TWM620890U - Bidirectional potential energy power generating equipment and its power output device - Google Patents

Abstract

A two-way potential energy generating device includes two generating sets, a support structure, a power output mechanism, a gravity supply mechanism and an electric control mechanism. The sling drives the pulley to rotate, and the two ends of the sling are connected to two load-bearing members. When the load-bearing member at one end of the sling is at the designated high position, the load-bearing member at the other end is at the designated low position. After the high-position bearing member bears the weight material, it descends, and the sling drives the pulley to rotate so that the clutch of the first generator set is in an engaged state and drives the generator to generate electricity. When the bearing member descends to a designated low position to discharge the material, the other end bearing member of the sling rises to the designated high position and receives the material and then descends. The sling drives the pulley to rotate in reverse to make the clutch of the second generator set in an engaged state and drive the generator to generate electricity. The two load-bearing parts repeat up and down so that the two generator sets alternately generate power to achieve the function of bidirectional power generation.

Description

Bidirectional potential energy generating equipment and its power output device

The new model relates to a two-way potential energy generating device, in particular to a two-way potential energy generating device and its power output device which can convert the potential energy of gravity into rotational kinetic energy to provide generator power.

The current power generation methods of power generation equipment include nuclear power generation, thermal power generation, solar power generation, hydropower generation, and wind power generation. However, nuclear power generation and thermal power generation are prone to environmental problems. The power generation equipment of solar power, hydropower and wind power generation must be installed in specific geographical environment, and solar power, wind power generation is faced with natural weather factors such as sunshine, cloudy and sunny, wind direction or wind speed, and cannot continue to provide power to the power generation equipment and cause its power generation. Inefficient.

Therefore, one of the objectives of the present invention is to provide a bidirectional potential energy generating device that can overcome at least one of the shortcomings of the prior art.

Therefore, the two-way potential power generation equipment of the present invention includes a first generator set, a second generator set, and a power output device.

The power output device includes a support structure, a power output mechanism, a gravity supply mechanism, and an electric control mechanism. The support structure supports the first generator set and the second generator set. The power output mechanism is arranged on the bracket structure and connected between the first generator set and the second generator set and includes a rotating assembly capable of moving in a first rotating direction and a direction opposite to the first rotating assembly. When the rotating assembly rotates in a second rotating direction, the power output mechanism is configured to output power to the first generator set to drive it to generate electricity when the rotating assembly rotates in the first rotating direction. When the rotating assembly rotates in the second rotating direction, When the direction of rotation rotates, power is output to the second generator set to drive it to generate electricity. The gravity supply mechanism is arranged on the support structure and includes a sling for driving the rotation assembly to rotate, a first bearing member connected to one end of the sling, and a second bearing member connected to the other end of the sling , And a supply assembly for supplying a substance with weight, the first carrier and the second carrier can each be capable of receiving the substance supplied by the supply assembly at a first height position, and a gap is located The bottom of the first height position is used to move up and down between the second height position where the carried substance is discharged. The electronic control mechanism can selectively control the supply assembly to supply the substance to the first carrier or the second carrier.

In some embodiments, the first generator set includes a first generator, a first transmission assembly connected to the first generator, and a first transmission assembly connected to the rotating assembly and the first transmission assembly. Between the first clutch, the second generator set includes a second generator, a second transmission assembly connected to the second generator, and a second generator connected to the The second clutch between the rotating assembly and the second transmission assembly, the first clutch is arranged to be in an engaged state when the rotating assembly rotates in the first rotation direction so that the power can pass through the first clutch and The first transmission assembly is output to the first generator, and when the rotating assembly rotates in the second rotation direction, it is in a separated state so that the power cannot be output to the first clutch and the first transmission assembly The first generator and the second clutch are arranged to be in an engaged state when the rotating assembly rotates in the second rotation direction so that the power can be output to the second through the second clutch and the second transmission assembly A generator, and when the rotating assembly rotates in the first rotation direction, it is in a disconnected state so that the power cannot be output to the second generator through the second clutch and the second transmission assembly.

In some embodiments, the rotating assembly includes a rotating shaft, and a set of pulleys fixed on the rotating shaft for winding the sling, and the first clutch and the second clutch are arranged in opposite directions along the rotating shaft and each includes a set of pulleys. A ratchet wheel fixed to the rotating shaft, and a meshing unit for meshing with the ratchet wheel, the meshing unit of the first clutch and the meshing unit of the second clutch are respectively provided in the first transmission assembly and the second transmission Assembly.

In some embodiments, the power output mechanism further includes a brake assembly that can be controlled by the electronic control mechanism to brake the pulley.

In some embodiments, the substance supplied by the supply assembly is a liquid, and the first carrier and the second carrier each include a carrier box and a gate, and the carrier box is formed with an injecting material into the carrier box. Entrance, and one located below the entrance for A discharge port for discharging the substance. The gate can be pivotally connected in the carrying box to control the opening and closing of the discharge port. The support structure includes a first top column and a second top column. The first top column is used for The gate of the first bearing member at the second height position is pushed upward to rotate and open the discharge port, and the second pillar is used to push upward the gate of the first bearing member at the second height position. The gate of the two load-bearing members rotates and opens the discharge port.

In some embodiments, the substance supplied by the supply assembly is a liquid, the first carrier and the second carrier each form an inlet for the substance to be injected, and the supply assembly includes a storage for the substance A supply box connected to one side of the supply box for injecting the substance into the inlet of the first carrier, and a first supply tube connected to the other side of the supply box for the second carrier The inlet of the second supply pipe for injecting the substance, the electronic control mechanism includes a controller, a first valve arranged on the first supply pipe, and a second valve arranged on the second supply pipe, the control The device is electrically connected to the first valve and the second valve for controlling the opening and closing of the first valve and the second valve.

In some embodiments, the power take-off mechanism further includes a brake assembly for braking the rotating assembly, and the electronic control mechanism further includes a first liquid level sensor electrically connected to the controller , And a second liquid level height sensor electrically connected to the controller, the first liquid level height sensor being used for sensing through the entrance of the first carrier located at the first height position The height of the substance liquid level in the first carrier, and the second liquid level sensor is used to pass through the entrance of the second carrier located at the first height position to sense the level of the substance in the second carrier The height of the substance level, when the control When the controller controls the opening of the first valve to inject the substance into the first carrier or controls the opening of the second valve to inject the substance into the second carrier, the controller controls the brake assembly to the rotating assembly. When the substance injected into the first bearing member or the second bearing member reaches a preset value, the controller controls the first valve or the second valve to close and controls the brake assembly to rotate The assembly releases evil spirits.

In some embodiments, the first generator set includes a first generator, a first transmission assembly connected to the first generator, and a first transmission assembly connected to the rotating assembly and the first transmission assembly. Between the first clutch, the second generator set includes a second generator, a second transmission assembly connected to the second generator, and a second transmission assembly connected between the rotating assembly and the second transmission assembly The controller is also electrically connected to the first clutch and the second clutch for controlling the first clutch and the second clutch to change between an engaged state and a disengaged state, respectively. When the When the substance injected by the first carrier reaches the preset value, the controller controls the first clutch to switch to the engaged state and controls the second clutch to switch to the disengaged state. When the substance injected by the second carrier When the substance reaches the preset value, the controller controls the first clutch to switch to the disengaged state and controls the second clutch to switch to the engaged state.

In some embodiments, the supply assembly further includes a storage box disposed at the bottom end of the support structure for accumulating the substance discharged by the first carrier or the second carrier, a pump, and a storage box connected to A first recovery pipe between the accumulation tank and the pump, and a second recovery pipe connected between the pump and the supply tank, the pump can be controlled by the electronic control machine The structure controls to extract the substance in the storage tank through the first recovery pipe and return to the supply tank through the second recovery pipe.

In some embodiments, the support structure includes two spaced apart vertical rails, a top plate disposed at the tops of the vertical rails, and two guide wheels pivotally connected to the top plate and adjacent to the tops of the vertical rails. The first supporting member and the second supporting member are respectively slidably connected to the vertical guide rails, and the first generator set, the second generator set, the power output mechanism, the supply assembly and the electric control mechanism are arranged in The top plate and the guide wheels are used for winding the sling.

Therefore, another object of the present invention is to provide a power output device for bidirectional potential energy generating equipment that can overcome at least one of the disadvantages of the prior art.

Therefore, the power output device of the new two-way potential energy generating device includes a support structure, a power output mechanism, a gravity supply mechanism, and an electric control mechanism.

The power output mechanism is arranged on the support structure and includes a rotating assembly that can rotate in a first rotating direction and a second rotating direction opposite to the first rotating direction, and the power output mechanism is arranged to be The rotating assembly outputs power when rotating in the first rotating direction or the second rotating direction. The gravity supply mechanism is arranged on the support structure and includes a sling for driving the rotation assembly to rotate, a first bearing member connected to one end of the sling, and a second bearing member connected to the other end of the sling , And a supply assembly for supplying substances with weight, each of the first carrier and the second carrier can be at a first height to receive the substance supplied by the supply assembly And a gap is located below the first height position to move up and down between the second height position for discharging the carried substance. The electronic control mechanism can selectively control the supply assembly to supply the substance to the first carrier or the second carrier.

The present invention has at least the following effects: the power output device can continuously provide the power to the first generator set and the second generator set to make the first generator and the second generator run to generate electricity, thereby making The power generation equipment can continuously and stably generate power to improve power generation efficiency. In addition, because the material supplied by the supply assembly can be selected from liquid, sand, gravel or metal particles, etc., and the supply assembly can repeatedly recycle the material to use its weight to drive the first carrier and the The second bearing member moves to generate gravitational potential energy. Therefore, compared with the existing nuclear power generation and thermal power generation, there will be no environmental protection problems of waste and exhaust gas emission. Furthermore, the power generation equipment does not need to be installed in a specific geographical environment, which can improve the scope of application and the flexibility of use.

100: Two-way potential energy generation equipment

1: The first generator set

11: The first generator

12: The first transmission assembly

121: First gearbox

122: first drive shaft

123: The first output shaft

13: The first clutch

131, 231: Ratchet

132, 232: meshing unit

133, 233: Shell

134, 234: Pawl

135, 235: Shrapnel

2: The second generator set

21: second generator

22: The second transmission assembly

221: second gearbox

222: second drive shaft

223: second output shaft

23: second clutch

3: Power output device

4: Support structure

41: Vertical rail

411: guide groove

42: top plate

421: Board

422: main bracket

423: side bracket

43: guide wheel

44: The First Pillar

441, 451: horizontal column section

442, 452: Top column section

45: second top pillar

5: Power output mechanism

51: Rotating assembly

511: Hinge

512: pulley

513: groove

52: Brake assembly

521: Brake Pad

522: Actuation Unit

6: Gravity supply mechanism

61: Sling

62: The first carrier

620, 640: Carrying box

621, 641: Roller

622, 642: Gate

623, 643: Entrance

624, 644: Outlet

625, 645: door panels

626, 646: Waterproof gasket

627, 647: Shaft

628, 648: connecting part

629, 649: drive unit

630, 650: drive rod

631, 651: fixed pulley

632, 652: connecting rope

633, 653: Pivot link section

634, 654: Outer pole section

635, 655: inner pole section

636, 656: End

637, 657: Joint

64: second carrier

66: supply assembly

661: Supply Box

662: First Supply Pipe

663: Second Supply Pipe

664: Accumulation Box

665: Pump

666: The first recovery tube

667: Second Recovery Pipe

668: Accumulation Space

7: Electronic control mechanism

71: Controller

72: The first valve

73: Second valve

74: The first liquid level height sensor

75: The second liquid level height sensor

8: Substance

R1: first rotation direction

R2: second rotation direction

D1: first horizontal

D2: second horizontal

D3: Portrait

The other features and effects of the present invention will be clearly presented in the embodiments with reference to the drawings, in which: Figure 1 is a perspective view of the first embodiment of the new two-way potential energy power generation equipment, illustrating a first generator set, The configuration relationship between a second generator set and a power output device; Figure 2 is a side view of Figure 1; Figure 3 is an incomplete side view of the first embodiment; Figure 4 is a cross-sectional view taken along line IV-IV in Figure 3; Figure 5 is a cross-sectional view taken along line VV in Figure 3; 6 is an incomplete plan view of the first embodiment, illustrating that the two brake pads of a brake assembly are in a released state; FIG. 7 is an incomplete plan view of the first embodiment, illustrating the brake assembly Wait for the brake pads to be in a braking state; Figure 8 is an incomplete cross-sectional view of the first embodiment, illustrating a first bearing member at a first height position and a second bearing member at a second height position; Figure 9 It is an incomplete cross-sectional view of the first embodiment, illustrating that the first bearing member is at the second height position, and the second bearing member is at the first height position; FIG. 10 is the first embodiment of the bidirectional potential energy generating device of the present invention. An incomplete cross-sectional view of the second embodiment; FIG. 11 is an incomplete cross-sectional view of the second embodiment, illustrating the first carrier at the first height position and the second carrier at the second height position; 12 is an incomplete cross-sectional view of the second embodiment, illustrating that the first bearing member is at the first height position and the second bearing member is at the second height position; and FIG. 13 is the novel bidirectional potential energy power generation equipment An incomplete side view of the third embodiment.

Before the present invention is described in detail, it should be noted that in the following description, similar elements are represented by the same numbers.

Referring to FIG. 1, a first embodiment of the two-way potential energy generating device 100 of the present invention. The two-way potential energy generating device 100 is suitable to be installed on a required occasion to provide the power required for the operation of related electronic devices. For example, the two-way potential power generation equipment 100 can be installed at a specific height, indoor or outdoor elevated platforms, between high-rise buildings in residential communities, or under elevated land bridges, and the generated electricity can be directly supplied to factories, residential communities, public facilities, etc. Traffic lighting. The generated electricity can also provide electricity demand in neighboring areas, and is connected in parallel with the existing electricity supply system to expand the scope of electricity supply.

Referring to FIGS. 1 and 2, the bidirectional potential energy power generation equipment 100 includes a first generator set 1, a second generator set 2, and a power output device 3. For the convenience of subsequent description, a first transverse direction D1 of the bidirectional potential energy generating device 100 is defined, a second transverse direction D2 perpendicular to the first transverse direction D1, and a second transverse direction D2 perpendicular to the first transverse direction D1 and the second transverse direction D2 are defined. The vertical D3. Wherein, the first transverse direction D1 is taken as an example in a front and rear direction, the second transverse direction D2 is taken as an example in a left-right direction, and the longitudinal direction D3 is an up-down direction.

1 and 3, the first generator set 1 and the second generator set 2 have the same structure and can be driven to generate electricity for electrical connection to related electronic devices that require electricity. The first generator set 1 includes a first generator 11, a first transmission assembly 12 connected to the first generator 11, and a first transmission assembly 12 connected to the first transmission assembly 12 The first clutch 13. The first transmission assembly 12 includes a first transmission 121, a first transmission shaft 122 connected to one side of the first transmission 121, and a first transmission shaft 122 connected to the other side of the first transmission 121 and the first transmission shaft. The first output shaft 123 between the generator 11. The second generator set 2 and the first generator set 1 are arranged in the opposite direction along the first transverse direction D1. The second generator set 2 includes a second generator 21 and a second transmission connected to the second generator 21 Assembly 22, and a second clutch 23 connected to the second transmission assembly 22. The second transmission assembly 22 includes a second transmission 221, a second transmission shaft 222 connected to one side of the second transmission 221, and a second transmission shaft 222 connected to the other side of the second transmission 221 and the second transmission shaft 222. The second output shaft 223 between the generator 21. In the first embodiment, the first clutch 13 and the second clutch 23 are externally engaged ratchet and pawl clutches for example, and the first gearbox 121 and the second gearbox 221 are for example accelerators.

3, 4 and 5, the first clutch 13 and the second clutch 23 have the same structure. The first clutch 13 and the second clutch 23 each include a ratchet wheel 131, 231, and a gear for meshing with The meshing units 132, 232 of the ratchet wheels 131, 231. The engagement unit 132 of the first clutch 13 and the engagement unit 232 of the second clutch 23 are respectively disposed at the end of the first transmission shaft 122 of the first transmission assembly 12 and the first transmission assembly 22 of the second transmission assembly 22. Two end of the drive shaft 222. The engagement unit 132, 232 includes a housing 133, 233, a plurality of pawls 134, 234 pivotally connected to the housing 133, 233, and a plurality of elastic pieces 135, 235 provided in the housing 133, 233 . The housing 133 and the housing 233 are respectively fixedly disposed on the first transmission shaft 122 The end and the end of the second transmission shaft 222. The pawls 134 and 234 are used for meshing with the ratchet wheels 131 and 231 respectively. The elastic pieces 135 and 235 apply elastic force to the pawls 134 and 234 toward the ratchet wheels 131 and 231 respectively, so that the pawls 134 and 234 mesh with the ratchet wheels 131 and 231 respectively. Thereby, the first clutch 13 and the second clutch 23 can be maintained in an engaged state (as shown in FIGS. 4 and 5).

1 and 2, the power output device 3 includes a support structure 4, a power output mechanism 5, a gravity supply mechanism 6, and an electric control mechanism 7. The support structure 4 includes two vertical rails 41 arranged in the opposite direction along the second transverse direction D2 and spaced left and right, a top plate 42 arranged at the top of the vertical rails 41, two pivotally connected to the top plate 42 and respectively adjacent to the Equivalent to the guide wheel 43 at the top of the vertical guide rail 41, a first top post 44, and a second top post 45. Each of the vertical rails 41 extends along the longitudinal direction D3 and forms a guide groove 411 with an opening facing outward. The top plate 42 includes a plate body 421 arranged on the top of the vertical guide rails 41 for carrying the first generator set 1 and the second generator set 2, a main bracket 422 arranged on the top surface of the plate body 421, and two Two side brackets 423 are respectively provided on the left and right sides of the board 421. The first generator set 1 and the second generator set 2 are arranged on the top surface of the board 421 in opposite directions along the first transverse direction D1 and are respectively located on the front and rear sides of the main support 422. Each of the side brackets 423 is used to support the corresponding guide wheel 43 and be pivotally connected. The first top column 44 and the second top column 45 have the same structure and are arranged on the vertical guide rails 41 in the opposite direction along the second transverse direction D2. The first top column 44 and the second top column 45 each have a The horizontal column sections 441, 451 connected to the corresponding vertical rail 41 and protruding outside and adjacent to the bottom end thereof, and a T-shaped top column sections 442, 452 are connected to the ends of the horizontal column sections 441, 451. The horizontal column segments 441 and 451 extend along the second transverse direction D2.

Referring to FIGS. 1, 3, 4 and 5, the power output mechanism 5 is arranged on the support structure 4 and connected between the first generator set 1 and the second generator set 2. The power output mechanism 5 includes a rotating assembly 51 pivotally connected to the main bracket 422 rotatably, and a brake assembly 52. The rotating assembly 51 includes a rotating shaft 511 pivotally connected to the main bracket 422 and a set of pulleys 512 fixed to the rotating shaft 511. The axial direction of the rotating shaft 511 extends along the first transverse direction D1. The ratchet wheels 131 and 231 are sleeved on the rotating shaft 511 and are respectively adjacent to the two ends of the rotating shaft 511 so that the ratchet wheels 131 and 231 can be driven by the rotating shaft 511 to rotate. The outer peripheral surface of the pulley 512 is recessed radially inward to form a groove 513. The rotating assembly 51 can rotate along a first rotation direction R1 (as shown in FIG. 9) and a second rotation direction R2 (as shown in FIG. 8) opposite to the first rotation direction R1.

In the first embodiment, the first clutch 13 is set to be in the engaged state when the rotating assembly 51 rotates in the first rotation direction R1, so that the power generated when the rotating assembly 51 rotates can pass through the rotating assembly 51. The first clutch 13 and the first transmission assembly 12 are output to the first generator 11 to drive it to operate and generate electricity. The first clutch 13 is also set to be in a disengaged state where the ratchet wheel 131 can rotate relative to the pawls 134 when the rotating assembly 51 rotates along the second rotation direction R2, so that the rotating assembly 51 rotates when the rotating assembly 51 rotates. The generated power cannot be output to the first generator 11 through the first clutch 13 and the first transmission assembly 12. The second clutch 23 is set to When the component 51 rotates in the second rotation direction R2, it is in the engaged state, so that the power generated when the rotating assembly 51 rotates can be output to the second engine through the second clutch 23 and the second transmission assembly 22 The motor 21 drives its operation to generate electricity. The second clutch 23 is also set to be in a disengaged state where the ratchet wheel 231 can rotate relative to the pawls 234 when the rotating assembly 51 rotates in the first rotation direction R1, so that the rotating assembly 51 rotates when the rotating assembly 51 rotates. The generated power cannot be output to the second generator 21 through the second clutch 23 and the second transmission assembly 22.

Referring to Figures 3, 6 and 7, the brake assembly 52 includes two brake pads 521 movably sleeved on the shaft 511 and located on the opposite side of the pulley 512, and a brake pad 521 connected to one end of the brake pads 521 Actuation unit 522. The actuation unit 522 can be operated to actuate the brake pads 521 to switch between a brake release state (as shown in FIG. 6) and a brake state (as shown in FIG. 7). When the brake pads 521 are in the brake release state, the brake pads 521 are spaced apart from the opposite side of the pulley 512 by a certain distance, so that the pulley 512 can rotate. When the brake pads 521 are in the braking state, the brake pads 521 tightly contact the opposite side of the pulley 512 and generate friction therewith to prevent the pulley 512 from rotating.

Referring to Figures 1, 2 and 8, the gravity supply mechanism 6 is disposed on the support structure 4 and includes a sling 61 for driving the rotation assembly 51 to rotate, and a first load bearing connected to one end of the sling 61 The piece 62, a second supporting piece 64 connected to the other end of the sling 61, and a supply assembly 66 for supplying a substance 8 having a weight. The sling 61 It is accommodated in the groove 513 of the pulley 512 and is wound around the pulley 512 and the guide wheels 43, and two opposite ends of the sling 61 are located outside the vertical guide rails 41, respectively. The first supporting member 62 and the second supporting member 64 are arranged on the vertical rails 41 in the opposite direction along the second transverse direction D2, and are respectively slidably connected to the guide grooves 411 of the vertical rails 41. The first supporting member 62 and the second supporting member 64 can each be capable of receiving the substance 8 supplied by the supply assembly 66 at a first height position, and a gap is located below the first height position for carrying Move up and down between the second height position where the substance 8 is discharged. Wherein, when the first supporting member 62 is positioned at one of the first height position and the second height position, the second supporting member 64 is positioned at the other of the first height position and the second height position. One location. In the first embodiment, the difference between the first height position and the second height position is, for example, 5 meters.

In the first embodiment, the substance 8 is a liquid such as water as an example. The first carrier 62 and the second carrier 64 each include a carrier box 620, 640, a roller 621, 641, and a gate 622, 642. The carrying boxes 620 and 640 are formed with an inlet 623 and 643 for the substance 8 to be injected, and an outlet 624 and 644 for the substance 8 to be discharged under the inlet 623 and 643. The rollers 621, 641 are pivotally connected to the carrying boxes 620, 640 rotatably and slidably connected to the guide grooves 411 of the corresponding vertical rail 41, so that the first carrier 62 and the second The supporting member 64 can smoothly slide on the vertical guide rails 41 respectively. The gates 622 and 642 are pivotally connected to the carrying boxes 620 and 640 rotatably to control the opening and closing of the discharge ports 624 and 644. The gate The doors 622, 642 have a door panel 625, 645, and a waterproof gasket 626, 646 disposed on the bottom surface of the door panel 625, 645. The door panels 625 and 645 have shaft portions 627 and 647 pivotally connected to the carrying boxes 620 and 640. The waterproof gaskets 626 and 646 are made of elastic materials such as rubber or silicon, and are used to abut against the inner surface of the carrying boxes 620 and 640 and surround the outer periphery of the discharge ports 624 and 644. In this way, the substance 8 in the carrying boxes 620 and 640 is prevented from seeping out through the discharge ports 624 and 644.

When the first supporting member 62 moves down to the second height position, the top column section 442 of the first top column 44 will push up the gate 622 of the first supporting member 62 to rotate and open the The discharge port 624 enables the substance 8 in the first carrier 62 to be discharged downward through the discharge port 624. When the second supporting member 64 moves down to the second height position, the top column section 452 of the second top column 45 will push up the gate 642 of the second supporting member 64 to rotate and open The discharge port 644 enables the substance 8 in the second carrier 64 to be discharged downward through the discharge port 644.

The supply assembly 66 includes a supply box 661 arranged on the top surface of the plate body 421 of the top plate 42 and adjacent to the front end of the plate body 421 and storing the substance 8, and a supply box 661 connected to one side of the supply box 661 and extending to the A first supply tube 662 above the first supporting member 62, a second supply tube 663 connected to the other side of the supply box 661 and extending above the second supporting member 64, and a second supply tube 663 disposed at the bottom end of the vertical rails 41 The accumulation tank 664, a pump 665 located in front of the accumulation tank 664, a first recovery pipe 666 connected between the accumulation tank 664 and the pump 665, and a connection between the pump 665 and the supply tank 661 The second recovery pipe 667. The first supply pipe 662 is used to inject the substance 8 into the inlet 623 of the first carrier 62. The second supply pipe 663 is used to inject the substance 8 into the inlet 643 of the second carrier 64. The storage box 664 forms a storage space 668 with an upward opening for storing the substance 8 discharged from the first supporting member 62 and the second supporting member 64. When the pump 665 is running, the pump 665 extracts the substance 8 in the accumulation space 668 of the accumulation tank 664 through the first recovery pipe 666 and flows back to the supply tank 661 through the second recovery pipe 667, so that the supply The box 661 can continuously supply the substance 8 to the first supply pipe 662 or the second supply pipe 663. Thereby, only a predetermined volume of the substance 8 is stored in the supply box 661, and it can be reused repeatedly through the aforementioned supply and recovery methods.

The electric control mechanism 7 includes a controller 71 arranged on the top surface of the plate body 421 of the top plate 42, a first valve 72 arranged on the first supply pipe 662 to control its flow or blocking, and a set A second valve 73 for controlling or blocking the flow of the second supply pipe 663, a first liquid level sensor 74 disposed on the side of the plate 421 and above the first carrier 62, And a second liquid level sensor 75 disposed on the other side of the board 421 and above the second supporting member 64. The controller 71 is electrically connected to the actuation unit 522 of the brake assembly 52 to control the actuation unit 522 to actuate the brake pads 521 to switch between the brake release state and the brake state. The controller 71 is also electrically connected to the pump 665 to control the opening and closing of the pump 665. The controller 71 is also electrically connected to the first valve 72 and the second valve 73 for controlling the first valve 72 and the The opening and closing of the second valve 73 allows the electronic control mechanism 7 to selectively control the supply assembly 66 to supply the substance 8 to the first carrier 62 or the second carrier 64. The controller 71 is also electrically connected to the first liquid level height sensor 74 and the second liquid level height sensor 75. The first liquid level height sensor 74 is used for sensing the liquid level height of the substance 8 in the carrying box 620 through the inlet 623 of the first carrier 62 located at the first height position. The second liquid level sensor 75 is used for sensing the liquid level of the substance 8 in the carrying box 640 through the inlet 643 of the second carrier 64 located at the first height position.

The following is a detailed description of the operation mode of the two-way potential energy generating device 100: Referring to FIG. 1, FIG. 2, FIG. 7 and FIG. 8, when the first supporting member 62 is at the first height position, the second supporting member 64 bits are in this second height position. At this time, the first liquid level sensor 74 penetrates into the carrying box 620 through the inlet 623 of the first carrying member 62. The controller 71 controls the actuation unit 522 to actuate the brake pads 521 to change from the brake release state to the brake state, so as to prevent the rotating assembly 51 from rotating. Then, the controller 71 controls the first valve 72 to open, and the first valve 72 controls the first supply pipe 662 to be in a circulating state, so that the first supply pipe 662 injects the first supply pipe 662 into the inlet 623 of the first carrier 62 The substance 8 makes it flow into the carrying box 620. The second valve 73 remains closed.

When the first liquid level sensor 74 senses the When the liquid level of the substance 8 reaches a preset value, the first liquid level sensor 74 generates a sensing signal. When the controller 71 receives the sensing signal, it controls the first valve 72 to close, so that the first supply pipe 662 stops injecting the substance 8, and at the same time, the controller 71 controls the actuation unit 522 to actuate the brakes The piece 521 is transformed from the brake state to the brake release state.

Referring to Figure 1, Figure 6, Figure 8 and Figure 9, since the first supporting member 62 carries a predetermined weight of the substance 8 and the second supporting member 64 does not carry the substance 8, therefore, the first supporting member 62 The total weight of the substance 8 and the carried substance 8 will be greater than the weight of the second carrying member 64. At this time, the first carrier 62 moves down by gravity and pulls one end of the sling 61 so that the sling 61 drives the rotating assembly 51 to rotate in the first rotation direction R1, and the other end of the sling 61 will The second supporting member 64 is pulled upward.

When the first carrier 62 moves down to the position where the door panel 625 of the gate 622 contacts the top column section 442 of the first top column 44, the door panel 625 will be affected by the top column section of the first top column 44. 442 blocked. When the first supporting member 62 continues to move downward, the top column section 442 of the first top column 44 pushes the door panel 625 of the gate 622 upward to rotate and open the discharge port 624.

When the first carrier 62 moves down to the second height position shown in FIG. 9, the controller 71 controls the actuation unit 522 to actuate the brake pads 521 to change from the brake release state to the brake state. The top column section 442 of the first top column 44 penetrates into the carrying box 620 through the discharge port 624 and supports the gate 622 to keep it as shown in FIG. 9 The open state of the display. The substance 8 carried in the carrying box 620 will flow down into the accumulation space 668 of the accumulation box 664 through the discharge port 624, so that the carrying box 620 can discharge the substance 8. At the same time, the second carrier 64 moves up to the first height position shown in FIG. 9, and the second liquid level sensor 75 penetrates into the carrier box through the entrance 643 of the second carrier 64 Within 640.

The gravitational potential generated during the downward movement of the first supporting member 62 and the carried substance 8 from the first height position to the second height position can pull the sling 61 to drive the rotation The assembly 51 rotates, so that the rotating assembly 51 can convert the aforementioned gravitational potential energy into rotational kinetic energy. Thereby, the power generated by the rotation of the rotating assembly 51 can be output to the first generator 11 through the first clutch 13 and the first transmission assembly 12, so that the first generator 11 is operated to generate electricity.

1 and 9, after that, the controller 71 controls the second valve 73 to open, and the second valve 73 controls the second supply pipe 663 to be in a flow state, so that the second supply pipe 663 responds to the second carrier. The inlet 643 of 64 injects the substance 8 into the carrying box 640. When the second liquid level sensor 75 senses that the liquid level of the substance 8 in the carrying box 640 reaches the preset value, the second liquid level sensor 75 generates a sensing signal. When the controller 71 receives the sensing signal, it controls the second valve 73 to close, so that the second supply pipe 663 stops injecting the substance 8, and at the same time, the controller 71 controls the actuation unit 522 to actuate the brakes The piece 521 is transformed from the brake state to the brake release state. On the other hand, the controller 71 will start the pump 665 to run, so that the pump 665 The substance 8 accumulated in the accumulation space 668 of the accumulation tank 664 is extracted through the first recovery pipe 666 and returned to the supply tank 661 through the second recovery pipe 667.

1, 6, 8 and 9, because the second carrier 64 carries a predetermined weight of the substance 8, and the first carrier 62 does not carry the substance 8, therefore, the second carrier 64 The total weight of the substance 8 and the carried material 8 will be greater than the weight of the first carrying member 62. At this time, the second carrier 64 moves downward by gravity and pulls the other end of the sling 61 so that the sling 61 drives the rotating assembly 51 to rotate in the second rotation direction R2, and one end of the sling 61 will The first supporting member 62 is pulled upward.

When the second carrier 64 moves down to the position where the door panel 645 of the gate 642 contacts the top column section 452 of the second top column 45, the door panel 645 will be affected by the top column section of the second top column 45. 452 blocked. When the second supporting member 64 continues to move downward, the top column section 452 of the second top column 45 pushes the door plate 645 of the gate 642 upward to rotate and open the discharge port 644.

When the second carrier 64 moves down to the second height position shown in FIG. 8, the controller 71 controls the actuation unit 522 to actuate the brake pads 521 to change from the brake release state to the brake state. The top column section 452 of the second top column 45 penetrates into the carrying box 640 through the discharge port 644 and supports the gate 642 to maintain an open state as shown in FIG. 8. The substance 8 carried in the carrying box 640 will flow down into the accumulation space 668 of the accumulation box 664 through the discharge port 644, so that the carrying box 640 can discharge the substance 8. At the same time, the first carrier 62 moves up to the At the first height position, the first liquid level height sensor 74 penetrates into the carrying box 620 through the inlet 623 of the first carrier 62.

The gravitational potential generated during the downward movement of the second carrier 64 and the carried substance 8 from the first height position to the second height position can pull the sling 61 to drive the rotation The assembly 51 rotates, so that the rotating assembly 51 can convert the aforementioned gravitational potential energy into rotational kinetic energy. Thereby, the power generated by the rotation of the rotating assembly 51 can be output to the second generator 21 through the second clutch 23 and the second transmission assembly 22, so that the second generator 21 is operated to generate electricity.

By repeating the above-mentioned operation method, the power output device 3 can continuously provide the power to the first generator set 1 and the second generator set 2 to make the first generator 11 and the second generator 21 operate and generate electricity, Thereby, the power generation equipment 100 can continuously and stably generate power to improve the power generation efficiency.

It should be noted that, in another implementation aspect of the first embodiment, the substance 8 supplied by the supply assembly 66 may also be a solid with a weight, so as to be suitable for desert areas, water-deficient areas, and remote areas. Implement. The substance 8 may be a solid such as sand, crushed stone, or metal particles, for example. At this time, the first carrier 62 and the second carrier 64 can be made into a flat structure to carry the substance 8, and the supply assembly 66 can transport the substance 8 to the first carrier through, for example, a conveyor belt structure. The material 8 discharged from the first supporting member 62 or the second supporting member 64 is recovered for reuse.

10 and FIG. 11, the second embodiment of the two-way potential power generation equipment 100 of the present invention, the overall structure is roughly the same as the first embodiment, the difference lies in the structure of the first carrier 62 and the second carrier 64 .

In the second embodiment, the horizontal column section 441 of the first top column 44 and the horizontal column section 451 of the second top column 45 are respectively protruded from the front ends of the vertical guide rails 41 and extend along the first transverse direction D1 . The gates 622, 642 also have a connecting portion 628, 648 opposite to the shaft portion 627, 647. The connecting portion 628, 648 is an example of a protrusion protruding from one side of the door panel 625, 645. The first carrier 62 and the second carrier 64 each further include a transmission unit 629, 649 connected between the carrier box 620, 640 and the gate 622, 642. The transmission units 629 and 649 include a transmission rod 630 and 650, certain pulleys 631 and 651, and a connecting rope 632 and 652. The transmission rods 630, 650 have a pivotal rod section 633, 653 pivotally connected to the side plate of the carrier box 620, 640, and an outer side connected to one end of the pivotal rod section 633, 653 and located outside the carrier box 620, 640. The rod segments 634 and 654, and an inner rod segment 635, 655 connected to the other end of the pivotal rod segments 633, 653 and located in the carrying boxes 620, 640. The outer rod sections 634 and 654 have end portions 636 and 656 for pushing the top column section 442 of the first top column 44 or the top column section 452 of the second top column 45. The inner rod segments 635, 655 have a joint portion 637, 657 spaced apart from the pivotal rod segments 633, 653, and the joint portion 637, 657 is an example of a convex post. The fixed pulleys 631 and 651 are pivotally connected to the inner sides of the top plates of the carrying boxes 620 and 640 rotatably. The connecting ropes 632, 652 are wound around the fixed pulleys 631, 651 and the two ends are respectively connected Connected to the connecting parts 628 and 648 and the connecting parts 637 and 657.

10 and 11, when the first supporting member 62 and the second supporting member 64 are at the first height position, the transmission rods 630 and 650 are in a horizontal state.

When the first supporting member 62 moves down from the first height position to the second height position, the top column section 442 of the first top column 44 pushes up the end portion 636 of the outer rod section 634, so that The pivotal rod section 633 of the transmission rod 630 rotates relative to the carrying box 620 along the first rotation direction R1. During the rotation of the transmission rod 630, one end of the connecting rope 632 is pulled down through the inner rod section 635, so that the other end of the connecting rope 632 pulls up the connecting portion 628 to drive the shaft portion 627 of the gate 622 to rotate along the second rotation. Rotate in direction R2. In this way, the gate 622 opens the discharge port 624.

When the second supporting member 64 moves down from the first height position to the second height position, the top column section 452 of the second top column 45 pushes the end portion 656 of the outer rod section 654 upward, so that The pivotal rod section 653 of the transmission rod 650 rotates relative to the carrying box 640 along the second rotation direction R2. During the rotation of the transmission rod 650, one end of the connecting rope 652 is pulled down through the inner rod section 655, so that the other end of the connecting rope 652 pulls up the connecting portion 648 to drive the shaft portion 647 of the gate 642 to rotate along the first rotation. Rotate in direction R1. In this way, the gate 642 opens the discharge port 644.

Referring to FIG. 13, the overall structure of the third embodiment of the bidirectional potential energy generating device 100 of the present invention is substantially the same as that of the first embodiment, except for the structure of the first clutch 13 and the second clutch 23.

In the third embodiment, the first clutch 13 and the second clutch 23 are electronically controlled clutches as an example. The controller 71 of the electronic control mechanism 7 (as shown in FIG. 1) is electrically connected to the first clutch 13 and the second clutch 23, and is used to control the first clutch 13 and the second clutch 23 to be in the Change between the engaged state and the separated state. When the liquid level of the substance 8 injected by the first carrier 62 reaches the preset value, the controller 71 controls the first clutch 13 to switch to the engaged state and controls the second clutch 23 to switch to the disengaged state . When the liquid level of the substance 8 injected by the second carrier 64 reaches the preset value, the controller 71 controls the first clutch 13 to switch to the disengaged state and controls the second clutch 23 to switch to the engaged state .

In summary, the two-way potential power generation equipment 100 of each embodiment can continuously provide the power to the first generator set 1 and the second generator set 2 through the power output device 3 so that the first generator 11 and the second generator 21 operate to generate electricity, thereby enabling the power generating device 100 to continuously and stably generate electricity to improve the efficiency of power generation. In addition, since the substance 8 supplied by the supply assembly 66 can be selected from liquid, sand, gravel or metal particles, etc., and the supply assembly 66 can repeatedly recycle the substance 8 to use its weight to drive the first The supporting member 62 and the second supporting member 64 move to generate gravitational potential energy. Therefore, compared with the existing nuclear power generation and thermal power generation, there is no environmental protection problem of waste and exhaust gas emission. Furthermore, the power generation equipment 100 does not need to be installed in a specific geographical environment, which can increase the scope of the application and the flexibility of use, so it can indeed achieve the purpose of new cost.

However, the above are only examples of the present model. When the scope of implementation of the present model cannot be limited by this, all simple equivalent changes and modifications made in accordance with the scope of the patent application of the present model and the contents of the patent specification shall still belong to This new patent covers the scope.

100: Two-way potential energy generation equipment

1: The first generator set

11: The first generator

12: The first transmission assembly

13: The first clutch

2: The second generator set

21: second generator

22: The second transmission assembly

23: second clutch

3: Power output device

4: Support structure

41: Vertical rail

411: guide groove

42: top plate

421: Board

422: main bracket

423: side bracket

43: guide wheel

44: The First Pillar

441: horizontal column section

442: Top column section

45: second top pillar

5: Power output mechanism

52: Brake assembly

521: Brake Pad

522: Actuation Unit

6: Gravity supply mechanism

61: Sling

62: The first carrier

620: Carrying Box

623: entrance

64: second carrier

66: supply assembly

661: Supply Box

662: First Supply Pipe

663: Second Supply Pipe

664: Accumulation Box

665: Pump

666: The first recovery tube

667: Second Recovery Pipe

668: Accumulation Space

7: Electronic control mechanism

71: Controller

72: The first valve

73: Second valve

74: The first liquid level height sensor

75: The second liquid level height sensor

D1: first horizontal

D2: second horizontal

D3: Portrait

Claims (17)

A two-way potential energy power generation equipment, including: a first generator set; a second generator set; a power output device, including: a support structure, carrying the first generator set and the second generator set; a power output mechanism, It is arranged in the support structure and connected between the first generator set and the second generator set and includes a rotating assembly capable of moving along a first rotating direction and a first rotating direction opposite to the first rotating direction. Rotating in two directions of rotation, the power output mechanism is configured to output power to the first generator set to drive power generation when the rotating assembly rotates in the first direction of rotation, and when the rotating assembly rotates in the second direction of rotation Output power to the second generator set to drive it to generate electricity; a gravity supply mechanism is arranged on the support structure and includes a sling for driving the rotating assembly to rotate, and a first bearing member connected to one end of the sling , A second carrier connected to the other end of the sling, and a supply assembly for supplying substances with weight, the first carrier and the second carrier can each be capable of receiving the supply assembly The first height position of the supplied substance and the second height position where an interval is located below the first height position for discharging the carried substance to move up and down; and an electronic control mechanism that can selectively control The supply assembly supply The substance to the first carrier or the second carrier. The two-way potential energy generating device according to claim 1, wherein the first generator set includes a first generator, a first transmission assembly connected to the first generator, and a rotating assembly Between the first clutch and the first transmission assembly, the second generator set includes a second generator, a second transmission assembly connected to the second generator, and a second transmission assembly connected to the rotating assembly and The second clutch between the second transmission assembly, the first clutch is arranged to be in an engaged state when the rotating assembly rotates in the first rotation direction so that the power can pass through the first clutch and the first transmission The assembly is output to the first generator, and when the rotating assembly rotates in the second rotation direction, it is in a disconnected state so that the power cannot be output to the first generator through the first clutch and the first transmission assembly An electric motor, the second clutch is arranged to be in an engaged state when the rotating assembly rotates in the second rotation direction so that the power can be output to the second generator through the second clutch and the second transmission assembly, and When the rotating assembly rotates in the first rotating direction, it is in a disconnected state so that the power cannot be output to the second generator through the second clutch and the second transmission assembly. The two-way potential energy generating device according to claim 2, wherein the rotating assembly includes a rotating shaft and a set of pulleys fixed on the rotating shaft for winding the sling, and the first clutch and the second clutch are along the rotating shaft They are arranged in opposite directions and each include a set of ratchet wheels fixed to the rotating shaft and a meshing unit for meshing with the ratchet. The meshing unit of the first clutch and the meshing unit of the second clutch are respectively arranged on the first Transmission assembly and the Second transmission assembly. The two-way potential power generation equipment according to claim 3, wherein the power output mechanism further includes a brake assembly that can be controlled by the electronic control mechanism to brake the pulley. The bidirectional potential energy power generation device according to any one of claims 1 to 4, wherein the substance supplied by the supply assembly is a liquid, and the first carrier and the second carrier each include a carrier box, And a gate, the carrying box is formed with an inlet for the substance to be injected, and a discharge port located below the entrance for discharging the substance, and the gate is pivotally connected in the carrying box to control the opening of the discharge port. Closed, the support structure includes a first top post and a second top post, the first top post is used to push up the gate of the first carrier at the second height position to rotate and open The discharge port and the second top pillar are used for pushing upward the gate of the second bearing member located at the second height position to rotate and open the discharge port. The two-way potential energy power generation device according to claim 1, wherein the substance supplied by the supply assembly is a liquid, the first carrier and the second carrier each form an inlet for the substance to be injected, and the supply The assembly includes a supply box storing the substance, a first supply pipe connected to one side of the supply box for injecting the substance into the inlet of the first carrier, and a first supply pipe connected to the other side of the supply box A second supply pipe for injecting the substance into the inlet of the second carrier. The electric control mechanism includes a controller, a first valve set on the first supply pipe, and a second supply pipe. The second valve of the pipe, the controller is electrically connected to the first valve and the The second valve is used to control the opening and closing of the first valve and the second valve. The two-way potential power generation equipment according to claim 6, wherein the power output mechanism further includes a brake assembly for braking the rotating assembly, and the electronic control mechanism further includes an electrical connection to the controller A first liquid level height sensor, and a second liquid level height sensor electrically connected to the controller, the first liquid level height sensor being used to pass the first liquid level height sensor located at the first height position The inlet of the carrier is used to sense the height of the substance liquid level in the first carrier, and the second liquid level sensor is used to sense the inlet of the second carrier located at the first height position. Measure the level of the substance in the second carrier, when the controller controls the first valve to open to inject the substance into the first carrier or controls the second valve to open to inject the second carrier When the substance is used, the controller controls the brake assembly to brake the rotating assembly. When the substance injected into the first bearing member or the second bearing member reaches a preset value, the controller controls the first The valve or the second valve closes and controls the brake assembly to release the brake to the rotating assembly. The two-way potential power generation equipment according to claim 7, wherein the first generator set includes a first generator, a first transmission assembly connected to the first generator, and a rotating assembly Between the first clutch and the first transmission assembly, the second generator set includes a second generator, a second transmission assembly connected to the second generator, and a second transmission assembly connected to the rotating assembly and The second clutch between the second transmission assembly, the controller is also electrically connected to the first clutch and the second clutch for controlling the first clutch and the second clutch to be in an engaged state. State and a disengaged state, when the substance injected by the first carrier reaches the preset value, the controller controls the first clutch to switch to the engaged state and controls the second clutch to switch to the disengaged state State, when the substance injected by the second carrier reaches the preset value, the controller controls the first clutch to switch to the disengaged state and controls the second clutch to switch to the engaged state. The two-way potential energy power generation equipment according to claim 6, wherein the supply assembly further includes an accumulation disposed at the bottom end of the support structure for accumulating the substance discharged by the first carrier or the second carrier Tank, a pump, a first recovery pipe connected between the storage tank and the pump, and a second recovery pipe connected between the pump and the supply tank, the pump can be controlled by the electronic control mechanism The substance in the accumulation tank is extracted through the first recovery pipe and returned to the supply tank through the second recovery pipe. The bidirectional potential power generation equipment according to any one of claims 1 to 4, wherein the support structure includes two spaced apart vertical rails, a top plate arranged at the top of the vertical rails, and two pivotally connected to The top plate is respectively adjacent to the guide wheels at the top ends of the vertical rails, the first bearing member and the second bearing member are respectively slidably connected to the vertical rails, the first generator set, the second generator set, and the power The output mechanism, the supply assembly and the electric control mechanism are arranged on the top plate, and the guide wheels are used for winding the sling. A power output device for a two-way potential energy generating device, comprising: a support structure; a power output mechanism, arranged on the support structure and including a rotating assembly, the rotating assembly can be along a first rotation direction and a direction opposite to the First A rotation direction rotates in a second rotation direction, the power output mechanism is arranged to output power when the rotating assembly rotates in the first rotation direction or the second rotation direction; a gravity supply mechanism is arranged on the support structure and includes A sling for driving the rotating assembly to rotate, a first bearing member connected to one end of the sling, a second bearing member connected to the other end of the sling, and a material for supplying weight The supply assembly, the first carrier and the second carrier can each be capable of receiving the substance supplied by the supply assembly at a first height position, and a gap is located below the first height position for carrying Moves up and down between the second height position where the substance is discharged; and an electronic control mechanism can selectively control the supply assembly to supply the substance to the first carrier or the second carrier. The power output device of the bidirectional potential energy generating equipment according to claim 11, wherein the rotating assembly includes a rotating shaft and a set of pulleys fixed on the rotating shaft for the sling to be wound around, and the power output mechanism further includes an energy A brake assembly that is controlled by the electronic control mechanism to brake the pulley. The power output device of a bidirectional potential energy generating device according to any one of claims 11 to 12, wherein the substance supplied by the supply assembly is a liquid, and the first bearing member and the second bearing member each include A carrying box, and a gate. The carrying box is formed with an inlet for the substance to be injected, and an outlet located below the inlet for discharging the substance. The gate can be pivotally connected to the carrying box for control The outlet opening and closing, the support structure includes a first top pillar and a second top pillar, the first The top post is used to push upward the gate of the first carrier at the second height position to rotate and open the discharge port, and the second top post is used to push upward the gate at the second height position Of the gate of the second carrier to rotate and open the outlet. The power output device of the two-way potential power generation equipment according to claim 11, wherein the substance supplied by the supply assembly is a liquid, and the first carrier and the second carrier are each formed with an injection device for the substance Inlet, the supply assembly includes a supply box storing the substance, a first supply pipe connected to one side of the supply box for injecting the substance into the inlet of the first carrier, and a first supply pipe connected to the supply The other side of the box is used to inject the substance into the second supply pipe of the second carrier. The electric control mechanism includes a controller, a first valve arranged on the first supply pipe, and a second supply pipe arranged on the first supply pipe. The second valve of the second supply pipe is electrically connected to the first valve and the second valve, and the controller is used to control the opening and closing of the first valve and the second valve. The power output device of the bidirectional potential energy generating device according to claim 14, wherein the power output mechanism further includes a brake assembly for braking the rotating assembly, and the electronic control mechanism further includes an electrical connection to A first liquid level height sensor of the controller, and a second liquid level height sensor electrically connected to the controller, and the first liquid level height sensor is used to pass through the first height position The entrance of the first carrier is used to sense the height of the substance liquid level in the first carrier, and the second liquid level sensor is used to pass the second carrier located at the first height position The inlet is used to sense the height of the substance liquid level in the second carrier, when When the controller controls the opening of the first valve to inject the substance into the first carrier or controls the opening of the second valve to inject the substance into the second carrier, the controller controls the rotation of the brake assembly When the substance injected into the first bearing member or the second bearing member reaches a preset value, the controller controls the first valve or the second valve to close and controls the brake assembly to The revolving assembly releases the evil spirit. The power output device of a two-way potential energy generating device according to claim 14, wherein the supply assembly further includes a bottom end of the support structure for accumulating the discharge of the first bearing member or the second bearing member The storage tank of the substance, a pump, a first recovery pipe connected between the storage tank and the pump, and a second recovery pipe connected between the pump and the supply tank, the pump can be powered by the electric The control mechanism controls to extract the substance in the accumulation tank through the first recovery pipe and return to the supply tank through the second recovery pipe. The power output device of a bidirectional potential energy generating device according to any one of claims 11 to 12, wherein the support structure includes two spaced apart vertical rails, a top plate arranged at the top of the vertical rails, and two Guide wheels pivotally connected to the top plate and respectively adjacent to the top ends of the vertical rails, the first bearing member and the second bearing member are respectively slidably connected to the vertical rails, the power output mechanism, the supply assembly and The electric control mechanism is arranged on the top plate, and the guide wheels are used for winding the sling.

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