CN211529978U

CN211529978U - Encapsulated large area perovskite solar cells

Info

Publication number: CN211529978U
Application number: CN202020407299.3U
Authority: CN
Inventors: 陈宗琦; 杨松旺; 金胜利; 陈薪羽; 黄绵吉; 华晓宇; 关键; 彭浩; 褚晓虹; 林王坚; 张力
Original assignee: Shanghai Institute of Ceramics of CAS; Zhejiang Energy Group Research Institute Co Ltd; Zhejiang Tiandi Environmental Protection Technology Co Ltd
Current assignee: Zhejiang Zheneng Technology Environmental Protection Group Co ltd; Shanghai Institute of Ceramics of CAS; Zhejiang Energy Group Research Institute Co Ltd
Priority date: 2020-03-26
Filing date: 2020-03-26
Publication date: 2020-09-18
Anticipated expiration: 2030-03-26

Abstract

The utility model discloses a large tracts of land perovskite solar cell of encapsulation, include: the solar cell module comprises a transparent substrate, a conductive layer formed on the transparent substrate, a non-conductive etching line formed on the conductive layer, a conductive grid line arranged on the conductive layer through printing and a perovskite solar cell module arranged on the conductive layer, wherein the cell module comprises two or more large units, and each large unit comprises two or more small units; the large cells are connected in parallel and the small cells are connected in series, or the large cells are connected in series and the small cells are connected in parallel, by etching the lines and the conductive gate lines. A plurality of large units on the same transparent substrate are connected in parallel, so that the series resistance of the battery is reduced, the working current is improved, and the voltage of the battery is improved as the large units are connected in series by a plurality of small units; or a plurality of big units are connected in series, the voltage of the battery is improved, and a plurality of small units are connected in parallel between the big units, so that the series resistance of the battery is reduced, and the working current is improved.

Description

Encapsulated large area perovskite solar cells

Technical Field

The utility model relates to a solar cell field, concretely relates to large tracts of land perovskite solar cell of encapsulation.

Background

In the last 10 years, perovskite solar cells have developed rapidly due to their outstanding advantages, and in particular, perovskite solar cells are simple to fabricate, are low in cost, and can be used to fabricate flexible, transparent cells. Meanwhile, the band gap width is more appropriate, and the color of the battery can be controlled by changing the band gap to prepare the color battery. Moreover, the charge diffusion length is up to micron order, and the charge lifetime is longer. In addition, the perovskite crystal material can present the properties of both an n-type semiconductor and a p-type semiconductor due to the unique defect characteristics, so that the application of the perovskite crystal material is more diversified. Therefore, perovskite solar cells and related materials become research directions in the photovoltaic field, photoelectric conversion efficiency of more than 25% is obtained at present, the use cost of the solar cells can be greatly reduced, and the application prospect is very wide.

The perovskite solar cell mainly comprises a transparent conducting layer, a hole blocking layer, an electron transport layer, a perovskite light absorption layer, a hole transport layer and a counter electrode. An insulating layer is sometimes added between the electron transport layer and the perovskite light absorbing layer to increase the open circuit voltage of the cell.

At present, the industrialization of perovskite solar cells is an important problem, and perovskite solar cell modules all use small cells which are made into large modules in a series-parallel connection mode and then packaged, so that additional process procedures are brought, for example: leading out the wires among the multiple batteries, mutually connecting, placing, filling the glue film in the gaps and the like. Furthermore, additional resistance, such as resistance at the leads or joints, may be introduced, and even desoldering may occur, resulting in reduced battery performance. Therefore, the fabrication of a series-parallel packaged large-area cell module having a plurality of unit cells on the entire substrate is an important approach for the industrialization of perovskite solar cells.

In contrast, patent document 1 discloses a perovskite solar cell module, and patent document 2 discloses a perovskite solar cell module and a method for manufacturing the same. Although the perovskite solar cell module formed by connecting single perovskite solar cells in series or in parallel is provided, the series structure in the series module can cause larger series resistance, the parallel structure can cause insufficient module voltage, a plurality of scattered modules are still needed in the later period, and the perovskite solar cell module is connected into an integral assembly through series and parallel connection and is not suitable for single module power generation.

Prior art documents:

patent document 1: chinese patent publication CN 108550705A;

patent document 2: chinese patent publication CN 106910827A.

SUMMERY OF THE UTILITY MODEL

Problem that utility model will solve:

in view of the above, the present invention provides a large-area perovskite solar cell, in which the inside of the cell module is connected in series or in parallel, and the ranges of the current and voltage of the cell can be controlled; and meanwhile, a reliable packaging assembly is formed, and the packaging problem of the assembly is solved.

Means for solving the problems:

in order to solve the technical problem, the utility model provides a large tracts of land perovskite solar cell of encapsulation, include:

the solar cell module comprises a transparent substrate, a conductive layer formed on the transparent substrate, a non-conductive etching line formed on the conductive layer, a conductive grid line arranged on the conductive layer through printing and a perovskite solar cell module arranged on the conductive layer, wherein the cell module comprises two or more large units, and the large units comprise two or more small units;

and enabling the large units to be connected in parallel and the small units to be connected in series or enabling the large units to be connected in series and the small units to be connected in parallel through the etching line and the conductive grid line.

According to the utility model, a plurality of large units on the same transparent substrate are connected in parallel to form a perovskite solar cell module, thereby reducing the series resistance of the cell and improving the working current of the cell, and the large units are connected in series by a plurality of small units to improve the voltage of the cell; or a plurality of large units on the same transparent substrate are connected in series to form the perovskite solar cell module, the voltage of the cell is improved, and a plurality of small units are connected in parallel among the large units, so that the series resistance of the cell is reduced, and the working current of the cell is improved. And the conductive grid wire 3 is directly manufactured on the transparent substrate by printing, and can not be removed by a chemical corrosion method, compared with the traditional bus bar or lead connection, the process is simple, the later stage is not easy to fall off, and the stability is good.

Furthermore, the small units comprise a hole blocking layer, an electron transmission layer, an insulating layer, a perovskite light absorption layer, a hole transmission layer and a counter electrode which are sequentially arranged from bottom to top, wherein the perovskite light absorption layer is introduced from the counter electrode through the counter electrode with a flow guide function and permeates into the perovskite solar cell, the perovskite light absorption layer is filled in the electron transmission layer and the insulating layer, and an independent continuous perovskite thin film layer is formed between the insulating layer and the hole transmission layer.

Further, the positive cell electrode and the negative cell electrode of the large cell are separated by the etched line.

Further, the positive unit electrodes and the negative unit electrodes of all the large units are connected with each other, the counter electrodes of the small units cross the etching line and contact the conducting layers corresponding to the heteropolar electrodes of the other small units, and therefore the perovskite solar cell module with the large units connected in parallel and the small units connected in series is formed; or the positive unit electrode of the large unit is connected with the negative unit electrode of the other large unit, and the counter electrode of the small unit crosses the etching line and contacts the conducting layer corresponding to the same pole of the other small unit, so that the perovskite solar cell assembly with the large units connected in series and the small units connected in parallel is formed.

Further, the conductive grid lines are connected with all the positive unit electrodes of the large units and converged to form a positive assembly electrode of the perovskite solar cell module, and the conductive grid lines are connected with all the negative unit electrodes of the large units and converged to form a negative assembly electrode of the perovskite solar cell module; or the conductive grid line crosses the etching line to connect the positive unit electrode of the large unit with the negative unit electrode of the other large unit and form a component electrode of the perovskite solar cell component.

Further, the battery pack further comprises a side face protection adhesive and a protection layer, wherein the side face protection adhesive is arranged around the battery pack and forms a packaging space for accommodating the battery pack, and the edge of the protection layer is hermetically connected with the top of the side face protection adhesive, so that the battery pack is sealed in the packaging space. Therefore, the impact resistance, the sealing property, the insulating property and the ultraviolet resistance of the packaged battery pack are improved.

Furthermore, the protective layer is provided with a hole for a lead to extend out, one end of the lead is connected with a component electrode of the perovskite solar cell module positioned below the protective layer, and the other end of the lead is connected with a junction box positioned above the protective layer. Therefore, the impact resistance, the sealing property, the insulating property and the ultraviolet resistance of the packaged battery pack are improved.

Further, the battery pack further comprises a front protection adhesive filled between the battery pack and the protection layer. Therefore, the impact resistance, the sealing property, the insulating property and the ultraviolet resistance of the packaged battery pack are improved.

Further, still include along the frame that sets up around the transparent basement, the top of frame to the protective layer is protruding to be stretched and is formed the bulge, the lower surface butt of going up the bulge in the upper surface edge of protective layer, the bottom of frame to the transparent basement is protruding to be stretched and is formed lower bulge, the upper surface butt of bulge down in the lower surface edge of transparent basement. The frame is fixed through upper and lower bulge transparent base, front protection glue, side protection glue and protective layer, and the protection glue of side still receives the damage of external physics friction and collision, and further improves the waterproof performance of side direction all around.

Furthermore, a limiting space is formed between the upper protruding portion and the lower protruding portion of the frame, and a protective gasket is arranged on the surface of the frame, which is located in the limiting space. The protection gasket set up the destruction of further separation aqueous vapor to internal battery on the one hand, and on the other hand avoids frame and transparent basement, side protection to glue, protective layer direct contact, plays buffering, absorbing effect.

According to the utility model discloses, glue, protect through positive protective glue and protective layer at the top through the side protection all around to further add in the periphery and establish the frame and consolidate, form the large tracts of land perovskite solar cell of a encapsulation. Meanwhile, the conductive grid lines are distributed on the conductive layer on the transparent substrate to collect electrons, so that the resistance is reduced, and the electron collection is improved. The positive and negative electrodes of the large unit are separated by the etching lines, so that the positive electrodes of all the units are interconnected, and the negative electrodes of all the units are interconnected to form a parallel assembly. Inside keeping apart into the subelement through the etching line of great cell, the width of the counter electrode layer of subelement is greater than the width of the part of subelement except counter electrode layer for when it covers this unit top, can also span the etching line, contact the conducting layer that another subelement heteropolar corresponds, form series connection, thereby form the great cell and connect in parallel, the large tracts of land whole subassembly that the subelement is established ties. Or the large units are separated by the etching lines, the small units are connected in parallel inside the large units, and the positive electrode and the negative electrode are connected with the negative electrode and the positive electrode of the other large unit of the etching lines, so that a large-area integral assembly with the large units connected in series and the small units connected in parallel is formed. The utility model discloses can make a plurality of big, little unit cell effectively on the whole base plate of large tracts of land, form cluster, parallelly connected structure, reduce resistance, improve battery voltage.

Drawings

Fig. 1 is a schematic plan view of a perovskite solar cell module according to an embodiment of the present invention when it is not packaged (3 small cells are connected in series and 2 large cells are connected in parallel);

FIG. 2 is a cross-sectional view taken at A-A of FIG. 1;

FIG. 3 is a schematic illustration of the conductive grid lines and electrode distribution of FIG. 1;

fig. 4 is a schematic plan view of a perovskite solar cell module according to an embodiment of the present invention when it is not packaged (3 small cells are connected in parallel and 2 large cells are connected in series);

fig. 5 is a schematic diagram showing the distribution of etching lines and conductive grid lines when the perovskite solar cell module according to an embodiment of the present invention is not packaged (19 small cells are connected in series and 2 large cells are connected in parallel);

fig. 6 is a plan view of a perovskite solar cell module according to an embodiment of the present invention when it is not encapsulated (4 small cells are connected in series and 11 large cells are connected in parallel);

fig. 7 is a schematic plan view of a perovskite solar cell module according to an embodiment of the present invention without being packaged (3 small cells are connected in parallel and 4 large cells are connected in series);

fig. 8 is a plan view of a perovskite solar cell module according to an embodiment of the present invention after packaging;

FIG. 9 is a cross-sectional view taken at A-A of FIG. 8;

fig. 10 is a schematic diagram of the positive and negative wiring of the battery of fig. 1 with the assembly electrodes continuously led out of the protective layer when the battery is packaged but not framed;

FIG. 11 is a cross-sectional view of the package of FIG. 10 after being encapsulated at A-A; (the electrode 3b is passed through the side protective adhesive 12 to the outside, and connected to the junction box 16 through the lead wire 14)

FIG. 12 is a schematic diagram of the positive and negative wiring lines with the module electrodes discontinuously led out to the outside of the protective layer when the battery in FIG. 1 is packaged but not framed;

FIG. 13 is a transverse cross-sectional view of FIG. 12;

reference numerals:

0 transparent substrate

1 conductive layer

2 etching line

3 conductive grid line

3a cell electrode

3b component electrode

4 hole blocking layer

5 electron transport layer

6 insulating layer

7 hole transport layer

8 pairs of electrodes

9 perovskite light-absorbing layer

a hole

10 cell assembly

11 front face protective adhesive

12 side face protective adhesive

13 protective layer

14 conducting wire

15 hole plugging glue

15b component electrode protection glue

16 terminal box

17 protective pad

18 rims

19 Small Unit

20 large units.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention. The dimensions in the figures are for ease of viewing only and are not to scale with actual dimensions.

As shown in fig. 1 and 2, the encapsulated perovskite solar cell includes: the perovskite solar cell comprises a transparent substrate 0, a transparent conductive substrate of a conductive layer 1 formed on the transparent substrate 0 and a perovskite solar cell component arranged on the conductive layer 1, wherein in order to convert light energy of the perovskite solar cell into electric energy, the transparent substrate 0 and the conductive layer 1 are made of transparent materials so that the perovskite solar cell component has a good light absorption effect, and the conductive layer 1 is made of conductive materials. The transparent substrate 0 is a whole substrate and can be glass or plastic; the conductive layer 1 may be a transparent conductive film (TCO), for example: FTO, AZO or ITO, and preferably FTO with the best heat resistance and chemical stability is adopted.

The conductive layer 1 on the whole transparent conductive substrate is etched by carrying out laser or chemical method on the transparent substrate 0 to form a non-conductive etching line 2, the conductive layer 1 of the whole substrate is divided into two parts by the etching line 2, and the subsequent anode and cathode are respectively led to two ends of the etching line. Dividing the battery assembly into two or more large cells 20 using etched lines 2, each large cell 20 further comprising two or more small cells 19 connected in parallel; or the battery module includes two or more large cells 20 connected in parallel, each large cell 20 being divided into two or more small cells 19 by etched lines. The small units 19 are in a quadrilateral strip shape, and are arranged on the transparent substrate 0 to form M rows of array arrangement in the width direction, the width of each small unit is 1-20 mm, and the distance between every two adjacent small units is 10 micrometers-0.8 mm. The utility model discloses can make a plurality of big, little unit cell effectively on the whole base plate of large tracts of land, form cluster, parallelly connected structure, reduce resistance, improve battery voltage.

The small unit 19 comprises a hole blocking layer 4, an electron transport layer 5, an insulating layer 6, a perovskite light absorption layer 9, a hole transport layer 7 and a counter electrode 8 which are arranged from bottom to top in sequence, wherein the hole blocking layer 4 is TiO₂The dense layer can be prepared by printing, coating and the like by using a slurry containing tetraisopropyl titanate, ethyl cellulose and terpineol. TiO 2₂The compact layer can prevent the recombination of holes and electrons in the battery at the current collecting electrode, so that the photoelectric conversion efficiency of the battery is improved. The process is beneficial to the amplification of the film forming process and is suitable for coating films on large-area substrates. The electron transmission layer 5 is formed by screen printing of nano titanium dioxide slurry; the insulating layer 6 is formed by screen printing nano zirconium dioxide or aluminum oxide slurry. The existence of the insulating layer 6 can separate the anode and the cathode of the unit, thereby avoiding the short circuit in the unit. The counter electrode 8 may be formed by screen printing a carbon paste, which is a mixture of a plurality of carbon materials; or plated transparent conductive film (TCO): FTO, AZO or ITO; or metal (metal paste printing, metal tape). The counter electrode 8 can be a carbon electrode formed by carbon slurry, and compared with a traditional metal counter electrode, the counter electrode is low in cost, good in stability and simple in process. If the counter electrode formed by the transparent conductive film is selected, compared with the traditional metal electrode, the transmittance is higher, and the utilization rate of light is improved; on the structure with a longer electron transmission path, metal adhesive tape or metal paste is selected for printing, and compared with the traditional metal evaporation electrode, the metal evaporation electrode is simple to manufacture and low in equipment requirement. The hole transport layer 7 is formed by screen printing of nickel oxide slurry mixed by nano nickel oxide NiOx and micron or submicron flaky nickel oxide NiOx, and has better stability compared with the traditional organic hole transport layer. For carbon antipodal perovskite cells, the hole transport layer 7 is often omitted. Preferably, the perovskite light absorption layer 9 is introduced from the counter electrode layer to penetrate into the conductive layer through the carbon counter electrode with flow guiding function, and is filledThe electron transport layer 5 and the insulating layer 6 are filled, and a continuous independent perovskite thin film is formed between the insulating layer 6 and the hole transport layer 7. In other words, the electron transport layer 5, the insulating layer 6, the hole transport layer 7, and the counter electrode 8 are first formed, and finally the perovskite light absorption layer penetrates from above the counter electrode 8, so that the electron transport layer 5 and the insulating layer 6 are filled and a continuous perovskite thin film layer is formed at the same time, since the gap between the two interfaces of the insulating layer and the hole transport layer is large, the perovskite light absorption layer can be formed at the gap, it should be noted that the interfaces of these layers are not completely independent as in fig. 2, and fig. 2 only illustrates the positions of the layers. The structure has the advantages that the hole extraction rate of the perovskite material is improved, and electron hole recombination caused by residue of a perovskite precursor solution in a hole transport layer and/or a counter electrode is avoided.

As shown in fig. 1 and 3, when the large cells 20 are connected in parallel, the small cells 19 are connected in series: cell electrodes 3a are formed on two sides of each large cell 20, positive cell electrodes and negative cell electrodes of the large cells 20 are isolated by etching lines 2, positive cell electrodes and negative cell electrodes of all the large cells 20 are connected with each other, counter electrodes 8 of the small cells 19 cross the etching lines 2 and contact conductive layers corresponding to opposite poles of the other small cells, and thus perovskite solar cell modules in which the large cells 20 are connected in parallel and the small cells 19 are connected in series are formed. As shown in fig. 4, when the small cells 19 are connected in parallel, the large cells 20 are connected in series: each large cell 20 is formed at both sides thereof with its cell electrode 3a, the positive cell electrode of one large cell 20 is connected with the negative cell electrode of the other large cell 20, and the counter electrode 8 of the small cell 19 crosses the etch line 2 and contacts the conductive layer corresponding to the same pole of the other small cell 19, thereby constituting a perovskite solar cell module in which the large cells 20 are connected in series and the small cells 19 are connected in parallel.

Specifically, a conductive grid line 3 for connecting electrodes is distributed on a conductive layer of the transparent substrate. As shown in fig. 3, when the large cells are connected in parallel and the small cells are connected in series, the conductive grid lines 3 connect the positive cell electrodes of all the large cells 20 and converge to form the positive assembly electrode 3b of the perovskite solar cell module, and the conductive grid lines 3 connect the negative cell electrodes of all the large cells and converge to form the negative assembly electrode 3b of the perovskite solar cell module. As shown in fig. 4, when the large cells are connected in series and the small cells are connected in parallel, the conductive grid line 3 crosses the etching line 2 to connect the positive cell electrode of one large cell 20 with the negative cell electrode of another large cell 20, the head and tail parts of the conductive grid line 3 form the component electrode 3b of the perovskite solar cell component, and the upper electrode in fig. 4 is the cell electrode 3a and also the component electrode 3 b. The resistance of the conductive grid line 3 is far smaller than that of the conductive layer 1, and the conductive grid line 3 can collect electrons on the conductive layer 1, so that the internal resistance of the battery can be effectively reduced by introducing the conductive grid line 3, and the battery efficiency is improved. The conductive grid lines 3 are directly manufactured on the substrate through printing, if a chemical corrosion method is not used, the conductive grid lines cannot be removed from the substrate, and compared with the traditional bus bar or lead connection, the conductive grid lines are simple in process, not prone to falling off in the later period and good in stability. The conductive grid line 3 is made of metal and comprises at least one of gold, silver, copper, tin and aluminum; the width of the conductive grid line is 0.01 mm-2 mm, the thickness is 1 mu m-20 mu m, and the conductive grid line and the perovskite solar cell small unit are at least 10 mu m apart.

As shown in FIGS. 1 and 5, the cells 19 of FIG. 1 are defined as being connected in series in the transverse direction, and the cells of FIG. 5 are defined as being connected in series in the longitudinal direction. In fig. 1, since the counter electrode layer of the small unit crosses the etching line, the width of the electron transmission path is small unit 19, and the resistance relative to the length direction (as shown in fig. 5) is negligible, so that the method is suitable for the material (carbon or transparent conductive film) of the counter electrode 8 with ordinary conductivity, but each small unit needs to be separated by the etching line 2, and the etching line is a non-effective power generation region, which affects the effective area of the battery assembly 10. In fig. 5, the electron transmission path is the length of the small unit 19, which is much larger than the width thereof, and therefore is suitable for the counter electrode 8 material (metal electrode) with excellent conductivity, although the conductive grid lines 3 are arranged in the transverse gaps of the small unit 19 in the current drawing, on the premise that the conductive layer 1 has excellent conductivity, the conductive grid lines 3 do not need to be additionally arranged, the gaps are infinitely reduced, and the effective area of the battery assembly 10 is increased. As shown in fig. 6 and 7, a possibility is provided for connecting the small cells 19 in parallel and the large cells 20 in series. Such a connection mode with more and fewer strings can reduce the internal resistance of the battery pack 10, and is suitable for occasions with low voltage requirements.

The encapsulation portion of the perovskite solar cell is explained below. As shown in fig. 8 and 9, a side protective adhesive 12 is disposed around the battery assembly, a protective layer 13 is covered on the top of the side protective adhesive 12, the edge of the lower surface of the protective layer 13 is hermetically connected with the upper surface of the side protective adhesive 12, and the protective layer 13 is located above the battery assembly, so that the battery assembly is sealed in a package space surrounded by the transparent substrate 0, the side protective adhesive 12, and the protective layer 13. The packaging space is also filled with a front protective adhesive 11 between the battery pack and the protective layer. The front surface protective film 11 may be a cross-linked film or a thermoplastic film, and may be made of high density linear polyethylene (HDPE), polyethylene octene co-elastomer (POE), ethylene-vinyl acetate copolymer (EVA), polyvinyl butyral (PVB), and/or silicone resin. The front protection glue 11 plays a role in shock resistance and impact resistance of the front of the battery, and can also bond the battery and the protection layer to play a role in fixing. The side protective adhesive 12 may be acrylic adhesive, epoxy adhesive, or butyl tape, which provides excellent chemical stability and moisture barrier property, and improves the side waterproof property of the battery pack. The protective layer 13 may be tempered glass, ceramic plate, polymer composite material or corrosion-resistant metal plate. The metal plate can be stainless steel, anodic aluminum oxide and titanium alloy. The protective layer 13 serves as a waterproof, and physical protection, function of the back side of the perovskite solar cell. The cell converts light energy into electric energy, the light reflecting performance of the metal plate and the ceramic plate can improve the utilization rate of light, and the tempered glass is transparent and can utilize incident light on the back surface, so that the utilization rate of light is also improved. The polymer composite may be PVDF, TPT, TPE, BBF or APE. Through the arrangement of the side protective adhesive 12, the front protective adhesive 11 and the protective layer 13, the packaged battery assembly has the following advantages: (1) the single-stroke impact resistant material can provide enough mechanical strength, can withstand the stress generated by impact, vibration and the like in the processes of transportation, installation and use, and can withstand the single-stroke force of hail; (2) the sealing structure has good sealing property, and can prevent wind and water and isolate corrosion to the battery piece under atmospheric conditions; (3) has good electrical insulation performance; (4) according to the type of the protective layer, the ultraviolet resistance is improved; (5) the service life is prolonged.

In the present embodiment, as shown in fig. 8 and 9, the module electrodes of the perovskite solar cell module 10 are located in the package space (i.e., on the side of the side surface protection paste 12 close to the cell module 10) and on the side of the cell module 10. At this time, the widths of the protective layer 13 and the side encapsulation paste 12 are adapted to the width of the transparent substrate 0. The component electrode is connected with a lead 14, a hole a for the lead 14 to extend out is arranged on the protective layer 13, and the lead 14 passes through the hole a and is connected with a junction box 16 positioned above the protective layer 13. After the wires 14 are connected, the hole is sealed by using hole plugging rubber 15, and the hole plugging rubber 15 can be butyl rubber, epoxy resin, acrylic resin or silica gel, so that excellent chemical stability and moisture barrier property are provided, and the waterproof performance of the battery assembly is improved. The conductive wires 14 may be made of copper or tin-plated copper for both conductivity and cost. This structure has good conductivity because the module electrodes are continuous, and has good waterproof and durability because the side protective paste 12 and the protective layer 13 are completely sealed without gaps.

The utility model discloses still include the frame 18 that sets up around transparent basement along, the top of frame 18 is protruding to stretching of protective layer 13 and is formed the bulge, goes up the lower surface butt of bulge in protective layer 13's upper surface edge, and the bottom of frame is to the protruding bulge of stretching formation down of transparent basement 0, and the upper surface butt of lower bulge is at the lower surface edge of transparent basement 0. The frame 18 can be an aluminum alloy frame, and can fix the transparent substrate, the front protective adhesive, the side protective adhesive and the protective layer; the side face protective glue is protected from being damaged by external physical friction and collision; the waterproof performance in the peripheral side direction can be further improved; and the weight of the overall perovskite solar cell module is reduced. A limiting space is formed between the upper protruding part and the lower protruding part of the frame 18, and a protective gasket 17 is arranged on the surface of the frame 18 in the limiting space. The protective gasket 17 can be made of fluorine-containing rubber, silicon rubber or butyl rubber, and can provide excellent chemical stability, thermal stability and wear resistance and simultaneously further prevent the damage of moisture to the internal battery; the frame 18 can also be prevented from directly contacting the transparent substrate 0, the side protective adhesive 12 and the protective layer 13, and the buffering and shock-absorbing effects can be achieved.

In another embodiment, as shown in fig. 10 to 13, the component electrode of the perovskite solar cell component 10 is located outside the packaging space (i.e. on the side of the side surface protection glue 12 away from the cell component 10), and at this time, the width of the protection layer 13 and the side surface packaging glue 12 is smaller than the width of the transparent substrate 0, so that a channel is formed between the protection layer 13 and the frame 18 corresponding to the component electrode. The component electrodes are connected to leads 14, which leads 14 pass through the passages and are connected to a terminal block 16 located above the protective layer 13. The terminal box 16 abuts against the upper projection of the frame 18, and after the wires 14 are connected, the passage is sealed with the module electrode protection paste and the wires 14 are partially embedded therein, and the remaining portion of the wires 14 is surrounded by the protection pad 17. Compared with the structure that the component electrodes are positioned in the packaging space as shown in fig. 8 and 9, the structure has the advantages that the process and the materials are fewer, the process is more convenient, and the trouble of forming holes on the protective layer 13 and filling hole glue is avoided. For the structure in which the module electrodes are continuously led out of the protective layer as shown in fig. 10 and 11, although gaps may be generated at the side protective paste 12 due to the electrode penetrating through the side protective paste 12, compared with the structure of fig. 8 and 9, the structure is more suitable for the perovskite solar cell having a low sensitivity to water, but the module electrodes of the structure are continuous, so that the advantages of rapid process and good conductivity can be considered. For the structure in which the module electrodes are discontinuously led out to the outside of the protective layer as shown in fig. 12 and 13, although the conductivity is only achieved by the conductive layer on the transparent substrate 0, the side protective adhesive 12 and the protective layer 13 of the structure do not have gaps although the conductivity is sacrificed a little, so that the advantages of fast process, good water resistance and good durability are both considered, and the structure is suitable for the perovskite solar cell which is extremely sensitive to water.

The perovskite solar cell module of the utility model is divided into a plurality of large-cell series and parallel connections on a large-area (for example, 600mm x 600 mm) whole substrate, and the large cell is divided into a plurality of small cells and connected in series, thereby reducing the series resistance of the cell module and improving the voltage of the cell module; and the number of the large units 20 and the small units 19 connected in series and in parallel can be adjusted according to the requirement to meet the specific current and voltage output. The battery assembly 10 is sealed and isolated from the external environment by the front protection glue 11, the side protection glue 12, the protection layer 13 and the hole blocking glue 15, the frame 18 of the protection gasket 17 is further sealed and reinforced, and the positive pole and the negative pole are led out to the junction box 16 from the hole a by the lead 14. Provides a new idea for manufacturing a large-area solar cell packaging assembly.

The present invention will be described in further detail below with reference to examples.

Example 1:

the battery with 19 small units connected in series and 2 large units connected in parallel as shown in fig. 5 is manufactured by the following specific steps.

(1) And (3) using laser to punch holes on the transparent conductive substrate and etching off the conductive FTO layer to ensure infinite resistance between units.

(2) And ultrasonically cleaning the FTO glass for ten minutes by using acetone, an alkaline detergent, deionized water and acetone respectively, and finally drying.

(3) Preparation of TiO on FTO glass substrate₂The dense layer, solvent are terpineol, including following composition: 1.5ml tetraisopropyl titanate, 3.5g ethyl cellulose, 80ml terpineol, were coated on a clean FTO substrate and sintered in a muffle furnace at 510 ℃ for 30 min.

(4) And (3) screen-printing titanium dioxide slurry as an electron transport layer on the compact layer, wherein the solid content is 10%, and the solvent terpineol is sintered for 30min at 510 ℃ in a muffle furnace.

(5) And (3) screen-printing zirconium dioxide slurry as an insulating layer on the electron transmission layer, wherein the solid content is 5%, and the solvent terpineol is sintered for 30min at 510 ℃ in a muffle furnace.

(6) And (3) screen-printing a mixed nickel oxide slurry of nano nickel oxide and micron or submicron flaky nickel oxide as a hole transport layer on the insulating layer, wherein the solid content is 5 percent, and the solvent terpineol is sintered for 30min at 510 ℃ in a muffle furnace.

(7) And (3) screen-printing a conductive silver grid on an FTO glass substrate, wherein the solid content is 70 percent, and the solvent terpineol is sintered for 30min at 510 ℃ in a muffle furnace.

(8) And (3) screen-printing carbon slurry serving as a counter electrode on the hole transport layer, wherein the solid content is 37%, terpineol serving as a solvent is sintered for 30min at 430 ℃ in a muffle furnace, and the carbon slurry contains fibrous carbon, so that a flow guide function is provided for perovskite permeation.

(9) 15.3 mg of 5-Aminopentanoic acid hydroiodide (5-AVAI) and 576 mg of lead iodide (PbI) were weighed out₂) 195 mg CH₃NH₃I powder, 1ml of gamma-butyrolactone (GBL) is measured and stirred for 6 hours at 60 ℃ to form CH₃NH₃PbI₃A perovskite precursor solution. And introducing the perovskite precursor solution from the carbon layer with the flow guiding function by adopting a cascade liquid-transferring gun to prepare the perovskite thin film, annealing for 60 minutes at 50 ℃, penetrating and filling the perovskite precursor solution into the mesoporous electron transport layer and the mesoporous insulating layer through the carbon layer with the flow guiding function, and forming an independent continuous perovskite thin film between the insulating layer and the carbon layer.

(10) And the other side of the battery is led out of the opening to be connected with a junction box. Filling the holes with acrylic resin, and curing by ultraviolet irradiation.

(11) And adhering a butyl adhesive tape around the transparent conductive substrate, and sequentially covering the counter electrode with a POE adhesive film and toughened glass.

(12) Putting the battery with the protective layer into a laminating machine, setting the temperature to be 95 ℃, firstly vacuumizing, increasing the pressure by slowly restoring the atmosphere, and dividing the battery into three sections of 30Kpa, 30Kpa and 40Kpa, wherein the total time consumption is 15 min. If the pressure is too high, the layers in the battery can be pressed against each other to damage the internal structure, and hole-electron recombination can be caused.

(13) The copper wire is connected to the junction box and fixed to the back of the battery with silicone.

(14) And (3) padding silica gel pads on the peripheral edges and the side faces of the front and back faces of the battery, fixing the silica gel pads by using an aluminum alloy frame, and finally manufacturing the large-area perovskite solar battery serial and parallel connection battery packaging assembly.

Specifically, the series-parallel structure in fig. 5 may be formed, for example, as follows:

the small units are mutually separated through the etching line, the long sides of the small units are tightly attached to the etching line, the parts (the hole blocking layer, the electron transport layer, the insulating layer and the hole transport layer) of the small units except the counter electrode (the positive electrode) cover the conducting layer (the negative electrode) on the transparent conducting substrate on one side (the left side) of the etching line, and the counter electrode stretches across the etching line to the other side (the right side) and covers the conducting layer (the negative electrode) on the transparent conducting substrate on the right side of the etching line. The positive and negative electrodes in the cell are separated by an insulating layer. The anode of the unit on the left side of the etching line is contacted with the cathode of the unit on the right side of the etching line to form series connection. The positive electrodes of the two large units are connected with each other, the negative electrodes of the two large units are connected with each other, the two large units are led out to the hole through the conductive grid lines respectively to form the positive electrode and the negative electrode of the assembly, and the positive electrode and the negative electrode are separated through the etching lines.

The utility model discloses a screen printing, the technology of sintering conductive paste, according to the pattern that has designed, directly will conduct gate line preparation on the base plate, if the method that need not chemically corrode, can't get rid of it from the base plate, compare in traditional area of converging, simple process, the later stage is difficult for droing, and stability is good.

Example 2:

the preparation and packaging process of the battery are the same as those of example 1, and are not repeated herein.

Specifically, a structure in which 4 small units are connected in series and 11 large units are connected in parallel as in fig. 6 may be prepared, for example, as follows:

the short side of the small unit is tightly attached to the etching line, the parts (the hole blocking layer, the electron transport layer, the insulating layer and the hole transport layer) of the small unit except the counter electrode (the positive electrode) are covered on the conducting layer (the negative electrode) on the transparent conducting substrate on one side (the upper side) of the etching line, and the counter electrode vertically spans the etching line to the other side (the lower side) and covers on the conducting grid line (the negative electrode) on the lower side of the etching line. The positive and negative electrodes in the cell are separated by an insulating layer. The positive electrode of the unit at the upper side of the etching line is contacted with the negative electrode of the unit at the lower side of the etching line to form a series connection of 4 nodes from top to bottom. The anodes of the transverse 11 strings of large units are connected with each other, the cathodes of the transverse 11 strings of large units are connected with each other, and the anodes and the cathodes of the transverse 11 strings of large units are led out to the holes respectively through the conductive grid lines to form the anode and the cathode of the assembly and are separated by etching lines.

Example 3:

Specifically, a structure in which 3 small units are connected in parallel and 2 large units are connected in series as in fig. 4 may be prepared, for example, as follows:

the middle longitudinal etching line divides the conductive layer on the transparent conductive substrate into a left large unit and a right large unit which are 2 large units. In the large unit on the left side, the conductive grid lines are distributed in the small unit gaps, and electrons (negative electrodes) on the conductive layer are collected to the left opening on the upper end to form a negative electrode of the assembly; the short side of the lower side of each small unit is tightly attached to an etching line, the parts (a hole blocking layer, an electron transport layer, an insulating layer and a hole transport layer) of each small unit except a counter electrode (a positive electrode) are covered on a conducting layer (a negative electrode) on a transparent conducting substrate on one side (the upper side) of a transverse etching line, and the counter electrode vertically spans the transverse etching line to the other side (the lower side) and covers a conducting grid line (a positive electrode) on the lower side of the etching line. The conductive grid line crosses the longitudinal etching line to the large unit on the right side and is distributed in the small unit gap on the right side to collect electrons (negative electrodes) on the conductive layer. The positive pole of the left big unit is connected to the negative pole of the right big unit to form 2 big units which are connected in series. The short side of the upper side of the 3 small units on the right side is tightly attached to an etching line, and with the large unit on the left side, the counter electrode vertically crosses a transverse etching line to the other side (upper side) to cover a conductive grid line (anode) on the upper side of the etching line and converge to a hole on the right side to form an assembly anode. That is, the upper electrode is both the cell electrode and the element electrode.

According to embodiments 1-3, the utility model discloses a series connection on the single substrate, parallelly connected structure's encapsulation battery possesses following beneficial effect: (1) the current and the voltage of the battery are controllable; (2) the subsequent series and parallel connection process of different battery pieces by using a connecting piece is omitted; (3) forming a packaged battery with reliable stability; (4) if there is the shadow case of sheltering from, owing to be single substrate structure, even shelter from the part, only lose effective area, the generated energy reduces, has overcome the following problem of appearing easily in the aspect of traditional technology stability: (1) because the attenuation degrees of different battery pieces are different, the performance of the battery assembly after series connection and parallel connection is influenced by the single battery piece with the worst performance; (2) the deterioration of the connecting piece leads to the increase of the series resistance, and the building performance of the whole battery is influenced; (3) if the shadow is blocked, the hot spot effect is easy to occur.

The present invention may be embodied in several forms without departing from the spirit of the essential characteristics thereof, and the embodiments are therefore to be considered in all respects as illustrative and not restrictive, since the scope of the invention is defined by the appended claims rather than by the description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims

1. An encapsulated large area perovskite solar cell, comprising: the solar cell module comprises a transparent substrate, a conductive layer formed on the transparent substrate, a non-conductive etching line formed on the conductive layer, a conductive grid line arranged on the conductive layer through printing and a perovskite solar cell module arranged on the conductive layer, wherein the cell module comprises two or more large units, and the large units comprise two or more small units;

2. The encapsulated large area perovskite solar cell as claimed in claim 1, wherein the small unit comprises a hole blocking layer, an electron transport layer, an insulating layer, a perovskite light absorption layer, a hole transport layer and a counter electrode arranged from bottom to top, the perovskite light absorption layer is introduced from the counter electrode to penetrate into the perovskite solar cell through the counter electrode with a flow guiding function, fills the electron transport layer and the insulating layer, and forms a separate continuous perovskite thin film layer between the insulating layer and the hole transport layer.

3. The encapsulated large area perovskite solar cell of claim 1 wherein the positive and negative cell electrodes of the large cell are separated by the etched lines.

4. The encapsulated large area perovskite solar cell of claim 3,

all the positive unit electrodes of the large units are connected with each other, the negative unit electrodes of the large units are connected with each other, and the counter electrodes of the small units cross the etching line and contact the conducting layers corresponding to the heteropolarity of the other small units, so that the perovskite solar cell assembly with the large units connected in parallel and the small units connected in series is formed;

or the positive unit electrode of the large unit is connected with the negative unit electrode of the other large unit, and the counter electrode of the small unit crosses the etching line and contacts the conducting layer corresponding to the same pole of the other small unit, so that the perovskite solar cell assembly with the large units connected in series and the small units connected in parallel is formed.

5. The encapsulated large area perovskite solar cell of claim 4 wherein the electrically conductive grid lines connect all of the large cell positive cell electrodes and converge to form a positive assembly electrode of the perovskite solar cell assembly, and the electrically conductive grid lines connect all of the large cell negative cell electrodes and converge to form a negative assembly electrode of the perovskite solar cell assembly;

or the conductive grid line crosses the etching line to connect the positive unit electrode of the large unit with the negative unit electrode of the other large unit and form a component electrode of the perovskite solar cell component.

6. The encapsulated large area perovskite solar cell of claim 1 further comprising a side protective gel disposed around the cell assembly and forming an encapsulation space to accommodate the cell assembly, wherein the edge of the protective layer is sealingly attached to the top of the side protective gel to seal the cell assembly within the encapsulation space.

7. The encapsulated large area perovskite solar cell of claim 6 wherein the protective layer is provided with through holes for lead wires to extend through, one end of the lead wires being connected to the module electrodes of the perovskite solar cell module below the protective layer and the other end being connected to a junction box above the protective layer.

8. The encapsulated large area perovskite solar cell of claim 6 further comprising a front side protective gel filled between the cell assembly and the protective layer.

9. The encapsulated large area perovskite solar cell of claim 6 further comprising a frame disposed around the transparent substrate, wherein the top of the frame protrudes toward the protective layer to form an upper protrusion, the lower surface of the upper protrusion abuts against the edge of the upper surface of the protective layer, the bottom of the frame protrudes toward the transparent substrate to form a lower protrusion, and the upper surface of the lower protrusion abuts against the edge of the lower surface of the transparent substrate.

10. The encapsulated large area perovskite solar cell of claim 9 wherein the upper and lower protrusions of the border define a spacing space therebetween, and wherein a surface of the border within the spacing space is provided with a protective gasket.