
line is energized from one end, its inherent
capacitance causes an unacceptable
voltage rise on the open end of the line. The
"shunt reactor" is installed to control
that open-circuit voltage. Where current into the
capacitor component of the line impedance
leads voltage by 90 degrees, current into
the shunt reactor lags voltage by
90 degrees. I have since learned that these shunt
reactors are rated at 33.3 MVAR each
to make up a 100 MVAR bank.
The switch being opened is called a
"circuit switcher." It consists of two series SF6
gas puffer interrupters (similar to
a circuit breaker) and an integrated center-break
disconnect. The interrupters are to
the right of the switch blades. They just look like
gray porcelain insulators. At 345
and 500 KV these types of switches typically have
two interrupters per phase in series
in order to withstand the open circuit voltage
encountered when de-energizing a line
or transformer. They rely on synchronized
opening of the two interrupters and
voltage even distributed across the two interrupters
by "grading" devices (typically lots
of series capacitors or resistors).
The way they are supposed to work is
the interrupters both trip, grading capacitors or
resistors cause the open circuit voltage
to split evenly across the two interrupters, the
switch blades open with no current
flow, and the interrupters close as the switch
reaches the full open position. I
originally titled this very BIG capacitor because that
is what unloaded transmission line
looks like. The parallel wires have a huge capacitive
effect between ground and each other.
On a 500KV line like this the current (leading the
voltage by 90 degrees) required to
energize this capacitor is approximately 1.8
amps
per-mile of line per phase. That's
1.8 amps per phase at 289KV,
or about 1.56 Mega
Vars (million volt amps reactive)
per mile. However, we are actually looking at the shunt
reactor current which is inductive
and lags the voltage by 90 degrees. So, I should have
said "very big inductor."
The switch operation you see in this
video in my opinion is a failed attempt to interrupt
that inductive current. The failure
appears to be that the far right interrupter does not
open or the grading device has failed.
The voltage across the remaining open
interrupter exceeds the rating and
it flashes over (you can see the first arc develop
across one interrupter). Therefore,
the switch blades are left to interrupt the current (not
designed to do that) as they open.
As the interrupter closes you can see the arc across
it go out. However, the arc across
the switch gets as tall as a 3 story building. The
arc
is extinguished
only when the circuit breaker energizing the line, circuit switcher, and
reactor is opened
by the operator. Because some trouble was expected on the
switch, arrangements
had been made ahead of time to trip open the circuit breaker if
necessary. This
is the only failure I have ever seen where the arc lasted so long and
grew so large without first going
phase-to-phase or phase-to-ground taking the circuit
out of service. It just keeps growing
straight up where it contacts nothing.
Since I have seen many people speculate
as to the amount of current in the arc, I will
offer the actual calculations that
are based on the assumption that the switch is only
interrupting the current into the
shunt reactor and the second hand report I received
that this is a 100 MVAR reactor bank.
Let’s look at only one phase:
33,300 KVAR divided by 289 K Volt =
115.2 amps. I was told by the person who took
the video that
the current was "about 100 amps."
I hope you enjoyed the show.