JP2009302561A - Solar battery module and solar battery array - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solar battery module that is for exhibiting a stable output characteristics and whose size is easily handled in construction while having a uniform configuration, and a solar battery array for expressing a stable output characteristics by adopting the same. <P>SOLUTION: The battery module 10 includes a battery panel 12 and its longitudinal length is 900 to 1,100 [mm]. The battery panel 12 is configured by connecting a number of battery cells 100 in series and its open voltage is set to 100 to 180 [V]. A battery cell 100 is belt-like and its short side length is 7 to 12 [mm], and is arranged in such a way that with a long side directing toward a transverse direction of the battery panel 12, and a short side directing toward a longitudinal direction of the battery panel 12, the cell runs parallel to the longitudinal direction of the battery panel. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a solar cell module for constituting a solar cell array installed in a house, and a solar cell array constituted by the solar cell module.

  In recent years, a photovoltaic power generation system that lays a solar cell module having a solar cell panel on a roof of a building to cover the power consumed by the building and sells surplus power to an electric power company has been increasing. A solar cell panel is an integrated solar cell, in which a conductive film or a semiconductor film is laminated on a glass substrate, and a plurality of grooves are provided on the glass substrate to form a predetermined number of unit cells (solar cell). Are electrically connected in series, and can obtain a voltage of 100 [V] or more. The following Patent Document 1 discloses a method for manufacturing such a solar cell panel.

  The solar cell module as described above can obtain a desired voltage by adjusting the number of solar cells connected in series. However, considering the convenience of laying and manufacturing, there is a limit to the size of the solar cell module, and there are certain limitations on the number of solar cells that can be connected in series in a single solar cell module and the output voltage. . Moreover, a single solar cell module does not have a large output current. Therefore, in the prior art, a plurality of solar cell blocks in which a plurality of solar cell modules are electrically connected in parallel are formed, and the solar cell blocks are connected in series with each other to form a solar cell array. The current is adjusted to a practical level.

  As described above, the solar cell modules are electrically connected in parallel to form the solar cell block, and when the solar cell array is configured using the solar cell block thus formed, the solar cell modules are connected in series. If the output of each solar cell module is approximately the same, even if some of the solar cell modules are installed in the shade and the output is reduced, the output of the entire solar cell array is not so much reduced.

Japanese Patent Laid-Open No. 11-298017

  Here, when the solar cell array is configured with the connection structure as described above, the output performance of each solar cell module is similar to the case where the output is reduced due to some solar cell modules being installed in the shade. Even if there is an individual difference, if the output of each solar cell block is approximately the same, the output of the solar cell array as a whole does not decrease so much. However, when various conditions such as variations in the output performance of the solar cell module and the sunlight conditions at the installation site act in combination, the output characteristics between the solar cell blocks vary, and the solar cell operating normally There was a problem that the output of the module could not be used effectively, and the output of the entire solar cell array could not be expected. For this reason, considering that the unexpected decrease in output occurs temporarily due to the installation of the solar cell module in the shade, there is a desire to minimize individual differences in the output performance of the solar cell module. was there. On the other hand, considering the ease of laying and manufacturing in buildings, it is not realistic to fine-tune output performance by changing the structure and size of each solar cell module, and the structure is uniform. Therefore, it has been desired to provide a solar cell module having a size that can be easily routed when laid.

  Therefore, the present invention employs a solar cell module having a uniform configuration and capable of exhibiting stable output characteristics and having a size that can be easily handled when laid, and the solar cell module. An object of the present invention is to provide a solar cell array capable of exhibiting stable output characteristics.

  The present invention provided to solve the above-described problems is a solar cell formed by electrically connecting a plurality of solar cell blocks formed by electrically connecting a plurality of solar cell modules in parallel. This is a solar cell module for array configuration. The solar cell module of the present invention has a length in the longitudinal direction of 900 to 1100 [mm], and includes a solar cell panel formed in a substantially rectangular plane shape, and the longitudinal direction of the solar cell panel is a row direction of a house. The solar cell panel is installed so that the short direction of the solar cell panel faces the ridge line direction of the house. Moreover, the solar cell of the present invention is such that the solar cell panel has a plurality of solar cells, and the solar cells are electrically connected in series so that the open circuit voltage is 100 to 180 [V]. The solar battery cell has a band shape and a short side length of 7 to 12 [mm], the long side faces in the short direction of the solar battery panel, and the short side in the long side direction of the solar battery panel. The solar cell panel is provided so as to be aligned in the longitudinal direction of the solar cell panel with the sides facing (Claim 1).

  The solar cell module of the present invention has a length in the longitudinal direction of 900 to 1100 [mm], and can be easily carried and installed in a place where the workability of laying work such as a roof of a building is poor. . Moreover, since the length in the longitudinal direction of the solar cell module of the present invention is about twice as large as a commonly used roof tile, the work efficiency is not so different from that of the roof tile. Can be installed.

  The solar battery panel constituting the solar battery module of the present invention has a width of 7 to 12 [mm] and a plurality of strip-like solar battery cells electrically connected in series, and the solar battery cell is the solar battery. They are arranged in the longitudinal direction of the panel, and the configuration is uniform. Moreover, the solar cell module of this invention can suppress the variation in output to the minimum by employ | adopting the above-mentioned uniform structure. Furthermore, since the open voltage of the solar cell panel which comprises the solar cell module of this invention is 100-180 [V], while connecting this electrically in parallel and forming a solar cell block, solar cell blocks Are connected in series, a solar cell array capable of outputting at a voltage suitable for input to devices such as a conventionally known AC power conditioner can be constructed.

  In the solar cell module of the present invention, the solar cell in a state where the long side of the solar cell faces in the short direction of the solar cell panel and the short side of the solar cell faces in the longitudinal direction of the solar cell panel. The cells are provided so as to be arranged in the longitudinal direction of the solar battery panel. Moreover, the solar cell module of the present invention is installed in such a posture that the longitudinal direction of the solar cell panel is directed to the row direction of the house, and the short side direction of the solar cell panel is directed to the row direction of the house. Here, when installing solar cell modules in a house in the same manner as roofing tiles, depending on the sunshine conditions, other solar cell modules may be shaded on the upper side in the building direction, or on the lower side in the building direction May overlap with other solar cell modules to form a portion that does not generate power, or a portion where the output is greatly reduced, resulting in electrical resistance. However, even if such a portion is formed, each solar cell normally functions in other portions, and all the solar cells can be maintained in an electrically conductive state. Therefore, according to the solar cell module of the present invention, even if the output may be reduced due to the influence of the sunshine condition, the influence on the output reduction of the entire solar cell array can be suppressed to the minimum.

  As for the solar cell module of this invention mentioned above, it is desirable for the open circuit voltage of a photovoltaic cell to be 1.2-1.5 [V] (Claim 2).

  According to such a configuration, it is possible to provide a solar cell module capable of outputting an open circuit voltage required for constructing a solar cell array.

  Moreover, as for the solar cell module of this invention mentioned above, it is desirable for the length of a transversal direction to be 240-480 [mm] (Claim 3).

  According to such a configuration, it is possible to provide a solar cell module that can be installed instead of the roof tiles that have been conventionally sown in a house.

  In the solar cell module of the present invention described above, the solar cell may be a tandem type.

  According to such a configuration, it is possible to provide a solar cell module that can effectively use the energy of incident light as much as possible and has high energy conversion efficiency.

In the above-described solar cell module of the present invention, the short-circuit current value of the solar cell panel is preferably 9 to 15 [mA / cm ² ] (Claim 5).

  Here, in the solar cell module in which a large number of solar cells are connected in series as described above, when a part of a specific solar cell does not generate power due to being shaded, the electrical resistance of the part increases. A phenomenon that generates heat (hot spot phenomenon) may occur. When the hot spot phenomenon occurs, there is a possibility that the solar cell module is deteriorated or damaged. When such a phenomenon occurs, the output specific to the solar cell module is reduced later, resulting in variations in the output of each solar cell module constituting the solar cell array or solar cell block. There is a possibility that some of the generated electric energy cannot be used effectively.

  Therefore, based on such knowledge, the solar cell module of the present invention described above has an effective power generation region in which the solar cell generates power by receiving light, extends in the longitudinal direction of the solar cell module, and the effective power generation of the solar cell. It is desirable that one or more dividing lines for dividing the region are provided.

  According to such a configuration, even if a part of a specific solar battery cell is shaded and no longer generates power, extremely high power does not act on the part, and the solar battery module is deteriorated due to a hot spot phenomenon. And avoid damage. Therefore, according to the above-described configuration, it is possible to minimize the occurrence of individual differences in the output performance of each solar cell module due to the hot spot phenomenon after the solar cell array is laid.

  The solar cell array of the present invention is formed by serially connecting two solar cell blocks formed by electrically connecting a plurality of the solar cell modules of the present invention described above in parallel (claims). Item 7).

  In this invention, since the solar cell module of this invention mentioned above is employ | adopted, the individual difference about the output characteristic for every solar cell module is small. Moreover, since the solar cell array of the present invention is formed by connecting a plurality of solar cell blocks by connecting solar cell modules in parallel and connecting them in series, the output of some of the solar cell modules was temporarily reduced. However, energy loss due to this can be minimized and stable output characteristics can be exhibited.

  In the solar cell array of the present invention described above, the solar cell block is preferably formed by electrically connecting 20 or more solar cell modules in parallel.

  Also, a solar cell module laying structure in which a solar cell module that is substantially rectangular and has a plurality of solar cells formed therein to constitute a single solar cell as a whole, is laid on the structure. The solar cell module has two sets of connectors, each of which has two or more independent terminals, and each of the two sets of connectors extends from the longitudinal center of the solar cell module. Connected to a cable having two or more conductors, and one terminal of each connector is connected to the positive electrode of the solar cell, and the other terminal of each connector is connected to the negative electrode of the solar cell. The cable connected to one connector of the pair of connectors is shorter than the cable connected to the other connector, and the cable length relationship is as follows. When the modules are arranged in a row, the connectors to which short cables are connected are in an insufficient length and cannot be connected, and the solar cell modules are arranged in a row on the structure. The connector of the adjacent solar cell module is joined to the connector to which the long cable is connected and the connector to which the short cable is connected, and in the state where both are joined, the positive side terminals of both connectors are connected to each other. It is also possible to have a configuration in which a plurality of solar cell modules are electrically connected in parallel.

In the solar cell module laying structure described above, the connector of the adjacent solar cell module is joined to the connector to which the long cable is connected and the connector to which the short cable is connected. In the laying structure of the solar cell module described above, a state where the connector to which the long cable is connected and the connector to which the short cable is connected is joined is a regular joined state. In the laying structure described above, when the long cable connector and the short cable connector of the adjacent solar cell modules are joined in this way, the positive electrode side terminals and the negative electrode side terminals of both connectors are connected to each other, The solar cell modules are electrically connected in parallel.
Further, in the solar cell module laying structure described above, an operator does not erroneously connect the connector. In other words, in the solar cell module laying structure described above, since the length of the cable is long and short in this way, when the solar cell modules are arranged in a row, the connectors to which the short cables are connected are not sufficiently long. There is no connection. Therefore, when a solar cell module is laid on the roof or the like, short cables of adjacent solar cell modules cannot be physically connected to each other, and an operator does not erroneously connect the connectors.

  According to the present invention, by adopting a solar cell module having a uniform structure and capable of exhibiting stable output characteristics and having a size that can be easily handled when laid, and the solar cell module. A solar cell array capable of exhibiting stable output characteristics can be provided.

It is a perspective view which shows the solar cell module which concerns on one Embodiment of this invention. It is a perspective view which shows the structure of the back surface side of the solar cell module of FIG. It is sectional drawing of the solar cell panel employ | adopted with the solar cell module shown in FIG. It is sectional drawing of the connector of the solar cell module of FIG. It is a flowchart which shows the work procedure of the laying structure of a solar cell module. It is explanatory drawing which shows the state which laid the solar cell module on the roof of a building. It is a conceptual diagram which shows the module stage to which the solar cell module was correctly wired. It is a conceptual diagram which shows the module stage to which the solar cell module was wired accidentally. It is a circuit diagram when a solar cell module is correctly wired. It is a conceptual diagram which shows a solar cell array. (A) is a front view of a lead-in cable, (b) is sectional drawing of the mold part of a lead-in cable. It is a top view of a terminal protection member. (A) is a top view of the connector whose both poles are male pieces, (b) is a top view of the connector whose both poles are female pieces. It is a perspective view which shows the modification of the solar cell module shown in FIG.

  Next, the solar cell module 10 and the solar cell array 1 according to an embodiment of the present invention will be described in detail with reference to the drawings. The solar cell module 10 (hereinafter also simply referred to as the battery module 10) is laid in place of tiles on the roof R of a new or existing building. As shown in FIGS. 1 and 2, the battery module 10 includes a solar battery panel 12 (hereinafter also simply referred to as a battery panel 12), a terminal box 14 attached to the back surface of the battery panel 12, and an extension from the terminal box 14. Two first cables 16 and second cables 18, and a first connector 20 (hereinafter also referred to as a connector 20) and a second connector 22 (hereinafter also referred to as a connector 22) connected to each of them. I have.

  The battery module 10 is formed in a substantially rectangular surface as shown in FIGS. 1 and 2. In the battery module 10, the battery panel 12 occupies most of the area exposed to the outside when laid. Therefore, the size of the battery module 10 is approximately the same as the battery panel 12 or slightly larger than the battery panel 12. The battery module 10 of the present embodiment has a length L1 in the longitudinal direction smaller than 1200 [mm] in consideration of securing workability of installation work in a house while securing output. In the present embodiment, the length L1 is set in the range of 900 to 1100 [mm] in consideration of the interval between general scaffolds installed at the time of laying the battery module 10 and the ease of handling by the construction worker. ing. In addition, the battery module 10 has a length L2 in the short direction of 240 to 480 [mm] in consideration of the size of a general flat roof tile. In the present embodiment, the length L2 is set to 280 in consideration of improving the photoelectric conversion efficiency by minimizing the shaded portion due to the sunshine condition while being approximately the same as the working width of a general flat roof tile. It is adjusted within the range of ~ 360 [mm].

  The battery panel 12 is formed in a substantially rectangular surface as shown in FIGS. 1 and 2. The battery panel 12 is laid in such a posture that the longitudinal direction is directed to the row direction of the house and the short side direction is directed to the ridge direction of the house. The battery panel 12 is formed by arranging a large number of strip-shaped solar cells 100 (hereinafter also simply referred to as battery cells 100) in the longitudinal direction so as to be electrically connected in series. A voltage of 100 [V] can be obtained.

  The battery panel 12 is a so-called tandem solar cell in which two or more types of photoelectric conversion layers are combined, and has high photoelectric conversion efficiency. In the present embodiment, a hybrid solar cell that is a tandem system is adopted as the battery panel 12. More specifically, as shown in FIG. 3, the battery panel 12 includes a transparent front electrode layer 104, first and second thin film photoelectric conversion units 106 a and 106 b (hereinafter referred to as amorphous materials) on a transparent substrate 102. This is a so-called hybrid solar cell having a structure in which a metal back electrode layer 108, a sealing resin layer 110, and an organic protective layer 112 are sequentially laminated. The transparent substrate 102 is formed of a light-transmitting material such as a glass plate or a transparent resin film, and constitutes a surface that is located closest to the light incident side when the battery module 10 is installed.

The transparent front electrode layer 104 is a single-layer or multilayer structure formed at a position adjacent to the transparent substrate 102. The transparent front electrode layer 104 is formed by laminating transparent and conductive oxides such as an ITO film, SnO ₂ film, and ZnO film on the transparent substrate 102 in layers. The transparent front electrode layer 104 is formed using a conventionally known vapor deposition method, a CVD (Chemical Vapor Deposition) method, an EVD (Electrochemical Vapor Deposition) method, a vapor deposition method represented by a sputtering method, or the like.

  The thin film photoelectric conversion unit 106a includes an amorphous photoelectric conversion layer, and is provided at a position adjacent to the above-described transparent front electrode layer 104 in the light incident direction (upward in FIG. 3). The thin film photoelectric conversion unit 106a can have a structure in which, for example, a p-type silicon-based semiconductor layer, an i-type silicon-based amorphous photoelectric conversion layer, and an n-type silicon-based semiconductor layer are sequentially stacked from the transparent front electrode layer 104 side. . These p-type silicon-based semiconductor layer, i-type silicon-based amorphous photoelectric conversion layer, and n-type silicon-based semiconductor layer are also formed by an appropriate method such as a plasma CVD method in the same manner as the transparent front electrode layer 104 described above. can do. The thin film photoelectric conversion unit 106a preferably has a thickness of 0.01 μm to 0.5 μm, and more preferably has a thickness of 0.1 μm to 0.3 μm.

  The thin film photoelectric conversion unit 106b includes a crystalline photoelectric conversion layer, and is adjacent to the above-described thin film photoelectric conversion unit 106a in the light incident direction. The thin film photoelectric conversion unit 106b can have a structure in which, for example, a p-type silicon-based semiconductor layer, an i-type silicon-based crystalline photoelectric conversion layer, and an n-type silicon-based semiconductor layer are sequentially stacked from the thin film photoelectric conversion unit 106a side. Similarly to the thin film photoelectric conversion unit 106a, the p-type silicon-based semiconductor layer, the i-type silicon-based crystalline photoelectric conversion layer, and the n-type silicon-based semiconductor layer constituting the thin film photoelectric conversion unit 106b are all formed by plasma CVD. It can be formed by a method or the like.

  Here, the crystalline photoelectric conversion layer constituting the thin film photoelectric conversion unit 106b has a smaller number of light absorption systems than the amorphous photoelectric conversion layer constituting the thin film photoelectric conversion unit 106a described above. Therefore, the thickness of the crystalline thin film photoelectric conversion unit 106b is preferably about several to ten times the thickness of the amorphous thin film photoelectric conversion unit 106a. More specifically, the thin film photoelectric conversion unit 106b preferably has a thickness of 0.1 μm to 10 μm, and more preferably has a thickness of 0.1 μm to 5 μm.

  The p-type semiconductor layers constituting the photoelectric conversion units 106a and 106b described above are formed, for example, by doping silicon or a silicon alloy such as silicon carbide or silicon germanium with p-conductivity determining impurity atoms such as boron or aluminum. be able to. The amorphous photoelectric conversion layer and the crystalline photoelectric conversion layer can be formed of an amorphous silicon semiconductor material and a crystalline silicon semiconductor material, respectively. Specifically, the amorphous photoelectric conversion layer and the crystalline photoelectric conversion layer can be formed of intrinsic semiconductor silicon (such as silicon hydride), silicon alloy such as silicon carbide and silicon germanium, or the like. The amorphous photoelectric conversion layer and the crystalline photoelectric conversion layer may have any photoelectric conversion function. For example, a weak p-type or weak n-type silicon-based semiconductor material containing a small amount of conductivity-type determining impurities. It is also possible to configure using The n-type semiconductor layer of the amorphous photoelectric conversion layer or the crystalline photoelectric conversion layer is formed by doping silicon or a silicon alloy such as silicon carbide or silicon germanium with an n-conductivity determining impurity atom such as phosphorus or nitrogen. be able to.

  Further, the above-described thin film photoelectric conversion units 106a and 106b have different absorption wavelength ranges. Specifically, when the photoelectric conversion layer of the thin film photoelectric conversion unit 106a is made of amorphous silicon, the light component of about 550 nm can be absorbed most efficiently, whereas the thin film photoelectric conversion unit 106b When the photoelectric conversion layer is made of crystalline silicon, a light component of about 900 nm can be absorbed most efficiently.

  The metal back electrode layer 108 is provided at a position adjacent to the thin film photoelectric conversion unit 106b in the traveling direction of incident light. The metal back electrode layer 108 is made of silver, aluminum, or the like, and is a layer formed to a thickness of about 200 nm to 400 nm by a conventionally known vapor deposition method, sputtering method, or the like. A transparent conductive thin film (not shown) made of a non-metallic material such as ZnO is appropriately disposed between the metal back electrode layer 108 and the thin film photoelectric conversion unit 106b in consideration of improvement in adhesion between them. Can be provided. In addition to the function as an electrode of the battery panel 12, the metal back electrode layer 108 reflects light incident from the transparent substrate 102 and passing through the thin film photoelectric conversion units 106a and 106b, and enters the thin film photoelectric conversion units 106a and 106b. It also has a function as a reflective layer for re-incidence.

  In the battery module 10, the organic protective layer 112 is interposed via the sealing resin layer 110 at a position adjacent to the metal back electrode layer 108 described above in the traveling direction of incident light, that is, a position on the back side when installed in a house or the like. Is formed. The sealing resin layer 110 is a layer that bonds the organic protective layer 112 and the metal back electrode layer 108, for example, EVA (ethylene / vinyl acetate copolymer), PVB (polyvinyl butyral), PIB (polyisobutylene). And silicone resin. The organic protective layer 112 is a layer that seals the back side of the battery module 10. The organic protective layer 112 is, for example, a fluororesin film such as a polyvinyl fluoride film, an insulating film excellent in moisture resistance and water resistance, such as a film made of PET (polyethylene terephthalate), or a laminate of these. A structure in which a metal foil made of aluminum or the like is sandwiched between these films can be suitably employed.

  As shown in FIG. 3, the battery module 10 includes a plurality of batteries by dividing the thin film formed by stacking as described above into the first and second divided grooves 114 a and 114 b and the connection grooves 116. A cell 100 is formed. That is, the first and second divided grooves 114a and 114b and the connection groove 116 are formed between the adjacent battery cells 100 with the transparent front electrode layer 104, the thin film photoelectric conversion units 106a and 106b, the metal back electrode layer 108, and the like. It is provided so that the thin film to comprise may be divided | segmented. The first and second divided grooves 114a and 114b and the connection groove 116 are each linear and formed so as to extend in a direction perpendicular to the paper surface in FIG. ing. The first and second divided grooves 114a and 114b and the connection groove 116 are formed to be substantially parallel to each other.

  The first dividing groove 114 a is provided so as to divide the transparent front electrode layer 104 for each battery cell 100. The first dividing groove 114 a is an groove having an opening at the interface between the transparent front electrode layer 104 and the thin film photoelectric conversion unit 106 a and having the surface of the substrate 2 as a bottom surface. In the first dividing groove 114a, what constitutes the thin film photoelectric conversion unit 106a such as amorphous silicon is embedded. Therefore, the transparent front electrode layer 104 of the battery cell 100 is formed of the other battery cell 100 provided at a position adjacent to the longitudinal direction of the battery module 10 by amorphous silicon or the like embedded in the first dividing groove 114a. It is electrically insulated from the transparent front electrode layer 104.

  The second division groove 114 b is a groove that defines a boundary between adjacent battery cells 100. The second dividing groove 114b is provided at a position away from the first dividing groove 114a in the longitudinal direction of the battery module 10. The second dividing groove 114 b is formed to divide the thin film photoelectric conversion units 106 a and 106 b and the metal back electrode layer 108 for each battery cell 100. The second dividing groove 114 b has an opening at the interface between the metal back electrode layer 108 and the resin sealing layer 6, and the surface of the transparent front electrode layer 104 is the bottom surface. A resin constituting the sealing resin layer 110 such as the above-described EVA (ethylene / vinyl acetate copolymer) is embedded in the second dividing groove 114b. Therefore, the metal back electrode layer 108 of the battery cell 100 is electrically insulated from the metal back electrode layer 108 of another battery cell 100 provided at an adjacent position by the resin embedded in the second dividing groove 114b. ing.

  The connection groove 116 is provided between the first and second divided grooves 114a and 114b. The connection groove 116 is a groove that divides the thin film photoelectric conversion units 106 a and 106 b for each battery cell 100. The connection groove 116 has an opening at the interface between the thin film photoelectric conversion unit 106 b and the metal back electrode layer 108, and the surface of the transparent front electrode layer 104 is the bottom surface. A metal material constituting the metal back electrode layer 108 such as silver or aluminum is embedded in the connection groove 116, and one metal back electrode layer 108 and the other transparent front electrode layer 104 of the adjacent battery cell 100 are connected. Are electrically connected. That is, many battery cells 100 formed in the battery module 10 are electrically connected in series to the adjacent battery cells 100 by the metal material embedded in the connection grooves 116.

Each battery cell 100 is desirably formed so that the width (short side) L3 is 7 to 12 [mm] from the viewpoints of accuracy and ease of manufacturing, and minimizing variations in output. It is even more desirable that the width L3 is 8 to 10 [mm]. In addition, each battery cell 100 has a long side length L4 that is slightly shorter than the length of the battery panel 12 in the short direction, and is about 3/4 of the length L4. Therefore, each battery cell 100 has a band-like appearance when viewed from the transparent substrate 102 side. Each battery cell 100 is a tandem (hybrid) solar cell including thin film photoelectric conversion units 106a and 106b, and is configured by one unit by adding the open-circuit voltages of the two units. The voltage is higher than that of the solar cell, and the open circuit voltage is in the range of 1.2 to 1.5 [V]. The battery panel 12 has about 50 to 150 battery cells 100 connected in series, and is configured to output an open circuit voltage of 100 to 180 [V] as a whole. In the battery panel 12 of this embodiment, a large number of battery cells 100 are connected in series so that an open circuit voltage of about 100 [V] can be output as a whole. The battery panel 12 is preferably formed so that the short-circuit current value is in the range of 9 to 15 [mA / cm ² ], and is formed to be in the range of 10 to 13 [mA / cm ² ]. It is even more desirable.

  Further, the long side of each battery cell 100 faces in the short direction of the battery panel 12, and the short side of each battery cell 100 faces in the long direction of the battery panel 12. Therefore, in the battery panel 12, the area of the part functioning as the connection part of each battery cell 100, specifically, the first and second divided grooves 114a and 114b and the connection groove 116 can be suppressed. Further, by arranging each battery cell 100 in the battery panel 12 as described above, a part of the battery panel 12 may be shaded, or dust or dirt may be deposited on the lower side (eave side) of the battery panel 12 or the like. Even if it is deposited, the so-called hot spot phenomenon can be prevented from occurring.

  As shown in FIG. 2, the battery module 10 includes a terminal box 14 and first and second cables 16 and 18 taken out from the terminal box 14 on the back side of the battery panel 12 described above. The terminal box 14 includes a positive electrode connection terminal (not shown) to which the positive electrode of the battery panel 12 is connected and a negative electrode connection terminal (not shown) to which the negative electrode of the battery panel 12 is connected. It has been. In the terminal box 14, two plus side core wires 24, which are black coated conductors, are connected to the plus side electrode connection terminal, and a minus side core wire 26, which is a white sheathed conductor, is connected to the minus side electrode connection terminal. Are connected.

  The first and second cables 16 and 18 are used for electrical connection with other battery modules 10 when the battery modules 10 are laid and the solar cell array 1 is constructed. As shown in FIG. 1, the first cable 16 includes one plus side core wire 24 of the two plus side core wires 24 and 24 and one minus side core wire of the two minus side core wires 26 and 26. 26 is formed by bundling. The second cable 18 is formed by bundling the other plus-side core wire 24 of the two plus-side core wires 24 and 24 and the other minus-side core wire 26 of the two minus-side core wires 26 and 26. It has been done.

  As shown in FIG. 1, the first cable 16 and the second cable 18 are different in color, and the first cable 16 has a plus-side core wire 24 and a minus-side core wire 26 arranged in a white insulating tube 16a. The second cable 18 has a positive core wire 24 and a negative core wire 26 arranged in a black insulating tube 18a.

  The first cable 16 and the second cable 18 are long and short, and one is long and the other is short. Specifically, the first cable 16 is shorter than the second cable 18. The total length of the first cable 16 is less than 50% of the length of the long side of the rectangular battery panel 12, and the total length of the second cable 18 is 50% of the length of the long side of the battery panel 12. That's it.

  As shown in FIG. 1, a first connector 20 and a second connector 22 are provided at the respective ends of the first cable 16 and the second cable 18. Although the colors of the first connector 20 and the second connector are different, the structure is the same. In the present embodiment, the first connector 20 is white and the second connector 22 is black.

  As shown in FIG. 4, the first connector 20 and the second connector 22 include a pin-shaped terminal 28 and a socket-shaped terminal 30. The first connector 20 and the second connector 22 have a female piece 32 and a male piece 34, the pin-like terminal 28 is in the female piece 32, and the socket-like terminal 30 is in the male piece 34. is there.

  As shown in FIG. 1, in this embodiment, a plus-side core wire 24 is joined to the pin-like terminal 28 of the first connector 20, and a minus-side core wire 26 is joined to the socket-like terminal 30 of the first connector 20. Has been. Further, a minus-side core wire 26 is joined to the pin-like terminal 28 of the second connector 22, and a plus-side core wire 24 is joined to the socket-like terminal 30 of the second connector 22. That is, in the first connector 20, the pin-shaped terminal 28 is a positive electrode and the socket-shaped terminal 30 is a negative electrode. On the other hand, in the second connector 22, the pin-shaped terminal 28 is a negative electrode, and the socket-shaped terminal 30 is a positive electrode. Therefore, the first connector 20 and the second connector 22 are formed by fitting one female piece 32 and the other male piece 34 to connect one pin-like terminal 28 to the other socket-like terminal 30. It is possible to electrically connect the same poles in parallel.

  Next, the solar cell array 1 configured using the battery module 10 described above will be described with reference to the work procedure when laying on the roof R of the building shown in FIG. When laying the battery module 10, first, an eaves drainer or a predetermined roofing material is attached to the roof R of the building to be laid. In step 1, lines, shapes, and dimensions necessary for the progress of the work are displayed on the roof R. Inking out. In subsequent step 2, vertical piers (sink bars) are attached at predetermined intervals, and in step 3, Hiromiko (tile) and horizontal piers (tiles) are attached. The horizontal piers are attached at predetermined climb intervals. Next, in step 4, after mounting the blow-up prevention metal fitting for preventing the battery module 10 from blowing up at a predetermined position, the operation shifts to step 5.

  In step 5, the battery modules 10 are sequentially attached from the eaves side to the ridge side of the roof R, and the adjacent battery modules 10 and 10 are connected by the first cable 16 and the second cable 18. More specifically, as shown in FIG. 6, the battery module 10 is attached by forming the module stage 36 by arranging the short sides of the plurality of battery modules 10 next to each other in a row, and by using screws or the like. This is done by fixing the module 10 to the roof R. In the present embodiment, the module steps 36 are even steps (14 steps in FIG. 6) installed on the roof R.

  As shown in FIG. 7, during the formation of the module stage 36, in the adjacent battery modules 10, 10, the first connector 20 of one battery module 10 and the second connector 22 of the other adjacent battery module 10 are connected. Then, two adjacent battery modules 10 and 10 can be electrically connected in parallel. That is, by connecting the white first connector 20 attached to the white first cable 16 and the black second connector 22 attached to the black second cable 18, the adjacent battery modules 10, 10 are connected. Can be connected in parallel. Therefore, the battery module 10 of this embodiment connects all the left and right adjacent battery modules 10, 10 using the first cable 16 and the second cable 18, so that all the battery modules 10 included in the module stage 36 are connected. Can be sequentially connected in parallel (FIG. 9).

  Here, as described above, in the battery module 10 of the present embodiment, the first cable 16 is formed shorter than the second cable 18. Therefore, in the battery module 10, the operator confirms the lengths of the first cable 16 and the second cable 18, so that the connectors 20 and 22 attached to these are the first connector 20, or the second connector. It can be instantly determined whether it is 22.

  In the battery module 10 of the present embodiment, the total length of the first cable 16 is less than 50% of the length of the long side of the rectangular battery panel 12, and the total length of the second cable 18 is the battery. It is 50 percent or more of the length of the long side of the panel 12. Therefore, as shown in FIG. 7, the connectors 20, 20 attached to the first cable 16 cannot be connected between the battery modules 10, 10 adjacent to each other with their short sides abutted. Therefore, the battery module 10 of the present embodiment can reliably prevent erroneous connection between the first connectors 20 and 20 between the adjacent battery modules 10 and 10.

  In the battery module 10 of the present embodiment, the first cable 16 is white and the second cable 18 is black. Therefore, the battery module 10 allows the operator to easily determine the types of the connectors 20 and 22 attached to the first cable 16 and the second cable 18 by checking the colors of the first cable 16 and the second cable 18.

  In the battery module 10, the first connector 20 is white and the second connector 22 is black, and the first connector 20 and the second connector 22 are different in color. Therefore, in the battery module 10 of the present embodiment, the operator can quickly determine the type of the connectors 20 and 22 by checking the colors of the connectors 20 and 22 of the battery module 10. Therefore, the battery module 10 according to the present embodiment allows a worker to select an appropriate connector quickly, has few wiring misconnections, and has high work efficiency.

  As shown in FIG. 10, the solar cell array 1 formed by laying a large number of battery modules 10 includes an odd-numbered module level 36a, 36c and an even-numbered module level 36b, from the eaves side (lower side). The connection order of the first cable 16 and the second cable 18 is reversed left and right at 36d. That is, the odd-numbered module stages 36 a and 36 c connect the second connector 22 of the right battery module 10 and the first connector 20 of the left battery module 10 to connect the second cable 18 and the first cable 16. Are connected. On the other hand, the even-numbered module stages 36b and 36d connect the first cable 16 and the second cable 22 by connecting the first connector 20 of the right battery module 10 and the second connector 22 of the left battery module 10. The cable 18 is connected.

  When all the battery modules 10 constituting the module stage 36 are connected by the first cable 16 and the second cable 18, as shown in FIG. 7, at both ends of the plurality of battery modules 10 constituting the module stage 36. Among the arranged battery modules 10, 10, the first connector 20 of one battery module 10 is unused (unconnected), and the second connector 22 of the other battery module 10 is unused. . These unused first connector 20 and second connector 22 are used for electrical connection of the module stages 36 and 36 arranged above and below.

  For example, in the solar cell array 1 shown in FIG. 10, the odd-numbered module stages 36a and 36c and the even-numbered module stages 36b and 36d are connected, and the solar cell blocks 38a and 38b (hereinafter simply referred to as the battery block 38a). , 38b). Specifically, the second cable 18 of the battery modules 10a and 10c arranged at the left end of the odd-numbered module stages 36a and 36c is connected to the left end of the even-numbered module stages 36b and 36d. The second connector 22 of the battery modules 10a and 10c is connected to the first connector 20 of the battery modules 10b and 10d.

  Thereby, all the battery modules 10 included in the module stage 36a and the module stage 36b are connected in parallel, and the battery block 38a is formed. Further, all the battery modules 10 included in the module stage 36c and the module stage 36d are also connected in parallel to form a battery block 38b. The battery blocks 38a and 38b are each formed by electrically connecting 20 or more battery modules 10 in parallel. In addition, the battery blocks 38a and 38b have the same number of battery modules 10 respectively. The battery blocks 38 a and 38 b formed as described above are electrically connected in series by the lead-in cable 40. Thereby, the solar cell array 1 is constructed.

  As shown in FIG. 11A, the lead-in cable 40 includes a first series connector 42, a second series connector 44, an output connector 46, a first outdoor cable 48, a second outdoor cable 50, An inner cable 52 and a mold part 54 are provided. The first series connector 42 is connected to the first connector 20 of the battery module 10, and the second series connector 44 is connected to the second connector 22 of the battery module 10. The output connector 46 is connected to an indoor power conductor (not shown) and outputs power converted by the battery panel 12 of the battery module 10. The first outdoor cable 48 is connected to the first series connector 42, and the second outdoor cable 50 is connected to the second series connector 44. The indoor side cable 52 is connected to the output connector 46.

  The first series connector 42, the second series connector 44, and the output connector 46 have the same structure as the first connector 20 and the second connector 22 of the battery module 10. The first series connector 42 and the output connector 46 are black, and the second series connector 44 is white.

  Similar to the first cable 16 and the second cable 18 of the battery module 10, the first outdoor cable 48, the second outdoor cable 50, and the indoor side cable 52 are connected to the plus side core wire 24 in the insulating tubes 48a, 50a, 52a. One minus side core wire 26 is arranged one by one. The insulation tubes 48a and 52a of the first outdoor cable 48 and the indoor cable 52 are black, and the insulation tube 50a of the second outdoor cable 50 is white. A white vinyl tape 56 is wound around the output connector 46 of the indoor cable 52. As a result, the indoor cable 52 and the output connector 46 can be discriminated instantaneously.

  As shown in FIG. 11B, the first outdoor cable 48, the second outdoor cable 50, and the indoor side cable 52 are connected to the mold portion 54. More specifically, the plus side core wire 24 of the first outdoor cable 48 and the minus side core wire 26 of the second outdoor cable 50 are electrically connected, and the minus side core wire 26 of the first outdoor cable 48 and the indoor side cable 52 are connected. The negative side core wire 26 is electrically connected, and the positive side core wire 24 of the second outdoor cable 50 and the positive side core wire 24 of the indoor side cable 52 are electrically connected.

  As shown in FIG. 10, when the battery block 38a and the battery block 38b are connected in series using the lead-in cable 40, the white second series connector 44 of the lead-in cable 40 is a module stage constituting the battery block 38a. It is connected to the black second connector 22 of the battery module 10f at the right end of 36b. The black first series connector 42 of the lead-in cable 40 is connected to the white first connector 20 of the battery module 10g at the right end of the module stage 36c constituting the battery block 38b.

  That is, the connection between the lead-in cable 40 and the battery blocks 38a and 38b may be made by connecting connectors of different colors as in the connection of the adjacent battery modules 10 and 10, and misconnection of wiring is less likely to occur. Further, as described above, the connection of the lead-in cable 40 to the battery blocks 38a, 38b is merely a predetermined combination of the connectors 44, 22, 42, 20 and the work can be easily performed on the roof R. It can be carried out.

  Here, the battery blocks 38a and 38b of the present embodiment are obtained by connecting a plurality of battery modules 10 that can obtain a voltage of about 100 [V] in parallel. Therefore, the voltage obtained from the entire battery blocks 38a and 38b is also about 100 [V]. The solar cell array 1 is obtained by connecting two battery blocks 38a and 38b in series using a lead-in cable 40, and can output a voltage of about 200 [V], which is a rated voltage of various devices.

  As shown in FIG. 10, with the battery blocks 38a and 38b connected in series, the first connector 20 of the battery module 10e at the right end of the module stage 36a and the second connector of the battery module 10h at the right end of the module stage 36d. Reference numeral 22 denotes an unused (unconnected) state. In the solar cell array 1 of the battery module 10 of the present embodiment, the terminal protection member 58 shown in FIG. 11 is attached to the first connector 20 and the second connector 22. The terminal protection member 58 has substantially the same structure as the first connector 20 and the second connector 22 of the battery module 10 except that the cable is not connected. In the solar cell array 1 of the battery module 10 of the present embodiment, the terminal protection member 58 is attached to the unused connectors 20 and 22 so that the unused first connector 20 and the terminals 28 and 30 of the second connector 22 are dusty. And water can be prevented from adhering.

  Further, even when the laying operation of the solar cell array 1 performed as described above is interrupted, by attaching the terminal protection member 58 to the unconnected first connector 20 or the second connector 22, the connectors 20, 22 It is possible to prevent dust and water from adhering to the terminals 28 and 30.

  When the work of step 5 shown in FIG. 5 is completed as described above, the worker pulls the indoor cable 52 of the lead-in cable 40 into the building in step 6. After that, construction of the surrounding tiles is performed (Step 7), and after finishing the cleaning of the roof R (Step 8), after the inspection (Step 9) is performed, the lead-in cable 40 is bundled indoors (Step 10). The output connector 46 is connected to a connection box of a power conductor (not shown) (step 11), and a series of operations is completed.

  As described above, the battery module 10 of the present embodiment has a length in the longitudinal direction of 900 to 1100 [mm] and a length in the short direction of 240 to 480 [mm]. Therefore, the battery module 10 can be easily carried and installed in a place where the workability of the laying work such as the roof of a building is poor. Further, the battery module 10 of the present embodiment has a length in the longitudinal direction that is about twice as large as that of a general roof tile, and a length in the short side direction is about the same as that of the roof tile. Therefore, the above-described battery module 10 can be installed in the same manner as when the tiles are arranged side by side in the horizontal direction by placing the battery module 10 on the roof in a horizontally long (longitudinal direction) orientation, and is suitable for construction on the roof. ing.

  As described above, the battery panel 12 is formed by arranging a plurality of strip-shaped battery cells 100 having a width of 7 to 12 [mm] and electrically connected in series, and the configuration is uniform. Moreover, by forming in this way, the battery panel 12 has few individual differences in the output. Therefore, when the solar cell array 1 is constructed as described above, it is possible to minimize the output decrease of the entire solar cell array 1 due to individual differences in the output of each battery panel 12.

  As described above, each battery cell 100 constituting the solar battery panel 12 has a width of 7 to 12 [mm] and an open circuit voltage of 1.2 to 1.5 [V]. Therefore, when the size of the battery panel 12 or the battery module 10 is as described above, the output voltage can be set to a voltage suitable for configuring the solar cell array 1.

  Since the above-described solar battery cell 100 is a tandem type in which thin film photoelectric conversion units 106a and 106b are stacked, the energy of incident light can be utilized to the maximum extent possible. In the above embodiment, an example in which a two-stage tandem type (hybrid type) in which thin film photoelectric conversion units 106a and 106b are stacked is employed as the solar battery cell 100 is illustrated, but the present invention is limited to this. It may be a multi-stage n-stage tandem type (n = an integer greater than or equal to 3). Moreover, the solar cell 100 is not limited to a tandem type, and may be a single layer provided with only one of the thin film photoelectric conversion units 106a and 106b.

In the said embodiment, although the example which employ | adopted the thing which can output a short circuit current in the range of 9-15 [mA / cm < ² >] for the solar cell panel 12 was illustrated, this invention is not limited to this, It may be capable of outputting a short circuit current outside the range.

  As described above, in this embodiment, each of the battery blocks 38a and 38b is configured by electrically connecting 20 or more battery modules 10 in parallel, so that the output of some of the battery modules 10 is temporarily reduced. However, the influence on the output reduction of the entire solar cell array 1 is small. Therefore, the above-described solar cell array 1 can exhibit stable output performance without being substantially affected by a decrease in output in some of the battery modules 10. In the above-described embodiment, an example in which 20 or more battery modules 10 are connected in parallel to configure the battery blocks 38a and 38b is illustrated. However, the present invention is not limited to this, and the battery blocks 38a and 38b are configured. The number of battery modules 10 to be performed may be less than 20.

  The solar cell array 1 described above was formed by connecting two battery blocks 38 in series. However, the present invention is not limited to this, and more battery blocks 38 are formed. These may be connected in series.

  The battery module 10 is not provided with a dividing line that divides the battery cell 100 so as to electrically insulate a region (effective power generation region) that generates power by receiving light, but the present invention is limited to this. Instead, as shown in FIG. 14, one or a plurality of dividing lines 118 extending in the longitudinal direction of the battery module 10 may be provided. According to such a configuration, even if a part of a specific battery cell 100 is shaded and no longer generates power, the battery module 10 can be prevented from being deteriorated or damaged by the hot spot phenomenon. Further, if the dividing line 118 is provided, individual differences occur in the output performance of each battery module 10 due to the hot spot phenomenon after the solar cell array 1 is laid, and this causes the output balance of the solar cell blocks 38a and 38b to be lost. Therefore, the output of the normally functioning battery module 10 can be effectively used.

  The dividing line 118 may be provided so as to pass through any location of the battery cell 100, but the portion that becomes the upper end side (building side) of the battery module 10 in the installed state in the house, or the lower end side (eave side). It is preferable to provide in the part which becomes, ie, the position unevenly distributed in the short direction one end side and lower end side of the battery module 10. According to such a configuration, the hot spot phenomenon is prevented from occurring in a portion on the ridge side which is shaded by other battery modules 10 or roof tiles arranged on the upper side, or on a portion on the eave side where dust and dust easily collect. be able to.

Examples of the present invention will be further described below.
FIG. 1 is a perspective view of a tile-type solar cell module employed in an embodiment of the present invention. 4 is a cross-sectional view of the connector of the solar cell module of FIG.

The tile-type solar cell module 10 is an integrated solar cell, and a plurality of solar cells are formed inside to constitute one solar cell as a whole.
That is, the tile-type solar cell module 10 is formed by laminating a conductive film or a semiconductor film on a glass substrate, and further providing a plurality of grooves in the glass substrate to divide it into a large number of unit cells (cells), and electrically connecting each cell in series. It is a thing.

The tile-shaped solar cell module 10 has a rectangular shape as shown in the figure, and two cables 16 and 18 are extended from the central portion in the longitudinal direction.
Further, connectors 20 and 22 are connected to the cables 16 and 18, respectively.
The cables 16 and 18 are long and short, one is long and the other is short. Specifically, the long cable 18 has a total length of 50% or more of the total length of the roof tile-type solar cell module 10, and the short cable 16 has a total length of 50% of the total length of the roof tile-type solar cell module 10. Less than a percent.
The cables 16 and 18 are different in color. Each of the cables 16 and 18 has two systems of electrically conductive wires 24 and 26 (a plus side core wire 24 and a minus side core wire 26). More specifically, it is a cable in which two coated conductors 24 and 26 are arranged in the same insulating tube.

Connectors 20 and 22 are connected to the two cables 16 and 18, respectively. The connectors 20 and 22 are different in color but have the same structure, and have two terminals 28 and 30 (a pin terminal 28 and a socket terminal 30) as shown in FIG.
Of the two terminals 28 and 30, one pin-shaped terminal 28 is a pin, and the other socket-shaped terminal 30 is a socket.
The connectors 20 and 22 have a female piece 32 and a male piece 34, the pin-like terminal 28 is in the female piece 32, and the socket-like terminal 30 is in the male piece 34.
The connectors 20 and 22 can be connected to each other, and one female piece 32 and the other male piece 34 are joined. At that time, one pin-shaped terminal 28 and the other socket-shaped terminal 30 are connected inside each female piece 32 and male piece 34.

In the present embodiment, the two covered conductors 24 and 26 of the two cables 16 and 18 are respectively connected to the positive electrode and the negative electrode of the solar cell (hereinafter referred to as a solar cell) in the roof tile solar cell module 10. Yes. That is, one coated conductor 24 in the cable 18 is connected to the positive electrode of the solar cell, and the other coated conductor 26 is connected to the negative electrode of the solar cell. Similarly, one coated conductor 24 in the cable 16 is connected to the positive electrode of the solar cell, and the other coated conductor 26 is connected to the negative electrode of the solar cell.
Therefore, one of the two terminals 28 and 30 of the connector 22 is connected to the positive electrode of the solar cell, and the other coated conductor is connected to the negative electrode of the solar cell. Similarly, one of the two terminals 28 and 30 of the connector 20 is connected to the positive electrode of the solar cell, and the other coated conductor is connected to the negative electrode of the solar cell.
However, when the polarities of the two terminals 28 and 30 of the connectors 20 and 22 are compared, they are opposite to each other. That is, in one connector 22, the pin-shaped terminal 28 is a positive electrode and the socket-shaped terminal 30 is a negative electrode, whereas in the other connector 20, the pin-shaped terminal 28 is a negative electrode and the socket-shaped terminal 30 is a positive electrode. is there.

Next, the laying structure of the tile-type solar cell module 10 will be described.
FIG. 7 is a conceptual diagram when the tile-type solar cell module is accurately wired. FIG. 8 is a conceptual diagram when the tile-type solar cell module is mistakenly wired. FIG. 9 is a circuit diagram when the tile-type solar cell module is correctly wired.
As shown in FIGS. 7 and 8, the above-described tile-shaped solar cell module 10 is laid on a structure such as a roof side by side.
Then, the connectors 20 and 22 of the adjacent tile type solar cell modules 10 are connected. When attention is paid to one tile-type solar cell module 10, the connector 22 of the tile-type solar cell module 10 and the connector 20 of the tile-type solar cell module 10 on the left are connected. Further, the connector 20 of the tile-type solar cell module 10 and the connector 22 of the tile-type solar cell module 10 on the right side are connected.
If it demonstrates paying attention to the length of a cable, the connector 22 of the long cable 18 of the said tile type solar cell module 10 and the connector 20 of the short cable 16 of the tile type solar cell module 10 on the left side will be connected. Further, the connector 20 of the short cable 16 of the tile-type solar cell module 10 and the connector 22 of the long cable 18 of the tile-type solar cell module 10 on the right side are connected.
As a result, the solar cells are connected in parallel as shown in FIG.

On the other hand, if the connection method is wrong and the connectors 22 of the long cable 18 are connected to each other as shown in FIG. 8, the other connectors 20 cannot be physically connected. It becomes. That is, the other connector 20 is connected to a short cable 16, and the short cable 16 is less than half of the total length of the roof tile solar cell module 10. Moreover, since the cables 16 and 18 are extended from the center part of the tile-shaped solar cell module 10, even if it is going to connect the short cables 16, length is not enough and both cannot be connected.
Therefore, the tile-type solar cell module 10 of the present embodiment cannot cause wiring errors.

  Next, the procedure for actually laying the roof solar cell module 10 of the present invention on the roof will be described. The tile-type solar cell module 10 of the present invention is desirably laid on the roof according to the following manual.

DESCRIPTION OF SYMBOLS 1 Solar cell array 10 Solar cell module 12 Solar cell panel 38 Solar cell block 100 Solar cell (battery cell)
118 dividing line

Claims (8)

A plurality of solar cell blocks formed by electrically connecting a plurality of solar cell modules in parallel, a solar cell module for solar cell array configuration formed by electrically connecting in series,
A length in the longitudinal direction is 900 to 1100 [mm], and includes a solar cell panel formed in a substantially rectangular plane shape, and the longitudinal direction of the solar cell panel is directed in a row direction of a house. It is installed so that the short-side direction faces the house building direction,
The solar battery panel has a plurality of solar battery cells, and the solar battery cells are electrically connected in series so that the open circuit voltage is 100 to 180 [V].
The solar cell has a strip shape and a short side length of 7 to 12 [mm], the long side faces in the short direction of the solar cell panel, and the short side in the longitudinal direction of the solar cell panel. A solar cell module, wherein the solar cell module is provided so as to be aligned in a longitudinal direction of the solar cell panel in a state of facing.   The solar cell module according to claim 1, wherein an open circuit voltage of the solar cell is 1.2 to 1.5 [V].   The solar cell module according to claim 1 or 2, wherein a length in a short direction is 240 to 480 [mm].   The solar battery module according to claim 1, wherein the solar battery cell is a tandem type. The short circuit current value of a solar cell panel is 9-15 [mA / cm < ² >], The solar cell module in any one of Claims 1-4 characterized by the above-mentioned. The solar battery cell has an effective power generation region that generates power by receiving light,
The solar cell module according to any one of claims 1 to 5, wherein one or a plurality of dividing lines extending in a longitudinal direction of the solar cell module and dividing an effective power generation region of the solar cell are provided.   A plurality of solar cell modules according to any one of claims 1 to 6, wherein two solar cell blocks formed by electrically connecting in parallel are formed by connecting them in series. Battery array.   The solar cell array according to claim 7, wherein the solar cell block is formed by electrically connecting 20 or more solar cell modules in parallel.

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