CN106098859A - A kind of collection collects the storage device being stored in crystal silicon solar cell sheet integrally - Google Patents

Abstract

The invention discloses a storage device integrating collection and storage of crystalline silicon solar cells, comprising a first horizontal bar, a first vertical bar, a second horizontal bar, a second vertical bar, a first horizontal bar, a first vertical bar The rod, the second horizontal bar, and the second vertical bar are connected end to end to form a vertically placed support unit. The first vertical bar is provided with multiple first long bars, and the second vertical bar is provided with multiple second long bars. block, the first long block and the second long block are located on the same horizontal plane, and are oppositely arranged, and a gap is provided between the first long block and the second long block, and the width of the gap is smaller than that of the crystalline silicon solar cell Minimum width. The storage device described in this application not only realizes the convenience of taking out and storing, but also realizes the full soaking of the crystalline silicon solar cells during the production process.

Description

A storage device integrating collection and storage of crystalline silicon solar cells

technical field

The invention relates to the technical field of solar cell equipment, in particular to a storage device integrating collection and storage of crystalline silicon solar cells.

Background technique

In the production process of solar cells, cells are made of monocrystalline silicon wafers. The quality of monocrystalline silicon wafers directly determines the power conversion efficiency of solar cells. Therefore, the manufacturing process of the battery sheet is a very critical process.

During the production process of the cell, the silicon wafer needs to be treated and soaked in the solution to remove a layer of phospho-silicate glass formed on the surface of the silicon wafer after diffusion and junction. During the soaking process, the silicon wafer needs to be neatly placed in the container inside for more even soaking. The prior art means can't reach evenly immersing the silicon chip and taking it out conveniently.

Based on this research and design a storage device applied to solar cells.

Contents of the invention

The object of the present invention is to provide a storage device integrating collection and storage of crystalline silicon solar cells to solve the technical problem in the prior art that the crystalline silicon solar cells cannot be fully and evenly soaked during the production process of the cells.

The present invention realizes through following technical scheme:

A storage device integrating collection and storage of crystalline silicon solar cells, comprising a first horizontal bar, a first vertical bar, a second horizontal bar, a second vertical bar, a first horizontal bar, a first vertical bar, a second The horizontal bar and the second vertical bar are connected end to end to form a vertically placed support unit. The first vertical bar is provided with a plurality of first long blocks, and the second vertical bar is provided with a plurality of second long blocks. The first The elongated block and the second elongated block are located on the same horizontal plane and are set opposite to each other. There is a gap between the first elongated block and the second elongated block, and the width of the gap is smaller than the minimum width of the crystalline silicon solar cell.

The key technical solution for storing crystalline silicon solar cells in this technical solution is to place the crystalline silicon solar cells between the first long block and the second long block that are oppositely arranged on the horizontal plane. There can be multiple first strips and second strips respectively arranged on the two vertical bars, so that a plurality of crystalline silicon solar cells can be placed between the first vertical bar and the second vertical bar, so that Soak in the solution evenly.

Preferably, the horizontal distance between the first vertical bar and the second vertical bar is greater than or equal to the maximum width of the crystalline silicon solar cell.

In order to place the crystalline silicon solar cell between the first vertical bar and the second vertical bar more conveniently, and save effort in the process of placing and taking it out, avoid contact between the surrounding surfaces of the crystalline silicon solar cell and the first vertical bar and the second vertical bar. contact between the rods. When the crystalline silicon solar cell is placed between the first long bar and the second long bar, when the width of the crystalline silicon solar cell is equal to the distance between the first vertical bar and the second vertical bar, it can reach For the purpose of storing and placing crystalline silicon solar cells, in order to reduce the friction generated during the access process, the inner sides of the first vertical bar and the second vertical bar can be set as smooth contact surfaces to avoid damage to stacked crystalline silicon solar cells .

Preferably, the first elongated block and the second elongated block have the same structure, and both are cuboid structures, and the longitudinal section of the first elongated block is a cube;

The first vertical bar and the second vertical bar are of the same structure, and both are cuboid structures. The first vertical bar and the second vertical bar are respectively provided with mounting brackets for installing the first long bar and the second long bar. The cube through hole, the width of the cube through hole is greater than or equal to the longitudinal section width of the first elongated block.

Here, the connection relationship between the first long block and the second long block and the first vertical bar and the second vertical bar is respectively limited. In order to facilitate the rapid insertion of the first long bar and the second long bar into the square In the through hole, the width of the cube through hole is set to be greater than or equal to the longitudinal section width of the first strip, and the second strip is of the same structure as the first strip, then the width of the square through hole is greater than or equal to the second strip The longitudinal section width of the block.

Preferably, the storage device applied to crystalline silicon solar cells further includes a plurality of support units, the support units are parallel to each other and connected by connecting rods.

A plurality of support units parallel to each other are arranged, and are connected to each other through connecting rods. The structure of the plurality of support units includes structures such as a first horizontal bar, a second horizontal bar, a first vertical bar, and a second vertical bar, and the first The vertical bar and the second vertical bar are respectively provided with a first elongated block and a second elongated block. In this way, a plurality of interconnected support units are provided to facilitate placement of a plurality of crystalline silicon solar cells.

Preferably, the lower ends of the first vertical rod and the second vertical rod are both provided with a support structure in contact with the ground.

Preferably, the first vertical bar, the second vertical bar, the first horizontal bar, and the second horizontal bar are all made of aluminum alloy, and the first long bars that are oppositely arranged on the first vertical bar and the second vertical bar are respectively The spacing between the bar block and the second long bar block in the vertical direction is equal.

Here, the distance between the first long block and the second long block is limited, so that the crystalline silicon solar cells can be placed neatly and avoid damage caused by friction and collision between them.

Preferably, for the plurality of first strips located on the first vertical bar, the distance between the first strips is greater than the thickness of the crystalline silicon solar cells;

For the plurality of second elongated blocks located on the second vertical bar, the distance between the second elongated blocks is greater than the thickness of the crystalline silicon solar cell.

Here, the spacing between the first strips and the spacing between the second strips are further defined. When placing multiple polycrystalline silicon solar cells on the storage device, especially when placing multiple polycrystalline silicon solar cells When one of the polycrystalline silicon solar cells is taken out, in order to avoid damage to the upper and lower solar cells during the removal process or inconvenient removal, the distance between the first long strips is set to be greater than the thickness of the crystalline silicon solar cells. The same is true for the setting of the second long strip, then in the process of placing and taking out, there is a certain distance between the crystalline silicon solar cell and the first long strip or the second long strip located at its upper and lower ends, which can solve the above-mentioned problems. technical issues.

Compared with the prior art, the present invention has the following advantages and beneficial effects:

1. The first horizontal bar, the second horizontal bar, the first vertical bar, and the second vertical bar are connected to each other as the bracket unit described in this application, and the first long block and the second long block can be conveniently arranged. A plurality of crystalline silicon solar cells are placed, and sufficient immersion of the crystalline silicon solar cells can be effectively realized.

2. In this application, the distance between the first long block and the second long block is limited. The distance between the first long block is greater than the thickness of the crystalline silicon solar cell. The same is true for the second long block. After the crystalline silicon solar cell is installed, gaps are formed on the upper surface thereof, which is convenient for taking out or placing the crystalline silicon solar cell.

3. The storage device described in this application not only realizes the convenience of taking out and storing, but also realizes the full immersion in the production process of the crystalline silicon solar cells.

Description of drawings

The drawings described here are used to provide a further understanding of the embodiments of the present invention, constitute a part of the application, and do not limit the embodiments of the present invention. In the attached picture:

Fig. 1 is a structural representation of the present invention;

Fig. 2 is the top view of structure of the present invention;

Fig. 3 is the side view of the first vertical rod among the present invention;

Marks and corresponding parts names in the attached drawings:

1-the first vertical bar, 2-the first long bar, 3-the second vertical bar, 4-the second long bar, 5-the first horizontal bar, 6-the second horizontal bar.

detailed description

In order to make the purpose, technical solutions and advantages of the present invention clearer, the present invention will be further described in detail below in conjunction with the examples and accompanying drawings. As a limitation of the present invention.

Example 1

As shown in Figures 1 to 3, a storage device for collecting and storing crystalline silicon solar cells includes a first horizontal bar 5, a first vertical bar 1, a second horizontal bar 6, and a second vertical bar 3 , the first horizontal bar 5, the first vertical bar 1, the second horizontal bar 6, and the second vertical bar 3 are connected end to end to form a vertically placed support unit, and the first vertical bar 1 is provided with a plurality of first long bars 2. The second vertical bar 3 is provided with a plurality of second long blocks 4, the first long block 2 and the second long block 4 are located on the same horizontal plane, and are oppositely arranged, the first long block 2 and the second long block There is a gap between the two long strips 4, and the width of the gap is smaller than the minimum width of the crystalline silicon solar cells.

Specifically, the horizontal distance between the first vertical bar 1 and the second vertical bar 3 may be greater than or equal to the maximum width of the crystalline silicon solar cell.

The key technical solution for storing crystalline silicon solar cells in this embodiment is to place the crystalline silicon solar cells between the first long block and the second long block that are oppositely arranged on the horizontal plane. There can be multiple first strips and second strips respectively arranged on the two vertical bars, so that a plurality of crystalline silicon solar cells can be placed between the first vertical bar and the second vertical bar, so that Soak in the solution evenly.

Example 2:

On the basis of Example 1, it is further defined that the first long block 2 and the second long block 4 have the same structure, and both are cuboid structures, and the longitudinal section of the first long block 2 is a cube;

The first vertical bar 1 and the second vertical bar 3 are of the same structure, and both are cuboid structures. The first vertical bar 1 and the second vertical bar 3 are respectively provided with the first long bar 2 and the second vertical bar. The square through hole of the second long strip 4, the width of the square through hole is greater than or equal to the longitudinal section width of the first long strip 2.

Here, the connection relationship between the first long block and the second long block and the first vertical bar and the second vertical bar is respectively limited. In order to facilitate the rapid insertion of the first long bar and the second long bar into the square In the through hole, the width of the cube through hole is set to be greater than or equal to the longitudinal section width of the first strip, and the second strip is of the same structure as the first strip, then the width of the square through hole is greater than or equal to the second strip The longitudinal section width of the block.

Example 3:

In this embodiment, on the basis of the above embodiments, specifically, the storage device applied to crystalline silicon solar cells further includes a plurality of support units, and the support units are parallel to each other and connected by connecting rods. Both the lower ends of the first vertical bar 1 and the second vertical bar 3 are provided with support structures in contact with the ground.

A plurality of support units parallel to each other are arranged, and are connected to each other through connecting rods. The structure of the plurality of support units includes structures such as a first horizontal bar, a second horizontal bar, a first vertical bar, and a second vertical bar, and the first The vertical bar and the second vertical bar are respectively provided with a first elongated block and a second elongated block. In this way, a plurality of interconnected support units are provided to facilitate placement of a plurality of crystalline silicon solar cells.

Example 4:

On the basis of the above-mentioned embodiments, this embodiment further defines that the first vertical bar 1, the second vertical bar 3, the first horizontal bar 5, and the second horizontal bar 6 are all made of aluminum alloy, and the respective The first elongated block 2 and the second elongated block 4 located opposite to each other on the first vertical bar 1 and the second vertical bar 3 are equally spaced in the vertical direction.

It can also be that, for the plurality of first long blocks 2 located on the first vertical bar 1, the distance between the first long blocks 2 is greater than the thickness of the crystalline silicon solar cells;

For the plurality of second strips 4 located on the second vertical bar 3 , the distance between the second strips 4 is greater than the thickness of the crystalline silicon solar cells.

Here, the spacing between the first strips and the spacing between the second strips are further defined. When placing multiple polycrystalline silicon solar cells on the storage device, especially when placing multiple polycrystalline silicon solar cells When one of the polycrystalline silicon solar cells is taken out, in order to avoid damage to the upper and lower solar cells during the removal process or inconvenient removal, the distance between the first long strips is set to be greater than the thickness of the crystalline silicon solar cells. The same is true for the setting of the second strip, then in the process of placing and taking out, there is a certain distance between the crystalline silicon solar cell and the first strip or the second strip located at its upper and lower ends, which can solve the above-mentioned problems. technical problems.

The specific embodiments described above have further described the purpose, technical solutions and beneficial effects of the present invention in detail. It should be understood that the above descriptions are only specific embodiments of the present invention and are not intended to limit the scope of the present invention. Protection scope, within the spirit and principles of the present invention, any modification, equivalent replacement, improvement, etc., shall be included in the protection scope of the present invention.

Claims (7)

1. A storage device integrating collection and storage of crystalline silicon solar cells, characterized in that it includes a first horizontal bar (5), a first vertical bar (1), a second horizontal bar (6), a second The vertical bar (3), the first horizontal bar (5), the first vertical bar (1), the second horizontal bar (6), and the second vertical bar (3) are connected end to end to form a longitudinally placed bracket unit, the first The vertical bar (1) is provided with a plurality of first strips (2), the second vertical bar (3) is provided with a plurality of second strips (4), the first strips (2) and the second strips The two long strips (4) are located on the same horizontal plane, and they are arranged opposite to each other. There is a gap between the first long strip (2) and the second long strip (4), and the width of the gap is smaller than that of the crystalline silicon solar cell. Minimum width. 2. A storage device integrating collection and storage of crystalline silicon solar cells according to claim 1, characterized in that, between the first vertical bar (1) and the second vertical bar (3) The horizontal distance is greater than or equal to the maximum width of the crystalline silicon solar cells. 3. A storage device integrating collection and storage of crystalline silicon solar cells according to claim 1, characterized in that, the first strip (2) and the second strip (4) are The same structure, and both are cuboid structures, the longitudinal section of the first long block (2) is a cube; The first vertical bar (1) and the second vertical bar (3) have the same structure, and both are cuboid structures. The first vertical bar (1) and the second vertical bar (3) are respectively provided with The cube through holes of the first elongated block (2) and the second elongated block (4) have a width greater than or equal to the longitudinal section width of the first elongated block (2). 4. A storage device integrating collection and storage of crystalline silicon solar cells according to claim 3, characterized in that the storage device applied to crystalline silicon solar cells further comprises a plurality of support units, the support The units are parallel to each other and connected by connecting rods. 5. A storage device integrating collection and storage of crystalline silicon solar cells according to claim 4, characterized in that the lower ends of the first vertical rod (1) and the second vertical rod (3) are both There is a pillar structure in contact with the ground. 6. A storage device integrating collection and storage of crystalline silicon solar cells according to claim 5, characterized in that the first vertical bar (1), the second vertical bar (3), and the first horizontal bar (5) and the second horizontal bar (6) are made of aluminum alloy, and the first long bars (2 ), the second long block (4) is equally spaced in the vertical direction. 7. A storage device for collecting and storing crystalline silicon solar cells according to claim 1, characterized in that the plurality of first long bars ( 2), the distance between the first long strips (2) is greater than the thickness of the crystalline silicon solar cell; For the plurality of second elongated blocks (4) located on the second vertical bar (3), the distance between the second elongated blocks (4) is greater than the thickness of the crystalline silicon solar cells.