CN211950787U - Gas and water conversion device and air compression system - Google Patents

Abstract

The application discloses a gas and water conversion device and an air compression system, wherein the gas and water conversion device comprises a swinging piece, a liquid flow port, a first gas flow port and a second gas flow port are formed in the swinging piece, and the liquid flow port is connected with a water inlet and a water outlet and is used for providing a port for liquid flow between the swinging piece and a liquid compression area; the first gas flow port is connected with the gas inlet and outlet and is used for providing a port for gas flow between the swinging piece and the gas compression area; the second gas flow port is connected with the gas return port, and the swinging piece discharges gas into the general cylinder through the gas return port through the second gas flow port by the swinging potential energy so as to push the operation of the air compression system. Through the device, initial power can be provided for the air compression system to push the air compression system to operate.

Description

Gas and water conversion device and air compression system

Technical Field

The utility model relates to a power equipment technical field especially relates to a gas and water conversion equipment and air compression system.

Background

With the improvement of living standard of people, the problem of energy utilization is more and more concerned by people, and the utilization of related natural resources becomes a research hotspot. Among them, aerodynamic force is an important natural resource, which is mainly expressed as compressed air, and high-pressure air formed by compression can be widely applied to many fields.

The conventional air compression is usually performed by electric energy compression, which is to convert electric energy into mechanical energy and then convert the mechanical energy into high-pressure wind energy by an air compressor for the production process. The traditional air compression mode is high in energy consumption, and the energy consumption of compressed air is mainly embodied in that the air compressor needs to consume a large amount of electric energy, so that how to reduce the energy consumption by adopting a gas-water conversion structure to perform air compression becomes a research hotspot, and how to drive an air compression system to operate by utilizing the acting force of air and water in the gas-water conversion structure is particularly critical.

How to drive the operation of the air compression system by the acting force of the air and the water becomes a technical problem to be solved urgently.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides a gas and water conversion equipment and air compression system can provide initial power for air compression system, promotes air compression system's operation.

On one hand, the air and water conversion device is applied to an air compression system, the air compression system comprises a general air cylinder, the general air cylinder is of a closed structure consisting of a cylinder body and a base, a gas compression area and a liquid compression area are distributed in the general air cylinder, and the general air cylinder is provided with a gas inlet and a gas outlet for communicating the gas compression area with the outside, a water inlet and a water outlet for communicating the liquid compression area with the outside and a gas return port for collecting gas;

the gas and water conversion device comprises a swinging piece, wherein a liquid flowing port, a first gas flowing port and a second gas flowing port are formed in the swinging piece, and the liquid flowing port is connected with the water inlet and the water outlet and is used for providing a port for liquid flowing between the swinging piece and the liquid compression area; the first gas flow port is connected with the water inlet and the water outlet and is used for providing an interface for gas flow between the swinging piece and the gas compression area; the second gas flow port is connected with the air return port, and the swinging piece discharges gas into the general cylinder through the second gas flow port through the air return port by the swinging potential energy so as to push the operation of the air compression system.

Optionally, in one embodiment, the swinging member includes a pendulum bob, the pendulum bob includes a first air-to-water conversion cylinder and a second air-to-water conversion cylinder, and the first air-to-water conversion cylinder and the second air-to-water conversion cylinder are linked through a linkage member, so that the first air-to-water conversion cylinder and the second air-to-water conversion cylinder move relatively.

Optionally, in one embodiment, the air-water converter further includes a support seat, the first air-water converter cylinder and the second air-water converter cylinder are mounted on the top of the support seat through a linkage component, and the support seat is used for supporting the first air-water converter cylinder and the second air-water converter cylinder to swing.

Optionally, in one embodiment, the linkage component includes a first swing arm, a second swing arm, and a rotation ring, the first swing arm is fixedly connected to the first air-water converting cylinder, the second swing arm is fixedly connected to the second air-water converting cylinder, the first swing arm and the second swing arm are fixedly connected to the rotation ring at a predetermined angle, and the rotation ring is mounted on the top of the supporting seat.

Optionally, in one embodiment, a lifting cylinder is further disposed on the support base, and the lifting cylinder is movably connected to the linkage member and used for pushing the linkage member to rotate so as to drive the first air-water converting cylinder and the second air-water converting cylinder to perform lifting movement.

Optionally, in one embodiment, the lifting cylinder is further connected to a controller, and the operation of the lifting cylinder is controlled based on the controller;

the controller is electrically connected with an air pressure sensor arranged in the general air cylinder, and the air pressure sensor is used for detecting the air pressure in a gas storage device in the air compression system.

Optionally, in one embodiment, the controller controls the operation of the lifting cylinder through a gas solenoid valve, the controller is connected to a control end of the gas solenoid valve through a control line, an input end of the gas solenoid valve is connected to the gas inlet and outlet through a gas pipe, and an output end of the gas solenoid valve is connected to the lifting cylinder through a push gas pipe and a contraction gas pipe, respectively.

Optionally, in one embodiment, the first gas flow port and the second gas flow port are respectively provided with a check valve to control the unidirectional flow of gas.

On the other hand, an air compression system is provided, which comprises a general cylinder, wherein the general cylinder is a closed structure formed by a cylinder body and a base, a gas compression area and a liquid compression area are distributed in the general cylinder, and the general cylinder is provided with a gas inlet and outlet for communicating the gas compression area with the outside, a water inlet and outlet for communicating the liquid compression area with the outside, and a gas return opening for collecting gas;

the gas return port is connected with the gas and water conversion device, the gas and water conversion device comprises a swinging piece, a liquid flow port, a first gas flow port and a second gas flow port are formed in the swinging piece, the liquid flow port is connected with the water inlet and outlet, the first gas flow port is connected with the gas inlet and outlet, the second gas flow port is connected with the gas return port, and the swinging piece discharges gas into the general cylinder through the second gas flow port through the gas return port by the aid of potential energy after swinging.

Implement the embodiment of the utility model provides a, will have following beneficial effect:

the gas and water conversion device and the air compression system are connected with a water inlet and a water outlet, a gas inlet and a gas outlet and a gas return port in the general air cylinder through the swinging piece, and the swinging piece discharges gas into the general air cylinder through the second gas flow port and the gas return port through the swinging potential energy so as to push the air compression system to operate. Through the device, the air is conveyed into the air compression system by utilizing the interaction force between the water and the air in the swinging piece, the initial power can be provided for the air compression system, the operation of the air compression system is pushed, and the energy consumption required by the air compression system is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Wherein:

FIG. 1 is a schematic diagram of a gas-to-water conversion apparatus according to an embodiment;

FIG. 2 is a schematic view of the construction of the oscillating member in one embodiment;

FIG. 3 is a schematic view showing the structure of a pendulum in one embodiment;

FIG. 4 is a schematic diagram of the control principle of the lifting cylinder in one embodiment;

fig. 5 is a schematic view of the internal structure of the overall cylinder in one embodiment.

In the figure: 100-general cylinder, 102-cylinder body, 104-base, 110-gas inlet and outlet, 120-water inlet and outlet, 130-return port, 140-compression cylinder, 142-air channel, 150-internal frame, 160-middle cylinder, 162-air vent, 164-linkage channel, 170-linkage component, 180-lifting component, 190-piston component, 200-gas and water conversion device, 210-swinging component, 220-supporting seat, 212-liquid flow port, 214-first gas flow port, 216-second gas flow port, 310-first gas and water conversion cylinder, 320-second gas and water conversion cylinder, 330-linkage component, 332-first swinging arm, 334-second swinging arm, 336-rotating ring, 410-lifting cylinder, 420-controller, 430-gas solenoid valve, 432-gas tube, 434-push gas tube, 436-shrink gas tube, 300-gas compression zone, 400-liquid compression zone.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. It will be understood that, as used herein, the terms "first," "second," and the like may be used herein to describe various elements, but these elements are not limited by these terms. These terms are only used to distinguish one element from another. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of the present application. The first element and the second element are both components, but they are not the same component.

Fig. 1 is a schematic structural diagram of an embodiment of an air-water conversion device, which is applied to an air compression system for providing aerodynamic force, and the air-water conversion device provided in this embodiment can provide initial power for the air compression system to push the air compression system to operate. As shown in fig. 1, the gas compression system includes a general cylinder 100, the general cylinder 100 is a closed structure composed of a cylinder body and a base, and a gas compression area 300 and a liquid compression area 400 are distributed in the general cylinder 100, wherein the gas in this embodiment is air, and it is understood that the gas may be gas with other properties in other embodiments. The liquid injected into the liquid compression region 400 in this embodiment is water, and it will be appreciated that the liquid may be other properties in other embodiments. The general cylinder 100 is provided with a gas inlet/outlet 110 for connecting the gas compression area 300 to the outside, a water inlet/outlet 120 for connecting the liquid compression area 400 to the outside, and a gas return port 130 for collecting gas. Specifically, liquid is injected into the overall cylinder 100 through the water inlet and outlet 120, and after the injected liquid reaches a preset water level line, high-pressure gas is conveyed into the overall cylinder 100 from the gas inlet and outlet 110 through a gas pressure device, which may be a gas pump, and the gas pump continuously compresses air through electric power to generate gas pressure, so that a gas compression area 300 and a liquid compression area 400 with preset pressure values are formed in the overall cylinder 100, which is favorable for the operation of a gas compression system.

The air-water converting apparatus 200 includes a swing member 210 and a support base 220, and the swing member 210 is movably mounted on the support base 220. As shown in fig. 1 and fig. 2, the oscillating member 210 is provided with a liquid flow port 212, a first gas flow port 214 and a second gas flow port 216, and the liquid flow port 212 is connected to the water inlet/outlet 110 and is used for providing a liquid flow interface between the oscillating member 210 and the liquid compression region 400; the first gas flow port 214 is connected to the gas inlet and outlet 120 for providing an interface for gas flow between the oscillating piece 210 and the gas compression zone 300; the second gas flow port 216 is connected to the return port 130, and the oscillating member 210 discharges gas through the second gas flow port 216 into the overall cylinder 100 through the return port 130 by the potential energy after oscillation, so as to promote the operation of the air compression system.

Specifically, the oscillating member 210 is a pendulum, the pendulum is provided with a liquid flow port 212, a first gas flow port 214, and a second gas flow port 216, the first gas flow port 214 and the second gas flow port 216 on the pendulum are respectively communicated with the gas inlet/outlet 110 and the return air port 130 through gas pipes, and the liquid flow port 212 is communicated with the water inlet/outlet 120 through a water pipe. When the pendulum has a swing height below the water line of the liquid compression zone 400, liquid within the liquid compression zone 400 enters the pendulum through the water inlet/outlet 120 via the liquid flow port 212; when the pendulum bob has a swing height above the water line of the liquid compression zone 400, air in the gas compression zone 300 enters the pendulum bob through the gas inlet/outlet 110 via the first gas flow port 214, and liquid in the pendulum bob flows back into the general cylinder 100 through the liquid flow port 212; when the pendulum's swing height is again below the water line of the liquid compression zone 400, liquid in the liquid compression zone 400 enters the pendulum through the liquid flow port 212, and air in the pendulum enters the overall cylinder 100 through the second gas flow port 216 via the return port 130.

The gas and water conversion device is connected with a water inlet and a water outlet, a gas inlet and a gas outlet and a gas return port in the general cylinder through the swinging piece, and the swinging piece discharges gas into the general cylinder through the second gas flow port and the gas return port through the swinging potential energy so as to push the operation of the air compression system. Through the device, the air is conveyed into the air compression system by utilizing the interaction force between the water and the air in the swinging piece, the initial power can be provided for the air compression system, the operation of the air compression system is pushed, and the energy consumption required by the air compression system is reduced.

In one embodiment, referring to fig. 3, the pendulum includes a first air and water converting cylinder 310 and a second air and water converting cylinder 320, and the first air and water converting cylinder 310 and the second air and water converting cylinder 320 are linked by a linking member 330, so that the first air and water converting cylinder 310 and the second air and water converting cylinder 320 move relatively. Specifically, when the first air-water switching cylinder 310 swings upward, the second air-water switching cylinder 320 swings downward; when the first air-water switching cylinder 310 swings downward, the second air-water switching cylinder 320 swings upward.

Further, the air and water converting apparatus further includes a supporting base 220, the first air and water converting cylinder 310 and the second air and water converting cylinder 320 are mounted on the top of the supporting base 220 through a linking member 330, and the supporting base 220 is used for supporting the first air and water converting cylinder 310 and the second air and water converting cylinder 320 to swing.

More specifically, the linkage part 330 includes a first swing arm 332, a second swing arm 334 and a rotation ring 336, one end of the first swing arm 332 is fixedly connected to the first air-water conversion cylinder 310, the other end of the second swing arm 334 is fixedly connected to the second air-water conversion cylinder 320, the other end of the first swing arm 332 and the other end of the second swing arm 334 are fixedly connected to the rotation ring 336 at a preset angle, the preset angle refers to an included angle formed by the intersection of the first swing arm 332 and the second swing arm 334, for example, the preset angle may be greater than 90 degrees and smaller than 180 degrees. The rotating ring 336 is mounted on the top of the supporting base 220, and the rotating ring 336 is specifically annular and movably mounted on a horizontal shaft disposed on the top of the supporting base 220, so that the rotating ring 336 can rotate on the horizontal shaft to drive the first air and water converting cylinder 310 and the second air and water converting cylinder 320 to perform lifting movement.

Further, a lifting cylinder (not shown) is disposed on the supporting base 220, and the lifting cylinder is movably connected to the linkage member 330 for pushing the linkage member 330 to rotate, so as to drive the first air and water converting cylinder 310 and the second air and water converting cylinder 320 to perform lifting movement.

Through the air and water conversion device provided by the embodiment, the first air and water conversion cylinder 310 and the second air and water conversion cylinder 320 perform lifting motion on the supporting seat 220, so that air can be conveyed to the air compression system by utilizing the interaction force between water and air in the pendulum bob, initial power can be provided for the air compression system, the air compression system is pushed to operate, and the energy consumption required by the air compression system is reduced.

In one embodiment, referring to fig. 4, which is a schematic diagram illustrating a control principle of the lifting cylinder in one embodiment, the lifting cylinder 410 is connected to the controller 420, and the operation of the lifting cylinder 410 is controlled based on the controller 420. The controller 420 is electrically connected to a pressure sensor disposed in the general cylinder 100, and detects a pressure in a gas storage device of the air compression system through the pressure sensor, and controls the movement of the lifting cylinder according to a preset control strategy according to the pressure in the gas storage device. Specifically, the air pressure sensor penetrates through the middle of the gas storage device and is used for detecting the air pressure in the gas storage device. For example, the air pressure sensor includes an induction coil and a floating magnet ring surrounding the induction coil, the floating magnet ring floats in the liquid compression region 400, when air is stored in the gas storage device, the floating magnet ring is located at a position where air and liquid are separated inside the gas storage device and changes position according to the amount of air in the gas storage device, when the air in the gas storage device increases, the position of the floating magnet ring decreases, and when the air in the gas storage device decreases, the position of the floating magnet ring increases, so that the content of air in the gas storage device can be monitored by the air pressure sensor, that is, the air pressure in the gas storage device is detected.

Further, when the air pressure sensor detects that the air pressure in the air storage device is insufficient, the controller 420 controls the lifting cylinder 410 to start operating to push the swing member to swing, so as to deliver air to the air storage device in the air compression system through the air return port.

Through the air pressure sensor provided by the embodiment, the air pressure stored in the gas storage device can be accurately monitored, and the operation of the lifting cylinder 410 is controlled through the controller 420, so that high-pressure air can be injected into the gas storage device when the air pressure in the gas storage device is insufficient, and the operation efficiency of the air compression system is improved.

In one embodiment, with continued reference to fig. 4, the controller 420 controls the operation of the lift cylinder 410 through the gas solenoid valve 430, the controller 420 is connected to the control end of the gas solenoid valve 430 through a control line, the input end of the gas solenoid valve 430 is connected to the gas inlet/outlet of the general cylinder 100 through a gas pipe 432, and the output end of the gas solenoid valve 430 is connected to the lift cylinder 410 through a push gas pipe 434 and a pinch gas pipe 436, respectively. The controller 420 controls the on/off of the gas solenoid valve 430 to control the on/off of the push gas pipe 434 or the contraction gas pipe 436, and further controls the lifting of the lifting cylinder 410 to drive the swinging member to swing.

In one embodiment, the first gas flow port and the second gas flow port are respectively provided with a check valve to control the gas to flow in one direction. The check valve is a valve in which the opening and closing member is a circular valve flap and acts by its own weight and medium pressure to block the reverse flow of the medium, and functions to allow the medium to flow in one direction only and to block the reverse flow. The first gas flow port in this embodiment is provided with a first check valve for opening when air in the gas compression zone 300 enters the oscillating member through the first gas flow port; the second gas flow port is provided with a second check valve for opening when the air in the oscillating member enters the overall cylinder through the second gas flow port.

The gas and water conversion device provided by the above embodiment is connected with the water inlet and outlet, the gas inlet and outlet and the return air port in the general cylinder through the swinging member, and the swinging member discharges gas into the general cylinder through the second gas flow port and the return air port through the swinging potential energy so as to push the operation of the air compression system. Through the device, the air is conveyed into the air compression system by utilizing the interaction force between the water and the air in the swinging piece, the initial power can be provided for the air compression system, the operation of the air compression system is pushed, and the energy consumption required by the air compression system is reduced.

Based on the same inventive concept, the following provides an air compression system, please continue to refer to fig. 1, the air compression system includes a general cylinder 100, the general cylinder 100 is a closed structure composed of a cylinder body and a base, and a gas compression area 300 and a liquid compression area 400 are distributed in the general cylinder 100. The general cylinder 100 is provided with a gas inlet/outlet 110 for connecting the gas compression area 300 to the outside, a water inlet/outlet 120 for connecting the liquid compression area 400 to the outside, and a gas return port 130 for collecting gas.

Further, the gas return opening 130 is connected to the gas-water converting device 200, the gas-water converting device 200 includes a swinging member 210, the swinging member 210 is provided with a liquid flow opening, a first gas flow opening and a second gas flow opening, the liquid flow opening is connected to the water inlet and outlet 120, the first gas flow opening is connected to the gas inlet/outlet 110, the second gas flow opening is connected to the gas return opening 130, and the swinging member 210 discharges the gas into the general cylinder 100 through the gas return opening 130 via the second gas flow opening by the potential energy after swinging.

Through the air compression system that this embodiment provided, utilize the interaction force between water and the air in the swinging member, carry the air in the air compression system, can provide initial power for the air compression system, promote the operation of air compression system, reduced the required energy consumption of air compression system.

In one embodiment, referring to fig. 5, which is a schematic view illustrating an internal structure of the general cylinder in one embodiment, an internal frame 150 is disposed in a liquid compression region 400 of the general cylinder 100, that is, the internal frame 150 is covered by liquid, a water level line of the liquid is higher than a certain position above the internal frame 150, and the internal frame 150 is fixedly mounted on the base 104.

The inner frame 150 is provided with a middle cylinder 160 for collecting air, and particularly, the middle cylinder 160 is erected in the middle area of the inner frame 150 in the height direction, and the middle cylinder 160 forms a semi-enclosed accommodating space for temporarily storing air. The air sources stored in the middle cylinder 160 include air injected from the return air port 130, and outside air introduced by the compression cylinder 140. Due to the characteristics of air and water, when air enters the liquid compression region 400, the air quickly floats up in the liquid region, and since the air return opening 130 and the compression cylinder 140 are both disposed below the middle cylinder 160, the air temporarily stores in the accommodating space formed by the middle cylinder 160 when floating up.

The middle cylinder 160 is provided with a controllable air vent 162 and a through linkage channel 164, the air vent 162 is provided at the top of the middle cylinder 160, the on-off of the air vent 162 is controlled by a controllable switch, so that the air stored in the middle cylinder 160 can be released, and the opening or closing of the air vent 162 can be controlled by an electromagnetic valve, for example. A linkage channel 164 opens through the middle cylinder 160, the linkage channel 164 providing an operable channel.

Further, the inner frame 150 is provided with the linkage assembly 170, the linkage assembly 170 is connected with the lifting assembly 180, the lifting assembly 180 is connected with the piston assembly 190, the piston assembly 190 penetrates through the linkage passage 164 to be matched with the compression cylinder 140 to perform piston movement, so that outside air enters the compression cylinder 140 through the air passage 142 and then enters the middle cylinder 160 through the compression cylinder 140, and the lifting assembly 180 transfers the air in the middle cylinder 160 to the air compression area 300 through lifting movement. Specifically, the linkage assembly 170 is installed on the top of the inner frame 170 to provide a support for the lifting assembly 180 to perform lifting movement, and the piston assembly 190 is configured with the cylinder piston 140. For example, the linkage assembly 170 may include a pulley and a connecting belt, the lifting assembly 180 may include a floating cylinder, and the piston assembly 190 may include a linkage rod and a piston, and it should be noted that the linkage assembly 170, the lifting assembly 180, and the piston assembly 190 may also be replaced by other structures having the same or similar functions, which is not limited in this embodiment.

Further, the air return opening 130 is used to connect with an air and water converting device, and air provided by the air and water converting device is introduced into the middle cylinder to push the operation of the lifting assembly. Specifically, the return air port 130 is used for injecting air into the general cylinder 100, and when the gas compression system starts to operate, the air injected through the return air port 130 is delivered to the middle cylinder 160 and then transferred to the lifting assembly 180 through the air port 162 of the middle cylinder 160, so that the lifting assembly 180 starts to operate, and initial power is provided for the lifting assembly 180 to perform lifting movement. The principle that gaseous meeting come-up in liquid is utilized to this embodiment, with gaseous storage in the accommodation space that is formed by the cylinder body to through the gaseous of the storage of controllable formula blow vent release cylinder body, and then utilize the effort of gaseous come-up to drive the operation of air compression system, can reduce air compression system's energy consumption.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (9)

1. The gas and water conversion device is characterized by being applied to an air compression system, wherein the air compression system comprises a general cylinder, the general cylinder is of a closed structure consisting of a cylinder body and a base, a gas compression area and a liquid compression area are distributed in the general cylinder, and the general cylinder is provided with a gas inlet and a gas outlet for communicating the gas compression area with the outside, a water inlet and a water outlet for communicating the liquid compression area with the outside and a gas return port for collecting gas;

the gas and water conversion device comprises a swinging piece, wherein a liquid flowing port, a first gas flowing port and a second gas flowing port are formed in the swinging piece, and the liquid flowing port is connected with the water inlet and the water outlet and is used for providing a port for liquid flowing between the swinging piece and the liquid compression area; the first gas flow port is connected with the gas inlet and outlet and is used for providing an interface for gas flow between the swinging piece and the gas compression area; the second gas flow port is connected with the air return port, and the swinging piece discharges gas into the general cylinder through the second gas flow port through the air return port by the swinging potential energy so as to push the operation of the air compression system.

2. The air-water converting device according to claim 1, wherein the swinging member comprises a pendulum bob, the pendulum bob comprises a first air-water converting cylinder and a second air-water converting cylinder, and the first air-water converting cylinder and the second air-water converting cylinder are linked by a linking member, so that the first air-water converting cylinder and the second air-water converting cylinder move relatively.

3. The apparatus as claimed in claim 2, further comprising a support base, wherein the first and second air-to-water converting cylinders are mounted on the top of the support base through a linkage member, and the support base is used for supporting the first and second air-to-water converting cylinders to swing.

4. The air-water converting device according to claim 3, wherein the linkage member comprises a first swing arm, a second swing arm and a rotating ring, the first swing arm is fixedly connected with the first air-water converting cylinder, the second swing arm is fixedly connected with the second air-water converting cylinder, the first swing arm and the second swing arm are fixedly connected to the rotating ring at a predetermined angle, and the rotating ring is mounted on the top of the supporting seat.

5. The air-water converting device according to claim 3, wherein the supporting base further comprises a lifting cylinder movably connected to the linking member for driving the linking member to rotate so as to drive the first air-water converting cylinder and the second air-water converting cylinder to move up and down.

6. The gas-water conversion device according to claim 5, wherein the lifting cylinder is further connected with a controller, and the operation of the lifting cylinder is controlled based on the controller;

the controller is electrically connected with an air pressure sensor arranged in the general air cylinder, and the air pressure sensor is used for detecting the air pressure in a gas storage device in the air compression system.

7. The gas-water conversion device according to claim 6, wherein the controller controls the operation of the lifting cylinder through a gas solenoid valve, the controller is connected with the control end of the gas solenoid valve through a control line, the input end of the gas solenoid valve is connected with the gas inlet and outlet through a gas pipe, and the output end of the gas solenoid valve is connected with the lifting cylinder through a push gas pipe and a contraction gas pipe respectively.

8. The gas and water conversion device of claim 1, wherein the first and second gas flow ports are respectively provided with a check valve for controlling the unidirectional flow of gas.

9. An air compression system is characterized by comprising a general air cylinder, wherein the general air cylinder is of a closed structure consisting of a cylinder body and a base, a gas compression area and a liquid compression area are distributed in the general air cylinder, and the general air cylinder is provided with a gas inlet and outlet for communicating the gas compression area with the outside, a water inlet and outlet for communicating the liquid compression area with the outside and a gas return port for collecting gas;

the gas return port is connected with the gas and water conversion device, the gas and water conversion device comprises a swinging piece, a liquid flow port, a first gas flow port and a second gas flow port are formed in the swinging piece, the liquid flow port is connected with the water inlet and outlet, the first gas flow port is connected with the gas inlet and outlet, the second gas flow port is connected with the gas return port, and the swinging piece discharges gas into the general cylinder through the second gas flow port through the gas return port by the aid of potential energy after swinging.

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