JP2006216608A - Solar battery module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To manufacture a solar battery module for low voltages having improved power generation characteristics at low costs. <P>SOLUTION: The solar battery module 10 has 32 unit cells 14. Eight unit cells 14 are electrically connected in series, thus composing a first cell row 16 and a second cell row 18. Then, the anode of the first cell row 16 serves also as that of the second cell row 18 on the right, and the cathode of the second cell row 18 also serves as that of the first cell row 16 on the right. In this case, the first cell row 16 and the second cell row 18 are all connected in parallel, and a wire 20 for the cathode and a wire 22 for the anode of the first cell row 16 and the second cell row 18 are electrically connected to a terminal box 32 on the back via one end surface and the other end surface of a glass substrate 24, respectively. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a solar cell module provided by connecting a plurality of unit cells electrically in series with each other.

  A chalcopyrite solar cell is a solar cell comprising a chalcopyrite compound (hereinafter also referred to as CIGS) expressed as Cu (InGa) Se as a light absorption layer, and has high energy conversion efficiency, and is hardly deteriorated by aging. It has attracted particular attention because it has various advantages such as no occurrence, excellent radiation resistance, a wide light absorption wavelength region, and a large light absorption coefficient.

The unit cell of this kind of chalcopyrite solar cell includes, for example, a first electrode layer made of Mo, a light absorption layer made of CIGS, a buffer layer, a high resistance layer (semi-insulating layer), and a transparent first layer made of ZnO / Al. An antireflection layer for preventing light incident on the two-electrode layer and the light absorption layer from being reflected and leaking to the outside is formed on the glass substrate in this order. Here, each of the buffer layer, the high resistance layer, and the antireflection layer is made of, for example, CdS, ZnO, or MgF ₂ . As the material of the buffer layer, ZnO or InS may be selected.

  The unit cells are electrically connected in series with each other and arranged in parallel, and as shown in FIG. 4, the unit cells are sealed in a state of being arranged in the casing 1 with a resin material (not shown). Thereby, the solar cell module 2 is formed.

  Note that the unit cell 3 is manufactured by appropriately performing division by scribing after providing each layer described above. That is, the dimension in the width direction of the unit cell 3 is determined by setting a scribe interval.

  Further, the cathode wiring 4 is drawn out from the unit cell 3a arranged at one end, while the anode wiring 5 is drawn out from the unit cell 3b arranged at the other end. As shown in FIG. 5, these wirings 4 and 5 are provided over the entire longitudinal direction X of the main surface of the glass substrate, wrap around the back surface along the thickness direction, and further to the terminal box 6 provided on the back surface. Extend.

  In the solar cell module 2 configured as described above, as indicated by i in FIG. 4, a current flows from left to right in FIG. 4, that is, from the cathode to the anode.

JP-A-11-31815 JP 2004-115356 A

  The voltage required for the solar cell module is determined by the input voltage specification of the power conditioner. Usually, since the input voltage specification of the power conditioner used as an alternative to the commercial power supply is 250 to 300 V, a voltage value as high as possible is required for one solar cell module. However, a low voltage electromotive force of about 12 V may be required depending on the application, such as when the commercial power source is not substituted.

  It is recalled that the number of unit cells is reduced in order to reduce the electromotive force. However, in this case, there is an inconvenience that a linear correlation is not recognized between the number of unit cells and the power generation characteristics of the solar cell module. That is, for example, when trying to produce a solar cell module whose electromotive force is 1/4 of the solar cell module 2 shown in FIG. 4, the number of unit cells 3 cannot be reduced to 1/4, and more It is necessary to. In other words, if the number of unit cells is reduced, the power generation characteristics of the solar cell module will be lower than the estimated performance.

  Moreover, a solar cell module with a reduced number of unit cells cannot be manufactured with the same equipment and process as a normal solar cell module. That is, it is necessary to separately provide equipment for manufacturing a low-voltage solar cell module, which increases the capital investment.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a solar cell module that exhibits sufficient power generation characteristics without increasing capital investment.

In order to achieve the above object, a solar cell module according to the present invention includes at least a first electrode layer, a p-type light absorption layer made of a chalcopyrite compound, and a transparent and n-type second electrode layer. A first cell row and a second cell row in which a plurality of cells are electrically connected in series are alternately provided on the main surface of the same substrate,
A connection terminal for electrically connecting an external load is disposed on the back surface of the substrate,
Adjacent cell rows of the first cell row and the second cell row share a cathode or an anode,
The cathode electrode wirings of the first cell row and the second cell row extend from the main surface of the substrate to the back surface via one end of the substrate and are electrically connected to the connection terminal. And
The anode electrode wirings of the first cell row and the second cell row extend from the main surface of the substrate to the back surface via the other end portion facing the one end portion and to the connection terminal. Electrically connected,
The first cell row and the second cell row are electrically connected in parallel.

  In the present invention, cell rows in which currents flow in opposite directions are provided, and the cell rows are electrically connected in parallel. Therefore, it is not necessary to reduce the number of cell rows when producing a low-voltage solar cell module, so that existing equipment can be used. Therefore, no new capital investment is required.

  Moreover, since the cell rows are electrically connected in parallel, the electromotive force of the entire solar cell module is equal to the electromotive force of one cell row. That is, with the above configuration, a low voltage solar cell module can be obtained at low cost.

  Furthermore, the solar cell module having such a configuration exhibits excellent power generation characteristics because the number of unit cells is large.

  In addition, since the cathode wiring and the anode wiring are extended to the back surface via different end faces, it is possible to avoid a short circuit between the cathode and the anode.

  According to the present invention, since the cell rows in which currents flow in opposite directions are provided and these cell rows are connected in parallel, a low voltage solar cell module can be obtained without reducing the number of cell rows. Can be configured. Moreover, this solar cell module exhibits excellent power generation characteristics.

  And since it is not necessary to reduce the number of cell rows, a solar cell module can be produced using existing equipment. In other words, since no new capital investment is required, the solar cell module can be manufactured at low cost.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of a solar cell module according to the present invention will be described and described in detail with reference to the accompanying drawings.

  FIG. 1 shows a schematic overall plan view of the solar cell module according to the present embodiment. In this case, in the solar cell module 10, 32 unit cells 14 are arranged adjacent to each other in the casing 12. Note that a resin (not shown) is molded in the casing 12, thereby protecting all the unit cells 14.

  Here, eight unit cells 14 are electrically connected in series to form a first cell row 16 and a second cell row 18. That is, in this solar cell module 10, there are two first cell rows 16 and two second cell rows 18, and the first cell row 16 and the second cell row 18 are arranged adjacent to each other. .

  On the left end and the right end of the first cell row 16, a cathode wiring 20 and an anode wiring 22 are provided over the entire vertical direction X, respectively, while on the left end and the right end of the second cell row 18, respectively. The anode wiring 22 and the cathode wiring 20 are provided over the entire vertical direction X. That is, the solar cell module 10 as a whole has a configuration in which three cathode wirings 20 and two anode wirings 22 are provided.

  FIG. 2 shows a longitudinal section in the vicinity of the central cathode wiring 20. In FIG. 2, the left side is the second cell row 18 and the right side is the first cell row 16.

  As shown in FIG. 2, the unit cell 14 is configured by laminating a metal electrode layer 26, a light absorption layer 28 made of CIGS, and a transparent electrode layer 30 made of so-called ITO on a glass substrate 24. In the same first cell row 16 or second cell row 18, the metal electrode layer 26 is in contact with the transparent electrode layer 30 of another unit cell 14 adjacent to an arbitrary unit cell 14, thereby adjacent units. The cells 14 and 14 are electrically connected directly.

  On the other hand, as understood from FIG. 2, the transparent electrode layer 30 in the unit cells 14 constituting the first cell row 16 and the transparent electrode layer 30 in the unit cells 14 constituting the second cell row 18 are the same. Therefore, the current flows from the left to the right in the first cell row 16 as shown by i in FIG. 1, and the second cell row 18. Then it flows from right to left. That is, the cathode of the second cell row 18 also serves as the cathode of the first cell row 16 on the right side of the second cell row 18. Similarly, the anode of the first cell row 16 also serves as the anode of the second cell row 18 on the right side of the first cell row 16 (see FIG. 1).

  The two first cell rows 16 and the two second cell rows 18 are all electrically connected in parallel. Specifically, as shown in FIG. 3, the three cathode wirings 20 extend to the back surface through the upper end surface of the glass substrate 24, and are combined into one bundled wire. It is electrically connected to a terminal box 32 installed in. On the other hand, the two anode wirings 22 exist on the back surface through the lower end surface of the glass substrate 24, and, like the cathode wiring 20, are bundled into one bundle wire and electrically connected to the terminal box 32. It is connected.

  In this way, by bringing the cathode wiring 20 and the anode wiring 22 from the other end surface to the back surface, it is possible to avoid contact between the wirings 20 and 22. Eventually, a short circuit between the cathode and the anode can be avoided.

  When the solar cell module 10 configured as described above is irradiated with light such as sunlight, a pair of electrons and holes is generated in the light absorption layer 28 of each unit cell 14. Electrons gather at the interface of the transparent electrode layer 30 (n-type side) at the junction interface between the light absorption layer 28 made of CIGS, which is a p-type semiconductor, and the transparent electrode layer 30, which is an n-type semiconductor. The holes gather at the interface of the light absorption layer 28 (p-type side). When this phenomenon occurs, an electromotive force is generated between the light absorption layer 28 and the transparent electrode layer 30. An external load (not shown) that is electrically connected to the terminal box 32 is energized using the electrical energy generated by the electromotive force as a source.

  At this time, since the unit cells 14 are connected in series in the first cell row 16 and the second cell row 18, the current flows from the cathode to the anode, and further from the cathode wiring 20 to the anode wiring 22. Flowing. That is, in FIG. 1, a current flows from the left to the right in the first cell row 16 and from the right to the left in the second cell row 18.

  During this time, the cathode wiring 20 and the anode wiring 22 extend to the back surface via another end face of the glass substrate 24, so that the cathode wiring 20 and the anode wiring 22 do not come into contact with each other. There is no short circuit between the anode and the cathode.

  Further, even if current flows through all of the first cell column 16 and the second cell column 18 in this way, as described above, in the present embodiment, all of these cell columns are connected in parallel. For this reason, the electromotive force of the whole solar cell module 10 is equal to the electromotive force of one cell row 16 (18).

  Thus, according to the present embodiment, the electromotive force can be reduced without reducing the number of unit cells 14. For this reason, it is possible to manufacture with the same installation as the solar cell module which electrically connects all the unit cells 14 in series. Therefore, the capital investment does not increase with the provision of the first cell row 16 and the second cell row 18.

  Further, since the number of unit cells 14 is not reduced, the power generation characteristics as the solar cell module 10 are also ensured.

  In the above-described embodiment, the unit cell 14 is configured by the metal electrode layer 26 (first electrode layer), the light absorption layer 28, and the transparent electrode layer 30 (second electrode layer). These layers may be added. For example, a buffer layer may be interposed between the light absorption layer 28 and the transparent electrode layer 30.

  Further, the number of unit cells 14 is not particularly limited to 32, and the number of first cell columns 16 and second cell columns 18 is not particularly limited to two. Furthermore, the first cell row 16 and the second cell row 18 do not have to be the same number.

It is a schematic whole plane explanatory drawing of the solar cell module which concerns on this Embodiment. It is a schematic longitudinal cross-section explanatory drawing of the center part vicinity in the solar cell module of FIG. It is a general | schematic whole top view which shows the back side of the solar cell module of FIG. It is a schematic whole plane explanatory drawing of the solar cell module which concerns on a prior art. It is a schematic whole top view which shows the back side of the solar cell module which concerns on a prior art.

Explanation of symbols

2, 10 ... solar cell module 3, 3a, 3b, 14 ... unit cell 16, 18 ... cell array 20 ... cathode wiring 22 ... anode wiring 26 ... metal electrode layer 28 ... light absorption layer 30 ... transparent electrode layer 32 ... Terminal box

Claims (1)

A first cell array in which a plurality of unit cells each including at least a first electrode layer, a p-type light absorption layer made of a chalcopyrite compound, and a second electrode layer that is transparent and n-type are electrically connected in series; Cell rows are alternately provided on the main surface of the same substrate,
A connection terminal for electrically connecting an external load is disposed on the back surface of the substrate,
Adjacent cell rows of the first cell row and the second cell row share a cathode or an anode,
The cathode electrode wirings of the first cell row and the second cell row extend from the main surface of the substrate to the back surface via one end of the substrate and are electrically connected to the connection terminal. And
The anode electrode wirings of the first cell row and the second cell row extend from the main surface of the substrate to the back surface via the other end portion facing the one end portion and to the connection terminal. Electrically connected,
The solar cell module, wherein the first cell row and the second cell row are electrically connected in parallel.

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