CN221236831U

CN221236831U - Pressure-driven hydraulic-pushing power generation system

Info

Publication number: CN221236831U
Application number: CN202323518453.7U
Authority: CN
Inventors: 陈敏
Original assignee: Individual
Current assignee: Individual
Priority date: 2023-12-21
Filing date: 2023-12-21
Publication date: 2024-06-28
Anticipated expiration: 2033-12-21

Abstract

The application discloses a pressure-driven hydraulic pushing power generation system, which belongs to the field of power generation equipment, and the technical scheme is characterized by comprising a vibration-absorbing and force-applying device, a flow pipeline, an impeller power generation device and flowing liquid, wherein the vibration-absorbing and force-applying device is arranged on a motor vehicle and is used for absorbing vibration of the motor vehicle and transmitting potential energy generated during vibration absorption to the impeller power generation device through the flowing liquid by the flow pipeline; the flow pipeline is arranged between the shock-absorbing force-applying device and the impeller power generation device, is used for transmitting flowing liquid between the shock-absorbing force-applying device and the impeller power generation device and controlling the flowing liquid to flow singly; the impeller power generation device is arranged on the motor vehicle and is used for converting potential energy transmitted by flowing liquid into electric energy; the application has the effect of converting potential energy in the expansion process of the shock absorber into electric energy.

Description

Pressure-driven hydraulic-pushing power generation system

Technical Field

The present application relates to a power generation device, and more particularly, to a pressure-driven hydraulic-propulsion power generation system.

Background

With the development of society, vehicles are increasingly growing, jolting is generated when the vehicles run on a road section with a hollow in the road, and in order to reduce jolting of the vehicles, shock absorbers are generally arranged on the vehicles, so that jolting caused during running of the vehicles is reduced.

At present, a shock absorber on a vehicle only plays a role in shock absorption, potential energy generated by expansion and contraction of the shock absorber in the running process of the vehicle has an invisible effect, and the potential energy generated by expansion and contraction of the shock absorber in the running process of the vehicle can be converted into standby electric energy of the vehicle.

In view of this, the present inventors devised a pressure-driven hydraulic-driven power generation device that converts the expansion potential energy of a shock absorber into electric energy.

Disclosure of utility model

Aiming at the defects of the prior art, the utility model aims to provide a pressure-driven hydraulic pushing power generation system, which has the advantage that potential energy in the expansion process of a shock absorber can be converted into electric energy.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a pressure-driven hydraulic-driven power generation system comprises a shock-absorbing force-applying device, a flow pipeline, an impeller power generation device and flowing liquid,

The vibration-absorbing force-applying device is arranged on the motor vehicle and is used for absorbing vibration of the motor vehicle and transmitting potential energy generated during vibration absorption to the impeller power generation device through flowing liquid by the flow pipeline;

The flow pipeline is arranged between the shock-absorbing force-applying device and the impeller power generation device, is used for transmitting flowing liquid between the shock-absorbing force-applying device and the impeller power generation device and controlling the flowing liquid to flow singly;

the impeller power generation device is arranged on the motor vehicle and is used for converting potential energy transmitted by flowing liquid into electric energy;

The flowing liquid is arranged on the shock-absorbing force-applying device, the flowing pipeline and the impeller power generation device and is used for transmitting energy.

Through adopting above-mentioned technical scheme, when motor vehicle that installs the shock absorber force application device takes place to shake jolt, the shock absorber force application device can produce the flexible and pass through the runner pipeline with its inside flowing liquid and transmit on the impeller power generation facility, by the pressure potential energy conversion that the impeller power generation facility will transmit into the electric energy, and the negative pressure that the shock absorber force application device produced under the restoration and impeller power generation facility self internal pressure effect flow liquid on the impeller power generation facility back to the shock absorber force application device through the runner pipeline.

In summary, the vibration-absorbing force-applying device, the flow pipeline, the impeller power generation device and the flowing liquid are mutually matched to form a complete power generation system, jolt brought in the sales process of the motor vehicle enables the vibration-absorbing force-applying device to do telescopic motion, the vibration-absorbing force-applying device acts pressure potential energy on the impeller power generation device through the flowing liquid and the flow pipeline in the telescopic motion process, and the impeller power generation device converts the pressure potential energy into electric energy, so that the purpose of converting potential energy in the telescopic process of the vibration absorber into electric energy is achieved.

The utility model is further provided with: the shock-absorbing force application device comprises a hydraulic prop, a piston rod, a spring partition plate, a supporting spring and a shock absorption cover, wherein the piston rod, the spring partition plate, the supporting spring and the shock absorption cover are arranged on the hydraulic prop, a hydraulic cavity is arranged at one end, far away from the supporting spring, of the hydraulic prop, a piston cover which is connected with the piston rod and used for extruding inflow liquid in the hydraulic cavity into a flow pipeline is arranged in the hydraulic cavity, a liquid inlet and a liquid outlet which are communicated with the flow pipeline are arranged at one end, far away from the supporting spring, of the hydraulic cavity, and the piston cover partitions the hydraulic cavity into two independent spaces.

By adopting the technical scheme, when the shock-absorbing force-applying device is installed on the motor vehicle, the hydraulic prop and the shock-absorbing cover are fixed on the motor vehicle; when the motor vehicle provided with the shock-absorbing force application device jolts, the piston rod moves towards the direction of the hydraulic prop under the action of the vehicle and compresses the supporting spring between the two spring clapboards, the piston rod drives the piston cover to move along the bottom of one end of the hydraulic cavity away from the supporting spring when moving towards the direction of the hydraulic prop, flowing liquid flows to the flow pipeline through the liquid outlet under the compression of the piston cover and the hydraulic cavity and flows to the impeller power generation device, and the piston rod drives the piston cover to move along one end of the hydraulic cavity close to the supporting spring when moving away from the direction of the hydraulic prop in the process of restoring the supporting spring, and negative pressure formed in the hydraulic cavity and flowing liquid on the impeller power generation device are driven to enter the hydraulic cavity through the liquid inlet under the action of internal pressure on the impeller power generation device.

The utility model is further provided with: one end of the piston cavity, which is far away from the supporting spring, is provided with a reset spring which is propped against the piston cover and always applies acting force towards the extending direction of the piston rod.

Through adopting above-mentioned technical scheme, reset spring's setting can exert auxiliary force when the piston lid is kept away from the hydraulic pressure chamber bottom to carry out the power to the piston rod removal.

The utility model is further provided with: the flow pipeline comprises a feeding pipeline, a discharging pipeline and a one-way valve, wherein the feeding pipeline is arranged between the shock-absorbing force application device and the impeller power generation device and used for enabling flowing liquid to flow from the shock-absorbing force application device to the impeller power generation device, the discharging pipeline is arranged between the shock-absorbing force application device and the impeller power generation device and used for enabling flowing liquid to flow from the impeller power generation device to the shock-absorbing force application device, and the one-way valve is arranged on the discharging pipeline and used for controlling single flowing of the flowing liquid.

By adopting the technical scheme, when the vibration-absorbing force-applying device pushes the flowing liquid on the vibration-absorbing force-applying device to the impeller power generation device, the flowing liquid flows to the impeller power generation device through the feeding pipeline, and the impeller power generation device generates power; when the negative pressure in the vibration-absorbing force-applying device and the pressure in the impeller power generation device push the flowing liquid on the impeller power generation device to the vibration-absorbing force-applying device, the flowing liquid flows to the vibration-absorbing force-applying device through the discharging pipeline and the one-way valve thereon.

The utility model is further provided with: the impeller power generation device comprises an engine body provided with an impeller cavity and a liquid storage cavity, a rotating impeller arranged in the impeller cavity and driven to rotate by flowing liquid, and a generator arranged on the engine body and coaxially connected with the rotating impeller, wherein the impeller cavity is in cylindrical arrangement, the rotating impeller comprises a rotating column coaxial with the impeller cavity, and arc-shaped blades arranged on the periphery of the rotating column and uniformly arranged along the axis of the rotating column, a plurality of spaces are formed by the arc-shaped blades, the rotating column and the inner wall of the impeller cavity, a feed inlet which is perpendicular to the axis of the impeller cavity and communicated with the impeller cavity is arranged on the engine body, a communicating pipe far away from the feed inlet is arranged between the impeller cavity and the oil storage cavity, and a discharge port which is communicated with the oil storage cavity is arranged on the engine body.

By adopting the technical scheme, when the vibration-proof force-applying device pushes flowing liquid onto the impeller power generation device, the flowing liquid is pushed to the feed inlet, the feed inlet enters the impeller cavity of the machine body and the flowing liquid applies acting force on the arc-shaped blades, so that the arc-shaped blades drive the rotating column to rotate, and the rotating impeller formed by the arc-shaped blades and the rotating column drives the generator to rotate and generate power; the flowing liquid in the impeller cavity flows to the communication pipeline under the drive of the arc impeller and enters the liquid storage cavity through the communication pipeline; under the action of the negative pressure of the shock-absorbing force-applying device and the internal pressure of the oil cavity, the flowing liquid in the oil cavity is pushed to the shock-absorbing force-applying device through the discharge hole.

The utility model is further provided with: the flowing liquid is an oil body.

By adopting the technical scheme, the oil body has the function of lubrication and protection, so that the flowing liquid adopts the oil body.

In summary, the utility model has the following advantages:

1. The vibration-absorbing force-applying device, the flow pipeline, the impeller power generation device and the flowing liquid are mutually matched to form a complete power generation system, jolt brought in the sales process of the motor vehicle enables the vibration-absorbing force-applying device to do telescopic motion, the vibration-absorbing force-applying device acts pressure potential energy on the impeller power generation device through the flowing liquid and the flow pipeline in the telescopic motion process, and the impeller power generation device converts the pressure potential energy into electric energy, so that the purpose of converting potential energy in the telescopic process of the vibration absorber into electric energy is achieved.

2. By arranging the return spring, an auxiliary force can be applied when the piston cover is far away from the bottom of the hydraulic cavity, and the piston rod is moved to store the force.

3. The lubricating protection effect on the shock-absorbing force-applying device, the flow pipeline and the impeller power generation device can be effectively achieved by adopting the oil body as the flowing liquid.

Drawings

FIG. 1 is a schematic view of the overall structure of the present embodiment;

fig. 2 is a schematic sectional structure of the present embodiment.

Reference numerals illustrate: 1. a hydraulic prop; 2. a piston rod; 3. a spring separator; 4. a support spring; 5. a damper cap; 6. a hydraulic chamber; 7. a piston cap; 8. a liquid inlet; 9. a liquid outlet port; 10. a return spring; 11. a feed conduit; 12. a discharge pipe; 13. a one-way valve; 14. an impeller cavity; 15. a liquid storage cavity; 16. a body; 17. rotating the impeller; 171. rotating the column; 172. an arc-shaped blade; 18. a generator; 19. a feed inlet; 20. a discharge port; 21. and communicating pipe.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings.

A pressure-driven hydraulic-driven power generation system, as shown in figures 1 and 2, comprises a shock-absorbing force-applying device, a flow pipeline, an impeller power generation device and flowing liquid,

The flowing liquid is arranged on the vibration absorbing and force applying device, the flowing pipeline and the impeller power generation device and is used for transmitting energy, and the flowing liquid is an oil body.

As shown in fig. 1 and 2, the shock-absorbing force application device comprises a hydraulic prop 1, a piston rod 2 slidably mounted on the hydraulic prop 1, two spring separators 3 respectively fixed on the piston cap 7 and the hydraulic prop 1, a supporting spring 4 sleeved between the piston rod 2 and the two spring separators 3, and a shock-absorbing cover 5 fixed on one end of the piston cap 7 far away from the hydraulic prop 1, wherein a hydraulic cavity 6 is formed at one end of the hydraulic prop 1 far away from the supporting spring 4, a piston cap 7 connected with the piston rod 2 and used for extruding fluid in the hydraulic cavity 6 into a flow pipeline is mounted in the hydraulic cavity 6, a fluid inlet 8 and a fluid outlet 9 communicated with the flow pipeline are formed at one end of the hydraulic cavity 6 far away from the supporting spring 4, and the hydraulic cavity 6 is partitioned into two independent spaces by the piston cap 7.

When the shock absorbing and applying device is installed on the motor vehicle, the hydraulic prop 1 and the shock absorbing cover 5 are fixed on the motor vehicle; when the motor vehicle provided with the shock-absorbing force application device jolts, the piston rod 2 moves towards the direction of the hydraulic prop 1 under the action of the vehicle and compresses the supporting spring 4 between the two spring clapboards 3, the piston rod 2 drives the piston cover 7 to move along the bottom of one end of the hydraulic cavity 6 away from the supporting spring 4 when moving towards the direction of the hydraulic prop 1, flowing liquid flows to the flow pipeline through the liquid outlet 9 under the compression of the piston cover 7 and the hydraulic cavity 6 and flows to the impeller power generation device, and the piston rod 2 drives the piston cover 7 to move along one end of the hydraulic cavity 6 close to the supporting spring 4 when moving away from the direction of the hydraulic prop 1 in the process of restoring the supporting spring 4, and the negative pressure formed in the hydraulic cavity 6 and the internal pressure on the impeller power generation device drive the flowing liquid on the impeller power generation device to enter the hydraulic cavity 6 through the liquid inlet 8.

Further, a return spring 10 which is tightly propped against the piston cover 7 and always applies a force towards the extending direction of the piston rod 2 is fixed at one end of the piston cavity away from the supporting spring 4, so that an auxiliary force can be applied when the piston cover 7 is away from the bottom of the hydraulic cavity 6, and the piston rod 2 can be moved to store the force.

As shown in fig. 1 and 2, the flow conduit includes a feed conduit 11 mounted between the damper force applying device and the impeller power generating device for flowing the flowing liquid from the damper force applying device to the impeller power generating device, a discharge conduit 12 mounted between the damper force applying device and the impeller power generating device for flowing the flowing liquid from the impeller power generating device to the damper force applying device, and a check valve 13 mounted on the discharge conduit 12 for controlling the single flow of the flowing liquid.

When the vibration absorbing and force applying device pushes the flowing liquid on the vibration absorbing and force applying device to the impeller power generation device, the flowing liquid flows to the impeller power generation device through the feeding pipeline 11, and the impeller power generation device generates power; when the negative pressure in the vibration-absorbing force-applying device and the pressure in the impeller power generation device push the flowing liquid on the impeller power generation device to the vibration-absorbing force-applying device, the flowing liquid flows to the vibration-absorbing force-applying device through the discharging pipeline 12 and the one-way valve 13 thereon.

As shown in fig. 1 and 2, the impeller power generation device comprises a machine body 16 provided with an impeller cavity 14 and a liquid storage cavity 15, a rotary impeller 17 installed in the impeller cavity 14 and driven to rotate by flowing liquid, and a generator 18 installed on the machine body 16 and coaxially connected with the rotary impeller 17, wherein the impeller cavity 14 is in a cylindrical shape, the rotary impeller 17 comprises a rotary column 171 coaxial with the impeller cavity 14, arc-shaped blades 172 installed on the periphery of the rotary column 171 and uniformly arranged along the axis of the rotary column 171, a plurality of spaces are formed by the arc-shaped blades 172, the rotary column 171 and the inner wall of the impeller cavity 14, a feed inlet 19 perpendicular to the axis of the impeller cavity 14 and communicated with the impeller cavity 14 is formed on the machine body 16, a communicating pipe far away from the feed inlet 19 is formed between the impeller cavity 14 and the liquid storage cavity, a discharge outlet 20 communicated with the liquid storage cavity is formed on the machine body 16, and the feed inlet 19 and the discharge outlet 20 are communicated with a flow passage.

When the vibration-absorbing force-applying device pushes the flowing liquid to the impeller power generation device, the flowing liquid is pushed to the feed inlet 19, the flowing liquid enters the impeller cavity 14 of the machine body 16 from the feed inlet 19 and applies force to the arc-shaped blades 172 by the flowing liquid, so that the arc-shaped blades 172 drive the rotating column 171 to rotate, and the rotating impeller 17 formed by the arc-shaped blades 172 and the rotating column 171 drives the generator 18 to rotate and generate power; the flowing liquid in the impeller cavity 14 flows to the communication pipeline under the drive of the arc impeller and enters the liquid storage cavity 15 through the communication pipeline; the flowing liquid in the oil cavity is pushed to the shock-absorbing force-applying device through the discharging hole 20 under the negative pressure of the shock-absorbing force-applying device and the internal pressure of the oil cavity.

The working process and the beneficial effects of the utility model are as follows: when the motor vehicle provided with the vibration-absorbing force-applying device vibrates and jolts, the vibration-absorbing force-applying device can stretch and transfer the flowing liquid in the vibration-absorbing force-applying device to the impeller power generation device through the flow pipeline, the impeller power generation device converts the transferred pressure potential energy into electric energy, and the vibration-absorbing force-applying device returns the flowing liquid on the impeller power generation device to the vibration-absorbing force-applying device through the flow pipeline under the action of the negative pressure generated by restoration and the internal pressure of the impeller power generation device.

The above embodiments are only preferred embodiments of the present utility model, and are not intended to limit the present utility model, and any modifications, equivalent substitutions, improvements, etc. within the design concept of the present utility model should be included in the scope of the present utility model.

Claims

1. A pressure driven hydraulically powered power generation system, characterized by: comprises a shock absorbing force applying device, a flowing pipeline, an impeller power generating device and flowing liquid,

The impeller power generation device is arranged on the motor vehicle and is used for converting potential energy transmitted by flowing liquid into electric energy; the flowing liquid is arranged on the shock-absorbing force-applying device, the flowing pipeline and the impeller power generation device and is used for transmitting energy.

2. A pressure driven hydraulically powered power generating system as defined in claim 1, wherein: the shock-absorbing force application device comprises a hydraulic prop (1), a piston rod (2) arranged on the hydraulic prop (1), a spring partition plate (3), a supporting spring (4) and a shock-absorbing cover (5), wherein one end of the hydraulic prop (1) away from the supporting spring (4) is provided with a hydraulic cavity (6), a piston cover (7) which is connected with the piston rod (2) and used for extruding liquid in the hydraulic cavity (6) into a flow pipeline is arranged in the hydraulic cavity (6), one end of the hydraulic cavity (6) away from the supporting spring (4) is provided with a liquid inlet (8) and a liquid outlet (9) which are communicated with the flow pipeline, and the piston cover (7) partitions the hydraulic cavity (6) into two independent spaces.

3. A pressure driven hydraulically powered power generating system as defined in claim 2, wherein: one end of the piston cavity, which is far away from the supporting spring (4), is provided with a reset spring (10) which is abutted against the piston cover (7) and always applies acting force towards the extending direction of the piston rod (2).

4. A pressure driven hydraulically powered power generating system as defined in claim 1, wherein: the flow pipeline comprises a feeding pipeline (11) which is arranged between the shock-absorbing force application device and the impeller power generation device and used for enabling flowing liquid to flow from the shock-absorbing force application device to the impeller power generation device, a discharging pipeline (12) which is arranged between the shock-absorbing force application device and the impeller power generation device and used for enabling flowing liquid to flow from the impeller power generation device to the shock-absorbing force application device, and a one-way valve (13) which is arranged on the discharging pipeline (12) and used for controlling single flowing of the flowing liquid.

5. A pressure driven hydraulically powered power generating system as defined in claim 1, wherein: the impeller power generation device comprises an engine body (16) provided with an impeller cavity (14) and a liquid storage cavity (15), a rotating impeller (17) which is arranged in the impeller cavity (14) and drives the impeller cavity (14) to rotate through flowing liquid, and a generator (18) which is arranged on the engine body (16) and is coaxially connected with the rotating impeller (17), wherein the impeller cavity (14) is in a cylindrical shape, the rotating impeller (17) comprises a rotating column (171) which is coaxial with the impeller cavity (14), arc-shaped blades (172) which are arranged on the peripheral side of the rotating column (171) and are uniformly arranged along the axis of the rotating column (171), a plurality of spaces are formed on the inner wall of the arc-shaped blades (172), the rotating column (171) and the inner wall of the impeller cavity (14), a feed inlet (19) which is perpendicular to the axis of the impeller cavity (14) and is communicated with the impeller cavity (14) is arranged on the engine body (16), a communicating pipe (20) which is far away from the feed inlet (19) is arranged between the impeller cavity (14) and the oil storage cavity, and the feed inlet (19) is communicated with the communicating pipe (20).

6. A pressure driven hydraulically powered power generating system as defined in claim 1, wherein: the flowing liquid is an oil body.