KR101153502B1 - Electric equipment underground construction structure and construction method for inundation prevention of large electric equipment - Google Patents

Abstract

The present invention discloses a large electrical installations underground construction structure and construction method for preventing the flooding of electrical installations to safely embed large electrical installations such as transformers underground.
The present invention after embedding the electrical equipment in the excavation for embedding the electrical equipment in order to completely prevent the occurrence of accidents caused by the flooding while laying the electrical equipment that causes serious damage during flooding The cover is made of a corrosion-resistant material on the cover and the opening is formed in the lower side of the cover, the switch is operated by a float and a rotation lever connected to the float to detect the inundation inside the cover, As the solenoid valve is opened and closed, air pressure is filled by the pneumatic generating means to fill the space on the surface of the water and the inside of the cover, thereby achieving the purpose of safe and complete flooding prevention of electrical equipment and constructing the grid at the same height as the road surface directly above the cover. Effective space for walking or driving of people or vehicles Allows bodoel.

Description

Electric Equipment Underground Construction Structure and Construction Method for Inundation Prevention of Large Electric Equipment}

The present invention relates to a large electrical installations underground construction structure and construction method for preventing the flooding of electrical installations to safely buried large electrical installations such as transformers underground.

As is well known, various large-scale electrical installations such as transformers, which may cause serious electric accidents when flooded, are generally installed on the ground rather than being installed on the column.

In this way, the electrical equipment installed on the ground is mainly due to the construction to occupy a part of the sidewalk or driveway, the appearance is not neat, there is a problem that causes a great inconvenience for human walking or driving of the vehicle.

In addition, the electrical equipment installed on the ground is installed in major shopping centers in the city, which not only impairs the aesthetic appearance of the city, but also interferes with the formation of the commercial area of the city, causing many complaints.

Therefore, a representative example of an attempt to bury underground in spite of the fear of flooding can be seen by Japanese Patent Publication No. So 58-6008 (name of invention: distribution box; referred to as 'quotation invention 1').

According to the cited invention 1 as shown in FIG. 1, the enclosure having the panel, the outer frame of the panel, the outer door packing, the see-through window, the outer window of the door is covered, the compressed air dehumidified to the panel side space is discharged from the pump Switchboard is presented,

Downwards, the feeder cable is connected to the terminal block, and the wiring drawn out of the cable buried pipe through the wiring sealing material is connected to two relays installed in an enclosed space.

This cited invention 1 requires a huge supply of dehumidified and cleanly filtered air in the pump is a huge cost, and the service life of the facility is also shortened. Therefore, the pump may be manually started when there is a fear of immersion, but if the pump is not operated quickly in such an emergency situation, there is a problem that an accident due to immersion cannot be avoided.

Moreover, even when the pump is operated normally during flooding, if the water level rises above the height of the pump, the pump itself is flooded and the motor of the pump cannot be prevented from shorting due to flooding. As the supply of air was also stopped, the switchboard was flooded, and thus there was a problem that was not widely used.

In addition, Japanese Patent Laid-Open No. 58-6011 (name of the invention: distribution box; hereinafter referred to as 'quoting invention 2'), as shown in FIG. 2, has a see-through window, an inner and an outer frame inside the enclosure, and the inside thereof. It is installed by installing a plurality of packings to seal the inner and outer frames to accommodate these relays,

Downwards, the feed cable is connected to the terminal block, and the wiring drawn out from the cable buried pipe through the wiring sealing material is connected to two relays installed in an enclosed space.In addition, the external air pressure supply means is provided through the cable buried pipe. The air supply pipe connected to is connected to the inside of the enclosure.

This invention has a problem in that it requires a huge cost for the operation and shorten the life of the equipment because it must be continuously supplied air dehumidified and cleanly filtered by pneumatic means. Therefore, it is possible to start the air supply by selectively opening and closing the valve only in the case of the switchboard which is likely to be flooded, but if the pump is not operated by quickly identifying the state of the switchboard in such an emergency situation, the accident caused by the flooding may be caused. There is a problem that can not be avoided in the case of the cited invention 2 because it is unreasonable to operate the pneumatic means continuously in normal times, it was not widely spread.

In addition, the inventions 1 and 2 as described above are particularly decisive problems, which are configured to supply air pressure directly to the inside of the enclosure so that water does not penetrate from the outside, thereby making it impossible to use packing for each element in the interior of the enclosure. Accordingly, the flow of air through the packing is inevitably avoided. Accordingly, if the pump or the pneumatic means is not operated continuously, the watertight state cannot be maintained. Accordingly, the water level rises above the pump or the pneumatic means due to the external flooding. If the pump or pneumatic means of the motor itself is submerged, the operation is stopped, and thus there is a problem that it is inevitable that the flooding into the switchboard loses the basic purpose to prevent the inundation. In addition, in the event of serious flooding, such as flooding, the electricity supply is cut off, and the motor of the pump or pneumatic means is not supplied with power. As a result, the air inside the enclosure is leaked out by the packing. As water infiltration into the enclosure from the outside cannot be avoided as a result, Cited Invention 1 and 2 have a fatal problem that loses its utility.

Japanese Patent Publication No. 58-6008 (Invention: Distribution Box) Japanese Patent Publication No. 58-6011 (Invention: Distribution Box)

In order to solve the above problems, the first object of the present invention is to immerse an electric installation that can completely protect the electric installation from flooding while embedding the electric installation that causes serious damage during flooding, rather than the ground. It is to provide an underground construction structure and construction method for prevention.

The second object of the present invention is an underground construction structure for preventing the flooding of the electrical installation so that the electrical installation is not submerged at all in the state of submerged more than the height of the electrical installation, especially in the absence of power supply from the outside due to power failure and To provide a construction method.

According to the present invention, after embedding electrical equipment in an excavation portion for embedding electrical equipment, the cover is made of a corrosion-resistant material on the cover, and then an open hole is formed under the cover, and a float for detecting inundation inside the cover; The solenoid valve is opened and closed by the above-mentioned switch when the flooding is connected to the float, so that the pneumatic pressure is filled by the pneumatic generating means to fill the space above the water surface and the inside of the cover by the pneumatic generating means. In addition, the present invention proposes an underground construction structure and a construction method of an electrical installation so that an effective space for walking or running of a person or a vehicle can be secured by constructing a grid at the same height as a road surface directly above the cover.

In this way, the present invention is not only to obtain an effective space that can be utilized for human walking or driving the vehicle while preventing the erosion of sidewalks and roadways by being embedded in the ground electrical equipment installed on the ground,

By removing the electrical facilities installed in front of the downtown shopping centers, it is useful to protect the commercial rights and prevent civil complaints, and to protect the electrical facilities from flooding to ensure the protection of valuable lives and property.

1 and 2 are explanatory diagrams showing a conventional cited invention.
3A to 3G are explanatory views showing a method for underground construction of an electrical installation for preventing flooding of a large electrical installation according to the present invention.
Figure 4 is a side cross-sectional view showing a construction state of the electrical installation according to the present invention.
Figure 5 is a side cross-sectional view showing the operation of the electric equipment is submerged in accordance with the present invention.
Figure 6 is a block diagram showing an electrical configuration for wirelessly transmitting the operating state in the present invention.
Figure 7 is a block diagram showing the electrical configuration for the transmission and reception of the operating state using the PLC in the present invention.
8 is a circuit diagram showing an example of an electrical configuration applied to the present invention.
Figure 9 is an installation state showing an example using a cylinder as a pneumatic generating means in the present invention.
10 is an explanatory view illustrating a structure for releasing heat transferred to a cover in the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3A to 3G sequentially illustrate the electric installation underground construction method for preventing the flooding of a large electric installation according to the present invention. As can be seen from this, the present invention forms an excavation part 200 to bury a large electrical installation 100 such as a transformer in the basement. Subsequently, the cable buried pipe 201 is formed on the bottom surface of the excavation part 200 and the feed cable 202 is installed thereon, so that the feed cable 202 is exposed upward from the center of the bottom surface.

Subsequently, the finishing work is performed using waterproof mortar on the bottom surface and the circumferential surface of the excavation part 200. In addition, the large electrical equipment 100 is mounted on the floor by using heavy equipment, and the power supply cable 202 is connected to construct the large electrical equipment 100.

In addition, the present invention is provided with a water level detecting means 300 on one side of the large electrical installation (100). The water level detecting means 300 is composed of a float 302 and a switch 301 which is operated by the rotation interval 303 and the rotation interval 303 connected to one side of the float 302.

In addition, in the present invention is to install the pneumatic generating means 400 on the upper surface of the large-scale electrical equipment (100). The pneumatic generating means 400 is composed of a compressor 402 for generating pressure by the motor 401 and the motor 401, and one or more reservoir tanks 403 connected to the outlet side of the compressor 402. . In addition, in the present invention, the hard cover 500 made of a metal or a synthetic resin made of a metal or synthetic resin opened downward above the large electric installation 100 is fixed to the upper side of the large electric installation 100, but the bottom of the cover 500 is fixed. While fixing the four corners of the cover 500 with a fixing means 501 such as a conventional anchor so as not to be separated in a state in which the opening is formed to be higher than the floor surface on which the above-described electrical equipment 100 is installed, the cover 500 The top height of the structure is to be equal to or less than the height of the ground, and this structure is illustrated in the cross-sectional view of FIG.

Accordingly, the lower end of the cover 500 is higher than the bottom of the electrical equipment 100 so that the pneumatic pressure generated by the pneumatic generating means 400 operated by the water level detecting means 300 installed in the electrical equipment 100 is covered. It will be filled in a sealed space between the 500 and the submerged water surface.

In addition, the present invention is fixed to mount the grid 600 of the same height as the height of the ground above the cover 500, for this purpose it is preferable that a step for placing the grid 600 is formed around the excavation 200 Do.

In the present invention as described above, pedestrians walk on the grid 600 having the same height as usual, and the large electric equipment inside the excavation part 200 by the feed cable 202 installed in the cable buried pipe 201. The number of electric power and the power distribution are made at 100.

In addition, in such a normal state, since the float 302 of the water level detecting means 300 installed on one side of the large electric installation 100 is lowered, the switch 301 is 'off', and thus the motor 401 At the outlet of the reservoir tank 403 powered by the switch 301 operated by the above-described float 302 in a state where the pneumatic pressure by the compressor 402 is stored in the reservoir tank 403 by the operation of. Since the installed solenoid valve 405 is closed, it is in an operation standby state, and the reservoir tank 403 is filled with air in an optimum pressure range by the pressure sensing switch 901 inside the reservoir tank 403.

In this state, when the water level rises due to heavy rains or the surrounding water and sewer rupture, water is introduced into the excavation part 200 and water is not discharged by a conventional sewer pipe not shown or described separately. Flow through the open portion existing between the bottom of the cover 500 and the bottom surface to raise the float 302 of the water level detecting means (300).

Accordingly, in the present invention, as the switch 301 'on' by the rotation period 303 of the float 302 supplies power to the motor 401, the compressor 402 operates, and such a compressor ( Operation of the 402 causes the reservoir tank 403 to be filled with pneumatic pressure. This pneumatic pressure causes the solenoid valve 405 to open immediately after the switch 301 is turned on by the float 302 to immediately discharge the pneumatic pressure filled in the reservoir tank 403 into the space inside the cover 500 and above the water surface. do.

In the present invention, in particular, since the cover 500 itself is opened only, and the remaining parts are all made of a hard metal or synthetic resin made of a sealing surface, the sealing by packing provided between the gaps of various elements as in the present invention. Unlike the structure, it is permanently and firmly maintained in a perfect sealed state, which is not damaged after a long time after installation or under bad conditions.

Therefore, the enclosed space inside the cover 500 and above the water is filled with air pressure stored in the reservoir tank 403 to block the rise of the water, thereby preventing the immersion elements such as the connecting terminal 203 of the electrical installation 100. It can be submerged and kept safe, and this state is shown in FIG. 5.

This state is maintained at a position where the proper air pressure filled in the reservoir tank 403 is balanced with the pressure at which the water surface is to rise. As such, in the present invention, there is no separate additional sealing structure such as an assembly structure or packing for sealing as in the present inventions 1 and 2, and thus it is possible to maintain the airtight state completely blocked from outside air when inundating, and between the space and the water surface. The space in the chamber has no structure that can leak air pressure so that it can be kept closed without any additional pressure supply.

Therefore, there is no power supply from the outside due to the blackout accident, even if the water is filled above the top height of the cover 500 in the present invention, unlike the cited inventions 1 and 2, the water level is prevented from rising by the once filled pneumatic electricity Since it is possible to prevent the equipment from being flooded, it is possible to ensure the protection of the electrical equipment 100 even in a bad condition occurs.

Therefore, in the present invention, even if the excavation part 200 equipped with the electrical equipment 100 is flooded due to unavoidable circumstances such as heavy rain, only the immersion prohibition element such as a portion of the connection terminal 203 connected to the cable 202 of the electrical equipment 100 is flooded. Can be preserved in an inundated state, which can be preserved until the inundation is resolved by the recovery team.

In addition, the present invention can operate the radio wave transmitter including the CDMA by the operation of the switch 301 installed on one side of the electrical installation 100, this embodiment was shown in FIG. In this embodiment, when the switch 301 is turned on by the operation of the float 302, the ID of the electric equipment 100 and a status code indicating the submerged state are output from the encoder 700, and the output of the encoder 700 is output. Is output from the modulator 702 together with the carrier frequency of the oscillator 701, and is amplified by the power amplifier 703 and then radiated to the outside via the antenna 704 so that the excavation portion 200 of the electrical installation 100 is ) Is flooded to the administrator carrying the terminal or mobile phone of the control station where the radio receiver is installed, it is possible to check the inundation situation, and if possible to go out immediately to take necessary measures corresponding to the inundation of the drilling unit 200 The water is removed and restored to its normal state, or the water level drops over time to recover.

In addition, the present invention, in addition to the radio wave transmission shown in FIG. 7 transmits the ID and the status code indicating the submerged state of the electric equipment 100 to the mobile phone of the control center or the manager by the power line communication method. It is possible.

To this end, a PLC transmitter which connects a power line coupling circuit through a signal point mapper, a wavelet inverse converter, a D / A converter, a transmission amplifier, and a bandpass filter to which the output of the encoder 700 is connected for transmission, is known. (800) can be used.

In addition, the embodiment includes a PLC receiving unit 801 composed of a power line coupling circuit, a band pass filter, an amplification degree controller, an A / D converter, a wavelet converter, and a symbol determiner to receive a corresponding signal from a control center. And by connecting a terminal equipped with a keyboard and the like will be able to receive the ID and the immersion state data of the above-described electrical equipment 100 in the control center.

According to such a PLC method, the radio transmission and reception is less expensive than the facility cost, and has the advantage of enabling stable communication, and even in a completely submerged state it is possible to continuously check the state of the electrical installation 100 through the power line.

The present invention is connected to the reservoir tank 403 while the switch 301 which is operated by the float 302 is 'off' when the water level is lowered and the float 302 is lowered because the submerged state of the electrical installation 100 is released. The solenoid valve 405 is closed, and the motor 401 starts normal operation again to fill the reservoir tank 403 with an appropriate pressure to prepare for the next operation.

An electrical configuration for this operation is illustrated in FIG. 8. As can be seen from the present invention, the switch 301 operated by the float 302 flows a current to the coil of the relay 900, and accordingly the contact of the relay 900 is turned off motor 401 The current flowing in the) is cut off, and further charging is stopped, and the other contact point of the relay is turned on to flow a current through the coil of the solenoid valve 405 to open the reservoir tank 403 by the solenoid valve 405 opened. The air filled above the set pressure charged in the) is released to pressurize the water so as not to rise, thereby preventing the flooding. In addition, in the standby state, the pressure sensing switch 901 is 'on' and the float 302 does not rise, the motor 401 is operated by the contact of the relay which is always 'on'. Pneumatic pressure is generated to increase the pressure of the reservoir tank 403. When the pressure rises above the range set by the above process, the pressure sensing switch 901 is immediately 'off', thereby shutting off the power supplied to the motor 401 so that the pressure in the reservoir tank 403 is no longer increased. The pressure of the tank 403 is to maintain the set range.

In addition, in the present invention, the pneumatic generating unit 400 installed on the upper surface of the large electrical installation 100 and the cylinder 404, which is a forced high-pressure container filled with a high-pressure air lacking the motor 401 and the compressor 402 and It could also be replaced by a solenoid valve 405 fixed to the outlet of the cylinder 404, which is shown in FIG.

The pneumatic generating means 400 of such a structure is the switch 301 is 'on' as the float 302 rises during immersion due to various factors, and as a result the solenoid valve 405 connected to the cylinder 404 is opened. The high-pressure air filled in the cylinder 404 fills the space between the upper side of the cover 500 and the surface of the water to block the rise of the water level.

In this embodiment, there is an advantage that can simplify the installation, there is a hassle to replace the cylinder 404 after a series of operations to prevent immersion.

In addition, in the present invention, since the electrical equipment 100 is covered by the cover 500, a problem of hardly dissipating heat generated from the electrical equipment 100 to the outside may occur. Therefore, in the present invention, as shown in FIG. 10, the heat dissipation fins 502 may be fixedly installed on the top and side surfaces of the cover 500 to improve heat dissipation efficiency.

In addition, the cover 500 used in the present invention should be used in a very harsh environment in which moisture or a snow remover, such as calcium chloride is sprayed, should be made of a corrosion resistant material, and in fact, stainless steel or aluminum alloy or fiber reinforced plastic, engineering plastic, It can be made of materials.

As described above, the present invention is not limited to the above-described embodiments, and may be implemented in various forms by combining or modifying various known elements within the scope of maintaining the technical features of the present invention.

100: electrical equipment 200: excavation 201: cable buried pipe
202: power supply cable 203: connection terminal 300: water level detection means
301: switch 302: float 303: rotation
400: pneumatic generating means 401: motor 402: compressor
403: reserve tank 404: bomb 405: solenoid valve
500: cup 501: fixing means 502: heat radiation fin
600: grid 700: encoder 701: oscillator
702: modulator 703: power amplifier 704: antenna
800: PLC transmitter 801: PLC receiver 900: Relay
901: pressure sensing switch

Claims (8)

Formation of excavation part to secure space for underground installation of electrical equipment, installation of cable embedding pipe and feeding cable for connection with electrical equipment, and finishing work using waterproof mortar on the bottom and periphery of the excavation part Implementation steps,
An electrical installation step of carrying out a large electrical installation on the floor using a known fixing means such as an anchor bolt, and a connection step of connecting the feeding cable installed in the above-mentioned cable buried pipe to the electrical installation;
The cover is formed to a size that can cover the above-described electrical equipment, and the cover is fixed to a fixed structure such as an anchor bolt such as an anchor bolt. Cover installation steps,
A grid installation step of mounting and fixing a grid having a height equal to that of the ground above the cover;
When the water level sensing means composed of the float installed on one side of the electrical equipment described above is in operation standby, the step of allowing the pneumatic pressure generated by the pneumatic generating means to be filled in the reservoir tank,
When the water level sensing means composed of the float installed on one side of the electrical equipment described above is in operation, the air pressure generated in the reserve tank is filled by the pneumatic means to fill the sealed space between the cover and the submerged water surface. An underground installation method for electrical installations to prevent flooding of large electrical installations. A feed cable installed in a cable buried pipe underground, an excavation part installed on the cable buried pipe, an electric device connected to the above-mentioned feed cable and fixed to the bottom of the excavated part, and a float installed on one side of the electric facility Configured level sensing means;
A motor operated by the water level sensing means and a pressure sensing switch of the reservoir tank, a compressor for generating pneumatic pressure by operation of the motor, a reservoir tank connected to the compressor to charge air pressure, and in the reserve tank A solenoid valve configured to control the pneumatic release of the pneumatic means, the pneumatic generating means being provided on the upper surface of the electrical equipment;
A cover which is integrally manufactured to cover the electrical equipment and the pneumatic generating means, is opened downward, and the other surface is sealed and closed;
An opening hole disposed between the fixed bottom and bottom surfaces of the cover;
An electrical installation underground construction structure for preventing the flooding of a large electrical equipment, characterized in that it is provided with a grid installed at the same height above the cover. Formation of excavation part to secure space for underground installation of electrical equipment, installation of cable embedding pipe and feeding cable for connection with electrical equipment, and finishing work using waterproof mortar on the bottom and periphery of the excavation part Implementation steps,
An electrical installation step of carrying out a large electrical installation on the floor using a known fixing means such as an anchor bolt, and a connection step of connecting the feeding cable installed in the above-mentioned cable buried pipe to the electrical installation;
A cover installation step of integrally formed and sealed structure and fixing the lower part with a known fixing means such as an anchor bolt so that an opening is formed under the cover;
A grid installation step of mounting and fixing a grid having a height equal to that of the ground above the cover;
A construction step of performing a step of closing and waiting for the solenoid valve connected to the cylinder when the water level sensing means composed of the float installed on one side of the electrical equipment is in the standby state;
In the operating state of the water level sensing means composed of the float installed on one side of the electrical equipment described above, the construction step to avoid the step of opening the solenoid valve so that the pneumatic charge filled in the cylinder is filled in the sealed space between the cover and the submerged water surface. Electric installation underground construction method for preventing the flooding of large electrical equipment characterized in that provided. A feed cable installed in a cable buried pipe underground, an excavation part installed on the cable buried pipe, an electric device connected to the above-mentioned feed cable and fixed to the bottom of the excavated part, and a float installed on one side of the electric facility Configured level sensing means;
The solenoid valve which is connected to the solenoid valve which is opened or closed by the water level sensing means is connected to the cylinder, and the pneumatic discharge of the cylinder is controlled by the water level sensing means, and the pneumatic pressure is installed on the upper surface of the electric equipment. Generating means;
A cover which is integrally manufactured to cover the electrical equipment and the pneumatic generating means, the cover of which is internally sealed and opened downward, and an open hole disposed between the fixed bottom and the bottom surface of the cover;
An electrical installation underground construction structure for preventing immersion of a large electrical installation, characterized in that it comprises a grid installed at the same height as the ground around the top of the excavation portion above the cover. The method according to claim 2 or 4,
A switch operated by the lifting and lowering of the float, an encoder operated by the switch, a modulator connected to an output of the encoder and an oscillator, a power amplifier for amplifying the output of the modulator, and the power An electric installation underground construction structure for preventing the flooding of a large electric installation, characterized in that the radio wave transmitter consisting of an antenna radiating the output of the amplification unit is installed on one side of the cover. The method according to claim 2 or 4,
A large-scale electric machine comprising a PLC transmitter connected to a power line coupling circuit through an encoder, a signal point mapper, a wavelet inverse converter, a D / A converter, a transmission amplifier, and a bandpass filter. Underground construction structures for electrical installations to prevent flooding of equipment. The method according to any one of claims 1 to 4,
The switch operated in accordance with the above-mentioned float lifting is connected in series with the relay coil and the power supply, the contactor and the pressure switch of the motor and the aforementioned relay are connected in series with the power supply, and the solenoid valve and other contacts of the relay are connected in series with the power supply. Underground construction structure for electrical installations to prevent flooding of large electrical installations, characterized in that. The method according to claim 2 or 4,
An underground installation structure for electrical installations for preventing flooding of large electrical installations, characterized in that by fixing and installing the heat radiation fins on the upper surface of the cover.

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