Contamination caused flashovers produce frequent outages in
severely contaminated areas. Lines closer to the ocean are in more danger of
becoming contaminated. Several countermeasures have been proposed to improve
insulator performance.
The most frequently used methods are:
1. Increasing leakage distance by increasing the number of
units or by using fog-type insulators. The disadvantages of the larger number
of insulators are that both the polluted and the impulse flashover voltages
increase. The latter jeopardizes the effectiveness of insulation coordination
because of the increased strike distance, which increases the overvoltages at
substations.
2. Application insulators are covered with a semiconducting
glaze. A constant leakage current flows through the semiconducting glaze. This
current heats the insulator’s surface and reduces the moisture of the
pollution. In addition, the resistive glaze provides an alternative path when
dry bands are formed.
The glaze shunts the dry bands and reduces or eliminates
surface arcing. The resistive glaze is exceptionally effective near the ocean.
3. Periodic washing of the insulators with high-pressure
water. The transmission lines are washed by a large truck carrying water and
pumping equipment. Trained personnel wash the insulators by aiming the water
spray toward the strings.
Substations are equipped with permanent washing systems.
High-pressure nozzles are attached to the towers and water is supplied from a
central pumping station. Safe washing requires spraying large amounts of water
at the insulators in a short period of time.
Fast washing prevents the formation of dry bands and
pollution-caused flashover. However, major drawbacks of this method include
high installation and operational costs.
4. Periodic cleaning of the insulators by high pressure
driven abrasive material, such as ground corn cobs or walnut shells. This
method provides effective cleaning, but cleaning of the residual from the
ground is expensive and environmentally undesirable.
5. Replacement of porcelain insulators with nonceramic
insulators. Nonceramic insulators have better pollution performance, which
eliminates short-term pollution problems at most sites. However, insulator
aging may affect the long-term performance.
6. Covering the insulators with a thin layer of
room-temperature vulcanized (RTV) silicon rubber coating. This coating has a
hydrophobic and dirt-repellent surface, with pollution performance similar to
nonceramic insulators.
Aging causes erosion damage to the thin layer after 5–10
years of operation. When damage occurs, it requires surface cleaning and a
reapplication of the coating.
Cleaning by hand is very labor intensive. The most advanced
method is cleaning with high pressure driven abrasive materials like ground
corn cobs or walnut shells. The coating is sprayed on the surface using standard
painting techniques.
7. Covering the insulators with a thin layer of petroleum or
silicon grease. Grease provides a hydrophobic surface and absorbs the pollution
particles.
After one or two years of operation, the grease saturates
the particles and it must be replaced. This requires cleaning of the insulator
and application of the grease, both by hand. Because of the high cost and short
life span of the grease, it is not used anymore.
1 comment:
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