JP4308387B2 - Defect repair method for thin film photoelectric conversion module and method for manufacturing thin film photoelectric conversion module - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a defect repair method for a thin film photoelectric conversion module and a method for manufacturing a thin film photoelectric conversion module, and in particular, a defect repair for a thin film photoelectric conversion module that insulates a short circuit between a transparent front electrode layer and a metal back electrode layer. The present invention relates to a method and a method for manufacturing a thin film photoelectric conversion module.
[0002]
[Prior art]
In general, a thin film photoelectric conversion module has a structure in which a plurality of thin film photoelectric conversion cells are connected in series on a substrate. Each thin film photoelectric conversion cell is formed, for example, by sequentially forming and patterning a front transparent electrode layer, a thin film photoelectric conversion unit, and a metal back electrode layer on a transparent substrate.
[0003]
By the way, in the film formation of a thin film photoelectric conversion unit, in particular, the film formation of a large area thin film photoelectric conversion unit, the generation of pinholes cannot be avoided. Since this pinhole is embedded with a metal material when the metal back electrode layer is subsequently formed, a short circuit occurs between the transparent front electrode layer and the metal back electrode layer. That is, in many cases, each thin film photoelectric conversion cell immediately after formation has a short-circuit defect.
[0004]
When such a short-circuit portion is left unattended, the expected module output cannot be obtained. Therefore, in the manufacturing process of the thin film photoelectric conversion module, generally, after the thin film photoelectric conversion cell is formed, a defect repairing step for insulating the short-circuit portion is performed. Here, “insulating” means to increase the resistance value of the short-circuit portion to a value sufficient to obtain the required electrical characteristics.
[0005]
As a method for repairing the above-described defect, for example, reverse bias processing is known. In this reverse bias treatment, a voltage is applied to the thin film photoelectric conversion cell having a short-circuit portion in the same direction as the power generation direction (when the thin film photoelectric conversion cell is considered as a diode, a voltage is applied in the reverse direction). Is done. When such a reverse bias voltage is applied, in a thin film photoelectric conversion cell having a pin junction or the like, the current concentrates on the short-circuit portion, and local heat generation occurs. As a result, the metal filling the pinhole is oxidized or melted away, and the transparent front electrode layer and the metal back electrode layer are insulated at the position of the pinhole.
[0006]
As described above, the reverse bias treatment is performed by applying a reverse bias voltage between the metal back electrode layer and the transparent front electrode layer for a specific thin film photoelectric conversion cell. Since it is covered with the thin film photoelectric conversion unit and the metal back electrode layer, a voltage cannot be directly applied. Therefore, the reverse bias treatment is conventionally performed by bringing a probe into contact with the metal back electrode layer of a pair of adjacent cells. That is, by utilizing the fact that one transparent front electrode layer of a pair of adjacent cells and the metal back electrode layer of the other cell are electrically connected, one transparent front electrode layer and the metal back surface of those cells A reverse bias voltage is applied to the electrode layer.
[0007]
However, in order to perform reverse bias processing on all cells by such a method, a mechanism for moving the probe up and down, a mechanism for moving the module horizontally, and the like are required. Also, with this method, it is difficult to apply a voltage uniformly to the cell, and the metal back electrode layer may be damaged by contact with the probe.
[0008]
[Problems to be solved by the invention]
The present invention has been made in view of the above problems, and it is possible to manufacture a thin film photoelectric conversion module having a sufficiently improved module output and a thin film photoelectric conversion module defect repair method and a thin film photoelectric conversion module. An object is to provide a manufacturing method.
[0009]
Another object of the present invention is to provide a thin film photoelectric conversion module defect repairing method and a thin film photoelectric conversion module manufacturing method capable of insulating a short-circuit portion without requiring a complicated transport mechanism or the like. To do.
[0010]
Furthermore, an object of the present invention is to provide a defect repair method for a thin film photoelectric conversion module and a method for manufacturing the thin film photoelectric conversion module that can uniformly apply a voltage to a cell during reverse bias processing.
[0011]
Another object of the present invention is to provide a defect repairing method for a thin film photoelectric conversion module and a manufacturing method for the thin film photoelectric conversion module that can insulate a short-circuit portion without damaging an electrode layer.
[0012]
[Means for Solving the Problems]
As a result of intensive studies to solve the above problems, the present inventor shields one of the plurality of thin film photoelectric conversion cells in a state where the series array is short-circuited, and irradiates the other thin film photoelectric conversion cells with light. For example, it has been found that a reverse bias voltage can be selectively applied to a light-shielded thin-film photoelectric conversion cell, and insulation processing of a short-circuited portion can be performed.
[0013]
That is, according to the present invention, a plurality of thin film photoelectric conversion cells each having a structure in which a first electrode layer, a thin film photoelectric conversion unit, and a second electrode layer are sequentially stacked on a substrate are connected in series. the defect repairing method of a thin film photoelectric conversion module comprising an array, state selectively reverse bias voltage to one of the previous SL plurality of thin film photoelectric conversion cells was short-circuited the serial array to be applied in remaining in the molten removed by the local heating of the plurality of the one to be formed on the metal material constituting the short circuit portions of the thin film photoelectric conversion cells by irradiating light of said plurality of thin film photoelectric conversion cells A method of repairing a defect in a thin film photoelectric conversion module is provided, which includes a step of insulating the short-circuit portion by oxidizing or oxidizing .
[0014]
According to the present invention, a plurality of thin film photoelectric conversion cells each having a structure in which a first electrode layer, a thin film photoelectric conversion unit, and a second electrode layer are sequentially stacked on a substrate are connected in series. forming an array of selectively said plurality of thin film photoelectric conversion cells in a state of reverse bias voltage are short-circuited the serial array to be applied to one of the previous SL plurality of thin film photoelectric conversion cells said one metallic material constituting the short circuit portion formed on its local and or oxide is removed melted by heating the short-circuit portion of the plurality of thin film photoelectric conversion cells by irradiating light to the rest Including a step of insulating the thin film photoelectric conversion module.
[0015]
In the present invention, when each thin film photoelectric conversion cell includes one thin film photoelectric conversion unit, usually, the step of insulating the short circuit portion shields one of the plurality of thin film photoelectric conversion cells with the series array short-circuited. And applying a reverse bias voltage selectively to the thin film photoelectric conversion cells shielded by irradiating the remaining thin film photoelectric conversion cells with light.
[0016]
In the present invention, the step of insulating the short-circuit portion is preferably performed in a state where a series structure in which a series array and a load are connected in series is formed and the series structure is short-circuited. In this case, it is possible to prevent an excessive voltage from being applied to the cell in which the insulation treatment of the short circuit portion is performed.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in more detail with reference to the drawings. In the drawings, the same members are denoted by the same reference numerals, and redundant description is omitted.
[0018]
FIG. 1 is a cross-sectional view schematically showing a thin film photoelectric conversion module before performing a defect repairing process according to an embodiment of the present invention. A thin film photoelectric conversion module 1 shown in FIG. 1 has a structure in which a plurality of thin film photoelectric conversion cells 10 are integrated on a transparent substrate 2. These thin film photoelectric conversion cells 10 have a strip shape that is long in the direction perpendicular to the paper surface, and are connected in series to form a series array. Each thin film photoelectric conversion cell 10 has a structure in which a transparent front electrode layer 3, a thin film photoelectric conversion unit 4, and a metal back electrode layer 5 are sequentially laminated on a transparent substrate 2. That is, this module 1 performs photoelectric conversion of light incident from the transparent substrate 2 side by the photoelectric conversion unit 4.
[0019]
The module 1 shown in FIG. 1 can be manufactured by the method shown below, for example.
First, the transparent front electrode layer 3 is formed as a large-area thin film on one main surface of the transparent substrate 2. The transparent substrate 2 can be composed of a glass plate, a transparent resin film, or the like. The transparent front electrode layer 3 can be composed of a transparent conductive oxide layer such as an ITO film, a SnO ₂ film, or a ZnO film. The transparent front electrode layer 3 may have a single layer structure or a multilayer structure. The transparent front electrode layer 3 can be formed by a vapor deposition method known per se such as a vapor deposition method, a CVD method, or a sputtering method.
[0020]
It is preferable to form a surface texture structure including fine irregularities on the surface of the transparent front electrode layer 3. By forming such a texture structure on the surface of the transparent front electrode layer 3, the light incident efficiency to the photoelectric conversion unit 4 can be improved. There is no restriction | limiting in particular in the method of forming a surface texture structure, A well-known various method can be used.
[0021]
Next, a groove 6 is formed in the transparent front electrode layer 3 formed as a large-area thin film by laser scribing using a YAG laser or the like, and the transparent front electrode layer 3 is divided corresponding to each cell 10. As described above, each of the cells 10 has a strip shape, and is integrated in the minor axis direction (horizontal direction in FIG. 1).
[0022]
Next, the thin film photoelectric conversion unit 4 is formed on the transparent front electrode layer 3. The thin film photoelectric conversion unit 4 has, for example, a p-type non-single crystal silicon-based semiconductor layer, a non-single crystal silicon-based thin film photoelectric conversion layer, and an n-type non-single crystal silicon-based semiconductor layer that are sequentially stacked on the transparent front electrode layer 3. It has a structure. These p-type semiconductor layer, photoelectric conversion layer, and n-type semiconductor layer can all be formed by a plasma CVD method.
[0023]
The p-type silicon-based semiconductor layer can be formed by doping silicon or a silicon alloy such as silicon carbide or silicon germanium with p conductivity type determining impurity atoms such as boron or aluminum.
[0024]
The photoelectric conversion layer formed on the p-type semiconductor layer can be formed of a non-single-crystal silicon-based semiconductor material. Examples of such a material include intrinsic semiconductor silicon (such as silicon hydride), silicon carbide, and silicon. Examples thereof include silicon alloys such as germanium. In addition, if the photoelectric conversion function is sufficiently provided, a weak p-type or weak n-type silicon-based semiconductor material containing a small amount of a conductivity type determining impurity may be used.
[0025]
The n-type silicon-based semiconductor layer formed on the photoelectric conversion layer can be formed by doping silicon or a silicon alloy such as silicon carbide or silicon germanium with n-conductivity determining impurity atoms such as phosphorus or nitrogen. .
[0026]
Along with the formation of the thin film photoelectric conversion unit 4 described above, the groove 6 formed in the transparent front electrode layer 3 is filled with a material constituting the thin film photoelectric conversion unit 4. Note that pinholes 9 are inevitably formed in the thin film photoelectric conversion unit 4 described above. For example, in a general-sized module 1, at least one pinhole 9 is usually formed in each cell 10.
[0027]
After forming the thin film photoelectric conversion unit 4 as described above, the groove 7 is formed in the photoelectric conversion unit 4 by laser scribing using a YAG laser or the like. The groove portion 7 is provided to electrically connect the transparent front electrode layer 3 of a certain cell 10 and the back surface metal electrode layer 5 of the cell 10 adjacent thereto.
[0028]
Next, the metal back electrode layer 5 is formed on the photoelectric conversion unit 4. The metal back electrode layer 5 not only has a function as an electrode, but also reflects light that enters the photoelectric conversion unit 4 from the transparent substrate 2 and reaches the back electrode layer 5 and re-enters the photoelectric conversion unit 4. It also functions as a layer. The metal back electrode layer 5 can be formed to a thickness of, for example, about 200 nm to 400 nm using silver, aluminum, or the like by a vapor deposition method, a sputtering method, or the like. In addition, a transparent conductive thin film (not shown) made of a non-metallic material such as ZnO is provided between the metal back electrode layer 5 and the photoelectric conversion unit 4 in order to improve the adhesion between them, for example. Can be provided.
[0029]
With the formation of the metal back electrode layer 5 described above, the groove portion 7 formed in the photoelectric conversion unit 4 is embedded with a metal material, and the metal back electrode layer 5 and the transparent front electrode layer 3 are electrically connected at the position of the groove portion 7. Is done. At the same time, the pinhole 9 is filled with a metal material, and the metal back electrode layer 5 and the transparent front electrode layer 3 are electrically connected even at the position of the pinhole 9.
[0030]
Next, a groove 8 is formed in the metal back electrode layer 5 by laser scribing using a YAG laser or the like, and the metal back electrode layer 5 is electrically insulated between the cells 10. Further, a power generation region is determined by laser scribing using a YAG laser or the like, and a pair of electrode bus bars (not shown) are provided at both ends of a row formed by the cells 10, thereby obtaining the structure shown in FIG.
[0031]
In the module 1 obtained by the method described above, as shown in FIG. 1, the transparent front electrode layer 3 and the metal back electrode layer are short-circuited at the position of the pinhole 9 in a single cell 10. If such a short circuit is left unattended, module output as expected cannot be obtained as described above. Therefore, in the manufacturing process of the thin film photoelectric conversion module 1 according to the present embodiment, after the thin film photoelectric conversion cell 10 is formed, a defect repairing process described below is performed.
[0032]
First, before describing the defect repairing process, a defect repairing apparatus used for repairing defects will be described.
[0033]
FIG. 2 is a diagram schematically showing a defect repair apparatus for the thin film photoelectric conversion module 1 according to an embodiment of the present invention. The defect repairing apparatus 15 shown in FIG. 2 mainly includes a support member 16 that supports the module 1, a light source 17, a light shielding plate 18, a load 19, and an ammeter 20.
[0034]
The support member 16 is not particularly limited as long as it supports the module 1 so that the light from the light source 17 is irradiated to the cell 10 of the module 1. For example, as the support member 16, a transparent plate-like body made of glass or the like can be used.
[0035]
The light source 17 is not particularly limited as long as it outputs light that can be photoelectrically converted by the cell 10 and can irradiate the cell 10 with light uniformly. Examples of such a light source 17 include an LED and a xenon lamp. The light source 17 may be a pulse light source.
[0036]
The light shielding plate 18 prevents photoelectric conversion in the cell 10 by preventing the light from the light source 17 from being applied to one of the cells 10. Therefore, the light shielding plate 18 does not necessarily need to completely shield the light from the light source 17 and may be a filter that absorbs only a light component in a wavelength region in which the cell 10 can perform photoelectric conversion. Further, the light shielding plate 18 may be disposed anywhere between the light source 17 and the module 1.
[0037]
Instead of providing the light shielding plate 18, a light source 17 such as an LED may be provided in an array corresponding to each cell 10 to control ON / OFF of the light source 17. When the light shielding plate 18 is provided, a mechanism for physically moving the light shielding plate 18 is necessary. However, when controlling the ON / OFF of the light source 17, such a physical movement mechanism is not necessary. Therefore, the time required for the defect repairing process can be shortened and the maintenance becomes easy.
[0038]
The load 19 is provided in order to prevent an excessive reverse bias voltage from being applied to the cell 10 that performs defect repair. Therefore, for example, if the illuminance of light from the light source 17 can be controlled so that an excessive reverse bias voltage is not applied to the cell 10 that repairs the defect, the load 19 is not necessarily provided. As the load 19, a variable resistor, a direct current power source capable of controlling the output, or the like can be used.
[0039]
The ammeter 20 is provided for the purpose of measuring the module output. The ammeter 20 is not necessarily provided, but when provided, the defect repair device 15 can be used as an output measuring device.
[0040]
The defect repair of the module 1 by the defect repair apparatus 15 described above is performed by the following method, for example.
[0041]
First, the module 1 is disposed on the support member 16 so that the transparent substrate 2 faces the light source 17 side. Next, the pair of electrode bus bars 11 of the module 1 is connected to the load 19, and the light shielding plate 18 is aligned with the cell 10 for repairing the defect.
[0042]
Thereafter, power is supplied to the light source 17 to irradiate the module 1 with light. Here, as described above, one of the cells 10 is shielded by the light shielding plate 18. Therefore, the light-shielded cell 10 behaves as a diode connected in series in the reverse direction with respect to the other cells 10. That is, when the module 1 has n cells 10, the voltage drop V ₂ due to the load 19 is obtained from the voltage (n−1) V ₁ obtained by multiplying the output voltage V ₁ of each cell by (n−1). The reduced voltage [(n−1) V ₁ −V ₂ ] is applied in the reverse direction to the cell 10 acting as a diode. As a result, the metal material constituting the light-shielded short-circuit portion 9 of the cell 10 is melted away or oxidized, and the transparent front electrode layer 3 and the metal back electrode layer 5 are insulated.
[0043]
After performing the above-described insulation treatment for a certain cell 10, the light shielding plate 18 is aligned with respect to another cell 10, and the above-described treatment is also performed for this cell 10. As described above, the defect repairing process is completed by performing the insulating process on all the cells 10. The defect repairing process described above is performed while adjusting the illuminance of light from the light source 17 in order to prevent an excessive reverse bias voltage from being applied to the cell 10 for repairing the defect, or the load 19 In the case of a variable resistor, the resistance value is adjusted, and in the case where the load 19 is a variable DC power supply, the output is adjusted, or the illuminance of light from the light source 17 and the resistance value of the load 19 or Adjust both output and output.
[0044]
After performing the above process with respect to all the cells 10, an organic protective film (not shown) is normally provided in the back surface side of the module 1 through the sealing resin layer (not shown). This sealing resin layer seals each thin film photoelectric conversion cell 10 formed on the transparent substrate 2, and a resin capable of adhering an organic protective film to these cells 10 is used. As such a resin, for example, EVA (ethylene / vinyl acetate copolymer) can be used. Moreover, as an organic protective film, a polyvinyl fluoride film (for example, Tedlar film (registered trademark)) or the like is used. These sealing resin / organic protective films can be simultaneously attached to the back side of the thin film photoelectric conversion module 1 by a vacuum laminating method.
[0045]
You may provide these sealing resin layers and organic protective films before the defect repair process mentioned above. In this case, the connection between the series array formed by connecting a plurality of cells 10 in series and the load 19 is performed via an extraction electrode (not shown) connected to the pair of electrode bus bars 11.
[0046]
As described above, according to the present embodiment, the insulation treatment of the short-circuited portion shields one of the plurality of thin-film photoelectric conversion cells 10 in a state where the series array is short-circuited, and is applied to the other thin-film photoelectric conversion cells 10. It is performed by performing light irradiation. That is, according to the present embodiment, it is possible to insulate the short-circuit portion without bringing a probe or the like into contact with the metal back electrode layer 5. Therefore, according to the present embodiment, it is possible to insulate the short-circuit portion without requiring a complicated transport mechanism or the like. Further, since it is not necessary to use a probe or the like, the metal back electrode layer 5 is not damaged, and a voltage can be uniformly applied to the cell 10 during the reverse bias process. Further, when the load 19 is a variable resistor during the defect repairing process described above, the load 19 is a DC power source whose output is variable by recording the resistance value and the reading of the ammeter 20. The output characteristic of the module 1 can be measured by recording the output voltage and the reading of the ammeter 20. That is, the defect can be repaired while measuring the output characteristics of the module 1.
[0047]
In the above-described embodiment, the present invention is applied to the defect repair processing of the module 1 shown in FIG. 1, but the short-circuit portion 9 electrically connects the transparent front electrode layer 3 and the metal back electrode layer 5. In this case, the present invention can be applied to the defect repair processing of the tandem type module.
[0048]
【Example】
Examples of the present invention will be described below.
[0049]
The thin film photoelectric conversion module 1 shown in FIG. 1 was produced by the method described below, and then the defects of the module 1 were repaired using the defect repairing device 15 shown in FIG.
[0050]
First, a 910 mm × 450 mm glass substrate having the SnO ₂ film 3 on one main surface was prepared. Next, the SnO ₂ film 3 was scribed and divided into a plurality of strip-like patterns by laser scanning in parallel with the long side of the substrate 1 using a YAG laser.
[0051]
Thereafter, a 10-nm-thick p-type hydrogen-containing amorphous silicon carbide layer, a 300-nm-thick i-type hydrogen-containing amorphous silicon layer, and a 10-nm-thick n-type are formed on the SnO ₂ film 3 by plasma CVD. Hydrogen-containing microcrystalline silicon layers were sequentially formed. Note that the p-type hydrogen-containing amorphous silicon carbide layer is doped with boron as an impurity, the i-type hydrogen-containing amorphous silicon layer is non-doped, and the n-type hydrogen-containing microcrystalline silicon layer is doped with phosphorus. As described above, the thin film photoelectric conversion unit 4 having a pin junction was formed.
[0052]
Next, the thin film photoelectric conversion unit 4 was scribed by performing laser scanning in parallel with the long side of the substrate 1 using a YAG laser, and the thin film photoelectric conversion unit 4 was divided into a plurality of strip patterns.
[0053]
Next, a 90 nm thick ZnO film (not shown) and a 300 nm thick Ag film 5 were sequentially formed on the thin film photoelectric conversion unit 4 by sputtering to form a back electrode layer. Similarly, this back electrode layer was divided into a plurality of strip patterns by laser scribing using a YAG laser.
[0054]
Subsequently, laser scribing was performed in parallel with the short side of the substrate 2 using a YAG laser, and the SnO ₂ film 3, the thin film photoelectric conversion unit 4, and the back electrode layer were each divided in the long side direction of the substrate 2. Thereafter, the power generation region was determined by laser scribing using a YAG laser or the like. As described above, 50 thin film photoelectric conversion cells 10 each having a size of 890 mm × 9 mm and connected in series in a direction parallel to the short side of the substrate 2 were formed.
[0055]
Furthermore, the module 1 shown in FIG. 1 was obtained by providing a pair of electrode bus bars 11 at both ends of the series array formed by the cells 10.
[0056]
Ten modules 1 were manufactured by the method described above, and the output characteristics of each module 1 were examined using a solar simulator with an irradiance of 100 mW / cm ² and an AM of 1.5 using a xenon lamp as a light source. The measurement temperature was 25 ° C. As a result, the maximum output of module 1 is 25 W on average. F. Was 50% on average.
[0057]
Next, the defect repairing process described above was performed on each of these modules 1 using the apparatus 15 shown in FIG. In this embodiment, a xenon lamp is used as the light source 17 and the irradiance is 100 mW / cm ² . In addition, the light shielding plate 18 is used to control the cell 10 to be insulated so that no light is irradiated at all, and the load 19 uses a DC power source whose output is variable, and a reverse bias voltage applied to each cell 10. Was controlled to be about 4 to 10V.
[0058]
Under the above conditions, a defect repairing step was performed for each cell 10 every 0.5 seconds, and then the output characteristics of the module 1 were examined under the above conditions. As a result, the average output of module 1 is improved to 35 W. F. Also improved to an average of 70%.
[0059]
【The invention's effect】
As described above, according to the present invention, the series array is irradiated with light so that a reverse bias voltage is selectively applied to one of the plurality of thin film photoelectric conversion cells in a state where the series array is short-circuited. Thus, the short circuit portion formed in one of the plurality of thin film photoelectric conversion cells is insulated. Therefore, in the present invention, in order to insulate the short-circuited portion, that is, to improve the module output, a complicated transport mechanism or the like is not required. In the present invention, since a reverse bias voltage can be applied to a desired cell without bringing a probe or the like into contact with the metal back electrode layer, it is possible to uniformly apply a voltage to the cell during reverse bias processing. Moreover, the electrode layer is not damaged.
[0060]
That is, according to the present invention, a thin film photoelectric conversion module defect repairing method and a thin film photoelectric conversion module manufacturing method capable of manufacturing a thin film photoelectric conversion module with sufficiently improved module output are provided. In addition, according to the present invention, there are provided a defect repair method for a thin film photoelectric conversion module and a method for manufacturing a thin film photoelectric conversion module that can insulate a short-circuit portion without requiring a complicated transport mechanism or the like. Furthermore, according to the present invention, there are provided a thin film photoelectric conversion module defect repairing method and a thin film photoelectric conversion module manufacturing method capable of uniformly applying a voltage to a cell during reverse bias processing. Moreover, according to this invention, the defect repair method of the thin film photoelectric conversion module and the manufacturing method of a thin film photoelectric conversion module which can insulate a short circuit part without damaging an electrode layer are provided.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view schematically showing a thin film photoelectric conversion module before performing a defect repairing step according to a first embodiment of the present invention.
FIG. 2 schematically shows a defect repair apparatus for a thin film photoelectric conversion module according to the first embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Thin film photoelectric conversion module 2 ... Transparent substrate 3 ... Transparent front electrode layer 4 ... Thin film photoelectric conversion unit 5 ... Back surface metal electrode layer 6-8 ... Groove 9 ... Pinhole or short circuit part 10 ... Thin film photoelectric conversion cell 11 ... Electrode bus bar DESCRIPTION OF SYMBOLS 15 ... Defect repair apparatus 16 ... Support member 17 ... Light source 18 ... Light-shielding plate or filter 19 ... Load 20 ... Ammeter

Claims (4)

Thin film photoelectric conversion comprising a series array in which a plurality of thin film photoelectric conversion cells each having a structure in which a first electrode layer, a thin film photoelectric conversion unit, and a second electrode layer are sequentially stacked on a substrate are connected in series. A module defect repair method,
Applying light to the rest of the plurality of thin film photoelectric conversion cells in a state that selectively reverse bias voltage is shorted the serial array to be applied to one of the previous SL plurality of thin film photoelectric conversion cells said plurality of said one metal material constituting the short circuit portion formed in the thin film photoelectric conversion cells and or oxidized melted removed by the local heat generation may include the step of insulating the short circuit portion by A defect repairing method for a thin film photoelectric conversion module. Process for insulating the short circuit portion, by irradiating light to the rest of the one of the light-shielded and the plurality of thin film photoelectric conversion cells of said serial array wherein a plurality of thin film photoelectric conversion cells in a state of being short-circuited The defect repairing method for a thin film photoelectric conversion module according to claim 1, further comprising selectively applying a reverse bias voltage to the light-shielded thin film photoelectric conversion cell.   3. The thin film according to claim 1, wherein a step of forming a series structure formed by connecting the series array and a load in series and insulating the short-circuit portion in a state where the series structure is short-circuited is performed. Defect repair method for photoelectric conversion module. Forming a series array in which a plurality of thin film photoelectric conversion cells each having a structure in which a first electrode layer, a thin film photoelectric conversion unit, and a second electrode layer are sequentially stacked on a substrate are connected in series;
Applying light to the rest of the plurality of thin film photoelectric conversion cells in a state that selectively reverse bias voltage is shorted the serial array to be applied to one of the previous SL plurality of thin film photoelectric conversion cells It said plurality of said one metal material constituting the short circuit portion formed in the thin film photoelectric conversion cells and or oxidized melted removed by the local heating by a step of insulating the short circuit portion A method for producing a thin-film photoelectric conversion module.

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