JPH09175594A - Pressure storage type internal water flood storage tank - Google Patents

Abstract

(57) [Summary] [Problem] To provide an inland water storage tank equipped with a compressed air storage power generation facility that can allow inflow of inland water without delay. SOLUTION: A water receiving facility provided on the ground is separated into an upper tank 53 for storing water and a lower tank 54 for storing compressed air by an intermediate bulkhead 52 formed across an intermediate portion of a vertical underground tank 50. And a lower tank 54 are connected to each other to provide a water pipe 60,
An underground tank for inland water flooding configured to automatically receive water from the water receiving equipment when the water supply pipe 60 is kept at a negative pressure and the water supply pipe 60 is opened.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses an underground tank that receives inland water flood in a city to store compressed air produced by night-time electric power (compressed air storage) and use the compressed air in the daytime. The present invention relates to an inland water flood storage tank equipped with an improved power generation facility adapted to generate electricity.

[0002]

2. Description of the Related Art As one of the measures for urban disaster prevention, river water may be flooded by heavy rain and damage facilities such as houses, subways, power transmission facilities and communication facilities. To prevent this, underground rainwater storage Providing facilities is proposed. Conventionally, this underground rainwater storage facility has been planned as a single installation for storing rainwater. Therefore, the time required for this equipment in the city was limited to only a few days in a year, and the operation rate was extremely low, which was an economic problem.

In order to solve this economic problem, compressed air is usually manufactured by using night power and stored in an underground tank, and this compressed air is used when daytime power is required. It is conceivable to install a compressed air storage power generation facility that generates electricity by generating electricity. However, this power generation equipment is usually designed mainly for the storage and use of compressed air, and there is no way to receive floods into underground tanks in a short time during heavy rain, and the original purpose of the inland flood storage tank Was difficult to achieve effectively.

An example of a vertical underground tank used in this compressed air storage power generation facility will be described. As shown in FIG. 14, an intermediate bulkhead 2 is arranged in a vertical underground tank 1, and an upper tank 3 and a lower tank are arranged. 4 are arranged vertically, and a water pipe 5 for letting in and out the flood water W ₁ flows into and from the lower tank 4,
An air pipe 6 for supplying or discharging compressed air a is arranged.

For this vertical underground tank 1, it is necessary to practically use a large tank having a diameter D of 30 to 40 m and a depth H of 100 to 200 m. Therefore, the vertical underground tank 1 is constructed. The wall body 8 that is to be installed has a large pressure P such as groundwater or sediment.
_To withstand ₁ (external pressure), a structure with high strength is required. However, by storing the compressed air a for the combustor of the gas turbine in the lower tank 4 side, the pressure P ₂ (internal pressure) of the compressed air a and the pressure P ₁ are opposed to each other, so that the wall body 8 is relatively made. It can have a weak, light structure.

[0006] And in the upper tank 3 of the vertical underground tank 1 to store water W ₂ such as a fire, the pressure P ₃ of the water W ₂ be facing the pressure P ₂ in said lower tank 4 Thus, the intermediate partition 2 is also made to have a light structure. Further, an opening / closing valve 5a is provided in the water pipe 5 to discharge the compressed air a from the air pipe 6 at the time of flood, and the opening / closing valve 5a is opened so that flood water W ₁ flows into the lower tank 4.

By the way, in the conventional compressed air storage power generation equipment using the underground tank 1, the water W ₁ of the flood water 5 is introduced into the lower tank 4 under the pressure P ₂ of the compressed air a when the flood occurs. It must be poured through, but this method is problematic in practice. That is, since the lower tank 4 is filled with the high-pressure compressed air a, the water W ₁ of the flood cannot flow in unless the inside of the lower tank 4 is discharged to the atmospheric pressure. However, since the pressure P ₁ that is the total pressure of ground water, earth and sand, etc. and the pressure P 3 of the water W _{2 in} the upper tank ₃ are acting on this lower tank 4, in order to reduce it to atmospheric pressure, the intermediate partition wall 2 , Wall 8
Must have a heavy structure, and at the same time requires a time to release a large amount of air.

To solve this problem, it is necessary to push the water W ₁ by a separately provided pump (not shown) while discharging the compressed air a filled in the lower tank 4. However, flooding due to heavy rain occurs in a short time, and the amount of flooding is large, so pumping will not work in practice.

[0009]

Normally, compressed air having a constant pressure manufactured by using night power is stored in an underground tank, and the compressed air is used to drive a turbine to generate electricity during the daytime. It is an object of the present invention to provide a pressure storage type internal water flood storage tank that is most suitable for a power generation facility that operates.

An object of the present invention is to provide an underground rainwater storage facility capable of urgently inflowing and storing inflowing water into the underground tank in the event of a disaster such as heavy rain. Another purpose is to use the negative pressure of the flow channel, which is a rational hydraulic and aerodynamic valve to open and close the inland water tank into the underground tank in an emergency response. Will provide a means to achieve.

[0011]

[Means for Solving the Problems] An underground water inundation underground tank according to the present invention for achieving the above object and a compressed air storage power generation facility using this underground tank are configured as follows. 1) An intermediate bulkhead formed across the intermediate portion of a vertical underground tank separates an upper tank for water storage and a lower tank for storing compressed air, and separates the water receiving equipment installed on the ground from the lower tank. A pressurized air storage type internal water flood storage tank configured to be connected to provide a water supply pipe, keep the inside of the water supply pipe at a negative pressure, and open the water supply pipe to automatically receive water from the water receiving equipment.

2) The above-mentioned pressurized water storage inundation storage tank is
An on-off valve is provided at the inlet of the water pipe connecting the ground and the lower tank, and with this on-off valve closed, a negative pressure is applied to the inside of the water pipe to form a water column in part or all of the water pipe, and the opening / closing is performed. When the valve is opened, the negative pressure in the upper part of the water column serves as a suction force to cause the water in the water receiving facility to flow into the underground tank for water supply.

3) The water pipe is formed in an inverted U-shaped passage. 4) The compressed air storage type internal water flood storage tank has an outer cylinder forming a tank wall, a gap having a predetermined distance from the outer cylinder, and an intermediate partition formed transversely to form an upper tank. A double-structure tank composed of an inner cylinder forming a lower tank is formed, and a water supply channel is formed in the gap.

5) An intermediate bulkhead that crosses the intermediate portion of the vertical underground tank forms an upper tank that can store water and a lower tank that stores compressed air. The lower tank, the drive system of the power generation equipment, and the compressor are connected to each other. Connected by an air pipe with an on-off valve,
It has a water receiving facility for storing water in the vicinity of the underground tank, and water for flooding flows in, the lower tank and the water storing facility are connected by a water supply pipe, and an opening / closing valve is provided in this water supply pipe. A power generation facility configured to form a liquid column in the water pipe with the water pipe closed is provided.

6) The water supply pipe of the power generation equipment is formed in an inverted U-shaped passage. 7) A water level gauge is installed in the water receiving equipment of the power generation equipment, and a pressure gauge is installed in the lower tank, and the signals of the water level gauge and the pressure gauge are introduced into comparators, respectively, and the air pipe is supplied by the signals from the comparators. It is configured to control the on-off valve provided in the. As a means for efficiently inflowing flood into the lower tank of the vertical underground tank, the inside of the water pipe can be maintained at a negative pressure, and hydraulically, flood water is continuously supplied to the water pipe under pressure. It is possible to let it flow down.

The water receiving or water storage facility installed in the vicinity of the underground tank means a small water storage tank for receiving a flood, or a lake or river existing in an artificial or natural environment. In cities, the upper tank space is the drain shaft for purification of waste water, sludge purification tank, ice water storage tank for cooling,
It can be used for fire fighting water tanks and drinking water tanks.

As described above, the present invention is constructed so that a negative pressure can be generated in the water pipe for inflowing flood water into the underground tank. Therefore, in conventional underground rivers and rainwater storage tanks, in order to reduce the free water flow that falls into the underground space due to heavy rain with a dampening work, an underground space such as a spiral intake channel is required. However, such equipment is unnecessary.

Further, in the compressed air storage power generation equipment using the underground tank having the above-mentioned structure, the compressor is normally driven by night power to produce compressed air, and the compressed air is supplied to the lower tank through the connecting pipe. And store. At this time, since the lower tank is sealed by the liquid column formed in the communication passage, that is, water dam, a predetermined pressure is maintained. The compressed air stored in this underground tank is supplied to a drive system such as a gas turbine of a power generation facility through a connecting pipe when the demand for electric power in the daytime is high.

On the other hand, when flood occurs due to heavy rain while the power generating equipment is operating as described above, this water enters the water receiving equipment such as a small tank and the water level of the water receiving equipment rises. Then, the level of this water level rise is detected by the water level gauge, and the pressure inside the lower tank is detected by the pressure gauge, and the signal is input to the comparator, the open valve is opened, and part of the compressed air in the lower tank is released. Then, when the pressure is reduced, the water in the water receiving facility flows into the lower tank through the water pipe, and the pressure in the lower tank is maintained. Of course, after the flood, the water in the lower tank is drained to a predetermined water level and used for compressed air storage in the power generation equipment.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION

(Embodiment 1) FIGS. 1 to 10 show a first embodiment (structure and action of a vertical underground tank). A vertical underground tank 50 is shown in FIG. As shown in the plan view, the intermediate partition wall 5 is crossed across the intermediate portion of the cylindrical wall body 51.
2 is formed and divided into upper and lower parts to form an upper tank 53 and a lower tank 54, and an air pipe 55 for supplying compressed air to a combustor of a gas turbine is connected to the intermediate partition wall 52,
Also, the water pipes 56 and 57 and the on-off valve 5 provided on the ground G
It is connected to the water supply pipe 60 via 8, 59.

FIG. 1 shows a state in which compressed air is completely filled in the lower tank 54 and disaster prevention water is further stored in the upper tank 53, and the opening / closing valves 58 and 59 are closed so that a certain amount of water is stored in the lower tank 54. The water w is stored. At this time,
The pressure of the compressed air a fills the water supply pipe 60 with water to form a liquid column at the height of the water supply pipe 60. FIG.
Indicates a state during power generation in the daytime, and the valve 55a
Is opened to supply compressed air a filled in the lower tank 54 to the gas turbine (not shown) through the air pipe 55 to generate electricity. During this power generation, the liquid column H is gradually lowered from its original state as the pressure of the compressed air a is reduced.

FIG. 4 shows a state in which the power generation is completed, and the valve 55a is closed, but a part of the compressed air a filled in the lower tank 54 is consumed during the power generation and its pressure is reduced. Is reduced to a ', so that the liquid column H is reduced according to the pressure. FIG. 5 shows a state in which the compressed air a has been filled in the lower tank 54 again, and the water pipe 60 is filled with a liquid column as in the case of FIG. In addition,
The height of the liquid column in this case is designed to be maximum by the pressure of the compressed air a.

FIG. 6 shows a state of preparation for receiving flood water and rainwater w'through the water pipe 56 in an emergency.
Although the valve 58 attached to 6 is opened, the valve 55a attached to the air pipe 55 is closed so that compressed air is not supplied. FIG. 7 shows a state in which rainwater w ′ is being stored,
The valve 55a attached to the air pipe 55 is opened to urgently discharge the compressed air a into the atmosphere, and the rainwater w ′ is caused to flow into the lower tank 54 through the water pipe 60 and stored therein. When the rainwater w ′ is caused to flow into the lower tank 54 while discharging the compressed air a in this manner, the liquid level gradually rises.

FIG. 8 shows a state where the rainwater w'is completely stored and the tank is full. FIG. 9 shows a state in which the water w stored after the end of the flood is being discharged, and the compressed air a is supplied into the lower tank 54 and the water supply pipe 6 is supplied.
It drains through 0, the valve 59, and the water pipe 57. FIG. 10 shows a state in which the water in the lower tank 54 has been completely discharged, the compressed air a is filled in the lower tank 54 again as shown in FIG. 1, and the water w has a required amount (depth). , And the inside of the water supply pipe 60 receives the pressure of the compressed air a to form a water column having a predetermined height.

As shown in FIGS. 1-10, when the lower tank 54 is filled with compressed air a, when the filled compressed air a is being consumed, a rainwater storage preparation step,
A liquid column is formed in the water pipe 60 at any time of storage of rainwater, completion of storage of rainwater, discharge of stored rainwater, and completion of this discharge. In particular, since compressed air in the underground tank 54 is consumed during power generation, a sufficient negative pressure is generated in the water pipe 60.

Therefore, in the case of heavy rain where it is necessary to urgently accept the inundation, if the compressed air a filled in the lower tank 54 is released, the valve 58 of the water pipe 60 is opened. By the action of the negative pressure generated in the water pipe 60, the rainwater is automatically sucked in and the inflow is started, and thereafter, the inflow of water into the lower tank 54 is performed while following the discharge speed of the compressed air a. Can be stored.

When the weather is restored, compressed air is filled in the underground tank 54, and the water stored by the pressure is pushed to the ground G and discharged into the river through the water pipe 57, and then the water pipe 57 is opened by the valve 59. By closing at 1, it becomes possible to perform the constant volume pressure electric power storage operation, as will be described in detail in the embodiment below. (Embodiment 2) FIG. 11 is a schematic cross-sectional view of a vertical underground tank 24 provided near a power generation facility 23 having a gas turbine 21, a compressor 22 and the like.

This vertical underground tank 24 is arranged with an outer cylinder 25 forming a tank wall and a predetermined distance d from the outer cylinder 25, and an intermediate tank 26 forming an upper tank 27 and a lower tank 28. The inner cylinder 29 is formed into a cylindrical shape, and the space d is formed as a communication passage 30.
12 is a sectional view taken along line ZZ in FIG.
5, a large number of connecting walls 25a are provided between the inner cylinder 29 and the inner cylinder 29.
Is connected to support the internal structure including the inner cylinder 29, and the space in the thickness direction of the connecting wall 25a forms a passage for allowing water W ₄ to flow into and out of the lower tank 28.

The lower tank 28 is connected to the combustor of the gas turbine 21 by an air pipe 32 so that the compressed air stored in the lower tank 28 is supplied to the combustor. The air pipe 32 is provided with an open valve 31. A compressor 22 is installed side by side with the gas turbine 21, and the compressed air a produced by the compressor 22 is stored in the lower tank 28 via the air pipe 32. A water W ₄ having a water level WL is partially stored in the lower tank 28, and the pressure in the tank is detected by a pressure gauge 33.

Further, a small tank 34 is provided near or around the vertical underground tank 24, and a water level gauge 35 is arranged in the small tank 34 and water W ₅ is stored therein. . A water guiding wall 29a formed by bending the upper end of the inner cylinder 29 downward in a U shape is arranged in the small tank 34. As a result, the upper portion of the communication passage 30 opens into the small tank 34. The water guiding wall 29a forms a seal structure.

The signal of the pressure gauge 33 is supplied to the comparator 37, and compared with the signal of the water level gauge 35 to be output to control the open valve 31. Next, a method for operating the power generation equipment will be briefly described. A) In the above configuration, the compressor 2 is normally powered by night power.
2 is driven to supply and store the compressed air a in the lower tank 28 through the air pipe 32. Then, at the time of daytime power demand, a system is adopted in which this compressed air a is supplied via the air pipe 32 as air for the combustor of the gas turbine 21 which is the drive system of the generator. Power is generated while operating the gas turbine 21 efficiently.

At this time, the compressed air a is supplied to the gas turbine 21 side so that the pressure in the lower tank 28 gradually changes.
The pressure is maintained while being absorbed by the change in the head of the liquid column 36 formed inside 9. (B) When heavy rain occurs and a flood occurs in the above state, this water flows into the small tank 34 and the water level of the water W ₅ in the small tank 34 rises. This water level rise is measured by the water level gauge 35
Detects it and inputs the signal V ₁ to the comparator 37.

In the comparator 37, the pressure gauge 33
From the pressure signal V ₂ in the lower tank 28 from
A control signal V ₃ is generated here, and the open valve 31 is opened by this signal V ₃ to release the compressed air a in the lower tank 28. The pressure in the lower tank 28 drops with the release of the compressed air a. Simultaneously with the pressure drop, the water W ₅ in the small tank 34 flows into the lower tank 28 through the communication passage 30, and the water level WL in this tank rises and maintains its pressure.

That is, a flood occurs, and its water W ₁ flows into the waterway 4
After passing through 0, it can flow into the small tank 34 and can flow into the lower tank 28 with pressure via the communication passage 30 without lowering the pressure. Further, by adjusting the pressure in the lower tank 28, various tank walls forming the vertical underground tank 24 can have a relatively thin and light structure.

(Embodiment 3) FIG. 13 shows another embodiment of the vertical underground tank 24, in which the lower tank 28 and the small tank 34 are connected in a tubular shape with an inverted U-shaped portion formed in the upper portion. A liquid column (not shown) is formed in the communication passage 30a, and the lower tank 28 is sealed with water.

Also in the vertical underground tank 24 in this embodiment, a liquid column is formed in the communication passage 30a, and the small tank 3
The water W ₅ flowing into the tank ₅ is supplied into the lower tank 28, and the pressure in the lower tank 28 is adjusted by operating the release valve 31 by the pressure change accompanying the change in the water level WL of the water W _{4 in} the lower tank 28. To be done.

[0037]

According to the invention of claim 1, a vertical underground tank having an upper tank and a lower tank formed by partitioning an intermediate portion into upper and lower parts by an intermediate partition is provided with a water pipe from the ground to the lower tank. Since a negative pressure is generated in the tank, rainwater can automatically flow into and store in the underground tank by opening this water pipe when the flood occurs.

According to the second aspect of the present invention, the opening / closing valve provided in the water supply pipe can be opened at the time of flood to allow rainwater to automatically flow into the lower tank. According to the invention of claim 3, the water in the underground tank can be water-sealed without providing an opening / closing valve by forming the water supply pipe as an inverted U-shaped pipe. According to the invention of claim 4, the equipment can be reduced in weight by using the vertical underground tank having the double structure.

According to the fifth aspect of the present invention, the vertical underground tank is effectively used to produce compressed air by utilizing the late-night electric power and the compressed air is stored in the tank, and the turbine is utilized in the daytime by utilizing the compressed air. In the event of a flood due to heavy rain, rainwater is stored in the lower tank while releasing compressed air to prevent damage from the flood.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a first embodiment of a vertical underground tank according to the first embodiment of the present invention, showing a state in which compressed air charging is completed.

2 is a plan view of the tank of FIG. 1. FIG.

FIG. 3 is a cross-sectional view showing a state of the tank during power generation.

FIG. 4 is a cross-sectional view showing a state of the tank in which power generation is completed.

FIG. 5 is a cross-sectional view showing a state of the tank that has been filled with compressed air.

FIG. 6 is a cross-sectional view showing a state of the tank that has been prepared for rainwater storage.

FIG. 7 is a cross-sectional view showing a state of the tank during rainwater storage.

FIG. 8 is a cross-sectional view showing a state of the tank that has completed storing rainwater.

FIG. 9 is a cross-sectional view showing the state of the tank during discharge of water after the end of the flood.

FIG. 10 is a cross-sectional view showing a state of the tank in which water discharge has been completed.

FIG. 11 is a cross-sectional view showing a second embodiment of the present invention, showing a schematic structure of a compressed air storage type internal water flood storage tank provided with a compressed air storage power generation facility.

12 is a sectional view taken along line ZZ in FIG.

FIG. 13 is a schematic view of a compressed air storage type internal water flood storage tank provided with a compressed air storage power generation facility according to a third embodiment of the present invention.

FIG. 14 is a schematic sectional view of a conventional inland water flood storage tank.

[Explanation of symbols]

1,24 Vertical underground tank 2,26
Intermediate bulkhead 3,27 Upper tank 4,28
Lower tank 5 Water pipe 6,32
Air tube 8 Wall 21 Gas turbine 22
Compressor 23 Power generation equipment 25
Outer cylinder 29 Inner cylinder 30, 30a
Communication passage 33 Pressure gauge 34
Small tank 35 Water level meter 36
Liquid column 50 Vertical underground tank 51
Wall 52 Intermediate bulkhead 53
Upper tank 54 Lower tank 55
Air pipe 56,57 Water pipe 58,59
Open / close valve 60 water pipe

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shigeru Nagamori 1 Yawata Kaigan Dori, Ichihara City, Chiba Mitsui Engineering & Shipbuilding Co., Ltd. inside Chiba Works (72) Masan Takahata 1 Hachiman Kaido Dori, Ichihara City, Chiba Mitsui Zosen Co., Ltd. Company Chiba office

Claims (7)

[Claims] 1. An upper tank for storing water and a lower tank for storing compressed air are separated by an intermediate partition formed across an intermediate portion of a vertical underground tank, and a water receiving facility provided on the ground and the lower portion. A pressurized air storage type inland water flood storage tank configured to provide a water pipe connected to a tank, keep the inside of the water pipe at a negative pressure, and open the water pipe to automatically receive water from the water receiving equipment. . 2. An opening / closing valve is provided at the inlet of a water pipe connecting the ground and the lower tank, and a negative pressure is applied to the inside of the water pipe with the opening / closing valve closed to form a water column in a part or all of the water pipe. The compressed air storage type according to claim 1, wherein when the on-off valve is formed, the negative pressure in the upper part of the water column serves as a suction force to cause the water in the water receiving facility to flow into the underground tank for water supply. Inland flood storage tank. 3. The water supply pipe is an inverted U-shaped passage.
Internal pressure flood storage tank of the described pressure storage type. 4. An outer cylinder forming a tank wall, and an inner cylinder having an upper tank and a lower tank formed by a middle partition wall having a gap portion having a predetermined distance from the outer cylinder and being transversely formed. A double-structured tank having the following structure, in which a water supply channel is formed in the gap portion, a compressed air storage type inland water flood storage tank. 5. An upper partition capable of storing water and a lower tank for storing compressed air are formed by an intermediate bulkhead that traverses an intermediate portion of a vertical underground tank, and the lower tank, the drive system of the power generation equipment, and the compressor are connected to each other. It is connected by an air pipe having an opening / closing valve, has a water receiving facility for storing water near the underground tank, and water flowing in at the time of flood, and connecting the lower tank and the water storing facility with a water pipe, A pressurized air storage type inundated water storage tank equipped with an on-off valve in the water pipe and a power generation facility configured to form a liquid column in the water pipe with the on-off valve closed. 6. The pressurized air storage type internal water flood storage tank according to claim 5, wherein the water supply pipe is an inverted U-shaped passage. 7. A water level gauge is provided in the water storage facility, and a pressure gauge is provided in the lower tank, and the signals of the water level gauge and the pressure gauge are introduced into a comparator, respectively, and the signal from this comparator is provided in an air pipe. A pressure air storage type internal water flood storage tank provided with the power generation equipment according to claim 5, which is configured to control the opening / closing valve.