JP2008066052A - Washing method of insulator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable to prevent insulation failure of an insulator positively. <P>SOLUTION: A cogeneration power generation system 4 and an electric power receiving station 6 are installed in a factory 2. The cogeneration power generation system 4 is provided with a tank 8. Pure water is stored in the tank 8. When sea water is adhered to an insulator 10, the pure water is guided to a nozzle 18 by a pump 16 and a hose 14, and the pure water is injected into the insulator 10 from the nozzle 18. The sea water is washed away by the pure water. By this washing, electric discharge along the surface of the insulator 10 is prevented. It is preferable that the specific resistance of the pure water is 2 kΩm or more. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a method for cleaning an insulator.

  In factories that consume a large amount of power, high-voltage power is supplied from the power company. The voltage of this electric power is 275 kV, for example. This electric power is transformed into 77 kV, for example, and sent to a power receiving station in the factory. A large number of insulators are installed at this power station. A distribution line is connected to this insulator. The insulator has an insulating function. Choshi is often installed outdoors.

  In factories in the coastal area, seawater may be blown up by strong winds such as during typhoons and adhere to the insulators. In the case of a typhoon with rain along with the wind, the seawater is washed away with rain. However, when there is little rainfall, washing away cannot be expected. Seawater contains salt. Seawater may cause discharge along the insulator surface. This phenomenon is called “insulation failure”. If an insulation failure occurs, power cannot be supplied to the factory and operation is stopped. The insulator may be damaged by the discharge due to the insulation failure.

JP-A-5-325689 discloses a cleaning apparatus for insulators. In this facility, washing water is sprayed from the spray nozzle toward the insulator. By washing off seawater with this washing water, insulation defects of the insulator are prevented.
JP-A-5-325689

  In the cleaning facility, the direction of the cleaning water sprayed from the nozzle depends on the wind direction and the wind speed. The washing water may not reach the insulator. If a large number of nozzles are provided, it can cope with any wind direction and wind speed, but this equipment has a complicated structure and is expensive.

  The washing water sprayed from the spray nozzle adheres to the insulator. On the insulator's surface, the wash water mixes with seawater. If the electrical resistance of the cleaning water is low, spraying of the cleaning water may cause a poor insulation.

  An object of the present invention is to provide a cleaning method capable of reliably preventing insulation failure of insulators.

The cleaning method according to the present invention includes:
A step of introducing pure water stored in the tank to the nozzle with a pump and a hose, and a step of injecting the pure water from the nozzle toward an insulator installed outdoors.

  Preferably, the electrical resistivity of the pure water is 2 kΩ · m or more. Preferably, the tank stores pure water for a steam turbine.

  In this cleaning method, pure water is used as cleaning water, so that insulation failure is reliably prevented. This cleaning method does not require new equipment. This cleaning method is low cost.

  Hereinafter, the present invention will be described in detail based on preferred embodiments with appropriate reference to the drawings.

  FIG. 1 is a conceptual diagram of a factory 2 in which a cleaning method according to an embodiment of the present invention is performed. This factory 2 is located in the coastal zone. In this factory 2, a cogeneration power generation system 4 and a power receiving station 6 are installed.

  Steelworks and the like often have a cogeneration power generation system 4 in the factory 2 for the purpose of power saving. In the cogeneration power generation system 4, a generator is driven by a gas turbine to obtain electric power. The exhaust heat of the gas turbine is guided to the boiler, and the exhaust water is used to heat pure water. Pure water becomes steam and is used in the factory. The cogeneration power generation system 4 includes a tank 8 that stores pure water. Pure water can be obtained, for example, by filtering ground water and further subjecting it to ion exchange.

  The power receiving station 6 includes a large number of insulators 10. A distribution line 12 is connected to the insulator 10. The distribution line 12 is a so-called bare wire. The insulator 10 is made of porcelain. The surface of the insulator 10 is uneven, and a large creepage distance is achieved by the unevenness. By this insulator 10, insulation between the distribution line 12 and the ground is achieved.

Also shown in FIG. 1 are a hose 14, a pump 16 and a nozzle 18. A fire hose can be used as the hose 14. The discharge speed of the pump 16 is, for example, 32 m ³ / h. The discharge pressure of the pump 16 is, for example, 0.5 MPa. A fire pump can be used as the pump 16. A fire-fighting nozzle can be used as the nozzle 18.

  When a typhoon or a seasonal wind is strong, seawater is blown up and may fly to the factory 2 and adhere to the insulator 10. At this time, pure water stored in the tank 8 is guided to the nozzle 18 by the hose 14 and the pump 16. Pure water is jetted from the nozzle 18 toward the insulator 10. By this injection, seawater is washed away with pure water, and insulation failure of the insulator 10 is prevented.

  Adhesion of seawater to the insulator 10 is likely to occur when a strong wind without rain blows. The frequency of such strong winds is not so high. Such strong winds may not blow at all throughout the year. In preparation for an extremely rare situation, it is not a good idea to provide a washing facility in the power receiving station 6 in advance. This is because the installation cost and maintenance cost of the cleaning equipment are enormous.

  In the cleaning method according to the present invention, since pure water stored in the tank 8 of the cogeneration power generation system 4 is used as cleaning water, it is not necessary to install a new tank 8 and a pure water production apparatus. The cogeneration power generation system 4 is often provided near the power receiving station 6 so that the electric power obtained by power generation can be easily transmitted to the substation equipment. By using the tank 8 of the cogeneration power generation system 4, pure water can be guided to the insulator 10 with a short hose 14.

  In the cleaning method according to the present invention, the fire hose 14, the fire pump 16, and the fire nozzle 18 that are often provided in the factory 2 can be used. This cleaning method does not require a new injection facility.

  In this cleaning method, pure water is used. In the present invention, pure water having an electrical resistivity of 2 kΩ · m or more is preferably used. Pure water has an extremely high electrical resistivity. By using this pure water, insulation failure is reliably prevented.

  During the injection of pure water, the nozzle 18 is held by an operator. The direction of the nozzle 18 is determined by the operator's intention. The direction of the nozzle 18 is arbitrary. By the injection from the nozzle 18, pure water can reliably reach the insulator 10 regardless of the wind direction and the wind speed.

The discharge speed of pure water from the nozzle 18 is preferably 10 m ³ / h or more and 50 m ³ / h or less. By setting the discharge speed to 10 m ³ / h or more, insulation failure is efficiently prevented. In this respect, the discharge speed is more preferably 20 m ³ / h or more. By setting the discharge speed to 50 m ³ / h or less, breakage of the insulator 10 due to water pressure is suppressed. In this respect, the discharge speed is more preferably 40 m ³ / h or less.

  The discharge pressure of pure water from the nozzle 18 is preferably 0.1 MPa or more and 2.0 MPa or less. By setting the discharge pressure to 0.1 MPa or more, defective insulation is efficiently prevented. In this respect, the discharge pressure is more preferably 0.3 MPa or more. By setting the discharge pressure to 2.0 MPa or less, damage to the insulator 10 due to water pressure is suppressed. In this respect, the discharge pressure is more preferably 1.0 MPa or less.

  The cleaning method according to the present invention can also be applied to insulators installed in power plants, substations, and the like.

FIG. 1 is a conceptual diagram of a factory in which a cleaning method according to an embodiment of the present invention is implemented.

Explanation of symbols

2 ... Factory 4 ... Cogeneration power generation system 6 ... Power receiving station 8 ... Tank 10 ... Insulator 12 ... Distribution line 14 ... Hose 16 ... Pump 18 ... Nozzle

Claims (3)

A method for cleaning an insulator, comprising a step of guiding pure water stored in a tank to a nozzle with a pump and a hose, and a step of injecting the pure water from the nozzle toward an insulator installed outdoors.   The cleaning method according to claim 1, wherein the pure water has an electrical resistivity of 2 kΩ · m or more.   The cleaning method according to claim 1 or 2, wherein the tank stores pure water for a cogeneration power generation system.

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