CN112234764A

CN112234764A - Elastic power generation device and application thereof

Info

Publication number: CN112234764A
Application number: CN202011299282.1A
Authority: CN
Inventors: 曹进江
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-18
Filing date: 2020-11-18
Publication date: 2021-01-15
Also published as: WO2022105538A1

Abstract

The application relates to an elastic power generation device and application of the device, and the elastic power generation device comprises a suspension unit for applying pressure to a rotor, wherein the rotor is suspended below the suspension unit, a driving device drives the rotor to rotate, and the rotor drives a power generation device to generate power; the rotor comprises a plurality of coaxial rotating discs arranged at intervals, and a power conversion unit is arranged on the circumferential surface of each rotating disc; the plurality of turntables are sleeved on the same rotating shaft, the turntables are linked with the driving device, and the rotating shaft is linked with the power generation device; the power conversion unit comprises a rod body which is arranged on the turntable and can move, and the outer end of the rod body is integrally connected with a base; the rod body side is provided with an inclined connecting rod, the inclined connecting rod is linked with a driven wheel, and the driven wheel is sleeved on the rotating shaft through a one-way bearing. This application drives the pivot in proper order through a plurality of power conversion units to drive power generation facility and generate electricity, the electric energy of production can be stored in order to wait to use in the electric power storage unit, has realized the purpose of turning into the electric energy with potential energy at the rotor rotation in-process.

Description

Elastic power generation device and application thereof

Technical Field

The present disclosure relates to power generation devices, and particularly to an elastic power generation device and an application using the same.

Background

With the development of society, the demand of energy is increasing, and although the traditional energy is the main component of energy, with the continuous exploitation of the traditional energy, the reduction of reserves and related environmental problems, the development and utilization of pollution-free new energy such as electric energy and wind energy need to be enhanced so as to replace the traditional energy with the new energy in some fields.

The new energy which people often contact is the field of automobile power, and with the gradual development and upgrade of new energy automobiles, especially the reasonable utilization of electric energy in electric automobiles, the conversion from mechanical energy to electric energy has gained a certain technical accumulation in the field.

Most of energy conversion devices in the prior art separate a part of power on a main power shaft, and the separated power is converted into electric energy through a power generation device.

Disclosure of Invention

The elastic power generation device aims to provide an elastic power generation device which can reasonably convert potential energy into electric energy; on the basis of the purpose, the application also aims to provide an application of the elastic power generation device.

The purpose of the application is realized as follows: an elastic power generation device comprises a suspension unit for applying pressure to a rotor, wherein the rotor is suspended below the suspension unit, a driving device drives the rotor to rotate, and the rotor drives a power generation device to generate power; the rotor comprises a plurality of coaxial rotating discs arranged at intervals, and a power conversion unit is arranged on the circumferential surface of each rotating disc; the plurality of turntables are sleeved on the same rotating shaft, the turntables are linked with the driving device, and the rotating shaft is linked with the power generation device;

the power conversion unit comprises a rod body which is arranged on the turntable and can move, and the outer end of the rod body is integrally connected with a base; the rod body side is provided with an inclined connecting rod, the inclined connecting rod is linked with a driven wheel, and the driven wheel is sleeved on the rotating shaft through a one-way bearing.

The two ends of the rotating shaft are rotatably connected with the inner frame and extend out of the inner frame, the inner frame is hung in the outer frame through the hanging unit, and the bottom of the outer frame is provided with a pressure bearing roller which is in rolling contact with the base of the power conversion unit; the outer frame is of a frame structure and comprises a top cross beam and two side walls, limiting holes are formed in the two side walls, and two ends of the rotating shaft extend out of the limiting holes; a power output wheel is arranged at one end of the rotating shaft extending out; a plurality of screw holes are arranged on the top beam.

The suspension unit comprises a plurality of springs arranged at a cross beam at the top of the outer frame, and the lower ends of the springs are connected with the top of the inner frame; the suspension unit further comprises a pressing plate arranged below the top cross beam of the outer frame, the lower end face of the pressing plate is fixedly connected with the upper end of the spring, and the lower end of the spring is connected with the top of the inner frame; the upper end face of the pressing plate is fixedly connected with a screw rod, the upper portion of the screw rod is screwed with a screw hole in the top cross beam of the outer frame and extends out, and a hand wheel is arranged on the extending portion.

The rotor also comprises a power input wheel sleeved at the power input end of the rotating shaft and a power output wheel at the power output end, the power input wheel is driven by a driving device, and the power output wheel is linked with the power input end of the power generation device; and a plurality of electric storage units are arranged in or outside the outer frame and are connected with a current output end circuit of the power generation device.

The periphery of the power input wheel is provided with a plurality of power input rods, and the power input rods are connected with the adjacent turntables and drive the turntables to rotate; the turntables are connected and linked through a connecting rod, and the connecting rod penetrates through the turntables 3-2; and bearings are arranged among the turntable, the power input wheel and the rotating shaft.

The power conversion unit comprises a gear sleeved outside the rotating shaft through a one-way bearing, and a guide ring fixed on the circular surface of the turntable, wherein a socket is arranged on the circular surface of the turntable at the inner side of the guide ring; the rod body is inserted into the guide ring; the lower end of the rod body is integrally connected with a base, the upper end of the rod body is provided with a plug, and the plug is inserted into the socket; a return spring is arranged between the plug and the socket; the side surface of the rod body is connected with an inclined connecting rod, the inner end of the inclined connecting rod is connected with a rack, and the rack is meshed and linked with the gear; a limiting pile is arranged on the side of the rack; the lower end face of the base is an arc surface, and an anti-skid rubber layer is arranged on the arc surface.

The power conversion unit comprises a cam sleeved outside the rotating shaft through a one-way bearing, and a guide ring fixed on the circular surface of the turntable, wherein a socket is arranged on the circular surface of the turntable at the inner side of the guide ring; the rod body is inserted into the guide ring; the lower end of the rod body is integrally connected with a base, the upper end of the rod body is provided with a plug, and the plug is inserted into the socket; a return spring is arranged between the plug and the socket; the side surface of the rod body is connected with an inclined connecting rod, and the inner end of the inclined connecting rod is hinged and linked with the cam; the lower end face of the base is an arc surface, and an anti-skid rubber layer is arranged on the arc surface.

A support ring is connected between the turntables, a through hole is arranged on the support ring, the rod body extends out of the through hole, and the extending end is integrally connected with a base; a cavity is formed between the support ring and the turntables, the leftmost turntable is provided with an oil filling hole, the rightmost turntable is not provided with an oil filling hole, and the rest turntables are provided with circulation holes.

The application of the elastic power generation device comprises the following steps:

step one, mounting a rotor: according to the

claims

1 and 2, the inner frame is hung in the outer frame through the hanging unit, the rotor is installed in the inner frame, the power input end of the rotor is linked with the driving device, and the power output end of the rotor is linked with the power generation device;

step two, pressure regulation: according to the claim 3, the height of the pressure plate is adjusted through the handwheel, so that the pressure of the spring on the inner frame is adjusted, namely the height of the rotor is adjusted, and the rotating shaft in the rotor is positioned at the lowest end of the limiting hole;

step three, power generation: the driving device drives the rotary table of the rotor to rotate, so that the power conversion unit on the rotary table is pressed through the bearing roller in sequence, and the base of the power conversion unit is pressed to move inwards, so that the rod body and the inclined connecting rod are driven to move upwards, the driven wheel is driven to rotate, and the rotating shaft is driven to rotate; the subsequent power conversion units are sequentially pressed to sequentially drive the rotating shaft, so that the pressure is converted into continuous driving force for the rotating shaft, and finally the power generation device is driven to continuously generate power;

step four, storage and use of electric energy: the power generation device transmits the electric energy to the electric storage unit for storage, and the electric energy in the electric storage unit can be used by the driving device and also can be used by an external load.

Furthermore, a main power output wheel rotating along with the rotating disc is arranged on the rotating disc at the outermost side; the main power output wheel provides the power of the driving device outwards.

Due to the fact that the technical scheme is adopted, the rotating shaft is sequentially driven by the power conversion units, the power generation device is driven to generate power, the generated electric energy can be stored in the electric storage unit to be used, and the purpose that potential energy is converted into the electric energy in the rotating process of the rotor is achieved.

This application overall structure is reasonable, the fault rate is very low, it generates electricity not to utilize the power of power supply at the rotation in-process, but utilize the rotor to compel power conversion unit at the rotation in-process middling pressure, and drive power generation facility and generate electricity, though the dead weight of rotor and transmission will certainly lose some power take off, nevertheless the power of seeing the loss on the whole is far less than the electric energy through power conversion unit conversion, thereby realize at power input, under the very little prerequisite of the influence that the output receives, carry out the conversion of electric energy, energy conversion rate is high-efficient.

Drawings

The specific structure of the invention is given by the following figures and examples:

FIG. 1 is a schematic structural diagram of the present application;

FIG. 2 is a side view schematic of the present application;

FIG. 3 is a schematic view of the structure of the rotor;

FIG. 4 is a schematic diagram of a power conversion device with a rack gear;

FIG. 5 is a schematic diagram of a power conversion device driven by an eccentric wheel;

FIG. 6 is a schematic diagram of a power conversion unit with a rack gear;

FIG. 7 is a schematic diagram of a power conversion unit with eccentric drive;

FIG. 8 is an enlarged view of portion A;

fig. 9 is a schematic view of a rotor structure with a support ring.

Legend: 1. the device comprises an outer frame, 2, a suspension unit, 3, a rotor, 3-1, a power input rod, 3-2, a turntable, 3-3, a connecting rod, 3-4, a power conversion unit, 3-411, a limiting pile, 3-412, a rack, 3-413, an inclined connecting rod, 3-414, a rod body, 3-415, a base, 3-416, a guide ring, 3-417, a return spring, 3-418, a plug, 3-419, a socket, 3-420, a one-way bearing, 3-421, a gear, 3-422, a cam, 3-5, a separating ring, 3-6, an oil filling hole, 3-7, a support ring, 4, a rotating shaft, 5, a bearing roller, 6, an inner frame, 7, an electric storage unit, 8, a power generation device, 9, a driving device, 10, a power output wheel, 11 and a limiting hole, 12. and a power input wheel.

Detailed Description

The present invention is not limited by the following examples, and specific embodiments may be determined according to the technical solutions and practical situations of the present invention.

Example 1: as shown in fig. 1 to 8, an elastic force generating device comprises a suspension unit 2 for applying pressure to a rotor 3, the rotor 3 is suspended under the suspension unit 2, a driving device 9 drives the rotor 3 to rotate, and the rotor 3 drives a generating device 8 to generate electricity; the rotor 3 comprises a plurality of rotating discs 3-2 which are coaxially arranged at intervals, and a power conversion unit 3-4 is arranged on the circumferential surface of each rotating disc 3-2; the plurality of rotary tables 3-2 are sleeved on the same rotary shaft 4, the rotary tables 3-2 are linked with the driving device 1, and the rotary shaft 4 is linked with the power generation device 6;

the power conversion unit 3-4 comprises a rod body 3-414 which is arranged on the turntable 3-2 and can move, and the outer end of the rod body 3-414 is integrally connected with a base 3-415; the side of the rod body 3-414 is provided with an inclined connecting rod 3-413, the inclined connecting rod 3-413 is linked with a driven wheel, and the driven wheel is sleeved on the rotating shaft 4 through a one-way bearing 3-420.

Further, as shown in fig. 1 and 2, both ends of the rotating shaft 4 are rotatably connected to the inner frame 6 and extend out of the inner frame 6, the inner frame 6 is suspended in the outer frame 1 by the suspension unit 2, and the bottom of the outer frame 1 is provided with a pressure roller 5, and the pressure roller 5 is in rolling contact with the bases 3 to 415 of the power conversion units 3 to 4.

Further, the outer frame 1 is a frame structure and comprises a top cross beam and two side walls, wherein the two side walls are provided with limiting holes 11, and two ends of the rotating shaft 4 extend out of the limiting holes; a power output wheel 10 is arranged at one end of the rotating shaft 4 extending out. A plurality of screw holes are arranged on the top beam. The limiting hole 11 limits the up-down movement distance of the rotating shaft 4, that is, the up-down movement distance of the rotor 3, that is, the force of the suspension unit 2 to apply pressure to the rotor, so as to prevent excessive kinetic energy loss due to excessive friction between the rotor 3 and the pressure roller 5 caused by excessive pressure application.

Further, a backing roller 5 is provided at the bottom of the outer frame 1, and the lower circumference of the base 3-415 is in rolling contact with the upper circumference of the backing roller 5.

Preferably, two backing rollers 5 are arranged side by side, forming a triangular arrangement with the rotor 3. The two sides of the lower circumference of the base 3-415 are respectively contacted with the upper circumference of the two pressure rollers 5 in a rolling way.

Further, the suspension unit 2 includes a plurality of springs provided at a top cross member of the outer frame 1, and lower ends of the springs are connected to the top of the inner frame 6. The spring provides downward pressure.

Further, the suspension unit 2 further comprises a pressing plate arranged below a top cross beam of the outer frame 1, the lower end face of the pressing plate is fixedly connected with the upper end of the spring, and the lower end of the spring is connected with the top of the inner frame 6; the upper end face of the pressing plate is fixedly connected with a screw rod, the upper part of the screw rod is screwed with a screw hole at the top cross beam of the outer frame 1 and extends out, and a hand wheel is arranged on the extending part. The hand wheel is rotated to adjust the extension of the screw rod, so that the height of the pressure plate is adjusted, the pressure applied to the inner frame 6 by the spring is further controlled, and the pressure applied to the rotor 3 is also controlled.

As shown in fig. 1, 2 and 3, the rotor 3 further includes a power input wheel 12 sleeved at the power input end of the rotating shaft 4, and a power output wheel 10 at the power output end, the power input wheel 12 is driven by the driving device 9, and the power output wheel 10 is linked with the power input end of the power generation device 8. The driving device 9 is an electric motor or an internal combustion engine, and the power generation device 8 is a generator.

Furthermore, a plurality of electric storage units 7 are arranged in or outside the outer frame 1, and the electric storage units 7 are connected with a current output end circuit of the power generation device 8.

The main power output wheel is arranged on the rotary disc 3-2 at the power output end side of the rotating shaft 4, and the main power output wheel can be externally connected with a load as an integral main power output end and used as a power source of the load to provide rotating force for the outside. The specific connection structure of the external load and the main power output wheel is not the invention point of the application, and the connection mode in the prior art can be referred to, and the application is not described in detail herein.

Furthermore, a plurality of power input rods 3-1 are arranged on the circumferential surface of the power input wheel 12, and the power input rods 3-1 are connected with the adjacent turntables 3-2 and drive the turntables 3-2 to rotate; the turntables 3-2 are linked through connecting rods 3-3, and the connecting rods 3-3 penetrate through the turntables 3-2.

Further, bearings are arranged among the rotary table 3-2, the power input wheel 12 and the rotating shaft 4, so that the rotary table 3-2 and the power input wheel 12 cannot directly drive the rotating shaft 4.

As shown in fig. 4 and 5, the projections of the power conversion units 3-4 on the circular surface of each turntable 3-2 on any one turntable 3-2 do not overlap. The projections of the plurality of power conversion units 3-4 are uniformly distributed on the same circular surface by taking the center of a circle of the projected rotating disc 3-2 as a central point.

As shown in fig. 6, the power conversion unit 3-4 includes a driven wheel sleeved outside the rotating shaft 4 through a one-way bearing 3-420, the driven wheel is a gear 3-421, and a socket 3-419 is arranged on a circular surface of the rotating disc 3-2 near the gear 3-421; the lower end of the rod body 3-414 is integrally connected with a base 3-415, and a return spring 3-417 is arranged between the upper end of the rod body 3-414 and a socket 3-419; the side surface of the rod body 3-414 is connected with a rack 3-412, and the rack 3-412 is meshed and linked with the gear 3-421.

As a further optimization of the application, the power conversion unit 3-4 comprises a gear 3-421 sleeved outside the rotating shaft 4 through a one-way bearing 3-420, a guide ring 3-416 fixed on the circular surface of the turntable 3-2, and a socket 3-419 arranged on the circular surface of the turntable 3-2 at the inner side of the guide ring 3-416; the rod body 3-414 is inserted into the guide ring 3-416; the lower end of the rod body 3-414 is integrally connected with a base 3-415, the upper end of the rod body 3-414 is provided with a plug 3-418, and the plug 3-418 is inserted into the socket 3-419; a return spring 3-417 is arranged between the plug 3-418 and the socket 3-419; the side surface of the rod body 3-414 is connected with an inclined connecting rod 3-413, the inner end of the inclined connecting rod 3-413 is connected with a rack 3-412, and the rack 3-412 is meshed and linked with the gear 3-421.

Furthermore, limiting piles 3-411 are arranged on the sides of the racks 3-412; the arrangement of the limiting piles 3-411 is to ensure that the racks 3-412 are tightly meshed with the gears 3-421 when being forced to move, so that the racks 3-412 are prevented from being separated from each other to influence transmission.

Further, the lower end surface of the base 3-415 is an arc surface, and an anti-skid rubber layer is arranged on the arc surface; an anti-slip rubber layer is also provided on the surface of the backing roller 5.

As shown in FIG. 9, a support ring 3-7 is connected between the turntables 3-2, a through hole is provided on the support ring 3-7, the rod body 3-414 extends out from the through hole, and the extending end is integrally connected with a base 3-415.

A cavity is formed between the support ring 3-7 and the turntables 3-2, oil injection holes are arranged on the turntables 3-2 on the left side, oil injection holes are not arranged on the turntables 3-2 on the right side, and circulation holes are arranged on the other turntables 3-2.

Before working, lubricating oil can be injected into the cavity between the support ring 3-7 and the rotary table 3-2 through the oil injection holes, and the lubricating oil can flow into each space through the flow through holes, so that the abrasion of each part in the rotor 3 is reduced.

Example 2: as shown in fig. 6, the power conversion unit 3-4 comprises a cam 3-422 sleeved outside the rotating shaft 4 through a one-way bearing 3-420, a guide ring 3-416 fixed on the circular surface of the turntable 3-2, and a socket 3-419 arranged on the circular surface of the turntable 3-2 inside the guide ring 3-416; the rod body 3-414 is inserted into the guide ring 3-416; the lower end of the rod body 3-414 is integrally connected with a base 3-415, the upper end of the rod body 3-414 is provided with a plug 3-418, and the plug 3-418 is inserted into the socket 3-419; a return spring 3-417 is arranged between the plug 3-418 and the socket 3-419; the side surface of the rod body 3-414 is connected with an inclined connecting rod 3-413, and the inner end of the inclined connecting rod 3-413 is hinged and linked with the cam 3-422.

Before the application works, the pressure applied on the rotor 3 is adjusted through the hand wheel, after the adjustment is finished, the driving device 9 is started, the driving device 9 drives the power input wheel 12 to rotate, the power input wheel 12 drives the adjacent turntables 3-2 to rotate, and the turntables 3-2 are driven to rotate at the same speed as the turntables 3-2 are connected through the connecting rods 3-3.

In the rotating process of the rotating disc 3-2, only one power conversion unit 3-4 on the rotating disc 3-2 is in contact with the pressure bearing roller 5, and the base 3-415 of the power conversion unit 3-4 in contact with the pressure bearing roller 5 is pressed to move inwards, so that the rod body 3-414 and the rack 3-412 are driven to move upwards, the gear 3-421 is driven to rotate, and the gear 3-421 drives the rotating shaft 4. By analogy, the subsequent power conversion units 3-4 are sequentially pressed to sequentially drive the rotating shaft 4, so that the pressure is converted into continuous driving force for the rotating shaft 4, and finally the power generation device 8 is driven to continuously generate power.

When the pressed power conversion unit 3-4 is separated from the pressure bearing roller 5, the base 3-415 and the rod body 3-414 extend outwards under the action of the return spring 3-417 so as to drive the rotating shaft to be pressed next time. In the process of extending the base 3-415 and the rod 3-414, the rack 3-412 is driven to move downwards, the gear 3-421 rotates in the opposite direction, but the rotation in the opposite direction of the gear 3-421 does not drive the rotating shaft 4 to rotate in the opposite direction under the blocking of the one-way bearing 3-420.

The specific structure and principle of the one-way bearing 3-420 is the prior art, and is a bearing which can rotate freely in one direction and is locked in the other direction. The one-way bearing is also called as an overrunning clutch, and is named according to different industries and different functions. The metal shell of the one-way bearing contains a plurality of rolling shafts, rolling needles or rolling balls, and the shape of the rolling seat of the one-way bearing enables the one-way bearing to roll only in one direction, but generates great resistance in the other direction so as not to roll. The specific structure of the one-way bearing 3-420 will not be described in detail herein.

Similarly, when the driven wheel is the cam 3-422, the working process is similar to the working process of the gear, and the cam 3-422 is driven by the inclined link 3-413, and the cam 3-422 rotates back and forth along with the up-and-down movement of the inclined link 3-413, so as to drive the rotating shaft 4 to rotate.

When the bearing roller 5 is used, the distance between the rotor 3 and the ground needs to be adjusted, and the base 3-415 of the power conversion unit 3-4 can be in contact with the ground and pressed to move inwards when the rotor 3 rotates. However, the surface of the base 3-415 is easily damaged by being pressed when the base is in contact with the ground, and if the surface of the base 3-415 is uneven, the base 3-415 is changed from one-way inward displacement to frequent inward and outward displacement in the pressing process, so that the driven wheel rotates back and forth, the driving effect on the rotating shaft 4 is reduced, and the scheme is not an optimal scheme.

step one, mounting the rotor 3: as described above, the inner frame 6 is suspended in the outer frame 1 through the suspension unit 2, the rotor 3 is installed in the inner frame 6, the power input end of the rotor 3 is linked with the driving device 9, and the power output end is linked with the power generation device 8;

step two, pressure regulation: the height of the pressing plate is adjusted through a hand wheel, so that the pressure of the spring on the inner frame 6 is adjusted, namely the height of the rotor 3 is adjusted, and the rotating shaft 4 in the rotor 3 is positioned at the lowest end of the limiting hole 11;

step three, power generation: the driving device 9 drives the rotary table 3-2 of the rotor 3 to rotate, so that the power conversion unit 3-4 on the rotary table 3-2 is pressed sequentially by the pressure bearing roller 5, the base 3-415 of the power conversion unit 3-4 is pressed to move inwards, the rod body 3-414 and the inclined connecting rod 3-413 are driven to move upwards, and the driven wheel is driven to rotate to drive the rotating shaft 4 to rotate; the subsequent power conversion units 3-4 are sequentially pressed to sequentially drive the rotating shaft 4, so that the pressure is converted into continuous driving force for the rotating shaft 4, and finally the power generation device 8 is driven to continuously generate power;

step four, storage and use of electric energy: the power generator 8 transmits electric energy to the electric storage unit 7 for storage, and the electric energy in the electric storage unit 7 can be used by the driving device 9 or an external load.

Furthermore, a main power output wheel rotating along with the rotary disc 3-2 is arranged on the rotary disc 3-2 at the outermost side.

This application accessible main power output wheel on the rotor 3 outwards provides drive arrangement 9's power, and power conversion unit 3-4 in the rotor 3 converts the pressure that suspension unit 2 provided into the drive power to countershaft 4, and then drives power generation facility 8 and generate electricity, and the electric energy of production can supply drive arrangement 9 to use, but the at utmost reduces drive arrangement 9's energy resource consumption.

The foregoing description is by way of example only and is not intended as limiting the embodiments of the present application. All obvious variations and modifications of the present invention are within the scope of the present invention.

Claims

1. An elasticity power generation facility which characterized in that: the device comprises a suspension unit for applying pressure to a rotor, wherein the rotor is suspended below the suspension unit, a driving device drives the rotor to rotate, and the rotor drives a power generation device to generate power; the rotor comprises a plurality of coaxial rotating discs arranged at intervals, and a power conversion unit is arranged on the circumferential surface of each rotating disc; the plurality of turntables are sleeved on the same rotating shaft, the turntables are linked with the driving device, and the rotating shaft is linked with the power generation device;

2. A spring-powered electricity generating apparatus as claimed in claim 1, wherein: the two ends of the rotating shaft are rotatably connected with the inner frame and extend out of the inner frame, the inner frame is hung in the outer frame through the hanging unit, and the bottom of the outer frame is provided with a pressure bearing roller which is in rolling contact with the base of the power conversion unit; the outer frame is of a frame structure and comprises a top cross beam and two side walls, limiting holes are formed in the two side walls, and two ends of the rotating shaft extend out of the limiting holes; a power output wheel is arranged at one end of the rotating shaft extending out; a plurality of screw holes are arranged on the top beam.

3. A spring-powered electricity generating apparatus as claimed in claim 1 or 2, wherein: the suspension unit comprises a plurality of springs arranged at a cross beam at the top of the outer frame, and the lower ends of the springs are connected with the top of the inner frame; the suspension unit further comprises a pressing plate arranged below the top cross beam of the outer frame, the lower end face of the pressing plate is fixedly connected with the upper end of the spring, and the lower end of the spring is connected with the top of the inner frame; the upper end face of the pressing plate is fixedly connected with a screw rod, the upper portion of the screw rod is screwed with a screw hole in the top cross beam of the outer frame and extends out, and a hand wheel is arranged on the extending portion.

4. A spring-powered electricity generating apparatus as claimed in claim 3, wherein: the rotor also comprises a power input wheel sleeved at the power input end of the rotating shaft and a power output wheel at the power output end, the power input wheel is driven by a driving device, and the power output wheel is linked with the power input end of the power generation device; and a plurality of electric storage units are arranged in or outside the outer frame and are connected with a current output end circuit of the power generation device.

5. A resilient electric generating apparatus according to claim 4, wherein: the periphery of the power input wheel is provided with a plurality of power input rods, and the power input rods are connected with the adjacent turntables and drive the turntables to rotate; the turntables are connected and linked through a connecting rod, and the connecting rod penetrates through the turntables 3-2; and bearings are arranged among the turntable, the power input wheel and the rotating shaft.

6. A resilient electric generating apparatus according to claim 1, 2, 4 or 5, wherein: the power conversion unit comprises a gear sleeved outside the rotating shaft through a one-way bearing, and a guide ring fixed on the circular surface of the turntable, wherein a socket is arranged on the circular surface of the turntable at the inner side of the guide ring; the rod body is inserted into the guide ring; the lower end of the rod body is integrally connected with a base, the upper end of the rod body is provided with a plug, and the plug is inserted into the socket; a return spring is arranged between the plug and the socket; the side surface of the rod body is connected with an inclined connecting rod, the inner end of the inclined connecting rod is connected with a rack, and the rack is meshed and linked with the gear; a limiting pile is arranged on the side of the rack; the lower end face of the base is an arc surface, and an anti-skid rubber layer is arranged on the arc surface.

7. A resilient electric generating apparatus according to claim 1, 2, 4 or 5, wherein: the power conversion unit comprises a cam sleeved outside the rotating shaft through a one-way bearing, and a guide ring fixed on the circular surface of the turntable, wherein a socket is arranged on the circular surface of the turntable at the inner side of the guide ring; the rod body is inserted into the guide ring; the lower end of the rod body is integrally connected with a base, the upper end of the rod body is provided with a plug, and the plug is inserted into the socket; a return spring is arranged between the plug and the socket; the side surface of the rod body is connected with an inclined connecting rod, and the inner end of the inclined connecting rod is hinged and linked with the cam; the lower end face of the base is an arc surface, and an anti-skid rubber layer is arranged on the arc surface.

8. A spring-powered electricity generating apparatus as claimed in claim 6 or 7, wherein: a support ring is connected between the turntables, a through hole is arranged on the support ring, the rod body extends out of the through hole, and the extending end is integrally connected with a base; a cavity is formed between the support ring and the turntables, the leftmost turntable is provided with an oil filling hole, the rightmost turntable is not provided with an oil filling hole, and the rest turntables are provided with circulation holes.

9. The application of the elastic power generation device is characterized in that: the method comprises the following steps:

step one, mounting a rotor: according to the claims 1 and 2, the inner frame is hung in the outer frame through the hanging unit, the rotor is installed in the inner frame, the power input end of the rotor is linked with the driving device, and the power output end of the rotor is linked with the power generation device;

10. Use of a resilient electric generating means according to claim 9, wherein: a main power output wheel rotating along with the turntable is arranged on the outermost turntable; the main power output wheel provides the power of the driving device outwards.