JP6950986B2 - Flood prevention device - Google Patents

Description

The present invention relates to a flood prevention device.

At the distribution substation, power receiving and transforming equipment is installed outdoors. The power receiving and transforming equipment houses power equipment such as a distribution board and a distribution board inside the box. Electric power is transferred to and from the power equipment via distribution lines that pass underground.
If the distribution substation is installed in a lowland, the area around the distribution substation may be flooded due to flood damage such as guerrilla rainstorms, floods, storm surges, and tsunamis. Then, when the power equipment of the power receiving / transforming equipment is flooded, the power receiving / transforming equipment loses the power transmission function (transformation function). If many of the power receiving and transforming facilities installed in the distribution substation lose their power transmission functions, there is a risk that the dwelling units in the supply area of the distribution substation will lose power. Not only that, once the power equipment is flooded, it loses its function as a power equipment, and it requires enormous cost and time to recover. Therefore, it is necessary to surely prevent the inundation of the electric power equipment of the power receiving and transforming equipment.

Japanese Unexamined Patent Publication No. 2013-162603

In order to prevent flooding of power equipment of power receiving and transforming equipment, measures (raising) are taken to place the power receiving and transforming equipment above the expected flooding level. Specifically, measures such as arranging the power receiving / transforming equipment on the second floor of the building and making the power receiving / transforming equipment a stilt type can be mentioned.
However, raising the height of the power receiving and transforming equipment changes the structure of the power receiving and transforming equipment that has already been installed, and requires time and cost for construction.

Therefore, it is required to reliably prevent flooding of electric power equipment by a relatively simple method without changing the structure of the installed power receiving and transforming equipment.
In addition, such inundation of electric power equipment is not limited to the type of power receiving and transforming equipment installed in distribution substations, but also the type of equipment installed in relation to buildings (condominiums and commercial facilities) installed in urban areas. This is a common issue for electric power equipment (power receiving and transforming equipment).

Therefore, one object of the present invention is to provide an inundation prevention device capable of reliably preventing inundation of electric power equipment.

The present invention is an inundation prevention device for preventing water from entering the power equipment in a power equipment having a power equipment and a box having a top surface and a side surface and accommodating the power equipment inside. It has an airtightness, a cover that surrounds the top surface and the side surface of the box body and internally partitions an internal space that is open below, and a discharge port arranged inside the cover. Then, the height of the water surface is increased by discharging gas from the discharge port to pressurize the internal space sealed by closing the lower surface of the box body with the water surface of water entering the inside of the cover. Provided is an inundation prevention device including a pressurizing means for lowering the weight.

The power equipment may be supported from below by a base.
In one embodiment of the invention, the cover has a swellable bag shape.
The bag-shaped cover may be brought into an inflated state by the pressurizing means discharging gas from the discharge port to pressurize the cover.
In one embodiment of the present invention, the inundation prevention device further includes a connecting member that connects the lower end portion of the cover and the box body or a base that supports the box body from below. The connecting member may include means for preventing the cover, which has been in the expanded state due to the pressurization of the internal space by the pressurizing means, from moving upward due to the pressurization.
In one embodiment of the present invention, the discharge port is arranged inside the box body.
In one embodiment of the present invention, the pressurizing means includes the discharge port and a gas supply device that supplies gas to the discharge port. Then, the gas supply device switches between a gas supply means for supplying the gas to the discharge port and the supply and stop of the supply of the gas from the gas supply means to the discharge port, so that the gas from the discharge port can be stopped. Includes an on-off valve that switches between discharge and discharge stop.

In one embodiment of the invention, the gas supply means includes a compressed gas supply machine. The compressed gas supply machine includes an intake port arranged outside the cover, and a compressor that compresses the air taken in from the intake port and supplies the compressed air to the discharge port.
In one embodiment of the invention, the compressor is housed inside the cover.
In one embodiment of the invention, the gas supply means comprises a gas tank for storing the gas. The gas tank may include a gas cylinder that stores the high-pressure gas.

In one embodiment of the present invention, the power equipment is a plurality of power equipment including a first power equipment and a second power equipment different from the first power equipment. Then, the cover includes a first cover corresponding to the box body of the first electric power facility and a second cover corresponding to the box body of the second electric power facility. The discharge port includes a first discharge port arranged inside the first cover and a second discharge port arranged inside the second cover. The gas is supplied to the first discharge port and the second discharge port from the common gas supply means. The on-off valve is a first on-off valve that switches between supplying and stopping the supply of the gas from the common gas supply means to the first discharge port, and the second discharge from the common gas supply means. It includes a second on-off valve that switches between supplying and stopping the supply of the gas to the outlet.

In one embodiment of the present invention, the inundation prevention device detects the height of the water surface of the water entering the inside of the cover, and the height of the water surface is the lower end of the cover. Further includes a pressurization starting means for initiating pressurization of the internal space by the pressurizing means when the water surface height detecting means detects that a higher first height position has been reached. ..
In one embodiment of the present invention, the inundation prevention device has reached a second height position where the height of the water surface is lower than the first height position and higher than the lower end of the cover. Further includes a pressurization stop means for stopping the pressurization of the internal space by the pressurizing means when is detected by the water surface height detecting means.
The compressor and the intake port are provided by a support member outside the box body, which is a support member different from the box body and the base, and is not supported by the box body or the base. It may be supported in a state of being separated horizontally outward from the outer periphery of the inflated cover and separated above the upper end of the cover.
Further, the gas tank may be arranged outside the box body. At least the upper part of the gas tank may be housed in the internal space. Then, the on-off valve may be housed in the internal space.

According to the present invention, the lower surface of the box is blocked by the water surface of water entering the inside of the cover, whereby the internal space of the cover becomes a closed space. The pressure in the internal space can be increased by discharging the gas from the discharge port into the internal space which is a closed space. As a result, the height of the water surface that enters the inside of the cover can be lowered. Therefore, it is possible to reliably prevent flooding of electric power equipment.

After that, when the inundation water level around the power equipment rises, the pressure due to the water surface entering the inside of the cover rises, the air in the internal space is compressed, and the water level height of the water entering the inside of the cover rises. There is a risk of rising. In this case, the height of the water surface can be lowered by discharging the gas from the discharge port again to pressurize the internal space which is a closed space. Therefore, regardless of the height of the inundation water around the electric power equipment, the inundation of the electric power equipment can be surely prevented.

FIG. 1 is a perspective view of a power receiving / transforming facility to which the inundation prevention device according to the embodiment of the present invention is mounted. FIG. 2 is a perspective view showing a state in which the flood prevention device is attached to the power receiving / transforming facility. FIG. 3 is a plan view showing a state in which the inundation prevention device is attached to the power receiving / transforming facility. FIG. 4 is a cross-sectional view schematically showing a state in which the inundation prevention device is attached to the power receiving / transforming facility. 5A to 5C are schematic views for explaining the operation and the like of the inundation prevention device. 5D to 5F are schematic views for explaining the operation and the like of the inundation prevention device. 5G and 5H are schematic views for explaining the operation and the like of the inundation prevention device. FIG. 6 is a diagram schematically showing a first modification. FIG. 7A is a diagram schematically showing a second modification. FIG. 7B is a diagram schematically showing a third modification. FIG. 8 is a diagram for explaining a flood prevention device according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a perspective view of an electric power facility to which the inundation prevention device 1 according to the embodiment of the present invention is mounted.
The power equipment to be installed is, for example, a self-supporting power receiving / transforming equipment 101 installed outdoors on the premises of a distribution substation. The power receiving / transforming equipment 101 is equipment that transmits electricity while transforming high-voltage electricity to a voltage lower than that.

The power receiving / transforming equipment 101 includes a rectangular box body 102 whose lower side is open, and a power equipment device 103 housed inside the box body 102. The electric power equipment 103 includes a distribution board, a distribution board, and the like. The box body 102 has a rectangular top surface 102a and four rectangular side surfaces 102b. One of the four side surfaces 102b constitutes a front surface that can be operated by an operator. A single-door door 104 is attached to the front surface of the box body 102. FIG. 1 shows a state in which the door 104 is open. The inside of the box body 102 is not sealed.

As an example of the size of the box body 102, a width of 980 mm, a depth of 880 mm, and a height (height from the installation surface F (ground)) of 2000 mm can be exemplified.
The power receiving / transforming equipment 101 is supported from below by a base 105 made of a concrete block or the like installed on the installation surface F (see FIG. 4 or the like). The base 105 has a rectangular planar shape. An opening 106 is formed in the central portion of the base 105. A cable 107 is pulled into the electric power equipment 103 from a cable pit (not shown) buried in the ground through an opening 106 of the base 105. Electric power is transferred to and from the electric power equipment 103 via the cable 107.

The power equipment 103 includes a power supply unit 108, a transformer, instruments, a break circuit, a monitor, a lamp, and the like. The 100V power supply of the power supply unit 108 is used to drive the flood prevention device 1.
The inundation prevention device 1 is attached to the power receiving / transforming equipment 101 to prevent the inundation of the electric power equipment 103 arranged in the power receiving / transforming equipment 101.
FIG. 2 is a perspective view showing a state in which the water ingress prevention device 1 is attached to the power receiving / transforming equipment 101. FIG. 3 is a plan view showing a state in which the inundation prevention device 1 is attached to the power receiving / transforming equipment 101. FIG. 4 is a cross-sectional view schematically showing a state in which the inundation prevention device 1 is attached to the power receiving / transforming equipment 101. In FIG. 4, the connecting member 4 is not shown because of the illustration. The same applies to FIGS. 5A to 5H described later.

As shown in FIGS. 2 to 4, the inundation prevention device 1 is provided on a cover 2 covering the box body 102, a discharge nozzle 31 having a discharge port 31a arranged in the internal space SP of the cover 2, and a discharge nozzle 31. A gas supply device 3 for supplying gas, a plurality of connecting members 4 for connecting the cover 2 to the base 105, and a water surface height sensor (water surface height detection) for detecting the water surface height of water entering the inside of the cover 2. Means) 5 and a control unit (pressurization start means, pressurization stop means) 6. The discharge nozzle 31 and the gas supply device 3 constitute a pressurizing means.

As shown in FIGS. 2 and 4, the cover 2 has an airtight and expandable bag shape. As used herein, the term "expansion and contraction" refers to a state in which the gas expands and contracts (shrinks) due to the inflow and outflow of gas. The cover 2 has a rectangular box shape with the lower side open in the inflated state (the state shown in FIG. 4). In this state, the cover 2 partitions the internal space SP that is open downward. The size of the cover 2 in the inflated state is larger than that of the box body 102.

The cover 2 surrounds substantially the entire area of the top surface 102a and the four side surfaces 102b of the box body 102 in a state of being attached to the power receiving / transforming equipment 101. In the mounted state of the cover 2, the height of the cover 2 in the vertical direction is set so that the lower end 2d of the cover 2 is located below the lower end 102d of the box body 102.
As shown in FIGS. 2 and 4, the cover 2 is airtight. The cover 2 is selected of a material that can withstand high buoyancy. The cover 2 is made of, for example, nylon or polyester material. Nylon has excellent flexibility, and polyester has excellent rigidity. It is desirable that these materials are selected to have high strength. The cover 2 may have a rubber coating. Further, it is desirable that the material of the cover 2 is as light as possible. That is, the bag-shaped cover 2 is lightweight.

As will be described later, it is not desirable that the gas inside the cover 2 leaks from the lower end 2d of the cover 2 (gas leakage). Therefore, in order to increase the rigidity of the lower end portion of the cover 2 and prevent the lower end 2d of the cover 2 from being turned up, a plurality of fabrics (for example, two sheets) may be stacked on the lower end portion of the cover 2.
As shown in FIG. 4, the gas supply device 3 opens and closes the compressed gas supply device (gas supply means), the discharge pipe 34 connecting the compressed gas supply machine and the discharge nozzle 31, and the discharge pipe 34. Includes valve 36 and. The compressed gas supply machine includes an intake nozzle 32 having an intake port 32a, a compressor 33, and an intake pipe 35 connecting the intake nozzle 32 and the compressor 33. The air sucked from the intake port 32a of the intake nozzle 32 is applied to the compressor 33 via the intake pipe 35. Then, when the on-off valve 36 is opened, the air compressed by the compressor 33 is discharged from the discharge port 31a of the discharge nozzle 31 via the discharge pipe 34. Further, when the on-off valve 36 is closed, the discharge of air from the discharge port 31a of the discharge nozzle 31 is stopped. The on-off valve 36 may be an electromagnetic valve or another valve.

The discharge nozzle 31 is arranged inside the box body 102 above the first height position PH1 described later. Since the discharge port 31a of the discharge nozzle 31 is arranged inside the box body 102, the discharge nozzle 31 does not come into contact with the cover 2. If the discharge nozzle 31 is arranged outside the box body 102, the discharge nozzle 31 and the cover 2 may interfere with each other, which may adversely affect the discharge of air from the discharge port 31a of the discharge nozzle 31. By arranging the discharge nozzle 31 inside the box body 102, interference between the discharge nozzle 31 and the cover 2 can be avoided, and thereby air can be satisfactorily discharged from the discharge port 31a of the discharge nozzle 31.

The intake nozzle 32 is arranged on the outside of the cover 2. In the example of FIG. 4 and the like, the intake nozzle 32 is supported by the support column 37. The support column 37 is supported from below by a base 38 made of a concrete block or the like installed on the installation surface F. The base 38 may be provided integrally with the base 105. The intake nozzle 32 is arranged above the first height position PH1. More preferably, the intake nozzle 32 should be arranged as high as possible. In the example of FIG. 4, the intake nozzle 32 is arranged above the upper end of the power receiving / transforming facility 101, that is, above the top surface 102a of the box body 102.

An insect invasion prevention net (not shown) for preventing insects from invading the intake port 32a is attached to the intake port 32a. Insects may invade the intake port 32a to form a nest inside the intake pipe, and as a result, the inside of the intake pipe 35 or the intake port 32a may be clogged. If such clogging occurs, the air from the intake port 32a may not be satisfactorily applied to the compressor 33. By preventing the invasion of insects from the intake port 32a by the insect invasion prevention net, it is possible to prevent the occurrence of clogging, whereby the air from the intake port 32a can be satisfactorily applied to the compressor 33.

The compressor 33 is arranged inside the box body 102. The compressor 33 has a known configuration including a compressor main body (not shown) and an air tank (not shown) capable of storing a predetermined amount of gas taken in from the intake nozzle 32 via the intake pipe 35. be. The compressor body and the air tank are housed in the same housing, so that the compressor 33 is usually treated as one device. The compressor 33 is arranged inside the box body 102 in a hollow portion formed behind the electric power equipment 103. The compressor 33 is arranged above the first height position PH1. The on-off valve 36 is arranged inside the box body 102.

The plurality of connecting members 4 connect the lower end portion of the cover 2 and the base 105. Each connecting member 4 includes a connecting member 41 fixed to the base 105, and a connecting member 42 connecting the connecting member 41 and the end portion of the cover 2. The connector 41 includes anchor bolts, eye nuts, and the like. The connecting member 42 includes a rope, a chain, a rubber cord, a cannabis shackle, and the like.
In the example of FIG. 3, the number of connecting members 4 is, for example, eight. In the example of FIG. 3, the connecting member 4 connects the lower end portion of the cover 2 and the individual corner portions of the base 105. Further, in this example, the connecting member 4 connects the lower end portion of the cover 2 and the central portion of each side of the base 105. In this way, the connecting member 4 not only connects the lower end portion of the cover 2 and the individual corner portions of the base 105, but also connects the lower end portion of the cover 2 and the central portion of each side of the base 105. This is to prevent the lower end 2d of the cover 2 from being turned up and to prevent the gas inside the cover 2 from leaking from the lower end 2d of the cover 2 (gas leakage). In the above description, the case where the connecting member 4 is composed of a plurality of members has been described as an example, but the connecting member 4 may be one member.

The water surface height sensor 5 is arranged inside the box body 102. The water surface height sensor 5 determines whether or not the water surface height of the water entering the inside of the cover 2 reaches a predetermined first height position PH1, or a predetermined first height position lower than the first height position PH1. Detects whether or not the height position is less than PH2 of 2. The first height position PH1 and the second height position PH2 are arranged below the lower end 103d of the power equipment 103 and above the lower end 2d of the cover 2. That is, the distance D1 from the lower end of the base 105 to the first height position PH1, the distance D2 from the lower end of the base 105 to the second height position PH2, and the lower end of the power equipment 103 from the lower end of the base 105. The relationship between the distance DT to 103d and the distance DD from the lower end of the base 105 (that is, the installation surface F of the base 105) to the lower end 2d of the cover 2 is as follows: distance DD <distance D2 <distance D1 <distance. It is DT. As an example of the distance D1, the distance D2, the distance DT, and the distance DD, 75 mm, 60 mm, 100 mm, and 50 mm can be exemplified, respectively.

The water level sensor 5 is, for example, a float type liquid level sensor (water level sensor). The water surface height sensor 5 may be composed of an optical position sensor or a capacitance type sensor. In addition, a semiconductor type pressure type water level gauge, a ceramic type pressure type water level gauge, a differential transformer type pressure type water level gauge, a crystal type pressure type water level gauge, and an ultrasonic type pressure type water level gauge are used as a water level sensor 5. May be used as.

Since the water surface height sensor 5 is arranged inside the box body 102, the water surface height sensor 5 does not come into contact with the cover 2. If the water surface height sensor 5 is arranged outside the box body 102, the water surface height sensor 5 and the cover 2 may interfere with each other, which may adversely affect the detection of the water surface height by the water surface height sensor 5. .. By arranging the water surface height sensor 5 inside the box body 102, interference between the water surface height sensor 5 and the cover 2 can be avoided, so that the water surface height sensor 5 can satisfactorily detect the water surface height.

As a power source for driving the compressor 33 and the water surface height sensor 5, a 100 V power source of the power source unit 108 of the power receiving / transforming equipment 101 is used. Therefore, the flood prevention device 1 does not have its own power supply. By using the 100V power supply of the power supply unit 108 as the driving power supply, the electric power can be stably supplied to the compressor 33.
The control unit 6 is arranged inside the box body 102 above the first height position PH1. The control unit 6 is configured by using, for example, a microcomputer. The control unit 6 has a calculation unit such as a CPU and a storage device such as a solid state drive. The control unit 6 controls the operation of the compressor 33. Further, the detection output from the water surface height sensor 5 is input to the control unit 6.

5A to 5H are schematic views for explaining the operation and the like of the inundation prevention device 1.
The flood prevention device 1 does not always have all the constituent members attached to the power receiving / transforming equipment 101. Only some parts are attached to the power receiving / transforming equipment 101 in advance. Then, at a time when flood damage may occur, the operator attaches the remaining constituent members to the power receiving / transforming equipment 101.
Hereinafter, mounting of the inundation prevention device 1 will be described with reference to FIGS. 5A to 5H.

FIG. 5A shows the power receiving / transforming equipment 101 before the inundation prevention device 1 is attached. As shown in FIG. 5B, the gas supply device 3 (including the compressed gas supply device, the discharge pipe 34, and the on-off valve 36), the water surface height sensor 5, and the water surface height sensor 5 for the power receiving / transforming equipment 101 in the state shown in FIG. 5A. The connecting tool 41 of the connecting member 4 and the control unit 6 are mounted. These installations are carried out by workers. Further, in order to mount the intake nozzle 32 included in the compressed gas supply machine, the operator erects the support column 37 on the base 38. On the other hand, the connecting member 42 of the cover 2 and the connecting member 4 is housed in the warehouse.

Then, in the periodic inspection once to several times a year, the worker turns on the power of the compressor 33 and the power of the water level sensor 5, and actually operates the water level sensor 5. , Check whether or not air is normally discharged from the discharge port 31a of the discharge nozzle 31. In addition, the operator visually confirms whether or not a foreign substance (for example, a nest of insects) is present in the intake port 32a of the intake nozzle 32. In addition, the operator inspects the cover 2 and the connecting member 4 for defects.

The operator takes out the cover 2 and the connecting member 42 from the warehouse at the timing when it is grasped from the weather forecast and the earthquake flash report that there is a possibility of flood damage. Then, the operator turns on the power of the compressor 33 to operate the compressor 33, and turns on the power of the water surface height sensor 5. By operating the compressor 33, an air tank (not shown) is filled with air at a predetermined pressure (for example, about 6 kg / cm ^2). Then, the operator confirms that the compressor 33 is normally driven (including: that the air tank is well filled with air), and actually operates the water surface height sensor 5 to discharge the compressor 33. Confirm that the air is normally discharged from the discharge port 31a of the nozzle 31. After that, as shown in FIG. 5C, the operator covers the power receiving / transforming equipment 101 to be mounted with the cover 2, and attaches the connecting member 42 to the connecting metal fitting (not shown) at the lower end of the cover 2 and the base 105. It bridges with the driven (fixed) connector 41. As a result, the attachment of the cover 2 to the power receiving / transforming equipment 101 is completed.

Since the bag-shaped cover 2 is lightweight, the work of covering the box body 102 with the cover 2 can be performed manually (for example, by two people) without using other mechanical devices.
Further, the operator reconfirms whether or not a foreign substance (for example, a nest of insects) is present in the intake port 32a of the intake nozzle 32.
Then, when the periphery of the power receiving / transforming facility 101 is flooded, water penetrates into the cover 2 as shown in FIG. 5D. The height of the water surface rises due to the increase in water. When the water surface height sensor 5 detects that the height of the water surface has reached the first height position PH1, the control unit 6 opens the on-off valve 36 and discharge nozzle 31 as shown in FIG. 5D. Air is discharged from the discharge port 31a of. As a result, the pressurization of the internal space SP is started. Since the inside of the box body 102 is not sealed (that is, the space outside the box body 102 in the internal space SP and the inside of the box body 102 communicate with each other), the air is discharged from the discharge nozzle 31. The entire internal space SP including the inside of the box body 102 is pressurized. Since the compressor 33 includes an air tank and the air tank is filled with air, air can be discharged from the discharge port 31a of the discharge nozzle 31 immediately after the opening / closing valve 36 is opened. When the height of the water surface reaches the first height position PH1, the internal space SP is blocked by the water surface of the water. That is, the internal space SP is a closed space. Due to the pressurization of the internal space SP, the cover 2 that has shrunk (shrinked) first swells. Then, from the inflated state of the cover 2, the internal space SP is further pressurized while maintaining the state in which the internal space SP is sealed. As a result, the pressure in the internal space SP rises. As a result, as shown in FIG. 5E, the height of the water surface is lowered.

Since the lower end of the cover 2 and the base 105 are connected by a plurality of connecting members 4, it is possible to prevent the cover 2 from moving upward. As a result, the internal space SP can be reliably maintained in a closed state.
Then, when the water surface height sensor 5 detects that the height of the water surface has dropped below the second height position PH2, the control unit 6 closes the on-off valve 36 and as shown in FIG. 5F, The discharge of air from the discharge port 31a of the discharge nozzle 31 is stopped. Thus, the pressure of the internal space SP is stopped.

As the water level increases further, the inundation water level around the power receiving / transforming facility 101 rises as shown in FIG. 5G. At this time, the pressure due to the water surface of the water entering the inside of the cover 2 rises, the air in the internal space SP is compressed, and as shown in FIG. 5G, the water surface height of the water entering the inside of the cover 2 rises again. To rise.
When the water surface height sensor 5 detects again that the height of the water surface has reached the first height position PH1, the control unit 6 opens the on-off valve 36 and discharge nozzles as shown in FIG. 5G. Air is discharged from the discharge port 31a of 31. As a result, the pressurization of the internal space SP is started. When the height of the water surface reaches the first height position PH1, the internal space SP is blocked by the water surface of the water. That is, the internal space SP is a closed space. By pressurizing the internal space SP while the internal space SP is sealed, the pressure of the internal space SP can be increased. As a result, the height of the water surface that enters the inside of the cover 2 is lowered.

Then, when the water surface height sensor 5 detects again that the height of the water surface has dropped below the second height position PH2, the control unit 6 closes the on-off valve 36 and as shown in FIG. 5H. , The discharge of air from the discharge port 31a of the discharge nozzle 31 is stopped. As a result, the pressurization of the internal space SP by the pressurizing means (discharge nozzle 31 and gas supply device 3) is stopped.
When the height of the water surface reaches the first height position PH1, the pressurization of the internal space SP is started, and when the height of the water surface drops below the second height position PH2, the pressurization of the internal space SP is stopped. NS. By repeating such pressurization and pressurization stop, regardless of the height of the flooded water around the power receiving / transforming equipment 101 (even if almost all of the power receiving / transforming equipment 101 is submerged). The height of the water surface inside the cover 2 can be maintained between the first height position PH1 and the second height position PH2. As a result, the inundation of the electric power equipment 103 can be reliably prevented.

As described above, according to this embodiment, the lower surface of the box 102 is blocked by the water surface of the water entering the inside of the cover 2, whereby the internal space SP of the cover 2 becomes a closed space. By discharging air from the discharge port 31a to the internal space SP, which is a closed space, the pressure of the internal space SP can be increased. As a result, the height of the water surface of the water entering the inside of the cover 2 can be lowered. Therefore, the inundation of the electric power equipment 103 can be reliably prevented.

After that, when the inundation water level around the power receiving / transforming facility 101 rises, the pressure due to the water surface of the water entering the inside of the cover 2 rises, the air in the internal space SP is compressed, and the water entering the inside of the cover 2 Water level may rise. In this case, the height of the water surface can be lowered by again discharging air from the discharge port 31a of the discharge nozzle 31 to pressurize the internal space SP which is a closed space. Therefore, the inundation of the electric power equipment 103 can be reliably prevented regardless of the height of the inundation water level around the power receiving / transforming equipment 101.

Further, according to this embodiment, the lower end portion of the cover 2 and the base 105 are connected by a plurality of connecting members 4. When the cover 2 is lightweight (particularly when the cover 2 is provided in a retractable bag shape), the cover 2 moves upward due to the pressurization of the internal space SP, and as a result, the internal space SP is sealed. May not be maintained. If the internal space SP cannot be maintained in a closed state, the pressure of the internal space SP cannot be increased. By connecting with the connecting member 4, it is possible to prevent the cover 2 from moving upward. As a result, the internal space SP can be reliably maintained in a closed state.

Further, since the compressor 33 is housed inside the cover 2 and the compressor 33 is arranged above the first height position PH1, the compressor 33 can be reliably protected from inundation. Therefore, even when the surroundings of the power receiving / transforming facility 101 are flooded, the internal space SP can be pressurized, and the inside of the internal space SP can be maintained at a high voltage. Further, since the compressor 33 is housed inside the box body 102, the compressor 33 can be protected from rain and wind by the box body 102.

Further, even if there is a small hole or the like in the cover 2 and a small amount of air leaks from the internal space SP, the frequency of driving the compressor 33 increases, so that water is contained inside the cover 2. The height of the water surface can be maintained between the first height position PH1 and the second height position PH2.
Further, since the compressor 33 includes an air tank, air can be discharged from the discharge port 31a immediately after the opening / closing valve 36 is opened. Therefore, it is possible to cope well with a sudden rise in water level.

FIG. 6 is a diagram schematically showing a first modification.
As shown in FIG. 6, the compressor 33 may be arranged outside the box body 102. Specifically, the compressor 33 may be arranged on the top surface 102a of the box body 102. The compressor 33 is housed inside the case body 151 in order to prevent the compressor 33 from being exposed to wind and rain before the cover 2 is attached.

FIG. 7A is a diagram schematically showing a second modification.
As shown in FIG. 7A, the compressor 33 may be arranged outside the cover 2. Specifically, FIG. 7
As shown in A, the compressor 33 may be supported by the support column (support member) 37. This makes it possible to prevent the compressor 33 from being flooded.
In this case, a plurality of compressors 33 (that is, compressors corresponding to a plurality of power receiving and transforming facilities 101).
Can also be centralized and placed in one place.

Further, as shown in FIG. 7B, when one compressor can individually send / stop air to a plurality of compressors, the functions of the plurality of compressors 33 can be combined with one compressor. Can be realized with.
In FIG. 7B, it is considered a case where two power receiving / transforming equipment 101, a first power receiving / transforming equipment (first power equipment) 101A and a second power receiving / transforming equipment (second power equipment) 101B, are provided as the plurality of power receiving / transforming equipment 101. .. Each of the power receiving and transforming facilities 101A and 101B is equipped with a flood prevention device 1.

The cover 2 of the inundation prevention device 1 mounted on the first power receiving / transforming facility 101A is referred to as the first cover 2A. Then, the discharge nozzle arranged inside the first cover 2A is the first discharge nozzle 131 having the first discharge port 131a as the discharge port.
The cover 2 of the inundation prevention device 1 mounted on the second power receiving / transforming facility 101B is referred to as the second cover 2B. Then, the discharge nozzle arranged inside the second cover 2B is a second discharge nozzle 132 having the second discharge port 132a as the discharge port. Air is supplied to the first discharge port 131a and the second discharge port 132a from a common compressed gas supply machine (compressor 33, intake nozzle 32, and intake pipe 35).

A first discharge pipe 34A is provided as a discharge pipe that connects the first discharge nozzle 131 and the compressed gas supply machine. The first discharge pipe 34A is interposed with a first open / close valve 36A that opens / closes the first discharge pipe 34A. When the first opening / closing valve 36A is opened, the air compressed by the compressor 33 is discharged from the first discharge port 131a of the first discharge nozzle 131 via the discharge pipe 34. Further, when the first opening / closing valve 36A is closed, the discharge of air from the first discharge port 131a of the first discharge nozzle 131 is stopped.

A second discharge pipe 34B is provided as a discharge pipe that connects the second discharge nozzle 132 and the compressed gas supply machine. The second discharge pipe 34B is interposed with a second opening / closing valve 36B that opens / closes the second discharge pipe 34B. When the second on-off valve 36B is opened, the air compressed by the compressor 33 is discharged from the second discharge port 132a of the second discharge nozzle 132 via the discharge pipe 34. Further, when the first opening / closing valve 36A is closed, the discharge of air from the second discharge port 132a of the second discharge nozzle 132 is stopped.

In this way, from the compressed gas supply machine (compressor 33, intake nozzle 32, and intake pipe 35) common to the first discharge port 131a and the second discharge port 132a corresponding to the different power receiving and transforming facilities 101A and 101B. Since the compressed gas is supplied, the compressed gas is compared with the case where the compressed gas supply machines (compressor 33, intake nozzle 32 and intake pipe 35) are provided one by one corresponding to the individual discharge ports 131a and 132a. The number of feeders can be reduced. As a result, it is possible to reduce costs and save space at the installation location. It is desirable that the compressor 33 in the example of FIG. 7B has a higher compressive force than the compressor 33 in the example of FIG.

Further, FIG. 7B shows an example in which the compressed gas supply device (compressor 33, intake nozzle 32, and intake pipe 35) supplies the compressed gas to the covers 2A and 2B corresponding to the two power receiving and transforming facilities 101A and 101B. As described above, the compressed gas may be supplied to the cover (cover 2) corresponding to three or more power receiving and transforming facilities.
FIG. 8 is a diagram for explaining the inundation prevention device 201 according to another embodiment of the present invention.

In the embodiment shown in FIG. 8, the parts corresponding to the respective parts shown in the embodiments shown in FIGS. 1 to 7B are designated with the same reference numerals as those in the cases of FIGS. 1 to 7B, and the description thereof will be omitted. do.
The inundation prevention device 201 shown in FIG. 8 differs from the inundation prevention device 1 shown in FIGS. 1 to 7B in that the internal space SP is generated by discharging gas from the gas tank 232 instead of discharging air by the compressor 33. It is a point to pressurize. That is, the inundation prevention device 201 includes a gas supply device 203 instead of the gas supply device 3 in the configuration of the inundation prevention device 1.

The gas supply device 203 opens and closes a gas tank (gas supply means) 232 for storing gas, a discharge pipe 234 for supplying gas from the gas tank 232 to the discharge nozzle 31, and a discharge pipe 234 to open and close the discharge nozzle. It includes an on-off valve 236 that switches between discharging gas from 31 and stopping discharging.
The gas tank 232 is arranged on one side or both sides of the power receiving / transforming facility 101 (one side is shown in FIG. 8), and is housed inside the cover 2. The gas tank 232 is, for example, a cylinder that stores gas in a high pressure state. The gas stored in the gas tank 232 is an inert gas such as nitrogen gas, air or the like. When the on-off valve 236 is opened, gas is supplied from the gas tank 232 to the discharge pipe 234, and the gas is discharged from the discharge port 31a of the discharge nozzle 31.

Further, the inundation prevention device 201 is different from the inundation prevention device 1 in that a mechanical water surface height sensor 205 (water surface height detecting means) is used instead of the water surface height sensor. The opening and closing of the on-off valve 236 is mechanically linked to the presence or absence of detection of the mechanical water level sensor 205 by, for example, interposing a link mechanism (pressurizing start means, pressurizing stop means) 206. That is, the flood prevention device 201 is not provided with a control unit.

Since the opening and closing of the on-off valve 236 is mechanically linked to the presence or absence of detection by the water surface height sensor 205, no electric power is required to open and close the on-off valve 236. Therefore, it is not essential to acquire the power supply from the power receiving / transforming facility 101. Therefore, even in a situation where power cannot be obtained from the power receiving / transforming equipment 101, the height of the water surface that enters the inside of the cover 2 can be lowered, and the inundation of the power equipment equipment can be reliably prevented.

When the periphery of the power receiving / transforming facility 101 is flooded, water enters the inside of the cover 2. The height of the water surface rises due to the increase in water. When the water surface height sensor 205 detects that the height of the water surface has reached the first height position PH1, the link mechanism 206 opens the open / close valve 236 from the previously closed state. As a result, the gas is discharged from the discharge port 31a of the discharge nozzle 31. When the pressurization of the internal space SP by the gas supply device 203 is started, the water surface height starts to decrease.

Then, when the water surface height sensor 205 detects that the height of the water surface has dropped below the second height position PH2, the link mechanism 206 closes the on-off valve 236. As a result, the discharge of gas from the discharge port 31a of the discharge nozzle 31 is stopped. As a result, the pressurization of the internal space SP by the gas supply device 203 is stopped.
In this way, pressurization and pressurization stop are repeated according to the height of the water surface.

According to the embodiment of FIG. 8, since electric power is not required to open / close the opening / closing valve 236, it is not essential to acquire the power source from the power receiving / transforming facility 101. Therefore, even in a situation where power cannot be obtained from the power receiving / transforming equipment 101, the height of the water surface that invades the inside of the cover 2 can be lowered, and the inundation of the power equipment equipment 103 can be reliably prevented.
Although the two embodiments of the present invention have been described above, the present invention can also be implemented in other embodiments.

For example, the modified example of FIG. 7A and the modified example of FIG. 7B may be combined with the embodiment of FIG. That is, the gas tanks 232 may be centrally arranged, or the gas may be supplied to the plurality of covers 2 by one gas tank 232.
Further, in the embodiment of FIGS. 1 to 7B, the inundation prevention device 1 may be equipped with a UPS (uninterruptible power supply), and the power may be obtained from the UPS instead of the power receiving / transforming facility 101. .. In this case, the UPS is preferably housed inside the cover 2, particularly inside the box 102 from the viewpoint of avoiding rain and wind.

Further, in the embodiment of FIGS. 1 to 7B, it is first detected by the water surface height sensor 5 that the circumference of the power receiving / transforming facility 101 is flooded and the water surface height reaches the first height position PH1. Then, the control unit 6 may transmit to that effect to the center or the like outside the aircraft.
Further, in each of the above-described embodiments, the cover 2 has been described as having a bag-like shape that can be expanded and contracted, but may be a container shape that does not expand and contract. In this case, it is desirable to use a material that is as light as possible.

Further, the control unit 6 may be configured by using an electric circuit such as a relay circuit instead of a computer such as a microcomputer.
Further, when the on-off valves 36 and 236 are composed of solenoid valves, the outputs (on / off) of the water surface height sensors 5,205 are input to the on-off valves 36 and 236 formed of the solenoid valves, and the water surface height sensors are input. The opening / closing valves 36 and 236 may be opened / closed based on the inputs of 5,205. In this case, the control unit 6 can be omitted, and the functions of the water surface height sensor 5 and the on-off valves 36 and 236 realize the pressurization start means and the pressurization stop means.

In addition, the inundation prevention devices 1,201 are not only power receiving and transforming equipment installed in distribution substations, but also power receiving and transforming equipment installed in relation to buildings (condominiums and commercial facilities) installed in urban areas. Can also be applied to. In addition, it can be applied to various electric power facilities other than power receiving and transforming facilities.
In addition, various design changes can be made within the scope of the matters described in the claims.

1: Flood prevention device 2: Cover 3: Compressed air supply device (gas supply means, pressurization means)
4: Connecting member 5: Water surface height sensor (water surface height detecting means)
6: Control unit (pressurization start means, pressurization stop means)
31a: Discharge port (pressurizing means)
32a: Intake port 33: Compressor 101: Power receiving / transforming equipment (electric power equipment)
102: Box body 102a: Top surface 102b: Side surface 103: Electric power equipment 105: Base 201: Flood prevention device 203: Gas supply device (pressurizing means)
205: Water surface height sensor (water surface height detecting means)
206: Link mechanism (pressurization start means, pressurization stop means)
232: Gas tank (gas supply means)
236: Open / close valve PH1: First height position PH2: Second height position SP: Internal space

Claims (11)

And power equipment, having a top surface and side surfaces, have a, a box body that houses the power equipment inside, in the power equipment that will be supported from below by the base, the immersion to the power equipment It is an inundation prevention device to prevent
A bag-shaped cover that has airtightness, surrounds the top surface and the side surface of the box body, and internally partitions an internal space that opens downward , and can be expanded and contracted .
The internal space, which has a discharge port arranged inside the cover and is sealed by blocking the lower surface of the box body by the water surface of water entering the inside of the cover, is filled with gas from the discharge port. A pressurizing means that brings the bag-shaped cover into an inflated and inflated state by discharging and pressurizing, and lowers the height of the water surface.
A connecting means for connecting the lower end portion of the cover and the box body or the base, and the cover that has been in an expanded state due to the pressurization of the internal space by the pressurizing means is accompanied by the pressurization. look including a connecting means for preventing from moving upward Te,
The pressurizing means includes the discharge port and a gas supply device for supplying gas to the discharge port.
The gas supply device switches between a compressed gas supply machine that supplies gas to the discharge port and the supply and stop of supply of the gas from the compressed gas supply machine to the discharge port, so that the gas from the discharge port can be stopped. Including an on-off valve that switches between discharge and discharge stop,
The compressed gas feeder includes an intake port arranged outside the cover and a compressor that compresses the air taken in from the intake port and supplies the compressed air to the discharge port.
The compressor and the intake port are provided by a support member outside the box body, which is a support member different from the box body and the base, and is not supported by the box body or the base. An inundation prevention device supported in a state of being separated horizontally outward from the outer periphery of the inflated cover and separated above the upper end of the cover. An inundation prevention device for preventing inundation of the electric power equipment in the electric power equipment having the electric power equipment and a box having a top surface and a side surface and accommodating the electric power equipment inside.
A cover that is airtight and surrounds the top surface and the side surface of the box body to internally partition an internal space that is open below.
The internal space, which has a discharge port arranged inside the cover and is sealed by blocking the lower surface of the box body by the water surface of water entering the inside of the cover, is filled with gas from the discharge port. Includes a pressurizing means that lowers the height of the water surface by discharging and pressurizing.
The pressurizing means includes the discharge port and a gas supply device for supplying gas to the discharge port.
The gas supply device switches between a gas supply means for supplying gas to the discharge port and the supply and stop of supply of the gas from the gas supply means to the discharge port, so that the gas can be discharged from the discharge port and stopped. Including an on-off valve to switch the discharge stop,
The gas supply means, viewed contains a gas tank which is disposed outside of the box body a gas tank for storing the gas,
At least the upper and the on-off valve is accommodated in the internal space, water immersion prevention device of the gas tank. An inundation prevention device for preventing inundation of the electric power equipment in the electric power equipment having the electric power equipment and a box having a top surface and a side surface and accommodating the electric power equipment inside.
A cover that is airtight and surrounds the top surface and the side surface of the box body to internally partition an internal space that is open below.
The internal space, which has a discharge port arranged inside the cover and is sealed by blocking the lower surface of the box body by the water surface of water entering the inside of the cover, is filled with gas from the discharge port. Includes a pressurizing means that lowers the height of the water surface by discharging and pressurizing.
The pressurizing means includes the discharge port and a gas supply device for supplying gas to the discharge port.
The gas supply device switches between a gas supply means for supplying gas to the discharge port and the supply and stop of supply of the gas from the gas supply means to the discharge port, so that the gas can be discharged from the discharge port and stopped. Including an on-off valve to switch the discharge stop,
The electric power equipment includes a first electric power equipment and a second electric power equipment different from the first electric power equipment.
Is a multiple power facility, including
The cover includes a first cover corresponding to the box body of the first electric power facility and a second cover corresponding to the box body of the second electric power facility.
The discharge port includes a first discharge port arranged inside the first cover and a second discharge port arranged inside the second cover.
The gas is supplied to the first discharge port and the second discharge port from the common gas supply means.
The on-off valve is a first on-off valve that switches between supplying and stopping the supply of the gas from the common gas supply means to the first discharge port, and the second discharge from the common gas supply means. comprising a second on-off valve for switching the supply and supply stop of the gas to the outlet, a water immersion prevention device. An inundation prevention device for preventing inundation of the electric power equipment in the electric power equipment having the electric power equipment and a box having a top surface and a side surface and accommodating the electric power equipment inside.
A cover that is airtight and surrounds the top surface and the side surface of the box body to internally partition an internal space that is open below.
The internal space, which has a discharge port arranged inside the cover and is sealed by blocking the lower surface of the box body by the water surface of water entering the inside of the cover, is filled with gas from the discharge port. A pressurizing means that lowers the height of the water surface by discharging and pressurizing.
A water surface height detecting means for detecting the height of the water surface of the water entering the inside of the cover, and
When the water surface height detecting means detects that the height of the water surface has reached the first height position higher than the lower end of the cover, the pressurizing means pressurizes the internal space. Pressurization start means to start and
When the water surface height detecting means detects that the height of the water surface has reached a second height position lower than the first height position and higher than the lower end of the cover. wherein a pressure stop means for stopping the pressure of the inner space by the pressurizing means, the including, water immersion prevention device. Wherein said pressurizing means comprises a pre-Symbol discharge port, and a gas supply device for supplying a gas before Symbol discharge port,
Wherein the gas supply device, a gas supply means for supplying a gas before Symbol discharge port, and before SL gas supply means switching the supply and supply stop of the gas into the discharge port, of said gas from said discharge port The water inundation prevention device according to claim 4, further comprising an on-off valve for switching between discharge and discharge stop. The gas supply means includes a compressed gas supply machine, and the gas supply means includes a compressed gas supply machine.
The compressed gas feeder
An air intake port located outside the cover and
The inundation prevention device according to claim 2, 3 or 5, further comprising a compressor that compresses the air taken in from the intake port and supplies the compressed air to the discharge port. The inundation prevention device according to claim 6, wherein the compressor is housed inside the cover. The water inundation prevention device according to any one of claims 1 to 7 , wherein the discharge port is arranged inside the box body. A water surface height detecting means for detecting the height of the water surface of the water entering the inside of the cover, and
When the water surface height detecting means detects that the height of the water surface has reached the first height position higher than the lower end of the cover, the pressurizing means pressurizes the internal space. The inundation prevention device according to any one of claims 1 to 3 , further comprising a pressurization starting means for starting. The water inundation prevention device according to any one of claims 2 to 9, wherein the cover has a swellable bag shape. The inundation prevention device according to any one of claims 2 to 10, further comprising a connecting member for connecting the lower end portion of the cover and the box body or a base that supports the box body from below.

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