CN220352248U - Pure water hydrogen production PEM electrolytic tank - Google Patents

Abstract

The utility model discloses a pure water hydrogen production PEM (proton exchange membrane) electrolytic cell, and relates to the technical field of electrolytic cells; the utility model comprises a hydrogen production electrolytic tank, wherein an electrolytic cell plate is movably connected in the hydrogen production electrolytic tank; when the movable type electrolysis cell plate is used, the lifting tube is required to move downwards, when the lifting tube moves downwards, the lifting tube drives the plug blocks to move together, then the plug blocks are taken out of the plug grooves, meanwhile, the lifting tube moves on the reinforcing rod and continuously applies force to the limiting springs, the limiting springs continuously shrink on the reinforcing rod, then the electrolysis cell plates are moved, the distance between the two electrolysis cell plates is adjusted, after the distance between the two electrolysis cell plates is adjusted, the lifting tube is required to be loosened, then the limiting springs push the lifting tube to move upwards, then the plug blocks are enabled to move upwards, then the plug blocks enter the plug grooves, so that the electrolysis cell plates are fixed, an installation tool is not required when the electrolysis cell plates are fixed, the installation steps are simple, and convenience when personnel are installed is greatly improved.

Description

Pure water hydrogen production PEM electrolytic tank

Technical Field

The utility model relates to the technical field of electrolytic tanks, in particular to a pure water hydrogen production PEM electrolytic tank.

Background

When pure water hydrogen production is carried out, a pure water hydrogen production PEM electrolytic tank is needed, the pure water hydrogen production is carried out in the pure water hydrogen production PEM electrolytic tank, the pure water hydrogen production PEM electrolytic tank consists of a tank body, an anode and a cathode, an anode chamber and a cathode chamber are separated by a diaphragm, and when the existing pure water hydrogen production PEM electrolytic tank is used, the operation steps are simple, the carrying of personnel is convenient, but the problems of inconvenience still exist;

at present, when the existing pure water hydrogen production PEM electrolytic tank is used, personnel can fix a diaphragm mechanism used for placing an electrolytic diaphragm in the electrolytic tank, when the diaphragm mechanism moves, the electrolytic diaphragm can be moved, and then a certain influence is caused on the hydrogen production process, when the diaphragm mechanism is fixed, various installation fixing tools are needed, and then when the diaphragm mechanism is installed, the personnel are needed to prepare various installation tools in advance, and then convenience of personnel during installation is reduced.

In view of the above, the inventors propose a pure water hydrogen production PEM electrolyzer to solve the above problems.

Disclosure of Invention

In order to solve the problems that when the diaphragm mechanism in the electrolytic tank is fixed, a plurality of installation and fixing tools are needed, and then a person needs to prepare a plurality of installation tools in advance during installation, so that the convenience of the person during installation is reduced; the utility model aims to provide a pure water hydrogen production PEM electrolytic tank.

In order to solve the technical problems, the utility model adopts the following technical scheme: the utility model provides a pure water hydrogen manufacturing PEM electrolysis trough, including hydrogen manufacturing electrolysis trough, the inside swing joint of hydrogen manufacturing electrolysis trough has the electrolysis cell board, first reinforcement groove has been seted up on the inside wall of hydrogen manufacturing electrolysis trough, first reinforcement groove's inside grafting has first reinforcement piece, in the in-process that electrolysis cell board removed, first reinforcement piece will move in first reinforcement groove, the second reinforcement groove has been seted up on the inner wall of first reinforcement groove, the inside grafting of second reinforcement groove has the second reinforcement piece, first reinforcement piece and second reinforcement piece fixed connection, in the in-process that electrolysis cell board removed, utilize the second reinforcement piece, can improve the steadiness when first reinforcement piece removes, the equal fixedly connected with reinforcing rod in both sides at electrolysis cell board top, the surface swing joint of reinforcing rod has spacing spring, the top fixedly connected with lifter of spacing spring, the fixed surface fixedly connected with of lifter, the removal auxiliary ring utilizes the removal auxiliary ring, the personnel of being convenient for remove the lifter, first reinforcement piece is connected with electrolysis cell board fixed connection, the lifter down, it will continue to limit spring to shrink its inside grafting, the top fixedly connected with lifter plate, the lifter plate is equipped with the fixed connection who has the fixed connection of plug-in groove, the fixed connection is equipped with the fixed connection of two sides in the fixed connection of plug-in the electrolysis cell board, the fixed connection of plug-in the fixed connection has the fixed connection of two sides of plug board to the fixed connection of the electrolysis cell board, the plug-in the fixed connection of the plug board has the fixed connection of the electrolysis cell board.

Preferably, the equal fixedly connected with of both sides of hydrogen manufacturing electrolysis trough bottom removes the regulating plate, remove the bottom swing joint of regulating plate and have adjusted the base, the regulating tank with remove regulating plate looks adaptation has been seted up at the top of adjusting the base, the regulation hole has all been seted up to one side of removing regulating plate and adjusting the base, the inside threaded connection in regulation hole has the regulating rod, after removing hydrogen manufacturing electrolysis trough to suitable height, only need install the regulating rod in the regulation hole, it is fixed with removing the regulating plate, the bottom fixedly connected with reinforcement rubber piece of adjusting the base, the one end fixedly connected with rotatory piece of regulating rod, utilize rotatory piece, the personnel of being convenient for rotate the regulating rod, the surface of rotatory piece is provided with rotatory friction line.

Preferably, the lifting inserting groove is formed in the inner wall of the adjusting groove, the lifting inserting block is inserted into the lifting inserting groove and can move along with the movable adjusting plate, and the lifting inserting block is utilized to prevent the movable adjusting plate from being separated from the adjusting base, so that the top of the lifting inserting block is fixedly connected with the bottom of the movable adjusting plate.

Compared with the prior art, the utility model has the beneficial effects that:

1. when the movable type electrolysis cell plate is used, the lifting tube is required to move downwards, when the lifting tube moves downwards, the lifting tube drives the plug blocks to move together, then the plug blocks are taken out of the plug grooves, meanwhile, the lifting tube moves on the reinforcing rod and continuously applies force to the limiting springs, the limiting springs continuously shrink on the reinforcing rod, then the electrolysis cell plates are moved, the distance between the two electrolysis cell plates is adjusted, after the distance between the two electrolysis cell plates is adjusted, the lifting tube is required to be loosened, then the limiting springs push the lifting tube to move upwards, then the plug blocks are enabled to move upwards, then the plug blocks enter the plug grooves, so that the electrolysis cell plates are fixed, an installation tool is not required when the electrolysis cell plates are fixed, the installation steps are simple, and convenience when personnel are installed is greatly improved.

2. When the hydrogen production electrolytic cell is used, a person can move up and down, when the hydrogen production electrolytic cell moves up and down, the movable adjusting plate is driven to move together, after the hydrogen production electrolytic cell is moved to a proper height, the adjusting rod is only required to be arranged in the adjusting hole, so that the movable adjusting plate is fixed, and therefore, the electrolytic cell is convenient for the person to adjust the height suitable for operation, and further, the operation is convenient for the person with different heights.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic structural view of an adjusting base in the present utility model.

Fig. 3 is a schematic structural view of a first reinforcing block according to the present utility model.

Fig. 4 is a schematic structural view of a second fixing plate according to the present utility model.

In the figure: 1. a hydrogen production electrolytic tank; 2. an electrolysis cell plate; 3. a reinforcing rod; 4. a limit spring; 5. a lifting tube; 6. a plug block; 7. a first fixing plate; 8. a second fixing plate; 9. a plug-in groove; 10. a handle; 11. a first reinforcing groove; 12. a first reinforcing block; 13. a movement auxiliary ring; 14. a second reinforcing groove; 15. a second reinforcing block; 16. moving the adjusting plate; 17. adjusting the base; 18. an adjustment tank; 19. an adjustment aperture; 20. an adjusting rod; 21. reinforcing the rubber block; 22. a rotating block; 23. lifting the inserting groove; 24. lifting the plug-in block.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples: as shown in fig. 1-4, the utility model provides a pure water hydrogen production PEM electrolytic cell, which comprises a hydrogen production electrolytic cell 1, wherein an electrolytic cell plate 2 is movably connected in the hydrogen production electrolytic cell 1, both sides of the top of the electrolytic cell plate 2 are fixedly connected with reinforcing rods 3, the surfaces of the reinforcing rods 3 are movably connected with limiting springs 4, the top ends of the limiting springs 4 are fixedly connected with lifting tubes 5, when the lifting tubes 5 move downwards, the limiting springs 4 are pressed to continuously shrink, the top ends of the lifting tubes 5 are fixedly connected with plug-in blocks 6, when the lifting tubes 5 move upwards, the plug-in blocks 6 are driven to move upwards, both sides of the top of the hydrogen production electrolytic cell 1 are fixedly connected with first fixing plates 7, one side of each first fixing plate 7 is fixedly connected with a second fixing plate 8, and the bottoms of the second fixing plates 8 are provided with plug-in grooves 9 matched with the plug-in blocks 6, and when the pure water hydrogen production electrolytic cell plate 2 is used, the plug-in blocks 6 need to be plugged into the plug-in grooves 9 to fix the electrolytic cell plate 2.

The plug-in block 6 is plugged in the plug-in groove 9, and handles 10 are fixedly connected to the two sides of the hydrogen production electrolytic tank 1.

By adopting the technical scheme, the handle 10 is utilized, so that personnel can conveniently move the hydrogen production electrolytic tank 1.

The inner side wall of the hydrogen production electrolytic tank 1 is provided with a first reinforcing groove 11, and a first reinforcing block 12 is inserted into the first reinforcing groove 11.

By adopting the above technical scheme, the first reinforcing block 12 will move in the first reinforcing groove 11 during the movement of the electrolytic cell plate 2.

The surface of the lifting pipe 5 is fixedly connected with a movable auxiliary ring 13, and the first reinforcing block 12 is fixedly connected with the electrolytic cell plate 2.

By adopting the above technical scheme, the lift pipe 5 is convenient for personnel to move by utilizing the movable auxiliary ring 13.

The inner wall of the first reinforcing groove 11 is provided with a second reinforcing groove 14, a second reinforcing block 15 is inserted into the second reinforcing groove 14, and the first reinforcing block 12 is fixedly connected with the second reinforcing block 15.

By adopting the above technical scheme, the second reinforcing block 15 is utilized in the process of moving the electrolytic cell plate 2, so that the stability of the first reinforcing block 12 during movement can be improved.

The two sides of the bottom of the hydrogen production electrolytic tank 1 are fixedly connected with a movable adjusting plate 16, the bottom of the movable adjusting plate 16 is movably connected with an adjusting base 17, an adjusting groove 18 matched with the movable adjusting plate 16 is formed in the top of the adjusting base 17, adjusting holes 19 are formed in one sides of the movable adjusting plate 16 and the adjusting base 17, an adjusting rod 20 is connected with the inner threads of the adjusting holes 19, and a reinforcing rubber block 21 is fixedly connected with the bottom of the adjusting base 17.

Through adopting above-mentioned technical scheme, personnel can reciprocate hydrogen manufacturing electrolysis trough 1, and when hydrogen manufacturing electrolysis trough 1 reciprocates, it will drive and remove regulating plate 16 and remove together, after removing hydrogen manufacturing electrolysis trough 1 to suitable height, only need install regulating rod 20 in regulating hole 19 to with remove regulating plate 16 fixed can, utilize reinforcement rubber piece 21, can improve the steadiness when adjusting base 17 on the platform.

One end of the adjusting rod 20 is fixedly connected with a rotating block 22, and the surface of the rotating block 22 is provided with rotating friction lines.

By adopting the above technical scheme, the rotary block 22 is utilized, so that the personnel can conveniently rotate the adjusting rod 20.

The inner wall of the adjusting groove 18 is provided with a lifting inserting groove 23, the lifting inserting block 24 is inserted in the lifting inserting groove 23, and the top of the lifting inserting block 24 is fixedly connected with the bottom of the movable adjusting plate 16.

By adopting the above technical scheme, the lifting plug-in block 24 can move along with the movement adjusting plate 16, and the lifting plug-in block 24 can prevent the movement adjusting plate 16 from being separated from the adjusting base 17.

Working principle: when in use, the diaphragm is arranged between the two electrolytic cell plates 2, the anode chamber and the cathode chamber are separated by the diaphragm, when direct current passes through the hydrogen production electrolytic tank 1, oxidation reaction occurs at the interface between the anode and the solution, reduction reaction occurs at the interface between the cathode and the solution, so as to prepare hydrogen, in the use process, the lifting tube 5 is required to be moved downwards, when the lifting tube 5 is moved downwards, the lifting tube 5 drives the inserting block 6 to move together, the inserting block 6 is further taken out from the inserting groove 9, meanwhile, the lifting tube 5 moves on the reinforcing rod 3 and continuously applies force to the limiting spring 4, the limiting spring 4 is continuously contracted on the reinforcing rod 3, then the electrolytic cell plates 2 are moved, the distance between the two electrolytic cell plates 2 is adjusted, after the distance between the two electrolytic cell plates 2 is adjusted, the lifting tube 5 is required to be released, then the limiting spring 4 pushes the lifting tube 5 to move upwards, the plug-in block 6 is moved upwards, the plug-in block 6 enters the plug-in groove 9, so that the electrolytic cell plate 2 is fixed, an installation tool is not required when the electrolytic cell plate 2 is fixed, the installation step is simple, the convenience of personnel installation is greatly improved, in the process of moving the electrolytic cell plate 2, the first reinforcing block 12 moves in the first reinforcing groove 11, the second reinforcing block 15 moves in the second reinforcing groove 14, the stability of the electrolytic cell plate 2 when moving in the hydrogen production electrolytic cell 1 can be improved by utilizing the first reinforcing block 12, the stability of the first reinforcing block 12 when moving can be improved by utilizing the second reinforcing block 15, the personnel can move the hydrogen production electrolytic cell 1 up and down when the hydrogen production electrolytic cell 1 moves up and down, the movable regulating plate 16 is driven to move together, the hydrogen production electrolytic cell 1 moves to a proper height, the adjusting rod 20 is only required to be arranged in the adjusting hole 19 so as to fix the movable adjusting plate 16, so that the electrolytic tank is convenient for personnel to adjust the height suitable for operation, and further is convenient for personnel with different heights to operate.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (8)

1. A pure water hydrogen production PEM electrolyzer, comprising a hydrogen production electrolyzer (1), characterized in that: the hydrogen production electrolytic cell comprises a hydrogen production electrolytic cell body (1), wherein an electrolytic cell plate (2) is movably connected to the inside of the hydrogen production electrolytic cell body (1), reinforcing rods (3) are fixedly connected to two sides of the top of the electrolytic cell plate (2), limiting springs (4) are movably connected to the surfaces of the reinforcing rods (3), lifting tubes (5) are fixedly connected to the tops of the limiting springs (4), plug-in blocks (6) are fixedly connected to the tops of the lifting tubes (5), first fixing plates (7) are fixedly connected to two sides of the top of the hydrogen production electrolytic cell body (1), second fixing plates (8) are fixedly connected to one sides of the first fixing plates (7), and plug-in grooves (9) matched with the plug-in blocks (6) are formed in the bottoms of the second fixing plates (8).

2. A pure water hydrogen production PEM electrolyzer as in claim 1 characterized in that said plug-in block (6) is plugged into the interior of said plug-in slot (9), both sides of said hydrogen production electrolyzer (1) being fixedly connected with handles (10).

3. A pure water hydrogen production PEM electrolyser as claimed in claim 2 wherein said hydrogen production electrolyser (1) has a first reinforcing groove (11) on its inner side wall, said first reinforcing groove (11) having a first reinforcing block (12) inserted therein.

4. A pure water hydrogen production PEM electrolyser as claimed in claim 3 wherein said riser (5) has a surface fixedly connected with a mobile auxiliary ring (13), said first reinforcing block (12) being fixedly connected with said electrolyser plate (2).

5. A pure water hydrogen production PEM electrolytic cell as claimed in claim 4 wherein said first reinforcing groove (11) has a second reinforcing groove (14) on its inner wall, said second reinforcing groove (14) having a second reinforcing block (15) inserted therein, said first reinforcing block (12) being fixedly connected to said second reinforcing block (15).

6. The pure water hydrogen production PEM electrolytic tank according to claim 5, wherein two sides of the bottom of the hydrogen production electrolytic tank (1) are fixedly connected with a movable adjusting plate (16), the bottom of the movable adjusting plate (16) is movably connected with an adjusting base (17), an adjusting groove (18) which is matched with the movable adjusting plate (16) is formed in the top of the adjusting base (17), adjusting holes (19) are formed in one sides of the movable adjusting plate (16) and one side of the adjusting base (17), adjusting rods (20) are connected with internal threads of the adjusting holes (19), and reinforcing rubber blocks (21) are fixedly connected to the bottom of the adjusting base (17).

7. A pure water hydrogen production PEM electrolyser as claimed in claim 6 wherein one end of said regulating rod (20) is fixedly connected with a rotating block (22), the surface of said rotating block (22) being provided with rotating friction lines.

8. A pure water hydrogen production PEM electrolytic cell according to claim 7 characterized in that, a lifting inserting groove (23) is provided on the inner wall of said adjusting groove (18), a lifting inserting block (24) is inserted in the lifting inserting groove (23), the top of said lifting inserting block (24) is fixedly connected with the bottom of said movable adjusting plate (16).