CN222263433U - Modularized electrolytic hydrogen production power supply - Google Patents

Abstract

The utility model discloses a modular electrolytic hydrogen production power supply, including a casing, a mounting slot 1 is provided in the casing, a mounting slot 2 is provided in the casing and located on one side of the mounting slot 1, a mounting frame is provided in the mounting slot 1, a plurality of evenly distributed power unit modules are provided on the mounting frame, a reciprocating mechanism is provided in the mounting slot 2, a symmetrically arranged heat dissipation fan is provided in the mounting slot 1, two groups of heat dissipation fans are connected to the reciprocating mechanism, a refrigeration box is provided in the mounting slot 2, and the air inlet ends of the two groups of heat dissipation fans are connected to the refrigeration box through a flow hose. Beneficial effect: by providing a reciprocating mechanism, the two groups of heat dissipation fans can be driven to move up and down to expand their blowing area and improve the heat dissipation efficiency, prevent the power unit module from being damaged due to untimely heat dissipation, and improve its safety.

Description

Modularized electrolytic hydrogen production power supply

Technical Field

The utility model relates to the technical field of power supplies, in particular to a modularized electrolytic hydrogen production power supply.

Background

At present, the power requirement of the power supply needed in the electrolytic hydrogen production industry is higher, and according to different capacity requirements, the power supply with different power output is needed, the conventional power supply is matched with a plurality of energy level requirements, the maximum power design mode is adopted, so that the occasions with various different power requirements can be met, the existing power supply is mainly used for radiating the heat by arranging a fan in the power supply, and the fan is fixedly arranged in the power supply box and is limited in blowing area, so that the plurality of power supply unit modules in the power supply box cannot be quickly radiated.

For the problems in the related art, no effective solution has been proposed at present.

Disclosure of utility model

Aiming at the problems in the related art, the utility model provides a modularized electrolytic hydrogen production power supply, which aims to overcome the technical problems in the prior related art.

For this purpose, the utility model adopts the following specific technical scheme:

The utility model provides a modularization electrolysis hydrogen manufacturing power, includes the casing, set up mounting groove one in the casing, just be located mounting groove one-to-one has seted up mounting groove two in the casing, be equipped with the mounting bracket in the mounting groove one, be equipped with a plurality of power unit modules that evenly distribute on the mounting bracket, be equipped with reciprocating mechanism in the mounting groove two, be equipped with the radiator fan that the symmetry set up in the mounting groove one, two sets of radiator fan all with reciprocating mechanism is connected, be equipped with the refrigeration case in the mounting groove two, two sets of radiator fan inlet end all through the circulation hose with the refrigeration case is linked together.

Preferably, the mounting frame is connected with the casing through a fixing block.

Preferably, a first sealing door matched with the first mounting groove is arranged on one side of the casing, and a second sealing door matched with the second mounting groove is arranged on one side of the casing.

Preferably, the semiconductor refrigeration plates are symmetrically arranged in the refrigeration box, and an air inlet communicated with the refrigeration box is formed in one side of the machine shell.

Preferably, a filter screen matched with the air inlet is arranged in the air inlet.

Preferably, the reciprocating mechanism comprises symmetrically arranged guide plates arranged on the inner wall of the second mounting groove, gears are arranged between the two groups of guide plates, the gears are connected with the casing through rotating shafts, a first rack and a second rack which are meshed with the gears are arranged on two sides of the gears, a T-shaped limiting slide block is arranged on one side of each of the first rack and the second rack, T-shaped sliding grooves matched with the T-shaped limiting slide block are formed in one side of the guide plate, and the first rack and the second rack are connected with the two groups of cooling fans through connecting rods respectively.

Preferably, the casing is provided with a through hole matched with the connecting rod.

Preferably, the rack one-to-one sides are provided with travel plates, travel grooves are formed in one sides of the travel plates, L-shaped mounting frames are arranged on the inner walls of the travel grooves, motors are arranged on one sides of the L-shaped mounting frames, the driving ends of the motors penetrate through the L-shaped mounting frames and are connected with rotating plates, and extrusion blocks extending into the travel grooves are arranged on one sides of the rotating plates.

The utility model has the beneficial effects that the reciprocating mechanism can drive the two groups of heat dissipation fans to reciprocate up and down to enlarge the blowing area of the heat dissipation fans, improve the heat dissipation efficiency, prevent the damage caused by untimely heat dissipation of the power unit module and improve the safety of the power unit module.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and 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 a modular electrolytic hydrogen generation power supply in accordance with an embodiment of the present utility model;

FIG. 2 is a front view of a modular electrolytic hydrogen production power supply in accordance with an embodiment of the present utility model;

FIG. 3 is a cross-sectional view of a modular electrolytic hydrogen production power supply in accordance with an embodiment of the present utility model;

FIG. 4 is a schematic diagram of the structure of a reciprocating mechanism in a modular electrolytic hydrogen production power supply in accordance with an embodiment of the present utility model;

FIG. 5 is a schematic view of another angle of the reciprocating mechanism in a modular electrolytic hydrogen generation power supply in accordance with an embodiment of the present utility model;

fig. 6 is a right side view of a reciprocating mechanism in a modular electrolytic hydrogen generation power supply in accordance with an embodiment of the present utility model.

In the figure:

1. The device comprises a shell, a first mounting groove, a second mounting groove, a rotating plate, a 5 mounting frame, a 6 power supply unit module, a 7 heat dissipation fan, a 8 refrigerating box, a 9 circulating hose, a 10 sealing door, a 11 sealing door, a second sealing door, a 12 fixing block, a 13 semiconductor refrigerating plate, a 14 air inlet, a 15 guiding plate, a 16 gear, a 17 rack, a 18 rack, a second rack, a 19T-shaped limiting slide block, a 20 through hole, a 21 stroke plate, a 22 stroke groove, a 23L-shaped mounting frame, a 24 motor, a 25 and a connecting rod.

Detailed Description

For the purpose of further illustrating the various embodiments, the present utility model provides the accompanying drawings, which are a part of the disclosure of the present utility model, and which are mainly used to illustrate the embodiments and, together with the description, serve to explain the principles of the embodiments, and with reference to these descriptions, one skilled in the art will recognize other possible implementations and advantages of the present utility model, wherein elements are not drawn to scale, and like reference numerals are generally used to designate like elements.

According to an embodiment of the utility model, a modular electrolytic hydrogen production power supply is provided.

Embodiment one;

As shown in fig. 1-6, the modularized electrolytic hydrogen production power supply according to the embodiment of the utility model comprises a casing 1, wherein a first installation groove 2 is formed in the casing 1, a second installation groove 3 is formed in the casing 1 and positioned at one side of the first installation groove 2, a mounting frame 5 is arranged in the first installation groove 2, a plurality of uniformly distributed power supply unit modules 6 are arranged on the mounting frame 5, a reciprocating mechanism is arranged in the second installation groove 3, symmetrically arranged heat dissipation fans 7 are arranged in the first installation groove 2, two groups of heat dissipation fans 7 are connected with the reciprocating mechanism, a refrigerating box 8 is arranged in the second installation groove 3, and the air inlet ends of the two groups of heat dissipation fans 7 are communicated with the refrigerating box 8 through a circulating hose 9.

Embodiment two;

As shown in fig. 1-6, the modularized electrolytic hydrogen production power supply according to the embodiment of the utility model comprises a casing 1, wherein a first installation groove 2 is formed in the casing 1, a second installation groove 3 is formed in the casing 1 and positioned at one side of the first installation groove 2, a mounting frame 5 is arranged in the first installation groove 2, a plurality of uniformly distributed power supply unit modules 6 are arranged on the mounting frame 5, a reciprocating mechanism is arranged in the second installation groove 3, symmetrically arranged heat dissipation fans 7 are arranged in the first installation groove 2, two groups of heat dissipation fans 7 are connected with the reciprocating mechanism, a refrigerating box 8 is arranged in the second installation groove 3, and the air inlet ends of the two groups of heat dissipation fans 7 are communicated with the refrigerating box 8 through a circulating hose 9. The mounting frame 5 is connected with the casing 1 through a fixing block 12. One side of the machine shell 1 is provided with a first sealing door 10 matched with the first mounting groove 2, and one side of the machine shell 1 is provided with a second sealing door 11 matched with the second mounting groove 3. The refrigerating box 8 is internally provided with symmetrically arranged semiconductor refrigerating plates 13, and one side of the casing 1 is provided with an air inlet 14 communicated with the refrigerating box 8. The air inlet 14 is provided with a filter screen matched with the air inlet. When the power unit module 6 is cooled, the semiconductor refrigeration plate 13 in the refrigeration box 8 is started firstly, the semiconductor refrigeration plate 13 starts to refrigerate, then the cooling fan 7 is started to convey cold air in the refrigeration box 8 into the first installation groove 2 through the circulating hose 9 to cool, and the temperature in the first installation groove 2 can be cooled rapidly through the arrangement of the refrigeration box 8 and the semiconductor refrigeration plate 13.

Embodiment three;

As shown in fig. 1-6, the modularized electrolytic hydrogen production power supply according to the embodiment of the utility model comprises a casing 1, wherein a first installation groove 2 is formed in the casing 1, a second installation groove 3 is formed in the casing 1 and positioned at one side of the first installation groove 2, a mounting frame 5 is arranged in the first installation groove 2, a plurality of uniformly distributed power supply unit modules 6 are arranged on the mounting frame 5, a reciprocating mechanism is arranged in the second installation groove 3, symmetrically arranged heat dissipation fans 7 are arranged in the first installation groove 2, two groups of heat dissipation fans 7 are connected with the reciprocating mechanism, a refrigerating box 8 is arranged in the second installation groove 3, and the air inlet ends of the two groups of heat dissipation fans 7 are communicated with the refrigerating box 8 through a circulating hose 9. The reciprocating mechanism comprises symmetrically arranged guide plates 15 arranged on the inner wall of a second mounting groove 3, gears 16 are arranged between the two groups of guide plates 15, the gears 16 are connected with the casing 1 through rotating shafts, racks I17 and racks II 18 meshed with the gears 16 are arranged on two sides of the gears 16, T-shaped limit sliding blocks 19 are arranged on one sides, away from the gears 16, of the racks I17, the racks II 18, T-shaped sliding grooves matched with the T-shaped limit sliding blocks 19 are formed in one side of the guide plates 15, and the racks I17 and the racks II 18 are connected with two groups of heat dissipation fans 7 through connecting rods 25 respectively. The casing 1 is provided with a through hole 20 matched with the connecting rod 25. The first rack 17 side is equipped with travel plate 21, travel plate 21 one side has seted up travel groove 22, be equipped with L type mounting bracket 23 on the travel groove 22 inner wall, L type mounting bracket 23 one side is equipped with motor 24, motor 24 drive end runs through L type mounting bracket 23 is connected with rotor plate 4, rotor plate 4 one side is equipped with and extends to extrusion piece in the travel groove 22. When the heat dissipation fan 7 starts the motor 24 in the operation, the motor 24 drives the rotating plate 4 to rotate, the rotating plate 4 extrudes the inner wall of the travel groove 22 through the extrusion block, so that the travel plate 21 drives the rack I17 to reciprocate up and down, the rack I17 drives the rack II 18 to reciprocate up and down through the gear 16, the rack I17 and the rack II 18 respectively drive the two groups of heat dissipation fans 7 to reciprocate up and down, the reciprocating mechanism can drive the two groups of heat dissipation fans to reciprocate up and down to enlarge the blowing area of the heat dissipation fan, the heat dissipation efficiency is improved, the power supply unit module is prevented from being damaged due to untimely heat dissipation, and the safety is improved.

When the cooling fan 7 is in operation, the motor 24 is started, the rotating plate 4 is driven to rotate by the motor 24, the rotating plate 4 presses the inner wall of the stroke groove 22 through the extrusion block, the stroke plate 21 drives the rack one 17 to reciprocate up and down, the rack one 17 and the rack two 18 drive the two groups of cooling fans 7 to reciprocate up and down respectively through the gear 16, the two groups of cooling fans can be driven to reciprocate up and down through the reciprocating mechanism to enlarge the blowing area of the cooling fan to improve the cooling efficiency, the power unit module is prevented from being damaged in time, and the safety is improved.

In summary, by means of the technical scheme of the utility model, the reciprocating mechanism can drive the two groups of heat dissipation fans to reciprocate up and down to enlarge the blowing area of the heat dissipation fans, so that the heat dissipation efficiency is improved, the damage caused by untimely heat dissipation of the power unit module is prevented, and the safety of the power unit module is improved.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (8)

1. The utility model provides a modularization electrolysis hydrogen manufacturing power, its characterized in that, including casing (1), set up mounting groove one (2) in casing (1), just be located in mounting groove one (2) one side has seted up mounting groove two (3), be equipped with mounting bracket (5) in mounting groove one (2), be equipped with power unit module (6) of a plurality of all distributions on mounting bracket (5), be equipped with reciprocating mechanism in mounting groove two (3), be equipped with radiator fan (7) of symmetry setting in mounting groove one (2), two sets of radiator fan (7) all with reciprocating mechanism is connected, be equipped with refrigeration case (8) in mounting groove two (3), two sets of radiator fan (7) inlet end all be linked together through circulation hose (9) with refrigeration case (8).

2. A modular electrolytic hydrogen production power supply according to claim 1, characterized in that the mounting frame (5) is connected to the housing (1) by means of a fixed block (12).

3. A modular electrolytic hydrogen production power supply according to claim 1, characterized in that a first door (10) matched with the first mounting groove (2) is arranged on one side of the casing (1), and a second door (11) matched with the second mounting groove (3) is arranged on one side of the casing (1).

4. A modular electrolytic hydrogen production power supply according to claim 1, characterized in that the refrigeration box (8) is provided with symmetrically arranged semiconductor refrigeration plates (13), and an air inlet (14) communicated with the refrigeration box (8) is formed in one side of the casing (1).

5. A modular electrolytic hydrogen production power supply according to claim 4, characterized in that the air inlet (14) is provided with a filter mesh matching it.

6. The modularized electrolytic hydrogen production power supply according to claim 1, wherein the reciprocating mechanism comprises symmetrically arranged guide plates (15) arranged on the inner wall of the second mounting groove (3), gears (16) are arranged between the two groups of guide plates (15), the gears (16) are connected with the casing (1) through rotating shafts, racks I (17) and racks II (18) meshed with the gears (16) are arranged on two sides of the gears (16), T-shaped limit sliding blocks (19) are arranged on one side, away from the gears (16), of the racks I (17) and the racks II (18), T-shaped sliding grooves matched with the T-shaped limit sliding blocks (19) are formed on one side of the guide plates (15), and the racks I (17) and the racks II (18) are respectively connected with the two groups of heat dissipation fans (7) through connecting rods (25).

7. A modular electrolytic hydrogen production power supply according to claim 6, characterized in that the casing (1) is provided with a through hole (20) matching the connecting rod (25).

8. The modularized electrolytic hydrogen production power supply according to claim 6, wherein a travel plate (21) is arranged on one side of the rack I (17), a travel groove (22) is formed in one side of the travel plate (21), an L-shaped mounting frame (23) is arranged on the inner wall of the travel groove (22), a motor (24) is arranged on one side of the L-shaped mounting frame (23), a driving end of the motor (24) penetrates through the L-shaped mounting frame (23) to be connected with a rotating plate (4), and a squeezing block extending into the travel groove (22) is arranged on one side of the rotating plate (4).