CN220464982U - Photovoltaic laminating machine capable of efficiently utilizing waste heat - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic laminating machines and discloses a photovoltaic laminating machine capable of efficiently utilizing waste heat, which comprises a feeding table main body, wherein a laminating machine main body is arranged on one side, close to the feeding table main body, of the photovoltaic laminating machine, a discharging table main body is arranged on one side, close to the laminating machine main body, a feeding table heat insulation cover is arranged at the top of the feeding table main body, a laminating machine heat insulation cover is arranged at the top of the laminating machine main body, a discharging table heat insulation cover is arranged at the top of the discharging table main body, a waste heat utilization component is arranged on the front side, close to the laminating machine main body, of the photovoltaic laminating machine capable of efficiently utilizing waste heat, a large amount of heat is dissipated in the cooling process of the cooling chamber of the discharging table main body during operation of the laminating machine main body, and the waste heat energy is avoided.

Description

Photovoltaic laminating machine capable of efficiently utilizing waste heat

Technical Field

The utility model relates to the technical field of photovoltaic laminating machines, in particular to a photovoltaic laminating machine capable of efficiently utilizing waste heat.

Background

In the packaging production process of the photovoltaic module, the lamination process is the process link with highest energy consumption, the main process flow is to input the spread photovoltaic module in the room temperature state into a laminating machine through a feeding table, laminate and package the photovoltaic module after heating to the lamination temperature (usually 150 ℃), and then dissipate the temperature to the room temperature through a discharging table for the next process.

In the process, the laminator main body is used as main heating equipment, the whole machine temperature is high, a large amount of heat can be dissipated to the factory building, and the photovoltaic module flowing out of the laminator main body can also dissipate a large amount of heat to the factory building in the cooling process of the cooling chamber of the discharging table end. In the above process, on one hand, the laminating machine emits a large amount of heat outwards, the heat is the main energy consumption of the laminating machine, and the more the heat is emitted, the higher the energy consumption of the laminating machine is. On the other hand, the increase in load of the air conditioning system also results in an increase in overall energy consumption due to the increase in plant temperature caused by heat dissipation in the lamination process. Waste heat generated by the photovoltaic laminating machine needs to be recovered, so that heat energy waste is avoided.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a photovoltaic laminating machine capable of efficiently utilizing waste heat, which has the advantages of efficiently utilizing the waste heat and the like, and solves the existing problems.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a photovoltaic laminator of high-efficient utilization waste heat, includes the feeding platform main part, is close to one side of feeding platform main part is provided with the laminator main part, is close to one side of laminator main part is provided with the ejection of compact platform main part, the top of feeding platform main part is provided with feeding platform heat preservation cover, the top of laminator main part is provided with the laminator heat preservation cover, the front side that is close to the laminator main part is provided with the waste heat utilization subassembly, the waste heat utilization subassembly is including the gas-collecting vessel that is located laminator main part front side, one side inside embedding of gas-collecting vessel has the air duct, one side fixedly connected with aspiration pump of air duct, the top of aspiration pump bonds there is first aspiration tube, one side outer wall integrated into one piece of first aspiration tube has the second aspiration tube, the end of first aspiration tube extends to the inside of laminator heat preservation cover, the one end of second aspiration tube extends to the inside of ejection of material platform heat preservation cover, the inside through fixed block fixed mounting has the board, one side fixedly connected with disk pipe of flow-blocking board, one side fixedly connected with the outlet pipe of air duct and the first end of two end of air duct, the air duct and the first end of two end are in the same place, the outlet pipe is in fixed connection together.

Preferably, the outer wall fixedly connected with heat absorption ring of coiled tube, the quantity of heat absorption ring is a plurality of, the inboard bonding of gas-collecting channel has the vacuum insulation board.

Preferably, the first branch pipe and the second branch pipe are embedded in the front side of the gas collecting tank, and the second branch pipe is located right below the first branch pipe.

Preferably, the number of the spoilers is five, and the five spoilers are equidistantly distributed in the gas collection box.

Preferably, the number of the first branch pipes and the second branch pipes is five.

Preferably, the inside embedding of feeding platform heat preservation cover has the intake pipe, the outer wall bonding of intake pipe has the gas-supply pipe, the quantity of intake pipe and gas-supply pipe is two, the inside embedding of ejection of compact platform heat preservation cover has ejection of compact platform gas collecting channel, the inside embedding of laminator heat preservation cover has the laminator gas collecting channel, one the end of gas-supply pipe bonds together with the outer wall of ejection of compact platform gas collecting channel, another the end of gas-supply pipe bonds together with the outer wall of laminator gas collecting channel, two the equal fixedly connected with axial fan in the middle of the gas-supply pipe.

In summary, the present utility model includes at least one of the following beneficial effects:

1. this photovoltaic laminator of high-efficient utilization waste heat, through the waste heat utilization subassembly of setting, can carry out recycle with the cooling in-process of ejection of compact platform main part end cooling chamber that looses a large amount of heat when operating the laminator main part effectively, avoid the heat energy extravagant. When the heat-insulating cover is used, the air pump can be started, the heat-insulating cover of the laminating machine and the internal residual hot air of the laminating machine body are absorbed into the air collecting box through the first air extracting pipe and the second air extracting pipe respectively, then cold water can be discharged into the coiled pipe from the water inlet pipe and the first branch pipe, the cold water in the coiled pipe is heated by the blocking effect of the flow blocking plate and the heat absorbing effect of the heat absorbing ring, after the hot water is heated, the hot water can be discharged through the water outlet pipe and the second branch pipe, and people can perform functions or other functions through the hot water, so that the recycling of waste heat is realized.

2. This high-efficient photovoltaic laminator that utilizes waste heat through the setting of feeding platform heat preservation cover, laminator heat preservation cover and ejection of compact platform heat preservation cover, can improve the heat preservation effect of photovoltaic laminator, avoids the heat to run off when the photovoltaic laminator heats the work piece.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of a waste heat utilizing assembly according to the present utility model;

FIG. 3 is a cross-sectional view of a coil of the present utility model;

FIG. 4 is a side elevation view of the spoiler of the present utility model.

Wherein: 1. a feed table body; 2. a laminator body; 3. a discharge table main body; 4. a feeding table heat-insulating cover; 5. laminating machine heat preservation cover; 6. a discharge table heat preservation cover; 7. a discharge table gas collecting tube; 8. an air inlet pipe; 9. a gas pipe; 10. an axial flow fan; 11. laminating a gas collecting tube; 12. a waste heat utilization assembly; 13. a gas collection box; 14. an air duct; 15. an air extracting pump; 16. a first exhaust pipe; 17. a second exhaust pipe; 18. a spoiler; 19. a coiled tube; 20. a water inlet pipe; 21. a first branch pipe; 22. a water outlet pipe; 23. a second branch pipe; 24. a heat absorbing ring; 25. a vacuum insulation board; 26. and an air outlet pipe.

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.

Referring to fig. 1-4, a photovoltaic laminating machine capable of efficiently utilizing waste heat comprises a feeding table main body 1, wherein a laminating machine main body 2 is arranged on one side close to the feeding table main body 1, a discharging table main body 3 is arranged on one side close to the laminating machine main body 2, a feeding table heat insulation cover 4 is arranged at the top of the feeding table main body 1, a laminating machine heat insulation cover 5 is arranged at the top of the laminating machine main body 2, and a discharging table heat insulation cover 6 is arranged at the top of the discharging table main body 3.

Through the setting of feeding platform heat preservation cover 4, laminator heat preservation cover 5 and ejection of compact platform heat preservation cover 6, can improve the heat preservation effect of photovoltaic laminator, heat loss when avoiding the heating work piece of photovoltaic laminator.

As shown in fig. 1, a waste heat utilization component 12 is arranged near the front side of the laminator main body 2, an air inlet pipe 8 is embedded in the feeding table heat insulation cover 4, an air pipe 9 is bonded on the outer wall of the air inlet pipe 8, the number of the air inlet pipe 8 and the number of the air pipe 9 are two, a discharge table gas collecting pipe 7 is embedded in the discharging table heat insulation cover 6, a laminator gas collecting pipe 11 is embedded in the laminating machine heat insulation cover 5, the tail end of one air pipe 9 is bonded with the outer wall of the discharge table gas collecting pipe 7, the tail end of the other air pipe 9 is bonded with the outer wall of the laminator gas collecting pipe 11, and an axial flow fan 10 is fixedly connected in the middle of the two air pipes 9.

As shown in fig. 2-4, the waste heat utilization assembly 12 includes a gas collecting tank 13 located at the front side of the laminator main body 2, an air duct 14 is embedded in one side of the gas collecting tank 13, an air pump 15 is fixedly connected to one side of the air duct 14, a first air exhaust pipe 16 is adhered to the top of the air pump 15, a second air exhaust pipe 17 is integrally formed on one side outer wall of the first air exhaust pipe 16, the tail end of the first air exhaust pipe 16 extends to the inside of the laminator insulation cover 5, one end of the second air exhaust pipe 17 extends to the inside of the discharge table insulation cover 6, a flow blocking plate 18 is fixedly mounted in the gas collecting tank 13 through a fixing block, a coil 19 is fixedly connected to one side of the flow blocking plate 18, a water inlet of the coil 19 is fixedly connected with one end of the first branch pipe 21, the other end of the first branch pipe 21 is fixedly connected with the water inlet pipe 20, a water outlet of the coil 19 is fixedly connected with one end of the second branch pipe 23, and the other end of the second branch pipe 23 is fixedly connected with the water outlet pipe 22. An air outlet pipe 26 is embedded in one side of the air collecting box 13. The outer wall of the coil pipe 19 is fixedly connected with heat absorption rings 24, the number of the heat absorption rings 24 is a plurality of, and a vacuum insulation board 25 is adhered to the inner side of the gas collection box 13. The first branch pipe 21 and the second branch pipe 23 are embedded in the front side of the gas collecting tank 13, and the second branch pipe 23 is positioned right below the first branch pipe 21. The number of spoilers 18 is five, and the five spoilers 18 are equidistantly distributed inside the gas collection tank 13. The number of the first branch pipes 21 and the second branch pipes 23 is five.

When in use, the air pump 15 can be started, residual hot air in the heat insulation cover 5 and the main body 2 of the laminating machine is absorbed into the air collecting box 13 through the first air extracting pipe 16 and the second air extracting pipe 17 respectively, then cold water can be discharged into the coil pipe 19 from the water inlet pipe 20 and the first branch pipe 21, the cold water in the coil pipe 19 is heated by utilizing the blocking effect of the flow blocking plate 18 and the heat absorbing effect of the heat absorbing ring 24, and after the hot water is heated, the hot water can be discharged through the water outlet pipe 22 and the second branch pipe 23, so that people can perform functions or other effects through the hot water, and the waste heat recycling is realized.

Through the waste heat utilization assembly 12 that sets up, can dispel a large amount of heat and carry out recycle with the 3 end cooling room cooling processes of ejection of compact platform main part when operating to laminator main part 2 effectively, avoid the heat energy extravagant.

Standard parts used in the application files can be purchased from the market, and can be customized according to the description of the specification and the drawing, the specific connection modes of the parts are conventional means such as mature bolts, rivets and welding in the prior art, and the machines, the parts and the equipment are of conventional types in the prior art.

Although embodiments of the present utility model 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 therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a photovoltaic laminator of high-efficient utilization waste heat, includes feeding table main part (1), its characterized in that: be close to one side of feeding platform main part (1) is provided with laminator main part (2), is close to one side of laminator main part (2) is provided with ejection of compact platform main part (3), the top of feeding platform main part (1) is provided with feeding platform heat preservation cover (4), the top of laminator main part (2) is provided with laminator heat preservation cover (5), the top of ejection of compact platform main part (3) is provided with ejection of compact platform heat preservation cover (6), is close to the front side of laminator main part (2) is provided with waste heat utilization component (12), waste heat utilization component (12) are including gas collection box (13) that are located laminator main part (2) front side, one side inside embedding of gas collection box (13) has air duct (14), one side fixedly connected with aspiration pump (15) of air duct (14), the top bonding of aspiration pump (15) has first aspiration tube (16), first aspiration tube (16) one side outer wall integrated into one piece has second tube (17), the end of first aspiration tube (16) extends to the inside of laminator cover (5), second aspiration tube (17) extends to inside air collection plate (18) fixed connection has air-blocking plate (18), the water inlet of coiled pipe (19) is in the same place with the one end fixed connection of first minute pipe (21), the other end and inlet tube (20) fixed connection of first minute pipe (21) are in the same place, the delivery port of coiled pipe (19) is in the same place with the one end fixed connection of second minute pipe (23), the other end and outlet pipe (22) fixed connection of second minute pipe (23) are in the same place, inside embedding in one side of gas-collecting channel (13) has outlet duct (26).

2. The photovoltaic laminator of claim 1, wherein the laminator is capable of efficiently utilizing waste heat, and is characterized by: the outer wall fixedly connected with heat absorption ring (24) of coiled tube (19), the quantity of heat absorption ring (24) is a plurality of, the inboard bonding of gas-collecting channel (13) has vacuum insulation board (25).

3. The photovoltaic laminator of claim 1, wherein the laminator is capable of efficiently utilizing waste heat, and is characterized by: the first branch pipe (21) and the second branch pipe (23) are embedded into the front side of the gas collecting tank (13), and the second branch pipe (23) is located right below the first branch pipe (21).

4. The photovoltaic laminator of claim 1, wherein the laminator is capable of efficiently utilizing waste heat, and is characterized by: the number of the spoilers (18) is five, and the five spoilers (18) are equidistantly distributed in the gas collection box (13).

5. The photovoltaic laminator of claim 1, wherein the laminator is capable of efficiently utilizing waste heat, and is characterized by: the number of the first branch pipes (21) and the second branch pipes (23) is five.

6. The photovoltaic laminator of claim 1, wherein the laminator is capable of efficiently utilizing waste heat, and is characterized by: the inside embedding of feeding platform heat preservation cover (4) has intake pipe (8), the outer wall bonding of intake pipe (8) has gas-supply pipe (9), the quantity of intake pipe (8) and gas-supply pipe (9) is two, the inside embedding of ejection of compact platform heat preservation cover (6) has ejection of compact platform gas collecting channel (7), the inside embedding of laminator heat preservation cover (5) has laminator gas collecting channel (11), one the end of gas-supply pipe (9) bonds together with the outer wall of ejection of compact platform gas collecting channel (7), another the end of gas-supply pipe (9) bonds together with the outer wall of laminator gas collecting channel (11), two equal fixedly connected with axial fan (10) in the middle of gas-supply pipe (9).