CN216773257U

CN216773257U - Double-sided MWT-HIT battery pack

Info

Publication number: CN216773257U
Application number: CN202122360815.9U
Authority: CN
Inventors: 吴仕梁; 王飞; 王伟; 张凤鸣; 刘晓瑞; 罗西佳; 王浩
Original assignee: Nanjing Rituo Photovoltaic New Energy Co ltd
Current assignee: Jiangsu Sunport Power Corp Ltd
Priority date: 2021-09-28
Filing date: 2021-09-28
Publication date: 2022-06-17
Anticipated expiration: 2031-09-28

Abstract

The utility model discloses a double-sided MWT-HIT battery assembly, which sequentially comprises front-side super-white high-transmittance glass, a front-side packaging polymer, a front-side electrode, a front-side TCO layer, a front-side N < + > type doped amorphous silicon layer, a front-side intrinsic amorphous silicon passivation layer, an N-type monocrystalline silicon substrate, a back-side intrinsic amorphous silicon passivation layer, a back-side P-type doped amorphous silicon emission layer, a back-side TCO layer, a back-side positive electrode ring, an integrated composite local conductive core plate and back-side super-white high-transmittance glass from top to bottom; the battery component of the battery component exerts the characteristics of low shading area and low silver consumption of the front surface of the MWT structure to the back surface, greatly relieves the problem of high silver consumption in the industrialized HIT battery, can be matched with an ultrafine grid technology, and is beneficial to cost reduction and efficiency improvement of the industrialized HIT battery.

Description

Double-sided MWT-HIT battery pack

Technical Field

The utility model belongs to the technical field of photovoltaic module production, and particularly relates to a double-sided MWT-HIT battery module.

Background

The MWT battery has a back contact structure, and due to the fact that the front side is not provided with the main grid, the shading area can be effectively reduced, and meanwhile silver paste consumption is greatly reduced. Compared with other back contact structures such as IBC, the method has the advantages of simple process, low cost and better cost performance. However, the present invention is limited to a back-side packaging method, and it is difficult to realize a double-sided package at low cost. The HIT battery has the advantages of high conversion efficiency, low temperature coefficient, low attenuation, good low light property and the like, but the consumption and unit price of the low-temperature silver paste are high at present, the highest proportion of BOM cost is occupied, and the cost performance is relatively poor.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the background art, the utility model aims to provide a double-sided MWT-HIT battery assembly production method, which exerts the characteristics of low shading area and low silver consumption of the front side of the MWT structure to the back side, greatly relieves the problem of high silver consumption in an industrialized HIT battery, can be matched with an ultrafine grid technology, and is beneficial to cost reduction and efficiency improvement of the industrialized HIT battery.

The utility model relates to a double-sided MWT-HIT battery assembly, which sequentially comprises front-side super-white high-transmittance glass, a front-side packaging polymer, a front-side electrode, a front-side TCO layer, a front-side N < + > type doped amorphous silicon layer, a front-side intrinsic amorphous silicon passivation layer, an N-type monocrystalline silicon substrate, a back-side intrinsic amorphous silicon passivation layer, a back-side P-type doped amorphous silicon emission layer, a back-side TCO layer, a back-side positive electrode ring, an integrated composite local conductive core plate and back-side super-white high-transmittance glass from top to bottom;

the front TCO layer is provided with a front fine grid, the back TCO layer is provided with a back fine grid, and the front fine grid pattern is as high as the back fine grid pattern;

the back fine grid is of a ferrule structure at the electrode point to form a back positive electrode ring surrounding the back positive electrode point, and the back positive electrode point are provided with printing etching slurry for isolation and insulation;

the N-type monocrystalline silicon substrate is provided with a through hole, slurry in the through hole penetrates through the front TCO layer, the front N + type doped amorphous silicon layer, the front intrinsic amorphous silicon passivation layer, the N-type monocrystalline silicon substrate, the back intrinsic amorphous silicon passivation layer, the back P-type doped amorphous silicon emitting layer, the back TCO layer, the back electrode ring and the integrated composite local conductive core plate, low-temperature silver slurry in the through hole serves as hole plugging slurry, and the through hole forms a back cathode point.

Further, the integrated composite local conductive core board comprises a second back conductive foil, a second back high-transmittance insulating polymer, a first back conductive foil and a first back high-transmittance insulating polymer which are sequentially arranged from top to bottom, wherein,

the second back conductive foil is provided with an annular region, the annular region completely covers the back positive electrode ring and is effectively connected and conductive through conductive adhesive on the back positive electrode ring, and the annular region avoids the negative electrode point overlap of the back;

a round hole is formed in the second back high-transmittance insulating polymer, the back cathode point is located in the center of the round hole, the diameter of the round hole of the second back high-transmittance insulating polymer is smaller than the inner diameter of the round hole in the second back conductive foil, and the back cathode point area is only leaked out of the round hole of the second back high-transmittance insulating polymer;

the first back conductive foil is a grid-shaped conductive circuit, and grid points of the grid-shaped conductive circuit and the back negative points are bonded and electrically conducted through conductive adhesive at the tops of the back negative points;

and covering a first back high-permeability insulating polymer on the outer side surface of the first back conductive foil.

Further, a color changing film layer is arranged between the integrated composite local conductive core board and the back ultra-white high-transparency glass, the shape of the color changing film layer is the equal proportion amplification of the second back conductive foil, and the second back conductive foil and the first back conductive foil are required to be completely covered during covering.

The beneficial effect of this application contains:

compared with the HIT battery component product, the double-sided MWT-HIT battery component product structure and the process preparation method provided by the utility model have the following beneficial effects:

1. the MWT battery can also exert the characteristic of double-sided power generation, the limitation of outdoor application of the MWT battery component is broken, the comprehensive power generation amount is improved, and the power consumption cost is reduced;

2. compared with the traditional MWT component packaging, the specially designed composite local conductive core board reduces the consumption of conductive foil, and can greatly reduce the cost;

MWT and HIT have structural advantages, can be adapted to a silicon wafer with the thickness of 100 microns, and further reduce the cost;

4. compared with the HIT battery, the use amount of low-temperature silver paste on the front surface and the back surface is greatly reduced, the welding strip type connection is improved into the composite type local conductive core board connection, the welding process is simplified, and the packaging yield is improved.

Drawings

FIG. 1: the utility model provides a finished product structure schematic diagram of a double-sided MWT-HIT battery component;

FIG. 2: the utility model designs a schematic diagram of the contraposition relation when the second back conductive foil is laid on the back of the cell;

FIGS. 3-7: the utility model designs an exploded view of an integrated composite local conductive core board;

FIG. 8: the utility model discloses a top view of an integrated composite local conductive core board;

in the figure, a 1-N type monocrystalline silicon substrate, a 2-back intrinsic amorphous silicon passivation layer, a 3-front intrinsic amorphous silicon passivation layer, a 4-back P type doped amorphous silicon emission layer, a 5-front N + type doped amorphous silicon layer, a 6-front TCO layer, a 7-back TCO layer, an 8-back cathode point, a 9-front fine grid, a 10-back fine grid, an 11-back positive electrode ring, a 12-first back high-transmittance insulating polymer, a 13-second back high-transmittance insulating polymer, a 14-first back conductive foil, a 15-second back conductive foil, a 16-back ultra-white high-transmittance glass, a 17-back color changing film, a 18-conductive adhesive and a 19-insulating region.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

The embodiment of the utility model relates to a double-sided MWT-HIT battery assembly, which sequentially comprises front-side ultra-white high-transmittance glass, a front-side packaging polymer, a front-side electrode, a front-side TCO layer, a front-side N + -type doped amorphous silicon layer, a front-side intrinsic amorphous silicon passivation layer, an N-type monocrystalline silicon substrate, a back-side intrinsic amorphous silicon passivation layer, a back-side P-type doped amorphous silicon emission layer, a back-side TCO layer, a back-side electrode ring, a second back-side conductive foil, a second back-side high-transmittance insulating polymer, a first back-side conductive foil, a back-side color-changing film, a first back-side high-transmittance insulating polymer and back-side ultra-white high-transmittance glass. The back fine grid pattern is designed for the ferrule only at the electrode point, so as to form a back electrode ring surrounding the back positive electrode point. And the back electrode ring and the back anode electrode point are isolated and insulated by printing etching slurry. The electrode ring collects current by the back fine grid lines with the height consistent with that of the front fine grid pattern and is used as a joint point for subsequently forming contact with the composite local conductive core board through printing conductive adhesive. Except the positions occupied by the local conductive foils, other areas do not shield the incident light on the back surface, and the incident light on the back surface is fully utilized to carry out double-surface power generation. The battery end finishes the penetration of the front electrode and the slurry in the cavity, the front electrode and the back electrode are screen-printed with low-temperature silver paste, and the low-temperature silver paste is used as hole plugging slurry and is collected and guided to the back through holes formed in the silicon wafer by laser before texturing. The back anode electrode ring and the back cathode electrode point form good conductive contact with respective contacts in the integrated composite local conductive core board after conductive adhesive is printed on the back anode electrode ring and the back cathode electrode point, and the anode and the cathode on the back are isolated and insulated by printing etching slurry. In the integrated composite local conductive core board, the regions except the conductive foil distribution are laminated to form high-transmittance regions, so that the incident light on the back surface is absorbed. Compare in single face MWT-HIT battery, this utility model has created another way, and the compound local conductive core board of integrated form through special design once encapsulates the realization in the subassembly end, compares in conventional double-sided battery's solder strip connected mode, because conductive core board has better roughness and integration, can improve the yield, reduces man-hour.

As shown in fig. 1 to 8, as an innovation of the present application, the present application provides an integrated composite local conductive core board, which includes a second back conductive foil, a second back high-transmittance insulating polymer, a first back conductive foil, and a first back high-transmittance insulating polymer, which are sequentially disposed from top to bottom; to ensure a clearer description of embodiments of the present invention, the following description is provided.

Taking fig. 2 as an example, fig. 2 is a back view of an MWT-HIT battery, the integrated composite local conductive core board of the present invention is aligned and contacted with the back of the MWT-HIT battery, and is laminated and packaged, and before the alignment contact lamination and packaging, conductive adhesives are printed on the back cathode point and the back anode electrode ring shown in fig. 2 respectively; the layers were then overlaid in the following order:

1. the second back conductive foil covers the back positive electrode ring, and the circular ring-shaped area in the second back conductive foil completely covers the back positive electrode ring and is effectively connected and conducted through the conductive adhesive on the back positive electrode ring. The conductive paste printed on the back side positive electrode ring is required to be not protruded beyond the position of the circular ring in the second back side conductive foil after the lamination packaging, and another alignment requirement for the second back side conductive foil is required to be not overlapped with the back side negative electrode point shown in fig. 2.

2. The second back high-permeability insulating polymer is covered as shown in fig. 6, and the alignment requirement is that the back cathode point in fig. 2 after covering needs to be in the center of the circular hole of the second back high-permeability insulating polymer, and the diameter of the circular hole of the second back high-permeability insulating polymer is larger than that of the back cathode point. The diameter of the round hole of the second back high-transmittance insulating polymer is smaller than the inner diameter of the round ring in the second back conductive foil, the area of the second back conductive foil can be completely covered after the second back high-transmittance insulating polymer is covered, and only the back cathode point area leaks out of the round hole of the second back high-transmittance insulating polymer.

3. The covering of the first back conductive foil is performed, and the grid points of the first back conductive foil as shown in fig. 5 and the back negative electrode points as shown in fig. 2 are bonded and conducted through the conductive adhesive on the back negative electrode points.

4. And (3) carrying out color changing film covering, wherein the shape of the color changing film is the equal-scale enlargement of the second back surface conductive foil, and the second back surface conductive foil and the first back surface conductive foil are required to be completely covered during covering. The color system of the color-changing film of the layer is the same as that of the back surface of the battery piece, and only plays a role in beauty.

5. And finally, covering the first back surface with high-transmittance insulating polymer. The above is a description of the alignment connection between each layer of the integrated composite local conductive core board and the back structure of the battery piece when the layers are decomposed and covered.

Furthermore, in order to save labor and improve positioning accuracy, the composite local conductive core board can be pressed in advance and then manufactured into an integral type.

The MWT battery and the HIT battery are combined through the structural design, in addition, the double-sided power generation characteristic is achieved, on one hand, the performance advantage of the HIT battery can be exerted, on the other hand, the back contact advantage of the MWT battery can also be exerted, the MWT-HIT battery can be endowed with double-sided performance through the packaging of the specially designed integrated composite type local conductive core board, and the characteristic of low silver consumption on the front side of the MWT battery is applied to the back side, so that the cost advantage of the MWT battery can be exerted better. Through the innovative design of the back structure of the battery and the innovative design of the back component packaging technology, the double-sided MWT-HIT battery has the high efficiency and the double-sided performance of the HIT battery, and simultaneously has the characteristics of low silver consumption and back contact of the MWT battery, the cost of the double-sided MWT-HIT battery component product is greatly reduced, and the cost performance is improved.

Example 3

On the other hand, the utility model also provides a process preparation method of the double-sided MWT-HIT battery component, which comprises the following process steps:

s01 laser drilling is carried out on the N-type silicon wafer;

s02 silicon wafer cleaning and polishing: texturing and cleaning an N-type monocrystalline silicon substrate, removing a mechanical damage layer and pollutants on the surface of the silicon substrate, and forming a pyramid textured surface;

s03 depositing intrinsic amorphous silicon layer on both sides;

s04, performing N-type amorphous silicon deposition on the front surface;

s05, depositing P-type amorphous silicon on the back surface;

TCO deposition is carried out on the front surface of S06;

TCO deposition is carried out on the back of S07;

s08, printing etching slurry on the back around the hole to perform local etching of back TCO and P-type amorphous silicon;

s09 screen printing pore-plugging slurry: printing the hole plugging slurry into holes which are punched on the silicon wafer by laser in advance from the back;

s10 screen printing of back low-temperature silver paste;

s11 Screen printing front low-temperature silver paste

S12, sequentially laying back ultra-white high-transmittance glass, a first back high-transmittance insulating polymer, a first back conductive foil, a second back high-transmittance insulating polymer, a second back conductive foil, a printed conductive adhesive, a battery piece, a front packaging polymer and front ultra-white high-transmittance glass;

s13, entering a component laminating machine for component packaging;

further: the back high-transmittance insulating polymer, the first back conductive foil, the back high-transmittance insulating polymer and the second back conductive foil laid in the step S1201 can be integrally formed in advance, so that the working hours can be effectively shortened, and the alignment precision can be improved; in the step S1201, a layer of color-changing film having the same color system as the back surface of the cell sheet may be further laid before the first back surface conductive foil is laid, the color-changing film has stable chemical properties, and after lamination, the insulating polymer having high transmittance to the back surface and the first back surface conductive foil have good bondability, and is only used to shield the distribution of the local conductive foil, and improve the back surface color consistency after encapsulation.

Example 2

The present application further provides an integrated composite local area conductive core board, which is described below to ensure that the description of the embodiments of the present invention is clearer. Taking fig. two as an example, fig. two is a back view of the MWT-HIT cell. The integrated composite local conductive core board is mainly in contraposition contact with the back surface of the MWT-HIT battery and is laminated and packaged. It is necessary to print conductive paste on the back cathode point and the back anode electrode ring shown in fig. 2 before the package is laminated in alignment with the contact. The coverage of the layers is then performed in the following order.

1. The second back conductive foil covers the back positive electrode ring, and the circular ring-shaped area in the second back conductive foil completely covers the back positive electrode ring and is effectively connected and conducted through the conductive adhesive on the back positive electrode ring. The requirement for the conductive paste printed on the back side positive electrode ring is that the conductive paste at that position does not overflow the position of the circular ring in the second back side conductive foil after the lamination packaging. Another requirement for alignment of the second back side conductive foil is that the circular ring in the second back side conductive foil does not overlap the back side negative electrode spot shown in fig. two.

2. The second back high-permeability insulating polymer is covered as shown in fig. 6, and the alignment requirement is that the back cathode point in fig. 2 after covering needs to be in the center of the circular hole of the second back high-permeability insulating polymer, and the diameter of the circular hole of the second back high-permeability insulating polymer is larger than that of the back cathode point. The diameter of the round hole of the second back high-transmittance insulating polymer is smaller than the inner diameter of the round ring in the second back conductive foil, the second back high-transmittance insulating polymer can completely cover the area of the second back conductive foil after covering, and only the back negative electrode point area leaks out of the round hole of the second back high-transmittance insulating polymer.

Furthermore, in order to save working hours and improve positioning accuracy, the composite local conductive core board can be manufactured into an integrated type after being pressed in advance.

The utility model has the important characteristic that the back cathode point and the back anode ring are not in the same plane but in an upper plane and a lower plane when contacting with the conductive foil, and belong to three-dimensional packaging. Compared with planar packaging, the three-dimensional packaging method in the patent can place the first back conductive foil and the second back conductive foil on different planes, and can achieve local distribution instead of large-area distribution. The area outside the conductive foil can receive the sunlight to carry out double-sided power generation.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims

1. A double-sided MWT-HIT battery assembly is characterized by comprising front-side ultra-white high-transmittance glass, a front-side packaging polymer, a front-side electrode, a front-side TCO layer, a front-side N + -type doped amorphous silicon layer, a front-side intrinsic amorphous silicon passivation layer, an N-type monocrystalline silicon substrate, a back-side intrinsic amorphous silicon passivation layer, a back-side P-type doped amorphous silicon emission layer, a back-side TCO layer, a back-side positive electrode ring, an integrated composite local conductive core plate and back-side ultra-white high-transmittance glass from top to bottom in sequence;

the back fine grid is of a ferrule structure at the electrode point to form a back positive electrode ring surrounding the back positive electrode point, and the back positive electrode ring and the back positive electrode point are provided with printing etching slurry for isolation and insulation;

the N-type monocrystalline silicon substrate is provided with a through hole, slurry in the through hole penetrates through the front TCO layer, the front N + type doped amorphous silicon layer, the front intrinsic amorphous silicon passivation layer, the N-type monocrystalline silicon substrate, the back intrinsic amorphous silicon passivation layer, the back P-type doped amorphous silicon emitting layer, the back TCO layer, the back positive electrode ring and the integrated composite local conductive core plate, low-temperature silver paste in the through hole serves as hole plugging slurry, and the through hole forms a back negative electrode point.

2. The assembly of claim 1, wherein the integrated composite local conductive core comprises, in order from top to bottom, a second back conductive foil, a second back high-permeability insulating polymer, a first back conductive foil, and a first back high-permeability insulating polymer, wherein,

a round hole is formed in the second back high-transmittance insulating polymer, the back cathode point is located in the center of the round hole, the diameter of the round hole of the second back high-transmittance insulating polymer is smaller than the inner diameter of the round hole in the second back conductive foil, and the back cathode point region is only leaked out of the round hole of the second back high-transmittance insulating polymer;

3. The assembly of claim 1, wherein a color modifying film is disposed between the integrated composite local area conductive core and the back ultra-white high-transmittance glass, the color modifying film is shaped to be an isometric enlargement of the second back conductive foil and is required to completely cover the second back conductive foil and the first back conductive foil.