CN112228303A - Air compression pressure-collecting system - Google Patents

Abstract

The invention belongs to the field of new energy preparation and collection, and particularly relates to an air compression pressure-collecting system, which aims to solve the problems that when compressed air is prepared at present, electric energy is required to be consumed for preparation by a physical means, specific natural kinetic energy is required to be collected or redundant kinetic energy of other machinery is required to be collected, the consumed resources are large for collection by a chemical means, and the return ratio is not high only for collecting the compressed air; the gas generating device passes through the pipeline interconnect, and the gas circuit is all connected to the gaseous generating device of multiunit, the exit end and the gas collecting tank of gas circuit are connected, utilize water gravity as original power, produce height drop through water gravity and do a work and make the system can move, and then compress the air in the gas collecting tank, make the air in the gas collecting tank collect in the gas collecting tank, through setting up the gaseous generating device of multiunit, circulation to as power supply each other, can last the operation for a long time.

Description

Air compression pressure-collecting system

Technical Field

The invention belongs to the field of new energy preparation and collection, and particularly relates to an air compression pressure-collecting system.

Background

Air occupies a certain space, but it does not have a fixed shape and volume. When pressure is applied to the air in the closed container, the volume of the air is compressed, and the internal pressure is increased. When the external force is removed, the air returns to its original volume under the action of the internal pressure. If there is a movable object in the container, the object will be pushed outward by the pressure of the air in the container when the air returns to its original volume. The principle is widely applied to production and life. For example: compressed air is pumped into the leather ball, and the more sufficient the air is, the harder the ball is; compressed air is pumped into the tire, and the tire can bear certain weight. On a large automobile, a door and a brake are opened and closed by compressed air; the hydraulic press uses compressed air to pressurize water, and in a factory, the compressed air is used for starting an air hammer to strike iron; in a coal mine, the pneumatic pick can be started to drill holes. But also for piping liquids and granular objects.

Compressed air, i.e. air compressed by an external force. The air has compressibility, and the volume of the air is reduced and the pressure of the air is increased by the mechanical work of the air compressor, so that the compressed air is called. Compressed air is an important power source. Compared with other energy sources, the energy source has the following obvious characteristics: the air-permeable fire-resistant composite material is clear and transparent, convenient to convey, free of special harmful performance, free of fire danger and overload, capable of working in various adverse environments, and inexhaustible air is available everywhere on the ground.

Compressed air is the second largest power source second to electric power, and is a process air source with multiple purposes, and is widely applied to industries and departments of petroleum, chemical industry, metallurgy, electric power, machinery, light industry, textile, automobile manufacturing, electronics, food, medicine, biochemistry, national defense, scientific research and the like.

At present, when compressed air is prepared, the conventional method adopts physical means such as an air compressor or other chemical gas generation means, most of common air compressors are driven by electric power and consume a large amount of electric energy, or are arranged at special positions and driven by natural kinetic energy such as wind power or water power, or are in parallel motion with other machines, the redundant kinetic energy in the original mechanical activity process is utilized, and the chemical gas generation means is mostly used for small-batch production in the field of experiments or is independently prepared for a certain special gas.

In summary, when compressed air is prepared at present, electric energy is consumed for preparation by a physical means, specific natural kinetic energy is required to be collected or redundant kinetic energy of other machines is required to be collected, the collection by a chemical means consumes large resources, and the return ratio is not high only for collecting compressed air.

Disclosure of Invention

The invention discloses the following purposes: the invention provides an air compression pressure-collecting system, aiming at solving the problems that electric energy is consumed for preparation by a physical means, specific natural kinetic energy is required to be collected or redundant kinetic energy of other machines is required to be collected when compressed air is prepared at present, the consumed resources are large for collection by a chemical means, and the return ratio is not high only for collecting the compressed air.

The invention is implemented by the following embodiments: an air compression pressure-collecting system comprises a gas collecting tank, a pipeline, a gas path and a gas generating device;

the gas generating devices are connected with each other through pipelines, the gas generating devices are all connected with the gas circuit, and the outlet end of the gas circuit is connected with the gas collecting tank.

Further, the number of the gas generating devices is three; the following labels are group A, group B, group C;

the gas generating device comprises a support frame, a first water tank, a second water tank, a running main body water pressure tank, a traction plate, a traction mechanism, a gas collecting tank, a liquid pressure piston, a first connecting ejector rod, a gas pressure piston, a second connecting ejector rod and a hanging padlock;

the first water tank and the second water tank are both arranged in the support frame, the first water tank is arranged below the second water tank, and the first water tank and the second water tank are fixedly connected through a support rod; the hanging padlock is arranged on the support frame and used for limiting the initial positions of the first water tank and the second water tank;

the traction plate is arranged below the operation main body water pressure tank fixed on the support frame, two sides of the operation main body water pressure tank are respectively provided with a gas collecting tank fixed on the support frame, a liquid pressure piston is arranged below the inside of the operation main body water pressure tank, the liquid pressure piston is connected with the traction plate through a first connecting ejector rod, a gas pressure piston is arranged below the inside of the gas collecting tank, and the gas pressure piston is connected with the traction plate through a second connecting ejector rod;

the traction plate is connected with the upper part of the first water tank through a traction mechanism, so that the traction plate and the first water tank move reversely. Furthermore, the traction mechanism comprises two bearing rods, four pulleys and four traction ropes;

the two bearing rods are symmetrically arranged on the side part above the support frame, two pulleys are arranged on each bearing rod, one end of each traction rope is connected with the upper part of the water tank, and the other end of each traction rope is connected with the traction plate.

Furthermore, each gas collecting tank top all is equipped with gas inlet, and every gas inlet all links to each other with the gas circuit entry end, be equipped with adjusting valve on the gas circuit.

Still further, the pipeline comprises a first water pipe, a second water pipe, a third water pipe, a fourth water pipe, a fifth water pipe, a sixth water pipe, a seventh water pipe, an eighth water pipe and a ninth water pipe;

the first water tank of the gas generating device in the group A is connected with the operation main body hydraulic pressure tank of the gas generating device in the group C through a ninth water pipe;

the first water tank of the gas generating device in the group A is connected with the second water tank of the gas generating device in the group B through a first water pipe; the second water tank of the gas generating device in the group A is connected with the first water tank of the gas generating device in the group C through a seventh water pipe; the second water tank of the gas generating device in the group A is connected with the operation main body hydraulic pressure tank of the gas generating device in the group C through an eighth water pipe;

the operation main body hydraulic pressure tank of the gas generating device in the group A is connected with the second water tank of the gas generating device in the group B through a second water pipe;

the operation main body hydraulic pressure tank of the gas generating device in the group A is connected with the first water tank of the gas generating device in the group B through a third water pipe; the first water tank of the gas generating device in the group B is connected with the second water tank of the gas generating device in the group C through a fourth water pipe; the operation main body hydraulic pressure tank of the gas generating device in the group B and the second water of the gas generating device in the group C are communicated through a fifth water pipe

Connecting the boxes;

the operation main body hydraulic pressure tank of the gas generating device in the group B is connected with the first water tank of the gas generating device in the group C through a sixth water pipe.

Further, the inlet end of the first water pipe water flow direction, the inlet end of the third water pipe water flow direction, the inlet end of the fourth water pipe water flow direction, the inlet end of the sixth water pipe water flow direction, the inlet end of the seventh water pipe water flow direction and the inlet end of the ninth water pipe water flow direction are all provided with water inlet valves.

Furthermore, the inlet end of the first water pipe in the water flow direction is connected with the second water tank of the gas generating device in the group B through a first pipe joint, and the outlet end of the first water pipe in the water flow direction is connected with the first water tank of the gas generating device in the group A through a second pipe joint;

and the first water pipe is fixedly arranged on the adjacent support frames, and the arrangement mode of the third water pipe, the arrangement mode of the fourth water pipe, the arrangement mode of the sixth water pipe, the arrangement mode of the seventh water pipe and the arrangement mode of the ninth water pipe are the same as the arrangement mode of the first water pipe.

Furthermore, the water inlet valve comprises a ball valve I, a ball valve II, a ball valve switch gear I, a ball valve switch gear II, a ball valve switch rack I and a ball valve switch rack II;

the ball valve switch gear I is fixedly connected to the first water tank or the second water tank where the pipe joint I is located, and the ball valve switch gear I is arranged on the first water pipe, the third water pipe, the fourth water pipe, the sixth water pipe, the seventh water pipe or the ninth water pipe which are sleeved outside the joint of the set pipe; the ball valve switch rack I is matched with the ball valve switch gear I;

the ball valve switch rack I is fixedly connected to a first water pipe, a third water pipe, a fourth water pipe, a sixth water pipe, a seventh water pipe or a ninth water pipe outside the pipe joint, the ball valve switch gear II is arranged on the pipe joint I, and the ball valve switch rack II and the ball valve switch gear II are matched with each other.

Still further, the volume of the first water tank, the volume of the second water tank and the volume of the hydraulic tank of the operation body are all equal. Further, the gas generating device further comprises a hanging padlock switch lead;

the hanging padlock switch lead is connected with the hanging lock.

Has the advantages that: the invention uses water gravity as original power, the initial motion of the system needs to move downwards with a certain height drop, the system can operate by doing work through the water gravity, and further compresses the air in the air collecting tank, so that the air in the air collecting tank is collected in the air collecting tank, and the system can continuously operate and generate a large amount of compressed air by arranging a plurality of groups of air generating devices, circularly operate and serve as power sources of each other. Need not use electric energy or chemical means to produce gas, practiced thrift the energy, possess the great meaning to energy-concerving and environment-protective, and the gas that produces can be applied to multiple field, and system simple structure, and the practicality is strong, builds simply in the place that needs use this system, and not only simple to operate, later stage overhaul is also convenient, and is efficient to collecting compressed air, and application scope is extensive.

When the gas is collected sufficiently, the device can be used for stopping the system by human intervention optionally. Or partial structure is improved by utilizing the principle, and a mechanism for supplementing water is arranged, so that the system is prevented from stopping running due to water leakage or water loss when the system runs.

Drawings

FIG. 1 is a schematic view 1 of the present invention;

FIG. 2 is a schematic view of the present invention 2;

FIG. 3 is a partial view of the present invention;

FIG. 4 is a wire frame diagram 1 of the present invention;

FIG. 5 is a wire frame diagram of the present invention 2;

FIG. 6 is an enlarged view of a portion of the present invention;

FIG. 7 is a partial schematic view 1 of embodiment 1 of the present invention;

FIG. 8 is a partially enlarged schematic view of embodiment 1 of the present invention;

fig. 9 is a partial schematic view 2 of embodiment 1 of the present invention.

Detailed Description

The first embodiment is as follows: an air compression pressure-collecting system comprises a gas collecting tank 1, a pipeline, a gas circuit and a gas generating device 2;

the gas generating devices 2 are connected with each other through pipelines, the gas generating devices 2 are all connected with gas circuits, and the outlet ends of the gas circuits are connected with the gas collecting tank 1.

The second embodiment is as follows: the number of the gas generating devices 2 is three;

the gas generating device 2 comprises a support frame 3, a first water tank 5, a second water tank 4, a running main body water pressure tank 6, a traction plate 8, a traction mechanism, a gas collecting tank 10, a liquid pressure piston 11, a first connecting ejector rod 12, a gas pressure piston 13, a second connecting ejector rod 14 and a hanging lock 26;

the first water tank 5 and the second water tank 4 are both arranged in the support frame 3, the first water tank 5 is arranged below the second water tank 4, and the first water tank 5 and the second water tank 4 are fixedly connected through a support rod; a hanging padlock 26 provided on the support frame 3 for restricting an initial position of the first and second water tanks 5 and 4; the traction plate 8 is arranged below the operation main body water pressure tank 6 fixed on the support frame 3, two sides of the operation main body water pressure tank 6 are respectively provided with a gas collecting tank 10 fixed on the support frame 3, a liquid pressure piston 11 is arranged below the inside of the operation main body water pressure tank 6, the liquid pressure piston 11 is connected with the traction plate 8 through a first connecting ejector rod 12, a gas pressure piston 13 is arranged below the inside of the gas collecting tank 10, and the gas pressure piston 13 is connected with the traction plate 8 through a second connecting ejector rod;

the traction plate 8 is connected with the upper part of the first water tank 5 through a traction mechanism, so that the traction plate 8 and the first water tank 5 move reversely.

And a gas needle type valve is arranged on a gas outlet of the gas collecting tank 10 for gas outlet, and a negative pressure gas inlet valve is arranged on the tank wall of the gas collecting tank 10 for gas inlet.

The water outflow speed of the first water tank 5 and the second water tank 4 is faster than that of the main body hydraulic tank 6, and the water outflow emptying of the first water tank 5 and the water outflow emptying of the second water tank 4 are 20-30 s faster than that of the main body hydraulic tank 6.

Other embodiments are the same as the first embodiment.

The third concrete implementation mode: the traction mechanism comprises two bearing rods 9, four pulleys 15 and four traction ropes 7; two bearing rods 9 are symmetrically arranged on the side part above the support frame 3, two pulleys 15 are arranged on each bearing rod 9, one end of each traction rope 7 is connected with the upper part of the water tank 5, and the other end of each traction rope 7 is connected with the traction plate 5.

Other embodiments are the same as the second embodiment.

The fourth concrete implementation mode: each gas collection tank 10 top all is equipped with gas inlet, and every gas inlet all links to each other with the gas circuit entry end, be equipped with adjusting valve 16 on the gas circuit.

In this embodiment, a safety valve 29 is disposed on the gas collection tank 1 connected to the gas path, and a gas outlet pipe is connected to the gas outlet of the gas collection tank 1 and provided with a gas release valve 30.

Other embodiments are the same as the second embodiment.

The fifth concrete implementation mode: the pipelines comprise a first water pipe 17, a second water pipe 18, a third water pipe 19, a fourth water pipe 20, a fifth water pipe 21, a sixth water pipe 22, a seventh water pipe 23, an eighth water pipe 24 and a ninth water pipe 25; the first water tank 5 of the gas generating device 2 in the group A is connected with the operation main body hydraulic tank 6 of the gas generating device 2 in the group C through a ninth water pipe 25;

the first water tank 5 of the gas generating device 2 in the group A is connected with the second water tank 4 of the gas generating device 2 in the group B through a first water pipe 17; the second water tank 4 of the gas generating device 2 in the group A is connected with the first water tank 5 of the gas generating device 2 in the group C through a seventh water pipe 23; the second water tank 4 of the gas generator 2 of group A is connected with the gas generator 2 of group C through the eighth water pipe 24

The operation main body hydraulic pressure tank 6 is connected; the operation main body hydraulic pressure tank 6 of the gas generating device 2 in the group A is connected with the second water tank 4 of the gas generating device 2 in the group B through a second water pipe 18; the operation main body hydraulic pressure tank 6 of the gas generating device 2 in the group A is connected with the first water tank 5 of the gas generating device 2 in the group B through a third water pipe 19; the first water tank 5 of the gas generating device 2 in the group B is connected with the second water tank 4 of the gas generating device 2 in the group C through a fourth water pipe 20; the operation main body hydraulic pressure tank 6 of the gas generating device 2 in the group B is connected with the second water tank 4 of the gas generating device 2 in the group C through a fifth water pipe 21; the operation body hydraulic pressure tank 6 of the gas generator 2 of group B is connected to the first water tank 5 of the gas generator 2 of group C through the sixth water pipe 22.

Other embodiments are the same as the second embodiment.

The sixth specific implementation mode: and the inlet end of the first water pipe 17 in the water flow direction, the inlet end of the third water pipe 19 in the water flow direction, the inlet end of the fourth water pipe 20 in the water flow direction, the inlet end of the sixth water pipe 22 in the water flow direction, the inlet end of the seventh water pipe 23 in the water flow direction and the inlet end of the ninth water pipe 25 in the water flow direction are all provided with a water inlet valve 28.

The other embodiments are the same as the fifth embodiment.

The seventh embodiment: the inlet end of the first water pipe 17 in the water flow direction is connected with the second water tank 4 of the gas generating device 2 in the group B through a first pipe joint, and the outlet end of the first water pipe 17 in the water flow direction is connected with the first water tank 5 of the gas generating device 2 in the group A through a second pipe joint;

and the first water pipe 17 is fixedly arranged on the adjacent support frame 3, and the arrangement mode of the third water pipe 19, the arrangement mode of the fourth water pipe 20, the arrangement mode of the sixth water pipe 22, the arrangement mode of the seventh water pipe 23 and the arrangement mode of the ninth water pipe 25 are the same as the arrangement mode of the first water pipe 17.

The other embodiments are the same as the sixth embodiment.

The specific implementation mode is eight: the water inlet valve 28 comprises a first ball valve, a second ball valve, a first ball valve switch gear, a second ball valve switch gear, a first ball valve switch rack and a second ball valve switch rack;

the ball valve switch rack I is fixedly connected to the first water tank 5 or the second water tank 4 where the pipe joint I is located, and the ball valve switch gear I is arranged on the first water pipe 17, the third water pipe 19, the fourth water pipe 20, the sixth water pipe 22, the seventh water pipe 23 or the ninth water pipe 25 which are sleeved with the pipe and arranged outside the joint; the ball valve switch rack I is matched with the ball valve switch gear I; the first ball valve switch gear is connected with the first ball valve, and the first ball valve is arranged on the first water pipe 17, the third water pipe 19, the fourth water pipe 20, the sixth water pipe 22, the seventh water pipe 23 or the ninth water pipe 25;

the ball valve switch rack I is fixedly connected to a first water pipe 17, a third water pipe 19, a fourth water pipe 20, a sixth water pipe 22, a seventh water pipe 23 or a ninth water pipe 25 outside the pipe joint, the ball valve switch gear II is arranged on the pipe joint I, and the ball valve switch rack II and the ball valve switch gear II are matched with each other; the ball valve switch gear II is connected with the ball valve II, and the ball valve I is arranged on the pipe connector I;

in the present embodiment: take the water inlet valve 28 at the first water pipe 17 as an example;

the first water pipe 17 is fixed on the support frame 3 of the gas generating device 2 in the group A and the support frame 3 of the gas generating device 2 in the group B, and a pipe joint I is arranged below the water outlet end of the second water tank 4 of the gas generating device 2 in the group B; a pipe joint II is arranged above the inlet end of the first water tank 4 of the gas generating device in the group A; the inlet end of the first water pipe 17 is sleeved outside the first pipe joint, and the outlet end of the first water pipe 17 is arranged inside the second pipe joint; a ball valve switch rack I is fixed at a second water tank 4 of the gas generating device 2 of the pipe joint I or the group B; the ball valve switch gear I is arranged at the outlet end of the first water pipe 17; the ball valve I is arranged at the outlet end of the first water pipe 17 and is connected with the ball valve switch gear I; the ball valve switch rack I is matched with the ball valve switch gear I; a ball valve switch rack II is fixed at the outlet end of the first water pipe 17, and the ball valve switch rack II is arranged at the outlet end of the first water pipe 17; the ball valve switch rack II and the ball valve switch gear II are matched with each other; the ball valve II is arranged on the pipe joint I and is connected with the ball valve switch gear II.

In the operation process, the ball valve I is opened before the ball valve II by setting the ball valve switch gear I, the ball valve switch gear II, the ball valve switch rack I and the ball valve switch rack II to different parameters

The other embodiments are the same as the seventh embodiment.

The specific implementation method nine: the volume of the first water tank 5, the volume of the second water tank 4, and the volume of the operation body hydraulic tank 6 are all equal.

Other embodiments are the same as the second embodiment.

The detailed implementation mode is ten: the gas generating device 2 further comprises a suspension lock switch lead 27; the padlock switch lead 27 is connected to the padlock 26.

In the present embodiment, the suspension lock 26 of the gas generator 2 of group a is connected to the pulled end of the suspension lock switch lead 27 of the gas generator 2 of group a,

the suspension lock 26 of the gas generating device 2 in the group B is connected with the pulled end of the suspension lock switch lead 27 of the gas generating device 2 in the group B, and the pulling end of the suspension lock switch lead 27 of the gas generating device 2 in the group B is connected with the first water tank 5 or the second water tank 4 of the gas generating device 2 in the group A;

the suspension lock 26 of the gas generator 2 in group C is connected to the pulled end of the suspension lock switch lead 27 of the gas generator 2 in group C, and the pulled end of the suspension lock switch lead 27 of the gas generator 2 in group C is connected to the first water tank 5 or the second water tank 4 of the gas generator 2 in group B.

In this embodiment, the suspension lock is used to lock the first tank to restrict the first tank from falling down, and is opened by the lead wire disposed at the uppermost position.

Other embodiments are the same as the embodiments

The working principle is as follows: the system comprises three gas generating devices, and for the sake of clarity of description of the present principles, the following description is made by a first gas generating device, a second gas generating device, and a third gas generating device;

firstly, the operation conditions of the system need to be prepared, and the volumes of a main body water pressure tank in a first gas generating device, a first water tank in the first gas generating device, a second water tank in the first gas generating device, a main body water pressure tank in a second gas generating device, a first water tank in the second gas generating device, a second water tank in the second gas generating device, a main body water pressure tank in a third gas generating device, a first water tank in the third gas generating device and a second water tank in the third gas generating device in the system are all equal.

The group A gas generating devices are used as a starting group of the whole system, the main body water pressure tank, the first water tank and the second water tank of the group A gas generating devices are filled with water, the main body water pressure tank and the first water tank of the group B gas generating devices are filled with water, the first water tank and the second water tank of each group of gas generating devices are stopped at the highest point of each group of gas generating devices, and the top end of each group of gas generating devices is positioned at the highest point through a suspension locking position.

The hanging padlock of the A group of gas generating devices is pulled open manually. After the suspension lock is opened, a first water tank of the group A gas generating device and a second water tank of the group A gas generating device synchronously fall, a traction rope of the group A gas generating device is pulled, the traction rope of the group A gas generating device is pulled to move and then drives a traction plate of the group A gas generating device to lift, after the traction plate of the group A gas generating device lifts, on one hand, the traction plate of the group A gas generating device drives a second connecting ejector rod of the group A gas generating device to move upwards, the second connecting ejector rod of the group A gas generating device pushes a gas pressure piston of the group A gas generating device to compress air in a gas collecting tank of the group A gas generating device, and the air in the gas collecting tank of the group A gas generating device flows through a gas circuit and enters a gas collecting tank to be stored; on the other hand, the traction plate of the group A gas generating device drives the connecting ejector rod I of the group A gas generating device to move upwards, the connecting ejector rod I of the group A gas generating device pushes the liquid pressure piston of the group A gas generating device to push the water in the operation main body water pressure tank of the group A gas generating device, and the water in the operation main body water pressure tank of the group A gas generating device is upwards discharged under pressure and flows into the second water tank of the group B gas generating device through the second water pipe.

The first water tank of the group A gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, water in the second water tank of the group A gas generating device flows into the first water tank of the group C gas generating device through the seventh water pipe, and water in the first water tank of the group A gas generating device flows into the main body water pressure tank of the group C gas generating device through the ninth water pipe.

The first water tank of the group A gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, after the water in the second water tank of the group A gas generating device and the water in the first water tank of the group A gas generating device are discharged, because the sum of the two gravities of the drawing plate, the liquid pressure piston, the first connecting ejector rod, the gas pressure piston and the second connecting ejector rod of the group A gas generating device is equal to the sum of the gravities of the first water tank of the group A gas generating device and the second water tank of the group A gas generating device, when the main body water pressure tank in the group A gas generating device discharges water, because water goes upwards, part of the water stays in a water pipe (the second water pipe), the water is pressed downwards due to the gravity to provide power for the drawing plate to go downwards, the drawing plate of the group A gas generating device moves downwards, the drawing rope of the group A gas generating device is pulled, the drawing rope of the group A gas generating device drives the first water tank of the group A gas generating device and the second water tank of the, the suspension locks of the group A gas generating devices are locked again.

When a first water tank of the group A gas generating device and a second water tank of the group A gas generating device synchronously fall to the bottom, a hanging padlock arranged on the group B gas generating device is pulled to be opened, a first water tank in the group B gas generating device and a second water tank in the group B gas generating device synchronously fall, a traction rope of the group B gas generating device is pulled, the traction rope of the group B gas generating device is pulled to move after being pulled to drive a traction plate of the group B gas generating device to lift, after the traction plate of the group B gas generating device lifts, on one hand, the traction plate of the group B gas generating device drives a connecting ejector rod of the group B gas generating device to move upwards, a connecting ejector rod II of the group B gas generating device pushes a gas pressure piston of the group B gas generating device to compress air in a gas collecting tank of the group B gas generating device, and the air in the gas collecting tank of the group B gas generating device flows through a gas circuit, entering a gas collecting tank of the group B gas generating device for storage; on the other hand, the traction plate of the group B gas generating device drives the connecting ejector rod of the group B gas generating device to move upwards, the connecting ejector rod of the group B gas generating device pushes the liquid pressure piston of the group B gas generating device, the liquid pressure piston of the group B gas generating device pushes the water in the liquid pressure piston operation main body water pressure tank of the group B gas generating device, and the water in the liquid pressure piston operation main body water pressure tank of the group B gas generating device is upwards discharged under pressure and flows into the second water tank of the group C gas generating device through the second water pipe.

The first water tank of the group B gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, water in the second water tank of the group B gas generating device flows into the first water tank of the group A gas generating device through the first water pipe, and water in the first water tank of the group B gas generating device flows into the main body water pressure tank of the group A gas generating device through the third water pipe.

The first water tank of the B group gas generating device and the second water tank of the B group gas generating device synchronously fall to the bottom, after the water in the second water tank of the B group gas generating device and the water in the first water tank of the B group gas generating device are discharged, because the sum of the two gravities of the traction plate, the liquid pressure piston, the first connecting ejector rod, the gas pressure piston and the second connecting ejector rod of the B group gas generating device is equal to the sum of the gravities of the first water tank of the B group gas generating device and the second water tank of the B group gas generating device, when the main body water pressure tank in the B group gas generating device discharges water, because water goes upwards, part of the water stays in the water pipe, the water is pressed downwards due to the gravity to provide power for the downward movement of the traction plate, the traction plate of the B group gas generating device moves downwards to pull the traction rope of the B group gas generating device, the traction rope of the B group gas generating device drives the first water tank of the B group gas generating device and the second water tank of the, the suspension locks of the B group of gas generating devices are locked again.

When a first water tank of a group B gas generating device and a second water tank of a group B gas generating device synchronously fall to the bottom, a hanging padlock arranged on a group C gas generating device is pulled to be opened, a first water tank in the group C gas generating device and a second water tank in the group C gas generating device synchronously fall, a traction rope of the group C gas generating device is pulled, the traction rope of the group C gas generating device is pulled to move after being pulled to drive a traction plate of the group C gas generating device to lift, after the traction plate of the group C gas generating device lifts, on one hand, the traction plate of the group C gas generating device drives a second connecting ejector rod of the group C gas generating device to move upwards, the second connecting ejector rod of the group C gas generating device pushes a gas pressure piston of the group C gas generating device to compress air in a gas collecting tank of the group C gas generating device, and the air in the gas collecting tank of the group C gas generating device flows through a gas circuit, entering a gas collecting tank of the group C gas generating device for storage; on the other hand, the traction plate of the group C gas generating device drives the first connecting ejector rod of the group C gas generating device to move upwards, the first connecting ejector rod of the group C gas generating device pushes the liquid pressure piston of the group C gas generating device, the liquid pressure piston of the group C gas generating device pushes the water in the main liquid pressure tank of the main liquid pressure piston operation body of the group C gas generating device, and the water in the main liquid pressure tank of the main liquid pressure piston operation body of the group C gas generating device is upwards discharged under pressure and flows into the second water tank of the group A gas generating device through the eighth water pipe.

The first water tank of the group C gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, water in the second water tank of the group C gas generating device flows into the first water tank of the group B gas generating device through a fourth water pipe, and water in the first water tank of the group C gas generating device flows into a main body water pressure tank of the group B gas generating device through a sixth water pipe.

The first water tank of the C group gas generating device and the second water tank of the C group gas generating device synchronously fall to the bottom, after the water in the second water tank of the C group gas generating device and the water in the first water tank of the C group gas generating device are discharged, the sum of the gravity of the C group gas generating device and the gravity of the second water tank of the C group gas generating device is equal to the sum of the gravity of the first water tank of the C group gas generating device and the gravity of the second water tank of the C group gas generating device because the first ejector rod, the gas pressure piston and the second ejector rod of the C group gas generating device are connected, when a main body water pressure tank in the C group gas generating device discharges water, because the water goes upwards, part of the water stays in a water pipe (a second water pipe), the water is pressed downwards due to the gravity to provide power for the descending of the traction plate of the C group gas generating device, the traction rope of the C group gas generating device is pulled, and the traction rope of the C group gas generating device drives the first water tank of the C group gas generating And the suspension lock of the C group gas generating device is locked again.

At this point, each gas generator is at its initial height and continues to operate according to the principles described above until it stops, optionally with human intervention to stop the system when sufficient gas is collected. Or partial structure is improved by utilizing the principle, and a mechanism for supplementing water is arranged, so that the system is prevented from stopping running due to water leakage or water loss when the system runs.

Example 1:

firstly, the operation conditions of the system need to be prepared, and the volume of a main water pressure tank in a first gas generating device, a first water tank in the first gas generating device, a second water tank in the first gas generating device, a main water pressure tank in a second gas generating device, a first water tank in the second gas generating device, a second water tank in the second gas generating device, a main water pressure tank in a third gas generating device, a first water tank in the third gas generating device and a second water tank in the third gas generating device in the system are all 10 cubic meters. The inner diameters of the first water pipe, the second water pipe, the third water pipe, the fourth water pipe, the fifth water pipe, the sixth water pipe, the seventh water pipe, the eighth water pipe and the ninth water pipe are all 10cm, the height of the support frame is 1560cm, the top surface of the second water tank is 1520cm away from the ground, the height of the second water tank is 100cm, the length and the width of the second water tank are 320cm, the distance between the first water tank and the second water tank is 350cm, the specifications of the first water tank and the second water tank are the same, the main water pressure tank and the gas collecting tank are cylindrical cylinders with the height of 320cm, the diameter of the main water pressure tank is 220cm, the diameter of the gas collecting pipe is 130cm, the main water pressure tank and the gas collecting pipe are located at the same height and are both 300cm away from the first water tank, the height of the liquid pressure piston and the height of the gas pressure piston are both 20cm, and the lengths of.

The group A gas generating devices are used as a starting group of the whole system, the main body water pressure tank, the first water tank and the second water tank of the group A gas generating devices are filled with water, the main body water pressure tank and the first water tank of the group B gas generating devices are filled with water, the first water tank and the second water tank of each group of gas generating devices are stopped at the highest point of each group of gas generating devices, and the top end of each group of gas generating devices is positioned at the highest point through a suspension locking position.

The hanging padlock of the A group of gas generating devices is pulled open manually. After the suspension lock is opened, a first water tank of the group A gas generating device and a second water tank of the group A gas generating device synchronously fall, a traction rope of the group A gas generating device is pulled, the traction rope of the group A gas generating device is pulled to move and then drives a traction plate of the group A gas generating device to lift, after the traction plate of the group A gas generating device lifts, on one hand, the traction plate of the group A gas generating device drives a second connecting ejector rod of the group A gas generating device to move upwards, the second connecting ejector rod of the group A gas generating device pushes a gas pressure piston of the group A gas generating device to compress air in a gas collecting tank of the group A gas generating device, and the air in the gas collecting tank of the group A gas generating device flows through a gas circuit and enters a gas collecting tank to be stored; on the other hand, the traction plate of the group A gas generating device drives the connecting ejector rod I of the group A gas generating device to move upwards, the connecting ejector rod I of the group A gas generating device pushes the liquid pressure piston of the group A gas generating device to push the water in the operation main body water pressure tank of the group A gas generating device, and the water in the operation main body water pressure tank of the group A gas generating device is upwards discharged under pressure and flows into the second water tank of the group B gas generating device through the second water pipe.

In the process: the first water tank of the group A gas generating device and the second water tank of the group A gas generating device fall synchronously by utilizing the gravity (196000N pulling force) brought by 20 cubic meters of water, the second water pipe is 10cm thick, (the lift is about 8.5 meters by 7.88 kilograms per meter), the lifting height is about 67 kilograms, the consumption generated by the friction of a pressure plug is consumed, the weight of the lifting height is not more than 500 kilograms, the pulling force (93100N pulling force) brought by 9.5 tons of water is remained, the volume of the gas collecting tank is 3.95 cubic meters, the volume of the two gas collecting tanks is 7.9 cubic meters in total, the gravity brought by 20 tons of water offsets the gravity brought by 10 tons of water of the operation main body water pressure tank, the remaining gravity drives the traction plate to lift, the water of the operation main body water pressure tank flows into the second water tank of the group B gas generating device, and the gas generated by the gas collecting tank enters the gas collecting tank.

When the first water tank of the group A gas generating device and the second water tank of the group A gas generating device run to the lowest point, the first water tank of the group A gas generating device is higher than the main body water pressure tank of the group C gas generating device, water in the first water tank of the group A gas generating device enters the main body water pressure tank of the group C gas generating device under the action of height drop, water in the second water tank of the group A gas generating device enters the first water tank of the group C gas generating device under the action of height drop, the group A gas generating device, the group B gas generating device and the group C gas generating device are arranged at equal intervals in the circumferential direction, the distance from the water tanks to the central point is 350cm, the group A gas generating device, the group B gas generating device and the group C gas generating device are arranged in an equilateral triangle (the triangle arrangement ensures that all water conveying pipelines are equal in length and the conveying time is equal), and after the running main body water pressure tank of the group A, the water in the first water tank and the second water tank of the group A gas generating device is gradually emptied, the water with the residual lift of 9 meters in the second water pipe can generate gravity, the weight is about 80 kilograms, the traction plate indirectly generates thrust, further, the traction plate is influenced by the gravity and runs downwards, the first water tank and the second water tank of the group A gas generating device are sent back to the highest position through the traction rope, then the suspension switch at the top of the group A gas generating device is triggered,

the first water tank of the group A gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, water in the second water tank of the group A gas generating device flows into the first water tank of the group C gas generating device through the seventh water pipe, and water in the first water tank of the group A gas generating device flows into the main body water pressure tank of the group C gas generating device through the ninth water pipe.

The first water tank of the group A gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, after the water in the second water tank of the group A gas generating device and the water in the first water tank of the group A gas generating device are discharged, the sum of the gravity of the group A gas generating device and the gravity of the second water tank of the group A gas generating device is equal to the sum of the gravity of the first water tank of the group A gas generating device and the gravity of the second water tank of the group A gas generating device because the sum of the gravity of the group A gas generating device and the gravity of the second water tank of the group A gas generating device, when the main body water pressure tank in the group A gas generating device discharges water, because the water goes upwards, part of the water stays in the water pipe (the second water pipe), the water is pressed downwards due to the gravity to provide power for the descending of the traction plate, the traction plate of the group A gas generating device moves downwards, the traction rope of the group A gas generating device is pulled, and the traction rope of the group A gas generating device And the suspension lock of the group A gas generating device is locked again.

When a first water tank of the group A gas generating device and a second water tank of the group A gas generating device synchronously fall to the bottom, a hanging padlock arranged on the group B gas generating device is pulled to be opened, a first water tank in the group B gas generating device and a second water tank in the group B gas generating device synchronously fall, a traction rope of the group B gas generating device is pulled, the traction rope of the group B gas generating device is pulled to move after being pulled to drive a traction plate of the group B gas generating device to lift, after the traction plate of the group B gas generating device lifts, on one hand, the traction plate of the group B gas generating device drives a connecting ejector rod of the group B gas generating device to move upwards, a connecting ejector rod II of the group B gas generating device pushes a gas pressure piston of the group B gas generating device to compress air in a gas collecting tank of the group B gas generating device, and the air in the gas collecting tank of the group B gas generating device flows through a gas circuit, entering a gas collecting tank of the group B gas generating device for storage; on the other hand, the traction plate of the group B gas generating device drives the connecting ejector rod of the group B gas generating device to move upwards, the connecting ejector rod of the group B gas generating device pushes the liquid pressure piston of the group B gas generating device, the liquid pressure piston of the group B gas generating device pushes the water in the liquid pressure piston operation main body water pressure tank of the group B gas generating device, and the water in the liquid pressure piston operation main body water pressure tank of the group B gas generating device is upwards discharged under pressure and flows into the second water tank of the group C gas generating device through the second water pipe.

The first water tank of the group B gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, water in the second water tank of the group B gas generating device flows into the first water tank of the group A gas generating device through the first water pipe, and water in the first water tank of the group B gas generating device flows into the main body water pressure tank of the group A gas generating device through the third water pipe.

The first water tank of the B group gas generating device and the second water tank of the B group gas generating device synchronously fall to the bottom, after the water in the second water tank of the B group gas generating device and the water in the first water tank of the B group gas generating device are discharged, because the sum of the two gravities of the drawing plate, the liquid pressure piston, the first connecting ejector rod, the gas pressure piston and the connecting ejector rod of the B group gas generating device is equal to the sum of the gravities of the first water tank of the B group gas generating device and the second water tank of the B group gas generating device, when the main body water pressure tank in the B group gas generating device discharges water, because water goes upwards, part of the water stays in the water pipe (the second water pipe), the water is pressed downwards due to the gravity to provide power for the drawing plate to go downwards, the drawing plate of the B group gas generating device moves downwards, the drawing rope of the B group gas generating device is pulled, the drawing rope of the B group gas generating device drives the first water tank of the B group gas generating device and the second water tank of the B, the suspension locks of the B group of gas generating devices are locked again.

When a first water tank of a group B gas generating device and a second water tank of a group B gas generating device synchronously fall to the bottom, a hanging padlock arranged on a group C gas generating device is pulled to be opened, a first water tank in the group C gas generating device and a second water tank in the group C gas generating device synchronously fall, a traction rope of the group C gas generating device is pulled, the traction rope of the group C gas generating device is pulled to move after being pulled to drive a traction plate of the group C gas generating device to lift, after the traction plate of the group C gas generating device lifts, on one hand, the traction plate of the group C gas generating device drives a second connecting ejector rod of the group C gas generating device to move upwards, the second connecting ejector rod of the group C gas generating device pushes a gas pressure piston of the group C gas generating device to compress air in a gas collecting tank of the group C gas generating device, and the air in the gas collecting tank of the group C gas generating device flows through a gas circuit, entering a gas collecting tank of the group C gas generating device for storage; on the other hand, the traction plate of the group C gas generating device drives the first connecting ejector rod of the group C gas generating device to move upwards, the first connecting ejector rod of the group C gas generating device pushes the liquid pressure piston of the group C gas generating device, the liquid pressure piston of the group C gas generating device pushes the water in the main liquid pressure tank of the main liquid pressure piston operation body of the group C gas generating device, and the water in the main liquid pressure tank of the main liquid pressure piston operation body of the group C gas generating device is upwards discharged under pressure and flows into the second water tank of the group A gas generating device through the eighth water pipe.

The first water tank of the group C gas generating device and the second water tank of the group A gas generating device synchronously fall to the bottom, water in the second water tank of the group C gas generating device flows into the first water tank of the group B gas generating device through a fourth water pipe, and water in the first water tank of the group C gas generating device flows into a main body water pressure tank of the group B gas generating device through a sixth water pipe.

The first water tank of the C group gas generating device and the second water tank of the C group gas generating device synchronously fall to the bottom, after the water in the second water tank of the C group gas generating device and the water in the first water tank of the C group gas generating device are discharged, the sum of the gravity of the C group gas generating device and the gravity of the second water tank of the C group gas generating device is equal to the sum of the gravity of the first water tank of the C group gas generating device and the gravity of the second water tank of the C group gas generating device because the first ejector rod, the gas pressure piston and the second ejector rod of the C group gas generating device are connected, when a main body water pressure tank in the C group gas generating device discharges water, because the water goes upwards, part of the water stays in a water pipe (a second water pipe), the water is pressed downwards due to the gravity to provide power for the descending of the traction plate of the C group gas generating device, the traction rope of the C group gas generating device is pulled, and the traction rope of the C group gas generating device drives the first water tank of the C group gas generating And the suspension lock of the C group gas generating device is locked again.

At this point, each gas generator is at its initial height and continues to operate according to the principles described above until it stops, optionally with human intervention to stop the system when sufficient gas is collected. Or partial structure is improved by utilizing the principle, and a mechanism for supplementing water is arranged, so that the system is prevented from stopping running due to water leakage or water loss when the system runs.

Claims (10)

1. An air compression pressure-collecting system, characterized in that: the device comprises a gas collecting tank (1), a pipeline, a gas path and a gas generating device (2);

the gas generating devices (2) are connected with each other through pipelines, the gas generating devices (2) are all connected with the gas circuit, and the outlet end of the gas circuit is connected with the gas collecting tank (1).

2. An air compression and pressure buildup system as in claim 1 wherein: the number of the gas generating devices (2) is three; the lower part is marked as A group, B group and C group;

the gas generating device (2) comprises a support frame (3), a first water tank (5), a second water tank (4), a running main body hydraulic tank (6), a traction plate (8), a traction mechanism, a gas collecting tank (10), a liquid pressure piston (11), a first connecting ejector rod (12), a gas pressure piston (13), a second connecting ejector rod (14) and a hanging padlock (26);

the first water tank (5) and the second water tank (4) are both arranged in the support frame (3), the first water tank (5) is arranged below the second water tank (4), and the first water tank (5) is fixedly connected with the second water tank (4) through a support rod; the hanging padlock (26) is arranged on the support frame (3) and used for limiting the initial positions of the first water tank (5) and the second water tank (4);

the drawing plate (8) is arranged below an operation main body water pressure tank (6) fixed on the support frame (3), two sides of the operation main body water pressure tank (6) are respectively provided with a gas collecting tank (10) fixed on the support frame (3), a liquid pressure piston (11) is arranged below the inside of the operation main body water pressure tank (6), the liquid pressure piston (11) is connected with the drawing plate (8) through a connecting ejector rod I (12), a gas pressure piston (13) is arranged below the inside of the gas collecting tank (10), and the gas pressure piston (13) is connected with the drawing plate (8) through a connecting ejector rod II;

the traction plate (8) is connected with the upper part of the first water tank (5) through a traction mechanism, so that the traction plate (8) and the first water tank (5) move reversely.

3. An air compression and pressure buildup system as claimed in claim 2, wherein: the traction mechanism comprises two bearing rods (9), four pulleys (15) and four traction ropes (7);

two bearing rods (9) are symmetrically arranged on the side part above the support frame (3), two pulleys (15) are arranged on each bearing rod (9), each pulley is connected with one end of the traction rope (7) and the upper part of the water tank (5), and the other end of the traction rope (7) is connected with the traction plate (5).

4. An air compression and pressure buildup system as claimed in claim 2, wherein: and a gas inlet is formed in the top end of each gas collecting tank (10), each gas inlet is connected with a gas path inlet end, and a regulating valve (16) is arranged on each gas path.

5. An air compression and pressure buildup system as claimed in claim 2, wherein: the pipelines comprise a first water pipe (17), a second water pipe (18), a third water pipe (19), a fourth water pipe (20), a fifth water pipe (21), a sixth water pipe (22), a seventh water pipe (23), an eighth water pipe (24) and a ninth water pipe (25);

the first water tank (5) of the gas generating device (2) of the group A is connected with the operation main body hydraulic tank (6) of the gas generating device (2) of the group C through a ninth water pipe (25);

the first water tank (5) of the gas generating device (2) of the group A is connected with the second water tank (4) of the gas generating device (2) of the group B through a first water pipe (17);

the second water tank (4) of the gas generating device (2) of the group A is connected with the first water tank (5) of the gas generating device (2) of the group C through a seventh water pipe (23);

the second water tank (4) of the gas generating device (2) of the group A is connected with the operation main body hydraulic pressure tank (6) of the gas generating device (2) of the group C through an eighth water pipe (24);

the operation main body hydraulic pressure tank (6) of the gas generating device (2) of the group A is connected with the second water tank (4) of the gas generating device (2) of the group B through a second water pipe (18);

the operation main body hydraulic pressure tank (6) of the gas generating device (2) of the group A is connected with the first water tank (5) of the gas generating device (2) of the group B through a third water pipe (19);

the first water tank (5) of the gas generating device (2) in the group B is connected with the second water tank (4) of the gas generating device (2) in the group C through a fourth water pipe (20);

the operation main body hydraulic pressure tank (6) of the gas generating device (2) of the group B is connected with the second water tank (4) of the gas generating device (2) of the group C through a fifth water pipe (21);

the operation main body hydraulic pressure tank (6) of the gas generating device (2) of the group B is connected with the first water tank (5) of the gas generating device (2) of the group C through a sixth water pipe (22).

6. An air compression and pressure buildup system as claimed in claim 5, wherein: the inlet end of the water flow direction of the first water pipe (17), the inlet end of the water flow direction of the third water pipe (19), the inlet end of the water flow direction of the fourth water pipe (20), the inlet end of the water flow direction of the sixth water pipe (22), the inlet end of the water flow direction of the seventh water pipe (23) and the inlet end of the water flow direction of the ninth water pipe (25) are respectively provided with a water inlet valve (28).

7. An air compression and pressure buildup system as claimed in claim 6, wherein: the inlet end of the first water pipe (17) in the water flow direction is connected with the second water tank (4) of the gas generating device (2) in the group B through a first pipe joint, and the outlet end of the first water pipe (17) in the water flow direction is connected with the first water tank (5) of the gas generating device (2) in the group A through a second pipe joint;

and the first water pipe (17) is fixedly arranged on the adjacent support frame (3), and the arrangement mode of the third water pipe (19), the arrangement mode of the fourth water pipe (20), the arrangement mode of the sixth water pipe (22), the arrangement mode of the seventh water pipe (23) and the arrangement mode of the ninth water pipe (25) are the same as the arrangement mode of the first water pipe (17).

8. An air compression and pressure buildup system as claimed in claim 7, wherein: the water inlet valve (28) comprises a ball valve I, a ball valve II, a ball valve switch gear I, a ball valve switch gear II, a ball valve switch rack I and a ball valve switch rack II;

the ball valve switch rack I is fixedly connected to the first water tank (5) or the second water tank (4) where the pipe joint I is located, and the ball valve switch gear I is arranged on a first water pipe (17), a third water pipe (19), a fourth water pipe (20), a sixth water pipe (22), a seventh water pipe (23) or a ninth water pipe (25) which are sleeved outside the joint of the setting pipe; the ball valve switch rack I is matched with the ball valve switch gear I;

the ball valve switch rack I is fixedly connected to a first water pipe (17), a third water pipe (19), a fourth water pipe (20), a sixth water pipe (22), a seventh water pipe (23) or a ninth water pipe (25) outside the pipe joint, the ball valve switch gear II is arranged on the pipe joint I, and the ball valve switch rack II and the ball valve switch gear II are matched with each other.

9. An air compression and pressure buildup system as claimed in claim 2, wherein: the volume of the first water tank (5), the volume of the second water tank (4) and the volume of the operation main body hydraulic pressure tank (6) are equal.

10. An air compression and pressure buildup system as claimed in claim 2, wherein: the gas generating device (2) further comprises a hanging padlock switch lead (27);

the hanging padlock switch lead (27) is connected with the hanging lock (26).

The suspension lock (26) of the gas generating device (2) of the group A is connected with the pulled end of the switch lead (27) of the suspension lock of the gas generating device (2) of the group A,

the suspension lock (26) of the gas generating device (2) in the group B is connected with the pulled end of the suspension lock switch lead (27) of the gas generating device (2) in the group B, and the pull end of the suspension lock switch lead (27) of the gas generating device (2) in the group B is connected with the first water tank (5) or the second water tank (4) of the gas generating device (2) in the group A;

the suspension lock (26) of the gas generating device (2) in the group C is connected with the pulled end of the suspension lock switch lead (27) of the gas generating device (2) in the group C, and the pull end of the suspension lock switch lead (27) of the gas generating device (2) in the group C is connected with the first water tank (5) or the second water tank (4) of the gas generating device (2) in the group B.

Images