SOLAR CELL DEGRADATION CONTROL-COATING LIQUID AND THIN FILM AND SOLAR CELL DEGRADATION CONTROL METHOD

Information

  • Patent Application
  • 20160111559
  • Publication Number
    20160111559
  • Date Filed
    May 23, 2014
    10 years ago
  • Date Published
    April 21, 2016
    8 years ago
Abstract
Provided is a solar cell degradation control-cover glass having a thin film that is formed by applying to a cover glass back surface a coating liquid comprising either an aqueous solution of a water-soluble compound of at least one metal selected from silicon, aluminum, zirconium, tin and zinc or a fine particle dispersion liquid of an oxide of such metal.
Description
TECHNICAL FIELD

The present invention relates to the protection of a solar cell. Particularly, the invention relates to a method for preventing a performance degradation called PID especially, through an easy and inexpensive treatment of coating the cover glasses of various solar cells; a coating liquid used in such method; and a thin film formed from such coating liquid.


BACKGROUND ART

Solar cells have been used more frequently as recyclable energies have been utilized more frequently. However, it has become clear in recent days that a significant degradation in power generation capacity occurs due to a phenomenon called PID (Potential Induced Degradation), especially in the case of a solar cell operated in a condition of a severe temperature/humidity. Although the cause for that remains unclear, there has been proposed a structure where the Na ions inside the cover glass diffuse internally such that a charge transfer of the cell (battery cell) is to be hindered (Non-patent document 1).


Since the cause for that is still not clear, there exists no specific measure to be taken. In fact, although various attempts have begun to be made to, for example, change a cell encapsulation agent and coat the cell itself for the purpose of protection, any of such substitutions is not easy due to the fact that the main materials of a solar cell are almost fixed. That is, in view of a cost increase due to additional production steps, there is currently almost no effective solution to PID. Moreover, in the case of a solar cell that has already been installed, it is impossible to modify the inner parts thereof, thus resulting in almost no solution.


PRIOR ART DOCUMENT
Non-Patent Document

Non-patent document 1: Professional journal of solar cell “PVeye” by Vis On Press Co., Ltd. December issue of 2012


SUMMARY OF THE INVENTION
Problem to be Solved by the Invention

The present invention was made to solve the aforementioned problem. And, it is an object of the present invention to prevent a degradation in a power generation capacity of solar cell without modifying the parts of the solar cell themselves.


Means to Solve the Problem

After giving a serious consideration to the matter, the inventors of the present invention found that the insulation property on the cover glass surface can be improved; a leakage current can be controlled; and a decrease in a power generation efficiency due to PID can be prevented, by forming on either the front or back surface of the solar cell cover glass a thin film of a metal oxide that is easily curable at a temperature of about normal temperature to 120° C.


Further, it was also made clear that the effect of controlling the performance degradation of a cell could be still be partially achieved even after coating the surface of the solar cell itself. This finding was significant in terms of protecting existing solar cells, because the finding indicates that even an installed solar cell can be processed.


That is, the present invention is to provide the following inventions.


In the beginning, the invention provides a solar cell degradation control-coating liquid including: an aqueous solution of a compound of at least one metal selected from silicon, aluminum, zirconium, tin and zinc; or a fine particle dispersion liquid of an oxide of the abovementioned metal, in which the aqueous solution and the fine particle dispersion liquid each contain the abovementioned compound or oxide in an amount of 0.01 to 10% by mass in terms of metal oxide, and the fine particle dispersion liquid contains fine particles that have an average primary particle diameter of not larger than 50 nm and are dispersed at a dispersion particle diameter (D50) of smaller than 100 nm.


Secondly, the invention provides a solar cell degradation control-thin film that is formed from the aforementioned coating liquid, includes an oxide of at least one metal selected from silicon, aluminum, zirconium, tin and zinc, and has a thickness of 10 to 700 nm.


Thirdly, the invention provides a solar cell degradation control method including: applying the abovementioned coating liquid to a front or back surface of a cover glass of a solar cell; and drying and curing a coating film thus formed at a temperature of from a normal temperature to 200° C.


Fourthly, the invention provides a degradation-controlled solar cell having a thin film of the thickness of 10 to 700 nm, which is formed on a front or back surface of a cover glass of the solar cell by applying the aforementioned coating liquid thereto.


Effects of the Invention

According to the present invention, performance degradations in various solar cell panels due to PID can be prevented through an easy and inexpensive method of forming a metal inorganic oxide thin film on a cover glass of a solar cell.







MODE FOR CARRYING OUT THE INVENTION
Solar Cell

There are no particular restrictions on the kinds of the solar cells to which the method of the invention can be applied, as long as the solar cells are those equipped with cover glasses provided on the surfaces thereof. However, it is especially preferred that such solar cells be those obtained by stacking a cover glass, a sealing sheet, a cell and a back sheet in the order of cover glass/sealing sheet/cell/sealing sheet/back sheet.


Formation of Metal Inorganic Oxide Thin Film

As a metal oxide coating liquid that can be used to form a thin film, a coating liquid meeting the following requirements can be preferably employed.


That is, there may be preferably employed an aqueous solution of a water-soluble metal compound or a dispersion liquid of metal oxide fine particles, either of which is capable of forming a metal inorganic oxide thin film after being applied.


The metal species in such case are selected from silicon, aluminum, zirconium, tin, zinc and the like.


Examples of the aqueous solution of a metal compound include aqueous solutions of the water-soluble compounds of the aforementioned metal species. Specific examples thereof include a water-soluble silicate liquid (aqueous solution of water-soluble silicate) as an SiO2 precursor; an aluminum chloride aqueous solution as an Al2O3 precursor; a (NH4)2ZrO(CO3)2 aqueous solution as a ZrO2 precursor; and a zinc acetate hydrate as a ZnO precursor.


As the abovementioned metal oxide fine particle dispersion liquid, there can be used a type of dispersion liquid obtained by dispersing in a solvent, preferably water, the oxide fine particles of the aforementioned metal species whose average primary particle diameter is not larger than 50 nm, preferably not larger than 30 nm, whereas a dispersion particle diameter thereof is smaller than D50=100 nm, preferably smaller than 70 nm, more preferably not larger than 50 nm.


Here, “D50” as the dispersion particle diameter refers to a diameter of 50% cumulative distribution on a volume basis that is measured through dynamic light scattering with the aid of a laser beam, using, for example, Nanotrac UPA-UZ152 manufactured by NIKKISO Co., Ltd. Particles exhibiting a D50 of larger than 100 nm leads to numerous voids in the thin film formed. That is, the density of the thin film is low in such case so that the abovementioned force for inhibiting the diffusion of Na ions is weak, thus making it impossible to achieve the effect of controlling a degradation in a power generation capacity.


The average primary particle diameter refers to an average value obtained by first measuring the particle size through a transmission electron microscope (e.g. H-9500 by Hitachi High-Technologies Corporation) at a magnification of about 150,000 where each particle can be singularly recognized; and then performing the same procedure in 20 other arbitrary fields of view.


Specifically, there may be used, for example, a colloidal silica as SiO2 fine particles exhibiting a dispersion particle diameter of 1 to 50 nm; an alumina fine particle-dispersion liquid, a zirconium oxide fine particle-dispersion liquid, a tin oxide fine particle-dispersion liquid and a zinc oxide fine particle-dispersion liquid, each dispersion liquid exhibiting a particle property where particles of the average primary particle diameter of not larger than 50 nm are dispersed at a dispersion particle diameter of smaller than 100 nm.


Form of Coating Liquid

As the abovementioned coating liquid, there is preferably used a type of liquid that contains the aforementioned metal compound or metal oxide fine particles, and contains such metal compound or metal oxide in an amount of 0.01 to 10% by mass, preferably 0.1 to 5% by mass, in terms of metal oxide. An extremely low concentration will cause the thin film to be formed extremely thin, whereas an extremely high concentration will cause the film to thicken such that the film will crack and that an insulation effect cannot be achieved thereby.


Formation of Thin Film

Any conventional method can be used to apply the coating liquid to a solar cell cover glass. Specifically, a coating film can be formed on a cover glass through a dip coating method, a spin coating method, a spray coating method, a flow coating method, brush coating method, an impregnation method, a roll method, a wire bar method, a die coating method, a screen printing method, gravure printing method, an ink-jet method and the like. While the abovementioned coating liquid can be applied to the front and/or back surface(s) of a solar cell cover glass, it is more effective that the coating liquid be applied to the back surface of the cover glass. Further, the coating liquid may also be directly applied to the surface of the solar cell.


When forming a thin film by drying and curing the coated film on the cover glass, it is preferred that such treatment be performed at a temperature of from a normal temperature to 200° C. for 1 to 120 min, more preferably at a temperature of normal temperature to 120° C. for 5 to 60 min. An excessively low temperature for drying and curing or an excessively short period for drying and curing may lead to curing failures. Meanwhile, an excessively high temperature for drying and curing or an excessively long period for drying and curing may cause Na ions to ooze out such that the insulation function of the thin film may be impaired.


It is preferred that the thin film to be formed have a thickness of 10 to 700 nm, more preferably 20 to 500 nm, particularly preferably 50 to 300 nm. When the thin film is excessively thin, the insulation effect may not be exhibited. Meanwhile, when the thin film is excessively thick, breakages may occur such that the insulation effect may not be exhibited as well.


As for the thin film of the present invention, it is preferred that the cover glass exhibit a reduction (Δ) of not more than 5% in total light transmittance; and an increase of not more than 2% in haze rate, before and after the thin film is formed.


A transparency will decrease in the case where the total light transmittance drops by more than 10% (Δ) after the thin film is formed. That is, the amount of lights reaching the solar cell will decrease in such case so that a power generation efficiency may be impaired. If the haze rate increases by more than 2% after the thin film is formed, the film will become turbid such that the amount of lights reaching the solar cell will decrease due to light scattering and that the power generation efficiency may be impaired accordingly.


WORKING EXAMPLE

The present invention is described in detail hereunder with reference to working and comparative examples. However, the present invention is not limited to the following working examples.


Working Examples 1 to 37, Comparative Examples 1 to 2

In each example, used as the coating liquid was an aqueous solution or aqueous dispersion liquid with a total solid content concentration of the following coating material for forming thin film being adjusted to 1% by mass (in terms of metal oxide). A dip coating method was used to apply each coating liquid to the front or back surface of the cover glass of the following solar cell test module, followed by drying and curing the same at 80° C. for 15 min such that thin films having the thicknesses shown in Tables 1 and 2 were able to be formed on the cover glass.


Structure of Solar Cell Test Module

As a test module, there was used a module obtained by stacking, through heat lamination, a cover glass, an EVA (ethylene-vinyl acetate copolymer) encapsulation sheet, a cell, the EVA encapsulation sheet and a back sheet in the order of cover glass/EVA encapsulation sheet/cell/EVA encapsulation sheet/back sheet, the cell being configured as four 6-inch multicrystalline silicon cells in series.


Coating Material for Forming Thin Film
SiO2 Precursor, Amorphous Silicate
Working Examples 1 to 6, Comparative Example 2

As a water-soluble silicate solution, there was used Shield-S (product name, silicate aqueous solution, product developed by PVC & Polymer Materials Research Center of Shin-Etsu Chemical Co., Ltd).


SiO2 Precursor, Silicate Molecule with Well-Defined Structure
Working Examples 7 to 12

A component used for forming water-soluble SiO2 was prepared as follows. That is, a PSS hydrate-octakis (tetramethylammonium) substitution product (polyhedral oligomeric silsesquioxane having Q38 TMA structure, by Sigma-Aldrich Corporation) was dissolved in water, followed by removing Na ions with a strong acid ion-exchange resin and then adjusting the solid content (1% by mass in terms of SiO2) by performing dilution with a purified water.


Al2O3 Precursor
Working Examples 13 to 18

An aqueous solution of a water-soluble aluminum salt used was prepared as follows. That is, ALFINE 83 (product name, 23% aqueous solution of highly basic aluminum chloride, by Taimei Chemicals Co., Ltd.) was diluted with a purified water to adjust the solid content (1% by mass in terms of Al2O3).


ZrO2 Precursor
Working Examples 19 to 24

An aqueous solution of a water-soluble zirconium salt used was prepared as follows. That is, Zircosol AC-20 (product name, (NH4)2ZrO (CO3)2, aqueous solution of zirconium compound, by DAIICHI KIGENSO KAGAKU KOGYO Co., Ltd.) was diluted with a purified water to adjust the solid content (1% by mass in terms of ZrO2).


Aqueous Dispersion Liquid of SnO2 Ultrafine Particles
Working Examples 25 to 30

SnO2 fine particles used were prepared by adjusting the concentration (1% by mass in terms of SnO2) of an ultrafine particles of Tin (IV) oxide sol (average primary particle diameter 5 nm, by Yamanaka & Co., Ltd) with a purified water. The aqueous dispersion liquid thus obtained exhibited a dispersion particle diameter D50 of 50 nm.


ZnO Precursor
Working Examples 31 to 36

A commercially available zinc acetate dihydrate was hydrolyzed with an aqueous solution of water/ethanol+triethanolamine in a manner such that the concentration thereof became 1% by mass in terms of zinc oxide. The hydrolyzed product was used immediately thereafter.


Aqueous Dispersion Liquid of SiO2 Fine Particles Large
Comparative Example 1

An aqueous dispersion liquid of SiO2 fine particles used was prepared by diluting SNOWTEX ST-OUP (product name, a colloidal silica having an average primary particle diameter of 100 nm, by NISSAN CHEMICAL INDUSTRIES, LTD) with a purified water such that the concentration thereof could be adjusted (1% by mass in terms of SiO2). The aqueous dispersion liquid thus obtained exhibited a dispersion particle diameter D50 of 100 nm.


Aqueous Dispersion Liquid of SiO2 Fine Particles Small
Working Example 37

An aqueous dispersion liquid of SiO2 fine particles used was prepared by diluting SNOWTEX ST-NXS (product name, particle diameter 4 to 6 nm, a colloidal silica having an average primary particle diameter of 5 nm, by NISSAN CHEMICAL INDUSTRIES, LTD) with a purified water such that the concentration thereof could be adjusted (1% by mass in terms of SiO2). The aqueous dispersion liquid thus obtained exhibited a dispersion particle diameter D50 of 5 nm.


Method of Thin Film Property Evaluation

The film thickness of the thin film was measured by a thin film measurement system F-20 (product name, by FILMETRICS) and a scanning electron microscope S-3400 nm (product name, by Hitachi High-Technologies Corporation).


The total light transmittance and haze rate of the thin film were measured by a digital hazemeter NDH-20D (by NIPPON DENSHOKU INDUSTRIES Co., LTD).


As for an environment for promoting PID of the solar cell, the solar cell was exposed for 96 hours to an environment of temperature 60° C./humidity 85% RH/water-filled surface, with a test voltage of −1,000 Vdc being applied thereto [frame potential as reference, −1,000 Vdc to internal circuit].


As for the properties of the solar cell, a prescribed device (I-V curve tracer MP160 by EKO Instruments) was used to measure an I-V property thereof, and an EL image inspection device (PVX-300 by ITES Co., Ltd) was used for measurement as well.


















TABLE 1










Decrement in
Increment in







Front
Back
total light
Haze value
Leakage
Decrement in
Light




surface
surface
transmittance
before and
current
conversion
emitting




coating
coating
before and after
after
value after
efficiency
area in



Coating material
thickness/nm
thickness/nm
coating Δ%
coating Δ%
96 hr/μA
Δη/point
EL test/%























Blank
None
None
None

7.5
8.21
25
















Working
1
Shield-S
20

0.1
0.1
7.4
6.99
50


example
2
(Silicate aqueous
100

0.5
0.2
6.1
5.21
75



3
solution, SiO2 thin
500

0.2
1
5.2
4.34
75



4
film precursor

20
0.2
0.1
5.8
4.22
75



5
aqueous solution)

100
0.3
0.2
4.2
1.25
100



6


500
0.3
1.1
3.1
0.50
100



7
Deionized Q8TMA
20

0.2
0.1
7.3
7.2
50



8
(polyhedral oligomeric
100

0.2
0.1
6.2
5.1
75



9
silsesquioxane all OH
500

0.3
1
5.3
4.7
75



10
type, SiO2 thin film

20
0.3
0.3
6.2
4.65
75



11
precursor aqueous

100
0.3
0.3
4.8
1.75
100



12
solution)

500
0.4
0.9
3.3
0.68
100



13
ALFINE83
20

0.3
0.3
7.4
7.98
50



14
(Al2O3 thin film
100

0.2
0.5
6.6
7.22
75



15
precursor aqueous
500

0.4
1.2
5.4
6.10
75



16
solution)

20
0.2
0.5
6.3
4.89
75



17


100
0.3
0.5
5.1
3.65
100



18


500
0.3
1.1
3.2
1.23
100

























TABLE 2










Decrement in
Increment in







Front
Back
total light
Haze value
Leakage
Decrement in
Light




surface
surface
transmittance
before and
current
conversion
emitting




coating
coating
before and after
after
value after
efficiency
area in



Coating material
thickness/nm
thickness/nm
coating Δ%
coating Δ%
96 hr/μA
Δη/point
EL test/%

























Working
19
Zircosol AC-20
20

0.3
0.9
7.2
7.87
50


example
20
(ZrO2 thin
100

0.4
1.2
6.2
7.65
75



21
film precursor
500

0.3
1.3
6.1
7.59
75



22
aqueous solution)

20
0.2
0.9
6.8
6.35
75



23


100
0.2
1.2
5.2
4.35
100



24


500
0.3
1.1
3.9
3.32
100



25
Ultrafine particles of
20

1.2
1.2
5.9
7.2
50



26
Tin (IV) oxide sol
100

1.5
1.5
5.8
5.1
75



27
(Aqueous dispersion
500

1.8
1.8
5.5
4.7
75



28
liquid of SnO2 ultrafine

20
1.1
1.5
5.9
4.65
75



29
particles)

100
1.1
1.6
4.6
1.75
100



30


500
1.9
1.6
3.2
0.68
100



31
Zinc acetate dihydrate
20

0.5
0.5
6.9
7.7
50



32
(ZnO thin
100

0.6
0.6
6.7
6.89
75



33
film precursor
500

1.0
1.2
5.8
6.45
75



34
aqueous solution)

20
0.6
0.6
5.5
5.26
75



35


100
0.6
0.8
4.8
4.35
100



36


500
1.2
1.2
3.3
4.21
100



37
SiO2 fine particles (small)

200
3.2
2.5
5.5
6.59
75


Comparative
1
SiO2 fine particles (large)

200
5.4
4.2
7.6
8.66
25


example
2
Shield-S

1000
4.3
2.1
6.8
8.11
25









According to the results shown in Tables 1 and 2, performance degradations were able to be controlled in the solar cells with various metal oxide films of the working examples being formed thereon. In contrast, significant performance degradations were observed in the blank solar cells.


In the working examples, although no significant difference in leakage current value was confirmed as a result of coating the surface of the cover glass, it was shown through EL image determination that a light emitting capability had still existed, and a decrease in a conversion efficiency was also able to be controlled in such case. This indicates that PID can still be alleviated even after processing the cover panel surface of a solar cell that had already been processed, which is significant.


In the working examples, as a result of coating the back surface of the cover glass, not only the leakage current value dropped by half or more, but multiple cells were also confirmed to still possess the light emitting capabilities through EL image inspection i.e. an obvious degradation control was exhibited.


It can be learnt that the insulation effect and the degradation control effect can be achieved with the thin film of the Working example 37 where a dispersion liquid of small fine particles was used. In contrast, no expected effect was achieved with the thin film of the Comparative example 1 due to the fact that large particles were employed. It is considered that the reason that an insufficient degradation control effect was achieved was because the particles used were large and thus had led to a low density of the thin film.


In the Comparative example 2, tests were performed by forming a SiO2-based thin film to a thickness of 1 micron (1,000 nm). An inorganic film having a thickness of 1 micron is extremely hard such that cracks will easily occur in a normal work environment. The occurrence of the cracks can be determined based on a significant degradation in optical property. It is considered that the reason that an insufficient degradation control effect was achieved was because such cracks had led to an insufficient density of the inorganic film.

Claims
  • 1. A solar cell degradation control-cover glass having a solar cell degradation control-thin film formed by applying to a back surface of said cover glass a solar cell degradation control-coating liquid comprising: an aqueous solution of a water-soluble compound of at least one metal selected from silicon, aluminum, zirconium, tin and zinc; ora fine particle dispersion liquid of an oxide of said metal, wherein said aqueous solution and said fine particle dispersion liquid each contain said compound or said oxide in an amount of 0.01 to 10% by mass in terms of metal oxide, and said fine particle dispersion liquid contains fine particles that have an average primary particle diameter of not larger than 50 nm and are dispersed at a dispersion particle diameter (D50) of smaller than 100 nm.
  • 2. The solar cell degradation control-cover glass according to claim 1, wherein said water-soluble compound is selected from a water-soluble silicate, an aluminum chloride, (NH4)2ZrO(CO3)2 and a zinc acetate.
  • 3. The solar cell degradation control-cover glass according to claim 1, wherein said fine particle dispersion liquid of said metal oxide is an aqueous dispersion liquid containing fine particles exhibiting a dispersion particle diameter D50 of not larger than 50 nm.
  • 4-8. (canceled)
  • 9. The solar cell degradation control-cover glass according to claim 1, wherein a step of forming said solar cell degradation control-thin film includes an operation of drying and curing a coated film at a temperature of from a normal temperature to 200° C.
  • 10. The solar cell degradation control-cover glass according to claim 2, wherein a step of forming said solar cell degradation control-thin film includes an operation of drying and curing a coated film at a temperature of from a normal temperature to 200° C.
  • 11. The solar cell degradation control-cover glass according to claim 3, wherein a step of forming said solar cell degradation control-thin film includes an operation of drying and curing a coated film at a temperature of from a normal temperature to 200° C.
  • 12. The solar cell degradation control-cover glass according to claim 1, wherein said solar cell degradation control-thin film has a film thickness of 10 to 700 nm.
  • 13. The solar cell degradation control-cover glass according to claim 2, wherein said solar cell degradation control-thin film has a film thickness of 10 to 700 nm.
  • 14. The solar cell degradation control-cover glass according to claim 3, wherein said solar cell degradation control-thin film has a film thickness of 10 to 700 nm.
  • 15. The solar cell degradation control-cover glass according to claim 4, wherein said solar cell degradation control-thin film has a film thickness of 10 to 700 nm.
  • 16. A solar cell having the solar cell degradation control-cover glass as set forth in claim 1.
  • 17. A solar cell having the solar cell degradation control-cover glass as set forth in claim 2.
  • 18. A solar cell having the solar cell degradation control-cover glass as set forth in claim 3.
  • 19. A solar cell having the solar cell degradation control-cover glass as set forth in claim 9.
  • 20. A solar cell having the solar cell degradation control-cover glass as set forth in claim 10.
  • 21. A solar cell having the solar cell degradation control-cover glass as set forth in claim 11.
  • 22. A solar cell having the solar cell degradation control-cover glass as set forth in claim 12.
  • 23. A solar cell having the solar cell degradation control-cover glass as set forth in claim 13.
  • 24. A solar cell having the solar cell degradation control-cover glass as set forth in claim 14.
  • 25. A solar cell having the solar cell degradation control-cover glass as set forth in claim 15.
Priority Claims (1)
Number Date Country Kind
2013-123725 Jun 2013 JP national
PCT Information
Filing Document Filing Date Country Kind
PCT/JP2014/063644 5/23/2014 WO 00