CN114562405A

CN114562405A - Multi-module air type energy storage power station

Info

Publication number: CN114562405A
Application number: CN202210370453.8A
Authority: CN
Inventors: 蔡正龙
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-04-10
Filing date: 2022-04-10
Publication date: 2022-05-31

Abstract

The invention relates to the field of energy storage power stations, in particular to a multi-module air type energy storage power station, which comprises a water channel, wherein a power generation mechanism is arranged in the water channel, an energy storage mechanism is arranged in the power generation mechanism, a fixing mechanism is arranged at the upper end of the energy storage mechanism, and a backflow mechanism is arranged at the other end of the fixing mechanism; the power generation mechanism comprises a fixing plate, the fixing plate is fixedly connected to the inner wall of the ditch, a connecting channel is formed in the surface of the fixing plate, high-pressure gas is input into the first cylinder through the three-way valve, the first piston plate is pushed to move through the high-pressure gas, the first piston plate drives the second piston plate to move through the U-shaped rod, the water flow inside the second cylinder is pushed to be input into the water pipe when the second piston plate moves, then the water flowing into the low-level water tank flows back into the high-level water tank through the water pipe, and then the water cannot be supplied for the backflow of the water flow when the electric quantity of the energy storage battery is low, and then the energy storage power station can generate electricity in time.

Description

Multi-module air type energy storage power station

Technical Field

The invention relates to the field of energy storage power stations, in particular to a multi-module air type energy storage power station.

Background

The energy storage power station is an equipment system which can store, convert and release circulated electric energy through an electrochemical battery or an electromagnetic energy storage medium, the water pumping energy storage power station is provided with a water pumping and power generating dual-purpose unit, can pump water and generate power, a reservoir drains water at daytime and the first night, water with high water level passes through the dual-purpose unit, the dual-purpose unit serves as a generator at the moment, and mechanical energy of the water with high water level is converted into electric energy to be transmitted to a power grid.

When the existing water pumping and energy storage power station is used, a water pumping-power generation dual-purpose unit needs to be installed, a large amount of electric power needs to be consumed when water is pumped at a low peak of power utilization, certain electric quantity needs to exist in an energy storage battery of the energy storage power station in order to enable low-level water to flow back to a high level, the electric power consumed at a high peak of power utilization cannot be predicted, and the residual electric quantity in the energy storage battery sometimes cannot provide enough electric power for the backflow of a water level, so that the water level cannot flow back in time, and further the energy storage power station can possibly generate power in time; and the existing water pumping and power generating dual-purpose unit needs to deal with the pressure of high-level water flow when pumping water in a reverse flow manner, so that a large amount of energy is needed when pumping water.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a multi-module air type energy storage power station.

The technical scheme adopted by the invention for solving the technical problems is as follows: a multi-module air type energy storage power station comprises a water channel, wherein a power generation mechanism is arranged in the water channel, an energy storage mechanism is arranged in the power generation mechanism, a fixing mechanism is arranged at the upper end of the energy storage mechanism, and a backflow mechanism is arranged at the other end of the fixing mechanism;

the power generation mechanism comprises a fixed plate, the fixed plate is fixedly connected to the inner wall of the water channel, a connecting channel is formed in the surface of the fixed plate, a rotary groove is formed in the inner wall of the upper end of the connecting channel, a rotary shaft is rotatably connected to the center of the rotary groove, a rotary drum is fixedly sleeved on the surface of the rotary shaft to rotate, and a plurality of rotary plates are fixedly connected to the outer wall of the rotary drum at equal intervals; the other ends of the rotating plates are fixedly connected with round rods, a fixing frame is fixedly connected to the side wall of one side of the fixing plate, an opening is formed in the side wall of the fixing frame, a hydraulic cylinder is embedded into the top end of the fixing frame, and a baffle is fixedly connected to the output end of the hydraulic cylinder; one end of the rotating shaft extends to the outside of the water channel and is connected to a generator, and the generator is fixedly connected with an energy storage battery;

the energy storage mechanism comprises an arc groove, the arc groove is formed in the inner wall of the rotating groove, a fixed shaft is fixedly connected to the inner wall of the arc groove, and an arc plate is rotatably connected to the surface of the fixed shaft; an insertion hole is formed in the inner wall of the upper end of the arc groove, the upper end of the insertion hole is communicated with the groove, the groove is formed in the upper surface of the fixing plate, and an insertion rod is inserted into the insertion hole; the upper end fixedly connected with piston block of inserted bar, the piston block activity cup joints inside the sleeve, sleeve fixed connection is on the inner wall of recess, fixed intercommunication has the intake pipe on the telescopic lateral wall, the one-way admission valve of fixedly connected with on the surface of intake pipe, telescopic inside joint has the spring.

Specifically, the fixing mechanism comprises a gas tank, the gas tank is clamped in the groove, a connecting interface is fixedly communicated with the side wall of one side of the gas tank, a connecting joint is connected inside the connecting interface, a connecting pipe is fixedly communicated with the lower end of the connecting joint, and the lower end of the connecting pipe is fixedly connected to the upper end of the sleeve; the surface of the connecting pipe is fixedly connected with a one-way exhaust valve, the inner wall of the groove is fixedly connected with a rotating rod, and the surface of the rotating rod is rotatably connected with a top cover; the upper surface of top cap corresponds with the upper surface of fixed plate, the trompil has been seted up on the upper surface of fixed plate, the annular has been seted up on the bottom inner wall in trompil, the inside joint of annular has the swivel, fixed the cup jointing has L shape pole on the inner wall of swivel, the upper end joint of L shape pole is on the upper surface of top cap, the lower surface joint of top cap is on the upper surface of gas pitcher.

The backflow mechanism comprises an exhaust pipe, the exhaust pipe is fixedly communicated with the outer wall of one side of the gas tank, the exhaust pipe is embedded in a fixing plate, the other end of the exhaust pipe is fixedly communicated with a first cylinder, a first piston plate is connected to the inside of the first cylinder in a sliding mode, a U-shaped rod is fixedly connected to one side of the first piston plate, the other end of the U-shaped rod is inserted into a second cylinder, and a second piston plate is fixedly connected to one end, located inside the second cylinder, of the U-shaped rod; a water inlet pipe is fixedly communicated with the side wall of the lower end of the second cylinder, a one-way water inlet valve is fixedly connected to the surface of the water inlet pipe, an air cylinder is fixedly connected to the upper surface of the first cylinder, and a water delivery pipe is fixedly communicated with the upper end of the second cylinder; the water delivery pipe is characterized in that a one-way drain valve is fixedly connected to the surface of the water delivery pipe, a first supporting rod is fixedly connected to one end of the water delivery pipe, the other end of the first supporting rod is fixedly connected to one side wall of the fixing plate, a second supporting rod is fixedly connected to the other end of the water delivery pipe, the second supporting rod is fixedly connected to the other side wall of the fixing plate, and a three-way valve is fixedly connected to the surface of the water delivery pipe.

Specifically, the baffle corresponds to the connecting channel, and the length and the width of the baffle are both larger than those of the connecting channel.

Specifically, the arc groove is arranged at the upper end of the inner wall of the rotary groove close to the fixed frame.

Specifically, the water inlet pipe and the water delivery pipe are symmetrically arranged on one side, far away from the exhaust pipe, of the second cylinder.

Specifically, the output end of the air cylinder is fixedly connected to the surface of the U-shaped rod.

Specifically, two ends of the water conveying pipe are respectively positioned at two sides of the fixing plate.

The invention has the beneficial effects that:

(1) according to the multi-module air type energy storage power station, high-pressure gas is input into the first cylinder through the three-way valve, the first piston plate is pushed to move through the high-pressure gas, the first piston plate drives the second piston plate to move through the U-shaped rod, water flow in the second cylinder is pushed to be input into the water conveying pipe when the second piston plate moves, then water flowing into the low-level water tank flows back into the high-level water tank through the water conveying pipe, and therefore the situation that power cannot be supplied to the water flow when the electric quantity of an energy storage battery is low is avoided, and the energy storage power station can generate power in time.

(2) According to the multi-module air type energy storage power station, the U-shaped rod is pulled through the air cylinder, the first piston plate and the second piston plate move back, air in the first cylinder is discharged through the three-way valve, water is pumped into the second cylinder through the water inlet pipe and the one-way water inlet valve to wait for next water delivery when the second piston plate moves back, and the stored gas assists backflow, so that energy consumed when water flows move back can be greatly reduced.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural diagram of a multi-module air-based energy storage power plant according to the present invention;

FIG. 2 is a schematic side view of a multi-module air-based energy storage power plant according to the present invention;

FIG. 3 is a schematic view of a fixed frame structure of a multi-module air-type energy storage power station according to the present invention;

FIG. 4 is a schematic structural diagram of a backflow mechanism of a multi-module air-type energy storage power station according to the present invention;

FIG. 5 is a schematic structural diagram of a fixing mechanism of a multi-module air-type energy storage power station according to the present invention;

fig. 6 is a schematic structural diagram of a power generation mechanism of a multi-module air type energy storage power station provided by the invention.

In the figure: 1. a ditch; 2. a power generation mechanism; 21. a fixing plate; 22. a connecting channel; 23. rotating the groove; 24. a rotating shaft; 25. a rotating drum; 26. rotating the plate; 27. a round bar; 28. a fixing frame; 29. an opening; 210. a hydraulic cylinder; 211. a baffle plate; 212. a generator; 213. an energy storage battery; 3. an energy storage mechanism; 31. an arc groove; 32. a fixed shaft; 33. an arc plate; 34. a jack; 35. a groove; 36. inserting a rod; 37. a piston block; 38. a sleeve; 39. an air inlet pipe; 310. a one-way intake valve; 311. a spring; 4. a fixing mechanism; 41. a gas tank; 42. a connection interface; 43. connecting a joint; 44. a connecting pipe; 45. a one-way exhaust valve; 46. a rotating rod; 47. a top cover; 48. hole turning; 49. a ring groove; 410. rotating the ring; 411. an L-shaped rod; 5. a reflux mechanism; 51. an exhaust pipe; 52. a first cylinder; 53. a first piston plate; 54. a U-shaped rod; 55. a second cylinder; 56. a second piston plate; 57. a water inlet pipe; 58. a one-way water inlet valve; 59. a cylinder; 510. a water delivery pipe; 511. a one-way drain valve; 512. a first support bar; 513. a second support bar; 514. and a three-way valve.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-6, the multi-module air type energy storage power station according to the present invention includes a water channel 1, a power generation mechanism 2 is disposed in the water channel 1, an energy storage mechanism 3 is disposed in the power generation mechanism 2, a fixing mechanism 4 is disposed at an upper end of the energy storage mechanism 3, and a backflow mechanism 5 is disposed at another end of the fixing mechanism 4;

the power generation mechanism 2 comprises a fixed plate 21, the fixed plate 21 is fixedly connected to the inner wall of the ditch 1, a connecting channel 22 is formed in the surface of the fixed plate 21, a rotating groove 23 is formed in the inner wall of the upper end of the connecting channel 22, a rotating shaft 24 is rotatably connected to the center of the rotating groove 23, a rotating drum 25 is fixedly sleeved on the surface of the rotating shaft 24 to rotate, and a plurality of rotating plates 26 are fixedly connected to the outer wall of the rotating drum 25 at equal intervals; the other ends of the plurality of rotating plates 26 are fixedly connected with round rods 27, a fixing frame 28 is fixedly connected to the side wall of one side of the fixing plate 21, an opening 29 is formed in the side wall of the fixing frame 28, a hydraulic cylinder 210 is embedded at the top end of the fixing frame 28, and a baffle 211 is fixedly connected to the output end of the hydraulic cylinder 210; one end of the rotating shaft 24 extends to the outside of the water channel 1 and is connected to the generator 212, the generator 212 is fixedly connected with the energy storage battery 213, the rotating plate 26 is driven to rotate by the low-level water flow flowing from the high-level water flow, the rotating plate 26 drives the rotating shaft 24 to rotate, and the generator 212 generates electricity;

the energy storage mechanism 3 comprises an arc groove 31, the arc groove 31 is arranged on the inner wall of the rotating groove 23, a fixed shaft 32 is fixedly connected on the inner wall of the arc groove 31, and an arc plate 33 is rotatably connected on the surface of the fixed shaft 32; an insertion hole 34 is formed in the inner wall of the upper end of the arc groove 31, the upper end of the insertion hole 34 is communicated with a groove 35, the groove 35 is formed in the upper surface of the fixing plate 21, and an insertion rod 36 is inserted into the insertion hole 34; the upper end fixedly connected with piston block 37 of inserted bar 36, piston block 37 activity cup joints inside sleeve 38, sleeve 38 fixed connection is on the inner wall of recess 35, the fixed intercommunication has intake pipe 39 on the lateral wall of sleeve 38, intake pipe 39's fixed connection has one-way admission valve 310 on the surface, sleeve 38's inside joint has spring 311, it rotates to promote slide 33 when commentaries on classics board 26 rotates, promote the inserted bar 36 through arc 33 and remove, and then with gas compression input gas pitcher 41 in, be used for extracting rivers.

Specifically, the fixing mechanism 4 includes a gas tank 41, the gas tank 41 is clamped in the groove 35, a connecting interface 42 is fixedly communicated with a side wall of one side of the gas tank 41, a connecting joint 43 is connected inside the connecting interface 42, a connecting pipe 44 is fixedly communicated with a lower end of the connecting joint 43, and a lower end of the connecting pipe 44 is fixedly connected to an upper end of the sleeve 38; a one-way exhaust valve 45 is fixedly connected to the surface of the connecting pipe 44, a rotating rod 46 is fixedly connected to the inner wall of the groove 35, and a top cover 47 is rotatably connected to the surface of the rotating rod 46; the upper surface of top cap 47 corresponds with the upper surface of fixed plate 21, rotating hole 48 has been seted up on the upper surface of fixed plate 21, annular groove 49 has been seted up on rotating hole 48's the bottom inner wall, the inside joint of annular groove 49 has swivel 410, fixed cover has connect L shape pole 411 on swivel 410's the inner wall, the upper end joint of L shape pole 411 is on the upper surface of top cap 47, the lower surface joint of top cap 47 is on the upper surface of gas pitcher 41, through the fixed top cap 47 of L shape pole 411, through the fixed gas pitcher 41 of top cap 47.

Specifically, the backflow mechanism 5 includes an exhaust pipe 51, the exhaust pipe 51 is fixedly communicated with an outer wall of one side of the gas tank 41, the exhaust pipe 51 is embedded in the fixing plate 21, the other end of the exhaust pipe 51 is fixedly communicated with a first cylinder 52, a first piston plate 53 is slidably connected inside the first cylinder 52, one side of the first piston plate 53 is fixedly connected with a U-shaped rod 54, the other end of the U-shaped rod 54 is inserted into a second cylinder 55, and one end of the U-shaped rod 54 located inside the second cylinder 55 is fixedly connected with a second piston plate 56; a water inlet pipe 57 is fixedly communicated with the side wall of the lower end of the second cylinder 55, a one-way water inlet valve 58 is fixedly connected with the surface of the water inlet pipe 57, an air cylinder 59 is fixedly connected with the upper surface of the first cylinder 52, and a water delivery pipe 510 is fixedly communicated with the upper end of the second cylinder 55; the one-way drain valve 511 of raceway 510's fixedly connected with on the surface, the first bracing piece 512 of one end fixedly connected with of raceway 510, the other end fixed connection of first bracing piece 512 is on one side lateral wall of fixed plate 21, the other end fixedly connected with second bracing piece 513 of raceway 510, second bracing piece 513 fixed connection is on the opposite side lateral wall of fixed plate 21, raceway 510's fixedly connected with three-way valve 514 on the surface, promote first piston plate 53 and second piston plate 56 through high-pressure gas, and then make gaseous promotion rivers flow to the fixed plate 21 opposite side.

Specifically, the baffle 211 corresponds to the connecting passage 22, and the length and the width of the baffle 211 are both greater than those of the connecting passage 22, so that the connecting passage 22 is completely blocked by the baffle 211.

Specifically, the arc groove 31 is formed at the upper end of the inner wall of the rotating groove 23 close to the fixed frame 28, so that the rotating plate 26 is in contact with the arc surface of the arc plate 33 when rotating, and the arc plate 33 is pressed to rotate.

Specifically, the water inlet pipe 57 and the water pipe 510 are symmetrically disposed on a side of the second cylinder 55 away from the exhaust pipe 51, so that when the high-pressure gas pushes the first piston plate 53 and the second piston plate 56, the water inside the second cylinder 55 is pushed into the water pipe 510.

Specifically, the output end of the air cylinder 59 is fixedly connected to the surface of the U-shaped rod 54, and the U-shaped rod 54 is pulled to move by the air cylinder 59.

Specifically, two ends of the water pipe 510 are respectively located at two sides of the fixing plate 21. And then the low-level water pool is input into the high-level water pool through the water delivery pipe 510

When in use, the utility model is used,

firstly, the hydraulic cylinder 210 is started to drive the baffle 211 to move upwards at the peak of electricity utilization, the baffle 211 moves upwards to remove the block of the connecting channel 22, so that the high-level water flow moves to the low-level water flow through the connecting channel 22, the rotating plate 26 is pushed when the water flow flows, so that the rotating plate 26 rotates, the rotating plate 26 drives the rotating drum 25 to rotate, the rotating drum 25 drives the rotating shaft 24 to rotate, the rotating shaft 24 drives the generator 212 to generate electricity when rotating, then the electricity is input into the energy storage battery 213, meanwhile, the rotating plate 26 drives the round rod 27 to push the arc plate 33 when rotating, so that the arc plate 33 rotates around the fixed shaft 32, the arc plate 33 pushes the inserted rod 36 to move upwards and downwards, so that the inserted rod 36 pushes the piston block 37 to move upwards, the piston block 37 pushes the air in the sleeve 38 to be input into the air tank 41 through the connecting pipe 44, then the piston block 37 is pushed to move backwards through the spring 311, and simultaneously, the air is pumped through the air inlet pipe 39 and the one-way air inlet valve 310 to perform static inflation, further, when electricity is generated, gas is filled into the gas tank 41, when electricity consumption is low, the air hydraulic cylinder 210 pushes the baffle 211 to move downwards to block the connecting channel 22, then the three-way valve 514 is started to input high-pressure gas into the first cylinder 52, the first piston plate 53 is pushed to move by the high-pressure gas, the first piston plate 53 pushes the U-shaped rod 54 to move, the U-shaped rod 54 drives the second piston plate 56 to move, the water flow in the second cylinder 55 is pushed to be input into the water conveying pipe 510 when the second piston plate 56 moves, water is input into the other end of the fixed plate 21 through the one-way drain valve 511 in the water conveying pipe 510, then the water flowing into the low-level water pool flows back into the high-level water pool, further, the situation that the electric quantity of the energy storage battery 213 is low and the power cannot be supplied for the backflow of the water flow is prevented, when the water in the second cylinder 55 is discharged once, the air cylinder 59 is started to pull the U-shaped rod 54, so that the first piston plate 53 and the second piston plate 56 move back, meanwhile, the air in the first cylinder 52 is exhausted through the three-way valve 514, when the second piston plate 56 moves back, the water is pumped into the second cylinder 55 through the water inlet pipe 57 and the one-way water inlet valve 58 to wait for the next water delivery, and the stored gas assists the backflow, so that the energy consumed when the water moves back can be greatly reduced.

The foregoing shows and describes the general principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a multimode air formula energy storage power station, includes ditch (1), its characterized in that: a power generation mechanism (2) is arranged in the water channel (1), an energy storage mechanism (3) is arranged in the power generation mechanism (2), a fixing mechanism (4) is arranged at the upper end of the energy storage mechanism (3), and a backflow mechanism (5) is arranged at the other end of the fixing mechanism (4);

the power generation mechanism (2) comprises a fixing plate (21), the fixing plate (21) is fixedly connected to the inner wall of the water channel (1), a connecting channel (22) is formed in the surface of the fixing plate (21), a rotary groove (23) is formed in the inner wall of the upper end of the connecting channel (22), a rotary shaft (24) is rotatably connected to the center of the rotary groove (23), a rotary drum (25) is fixedly sleeved on the surface of the rotary shaft (24) to rotate, and a plurality of rotary plates (26) are fixedly connected to the outer wall of the rotary drum (25) at equal intervals; the other ends of the rotating plates (26) are fixedly connected with round rods (27), a fixed frame (28) is fixedly connected to the side wall of one side of the fixed plate (21), an opening (29) is formed in the side wall of the fixed frame (28), a hydraulic cylinder (210) is embedded at the top end of the fixed frame (28), and a baffle (211) is fixedly connected to the output end of the hydraulic cylinder (210); one end of the rotating shaft (24) extends to the outside of the water channel (1) and is connected to a generator (212), and the generator (212) is fixedly connected with an energy storage battery (213);

the energy storage mechanism (3) comprises an arc groove (31), the arc groove (31) is formed in the inner wall of the rotating groove (23), a fixed shaft (32) is fixedly connected to the inner wall of the arc groove (31), and an arc plate (33) is rotatably connected to the surface of the fixed shaft (32); an insertion hole (34) is formed in the inner wall of the upper end of the arc groove (31), the upper end of the insertion hole (34) is communicated with a groove (35), the groove (35) is formed in the upper surface of the fixing plate (21), and an insertion rod (36) is inserted into the insertion hole (34); the upper end fixedly connected with piston block (37) of inserted bar (36), piston block (37) activity cup joints inside sleeve (38), sleeve (38) fixed connection is on the inner wall of recess (35), fixed intercommunication has intake pipe (39) on the lateral wall of sleeve (38), the one-way admission valve (310) of fixedly connected with on the surface of intake pipe (39), the inside joint of sleeve (38) has spring (311).

2. A multi-module air energy storage power plant as claimed in claim 1 wherein: the fixing mechanism (4) comprises a gas tank (41), the gas tank (41) is clamped in the groove (35), a connecting interface (42) is fixedly communicated with the side wall of one side of the gas tank (41), a connecting joint (43) is connected inside the connecting interface (42), a connecting pipe (44) is fixedly communicated with the lower end of the connecting joint (43), and the lower end of the connecting pipe (44) is fixedly connected to the upper end of the sleeve (38); a one-way exhaust valve (45) is fixedly connected to the surface of the connecting pipe (44), a rotating rod (46) is fixedly connected to the inner wall of the groove (35), and a top cover (47) is rotatably connected to the surface of the rotating rod (46); the upper surface of top cap (47) corresponds with the upper surface of fixed plate (21), change hole (48) have been seted up on the upper surface of fixed plate (21), annular (49) have been seted up on the bottom inner wall of change hole (48), the inside joint of annular (49) has swivel (410), fixed cover has connect L shape pole (411) on the inner wall of swivel (410), the upper end joint of L shape pole (411) is on the upper surface of top cap (47), the lower surface joint of top cap (47) is on the upper surface of gas pitcher (41).

3. A multi-module air energy storage power plant as claimed in claim 1 wherein: the backflow mechanism (5) comprises an exhaust pipe (51), the exhaust pipe (51) is fixedly communicated with the outer wall of one side of the gas tank (41), the exhaust pipe (51) is embedded in the fixing plate (21), the other end of the exhaust pipe (51) is fixedly communicated with a first cylinder (52), a first piston plate (53) is connected to the inside of the first cylinder (52) in a sliding mode, a U-shaped rod (54) is fixedly connected to one side of the first piston plate (53), the other end of the U-shaped rod (54) is inserted into a second cylinder (55), and a second piston plate (56) is fixedly connected to one end, located inside the second cylinder (55), of the U-shaped rod (54); a water inlet pipe (57) is fixedly communicated with the side wall of the lower end of the second cylinder (55), a one-way water inlet valve (58) is fixedly connected to the surface of the water inlet pipe (57), an air cylinder (59) is fixedly connected to the upper surface of the first cylinder (52), and a water delivery pipe (510) is fixedly communicated with the upper end of the second cylinder (55); the utility model discloses a water pipe, including raceway (510), the one-way drain valve (511) of fixedly connected with on the surface of raceway (510), the first bracing piece of one end fixedly connected with (512) of raceway (510), the other end fixed connection of first bracing piece (512) is on one side lateral wall of fixed plate (21), the other end fixedly connected with second bracing piece (513) of raceway (510), second bracing piece (513) fixed connection is on the opposite side lateral wall of fixed plate (21), the fixedly connected with three-way valve (514) on the surface of raceway (510).

4. A multi-module air energy storage power plant as claimed in claim 1 wherein: the baffle (211) corresponds to the connecting channel (22), and the length and the width of the baffle (211) are both larger than those of the connecting channel (22).

5. A multi-module air energy storage power plant as claimed in claim 1 wherein: the arc groove (31) is arranged at the upper end of the inner wall of one side of the rotary groove (23) close to the fixed frame (28).

6. A multi-module air energy storage power plant as claimed in claim 3 wherein: the water inlet pipe (57) and the water delivery pipe (510) are symmetrically arranged on one side, far away from the exhaust pipe (51), of the second cylinder (55).

7. A multi-module air energy storage power plant according to claim 3 wherein: the output end of the air cylinder (59) is fixedly connected to the surface of the U-shaped rod (54).

8. A multi-module air energy storage power plant according to claim 3 wherein: two ends of the water conveying pipe (510) are respectively positioned at two sides of the fixing plate (21).