JP2001250969A - Thin film solar battery module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thin film solar battery module whose photoelectric conversion efficiency is optimized in the solar battery module used in a state except for a standard state such as to install the module on a vertical wall face and a north side slope or to fit a color filter on the surface of the solar battery for the purpose of appearance. SOLUTION: In a thin film solar battery module, plural thin film solar battery units provided with transparent electrode layers, optical power generation layers and metallic electrode layers are formed on the surface of a substrate having electric insulation property, and the thin film solar battery units are connected in series. In the thin film solar battery module used in a state except for a standard state by the constitution and the installation condition of the solar battery module, the efficiency ratio of the photoelectric conversion efficiency of the solar battery module in the used state is made to be maximum. Consequently, thin film solar battery unit cell width W is made to be larger in the module used in a state whose solar radiation condition is inferior to the module used in the standard state.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a structure of a thin-film solar cell module.

[0002]

2. Description of the Related Art At present, research and development of clean energy are being promoted from the standpoint of environmental protection. Above all, solar cells are attracting attention because of their infinite resources (solar rays) and no pollution. A typical example of a solar cell (photoelectric conversion device) in which a plurality of solar cell elements formed on the same substrate are connected in series is a thin-film solar cell.

Thin-film solar cells are considered to be the mainstream of solar cells in the future because of their thinness, light weight, low production cost, and easy area enlargement. Demand is expanding for business use and general residential use, which are used for such purposes.

Conventional thin-film solar cells use a glass substrate, but research and development of a flexible solar cell using a plastic film has been advanced in terms of weight reduction, workability, and mass productivity. Further, a device using a film substrate insulated from a flexible metal material has been developed. Taking advantage of this flexibility, mass production has become possible by roll-to-roll or stepping roll manufacturing methods.

[0005] The above-mentioned thin-film solar cell has a photoelectric conversion element (a first electrode layer composed of a metal electrode layer, a photoelectric conversion layer composed of a thin film semiconductor layer, and a transparent electrode layer laminated on a flexible electrically insulating film substrate). Or a plurality of cells). The electrical connection between the first electrode layer of a certain photoelectric conversion element and the adjacent transparent electrode layer is repeated, so that the first electrode layer of the first photoelectric conversion element and the transparent electrode layer of the last photoelectric conversion element are required. Voltage can be output. For example, in order to obtain an AC of 100 V as a commercial power source by converting into an AC by an inverter, the output voltage of the thin-film solar cell is desirably 100 V or more, and actually several tens or more elements are connected in series.

[0006] Such a photoelectric conversion element and its serial connection are formed by forming an electrode layer and a photoelectric conversion layer, patterning each layer, and combining them. An example of the configuration and the manufacturing method of the solar cell is disclosed in, for example,
No. 0-233517 and Japanese Patent Application No. 11-19306.

FIG. 5 is a simplified perspective view of the structure of the thin-film solar cell described in the above publication. In FIG. 5, the unit photoelectric conversion element 62 formed on the front surface of the substrate 61 and the connection electrode layer (metal electrode layer) 63 formed on the back surface of the substrate 61 are completely separated into a plurality of unit units, respectively, and are separated from each other. Are shifted. For this reason, the current generated in the photoelectric conversion layer 65, which is the amorphous semiconductor portion of the element 62, is first collected in the transparent electrode layer 66, and then through the current collecting hole 67 formed in the transparent electrode layer region, the current on the rear surface is collected. Through the connection electrode layer 63, further through the connection hole 68 for series connection formed outside the transparent electrode layer region of the device in the connection electrode layer region, outside the transparent electrode layer region of the device adjacent to the device. The extended lower electrode layer 64 is reached, and the two devices are connected in series.

FIG. 4 shows a series-connected thin film solar cell of a type using a conventional glass substrate different from the above, FIG. 4 (a) is a plan view of the thin film solar cell surface on the non-light receiving surface side,
(B) is a sectional view, and (c) is an electric circuit diagram.

The glass substrate 1 has transparent electrode layers u1, u2,
, the photoelectric conversion layers s1, s2, s3, and the metal electrode layers e1, e2, e3,... are laminated to form a thin-film solar cell element. The outline of the manufacturing method is described below.

First, a transparent electrode layer u is formed on the substrate 1 by a thermal CVD method, and is patterned into a predetermined number of divisions by a laser processing method. At the same time, the thin-film solar cell and its periphery are also electrically separated.

Next, a photovoltaic layer s made of a-Si is formed by a plasma CVD method and is parallel to the patterning line of the transparent electrode layer u in a direction orthogonal to the serial direction of the thin-film solar cell. Laser processing.

Next, the metal electrode layer e is formed by sputtering, and the metal electrode layer e is laid parallel to the patterning line of the photoelectric conversion layer s.
In addition to the processing, the thin film solar cell and its periphery are electrically separated.

As a result of the above steps, the transparent electrode layer u1, the photoelectric conversion layer s1, the metal electrode layer e1-the transparent electrode layer u2, the photoelectric conversion layer s2, the metal electrode layer e2-the transparent electrode layer u3, the photoelectric conversion layer s3, the metal The series connection of the thin-film solar cell elements in the order of the electrode layer e3 is completed.

A plurality of solar cell units connected in series as described above are further formed into a panel shape to form a thin-film solar cell module, which is installed on a roof or a wall of a building or on a pedestal provided on the ground.

In the above conventional series-connected thin film solar cell,
The standard solar radiation intensity (1 kWm ^-2)
In order to maximize the conversion efficiency,
Width W is optimized. The reason is as shown in FIG.
Series resistance of a series-connected thin-film solar cell in a circuit diagram
(Rs) and the parallel resistance component (Rsh)
And the loss at the series connection
Uses unit width with small loss as the optimal pattern width
Because they do.

By the way, the above-mentioned standard state means a state in which the front surface of the battery where sunlight enters the thin-film solar cell is transparent and the sunlight enters the main surface of the thin-film solar cell in the normal direction. I do. In order to maximize the photoelectric conversion efficiency of the solar cell module, it is ideal to install the module so that sunlight enters the normal direction to the main surface of the thin film solar cell. The incident angle of light differs depending on the season, time, installation location, and the like. From the viewpoint of cost, it is usually difficult to track the movement of the sun. Therefore, in Japan, for example, the sun is usually set at a mid-south solar altitude (about 30 to 40 degrees) near the winter solstice point. Adapted and fixed modules are installed so that the maximum photovoltaic output can be obtained almost mid-south, so that effective output can be obtained throughout the year.

[0017]

In a conventional thin-film solar cell having a unit cell width, when the solar radiation intensity is weaker than the standard state, the loss of the series resistance (Rs) decreases and the parallel resistance (Rsh) decreases. , The balance between the series resistance component and the parallel resistance component is lost, and the photoelectric conversion efficiency of the solar cell is reduced. Therefore, in a series-connected thin-film solar cell module that is used in a state other than the standard state due to the configuration and installation conditions of the solar cell, the pattern width optimized based on the solar radiation intensity in the standard state will result in a loss of power generation of the solar cell. Becomes large.

Particularly, in a solar cell module installed on a vertical wall surface or a northern slope, or a solar cell module in which a color filter is attached to the surface of a solar cell for aesthetic reasons,
In the steady state, since the amount of incident light is smaller than that in the standard state, there is a problem that the conversion efficiency of the solar cell is reduced.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to install the filter on a vertical wall surface or a northern slope, or to attach a color filter to the surface of a solar cell for aesthetic purposes. An object of the present invention is to provide a thin-film solar cell module that optimizes photoelectric conversion efficiency in a solar cell module used in a state other than the standard state.

[0020]

According to the present invention, there is provided a thin-film solar cell comprising a transparent electrode layer, a photovoltaic layer, and a metal electrode layer on an electrically insulating substrate surface. A thin-film solar cell module formed by forming a plurality of units and connecting these thin-film solar cell units in series. The thin-film solar cell used in a state other than the standard state depending on the configuration and installation conditions of the solar cell module. In the battery module, in order to maximize the efficiency ratio of the photoelectric conversion efficiency of the solar cell module in the use state, the thin film solar cell unit is used in a state where the solar radiation condition is lower than the module used in the standard state. It is assumed that the cell width is large (claim 1).

According to an embodiment of the present invention, the thin-film solar cell module used in a state other than the standard state is a module in which a color filter is provided on a sunlight incident surface for aesthetic purposes (claim 2). The thin-film solar cell module used in a state other than the standard state is a module that is used by being attached to a vertical surface.

According to the present invention, as described later, a decrease in the conversion efficiency of the thin-film solar cell due to a decrease in the solar radiation intensity is prevented.
Power generation efficiency can be improved.

[0023]

Embodiments of the present invention will be described below with reference to the drawings.

Example 1 FIG. 1 shows the relationship between the unit cell width and the conversion efficiency ratio of a solar cell when the solar radiation intensity was changed.

As can be seen from this figure, the optimum solar radiation intensity is obtained when the unit cell width W is 12 to 13 mm. However, since the generated current decreases as the solar radiation intensity decreases, the conversion efficiency loss due to the series resistance (Rs) decreases, and the leakage current (parallel resistance (Rsh)) decreases.
, The conversion efficiency loss increases. As a result, the optimal unit cell width shifts in a wider direction as the solar radiation intensity decreases.

In Example 1, a-Si / a-Si
Using a two-layer tandem cell having a Ge structure, a thin film solar cell having three types of color filters of blue, green, and red having the spectral transmittance characteristics shown in FIG. The short circuit current densities were compared.

As a result, the reduction in short-circuit current density due to the attachment of the filter was about 21% for blue, about 22% for green, and about 54% for red.

From this result, the optimum value of the unit width when the blue and green filters are inserted is approximately 3 mm longer than that without the filter in the efficiency ratio curve of 0.8 KWm- ² in FIG. And 15 mm. In addition, the optimum width of the unit cell when the red filter is inserted is approximately ^{2 in} the efficiency ratio curve of 0.5 KWm- ² in FIG.
It should be 0 mm and about 8 mm longer. As described above, in the red filter, by increasing the unit cell width, about 1 unit is obtained.
% Efficiency could be improved.

The explanation of the above-mentioned optimization in FIG. 1 is, of course, the case where sunlight having a standard solar radiation intensity is incident. Actually, the standard solar radiation intensity cannot be obtained, or the incident angle of the sunlight depending on the season. , The optimum cell width varies every moment. However, considering the average, if a color filter is attached to the light incident surface of the solar cell, it is difficult to obtain the standard solar radiation intensity,
Based on the maximum solar radiation intensity when the filter is attached,
By optimizing the unit cell width, the solar cell conversion efficiency can be increased.

(Embodiment 2) FIG. 3 shows the dependence of the amount of incident light on the mounting angle of a solar cell. In the case of a vertical wall, the lower the solar altitude, the smaller this mounting angle will be. Considering that the minimum mounting angle is about 30 to 40 degrees of the solar altitude near the winter solstice, the incident light amount is about 0.8
It turns out that.

When this is applied to FIG.
It can be said that it is equivalent to 8 kWm ^-2 . Therefore, when a series-connected thin-film solar cell is mounted on a vertical wall, the unit width should be designed so as to be optimal at a solar radiation intensity of 0.8 kWm- ² .

The optimum value of the unit width at a solar radiation intensity of 0.8 kWm- ² is 15 mm from FIG.

[0033]

According to the present invention, as described above, a plurality of thin film solar cell units having a transparent electrode layer, a photovoltaic layer and a metal electrode layer are formed on the surface of an electrically insulating substrate. Thin-film solar cell module in which thin-film solar cell units are connected in series, for example, a solar cell module installed on a vertical wall surface or a northern slope, or a solar cell on which a color filter is attached to the surface of a solar cell for aesthetic purposes In order to maximize the efficiency ratio of the photoelectric conversion efficiency of the solar cell module in the use state in a thin film solar cell module used in a state other than the standard state depending on the configuration and installation conditions of the solar cell module such as a battery module In addition, thin-film solar cell unit modules are more likely to be used under conditions of poor solar radiation than modules used under standard conditions. The width is large. Thereby, in the thin-film solar cell module used in a state other than the standard state, it is possible to prevent a decrease in the conversion efficiency of the thin-film solar cell due to a decrease in the solar radiation intensity, and to improve the power generation efficiency.

[Brief description of the drawings]

FIG. 1 is a diagram showing a relationship between a unit cell width and a conversion efficiency ratio of a thin-film solar cell module according to the present invention.

FIG. 2 is a diagram showing a spectral transmittance of a color filter of the thin-film solar cell module according to the present invention.

FIG. 3 is a diagram showing the relationship between the mounting angle of the thin-film solar cell module according to the present invention and the amount of incident light.

FIG. 4 is a diagram showing a schematic configuration and an electric circuit of a conventional glass substrate type thin film solar cell.

FIG. 5 is a perspective view showing a schematic configuration of a different conventional thin film solar cell.

[Explanation of symbols]

1: substrate, e1, e2, e3: metal electrode layer, s1, s
2, s3: photoelectric conversion layer, u1, u2, u3: transparent electrode layer, W: unit cell width.

Claims (3)

[Claims] 1. A thin film solar cell unit having a transparent electrode layer, a photovoltaic layer, and a metal electrode layer is formed on a surface of an electrically insulating substrate, and these thin film solar cell units are connected in series. A thin-film solar cell module that is used in a state other than the standard state due to the configuration and installation conditions of the solar cell module, the efficiency ratio of the photoelectric conversion efficiency of the solar cell module in the use state A thin-film solar cell module characterized in that a thin-film solar cell unit cell width is larger in a module used in a condition with poorer solar radiation conditions than a module used in a standard state in order to maximize the following. 2. The thin-film solar cell module according to claim 1, wherein the thin-film solar cell module used in a state other than the standard state is a module provided with a color filter on a sunlight incident surface. Thin film solar cell module. 3. The thin-film solar cell module according to claim 1, wherein the thin-film solar cell module used in a state other than the standard state is a module mounted and used on a vertical surface. Solar cell module.