A cooling mechanism for a water electrolysis hydrogen generator

By introducing a disturbance component and heat conduction pipe into the water electrolysis hydrogen generator, and utilizing the disturbance of the support spring and telescopic rod to promote the flow of the cooling working fluid, the problem of poor cooling effect of traditional water electrolysis hydrogen generators is solved, and more efficient heat transfer is achieved.

CN224478154UActive Publication Date: 2026-07-10SUZHOU BLUE AIR ENERGY TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SUZHOU BLUE AIR ENERGY TECH CO LTD
Filing Date
2025-06-11
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Traditional water electrolysis hydrogen generators dissipate heat through heat-conducting pipes closely attached to the surface, resulting in only moderate cooling effects that cannot meet people's cooling needs.

Method used

By employing disturbance components and heat conduction pipes, and through the disturbance of support springs and telescopic rods, the flow of cooling working fluid is promoted, thereby increasing the heat transfer rate.

Benefits of technology

It accelerates the heat transfer rate and meets the cooling requirements of the water electrolysis hydrogen production machine.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of cooling mechanism for water electrolysis hydrogen generator, including fixed base, the both sides of fixed base top end are uniformly fixedly installed with quick-mounting assembly, two quick-mounting assemblies are fixedly installed with disturbance assembly between, the top of disturbance assembly is fixedly installed with cooling platform, the top of cooling platform is fixedly connected with several heat conduction pipes, two quick-mounting assemblies include height block and lifting plate, the side of height block top is equipped with lifting groove, connecting spring is fixedly installed in the bottom of lifting groove inner wall, the top of connecting spring and the bottom of lifting plate contact connection, the utility model discloses a kind of cooling mechanism for water electrolysis hydrogen generator, by setting disturbance assembly and heat conduction pipe, when heat pipe is supported spring and telescopic rod disturbance, cooling working substance in pipe will be disturbed, this disturbance will promote the flow of working substance and high-temperature gas mixing, to accelerate the speed of heat transfer, satisfy people's cooling demand to water electrolysis hydrogen generator.
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Description

Technical Field

[0001] This utility model relates to the field of water electrolysis hydrogen production machine technology, specifically a cooling mechanism for a water electrolysis hydrogen production machine. Background Technology

[0002] Electrolysis of water to produce hydrogen does not generate any harmful pollutants, making it a very clean and environmentally friendly method that meets modern environmental requirements. The energy utilization rate of water electrolysis is very high, reaching over 90%, because electrical energy can be fully utilized while also increasing hydrogen production. This is highly beneficial for energy conservation and efficiency. The equipment can be started and stopped at any time and can be expanded or reduced in capacity as needed, meaning this method is very flexible and can be adjusted according to actual needs. Water electrolysis can use any renewable energy source, including solar, wind, and hydropower, making it widely applicable and able to meet various energy demands. The water electrolysis hydrogen generator is equipped with a cooling system that reduces the temperature of the alkali solution flowing through the system through indirect heat exchange, maintaining electrolysis efficiency and stability.

[0003] However, traditional water electrolysis hydrogen production machines have the following drawbacks:

[0004] Traditional water electrolysis hydrogen generators dissipate heat through heat-conducting pipes attached to their surface, resulting in only moderate cooling performance that fails to meet people's cooling needs. Utility Model Content

[0005] The purpose of this invention is to provide a cooling mechanism for a water electrolysis hydrogen generator, in order to solve the problem mentioned in the background art that the traditional water electrolysis hydrogen generator itself dissipates heat through heat conduction pipes closely attached to its surface, resulting in a generally poor cooling effect that cannot meet people's cooling needs.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a cooling mechanism for a water electrolysis hydrogen production machine, comprising a fixed base, quick-assembly components fixedly installed on both sides of the top of the fixed base, a disturbance component fixedly installed between the two quick-assembly components, a cooling platform fixedly installed on the top of the disturbance component, a plurality of heat conduction pipes fixedly connected to the top of the cooling platform, each of the two quick-assembly components comprising a height block and a lifting plate, a lifting groove being provided on one side of the top of the height block, a connecting spring being fixedly installed at the bottom of the inner wall of the lifting groove, the top of the connecting spring being in contact with the bottom of the lifting plate, the disturbance component comprising two connecting shells and two mounting seats, a disturbance groove being provided on the opposite side of the two connecting shells, a length plate being slidably connected inside the two disturbance grooves, the opposite side of the two length plates being fixedly connected to one end of the two mounting seats respectively, and a disturbance plate being rotatably connected inside the two mounting seats.

[0007] Preferably, each end of one side of the inner wall of the lifting groove has a movable opening, and a quick-installation plate is rotatably connected inside each of the two movable openings. Positioning plates are fixedly installed at both ends of one side of the inner wall of the height block. Angle rods are rotatably connected to one side of each of the two positioning plates. The ends of the two angle rods away from the positioning plates are rotatably connected to one side of each of the two quick-installation plates. Quick-installation slots are provided at both ends of one side of the lifting plate, and the two quick-installation plates are respectively configured to correspond to the two quick-installation slots. When the user inserts the lifting plate into the lifting groove, the quick-installation plate deflects at an angle relative to the movable opening, and the quick-installation plate pulls the angle rod from one side, causing the angle rod to deflect at an angle relative to the positioning plate. The quick-installation plate then engages with the quick-installation slot, completing the rapid installation of the lifting plate.

[0008] Preferably, the bottom ends of the two height blocks are fixedly connected to the fixed base, the top ends of the two lifting plates are fixedly connected to the two connecting shells respectively, the quick-installation assembly is installed on the fixed base through the height blocks, and the quick-installation assembly is installed on the connecting shell through the lifting plates.

[0009] Preferably, a telescopic rod is fixedly installed at the top of each of the two connecting shells, and the movable end of each of the two telescopic rods is fixedly connected to the side of the cooling platform directly opposite to it. A support spring is fixedly installed on the surface of each of the two connecting shells, and the top of each of the two support springs is fixedly connected to the cooling platform. During the lifting and lowering of the cooling platform, the telescopic rods extend and retract, pulling or compressing the support springs. The support springs are elastic, and their elastic deformation buffers the compressive or tensile force.

[0010] Preferably, a return spring is fixedly installed on one side of the inner wall of each of the two disturbance grooves. One end of each of the two return springs is fixedly connected to the opposite side of the two length plates. The length plates slide relative to the disturbance grooves to adjust the distance between the length plates and the connecting shell. During the sliding process of the length plates, the length plates drive the mounting base to move synchronously, causing the disturbance plates to deflect at an angle and change their vertical height, thereby indirectly adjusting the cooling height of the cooling platform.

[0011] Preferably, the top ends of both disturbance plates are rotatably connected to the middle of the bottom end of the cooling platform, and the disturbance assembly is mounted on the cooling platform through the disturbance plates.

[0012] Preferably, all of the heat-conducting pipes are made of copper and are used to transfer and dissipate heat generated by the water electrolysis hydrogen generator.

[0013] Compared with the prior art, the beneficial effects of this utility model are: by setting up a disturbance component and a heat conduction pipe, when the heat conduction pipe is disturbed by the support spring and the telescopic rod, the cooling working fluid inside the pipe will be disturbed. This disturbance will promote the flow of the working fluid and the mixing of high-temperature gas, thereby accelerating the heat transfer speed and meeting people's cooling needs for water electrolysis hydrogen production machines. Attached Figure Description

[0014] Figure 1 This is a cross-sectional view of the present invention;

[0015] Figure 2 This is a connection diagram of the disturbance component and the cooling platform of this utility model;

[0016] Figure 3 This is a cross-sectional view of the quick-assembly component of this utility model;

[0017] Figure 4 This is a cross-sectional view of the disturbance component of this utility model.

[0018] In the diagram: 1. Fixed base; 2. Quick-release assembly; 21. Height block; 22. Lifting slot; 23. Connecting spring; 24. Lifting plate; 25. Quick-release slot; 26. Quick-release plate; 27. Positioning plate; 28. Angle rod; 29. ​​Movable opening; 3. Disturbance assembly; 31. Connecting shell; 32. Length plate; 33. Mounting base; 34. Disturbance plate; 35. Telescopic rod; 36. Support spring; 37. Disturbance slot; 38. Return spring; 4. Cooling platform; 5. Heat conduction pipe. Detailed Implementation

[0019] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0020] Please see Figure 1-4This utility model provides a cooling mechanism for a water electrolysis hydrogen production machine, including a fixed base 1. Quick-release components 2 are fixedly installed on both sides of the top of the fixed base 1. A disturbance component 3 is fixedly installed between the two quick-release components 2. A cooling platform 4 is fixedly installed on the top of the disturbance component 3. Several heat conduction pipes 5 are fixedly connected to the top of the cooling platform 4. Each of the two quick-release components 2 includes a height block 21 and a lifting plate 24. A lifting groove 22 is opened on one side of the top of the height block 21. A connecting spring 23 is fixedly installed at the bottom of the inner wall of the lifting groove 22. The top of the connecting spring 23 is in contact with the bottom of the lifting plate 24. The disturbance component 3 includes two connecting shells 31 and two mounting seats 33. A disturbance groove 37 is opened on the opposite side of the two connecting shells 31. A length plate 32 is slidably connected inside the two disturbance grooves 37. The opposite side of the two length plates 32 is fixedly connected to one end of the two mounting seats 33 respectively. A disturbance plate 34 is rotatably connected inside the two mounting seats 33.

[0021] Both ends of one side of the inner wall of the lifting groove 22 are provided with movable openings 29. The interior of each movable opening 29 is rotatably connected to a quick-installation plate 26. Both ends of one side of the inner wall of the height block 21 are fixedly installed with positioning plates 27. One side of each positioning plate 27 is rotatably connected to an angle rod 28. The ends of each angle rod 28 away from the positioning plate 27 are rotatably connected to one side of each quick-installation plate 26. Both ends of one side of the lifting plate 24 are provided with quick-installation slots 25. The two quick-installation plates 26 are respectively set with the two quick-installation slots 25. When the user inserts the lifting plate 24 into the lifting groove 22, the quick-installation plate 26 deflects at an angle relative to the movable opening 29, and the quick-installation plate 26 pulls the angle rod 28 from one side, causing the angle rod 28 to deflect at an angle relative to the positioning plate 27. The quick-installation plate 26 is then inserted into the quick-installation slot 25, completing the quick installation of the lifting plate 24.

[0022] The bottom ends of the two height blocks 21 are fixedly connected to the fixed base 1, and the top ends of the two lifting plates 24 are fixedly connected to the two connecting shells 31 respectively. The quick-installation component 2 is installed on the fixed base 1 through the height blocks 21, and the quick-installation component 2 is installed on the connecting shell 31 through the lifting plates 24.

[0023] Telescopic rods 35 are fixedly installed at the top of both connecting shells 31. The movable ends of both telescopic rods 35 are fixedly connected to the side of the cooling platform 4 facing each other. Support springs 36 are fixedly installed on the surface of both connecting shells 31. The tops of both support springs 36 are fixedly connected to the cooling platform 4. During the lifting and lowering of the cooling platform 4, the telescopic rods 35 extend and retract. During the extension and retraction of the telescopic rods 35, they pull or compress the support springs 36. The support springs 36 are elastic, and the elastic deformation of the support springs 36 buffers the compressive or tensile force.

[0024] A return spring 38 is fixedly installed on one side of the inner wall of each of the two disturbance grooves 37. One end of each return spring 38 is fixedly connected to the opposite side of the two length plates 32. The length plates 32 slide relative to the disturbance grooves 37, adjusting the distance between the length plates 32 and the connecting shell 31. During the sliding process, the length plates 32 drive the mounting base 33 to move synchronously, causing the disturbance plate 34 to deflect at an angle and change its vertical height, thereby indirectly adjusting the cooling height of the cooling platform 4.

[0025] The tops of the two disturbance plates 34 are rotatably connected to the middle of the bottom of the cooling platform 4, and the disturbance assembly 3 is mounted on the cooling platform 4 through the disturbance plates 34.

[0026] Several heat-conducting pipes 5 are made of copper and are used to transfer and dissipate heat generated by the water electrolysis hydrogen generator.

[0027] In this embodiment, the heat transfer pipe 5 dissipates heat generated by the water electrolysis hydrogen generator. During the heat transfer process, the length plate 32 slides relative to the disturbance groove 37, adjusting the distance between the length plate 32 and the connecting shell 31. As the length plate 32 slides, it drives the mounting base 33 to move synchronously, causing the disturbance plate 34 to deflect at an angle. This changes the vertical height of the disturbance plate 34, indirectly adjusting the cooling height of the cooling platform 4. When the user inserts the lifting plate 24 into the lifting groove 22, the quick-release plate 26 deflects at an angle relative to the movable opening 29, and the quick-release plate 26 pulls the angle rod 28 from one side, causing the angle rod 28 to deflect at an angle relative to the positioning plate 27. The quick-release plate 26 then engages in the quick-release groove 25, completing the quick installation of the lifting plate 24, which facilitates the subsequent replacement and disassembly of the heat transfer pipe 5 by the user.

[0028] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. A cooling mechanism for a water electrolysis hydrogen production machine, comprising a fixed base (1), characterized in that: Quick-installation components (2) are fixedly installed on both sides of the top of the fixed base (1). A disturbance component (3) is fixedly installed between the two quick-installation components (2). A cooling platform (4) is fixedly installed on the top of the disturbance component (3). Several heat conduction pipes (5) are fixedly connected to the top of the cooling platform (4). Each of the two quick-installation components (2) includes a height block (21) and a lifting plate (24). A lifting groove (22) is opened on one side of the top of the height block (21). A connecting spring is fixedly installed at the bottom of the inner wall of the lifting groove (22). 23), the top end of the connecting spring (23) is in contact with the bottom end of the lifting plate (24), the disturbance component (3) includes two connecting shells (31) and two mounting bases (33), each of the two connecting shells (31) has a disturbance groove (37) on one side opposite to the other, and a length plate (32) is slidably connected inside each of the two disturbance grooves (37), and one side of each of the two length plates (32) is fixedly connected to one end of each of the two mounting bases (33), and a disturbance plate (34) is rotatably connected inside each of the two mounting bases (33).

2. The cooling mechanism for a water electrolysis hydrogen production machine according to claim 1, characterized in that: The lifting groove (22) has movable openings (29) at both ends on one side of its inner wall. The two movable openings (29) are rotatably connected to quick-release plates (26). The height block (21) has positioning plates (27) fixedly installed at both ends on one side of its inner wall. Angle rods (28) are rotatably connected to one side of the two positioning plates (27). The ends of the two angle rods (28) away from the positioning plates (27) are rotatably connected to one side of the two quick-release plates (26). The lifting plate (24) has quick-release slots (25) at both ends on one side of its inner wall. The two quick-release plates (26) are respectively set to correspond to the two quick-release slots (25).

3. The cooling mechanism for a water electrolysis hydrogen production machine according to claim 1, characterized in that: The bottom ends of the two height blocks (21) are fixedly connected to the fixed base (1), and the top ends of the two lifting plates (24) are fixedly connected to the two connecting shells (31) respectively.

4. A cooling mechanism for a water electrolysis hydrogen production machine according to claim 1, characterized in that: Telescopic rods (35) are fixedly installed on the top of both connecting shells (31), and the movable ends of the two telescopic rods (35) are fixedly connected to the side of the cooling platform (4) facing each other. Support springs (36) are fixedly installed on the surface of both connecting shells (31), and the top ends of the two support springs (36) are fixedly connected to the cooling platform (4).

5. A cooling mechanism for a water electrolysis hydrogen production machine according to claim 1, characterized in that: A reset spring (38) is fixedly installed on one side of the inner wall of each of the two disturbance grooves (37), and one end of each reset spring (38) is fixedly connected to the opposite side of the two length plates (32).

6. A cooling mechanism for a water electrolysis hydrogen production machine according to claim 1, characterized in that: The tops of both disturbance plates (34) are rotatably connected to the middle of the bottom of the cooling platform (4).

7. A cooling mechanism for a water electrolysis hydrogen production machine according to claim 1, characterized in that: Several of the heat-conducting pipes (5) are made of copper.