Distributed energy coupling adjusting device
By introducing a combination of solar panels, batteries, a motor-driven gear system, and an exhaust fan into the distributed energy coupling regulation device, the problem of the temperature rise of electrical components affecting power regulation was solved, and the stable operation of the device and precise control of the hydrogen production rate were achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUAXIN HLDG (HENAN) CO LTD
- Filing Date
- 2025-07-03
- Publication Date
- 2026-06-26
Smart Images

Figure CN224418774U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of energy coupling technology, specifically a distributed energy coupling regulation device. Background Technology
[0002] Distributed energy is an energy supply system built at or near the user end, which integrates multiple energy forms and technologies to achieve efficient energy utilization and flexible energy supply.
[0003] Existing distributed energy coupling regulation devices typically regulate the power supply through a regulator. By controlling the amount of power, the rate at which hydrogen is produced by water electrolysis can be indirectly controlled, thereby achieving the effect of controlling the hydrogen production rate. However, the temperature of the electrical components inside the regulator will continue to rise during long-term operation, thus affecting the regulation of power.
[0004] Therefore, a distributed energy coupling and regulation device is proposed to solve the problems mentioned above. Utility Model Content
[0005] To address the shortcomings of existing technologies, this utility model provides a distributed energy coupling regulation device that can solve the problem of the impact of rising electrical component temperatures on power regulation.
[0006] To achieve the above objectives, this utility model provides the following technical solution: It includes a solar panel and transmission pipes fixedly connected to the lower ends of several solar panels. Each of the transmission pipes has a wire connected inside. A battery is located on the right side of the solar panel, and one end of the wire is connected to the inside of the battery. A regulator is located on the right side of the battery, and a wire is connected to one side of the battery, with one end of the wire connected to the inside of the regulator. Two regulating components are fixedly connected to one side of the regulator, and a motor is fixedly connected to the other side of the regulator. A drive gear is fixedly connected to the output end of the motor. Two driven gears are located outside the drive gear. A sector gear is fixedly connected to one end of each of the two driven gears. A rotating shaft is rotatably connected to one end of each of the two driven gears, and one end of each of the two rotating shafts is fixedly connected to the inside of the regulator. A bidirectional rack plate is movably arranged between the two sector gears.
[0007] Preferably, the bidirectional rack plate is meshed with the two sector gears, the bidirectional rack plate is disposed through the upper end of the adjuster, and a rectangular slide groove is fixedly connected to the inner side of the lower end of the adjuster.
[0008] Preferably, sliders are fixedly connected to both sides of the bidirectional rack plate, and the sliders are slidably connected inside the rectangular groove.
[0009] Preferably, two fixing plates are fixedly connected to one side of the bidirectional rack plate, and two exhaust fans are fixedly connected to the lower ends of the two fixing plates, and the two exhaust fans are symmetrically distributed.
[0010] Preferably, a wire is connected to the upper end of the regulator, a storage box is provided on the right side of the regulator, a conduit is provided through one side of the storage box, two connecting plates are fixedly connected to the upper end of the storage box, a power supply box is fixedly connected to one end of the two connecting plates, and one end of the wire is connected to the inside of the power supply box.
[0011] Preferably, two electrolyzers are fixedly connected to the inner side of the lower end of the storage box, and the upper ends of the two electrolyzers are connected with wires, which are connected inside the power supply box. A gas storage chamber is provided on the right side of the storage box, and the gas storage chamber and the conduit are connected through each other.
[0012] Preferably, the driving gear meshes with the driven gear, the two driven gears are symmetrically distributed, and the sector gear meshes with the bidirectional rack plate.
[0013] Compared with the prior art, the present invention provides a distributed energy coupling and regulation device, which has the following beneficial effects:
[0014] 1. The bidirectional rack plate can be controlled to move up and down by the rotation of the motor, which improves the linkage of the structure.
[0015] 2. By using a bidirectional rack and pinion plate to drive the exhaust fan to move up and down, the internal temperature of the regulator can be evenly cooled, thus improving the stability of operation. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the overall front view of the present invention;
[0017] Figure 2 This is a schematic cross-sectional view of the overall structure of this utility model;
[0018] Figure 3 This is a schematic diagram of the lifting mechanism of this utility model;
[0019] Figure 4 This is a schematic diagram of the cooling method of this utility model.
[0020] In the diagram: 1. Solar panel; 2. Battery; 3. Regulator; 4. Fixing plate; 5. Rectangular slide; 6. Bidirectional rack and pinion plate; 7. Motor; 8. Drive gear; 9. Driven gear; 11. Exhaust fan; 12. Sector gear; 13. Adjustment component; 14. Slider; 15. Power supply box; 16. Connecting plate; 17. Electrolyzer; 18. Storage box; 19. Gas storage chamber; 20. Transmission pipe. Detailed Implementation
[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0022] Example:
[0023] Please see Figure 1 - Figure 4 This embodiment of a distributed energy coupling regulation device includes a solar panel 1 and a transmission pipe 20 fixedly connected to the lower end of several solar panels 1. Each of the several transmission pipes 20 is connected with a wire. A storage battery 2 is provided on the right side of the solar panel 1, and one end of the wire is connected to the inside of the storage battery 2. A regulator 3 is provided on the right side of the storage battery 2. A wire is connected to one side of the storage battery 2, and one end of the wire is connected to the inside of the regulator 3. Two regulating components 13 are fixedly connected to one side of the inside of the regulator 3. A motor 7 is fixedly connected to the other side of the inside of the regulator 3. A drive gear 8 is fixedly connected to the output end of the motor 7. Two driven gears 9 are provided outside the drive gear 8. A sector gear 12 is fixedly connected to one end of each of the two driven gears 9. A rotating shaft is rotatably connected to one end of each of the two driven gears 9, and a bidirectional rack plate 6 is movably arranged between the two sector gears 12.
[0024] The bidirectional rack plate 6 is meshed with two sector gears 12. The bidirectional rack plate 6 is connected through the upper end of the adjuster 3. A rectangular slide groove 5 is fixedly connected to the inner side of the lower end of the adjuster 3.
[0025] Both sides of the bidirectional rack plate 6 are fixedly connected to sliders 14, and the sliders 14 are slidably connected inside the rectangular groove 5.
[0026] Two fixing plates 4 are fixedly connected to one side of the bidirectional rack plate 6. Two exhaust fans 11 are fixedly connected to the lower end of each fixing plate 4. The two exhaust fans 11 are symmetrically distributed.
[0027] Among them, generating electricity through solar panel 1 and storing the electricity in battery 2, adjusting the amount of electricity supplied through regulator 3, and electrolyzing water through electrolyzer 17 are all existing technologies, so they are not described in detail in this embodiment.
[0028] At this time, electricity is generated through solar panel 1, which stores the electrical energy inside battery 2. The power supply of battery 2 to power supply box 15 can be controlled by regulator 3, thereby controlling the power supply to electrolyzer 17 and consequently controlling the rate of hydrogen production. The hydrogen produced inside storage box 18 is then transported to gas storage chamber 19 via connecting pipe. Motor 7 drives drive gear 8 to rotate, which in turn drives two driven gears 9 on the outside. These driven gears 9, in turn, drive sector gears 12. A bidirectional rack plate 6 meshes with the two sector gears 12, causing the sector gears 12 to rotate. The bidirectional rack plate 6 is pushed up and down. By utilizing the symmetry of the sector gear 12 transmission, the bidirectional push of the bidirectional rack plate 6 is achieved, which can form a synchronous reverse driving force, reduce the yaw error of the bidirectional rack plate 6 during the movement, and improve the stability of the transmission system. By fixing two fixed plates 4 to one side of the bidirectional rack plate 6 and fixing two exhaust fans 11 to the lower end of the two fixed plates 4, the exhaust fans 11 will move up and down when the bidirectional rack plate 6 moves up and down, so as to achieve the effect of uniformly cooling the regulating component 13 inside the regulator 3, preventing the regulating component 13 from being damaged due to excessive temperature inside the regulator 3, and improving the stability of operation.
[0029] A wire is connected to the upper end of the regulator 3. A storage box 18 is provided on the right side of the regulator 3. A conduit is provided through one side of the storage box 18. Two connecting plates 16 are fixedly connected to the upper end of the storage box 18. A power supply box 15 is fixedly connected to one end of the two connecting plates 16, and one end of the wire is connected to the inside of the power supply box 15.
[0030] Two electrolyzers 17 are fixedly connected to the inner side of the lower end of the storage box 18. The upper ends of the two electrolyzers 17 are connected with wires, and the wires are connected inside the power supply box 15. A gas storage chamber 19 is provided on the right side of the storage box 18, and the gas storage chamber 19 is connected to the conduit.
[0031] The driving gear 8 is meshed with the driven gear 9, and the two driven gears 9 are symmetrically distributed. The sector gear 12 is meshed with the double-sided rack plate 6.
[0032] By setting two connecting plates 16 on the upper end of the storage tank 18, the position of the power supply box 15 can be fixed to prevent the power supply box 15 from shaking when supplying power to the two electrolyzers 17. A gas storage chamber 19 is set on the right side of the storage tank 18, and the gas storage chamber 19 is connected to the conduit. The hydrogen generated inside the storage tank 18 will enter the gas storage chamber 19 through the conduit to achieve the effect of storing hydrogen. By meshing the driving gear 8 and the driven gear 9, the driving gear 8 will drive the driven gear 9 when it rotates, which improves the linkage of the structure. By rotatably connecting a rotating shaft at one end of the two driven gears 9 and fixing one end of the rotating shaft to the inside of the regulator 3, the rotating shaft will provide rotational support for the rotation of the driven gears 9.
[0033] The working principle of the above embodiments is as follows:
[0034] In use, solar panel 1 generates electricity and stores the electrical energy inside battery 2. The power supply of battery 2 to power supply box 15 can be controlled by regulator 3, thereby controlling the power supply of electrolyzer 17 and thus controlling the rate of hydrogen production. The hydrogen produced inside storage box 18 is transported to gas storage chamber 19 through connecting pipe. The drive gear 8 drives two sector gears 12 to rotate. When the two sector gears 12 rotate, the bidirectional rack plate 6 pushes up and down to cool the regulating component 13.
[0035] The installation, connection, or setting methods disclosed in this embodiment are all common mechanical connection methods. As long as they can achieve their beneficial effects, they can be implemented. Therefore, this embodiment will not elaborate on their specific structural composition and working principle.
[0036] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A distributed energy coupling conditioning device, characterized by: The system includes a solar panel (1) and a power supply pipe (20) fixedly connected to the lower end of several solar panels (1). Each power supply pipe (20) has a wire connected inside it. A battery (2) is located on the right side of the solar panel (1), and one end of the wire is connected to the inside of the battery (2). A regulator (3) is located on the right side of the battery (2), and a wire is connected to one side of the battery (2), with one end of the wire connected to the inside of the regulator (3). Two wires are fixedly connected to one side of the regulator (3). An adjustment component (13) is provided. A motor (7) is fixedly connected to the other side of the regulator (3). A drive gear (8) is fixedly connected to the output end of the motor (7). Two driven gears (9) are provided on the outside of the drive gear (8). A sector gear (12) is fixedly connected to one end of each of the two driven gears (9). A rotating shaft is rotatably connected to one end of each of the two driven gears (9). One end of each of the two rotating shafts is fixedly connected to the inside of the regulator (3). A bidirectional rack plate (6) is movably arranged between the two sector gears (12).
2. The distributed energy coupling and regulation device according to claim 1, characterized in that: The bidirectional rack plate (6) is meshed with the two sector gears (12), the bidirectional rack plate (6) is connected through the upper end of the adjuster (3), and a rectangular slide groove (5) is fixedly connected to the inner side of the lower end of the adjuster (3).
3. The distributed energy coupling and regulation device according to claim 2, characterized in that: Both sides of the bidirectional rack plate (6) are fixedly connected to sliders (14), and the sliders (14) are slidably connected inside the rectangular groove (5).
4. A distributed energy coupling and regulation device according to claim 3, characterized in that: Two fixing plates (4) are fixedly connected to one side of the bidirectional rack plate (6), and two exhaust fans (11) are fixedly connected to the lower ends of the two fixing plates (4). The two exhaust fans (11) are symmetrically distributed.
5. A distributed energy coupling and regulation device according to claim 2, characterized in that: The regulator (3) has a wire connected to its upper end, and a storage box (18) is provided on the right side of the regulator (3). A conduit is provided through one side of the storage box (18). Two connecting plates (16) are fixedly connected to the upper end of the storage box (18). A power supply box (15) is fixedly connected to one end of the two connecting plates (16), and one end of the wire is connected to the inside of the power supply box (15).
6. A distributed energy coupling and regulation device according to claim 5, characterized in that: Two electrolyzers (17) are fixedly connected to the inner side of the lower end of the storage box (18). The upper ends of the two electrolyzers (17) are connected with wires, and the wires are connected inside the power supply box (15). A gas storage chamber (19) is provided on the right side of the storage box (18). The gas storage chamber (19) and the conduit are connected through each other.
7. A distributed energy coupling and regulation device according to claim 1, characterized in that: The driving gear (8) meshes with the driven gear (9), the two driven gears (9) are symmetrically distributed, and the sector gear (12) meshes with the bidirectional rack plate (6).