CN110350047A - Imbrication solar battery solar double-glass assemblies and preparation method thereof - Google Patents
Imbrication solar battery solar double-glass assemblies and preparation method thereof Download PDFInfo
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- CN110350047A CN110350047A CN201910605981.5A CN201910605981A CN110350047A CN 110350047 A CN110350047 A CN 110350047A CN 201910605981 A CN201910605981 A CN 201910605981A CN 110350047 A CN110350047 A CN 110350047A
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- 239000011521 glass Substances 0.000 title claims abstract description 189
- 230000000712 assembly Effects 0.000 title claims abstract description 49
- 238000000429 assembly Methods 0.000 title claims abstract description 49
- 238000002360 preparation method Methods 0.000 title claims abstract description 11
- 239000002313 adhesive film Substances 0.000 claims abstract description 46
- 238000004806 packaging method and process Methods 0.000 claims abstract description 12
- 238000000034 method Methods 0.000 claims description 25
- 238000003475 lamination Methods 0.000 claims description 22
- 239000004020 conductor Substances 0.000 claims description 6
- 239000003292 glue Substances 0.000 claims description 4
- 238000012360 testing method Methods 0.000 claims description 4
- 238000005507 spraying Methods 0.000 claims description 3
- 238000007747 plating Methods 0.000 claims description 2
- 238000005520 cutting process Methods 0.000 description 31
- 238000010586 diagram Methods 0.000 description 25
- 239000012634 fragment Substances 0.000 description 15
- 230000008569 process Effects 0.000 description 15
- 230000005611 electricity Effects 0.000 description 10
- 238000004519 manufacturing process Methods 0.000 description 10
- 238000013461 design Methods 0.000 description 9
- 238000003466 welding Methods 0.000 description 5
- 238000004891 communication Methods 0.000 description 4
- 239000006059 cover glass Substances 0.000 description 3
- 238000005516 engineering process Methods 0.000 description 3
- 238000009413 insulation Methods 0.000 description 3
- 238000012545 processing Methods 0.000 description 3
- 238000004070 electrodeposition Methods 0.000 description 2
- 239000004744 fabric Substances 0.000 description 2
- 238000009434 installation Methods 0.000 description 2
- 239000002184 metal Substances 0.000 description 2
- 238000012805 post-processing Methods 0.000 description 2
- 238000007639 printing Methods 0.000 description 2
- 238000005476 soldering Methods 0.000 description 2
- 239000002699 waste material Substances 0.000 description 2
- 239000000853 adhesive Substances 0.000 description 1
- 230000001070 adhesive effect Effects 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000015572 biosynthetic process Effects 0.000 description 1
- 238000005229 chemical vapour deposition Methods 0.000 description 1
- 230000008878 coupling Effects 0.000 description 1
- 238000010168 coupling process Methods 0.000 description 1
- 238000005859 coupling reaction Methods 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 230000018109 developmental process Effects 0.000 description 1
- 239000002360 explosive Substances 0.000 description 1
- 238000000605 extraction Methods 0.000 description 1
- 238000003698 laser cutting Methods 0.000 description 1
- 238000004021 metal welding Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 230000009467 reduction Effects 0.000 description 1
- 230000011218 segmentation Effects 0.000 description 1
- 238000007740 vapor deposition Methods 0.000 description 1
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/04—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices
- H01L31/042—PV modules or arrays of single PV cells
- H01L31/048—Encapsulation of modules
- H01L31/0488—Double glass encapsulation, e.g. photovoltaic cells arranged between front and rear glass sheets
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/04—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices
- H01L31/042—PV modules or arrays of single PV cells
- H01L31/05—Electrical interconnection means between PV cells inside the PV module, e.g. series connection of PV cells
- H01L31/0504—Electrical interconnection means between PV cells inside the PV module, e.g. series connection of PV cells specially adapted for series or parallel connection of solar cells in a module
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/18—Processes or apparatus specially adapted for the manufacture or treatment of these devices or of parts thereof
- H01L31/1876—Particular processes or apparatus for batch treatment of the devices
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/50—Photovoltaic [PV] energy
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P70/00—Climate change mitigation technologies in the production process for final industrial or consumer products
- Y02P70/50—Manufacturing or production processes characterised by the final manufactured product
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- Condensed Matter Physics & Semiconductors (AREA)
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- Computer Hardware Design (AREA)
- Microelectronics & Electronic Packaging (AREA)
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- Sustainable Development (AREA)
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Abstract
The present invention provides a kind of imbrication solar battery solar double-glass assemblies and preparation method thereof, imbrication solar battery solar double-glass assemblies are equipped with glass cover-plate, packaging adhesive film, battery strings group, and photovoltaic conductive glass, the battery strings group contains one or more battery strings, the battery strings are formed by connecting by the first multiple cell piece and at least one second of cell piece, the front electrode of plurality of the first cell piece is opposite with the polarity of rear electrode, rear electrode on the back side of second of cell piece includes anode and cathode, the both ends of the battery strings are respectively equipped with electrode;The photovoltaic conductive glass includes glass, the first conductive structure, the second conductive structure, and adhesive film, electrode connection opening is equipped on the adhesive film at position corresponding with first conductive structure, the electrode at the battery strings both ends passes through electrode connection opening and connect conducting with first conductive structure, and the first conductive structure includes the conductive layer being set up directly on the glass.
Description
Technical field
The present invention relates to technical field of solar batteries, and in particular to a kind of imbrication solar battery solar double-glass assemblies and its system
Preparation Method.
Background technique
Imbrication solar battery solar double-glass assemblies in the important development course that visible future is efficient photovoltaic module,
Imbrication feature of the module first is that by traditional full wafer cell piece be cut into several small pieces (1/4,1/5,1/6 etc., can divide equally, can also
Not divide equally), conducting resinl is then coated on the electrode of cell piece, the edge of adjacent cell piece uses upper and lower arranged superposed, leads
Cell piece is joined together to form battery strings after electric adhesive curing, does so and conducting resinl can be used to substitute traditional metal welding
The utilization rate of component area can be improved using imbrication connection type for band;Two, component had both can be improved to each in double-sided glass component
The universality of the complicated usage scenario of kind, more can be in conjunction with double-side cell, thus the generating efficiency of lifting assembly.
The prior art is when imbrication solar double-glass assemblies make, in order to avoid the bring hot spot wind that is locally blocked in component operation
Danger usually has several battery strings to combine to form battery strings group in one block assembly, and bypass diode in parallel solves again in battery strings group
Certainly these problems.The actual service condition of coupling unit, according in component number of batteries number, usually want 2~4 sides in parallel
Road diode differs.
In order to be incorporated to diode, then needs for battery strings to be segmented, then reuse convergent belt and connect battery strings.
But this method disadvantage includes: the utilization rate in order to improve area, can be hidden in as far as possible metal bus bars
Cell backside, and busbar is usually parallel to one end of bypass diode by way of module backside wire jumper, that is to say, that
Usually there are 4 to 8 wire jumpers to be parallel on 2-4 bypass diode in component, not only increases operation complexity, and fragment rate
Height, the degree of automation are low.
Summary of the invention
In view of this, the purpose of the present invention is to provide a kind of imbrication solar battery solar double-glass assemblies, processing technology letter
It is single, fragment rate is low, high degree of automation.
In addition, the object of the invention is also to provide a kind of this preparation methods of imbrication solar battery solar double-glass assemblies.
In order to solve the above technical problems, the invention adopts the following technical scheme:
The imbrication solar battery solar double-glass assemblies of embodiment according to a first aspect of the present invention, successively from light-receiving surface to shady face
Equipped with glass cover-plate, packaging adhesive film, battery strings group and photovoltaic conductive glass,
The battery strings group contains one or more battery strings, and the battery strings are by the first multiple cell piece and at least one
A second of cell piece is formed by connecting, and the polarity of the front electrode of plurality of the first cell piece is consistent, Duo Gesuo
The polarity for stating the rear electrode of the first cell piece is also consistent, and the front electrode of multiple the first cell piece and the back side
The polarity of electrode on the contrary, the rear electrode on the back side of second of cell piece includes anode and cathode, the battery strings
Both ends are respectively equipped with electrode;
The photovoltaic conductive glass includes:
Glass, the glass are equipped with through-hole;
First conductive structure, first conductive structure are arranged in glass described in the interior lateral edge of the glass and are laterally extended,
First conductive structure includes being set up directly on for connecting conducting, first conductive structure with the electrode at battery strings both ends
Conductive layer on the glass;
Second conductive structure, second conductive structure are arranged in the inside of the glass and vertically prolong along the glass
It stretches, one end of second conductive structure is connected with first conductive structure and the other end passes through the through-hole and extends to glass
The other side of glass;And
Adhesive film, the adhesive film are covered on the glass inner side to clamp institute between the adhesive film and the glass
The first conductive structure and second conductive structure are stated, on the adhesive film at position corresponding with first conductive structure
It connects and is open equipped with electrode,
The electrode at the battery strings both ends passes through electrode connection opening and connect conducting with first conductive structure.
According to some embodiments of the present invention, the first described cell piece include A-I class cell piece, A-II class cell piece,
And one of A-III class cell piece or a variety of, every kind includes one or more, wherein
In the A-I class cell piece, the front electrode, rear electrode be respectively 1 and be respectively formed in it is described the first
The opposite side edge of cell piece;
In the A-II class cell piece, there are 2 rear electrodes, one of them described rear electrode is located at the A-
The edge at the back side of II class cell piece, another described rear electrode are located at the middle part at the back side of the A-II class cell piece;
In the A-III class cell piece, there are 2 front electrodes and be located at the first described cell piece just
The opposite side edge in face, the rear electrode are 1 and are located at the middle part at the back side.
According to some embodiments of the present invention, second of cell piece is back contact solar battery piece, the back
Contact solar battery piece includes MWT structure or IBC structure,
Preferably, second of cell piece includes B-I class cell piece, B-II class cell piece, in B-III class cell piece
One or more, every kind includes one or more,
Wherein, the back side of the B-I class cell piece includes the anode that 2 cathode and 1 are located at middle part, wherein 1 cathode
Positioned at edge part 1, cathode is located at middle part;
The back of the B-II class cell piece includes 1 anode and 2 cathode, wherein 1 cathode is located at edge part, anode
Positioned at opposite side edge part and another 1 cathode be located at middle part;
The back of the B-IV class cell piece includes 2 anodes and 1 cathode, wherein and 2 anodes are located at edge part, and 1
Cathode is located at middle part.
According to some embodiments of the present invention, the battery strings connect again after being mutually connected in series by the first multiple described cell piece
A piece of second of cell piece is connect to be formed;
Or second of cell piece is connected after being mutually connected in series by the first multiple described pond piece and continues series/parallel institute
The first cell piece is stated to be formed;
Or it is alternately formed by connecting by the first multiple described cell piece and second of cell piece.
Further, the first multiple described cell piece, which are mutually connected in series, is: the wherein back of a piece of the first cell piece
Face electrode is covered on the front electrode of adjacent a piece of the first cell piece, the rear electrode and front electrode mutually covered it
Between be equipped with conductive material.
Further, the connection between the first described cell piece and second of cell piece is: the first described electricity
The front electrode of pond piece is connected with the positive or negative pole in the rear electrode of second of cell piece to be respectively formed parallel connection
Or series connection, conductive material is equipped between the front electrode being connected and rear electrode.
According to some embodiments of the present invention, first conductive structure further includes insulating layer, and the insulating layer setting exists
Between the conductive layer and the adhesive film, it is multiple and described that electrode connection opening is monoblock type or discontinuous is arranged
Open Side Down extends up to the conductive layer for electrode connection.
According to some embodiments of the present invention, second conductive structure is since the glass surface towards the glue film
Layer is sequentially laminated with conductive layer and insulating layer, the conductive layer and insulating layer of second conductive structure respectively with institute
The conductive layer and insulating layer for stating the first conductive structure connect one to one, and the other end of second conductive structure is set
There is the output electrode that conducting is connect with the conductive layer, and the output electrode passes through the through-hole and extends to the another of glass
Side, output electrode described in second conductive structure draw unit by electrode and are connected with the conductive layer,
Preferably, the conductive layer is formed on the glass by the method for plating,
Preferably, it is set respectively at position corresponding with first conductive structure, the second conductive structure on the glass
Fluted, first conductive structure, the second conductive structure are laid in the groove respectively.
The preparation method of the imbrication solar battery solar double-glass assemblies of embodiment according to a second aspect of the present invention, including walk as follows
It is rapid:
Step S1 provides battery strings group, and the battery strings group contains one or more battery strings, and the battery strings are by multiple
The first cell piece and at least one second of cell piece are formed by connecting, the front electrode of plurality of the first cell piece
Polarity it is consistent, the polarity of the rear electrode of multiple the first cell piece is also consistent, and the first multiple described electricity
The front electrode of pond piece and the polarity of rear electrode are on the contrary, the rear electrode on the back side of second of cell piece includes anode
And cathode, the both ends of the battery strings are respectively equipped with electrode;
Step S2, provides photovoltaic conductive glass, and the photovoltaic conductive glass includes:
Glass, the glass are equipped with through-hole;
First conductive structure, first conductive structure are arranged in glass described in the interior lateral edge of the glass and are laterally extended,
First conductive structure is for connecting conducting with the electrode at battery strings both ends, and first conductive structure includes conductive layer, institute
Conductive layer is stated to be arranged between the glass and the adhesive film;
Second conductive structure, second conductive structure are arranged in the inside of the glass and vertically prolong along the glass
It stretches, one end of second conductive structure is connected with first conductive structure and the other end passes through the through-hole and extends to glass
The other side of glass;And
Adhesive film, the adhesive film are covered on the glass inner side to clamp institute between the adhesive film and the glass
The first conductive structure and second conductive structure are stated, on the adhesive film at position corresponding with first conductive structure
It connects and is open equipped with electrode;
Step S3, the electrode connection opening spraying to electrode and/or the photovoltaic conductive glass in the battery strings group
Conductive glue;
Step S4, according to sequence from bottom to up, by glass cover-plate, packaging adhesive film, the battery strings group and the light
Volt electro-conductive glass is laid, and so that electrode and the electrode in the battery strings is connect opening and formed conductive connect correspondingly
It connects;
Step S5 connects wiring between the output electrode of the photovoltaic conductive glass after EL test, lamination treatment
Box obtains the imbrication solar battery solar double-glass assemblies.
Above-mentioned technical proposal of the invention has the following beneficial effects:
Imbrication solar battery solar double-glass assemblies according to an embodiment of the present invention, using back contact solar battery piece and often
The mode that rule solar battery sheet combines saves traditional electrode and draws confluence welding, reduces component feature space waste, raising group
The space utilization rate of part, the generating efficiency of lifting assembly;Meanwhile so that the parallel connection technology between battery strings is simplified, improve
Component production efficiency;Moreover, can reduce the difficulty for being incorporated to diode, yields is promoted;Further, it is led by using photovoltaic
Battery strings typesetting cloth is postponed in assembling imbrication solar battery solar double-glass assemblies, directly places photovoltaic conductive glass by electric glass
In battery strings, connect opening using the electrode on photovoltaic conductive glass, by photovoltaic conductive glass and the electrode of battery strings according to
Corresponding design connection conducting, operates in battery strings tailpiece cell backside without any high-temperature soldering, reduces stress and generates, raising group
The reliability of part;In addition, also omiting lid back side packaging adhesive film, various since photovoltaic conductive glass is equipped with adhesive film
Insulation strip and cover glass etc. operation not only contribute to reduce production cost, additionally it is possible to be significantly reduced fragment rate, be promoted
Component efficiency and heat resistanceheat resistant spot performance.
Detailed description of the invention
Fig. 1 is the explosive view of the imbrication solar battery solar double-glass assemblies of embodiment 1;
Fig. 2 be the first cell piece an example before cutting after positive and negative schematic diagram, wherein (a) be full wafer A front, (b) be
The back side full wafer A is (c) front a after cutting, is (d) back side a after cutting;
Fig. 3 be another example of the first cell piece before cutting after positive and negative schematic diagram, wherein (a) be full wafer A ' front,
(b) it is the back side full wafer A ', is (c) front a ' after cutting, is (d) back side a ' after cutting;
Fig. 4 be second of cell piece an example before cutting after positive and negative schematic diagram, wherein (a) is that full wafer B is being just before cutting
Face (b) is the back side full wafer B, is (c) front b after cutting, is (d) back side b after cutting;
Fig. 5 is the series connection schematic diagram of battery strings in the imbrication solar battery solar double-glass assemblies of embodiment 1;
Fig. 6 is the circuit diagram of the imbrication solar battery solar double-glass assemblies of embodiment 1;
Fig. 7 is the structural schematic diagram of the photovoltaic conductive glass in the imbrication solar battery solar double-glass assemblies of embodiment 1;
Fig. 8 is the enlarged diagram in the area Tu7Zhong①;
Fig. 9 be Fig. 8 in A-A to diagrammatic cross-section;
Figure 10 is the enlarged diagram in the area Tu7Zhong②;
Figure 11 be Figure 10 in A-A to diagrammatic cross-section;
Figure 12 be another example of second of cell piece before cutting after positive and negative schematic diagram, wherein (a) is full wafer B ' before cutting
Front (b) is the back side full wafer B ', is (c) front b ' after cutting, is (d) back side b ' after cutting;
The connection schematic diagram of battery strings in the imbrication solar battery solar double-glass assemblies for the embodiment 2 that Figure 13 is;
Figure 14 is the circuit diagram of the imbrication solar battery solar double-glass assemblies of embodiment 2;
Figure 15 is the structural schematic diagram of the photovoltaic conductive glass in the imbrication solar battery solar double-glass assemblies of embodiment 2;
Figure 16: the positive and negative schematic diagram of the first cell piece and second of cell piece in embodiment 3, wherein (a) is first
The front kind of cell piece 2a (b) is the back side full wafer the first cell piece 2a, is (d) the (c) to cut second of front cell piece 2b "
Two kinds of back sides cell piece 2b ";
Figure 17 is the connection schematic diagram of a battery strings in the imbrication solar battery solar double-glass assemblies of embodiment 3;
Figure 18 is the connection schematic diagram of another battery strings in the imbrication solar battery solar double-glass assemblies of embodiment 3;
Figure 19 is the circuit diagram of the imbrication solar battery solar double-glass assemblies of embodiment 3;
Figure 20 is the structural schematic diagram of the photovoltaic conductive glass in the imbrication solar battery solar double-glass assemblies of embodiment 3.
Specific embodiment
In order to make the object, technical scheme and advantages of the embodiment of the invention clearer, below in conjunction with the embodiment of the present invention
Attached drawing, the technical solution of the embodiment of the present invention is clearly and completely described.Obviously, described embodiment is this hair
Bright a part of the embodiment, instead of all the embodiments.Based on described the embodiment of the present invention, ordinary skill
Personnel's every other embodiment obtained, shall fall within the protection scope of the present invention.
Unless otherwise defined, technical term or scientific term used in the present invention are should be in fields of the present invention
The ordinary meaning that personage with general technical ability is understood." first ", " second " used in the present invention and similar word
It is not offered as any sequence, quantity or importance, and is used only to distinguish different component parts.Equally, "one" or
The similar word such as " one " does not indicate that quantity limits yet, but indicates that there are at least one." connection " or " connected " etc. are similar
Word is not limited to physics or mechanical connection, but may include electrical connection, it is either direct or between
It connects."upper", "lower", "left", "right" etc. are only used for indicating relative positional relationship, when the absolute position for being described object changes
Afterwards, then the relative positional relationship also correspondingly changes.
Imbrication solar battery solar double-glass assemblies according to an embodiment of the present invention are specifically described in conjunction with attached drawing first below.
As shown in Figure 1, imbrication solar battery solar double-glass assemblies according to an embodiment of the present invention from light-receiving surface to shady face according to
It is secondary to be equipped with glass cover-plate 101, packaging adhesive film 201, battery strings group 301 and photovoltaic conductive glass 401.
As shown in Figure 1, battery strings group 301 contains one or more battery strings 500.As shown in figure 5, battery strings 500 are by multiple
The first cell piece and at least one second of cell piece are formed by connecting.
Wherein, the polarity of the front electrode of the first cell piece is consistent, the back of multiple the first cell piece
The polarity of face electrode is also consistent, and the front electrode of multiple the first cell piece is opposite with the polarity of rear electrode.
Specifically, as shown in Fig. 2, Fig. 3 and Figure 16, the first described cell piece includes A-I class cell piece, A-II class
One of cell piece and A-III class cell piece are a variety of, and every kind includes one or more.
Wherein, as shown in Fig. 2, in the A-I class cell piece, the front electrode 11, rear electrode 12 respectively for 1 and are divided
It is not formed in the opposite side edge of the A-I class cell piece.That is, the front electrode 11, rear electrode 12 are located at this
The two sides of the long side of A-I class cell piece, and it is located at front and back.
As shown in figure 3, there is 2 rear electrodes, one of them described rear electrode in the A-II class cell piece
14 are located at the edge (front on one side opposite with the edge is formed with front electrode 13) at the back side of the A-II class cell piece,
Another rear electrode 15 is located at the middle part at the back side of the A-II class cell piece and is discontinuous line segment.
As shown in figure 16, in the A-III class cell piece, there are 2 front electrodes and be located at described first
The positive opposite side edge of kind cell piece, the rear electrode are 1 and are located at the middle part at the back side.In other words, the A-III class
Cell piece is 2 times of sizes of A-I class cell piece, it can be understood as, then shape is cut from centre when full wafer cell piece is cut
At A-I class cell piece, A-III class cell piece is formd if not cutting from centre.
Second of cell piece is back contact solar battery piece, and the back contact solar battery piece includes
MWT structure or IBC structure.Preferably, as shown in Fig. 4, Figure 12 and Figure 16, second of cell piece includes B-I class battery
One of piece, B-II class cell piece, B-III class cell piece are a variety of, and every kind includes one or more.
Specifically, as shown in figure 4, the back side of B-I class cell piece includes the anode 18 that 2 cathode and 1 are located at middle part,
Wherein 1 cathode 17 is located at the cathode 19 of edge part 1 and is located at middle part.Anode 18 is by perforation means and is located at positive electrode 16
It is conducted.
As shown in figure 12, the back of the B-II class cell piece includes 1 anode and 2 cathode, one of cathode 27
Positioned at edge part, anode 29 is located at the edge part of opposite side and another 1 cathode 28 is located at middle part.
As shown in Figure 16 (d), the back of the B-III class cell piece includes 2 anodes and 1 cathode, wherein 2 just
Pole 24 is located at edge part, and 1 cathode 25 is located at middle part.
According to some embodiments of the present invention, as shown in figure 5, the battery strings 500 are by the first multiple described cell piece
A piece of second of cell piece is reconnected after being mutually connected in series to be formed.That is, second of cell piece is located at battery strings
End.
Other embodiments according to the present invention, as shown in Figure 13 and Figure 18, the battery strings 500 are by multiple described first
Kind pond piece connects second of cell piece and continues the first cell piece described in series/parallel and formed after being mutually connected in series.Also
It is to say, second of cell piece is located at the middle part of battery strings.
Other embodiments according to the present invention, the battery strings 500 are by the first multiple described cell piece and second
Cell piece is alternately formed by connecting (not shown).
Specifically, the not special limitation such as quantity, link position of the first cell piece, second cell piece, can be with
It is arranged accordingly according to Layout Design demand.
Herein, it should be noted that when being related to the first cell piece of multi-disc, the first electricity of polymorphic type can be selected
Pond piece (as shown in figure 5, including A-I class cell piece, A-II class cell piece), can also select the first same type of cell piece
(not shown).Similarly, when being related to second of cell piece of multi-disc, second of cell piece of polymorphic type can be selected (not scheme
Show), the first same type of cell piece (not shown) can also be selected.
According to some embodiments of the present invention, the first multiple described cell piece, which are mutually connected in series, may is that (as shown in Figure 5)
Wherein the rear electrode 12 of a piece of the first cell piece is covered on the front electrode of adjacent a piece of the first cell piece
On 11, conductive material (such as conducting resinl) is equipped between the rear electrode mutually covered and front electrode.
In addition, the connection between the first described cell piece and second of cell piece may is that as shown in figure 5, institute
The front electrode (not shown) for stating the first cell piece is connected with the cathode 17 in the rear electrode of second of cell piece
To form series connection, conductive material (such as conducting resinl) is equipped between the front electrode being connected and rear electrode.
Imbrication solar battery solar double-glass assemblies according to an embodiment of the present invention, by using back contact solar battery piece
With the mode that conventional solar battery sheet combines, saves traditional electrode and draw confluence welding, reduce component feature space waste, mention
The space utilization rate of high component, the generating efficiency of lifting assembly;Meanwhile so that the parallel connection technology between battery strings is simplified,
Improve component production efficiency;Moreover, can reduce the difficulty for being incorporated to diode, yields is promoted.Further, by using light
Electro-conductive glass is lied prostrate, is postponed battery strings typesetting cloth in assembling imbrication solar battery solar double-glass assemblies, directly by photovoltaic conductive glass
It is placed in battery strings, opening is connected using the electrode on photovoltaic conductive glass, by the electrode of photovoltaic conductive glass and battery strings
Connection conducting is designed according to corresponding, is operated in battery strings tailpiece cell backside without any high-temperature soldering, is reduced stress and generate, mention
The reliability of high component;In addition, due to photovoltaic conductive glass be equipped with adhesive film, also omit lid back side packaging adhesive film,
Various insulation strips and cover glass etc. operation not only contribute to reduce production cost, additionally it is possible to it is significantly reduced fragment rate,
Lifting assembly efficiency and heat resistanceheat resistant spot performance.
In the following, the photovoltaic in imbrication solar battery solar double-glass assemblies according to an embodiment of the present invention is described in detail in conjunction with attached drawing
Electro-conductive glass 401.
According to some embodiments of the present invention, photovoltaic conductive glass 401, as shown in figs. 7 to 11, comprising: glass 1,
One conductive structure 2, the second conductive structure 3 and adhesive film 4.
Wherein, glass 1 is equipped with through-hole (not shown).
First conductive structure 2 is arranged in the inside (namely close to 301 side of battery strings group) of glass 1 and along 1 cross of glass
To extension (left and right directions as shown in Figure 7).First conductive structure 2 is led for connecting with the two end electrodes in battery strings group 301
It is logical.First conductive structure 2 includes the conductive layer 7 being set up directly on glass 1.Herein, it should be noted that set according to format
The first conductive structure of multiple groups 2 has can be set on photovoltaic conductive glass 401 in meter, also can be set 1 group and (including is located at light
Each row for lying prostrate the lower edges of electro-conductive glass is two rows of altogether) the first conductive structure 2 (not shown).For example, being provided with 3 altogether in Fig. 7
The first conductive structure 2 of group is to correspond to 3 row's battery strings groups (as shown in Figure 6);It is shown in Figure 15 and Figure 16 and is provided with 2 group first
The case where conductive structure 2, wherein corresponding two rows of battery strings groups are parallel connection, arranging the first conductive structure 2 positioned at the one of middle part can
To share and (width corresponding with two rows of electrodes can be provided accordingly on width).
The inside of glass 1 and vertically extending (up and down direction as shown in Figure 7) along glass 1 is arranged in second conductive structure 3.
Wherein, one end of the second conductive structure 3 and the first conductive structure 2 are connected and the other end passes through the through-hole and extends to glass 1
The other side.
Adhesive film 4 is covered on 1 inside of glass and is led with clamping the first conductive structure 2 between adhesive film 4 and glass 1 with second
Electric structure 3.Electrode connection opening 9 is equipped on adhesive film 4 at position corresponding with the first conductive structure 1, so as to battery strings 500
The electrode at both ends passes through electrode connection opening 9 and connect conducting with the first conductive structure 2.Wherein, the main function of adhesive film 4 be for
Photovoltaic conductive glass 401 and aftermentioned battery strings group bonded.In addition, its secondary role is clamped together with glass 1
First conductive structure 2 and the second conductive structure 3.
Above-mentioned photovoltaic conductive glass 401 according to an embodiment of the present invention can be substituted by the way that the first conductive structure 2 is arranged
Traditional metal bus bars are directly realized by photovoltaic conductive glass 401 and are connected with the connection of battery strings 500, further, pass through setting
The electric energy from battery strings 500 collected via the first conductive structure 2 is directly output to outside glass 1 by the second conductive structure 3
Side is operated in 500 tailpiece cell backside of battery strings without any welding;Further, since photovoltaic conductive glass 401 is equipped with glue
Film layer 4, therefore the operation that also omits lid back side packaging adhesive film, various insulation strips and cover glass etc., greatly reduce broken
Piece rate;And possibility is provided for the realization of whole-course automation.
Further, according to some embodiments of the present invention, as shown in figs. 7 to 9, the first conductive structure 2 is from 1 table of glass
Face starts to be sequentially laminated with conductive layer 7 and insulating layer 8 towards adhesive film 4, which is arranged in conductive layer 7 and adhesive film
Between 4.
Wherein, electrode connection opening 9 can for continuous integral type (not shown) or discontinuous arrangement it is multiple (such as Fig. 7 institute
Show), and electrode connection opening 9 extends downwardly until conductive layer 7 (as shown in Figure 9).
Form about electrode connection opening 9 does not limit specifically, can be according to the back side of battery strings 500 joined together
Electrode is accordingly arranged.For example, when the back side main grid that the rear electrode of battery slice is discontinuous line segment shape, correspondingly light
Volt electro-conductive glass 401 in electrode connection opening 9 can be formed as discontinuous arrangement it is multiple with respectively with back side main grid one by one
It is correspondingly connected with;When the back side main grid of cell piece is continuous linear, or even if overleaf main grid is discontinuous line segment shape
In the case where the main grid of the back side, electrode can be connected into opening 9 and be designed as continuous integral type.
According to some embodiments of the present invention, as shown in figs. 10-11, the second conductive structure 3 since 1 surface of glass to
Adhesive film 4 be sequentially laminated with conductive layer 7 and insulating layer 8.Wherein, the conductive layer 7 and insulating layer of the second conductive structure 3
8 connect one to one with the conductive layer 7 of the first conductive structure 2 and insulating layer 8 respectively.Second conductive structure 3 it is described another
End (one end namely far from the first conductive structure 2) is equipped with the output electricity that conducting is connect with the conductive layer 7 of the second conductive structure 3
Pole 5, and output electrode 5 passes through the through-hole and extends to the other side of glass 1.Output electrode 5 passes through the second conductive knot as a result,
The conductive layer 7 of the conductive layer 7 of structure 3 and the first conductive structure 2 is conducted and passes through the electric energy collected by the first conductive structure 2
The output electrode 5 output, this is simple and reliable for structure.Further, as shown in figure 11, which can be drawn by electrode
Unit 51 is electrically connected with conductive layer 7 out.
In addition, the setting method as the first conductive structure 2 and the second conductive structure 3, it can be according to designed domain
Conductive layer 7 is first deposited by vapor deposition, CVD method etc. on glass 1, hereafter laying insulating layer 8 is realized, in other words, can be with
The setting of the conductive layer 7 in the conductive layer 7 and the second conductive structure 3 in the first conductive structure 2 is completed by the same step, together
Sample, insulating layer 8 is same.
Further, it is respectively equipped at position corresponding with the first conductive structure 2, the second conductive structure 3 on glass 1
Groove (not shown), the first conductive structure 2, the second conductive structure 3 are laid in groove respectively.In this way, adhesive film 4 can be made
Keep smooth on the whole, further reduction fragment rate.
In the following, imbrication solar battery solar double-glass assemblies according to the present invention and its preparation side are described in detail by embodiment
Method.
Embodiment 1:
Fig. 1 is the structural schematic diagram of the imbrication solar battery solar double-glass assemblies in the embodiment of the present invention 1.
As shown in Figure 1, stacked tile type imbrication solar battery solar double-glass assemblies provided in this embodiment, support or oppose according to from light-receiving surface
Smooth surface sequence successively includes glass cover-plate 101, packaging adhesive film 201, battery strings group 301, photovoltaic conductive glass 401.
Wherein, battery strings group 301 is composed of multiple battery strings 500.As shown in figure 5, each battery strings 500 are by multiple
The first cell piece a, a ' and a piece of second of cell piece b are connected with each other.
Wherein, the back side of the first cell piece a ' has 2 primary gate electrodes 14, and 15, and the positive mask of second of cell piece b
There is electrode 16 (front can also not have electrode when occuping first position).
It designs in this way, the tow sides of convergent belt (welding) connection adjacent cells piece can not had to, it can be according to battery feelings
Condition flexible design circuit diagram can effectively improve production efficiency in assembly end, reduce the fragment rate etc. in production, while can guarantee
The effective rate of utilization that component area is improved on the basis of component heat resistanceheat resistant spot performance, increases the generating efficiency of component.
As shown in Figures 2 and 3, the first cell piece a, a ' is formed by full wafer battery cutting fragment respectively, after cutting fragment
The structure of the first the multiple cell piece formed is identical.
Similarly, second of cell piece b is also by full wafer battery through cutting.
Each battery strings 500 are connected in series mutually by multiple second of cell piece and the first multiple cell piece.
It is that the front electrode of wherein the first cell piece is covered on adjacent one first that the first multiple cell piece, which are mutually connected in series,
In the rear electrode of kind cell piece, conductive media object is equipped between the front electrode mutually covered and rear electrode.
Connection between the first cell piece and second of cell piece is front electrode and the institute of the first cell piece
The electrode connection for stating the close cell piece edge at the back side of second of cell piece, between the front electrode being connected and rear electrode
Equipped with conductive media object.
The first cell piece of same size and the current difference of second of cell piece are within 2%.
The front of second of cell piece also is provided with electrode (cathode) 16, and electrode leads to second of cell piece by perforation means
The back side formed with the electrode 17 and 18 of front identical polar, in addition, the back side of second of cell piece close to another side edge also
It is formed with the opposite polarity electrode (anode) 19 in front, it is mutually exhausted between the positive electrode and negative electrode on the back side of second of cell piece
Edge.
Photovoltaic conductive glass 401 in the present embodiment is the glass that band has conductivity, according to the arrangement of battery strings group 301
Design method, it is corresponding to design matching circuit structure, so that first in battery strings group 301 and photovoltaic conductive glass 401
Conductive structure 2 is connected with each other conducting.
Photovoltaic conductive glass 401 in the present embodiment, as shown in fig. 7, comprises be located at glass inner side and extend transversely
One conductive structure 2, for first conductive structure 2 for connecting conducting with the electrode at 301 both ends of battery strings group, described first is conductive
Structure 2 includes the conductive layer 7 being set up directly on the glass 1;And positioned at glass inner side and vertically extending second leads
Electric structure 3, one end of second conductive structure 3 and first conductive structure 2 are connected and the other end passes through the through-hole simultaneously
Extend to the other side of glass 1.First conductive structure 2 and the second conductive structure 3 are distributed with 500 head and the tail of battery strings and midfeather
The electrode left a blank connect one to one according to design, formed conductive communication, junction be equipped with conductive media object.
First conductive structure 2 will collect the electric energy of battery strings 500, and the electricity of the output by being arranged on the second conductive structure 3
Pole 5 connects terminal box.
After battery strings group 301 is good according to design arranged, the present invention does not need to converge in battery strings group 301
The welding of item can be connected by the first conductive structure 2 on glass 1 and the second conductive structure 3 with battery strings group 301 in the present invention
Conducting is connect, so that forming conductive communication between battery strings group 301 and electro-conductive glass.
As shown in figure 5, the connection between adjacent cell piece is carried out using lamination process when the first cell piece is mutually connected in series
Series connection, wherein the front main grid electrode of a piece of battery is arranged on the back side primary gate electrode of the first adjacent cell piece, anode
The position being in contact between cathode is equipped with conductive media object, when the first battery connects certain amount after (1~40), then
A piece of second of cell piece is sealed in, when second of cell piece and the first cell piece are mutually connected in series, between adjacent cell piece
Connection is attached using lamination process, wherein the front electrode of second a piece of of cell piece is stacked in the first adjacent a piece of electricity
At the rear electrode of pond piece, then proceed to connect on the first cell piece to second of cell piece, series connection a certain number of first
After kind cell piece, then a piece of second of cell piece of connecting, so circulation obtain required battery strings.
The electrode of second of cell backside can be a dotted, oval, rectangle either continuous grid line.
The present embodiment uses the first cell piece (conventional solar battery) and second of cell piece (back contact solar
Battery) production component is combined, it is connected after two kinds of cell piece cutting fragments using lamination process, segmentation is being carried on the back between battery strings
Contact cell backside is in parallel, forms the circuit that series and parallel combines, and in circuit appropriate location parallel diode, is made
Component, the specific steps are as follows:
Full wafer battery A is chosen, A is carried out not exclusively at primary gate electrode reserved location at the back side of A using laser
Cutting, depth of cut reach the 40%~60% of the thickness of A, conducting resinl are then imprinted on to printing machine the back side primary gate electrode of A
A, is divided into the cell piece a, Fig. 2 of multiple 1/5 sizes (a) by place using slicing apparatus, (b), (c), (d) before for cell piece cutting
Schematic diagram afterwards, wherein (a) figure is the front of cell piece before cutting, it (c) is fragment that (b) figure, which is the back side of cell piece before cutting,
The front of cell piece afterwards is (d) back side of cell piece after fragment;
The battery A ' for choosing another back electrode structure, using laser at the close primary gate electrode reserved location of A '
A ' is not exclusively cut, depth of cut reaches the 40%~60% of the thickness of A ', is divided into A ' using slicing apparatus multiple
It is (d) schematic diagram of cell piece cutting front and back, wherein (a) figure is to cut (c) (b) in the cell piece a ', Fig. 3 of 1/5 size (a)
The front of cell piece before cutting, (b) figure is the back side of cell piece before cutting, and is (c) front of cell piece after fragment, (d) is fragment
The back side of cell piece afterwards;
Choose back contact solar battery B, using laser B at the reserved location of primary gate electrode 17 to B into
Row not exclusively cutting, depth of cut reach the 40%~60% of the thickness of B, conducting resinl are then imprinted on to printing machine the back side of B
At primary gate electrode, B is divided into the cell piece b, Fig. 4 of multiple 1/5 sizes (a) using slicing apparatus, (d) is battery (c) (b)
The schematic diagram of piece cutting front and back, wherein (a) figure is the front of cell piece before cutting, (b) figure is the back side of cell piece before cutting,
(c) it is the front of cell piece after fragment, is (d) back side of cell piece after fragment;
Battery strings 500 make: taking a piece of second of cell piece b, check appearance, then choose a piece of the first cell piece a, together
Sample checks appearance, connects a and b using the mode of lamination, the front electrode 11 of the first cell piece a is arranged in second of battery
In the rear electrode 19 of piece b, it is provided with conductive media object at two contact electrode positions, takes second the first cell piece a, is examined
Appearance is looked into, second cell piece a and first cell piece a are connected using the mode of lamination, second cell piece a is just
Face electrode is arranged in the rear electrode of first cell piece a, and positive and negative electrode is in contact at position and is provided with conductive media object, makes
After a certain number of the first cell piece a of same procedure series connection, a piece of second of cell piece b is added, checks second of electricity
Pond piece b appearance connects the rear electrode 17 (cathode) of second of cell piece b and the rear electrode 12 (anode) of upper a piece of battery a
It connects;Then proceed to the first cell piece a that connects, electrode 19 (anode) connection of the front electrode and b battery of battery;
After the first cell piece a concatenated in battery strings 500 and second of cell piece b reach certain amount, one is chosen
A kind of cell piece a ' in piece ground, checks the appearance of cell piece a ', by the front electrode 13 of the first cell piece a ' and battery strings tail portion
The first cell piece a back side primary gate electrode 12 be overlapped, so production formed include the first multiple cell piece and at least one
The battery strings of second of cell piece b of piece, then multiple battery strings are formed into battery strings group according to circuit design arranged;
By the electrode connection opening spraying conducting resinl on the first conductive structure 2 on photovoltaic conductive glass 401, or will
Corresponding electrode coats conductive media object in battery strings group 301, by electrode connection opening and the counter electrode one in battery strings group
One connection, forms conductive communication;
According to the sequence from light-receiving surface to shady face, by glass cover-plate 101,201, battery packaging adhesive film (EVA or POE)
String group 301, photovoltaic conductive glass 401 are completed;
Be laid with after completing is included EL test, lamination postprocessing working procedures processing;
The terminal box of diode is had according to circuit diagram installation between the output electrode 15 of photovoltaic conductive glass 401
Stacked tile type imbrication solar battery solar double-glass assemblies are made.
Embodiment 2:
The structure of imbrication solar battery solar double-glass assemblies provided in this embodiment is similar with embodiment 1, and difference exists
In: as shown in figure 12, the specific electrode position arrangement and shape of second of cell piece b ' is different from embodiment 1;And such as Figure 13
Shown, when preparing battery strings 500, second of cell piece b ' is located at the middle part (as shown in Figure 12 and Figure 13) of battery strings 500,
And two rows battery is series-parallel;It correspondingly, also only include upper and lower two group of first conductive structure in photovoltaic conductive glass 401
2, the second conductive structure 3 is located at the one side edge on vertical.
Others, the specific preparation process of cell piece and the specific preparation process of imbrication solar battery solar double-glass assemblies
Similar to Example 1, description is omitted herein.
Embodiment 3:
Imbrication solar battery solar double-glass assemblies provided in this embodiment, as shown in Figure 16-Figure 20, by the first of identical quantity
Kind cell piece and/or second of cell piece carry out two small string battery strings of series connection formation, intermediate electricity in parallel using lamination process
The area of pond piece is two times of other cell pieces big, and power and electric current are 2 times of other circuits.There are two types of batteries in the present embodiment
String forms battery strings group for combining, and is that anode is drawn one is intermediate cell, is cathode extraction one is intermediate cell.
As shown in Figure 17-Figure 18, two baby battery strings are used using the first cell piece and/or second of cell piece
Lamination process is connected bunchiness, the first or second of the cutting cell piece for then reusing a piece of two times of areas are electric by two small strings
Pond forms new battery strings in series and parallel, wherein the cutting cell piece of two times of areas goes here and there cell piece negligible amounts in battery strings with two
It is connected using concatenated mode for a string, is connect with a fairly large number of another wear of cell piece using parallel way.
The preparation method of the stacked tile type imbrication solar battery solar double-glass assemblies, comprising the following steps:
The present embodiment combines production component using conventional solar battery and back contact solar battery, uses conductive glass
Glass, connection battery strings group form conductive communication, the specific steps are as follows:
With reference to Fig. 2, Figure 12, Figure 16, prepare the first cell piece a, 2a and second of cell piece b ' and 2b " respectively.
Battery strings 500 ' make: as shown in figure 17, taking a piece of second of cell piece b ', check appearance, then take a piece of first
Kind battery a equally checks appearance, and two panels cell piece carries out series connection bunchiness using lamination process, wherein a piece of the first cell piece a
Front electrode main grid 1 be arranged in the rear electrode 117 of adjacent second of cell piece b ', positive and negative anodes, which are in contact at position, to be arranged
There is conductive media object, if then taking dry plate the first cell piece a again, equally carries out series connection bunchiness, series connection one using lamination process
Stop after the first cell piece a of fixed number amount, form baby battery string, take the first cell piece 2a ' of a piece of two times of areas at this time,
Appearance is checked, by the back side of the front electrode 122 of the positive side of 2a ' and finally a piece of the first cell piece a of baby battery string electricity
Pole 12 is connected using lamination process, and the positive and negative anodes position that is in contact is provided with conductive media object, just by the positive other side 2a '
Face electrode and the rear electrode 12 of last a piece of the first cell piece a of another small string battery strings are gone here and there using the mode of lamination
It is unified into string, the centre formed is connected in parallel by the first cell piece of a piece of two times of areas in this way, being fabricated to two small string battery strings
The new battery strings 500 ' that anode is drawn;
Battery strings 500 " make: as shown in figure 18, take a piece of the first cell piece a, check appearance, then take it is a piece of the first
Battery a equally checks appearance, and two panels cell piece carries out series connection bunchiness using lamination process, wherein a piece of the first cell piece a
Front electrode main grid 1 is arranged in the rear electrode 12 of adjacent the first cell piece a, and positive and negative anodes are in contact at position to be provided with and lead
Electric medium equally carries out series connection bunchiness using lamination process if then taking dry plate the first cell piece a again, a fixed number of connecting
After the first cell piece a of amount, then a piece of the first cell piece a ' is chosen, cell piece a ' is same using lamination process and adjacent
Cell piece a is connected in series, and the front main grid electrode 13 of cell piece a ' is arranged in the back side primary gate electrode 12 of adjacent cell piece a
On, the positive and negative anodes position that is in contact is provided with conductive media object, and baby battery string is made, takes second of cell piece of a piece of two times of areas
2b " checks appearance, then a piece of the first cell piece a is taken equally to check appearance, and cell piece a and cell piece 2b " use lamination process
It is attached, the front electrode 11 of cell piece a is arranged on the pole 24 of the reverse side of cell piece 2b ", and positive and negative anodes are in contact position
Conductive media object has been installed, has then chosen a number of cell piece a again, equally has continued to connect using lamination process, then again
A piece of cell piece a ' is chosen, cell piece a ' and cell piece a are equally connected using lamination process, the front electrode of cell piece a '
13 are arranged again in the rear electrode 12 of adjacent cell piece a, and positive and negative anodes are in contact position equipped with conductive media object, finally, by more
The front electrode 11 of first cell piece a of baby battery string made of the first a cell piece with by the first multiple cell piece and one
Another side pole 24 in the back side of first cell piece 2b " of battery strings made of a second of cell piece 2b " is carried out using lamination process
Connection, positive and negative anodes are in contact position equipped with conductive media object, in this way, being fabricated to two small string battery strings by the of a piece of two times of areas
Two kinds of cell pieces are connected in parallel the new battery strings 500 " that the intermediate cell cathode to be formed is drawn;
The production of battery strings group 301: according to circuit diagram as shown in figure 19, according to from left to right 3 battery strings of arrangement
500 ', 3 battery strings 500 ", combination arrangement form battery strings group, and electrode connection 10 settings of opening on electro-conductive glass are conductive
Then electrode connection opening is connect conducting with the counter electrode in battery strings group by medium one by one;
Photovoltaic conductive glass 401 as shown in figure 20 is made, wherein the first conductive structure 2 includes 2 groups of totally three rows, centre one
It ranked first conductive structure and disconnect (disconnection herein refers to that electricity is not turned on) from middle part, the second conductive structure 3 is located at the perpendicular of glass 1
To both sides of the edge, to respectively correspond the arrangement of the battery strings 500 ' and 500 " in battery strings group 301;
According to the sequence from light-receiving surface to shady face, by glass cover-plate 101,201, battery packaging adhesive film (EVA or POE)
String group 301, photovoltaic conductive glass 401 are completed;
Be laid with after completing is included EL test, lamination postprocessing working procedures processing;
The terminal box of diode is had according to circuit diagram installation between the output electrode 15 of photovoltaic conductive glass 401
Stacked tile type imbrication solar battery solar double-glass assemblies are made.
The above is a preferred embodiment of the present invention, it is noted that for those skilled in the art
For, without departing from the principles of the present invention, it can also make several improvements and retouch, these improvements and modifications
It should be regarded as protection scope of the present invention.
Claims (9)
1. a kind of imbrication solar battery solar double-glass assemblies, which is characterized in that from light-receiving surface to shady face be successively arranged glass cover-plate,
Packaging adhesive film, battery strings group and photovoltaic conductive glass,
The battery strings group contains one or more battery strings, the battery strings by the first multiple cell piece and at least one the
Two kinds of cell pieces are formed by connecting, and the polarity of the front electrode of plurality of the first cell piece is consistent, and multiple described the
A kind of polarity of the rear electrode of cell piece is also consistent, and the front electrode and rear electrode of multiple the first cell piece
Polarity on the contrary, rear electrode on the back side of second of cell piece includes anode and cathode, the both ends of the battery strings
It is respectively equipped with electrode;
The photovoltaic conductive glass includes:
Glass, the glass are equipped with through-hole;
First conductive structure, first conductive structure is arranged in glass described in the interior lateral edge of the glass and is laterally extended, described
First conductive structure includes being set up directly on institute for connecting conducting, first conductive structure with the electrode at battery strings group both ends
State the conductive layer on glass;
The inside of the glass and, institute vertically extending along the glass is arranged in second conductive structure, second conductive structure
The one end for stating the second conductive structure is connected with first conductive structure and the other end passes through the through-hole and extends to glass
The other side;And
Adhesive film, the adhesive film are covered on the glass inner side to clamp described between the adhesive film and the glass
One conductive structure and second conductive structure are equipped on the adhesive film at position corresponding with first conductive structure
Electrode connection opening,
The electrode at the battery strings both ends passes through electrode connection opening and connect conducting with first conductive structure.
2. imbrication solar battery solar double-glass assemblies according to claim 1, which is characterized in that the first described cell piece packet
One of A-I class cell piece, A-II class cell piece and A-III class cell piece or a variety of are included, every kind includes one or more,
Wherein,
In the A-I class cell piece, the front electrode, rear electrode are respectively 1 and are respectively formed in the first described battery
The opposite side edge of piece;
In the A-II class cell piece, there are 2 rear electrodes, one of them described rear electrode is located at the A-II class
The edge at the back side of cell piece, another described rear electrode are located at the middle part at the back side of the A-II class cell piece;
In the A-III class cell piece, with 2 front electrodes and it is located at the positive of the first cell piece
Opposite side edge, the rear electrode are 1 and are located at the middle part at the back side.
3. imbrication solar battery solar double-glass assemblies according to claim 1, which is characterized in that second of cell piece be
Back contact solar battery piece, the back contact solar battery piece include MWT structure or IBC structure,
Preferably, second of cell piece includes one of B-I class cell piece, B-II class cell piece, B-III class cell piece
Or it is a variety of, every kind includes one or more,
Wherein, the back side of the B-I class cell piece includes the anode that 2 cathode and 1 are located at middle part, wherein 1 cathode is located at
The cathode of edge part 1 is located at middle part;
The back of the B-II class cell piece includes 1 anode and 2 cathode, wherein 1 cathode is located at edge part, anode is located at
The edge part of opposite side and another 1 cathode is located at middle part;
The back of the B-IV class cell piece includes 2 anodes and 1 cathode, wherein 2 anodes are located at edge part, 1 cathode
Positioned at middle part.
4. imbrication solar battery solar double-glass assemblies according to claim 1, which is characterized in that the battery strings are by multiple institutes
It states and reconnects a piece of second of cell piece after the first cell piece is mutually connected in series and formed;
Or second of cell piece is connected after being mutually connected in series as the first multiple described pond piece and is continued described in series/parallel
A kind of cell piece is formed;
Or it is alternately formed by connecting by the first multiple described cell piece and second of cell piece.
5. imbrication solar battery solar double-glass assemblies according to claim 4, which is characterized in that the first multiple described battery
Piece is mutually connected in series: wherein the rear electrode of a piece of the first cell piece is covered on the first adjacent a piece of described cell piece
Front electrode on, between the rear electrode mutually covered and front electrode be equipped with conductive material.
6. imbrication solar battery solar double-glass assemblies according to claim 4, which is characterized in that the first described cell piece with
Connection between second of cell piece is: the back of the front electrode of the first cell piece and second of cell piece
Positive or negative pole in the electrode of face is connected to be respectively formed between the front electrode in parallel or series, being connected and rear electrode
Equipped with conductive material.
7. imbrication solar battery solar double-glass assemblies according to claim 1, which is characterized in that first conductive structure is also
Including insulating layer, the insulating layer is arranged between the conductive layer and the adhesive film, and the electrode connection opening is whole
Formula or discontinuous arrangement it is multiple, and Open Side Down extends up to the conductive layer for electrode connection.
8. imbrication solar battery solar double-glass assemblies according to claim 7, which is characterized in that second conductive structure from
The glass surface starts to be sequentially laminated with conductive layer and insulating layer towards the adhesive film, second conductive structure
The conductive layer and insulating layer connect one to one with the conductive layer of first conductive structure and insulating layer respectively, institute
The other end for stating the second conductive structure is equipped with the output electrode that conducting is connect with the conductive layer, and the output electrode is worn
It crosses the through-hole and extends to the other side of glass, output electrode described in second conductive structure draws unit by electrode
It is connected with the conductive layer,
Preferably, the conductive layer is formed on the glass by the method for plating,
Preferably, it is respectively equipped at position corresponding with first conductive structure, the second conductive structure on the glass recessed
Slot, first conductive structure, the second conductive structure are laid in the groove respectively.
9. a kind of preparation method of imbrication solar battery solar double-glass assemblies, which comprises the steps of:
Step S1 provides battery strings group, and the battery strings group contains one or more battery strings, and the battery strings are by multiple first
Kind cell piece and at least one second of cell piece are formed by connecting, the pole of the front electrode of plurality of the first cell piece
Property it is consistent, the polarity of the rear electrode of multiple the first cell piece is also consistent, and the first multiple described cell piece
Front electrode and rear electrode polarity on the contrary, rear electrode on the back side of second of cell piece includes anode and negative
The both ends of pole, the battery strings are respectively equipped with electrode;
Step S2, provides photovoltaic conductive glass, and the photovoltaic conductive glass includes:
Glass, the glass are equipped with through-hole;
First conductive structure, first conductive structure is arranged in glass described in the interior lateral edge of the glass and is laterally extended, described
For first conductive structure for connecting conducting with the electrode at battery strings both ends, first conductive structure includes conductive layer, described to lead
Electric layer is arranged between the glass and the adhesive film;
The inside of the glass and, institute vertically extending along the glass is arranged in second conductive structure, second conductive structure
The one end for stating the second conductive structure is connected with first conductive structure and the other end passes through the through-hole and extends to glass
The other side;And
Adhesive film, the adhesive film are covered on the glass inner side to clamp described between the adhesive film and the glass
One conductive structure and second conductive structure are equipped on the adhesive film at position corresponding with first conductive structure
Electrode connection opening;
Step S3, it is conductive to the electrode connection opening spraying of electrode and/or the photovoltaic conductive glass in the battery strings group
Glue;
Step S4 leads glass cover-plate, packaging adhesive film, the battery strings group and the photovoltaic according to sequence from bottom to up
Electric glass is laid, and so that electrode and the electrode in the battery strings is connect opening and formed conductive connection correspondingly;
Step S5 connects terminal box between the output electrode of the photovoltaic conductive glass after EL test, lamination treatment,
Obtain the imbrication solar battery solar double-glass assemblies.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201910605981.5A CN110350047A (en) | 2019-07-05 | 2019-07-05 | Imbrication solar battery solar double-glass assemblies and preparation method thereof |
Applications Claiming Priority (1)
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