WO2024138771A1 - Multi-combination low-noise cleaning type power generation device and power generation system - Google Patents

Abstract

The present application relates to the technical field of power generation apparatuses, and provides a multi-combination low-noise cleaning type power generation device and a power generation system. The power generation device comprises a frame, a wind power impeller, a high-pressure gas cylinder, an air compressor, a booster valve, an air pressure regulating valve, a manual switch and a generator, wherein a main shaft is rotatably arranged in the frame, the wind power impeller is rotatably arranged on the main shaft, a multi-stage acceleration assembly is arranged in the frame, one end of the multi-stage acceleration assembly is in transmission connection with the main shaft, and the other end of the multi-stage acceleration assembly is in transmission connection with an input end of the generator. The power generation device further comprises a photovoltaic module, a first auxiliary driving assembly and a second auxiliary driving assembly, wherein the first auxiliary driving assembly is configured to drive the main shaft to rotate, the first auxiliary driving assembly comprises an auxiliary electric motor, the auxiliary electric motor is arranged in the frame, an output shaft of the auxiliary electric motor is in transmission connection with the main shaft, and an output end of a storage battery is connected to the auxiliary electric motor. The present application has the effects of reducing energy consumption and achieving energy conservation and environmental protection.

Description

A multi-combination low-noise clean power generation device and power generation system Technical Field

The present application relates to the technical field of power generation equipment, and in particular to a low-noise, clean power generation device and a power generation system.

Background technique

Electricity is a widely used energy source in people's lives. When working in a power outage or in an area without power supply in the wild, a generator is needed. Existing civilian generators generally use diesel generators. This type of power generation equipment converts the heat energy of diesel combustion into electrical energy. However, this type of generator has obvious defects. It makes a lot of noise during operation, and the exhaust gas generated by diesel combustion will also pollute the environment.

A Chinese patent with authorization announcement number CN202020872163X discloses a low-noise and clean power generation device, including a lightweight frame, a high-pressure gas tank, a high-pressure nozzle, a wind impeller, a multi-stage acceleration assembly and a generator body. The wind impeller is rotatably arranged in the lightweight frame, and the multi-stage family assembly is arranged in the lightweight frame. One end of the multi-stage acceleration assembly is connected to the wind impeller, and the other end is connected to the input shaft of the generator body. One end of the high-pressure nozzle is connected to the high-pressure gas tank, and the other end is arranged above the wind impeller. In actual use, the high-pressure gas tank is opened, and the high-pressure gas is ejected through the high-pressure nozzle, driving the wind impeller to rotate, thereby driving the multi-stage acceleration assembly to operate, and finally driving the input shaft of the generator to rotate, so as to achieve the purpose of power generation.

However, the inventors believe that the above-mentioned related technologies have the following defects. When the gas pressure in the high-pressure gas tank is insufficient, it is necessary to manually connect the power and start the air compressor to replenish the high-pressure gas in the high-pressure gas pipe. This brings great restrictions to the use of the device. During long-term use, manual nodes are required, which seriously affects the convenience of the device during use.

Summary of the invention

In order to solve the above technical problems, the present application provides a low-noise and clean power generation device and a power generation system.

In the first aspect, the present application provides a low-noise clean power generation device, which adopts the following technical solution:

A multi-combination low-noise clean power generation device, including a frame, a wind impeller, a high-pressure gas tank, an air compressor, a boost valve, an air pressure regulating valve, a manual switch and a generator, wherein a main shaft is rotatably arranged in the frame, and the wind impeller is rotatably arranged on the main shaft. A multi-stage acceleration component is arranged in the frame, and one end of the multi-stage acceleration component is transmission-connected to the main shaft, and the other end is transmission-connected to the input end of the generator; it also includes a photovoltaic component, a first auxiliary drive component and a second auxiliary drive component; the first auxiliary drive component is used to drive the main shaft to rotate, and the first auxiliary drive component includes an auxiliary motor, the auxiliary motor is arranged in the frame, and the output shaft of the auxiliary motor is transmission-connected to the main shaft.

Optionally, the multi-stage acceleration assembly includes a first transmission rod, a second transmission rod and a third transmission rod, wherein the first transmission rod, the second transmission rod and the third transmission rod are all rotatably arranged in a frame, one end of the first transmission rod is transmission connected to the main shaft, and the other end is transmission connected to the second transmission rod through a first acceleration gear set, an end of the second transmission rod away from the first transmission rod is transmission connected to the third transmission rod through a second acceleration gear set, and an end of the third transmission rod away from the second transmission rod is transmission connected to the input end of the generator through an acceleration pulley set.

Optionally, a plurality of partitions are provided in the frame, and the plurality of partitions divide the interior of the frame into a plurality of independent chambers, wherein the independent chambers include a main shaft chamber, a first transmission chamber, a second transmission chamber, a third transmission chamber, a power generation chamber, and a plurality of acceleration chambers for accommodating acceleration wheel sets, and the first transmission chamber and the third transmission chamber are both provided with magnet power assemblies.

Optionally, the second auxiliary drive assembly includes a mounting frame, an auxiliary drive shaft and an auxiliary drive impeller, the mounting frame is detachably connected to the frame, the auxiliary drive shaft is rotatably set on the mounting frame, the auxiliary drive impeller is set on the auxiliary drive shaft, and the auxiliary drive shaft is transmission-connected to the main shaft.

Optionally, the second auxiliary drive component includes a first power shaft and a wind input component, one end of the first power shaft is transmission connected to the main shaft, and the other end is transmission connected to the input end of the wind input component; the wind input component includes a first mounting frame and a wind impeller, the first mounting frame is rotatably provided with a first mounting shaft, the wind impeller is rotatably provided on the first mounting shaft, and the first mounting shaft is transmission connected to the first power shaft.

Optionally, a mounting groove is provided on the first mounting shaft, and a plurality of the mounting grooves are evenly arranged along the length direction of the first mounting shaft. A mounting ring is rotatably sleeved in each of the mounting grooves, and the wind impeller is fixedly connected to the mounting ring.

Optionally, a first latch tooth is provided in the mounting groove, a second latch tooth matched with the first latch tooth is provided on the mounting ring, the second latch tooth is rotationally connected to the mounting ring, and an elastic member is provided on the mounting ring, and the elastic member is used to drive the second latch tooth to deflect in a direction away from the mounting ring.

Optionally, the second auxiliary power drive assembly includes a second power shaft and a hydraulic input assembly, one end of the second power shaft is transmission connected to the main shaft, and the other end is transmission connected to the input end of the hydraulic input assembly; the hydraulic input assembly includes a second mounting frame and a hydraulic impeller, the second mounting frame is rotatably provided with a second mounting shaft, the hydraulic impeller is set on the second mounting shaft, and the second mounting shaft is transmission connected to the second power shaft.

Optionally, there are multiple hydraulic impellers, and the multiple hydraulic impellers are arranged in sequence along the length direction of the second mounting axis, a water tank is arranged on the second mounting frame, a water reservoir is arranged on the second mounting frame, the water reservoir is arranged below the hydraulic impeller, a water pump is arranged on the second mounting frame, a return pipe is arranged on the second mounting frame, one end of the return pipe is connected to the water reservoir, and the other end is connected to the water tank, the water pump is connected to the return pipe, and the water tank is connected to an outlet pipe, and the end of the outlet pipe away from the water tank is arranged above the hydraulic impeller.

Optionally, a gearbox is provided at one end of the second mounting shaft close to the second power shaft, the second mounting shaft is drivingly connected to the input end of the gearbox, and a belt drive assembly is drivingly connected between the output end of the gearbox and the second power shaft.

Optionally, the water outlet pipe is provided with a manual valve for opening and closing the water outlet pipe, the water outlet pipe is provided with a booster pump, and the second mounting frame is provided with a water inlet along the length direction of the second mounting axis.

Optionally, the magnet power assembly includes a mounting rod, a magnetic member and a circumferential magnetic ring magnet, the first transmission rod and the third transmission rod are both sleeved with a circumferential magnetic ring magnet, the mounting rod is vertically arranged in the first transmission chamber and the third transmission chamber, the magnetic member is arranged at one end of the mounting rod close to the circumferential magnetic ring magnet, and the first transmission chamber and the third transmission chamber are both provided with an adjustment assembly for adjusting the distance between the circumferential magnetic exchange magnet and the magnetic member.

Optionally, a plurality of mounting rods are provided in the first transmission chamber and/or the third transmission chamber, and the plurality of mounting rods are arranged along the circumference of the first transmission rod and/or the third transmission rod, and a magnetic member is provided at the end of each mounting rod.

Optionally, at least one group of wind input components is provided, and the power output end of each group of wind input components is transmission-connected to the first power shaft.

Optionally, the hydraulic input assembly is provided with at least one group, and the power output end of each group of the hydraulic input assembly is connected to the second power shaft in a transmission manner.

In a second aspect, the present application provides a power generation system, which adopts the following technical solution:

A power generation system includes a power generation device as described above, and also includes a control system and an electric energy conversion system, wherein the electric energy conversion system is used to convert the electric energy generated by the power generation device, the control system is electrically connected to the electric energy conversion system, and the control system is electrically connected to the power generation device.

Optionally, the power generation device is provided in multiple groups, and the power output ends of the multiple groups of power generation devices are electrically connected.

In summary, this application includes the following beneficial technical effects:

In actual use, the photovoltaic components absorb solar energy and convert it into electrical energy. Subsequently, the electrical energy can be input into the auxiliary motor of the first auxiliary drive component, the air compressor and the rotating motor of the rotating component through the control system, so as to realize the power supply to the auxiliary motor, the air compressor and the rotating motor. The electrical energy can also be stored in the battery. When the gas pressure in the high-pressure gas tank is lower than a certain pressure threshold, the control system controls the battery to output electrical energy or the solar panel to directly output the converted electrical energy to power the air compressor. After the air compressor is started to compress the air into high-pressure gas, the air is input into the high-pressure gas tank to realize the replenishment of the high-pressure gas in the high-pressure gas tank. After the air pressure in the high-pressure gas tank reaches the preset pressure threshold, the air compressor can be shut down.

At the same time, the solar energy is converted by the solar panel, and the converted electric energy or the battery is used to power the auxiliary motor, which drives the main shaft to rotate. In the process of replenishing the gas in the high-pressure gas tank, the main shaft can still be guaranteed to have a sufficient rotation speed to ensure that the generator can generate electricity normally, thereby improving the reliability of the device during use. At the same time, by driving the main shaft with the auxiliary motor, the rotation speed of the main shaft can be increased to a certain extent, thereby effectively improving the power generation effect and power generation of the generator, thereby forming a secondary utilization and recycling of energy;

In addition, in actual use, the main shaft can be driven by wind or water power to rotate. When the high-pressure gas in the high-pressure gas tank is insufficient, the main shaft can still be driven to rotate to generate electricity. Different numbers of wind input components or water input components can be set according to different locations, so as to cope with more types of terrain. On this basis, the power generation device, control system and power conversion system constitute a power generation system. According to different geographical locations, one or more groups of power generation devices can be selected for networking and integration, which significantly improves the scope of application of the device and greatly reduces the restrictions on power generation requirements. It can make full use of various natural clean energy such as wind, water and solar energy to generate electricity, which not only improves the overall practicality of the device, but also reduces noise during the power generation process, and does not generate wastewater and exhaust gas, and has good environmental protection and cleanliness.

During the rotation of the first transmission rod and the third transmission rod, the distance between the magnetic part and the surrounding magnetic ring magnets is adjusted by adjusting the distance between the magnetic part and the surrounding magnetic ring magnets through the adjustment component, so that the magnetic attraction between the mounting rod and the first transmission rod and the third transmission rod can be adjusted, so that the rotation speed of the first transmission rod and the third transmission rod can be adjusted within a certain range. When the rotation speed of the first transmission rod and the third transmission rod is slow, the distance between the magnetic part and the surrounding magnetic ring magnets is increased. When the rotation speed of the first transmission rod and the third transmission rod is fast, the distance between the magnetic part and the surrounding magnetic ring magnets is reduced. Through adjustment, the generator can maintain the required stable rotation speed, making power generation more stable and reliable.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings required for use in the embodiments will be briefly introduced below. It should be understood that the following drawings only show certain embodiments of the present application and therefore should not be regarded as limiting the scope. For ordinary technicians in this field, other related drawings can be obtained based on these drawings without paying creative work.

FIG1 is a schematic diagram of the overall structure of an embodiment of the present application;

FIG2 is a schematic diagram of the internal structure of the framework of an embodiment of the present application;

FIG3 is a schematic structural diagram of an implementation manner of a second auxiliary drive assembly according to an embodiment of the present application;

FIG4 is a schematic structural diagram of a wind-driven assembly according to an embodiment of the present application;

FIG5 is a schematic diagram of an exploded structure of a mounting ring according to an embodiment of the present application;

FIG6 is a cross-sectional view of a mounting ring according to an embodiment of the present application;

FIG7 is a schematic structural diagram of another implementation of the second auxiliary drive assembly of the embodiment of the present application;

FIG8 is a schematic structural diagram of a hydraulic drive assembly according to an embodiment of the present application;

FIG9 is a schematic diagram of the structure of a photovoltaic module according to an embodiment of the present application;

FIG. 10 is a schematic diagram of the workflow of an embodiment of the present application.

Icons: 1. Frame; 11. Auxiliary impeller; 12. High-pressure gas tank; 13. Air compressor; 14. Generator; 15. Main shaft; 16. Artificial inflation interface; 17. Automatic inflation interface; 18. Air pressure display gauge; 19. Drain pipe; 191. First solenoid valve; 192. Jet pipe; 193. Nozzle; 194. Second solenoid valve; 195. Air pressure safety valve; 196. Manual switch; 197. Air pressure regulating valve; 198. Booster valve; 2. Photovoltaic module; 21. Photovoltaic panel; 22. Battery; 23. Mounting plate; 24. Rotating assembly; 241, connecting shaft; 242, driving gear; 243, driven gear; 244, rotating motor; 3, first auxiliary driving assembly; 4, second auxiliary driving assembly; 41, mounting frame; 42, auxiliary driving shaft; 43, auxiliary driving impeller; 44, first power shaft; 45, wind input assembly; 451, first mounting frame; 452, wind impeller; 453, first mounting shaft; 454, mounting groove; 455, mounting ring; 456, first latching tooth; 457, second latching tooth; 458, elastic member; 459, rotating shaft; 46, second power shaft; 47, hydraulic input assembly; 471, second mounting frame; 472, hydraulic impeller; 473, second mounting shaft; 474, water tank; 475, water reservoir; 476, water pump; 477, water outlet pipe; 478, manual valve; 47 9. Booster pump; 48. Gearbox; 481. Belt drive assembly; 482. Bevel gear set; 5. Multi-stage acceleration assembly; 51. First transmission rod; 52. Second transmission rod; 53. Third transmission rod; 531. Flywheel; 54. First acceleration gear set; 55. Second acceleration gear set; 56. Acceleration pulley set; 6. Partition; 61. Spindle chamber; 62. First transmission chamber; 63. Second transmission chamber; 64. Third transmission chamber; 65. Power generation chamber; 66. Acceleration chamber; 67. Revolution counter; 68. Support frame; 7. Magnet power assembly; 71. Mounting rod; 72. Magnetic part; 73. Circumferential magnetic ring magnet; 74. Adjustment assembly; 8. Control system; 81. Electric energy conversion system; 82. Electricity system; 9. Speed limit assembly; 91. Vertical rod; 92. Magnetic block; 93. Iron ring.

Detailed ways

In order to make the purpose, technical solution and advantages of the embodiments of the present application clearer, the technical solution in the embodiments of the present application will be clearly and completely described below in conjunction with the drawings in the embodiments of the present application. Obviously, the described embodiments are part of the embodiments of the present application, rather than all the embodiments. The components of the embodiments of the present application described and shown in the drawings here can be arranged and designed in various different configurations.

The present application is further described in detail below in conjunction with Figures 1-10.

Example

In a first aspect, an embodiment of the present application discloses a multi-combination low-noise clean power generation device.

1 and 2, a multi-combination low-noise clean power generation device includes a frame 1, an auxiliary impeller 11, a high-pressure gas tank 12, an air compressor 13, a boost valve 198, an air pressure regulating valve 197, a manual switch 196, a generator 14, a photovoltaic component 2, a first auxiliary drive component 3 and a second auxiliary drive component 4. A main shaft 15 is rotatably arranged in the frame 1, and a wind impeller 452 is rotatably arranged on the main shaft 15. A multi-stage acceleration component 5 is arranged in the frame 1, and one end of the multi-stage acceleration component 5 is transmission-connected to the main shaft, and the other end is transmission-connected to the input end of the generator 14.

1 and 2 , the high-pressure gas tank 12 is provided with a manual inflation interface 16 and an automatic inflation interface 17 , and the high-pressure gas tank 12 is provided with an air pressure display gauge 18 , which can display the air pressure in the high-pressure gas tank 12 in real time, so as to facilitate timely replenishment of the high-pressure gas in the high-pressure gas tank 12 .

1 and 2 , the high-pressure gas tank 12 is connected to a drain pipe 19 , and the drain pipe 19 is provided with a first solenoid valve 191 for opening and closing the drain pipe 19 .

1 and 2 , the high-pressure gas tank 12 is connected to a jet pipe 192 , the end of the jet pipe 192 is connected to a nozzle 193 , the nozzle 193 is located above the wind impeller 452 , and a second solenoid valve 194 for opening and closing the jet pipe 192 is provided on the jet pipe 192 .

1 and 2 , an air pressure safety valve 195 is provided on the high-pressure gas tank 12 . When the air pressure in the high-pressure gas tank 12 is high, the air pressure safety valve 195 automatically opens to ensure the safety and reliability of the device during use.

As an embodiment of the present application, referring to Figure 2, the first auxiliary drive assembly 3 is used to drive the main shaft to rotate. The first auxiliary drive assembly 3 includes an auxiliary motor, which is arranged in the frame 1. The output shaft of the auxiliary motor is transmission-connected to the main shaft, and the output end of the battery 22 is connected to the auxiliary motor.

In actual use, the auxiliary motor is used to assist in accelerating the main shaft 15, thereby ensuring that the speed of the main shaft 15 and the input end of the generator 14 is within a reasonable speed range, further improving the reliability and stability of the generator 14 during the power generation process.

2 , the multi-stage acceleration assembly 5 includes a first transmission rod 51, a second transmission rod 52 and a third transmission rod 53. The first transmission rod 51, the second transmission rod 52 and the third transmission rod 53 are all rotatably arranged in the frame 1. One end of the first transmission rod 51 is transmission-connected to the main shaft, and the other end is transmission-connected to the second transmission rod 52 through a first acceleration gear set 54. One end of the second transmission rod 52 away from the first transmission rod 51 is transmission-connected to the third transmission rod 53 through a second acceleration gear set 55. One end of the third transmission rod 53 away from the second transmission rod 52 is transmission-connected to the input end of the generator 14 through an acceleration pulley set 56. A flywheel 531 is coaxially fixedly arranged on the third transmission rod 53, which can absorb and preserve the rotation amount of the third transmission rod 53 to a certain extent.

Referring to Figure 2, a plurality of partitions 6 are arranged in the frame 1, and the plurality of partitions 6 divide the interior of the frame 1 into a plurality of independent chambers. The independent chambers include a main shaft chamber 61, a first transmission chamber 62, a second transmission chamber 63, a third transmission chamber 64, a power generation chamber 65, and a plurality of acceleration chambers 66 for accommodating acceleration wheel sets. A magnet power assembly 7 is arranged in the first transmission chamber 62 and the third transmission chamber 64.

2 , the magnet power assembly 7 includes a mounting rod 71, a magnetic member 72 and a peripheral magnetic ring magnet 73. The first transmission rod 51 and the third transmission rod 53 are both sleeved with a peripheral magnetic ring magnet 73. The mounting rod 71 is vertically arranged in the first transmission chamber 62 and the third transmission chamber 64. The magnetic member 72 is arranged at one end of the mounting rod 71 close to the peripheral magnetic ring magnet 73. The first transmission chamber 62 and the third transmission chamber 64 are both provided with an adjustment assembly 74 for adjusting the distance between the peripheral magnetic exchange magnet and the magnetic member 72.

2 , as an embodiment of the present application, the adjustment assembly 74 is configured as an adjustment bracket, the adjustment bracket is fixedly disposed in the frame 1 , and the mounting rod 71 is fixedly connected to the piston rod of the adjustment cylinder.

During the rotation of the first transmission rod 51 and the third transmission rod 53, by adjusting the distance between the magnetic member 72 and the surrounding magnetic ring magnets 73, the rotation speed of the first transmission rod 51 and the third transmission rod 53 can be adjusted within a certain range. When the rotation speed of the first transmission rod 51 and the third transmission rod 53 is slow, the optimal working distance position is adjusted between the magnetic member 72 and the surrounding magnetic ring magnets 73. Through adjustment, the generator 14 can maintain the required stable rotation speed, making power generation more stable and reliable.

In addition, referring to Figure 2, a revolution counter 67 is provided in the frame 1, and the revolution counter 67 is used to detect the rotation speed of the third transmission rod 53 and record the number of rotations of the third transmission rod 53. A support frame 68 is provided in the frame 1, and the revolution counter 67 is fixedly arranged on the top of the support frame 68.

In actual use, the rotation speed of the third transmission rod 53 is detected in real time by the revolution counter 67. When the rotation speed of the third transmission rod 53 is higher than the preset speed, the revolution counter 67 controls the closing or partial closing of the first electromagnetic valve 191 and the second electromagnetic valve 194, and closes the first auxiliary drive assembly 3 and the second auxiliary drive assembly 4 or reduces the power of the first auxiliary drive assembly 3 and the second auxiliary drive assembly 4, so as to effectively reduce the rotation speed of the third transmission rod 53; when the rotation speed of the third transmission rod 53 is lower than the preset speed, the revolution counter 67 controls the further opening of the first electromagnetic valve 191 and the second electromagnetic valve 194, and increases the power of the first auxiliary drive assembly 3 and the second auxiliary drive assembly 4, so as to effectively increase the rotation speed of the third transmission rod 53. By controlling the rotation speed of the third transmission rod 53 within a suitable speed range, the speed of the input end of the generator 14 can be ensured to be within a reasonable range, so as to ensure that the generator 14 can perform power generation more stably and reliably in actual use.

The rotation speed range of the third transmission rod 53 is set differently according to different models of the generator 14 .

2 , a speed limiting component 9 is provided in the third transmission chamber 64, and the speed limiting component 9 is used to limit the rotation speed of the third transmission rod 53. As an implementation mode of the present application, the speed limiting component 9 includes a vertical rod 91, a magnetic block 92, and an iron ring 93. The vertical rod 91 is installed inside the third transmission chamber 64 along the vertical direction, the magnetic block 92 is installed on the top of the vertical rod 91, and the iron ring 93 is coaxially fixedly sleeved on the third transmission rod 53. When the rotation speed of the third transmission rod 53 is faster, it drives the vertical rod 91 to move upward, and then drives the magnetic block 92 to move toward the iron ring 93. When the distance between the magnetic block 92 and the iron ring 93 is reduced, the rotation speed of the third transmission rod 53 can be limited to a certain extent, thereby ensuring that the rotation speed of the input end of the generator 14 is within a reasonable range, thereby ensuring that in actual use, the generator 14 can perform power generation operations more stably and reliably.

As another embodiment of the present application, a plurality of auxiliary motors are provided, and the plurality of auxiliary motors are arranged along the circumferential direction of the main shaft.

As another embodiment of the present application, a plurality of auxiliary motors are provided, and the plurality of auxiliary motors are arranged in sequence along the length direction of the main shaft.

As an embodiment of the present application, referring to Figure 2, the second auxiliary drive component 4 includes a mounting frame 41, an auxiliary drive shaft 42 and an auxiliary drive impeller 43. The mounting frame 41 is detachably connected to the frame 1, the auxiliary drive shaft 42 is rotatably set on the mounting frame 41, the auxiliary drive impeller 43 is set on the auxiliary drive shaft 42, and the auxiliary drive shaft 42 is transmission connected to the main shaft.

In actual use, the auxiliary driving impeller 43 can be driven to rotate by external wind or water power, thereby driving the auxiliary driving shaft 42 to rotate, and driving the main shaft to rotate, thereby achieving the effect of driving the generator 14 to generate electricity.

As another embodiment of the present application, referring to Figures 3 and 4, the second auxiliary drive assembly 4 includes a first power shaft 44 and a wind input assembly 45, one end of the first power shaft 44 is transmission connected to the main shaft, and the other end is transmission connected to the input end of the wind input assembly 45.

4 and 5 , the wind input assembly 45 includes a first mounting frame 451 and a wind impeller 452 . The first mounting frame 451 is rotatably provided with a first mounting shaft 453 . The wind impeller 452 is rotatably provided on the first mounting shaft 453 . The first mounting shaft 453 is transmission-connected to the first power shaft 44 .

4 and 5 , a mounting groove 454 is formed on the first mounting shaft 453 , and a plurality of mounting grooves 454 are evenly arranged along the length direction of the first mounting shaft 453 . A mounting ring 455 is rotatably sleeved in each mounting groove 454 , and the wind impeller 452 is fixedly connected to the mounting ring 455 .

5 and 6 , a first latch tooth 456 is provided in the mounting groove 454 , a second latch tooth 457 matched with the first latch tooth 456 is provided on the mounting ring 455 , the second latch tooth 457 is rotationally connected to the mounting ring 455 , an elastic member 458 is provided on the mounting ring 455 , and the elastic member 458 is used to drive the second latch tooth 457 to deflect in a direction away from the mounting ring 455 .

Referring to Figure 6, as an embodiment of the present application, the elastic member 458 is configured as a torsion spring, a rotating shaft 459 is rotatably arranged in the mounting ring 455, the second locking tooth 457 is fixedly connected to the rotating shaft 459, the torsion spring is sleeved on the rotating shaft 459, one end of the torsion spring is fixedly connected to the rotating shaft 459, and the other end is fixedly connected to the inner wall of the mounting ring 455.

During actual use, the impeller receives external wind force and can drive the mounting ring 455 to rotate in the mounting groove 454. As the mounting ring 455 rotates, the mounting ring 455 drives the second latch tooth 457 to engage with the first latch tooth 456, thereby driving the first mounting shaft 453 to rotate. Since different impellers are located at different heights, the wind forces exerted on the impellers at different heights are also different. Through the mutually engaged first latch tooth 456 and second latch tooth 457, the first mounting shaft 453 can use the rotation speed of the mounting ring 455 with the fastest rotation speed as its own rotation speed. Other mounting rings 455 with slower rotation speeds will not affect the rotation speed of the first mounting shaft 453, thereby improving the rotation effect of the first mounting shaft 453 and further improving the efficiency of the auxiliary drive of the first mounting shaft 453.

As another embodiment of the present application, referring to Figure 7, the second auxiliary power drive assembly includes a second power shaft 46 and a hydraulic input assembly 47, one end of the second power shaft 46 is transmission connected to the main shaft, and the other end is transmission connected to the input end of the hydraulic input assembly 47.

7 and 8 , the hydraulic input assembly 47 includes a second mounting frame 471 and a hydraulic impeller 472 . A second mounting shaft 473 is rotatably provided on the second mounting frame 471 . The hydraulic impeller 472 is provided on the second mounting shaft 473 . The second mounting shaft 473 is transmission-connected to the second power shaft 46 .

7 and 8 , a plurality of hydraulic impellers 472 are provided, and the plurality of hydraulic impellers 472 are arranged in sequence along the length direction of the second mounting axis 473; a water tank 474 is provided on the second mounting frame 471; a water reservoir 475 is provided on the second mounting frame 471; the water reservoir 475 is arranged below the hydraulic impeller 472; a water pump 476 is provided on the second mounting frame 471; a return water pipe is provided on the second mounting frame 471; one end of the return water pipe is connected to the water reservoir 475, and the other end is connected to the water tank 474; the water pump 476 is connected to the return water pipe; a water outlet pipe 477 is connected to the water tank 474; and one end of the water outlet pipe 477 away from the water tank 474 is arranged above the hydraulic impeller 472.

Referring to Figure 8, a gearbox 48 is provided at one end of the second mounting shaft 473 close to the second power shaft 46, the second mounting shaft 473 is transmission-connected to the input end of the gearbox 48, a belt drive assembly 481 is transmission-connected between the output end of the gearbox 48 and the second power shaft 46, and the second power shaft 46 is transmission-connected to the main shaft 15 via a bevel gear set 482.

8 , a manual valve 478 for opening and closing the water outlet pipe 477 is provided on the water outlet pipe 477 , a booster pump 479 is provided on the water outlet pipe 477 , and a water inlet is provided on the second mounting frame 471 along the length direction of the second mounting shaft 473 .

In actual use, the main shaft 15 can be driven by wind or water power to rotate. When the high-pressure gas in the high-pressure gas tank 12 is insufficient, the main shaft 15 can still be driven to rotate to generate electricity. In addition, different numbers of wind input components 45 or water input components 47 can be set according to different locations, so as to cope with more types of terrain. On this basis, the power generation device and control system 8 and the power conversion system 81 constitute a power generation system. According to different geographical locations, one or more groups of power generation devices can be selected for networking and integration, which significantly improves the scope of application of the device and greatly reduces the restrictions on power generation requirements. It can make full use of various natural clean energy such as wind, water and solar energy to generate electricity, which not only improves the overall practicality of the device, but also reduces noise during the power generation process, and does not generate wastewater and exhaust gas, and has good environmental protection and cleanliness.

1 and 9 , as an embodiment of the present application, the photovoltaic assembly 2 includes a photovoltaic panel 21 and a battery 22. The output end of the photovoltaic panel 21 is connected to the input end of the battery 22, and the output end of the battery 22 is connected to the air compressor 13; the photovoltaic assembly 2 also includes a mounting plate 23, the photovoltaic panel 21 is rotatably arranged on the mounting plate 23, and a rotating assembly 24 is arranged on the mounting plate 23, and the rotating assembly 24 is used to drive the photovoltaic panel 21 to rotate.

As an embodiment of the present application, referring to Figure 9, the rotating component 24 includes a connecting shaft 241, a rotating motor 244, a driving gear 242 and a driven gear 243. One end of the connecting shaft 241 is rotatably set on the mounting plate 23, and the other end is fixedly connected to the photovoltaic panel 21. The rotating motor 244 is fixedly set on the mounting plate 23. The driving gear 242 is coaxially fixedly connected with the output shaft of the rotating motor 244. The driven gear 243 is fixedly sleeved on the connecting shaft 241, and the driven gear 243 is meshed with the driving gear 242.

As another embodiment of the present application, a plurality of mounting rods 71 are arranged in the first transmission chamber 62 and/or the third transmission chamber 64, and the plurality of mounting rods 71 are arranged along the circumference of the first transmission rod 51 and/or the third transmission rod 53, and a magnetic member 72 is arranged at the end of each mounting rod 71.

As another embodiment of the present application, at least one group of wind input components 45 is provided, and the power output end of each group of wind input components 45 is transmission-connected to the first power shaft 44 .

As another embodiment of the present application, at least one group of hydraulic input components 47 is provided, and the power output end of each group of hydraulic input components 47 is transmission-connected to the second power shaft 46 .

In a second aspect, an embodiment of the present application also discloses a power generation system.

Referring to Figure 10, a power generation system includes a power generation device as described above, and also includes a control system 8 and an electric energy conversion system 81. The electric energy conversion system 81 is used to convert the electric energy generated by the power generation device. The control system 8 is electrically connected to the electric energy conversion system 81, and the control system 8 is electrically connected to the power generation device. After the electric energy generated by the power generation device is converted by the electric energy conversion system 81, it can be supplied to the power consumption system 82 for use.

As an implementation mode of the present application, the power system 82 includes various components of the present application. The electric energy generated by the power generation system is used to compensate the power generation components of the present application to a certain extent, which can reduce the power consumption of the present application during actual use. At the same time, it can also realize the secondary recycling of part of the energy.

As an implementation mode of the present application, multiple groups of power generation devices are provided, and the power output ends of the multiple groups of power generation devices are electrically connected.

The implementation principle of a multi-combination low-noise clean power generation device and power generation system in the embodiment of the present application is:

In actual use, the photovoltaic component 2 absorbs solar energy and converts it into electrical energy. Then, the control system 8 can be used to input the electrical energy into the auxiliary motor of the first auxiliary drive component 3, the air compressor and the rotating motor of the rotating component 24, so as to power the auxiliary motor, the air compressor and the rotating motor. The electrical energy can also be stored in the battery 22. When the gas pressure in the high-pressure gas tank 12 is lower than a certain pressure threshold, the control system 8 controls the battery 22 to output electrical energy or the solar panel to directly output the converted electrical energy to power the air compressor. After the air compressor 13 is started to compress the air into high-pressure gas, the air is input into the high-pressure gas tank 12, so as to replenish the high-pressure gas in the high-pressure gas tank 12. After the air pressure in the high-pressure gas tank 12 reaches the preset pressure threshold, the air compressor 13 can be shut down.

At the same time, the solar energy is converted by the solar panel, and the converted electric energy or the storage battery 22 is used to power the auxiliary motor, and the auxiliary motor drives the main shaft to rotate. In the process of replenishing the gas in the high-pressure gas tank 12, it can still ensure that the main shaft has a sufficient rotation speed to ensure that the generator 14 can generate electricity normally, thereby improving the reliability of the device during use. At the same time, by driving the main shaft with the auxiliary motor, the rotation speed of the main shaft can be increased to a certain extent, thereby effectively improving the power generation effect and power generation of the generator 14, thereby forming a secondary utilization and recycling of energy;

In addition, in actual use, the main shaft can be driven by wind or water power to rotate. When the high-pressure gas in the high-pressure gas tank 12 is insufficient, the main shaft can still be driven to rotate to generate electricity. Different numbers of wind input components 45 or water input components 47 can be set according to different locations, so as to cope with more types of terrain. On this basis, the power generation device and control system 8 and the power conversion system 81 form a power generation system. According to different geographical locations, one or more groups of power generation devices can be selected for networking integration, which significantly improves the scope of application of the device and greatly reduces the restrictions on power generation requirements. It can make full use of various natural clean energy such as wind, water and solar energy to generate electricity, which not only improves the overall practicality of the device, but also reduces the noise during the power generation process, and does not generate wastewater and exhaust gas, and has good environmental protection and cleanliness.

The above are only preferred embodiments of the present application and are not intended to limit the present application. For those skilled in the art, the present application may have various modifications and variations. Any modifications made within the spirit and principles of the present application, including: equivalent replacement, improvement, addition, expansion, multi-group integration, computer control system, electrical components, safety measures, etc., shall be included in the protection scope of the present application.

Claims (18)

1. A multi-combination low-noise clean power generation device, comprising a frame, a wind impeller, a high-pressure gas tank, an air compressor, a boost valve, an air pressure regulating valve, a manual switch and a generator, characterized in that: a main shaft is rotatably arranged in the frame, the wind impeller is rotatably arranged on the main shaft, a multi-stage acceleration component is arranged in the frame, one end of the multi-stage acceleration component is transmission-connected to the main shaft, and the other end is transmission-connected to the input end of the generator;

   Also includes a photovoltaic assembly, a first auxiliary drive assembly and a second auxiliary drive assembly;

   The first auxiliary drive assembly is used to drive the main shaft to rotate. The first auxiliary drive assembly includes an auxiliary motor. The auxiliary motor is arranged in a frame. The output shaft of the auxiliary motor is drivingly connected to the main shaft.
2. A multi-combination low-noise clean power generator according to claim 1, characterized in that: the multi-stage acceleration assembly includes a first transmission rod, a second transmission rod and a third transmission rod, the first transmission rod, the second transmission rod and the third transmission rod are all rotatably arranged in the frame, one end of the first transmission rod is transmission-connected to the main shaft, and the other end is transmission-connected to the second transmission rod through a first acceleration gear set, the end of the second transmission rod away from the first transmission rod is transmission-connected to the third transmission rod through a second acceleration gear set, and the end of the third transmission rod away from the second transmission rod is transmission-connected to the input end of the generator through an acceleration pulley set.
3. According to claim 2, a multi-combination low-noise clean power generation device is characterized in that: a plurality of partitions are arranged in the frame, and the plurality of partitions divide the interior of the frame into a plurality of independent chambers, and the independent chambers include a main shaft chamber, a first transmission chamber, a second transmission chamber, a third transmission chamber, a power generation chamber and a plurality of acceleration chambers for accommodating acceleration wheel sets, and a magnet power assembly is arranged in the first transmission chamber and the third transmission chamber.
4. According to a multi-combination low-noise clean power generation device according to claim 1, it is characterized in that: the second auxiliary drive assembly includes a mounting frame, an auxiliary drive shaft and an auxiliary drive impeller, the mounting frame is detachably connected to the frame, the auxiliary drive shaft is rotatably set on the mounting frame, the auxiliary drive impeller is set on the auxiliary drive shaft, and the auxiliary drive shaft is transmission-connected to the main shaft.
5. According to the multi-combination low-noise clean power generation device of claim 1, it is characterized in that: the second auxiliary drive assembly includes a first power shaft and a wind input assembly, one end of the first power shaft is transmission-connected to the main shaft, and the other end is transmission-connected to the input end of the wind input assembly;

   The wind input assembly includes a first mounting frame and a wind impeller. The first mounting frame is rotatably provided with a first mounting shaft. The wind impeller is rotatably provided on the first mounting shaft. The first mounting shaft is transmission-connected to the first power shaft.
6. According to claim 5, a multi-combination low-noise clean power generation device is characterized in that: an installation groove is opened on the first installation shaft, and a plurality of the installation grooves are evenly arranged along the length direction of the first installation shaft, and a mounting ring is rotatably sleeved in each of the installation grooves, and the wind impeller is fixedly connected to the mounting ring.
7. According to claim 6, a multi-combination low-noise clean power generation device is characterized in that: a first latch tooth is arranged in the mounting groove, a second latch tooth matched with the first latch tooth is arranged on the mounting ring, the second latch tooth is rotatably connected to the mounting ring, and an elastic member is arranged on the mounting ring, and the elastic member is used to drive the second latch tooth to deflect in a direction away from the mounting ring.
8. According to the multi-combination low-noise clean power generation device of claim 1, it is characterized in that: the second auxiliary power drive assembly includes a second power shaft and a hydraulic input assembly, one end of the second power shaft is transmission-connected to the main shaft, and the other end is transmission-connected to the input end of the hydraulic input assembly;

   The hydraulic input assembly includes a second mounting frame and a hydraulic impeller. A second mounting shaft is rotatably arranged on the second mounting frame. The hydraulic impeller is arranged on the second mounting shaft. The second mounting shaft is transmission-connected to the second power shaft.
9. According to claim 8, a multi-combination low-noise clean power generation device is characterized in that: there are multiple hydraulic impellers, and the multiple hydraulic impellers are arranged in sequence along the length direction of the second mounting axis, a water tank is arranged on the second mounting frame, a water reservoir is arranged on the second mounting frame, the water reservoir is arranged below the hydraulic impeller, a water pump is arranged on the second mounting frame, a return pipe is arranged on the second mounting frame, one end of the return pipe is connected to the water reservoir, and the other end is connected to the water tank, the water pump is connected to the return pipe, the water tank is connected to a water outlet pipe, and the end of the outlet pipe away from the water tank is arranged above the hydraulic impeller.
10. According to the multi-combination low-noise clean power generation device as described in claim 8, it is characterized in that a gearbox is provided at one end of the second mounting shaft close to the second power shaft, the second mounting shaft is transmission-connected to the input end of the gearbox, and a belt drive assembly is transmission-connected between the output end of the gearbox and the second power shaft.
11. According to the multi-combination low-noise clean power generation device according to claim 9, it is characterized in that: the water outlet pipe is provided with a manual valve for opening and closing the water outlet pipe, the water outlet pipe is provided with a booster pump, and the second mounting frame is provided with a water inlet along the length direction of the second mounting axis.
12. According to a multi-combination low-noise clean power generation device as described in claim 3, it is characterized in that: the magnetic power component includes a mounting rod, a magnetic part and a circumferential magnetic ring magnet, the first transmission rod and the third transmission rod are both sleeved with a circumferential magnetic ring magnet, the mounting rod is arranged in the first transmission chamber and the third transmission chamber along the vertical direction, the magnetic part is arranged at one end of the mounting rod close to the circumferential magnetic ring magnet, and the first transmission chamber and the third transmission chamber are both provided with an adjustment component for adjusting the distance between the circumferential magnetic exchange magnet and the magnetic part.
13. According to a multi-combination low-noise clean power generation device as described in claim 12, it is characterized in that: a revolution counter is arranged in the frame, the revolution counter is used to detect the rotation speed of the third transmission rod, and a support frame is arranged in the frame, and the revolution counter is fixedly arranged on the top of the support frame.
14. According to a multi-combination low-noise clean power generation device according to claim 12, it is characterized in that: a plurality of mounting rods are arranged in the first transmission chamber and/or the third transmission chamber, and the plurality of mounting rods are arranged along the circumference of the first transmission rod and/or the third transmission rod, and a magnetic part is arranged at the end of each mounting rod.
15. A multi-combination low-noise clean power generation device according to any one of claims 5-7, characterized in that: the wind input component is provided with at least one group, and the power output end of each group of the wind input components is transmission-connected to the first power shaft.
16. A multi-combination low-noise clean power generation device according to any one of claims 8-11, characterized in that: the hydraulic input component is provided with at least one group, and the power output end of each group of the hydraulic input components is transmission-connected to the second power shaft.
17. A power generation system, characterized in that it includes a power generation device as described in any one of claims 1 to 16, and also includes a control system and an electric energy conversion system, the electric energy conversion system is used to convert the electric energy generated by the power generation device, the control system is electrically connected to the electric energy conversion system, and the control system is electrically connected to the power generation device.
18. A power generation system according to claim 17, characterized in that: the power generation device is provided in multiple groups, and the power output ends of the multiple groups of power generation devices are electrically connected.

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