CN221057381U - Lamination laying device of solar photovoltaic module - Google Patents

Abstract

The utility model belongs to the technical field of lamination of photovoltaic modules, in particular to a lamination laying device of a solar photovoltaic module. Firstly, arranging two symmetrical moving blocks, then simultaneously connecting the two moving blocks through a bidirectional driving assembly, and enabling the bidirectional driving assembly to realize boxing and laying, so that the formation of the original moving blocks of the moving blocks is shortened by half, and the laying efficiency is improved; secondly rely on the power of two-way drive assembly to realize automatic discharging, push out the mechanism and utilize the power of two-way drive assembly to push out from base one side with laying die holder, photovoltaic module body, and locking assembly is arranged in the locking of laying the die holder in the base, and push in the mechanism and be arranged in placing the push in to the base of not laying photovoltaic module body again, have automatic discharging, simple operation's advantage.

Description

Lamination laying device of solar photovoltaic module

Technical Field

The utility model belongs to the technical field of lamination of photovoltaic modules, and particularly relates to a lamination laying device of a solar photovoltaic module.

Background

The photovoltaic module, namely the solar cell module, has the advantages that the output voltage of the single solar cells is low, and the electrodes of the unpackaged cells are easy to fall off due to the influence of the environment, so that a certain number of single cells are sealed into the photovoltaic module in a serial-parallel connection mode, and corrosion of the cell electrodes and interconnection lines is avoided;

Through investigation publication (bulletin) number: CN217863214U discloses a lamination laying device for a solar photovoltaic module, and in this technology, "comprising: the photovoltaic module comprises a base, wherein a limiting groove is formed in the top surface of the base, a moving block is arranged on the top surface of the base, and a photovoltaic module body is movably sleeved in the limiting groove; the cleaning component is arranged on the bottom surface of the movable block and is used for removing bubbles and the like in the transparent adhesive film on the surface of the photovoltaic component body, and through the arrangement of the cleaning component, the laminated adhesive-deficient bubbles can be effectively cleaned through the cleaning component, so that the photovoltaic component body can be stable in the use process, meanwhile, the adhesive-deficient bubbles can be automatically cleaned through the cleaning component, thereby effectively reducing the labor cost and the material cost, effectively improving the production efficiency of the photovoltaic component body, ensuring that the transparent adhesive film cannot be hung up through the smooth outer wall surface of the extrusion column, ensuring that the transparent adhesive film cannot be wrinkled and the like;

However, the distance moved by the moving block of the device needs to cover the length of the photovoltaic module body, the device needs to be used again and operated in a reciprocating mode, the bubbles can be taken out, the working efficiency is affected, and the photovoltaic module body also needs to be manually taken out from the inner side of the device after being molded on the laying device, so that the operation convenience and the efficiency are low;

in order to solve the problems, the application provides a lamination laying device of a solar photovoltaic module.

Disclosure of utility model

In order to solve the problems in the prior art, the utility model provides a lamination laying device of a solar photovoltaic module, which has the characteristics of bidirectional lamination and improvement of efficiency and automatic discharging.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a solar photovoltaic module's lamination laying device, includes the base, the base upper end is provided with the lifter block through the electric push rod, be provided with the movable block in the lifter block, the movable block is two symmetrical, the movable block passes through two-way drive assembly and is connected with the lifter block, the base upper end slides and is provided with the laying die holder, the photovoltaic module body has been placed on the laying die holder, is provided with pushing mechanism between the lower extreme that is close to the terminal movable block of base and the laying die holder lower extreme, be provided with locking subassembly between pushing mechanism and the base, be provided with pushing mechanism between inside the laying die holder and the pushing mechanism; the bidirectional driving assembly comprises a driving motor fixed on one side of the moving block through a bracket and a bidirectional screw rod rotating on the moving block, the two moving blocks are in threaded sleeve joint with two ends of the bidirectional screw rod, and the driving motor drives the bidirectional screw rod through a synchronous belt wheel; the pushing mechanism comprises a telescopic pin fixed at two ends of the bottom of the moving block close to the tail end of the base, a telescopic sleeve which stretches out and draws back outside the telescopic pin, a pulling seat fixed at the other end of the telescopic sleeve and a pulling block arranged at the bottom of the laying die holder through an ejection spring.

As a preferable technical scheme of the lamination laying device of the solar photovoltaic module, the movable grooves for the telescopic sleeve and the pulling seat are formed in the base, the movable grooves for the telescopic pin are formed in the lifting block, one ends of the pulling seat and the pulling block are chamfer angles matched, the other ends of the pulling seat and the pulling block are vertical planes, and the pulling block is clamped with the plane contact end of the pulling seat through the ejection spring.

As a preferable technical scheme of the laminated laying device of the solar photovoltaic module, the locking module comprises locking blocks symmetrically fixed on two sides of the pulling block, locking counter bores formed in the upper end of the base, and a positioning table fixed at one end of the pulling seat, wherein the locking blocks are mutually inserted and combined with the locking counter bores through ejection springs.

As an optimal technical scheme of the laminated laying device of the solar photovoltaic module, the pushing mechanism comprises a Y-shaped frame horizontally arranged in a laying die holder through a reset spring, a plugboard fixed at one end of the Y-shaped frame, a top plate fixed at the upper end of a pulling block and a hand pushing plate fixed at one end of the Y-shaped frame far away from the plugboard.

As the preferable technical scheme of the lamination laying device of the solar photovoltaic module, the inserting plate and the top plate are provided with the chamfers which are matched with each other, and the inserting plate extrudes the top plate and then drives the pulling block to be separated from the clamping of the inserting plate.

As the preferable technical scheme of the lamination laying device of the solar photovoltaic module, the upper end of the base is provided with the sliding rail, the bottom of the laying die holder is provided with the sliding block fixed, and the laying die holder slides in the base through the sliding rail and the sliding block.

Compared with the prior art, the utility model has the beneficial effects that: firstly, arranging two symmetrical moving blocks, then simultaneously connecting the two moving blocks through a bidirectional driving assembly, and enabling the bidirectional driving assembly to realize boxing and laying, so that the formation of the original moving blocks of the moving blocks is shortened by half, and the laying efficiency is improved; secondly rely on the power of two-way drive assembly to realize automatic discharging, push out the mechanism and utilize the power of two-way drive assembly to push out from base one side with laying die holder, photovoltaic module body, and locking assembly is arranged in the locking of laying the die holder in the base, and push in the mechanism and be arranged in placing the push in to the base of not laying photovoltaic module body again, have automatic discharging, simple operation's advantage.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model. In the drawings:

FIG. 1 is a schematic view of a structure of a moving block in a laying-ready state and a photovoltaic module body in a laying station according to the present utility model;

FIG. 2 is a schematic view of the structure of the present utility model after two moving blocks of FIG. 1 are laid on two sides;

FIG. 3 is a schematic structural diagram of the photovoltaic module body when the moving block moves to the middle and pushes out the photovoltaic module body;

FIG. 4 is a partially exploded schematic illustration of the present utility model;

FIG. 5 is a schematic view of the bottom view of FIG. 4 according to the present utility model;

FIG. 6 is a partially enlarged schematic illustration of the structure of the portion A of the present utility model;

In the figure: 1. a base; 11. a slide rail; 2. a lifting block; 3. a moving block; 4. a bi-directional drive assembly; 41. a driving motor; 42. a two-way screw rod; 5. laying a die holder; 51. a slide block; 6. a photovoltaic module body; 7. a push-out mechanism; 71. a telescopic pin; 72. a telescopic sleeve; 73. pulling the seat; 74. an ejector spring; 75. pulling the block; 8. a locking assembly; 81. a locking block; 82. locking the counter bore; 83. a positioning table; 9. a pushing mechanism; 91. a return spring; 92. a Y-shaped frame; 93. inserting plate; 94. a top plate; 95. a hand pushing plate.

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

Referring to fig. 1-6, the present utility model provides the following technical solutions: the utility model provides a solar photovoltaic module's lamination laying device, including base 1, base 1 upper end is provided with lifting block 2 through the electric push rod, be provided with movable block 3 in the lifting block 2, movable block 3 is two symmetrical, movable block 3 is connected with lifting block 2 through two-way drive assembly 4, base 1 upper end slides and is provided with lays die holder 5, laid die holder 5 and placed photovoltaic module body 6, be close to base 1 terminal lower extreme of movable block 3 and lay die holder 5 lower extreme between be provided with push mechanism 7, be provided with locking subassembly 8 between push mechanism 7 and the base 1, be provided with push mechanism 9 between laying die holder 5 inside and push mechanism 7; the bidirectional driving assembly 4 comprises a driving motor 41 fixed on one side of the moving block 3 through a bracket and a bidirectional screw rod 42 rotating on the moving block 3, the two moving blocks 3 are in threaded sleeve joint with two ends of the bidirectional screw rod 42, and the driving motor 41 drives the bidirectional screw rod 42 through a synchronous pulley; the push-out mechanism 7 comprises a telescopic pin 71 fixed at both ends of the bottom of the moving block 3 near the end of the base 1, a telescopic sleeve 72 telescopic outside the telescopic pin 71, a pulling seat 73 fixed at the other end of the telescopic sleeve 72, and a pulling block 75 mounted at the bottom of the laying die holder 5 through an ejector spring 74.

Specifically, the movable groove for the telescopic sleeve 72 and the pulling seat 73 is formed in the base 1, the movable groove for the telescopic pin 71 is formed in the lifting block 2, one ends of the pulling seat 73 and the pulling block 75 are provided with matched chamfers, the other ends of the pulling seat 73 and the pulling block 75 are provided with vertical planes, the pulling block 75 is clamped with the plane contact ends of the pulling seat 73 through the ejection spring 74, when the chamfer ends of the pulling seat 73 and the ejection spring 74 face to face and move, the two parts cannot be affected each other, and when the planes contact each other, the pulling seat 73 pushes the pulling block 75 to synchronously move under the driving force of the bidirectional driving component 4, so that the 53 drives the laying mold seat 5 and the photovoltaic component body 6 to push out.

Specifically, the locking assembly 8 includes locking blocks 81 symmetrically fixed on two sides of the pulling block 75, locking counter bores 82 formed at the upper end of the base 1, and a positioning table 83 fixed at one end of the pulling seat 73, wherein the locking blocks 81 are mutually inserted with the locking counter bores 82 through the ejection springs 74, and in this embodiment, the locking assembly 8 is used for limiting the laying die holder 5 in the base 1, so as to ensure stable laying.

Specifically, the pushing mechanism 9 includes a Y-shaped frame 92 horizontally installed inside the laying mold base 5 by a return spring 91, a plug board 93 fixed at one end of the Y-shaped frame 92, a top board 94 fixed at the upper end of the pulling block 75, and a hand pushing board 95 fixed at one end of the Y-shaped frame 92 away from the plug board 93, in which the pushing mechanism 9 is manually operated in this embodiment, for releasing the pulling seat 73 and the pulling block 75 in the pushing mechanism 7, so that the laying mold base 5 can be moved independently.

Specifically, the insert plate 93 and the top plate 94 are provided with chamfers which are matched with each other, and the insert plate 93 presses the top plate 94 to drive the pulling block 75 to be separated from the engagement with the insert plate 93.

Specifically, the upper end of the base 1 is provided with a slide rail 11, the bottom of the laying die holder 5 is provided with a fixed slide block 51, the laying die holder 5 slides in the base 1 through the slide rail 11 and the slide block 51, and in this embodiment, the slide rail 11 and the slide block 51 ensure the sliding stability of the laying die holder 5.

The working principle and the using flow of the utility model are as follows: placing the photovoltaic module body 6 which is not laid and formed on the laying die holder 5, pushing the Y-shaped frame 92 through the push plate 95, compressing the reset spring 91, enabling the front end of the insertion plate 93 to be in contact with the top plate 94 and pushing the top plate 94 upwards, enabling the top plate 94 to drive the pulling block 75 to be separated from contact with the pulling seat 73, sliding the laying die holder 5 to the inner side of the base 1 through the sliding rail 11 and the sliding block 51, enabling the Y-shaped frame 92 and the insertion plate 93 to reset under the action of the reset spring 91 after the push plate 95 is loosened, enabling the top plate 94 to be pressed downwards under the action of the ejection spring 74, enabling the bottom of the locking block 81 to slide at the upper end of the base 1, enabling the locking block 81 to correspond to the locking counter bore 82 and to be inserted into each other under the action of the ejection spring 74 when the laying die holder 5 and the photovoltaic module body 6 completely enter a laying station, enabling the laying die holder 5 to be locked at the inner side of the base 1, enabling an electric push rod between the base 1 and the lifting block 2 to downwards move the lifting block 2, enabling the telescopic pin 71 to be in self-adapting depth in the telescopic sleeve 72, enabling the rubber pads and the bottom of the two moving blocks 3 to be simultaneously contacted with the middle of the photovoltaic module body 6, driving motor 41 to drive the bidirectional screw rod 42, enabling the two moving blocks 3 to move outwards and the two moving blocks to move towards the bottom of the base 73 and the telescopic sleeve 72 to be synchronously pulled outwards and then moved towards the bottom 75 when the bottom of the telescopic sleeve is moved to be moved towards the bottom 75 and outwards and moved to be close to the bottom of the telescopic sleeve 73;

After the laying is finished, the bidirectional driving assembly 4 is reversely started, the two moving blocks 3 are mutually close, at the moment, the inclined plane of the advancing end of the positioning table 83 jacks up the pulling block 75 upwards to be at a half height clamped with the pulling seat 73, the other half height is clamped with the pulling seat 73, at the moment, the half of the plane end of the pulling block 75 is clamped with the plane end on the pulling seat 73, the locking block 81 just withdraws upwards from the locking counter bore 82, the pulling seat 73 moves the laying die holder 5 and the photovoltaic assembly body 6 to the front end of the base 1 at the same time through the half contact height with the pulling block 75 until the two moving blocks 3 are completely reset, the laid photovoltaic assembly body 6 is taken down by a worker, and the steps are repeated after continuous operation.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (6)

1. The utility model provides a solar photovoltaic module's lamination laying device, includes base (1), base (1) upper end is provided with lifter block (2) through electric push rod, be provided with movable block (3), its characterized in that in lifter block (2): the photovoltaic module is characterized in that the two moving blocks (3) are symmetrical, the moving blocks (3) are connected with the lifting blocks (2) through two-way driving assemblies (4), a laying die holder (5) is slidably arranged at the upper end of the base (1), a photovoltaic module body (6) is placed on the laying die holder (5), a pushing mechanism (7) is arranged between the lower end, close to the tail end of the base (1), of the moving block (3) and the lower end of the laying die holder (5), a locking assembly (8) is arranged between the pushing mechanism (7) and the base (1), and a pushing mechanism (9) is arranged between the interior of the laying die holder (5) and the pushing mechanism (7);

The bidirectional driving assembly (4) comprises a driving motor (41) fixed on one side of the moving block (3) through a bracket and a bidirectional screw rod (42) rotating on the moving block (3), the two moving blocks (3) are in threaded sleeve connection with two ends of the bidirectional screw rod (42), and the driving motor (41) drives the bidirectional screw rod (42) through a synchronous belt wheel;

The pushing mechanism (7) comprises a telescopic pin (71) fixed at two ends of the bottom of the moving block (3) close to the tail end of the base (1), a telescopic sleeve (72) telescopic outside the telescopic pin (71), a pulling seat (73) fixed at the other end of the telescopic sleeve (72) and a pulling block (75) installed at the bottom of the laying die holder (5) through an ejection spring (74).

2. The lamination laying apparatus of a solar photovoltaic module according to claim 1, wherein: the lifting device is characterized in that a movable groove for a telescopic sleeve (72) and a pulling seat (73) is formed in the base (1), a movable groove for a telescopic pin (71) is formed in the lifting block (2), one ends of the pulling seat (73) and the pulling block (75) are chamfer angles matched with each other, the other ends of the pulling block (75) are vertical planes, and the pulling block (75) is clamped with the plane contact end of the pulling seat (73) through an ejection spring (74).

3. The lamination laying apparatus of a solar photovoltaic module according to claim 1, wherein: the locking assembly (8) comprises locking blocks (81) symmetrically fixed on two sides of the pulling block (75), locking counter bores (82) formed in the upper end of the base (1) and a positioning table (83) fixed at one end of the pulling seat (73), and the locking blocks (81) are mutually inserted and combined with the locking counter bores (82) through ejection springs (74).

4. The lamination laying apparatus of a solar photovoltaic module according to claim 1, wherein: the pushing mechanism (9) comprises a Y-shaped frame (92) horizontally arranged in the laying die holder (5) through a return spring (91), a plugboard (93) fixed at one end of the Y-shaped frame (92), a top plate (94) fixed at the upper end of the pulling block (75) and a hand pushing plate (95) fixed at one end, far away from the plugboard (93), of the Y-shaped frame (92).

5. The lamination laying apparatus of a solar photovoltaic module according to claim 4, wherein: the inserting plate (93) and the top plate (94) are provided with chamfers which are matched with each other, and the inserting plate (93) drives the pulling block (75) to be separated from the clamping of the inserting plate (93) after the inserting plate (93) extrudes the top plate (94).

6. The lamination laying apparatus of a solar photovoltaic module according to claim 1, wherein: the upper end of the base (1) is provided with a sliding rail (11), a sliding block (51) is fixed at the bottom of the laying die holder (5), and the laying die holder (5) slides in the base (1) through the sliding rail (11) and the sliding block (51).