CN221924215U - Be used for photovoltaic equipment and components and parts to make heat abstractor - Google Patents

Abstract

The utility model discloses a heat dissipation device for photovoltaic equipment and component manufacturing, and relates to the technical field of heat dissipation devices; the utility model comprises a base plate, a heat dissipation box is fixedly installed on the top of the base plate, symmetrically distributed exhaust holes are provided on the top of the heat dissipation box, symmetrically distributed support rods are fixedly installed on the side of the top of the base plate away from the heat dissipation box, guide rails are fixedly installed on the tops of two support rods, one end of the guide rail away from the support rod is located inside the heat dissipation box, a placement frame is slidably provided on the tops of the two guide rails, symmetrically distributed clamping rods are fixedly installed on the bottom ends of the placement frames, and clamping grooves are provided on the tops of the guide rails; the utility model sets a lifting plate, a first rotating shaft and a second rotating shaft, so that the movable plate can be raised and lowered, thereby avoiding leakage of cold air in the heat dissipation box, improving the heat dissipation effect of the components, and at the same time, when the outside temperature is high, it can also reduce the impact.

Description

A heat dissipation device for photovoltaic equipment and component manufacturing

Technical Field

The utility model relates to the technical field of heat dissipation devices, in particular to a heat dissipation device used for manufacturing photovoltaic equipment and components.

Background Art

Photovoltaic equipment refers to equipment that uses the photovoltaic effect to convert solar energy into electrical energy. Specifically, this conversion process is achieved through solar cells, which directly convert sunlight into electrical energy; electronic components are components of electronic components and small machines and instruments. They are often composed of several parts and can be used in similar products; they often refer to certain parts of electrical appliances, radios, instruments and other industries, and are a general term for electronic devices such as capacitors, transistors, hairsprings, and springs; common ones include diodes, etc.;

Publication No. CN218993774U discloses a heat dissipation device for photovoltaic equipment and component manufacturing, including a device body, a belt is arranged below the device body, a pulley is arranged inside the belt and a fixed arm is arranged on the outer wall, a cooling box is arranged on the outer side of the fixed arm, a base is arranged below the cooling box, and components are arranged inside, a blower is arranged on the base, an air inlet channel is arranged on the blower, a cooler is arranged on the air inlet channel, a cold air channel is arranged below the cooler, a fixing plate is arranged above the component, and an extension plate is arranged below the fixing plate, which can quickly and comprehensively dissipate heat for the component, improve the work efficiency of the staff, provide convenience for the user, and can also fix and limit the component, reduce the shaking of the component, ensure the safety of the device during heat dissipation, and solve the problem of uneven heat dissipation of heat dissipation devices for photovoltaic equipment and component manufacturing in the prior art;

The above patent uses a blower to dissipate heat from components when in use, but the cooling box in the above patent is not sealed, which easily leads to poor cooling effect of the blower when the outside temperature is high, and also increases the energy consumption of the blower and increases the cost;

In view of the above problems, the inventors propose a heat dissipation device for photovoltaic equipment and component manufacturing to solve the above problems.

Utility Model Content

In order to solve the problem that the outside air easily affects the cooling effect of components, the purpose of the utility model is to provide a heat dissipation device for photovoltaic equipment and component manufacturing.

To solve the above technical problems, the utility model adopts the following technical scheme: a heat dissipation device for photovoltaic equipment and component manufacturing, comprising a base plate, a heat dissipation box is fixedly installed on the top of the base plate, and the top of the heat dissipation box is provided with symmetrically distributed exhaust holes, and a symmetrically distributed support rod is fixedly installed on the side of the top of the base plate away from the heat dissipation box, and a guide rail is fixedly installed on the top of two support rods, and one end of the guide rail away from the support rod is located inside the heat dissipation box, and a placement frame is slidably provided at the top of the two guide rails, and a symmetrically distributed clamping rod is fixedly installed on the bottom end of the placement frame, and a clamping groove is provided on the top of the guide rail, and the clamping rod is movably clamped in the clamping groove, and a mounting plate is fixedly installed on the bottom end of the placement frame, and a second electric push rod is provided on the side of the mounting plate away from the heat dissipation box, and the output end of the second electric push rod is fixedly connected to the mounting plate, and the two support rods are fixedly installed on the top of the two support rods. A support plate is fixedly installed on the opposite sides of the support rod, the second electric push rod is fixedly installed on the top of the support plate, an empty groove is opened in the middle of the placement frame, and a symmetrically distributed lifting plate is fixedly installed on the top of the placement frame, and both sides of the lifting plate are distributed in an arc state. A movable plate is movably provided on one side of the heat dissipation box close to the lifting plate, and symmetrically distributed fixed plates are fixedly installed on both sides of the movable plate, and symmetrically distributed connecting blocks are fixedly installed on the bottom end of the fixed plate, and a first rotating shaft is rotatably installed on the bottom of the two connecting blocks, and a symmetrically distributed second rotating shaft is rotatably installed on the bottom of the movable plate, and the first rotating shaft and the second rotating shaft are used in conjunction with the lifting plate, a box body is fixedly installed on the lower surface of the inner wall of the heat dissipation box, a first fan is fixedly installed inside the box body, and evenly distributed condensing tubes are fixedly installed on the opposite sides of the inner wall of the top of the box body.

Preferably, a stabilizing frame is fixedly installed on the upper surface of the inner wall of the heat dissipation box, a first electric push rod is fixedly installed on the bottom end of the stabilizing frame, a moving frame is fixedly installed on the output end of the first electric push rod, evenly distributed heat conducting plates are fixedly installed on the opposite sides of the inner wall of the moving frame, second fans are fixedly installed on both sides of the moving frame, and the two second fans are distributed diagonally.

Preferably, a limiting plate is fixedly mounted on a side of the inner wall of the heat dissipation box away from the movable plate.

Compared with the prior art, the beneficial effects of the utility model are:

1. By setting the lifting plate, the first rotating shaft and the second rotating shaft, the movable plate can be raised and lowered, thereby preventing the cold air in the heat dissipation box from leaking out, improving the heat dissipation effect of the components, and at the same time reducing the impact when the outside temperature is high;

2. By driving the output end of the first electric push rod downward, the movable frame and the heat conducting plate are driven downward, so that the heat conducting plate and the components come into contact, and the heat conducting plate absorbs the heat on the surface of the components. Then, the heat conducting plate is driven to cool down the second fan, thereby further improving the cooling effect of the components and accelerating the cooling efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings required for use in the embodiments or the description of the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the utility model. For ordinary technicians in this field, other drawings can be obtained based on these drawings without paying creative work.

FIG1 is a schematic diagram of the overall structure of the utility model.

FIG. 2 is a schematic structural diagram of a placement frame in the present invention.

FIG. 3 is a schematic diagram of the structure of the first rotating shaft and the second rotating shaft in the present invention.

FIG. 4 is a schematic diagram of the structure inside the heat dissipation box of the present invention.

FIG. 5 is a schematic diagram of the structure inside the box body of the present invention.

In the figure: 1. bottom plate; 11. heat sink; 12. support rod; 13. guide rail; 14. placement frame; 15. empty slot; 16. lifting plate; 17. movable plate; 18. fixed plate; 19. connecting block; 191. first rotating shaft; 192. second rotating shaft; 193. box body; 194. first fan; 195. condenser; 2. stabilizing frame; 21. first electric push rod; 22. moving frame; 23. heat conducting sheet; 24. second fan; 3. limit plate; 4. exhaust hole; 5. clamping rod; 51. clamping slot; 6. mounting plate; 61. second electric push rod; 7. support plate.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments in the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Embodiment: As shown in Figures 1-5, the utility model provides a heat dissipation device for photovoltaic equipment and component manufacturing, including a base plate 1, a heat dissipation box 11 is fixedly installed on the top of the base plate 1, and a symmetrically distributed support rod 12 is fixedly installed on the side of the top of the base plate 1 away from the heat dissipation box 11, and a guide rail 13 is fixedly installed on the top of the two support rods 12, and the end of the guide rail 13 away from the support rod 12 is located inside the heat dissipation box 11, and the tops of the two guide rails 13 are slidably provided with a placement frame 14, and an empty groove 15 is opened in the middle of the placement frame 14. The top of the placement frame 14 is fixedly installed with symmetrically distributed lifting plates 16, and both sides of the lifting plates 16 are distributed in an arc state. A movable plate 17 is movably provided on one side of the heat dissipation box 11 near the lifting plate 16, and symmetrically distributed fixed plates 18 are fixedly installed on both sides of the movable plate 17. A symmetrically distributed connecting block 19 is fixedly installed on the bottom end of the fixed plate 18. A first rotating shaft 191 is rotatably installed at the bottom of the two connecting blocks 19, and a symmetrically distributed second rotating shaft 192 is rotatably installed at the bottom of the movable plate 17. The first rotating shaft 191 and the second rotating shaft 192 are used in conjunction with the lifting plate 16. A box body 193 is fixedly installed on the lower surface of the inner wall of the heat dissipation box 11, and a first fan 194 is fixedly installed inside the box body 193. A uniformly distributed Condenser 195, when actually used, components are placed in the empty slots 15 in the placement frame 14, and the placement frame 14 is pushed toward the heat sink 11 to move on the guide rail 13, and the placement frame 14 drives the lifting plate 16 to move. When it moves to a certain distance, the arc of the lifting plate 16 contacts the first rotating shaft 191, so that the first rotating shaft 191 rises along the arc, and the first rotating shaft 191 drives the connecting block 19, the fixed plate 18 and the movable plate 17 to rise. When the first rotating shaft 191 moves to the top of the lifting plate 16, the arc of the lifting plate 16 contacts the second rotating shaft 192, so that the second rotating shaft 192 rises along the arc until The second rotating shaft 192 comes to the top of the lifting plate 16, and the placement frame 14 enters the heat dissipation box 11 smoothly. When the placement frame 14 moves to the specified position, the second rotating shaft 192 descends along the arc at the other end of the lifting plate 16, and drives the movable plate 17 to descend, so that it is completely closed, and then rotates through the first fan 194 to cool the coolant in the condenser 195 and the surrounding air. The first fan 194 blows cold air onto the components to cool them down, thereby avoiding the leakage of cold air in the heat dissipation box 11, improving the heat dissipation effect of the components, and at the same time, when the outside temperature is high, it can also reduce the impact.

A stabilizing frame 2 is fixedly installed on the upper surface of the inner wall of the heat dissipation box 11, a first electric push rod 21 is fixedly installed on the bottom end of the stabilizing frame 2, a moving frame 22 is fixedly installed on the output end of the first electric push rod 21, evenly distributed heat conducting plates 23 are fixedly installed on the opposite side of the inner wall of the moving frame 22, and a second fan 24 is fixedly installed on both sides of the moving frame 22.

By adopting the above technical solution, the output end of the first electric push rod 21 is driven to move downward, thereby driving the movable frame 22 and the heat conducting plate 23 to move downward, so that the heat conducting plate 23 and the components come into contact, and the heat conducting plate 23 absorbs the heat on the surface of the components. Subsequently, the heat conducting plate 23 is driven to cool down the second fan 24, thereby further improving the cooling effect of the components and accelerating the cooling efficiency.

A limiting plate 3 is fixedly mounted on a side of the inner wall of the heat dissipation box 11 away from the movable plate 17 .

By adopting the above technical solution and setting the limiting plate 3, the placement frame 14 can be limited so that the components are located directly above the first fan 194, which facilitates the heat dissipation of the components.

The top of the heat dissipation box 11 is provided with symmetrically distributed exhaust holes 4 .

By adopting the above technical solution and providing the exhaust hole 4, the exhaust gas in the heat dissipation box 11 can be discharged.

The bottom end of the placement frame 14 is fixedly mounted with symmetrically distributed clamping rods 5 , and the top end of the guide rail 13 is provided with a clamping groove 51 , in which the clamping rod 5 is movably clamped.

By adopting the above technical solution and providing the clamping rod 5 and the clamping slot 51 , the stability of the placement frame 14 during movement is improved to avoid shaking.

A mounting plate 6 is fixedly mounted on the bottom end of the placement frame 14 . A second electric push rod 61 is arranged on a side of the mounting plate 6 away from the heat sink 11 . An output end of the second electric push rod 61 is fixedly connected to the mounting plate 6 .

By adopting the above technical solution and providing the second electric push rod 61 , it is convenient to push the placement frame 14 to move, so that the components can be pushed into the heat dissipation box 11 for cooling.

A support plate 7 is fixedly mounted on opposite sides of the two support rods 12 , and a second electric push rod 61 is fixedly mounted on the top of the support plate 7 .

By adopting the above technical solution and providing the support plate 7 , the second electric push rod 61 can be supported.

The two second fans 24 are distributed in a diagonal state.

By adopting the above technical solution, the cooling effect of the heat conducting sheet 23 is improved.

Working principle: In actual use, the components are placed in the empty slots 15 in the placement frame 14, and the placement frame 14 is pushed toward the heat sink 11 to move on the guide rail 13. The placement frame 14 drives the lifting plate 16 to move. When it moves to a certain distance, the arc of the lifting plate 16 contacts the first rotating shaft 191, so that the first rotating shaft 191 rises along the arc. The first rotating shaft 191 drives the connecting block 19, the fixed plate 18 and the movable plate 17 to rise. When the first rotating shaft 191 moves to the top of the lifting plate 16, the arc of the lifting plate 16 contacts the second rotating shaft 192, so that the second rotating shaft 192 rises along the arc until the second rotating shaft 192 reaches the top of the lifting plate 16. At this time, the placement frame 14 smoothly enters the heat sink 11. When the placement frame 14 moves to the specified position, the second rotating shaft 19 2 is lowered along the arc at the other end of the top plate 16, and drives the movable plate 17 to be lowered to be completely closed, and then the first fan 194 is rotated to cool the coolant in the condenser tube 195 and the surrounding air, and the first fan 194 blows the cold air onto the components to cool them, thereby avoiding the leakage of the cold air in the heat sink 11, improving the heat dissipation effect of the components, and at the same time, when the outside temperature is high, it can also reduce the impact; by driving the output end of the first electric push rod 21 to move downward, the moving frame 22 and the heat conducting sheet 23 are driven to move downward, so that the heat conducting sheet 23 and the components are in contact, and the heat conducting sheet 23 absorbs the heat on the surface of the components, and then the second fan 24 is driven to cool the heat conducting sheet 23, thereby further improving the cooling effect of the components and accelerating the cooling efficiency.

Obviously, those skilled in the art can make various changes and modifications to the present invention without departing from the spirit and scope of the present invention. Thus, if these modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include these modifications and variations.

Claims (8)

1. The utility model provides a be used for photovoltaic equipment and components and parts to make heat abstractor, includes bottom plate (1), its characterized in that: the top of bottom plate (1) fixed mounting has heat dissipation case (11), one side fixed mounting of the far away discrete heat dissipation case (11) in bottom plate (1) top has symmetrical distribution's bracing piece (12), two the top of bracing piece (12) is all fixed mounting has guide rail (13), the one end that bracing piece (12) was kept away from to guide rail (13) is located heat dissipation case (11) inside, two the top of guide rail (13) slides jointly and is equipped with places frame (14), empty slot (15) have been seted up at the middle part of placing frame (14), the top fixed mounting of placing frame (14) has symmetrical distribution's jacking plate (16), the both sides of jacking plate (16) are arc state distribution, one side activity that is close to jacking plate (16) of heat dissipation case (11) is equipped with fly leaf (17), the both sides of fly leaf (17) are all fixed mounting has symmetrical distribution's fixed plate (18), the bottom fixed mounting of fixed plate (18) has symmetrical distribution's bottom (19), two the bottom of rotating together of rotating frame (14) has empty slot (15), the top (192) of rotating together with first rotating shaft (192) and second rotating shaft (192) are installed with first rotating shaft (192) and second rotating shaft (192), the cooling box is characterized in that a box body (193) is fixedly arranged on the lower surface of the inner wall of the cooling box (11), a first fan (194) is fixedly arranged in the box body (193), and condensing pipes (195) which are uniformly distributed are fixedly arranged on the opposite sides of the inner wall of the top of the box body (193).

2. The heat dissipation device for manufacturing photovoltaic equipment and components as claimed in claim 1, wherein a stabilizing frame (2) is fixedly installed on the upper surface of the inner wall of the heat dissipation box (11), a first electric push rod (21) is fixedly installed at the bottom end of the stabilizing frame (2), a movable frame (22) is fixedly installed at the output end of the first electric push rod (21), heat conducting fins (23) which are uniformly distributed are fixedly installed on the opposite sides of the inner wall of the movable frame (22), and second fans (24) are fixedly installed on two sides of the movable frame (22).

3. A radiator for manufacturing photovoltaic equipment and components and parts according to claim 2, characterized in that the side of the inner wall of the radiator box (11) far away from the movable plate (17) is fixedly provided with a limit plate (3).

4. A radiator for manufacturing photovoltaic devices and components as claimed in claim 3, characterized in that the top of the radiator tank (11) is provided with symmetrically distributed exhaust holes (4).

5. The heat dissipating device for manufacturing photovoltaic equipment and components as claimed in claim 1, wherein symmetrically distributed clamping rods (5) are fixedly arranged at the bottom end of the placement frame (14), clamping grooves (51) are formed in the top ends of the guide rails (13), and the clamping rods (5) are movably clamped in the clamping grooves (51).

6. The heat dissipating device for manufacturing photovoltaic equipment and components as claimed in claim 5, wherein the bottom end of the placement frame (14) is fixedly provided with a mounting plate (6), one side of the mounting plate (6) far away from the discrete thermal box (11) is provided with a second electric push rod (61), and the output end of the second electric push rod (61) is fixedly connected with the mounting plate (6).

7. A radiator for manufacturing photovoltaic equipment and components according to claim 6, wherein the support plates (7) are fixedly mounted on opposite sides of the two support rods (12), and the second electric push rod (61) is fixedly mounted on top of the support plates (7).

8. A heat sink for photovoltaic equipment and components manufacture according to claim 2, characterized in that two of said second fans (24) are diagonally distributed.