JP4476071B2 - Solar cell panel and solar cell panel construction method - Google Patents

Description

  The present invention relates to a solar cell panel and a solar cell panel construction method.

  Solar cells that convert light into electric power are known. As a form that can be used stably for a long time when the solar cell is used and can be attached to a roof or a wall, a solar cell panel in which the solar cell is formed into a panel shape is known. As a method of installing the solar cell panel on the roof, there are a method of installing the solar cell panel on the roof via a support structure, a method of embedding the solar cell panel in the roof, and the like. Since the installation of the solar cell panel on the roof is performed on the roof, it is desired that the operation is as easy as possible, safer and more reliable.

  As a method of installing a solar cell panel on a tile via a support structure, for example, Japanese Patent Application Laid-Open No. 2003-293536 discloses a roof material with a solar cell. This roof material with a solar cell is a roof material with a solar cell provided with a roof base material in which a solar cell panel is fixed on the front surface side and a concave portion for accommodating a cable is formed on the back surface side. The lead wire drawn out from the solar cell panel is led from the front surface side to the concave portion on the back surface side through the outer periphery of the roof base material and connected to the cable, and the cable is connected from the concave portion to the outside of the roof base material. It is drawn out. A notch communicating with the recess may be formed on the outer periphery of the roof base material, and the lead wire may be drawn into the recess through the notch and the end of the cable may be pulled out.

  As a method for embedding a solar cell panel in a roof tile, Japanese Patent Application Laid-Open No. 2004-3132 discloses a structure for fixing a solar light utilization device. This fixing structure of the solar light utilization device is a fixing structure of the solar light utilization device installed on the tile roof in which a large number of tiles are arranged on the roof base. A support member for supporting the solar light utilization device is provided at a predetermined position of the roof base, and the support member is covered with a metal molding tile having the same appearance as the tile and having a through hole, and the support member and the solar light utilization device Is configured to be fixed through the through hole of the metal-molded roof tile.

JP 2003-293536 A JP 2004003132 A

  Accordingly, an object of the present invention is to provide a solar cell panel and a solar cell panel construction method that can be worked as easily as possible, safer, and reliably.

  The objective of this invention is providing the construction method of the solar cell panel which can improve the working efficiency in a solar cell panel construction site, and a solar cell panel.

  Moreover, the other object of this invention is to provide the construction method of the solar cell panel which can make connection of an earth cable easy, and a solar cell panel.

  Still another object of the present invention is to provide a solar cell panel and a solar cell panel construction method capable of improving the weather resistance of a connection cable.

  Another object of the present invention is to provide a solar cell panel and a solar cell panel construction method capable of connecting connection cables more easily and reliably.

  Still another object of the present invention is to provide a solar cell panel and a solar cell panel construction method that can increase the overall strength at low cost.

  Hereinafter, means for solving the problem will be described using the numbers and symbols used in the best mode for carrying out the invention. These numbers and symbols are added in parentheses in order to clarify the correspondence between the description of the claims and the best mode for carrying out the invention. However, these numbers and symbols should not be used for interpreting the technical scope of the invention described in the claims.

  Therefore, in order to solve the above-mentioned problem, the solar cell construction method of the present invention includes (a) a step of fixing a plurality of solar cell panels (1) to a roof (2), and (b) a plurality of solar cell panels. A step of installing a protective plate (30) so as to cover and electrically connect adjacent solar cell panels (1) between adjacent solar cell panels (1) of (1). To do. The solar cell panel (1) includes a solar cell module (12) that generates electricity by light and a frame (10) that is provided so as to surround the solar cell module (12) and has electrical conductivity. The protection plate (30) electrically connects the adjacent solar cell panels (1) in the frame (10).

  In the above solar cell construction method, (c) a step of electrically connecting a set of a plurality of solar cell panels (1) electrically connected by a protective plate (30) with a grounding cable (22). Is further provided. The grounding cable (22) includes a cable (22) connected to the ground and a plurality of terminals (41) electrically connected in the middle of the cable (22). Each of the plurality of terminals (41) is fitted into the frame (10) in one solar cell panel (1) in the set and is electrically connected, (42, 43, 44), A crimp terminal portion (46) for connecting the fitting portion (42, 43, 44) and the cable (22) is included.

  In the solar cell construction method, (d) a step of preparing a plurality of solar cell panels (1), and (e) a connection cable (21/23) for the plurality of solar cell panels (1) on the roof (2 ) Step of laying on, and (g) connecting the connection cable (21/23) to the plurality of solar cell panels (1), passing through the notch (11), and connecting the plurality of solar cell panels (1). And a step of placing on the roof (2). Here, the solar cell panel (1) passes the connection cable (21/23) of the solar cell module (1) when the frame (10) fixes the solar cell panel (1) to the roof (2). It has a notch (11) provided.

  In the solar cell construction method, the connection cable (23) includes a first cable (23a), a second cable (23b), and a plurality of cables that bind the first cable (23a) and the second cable (23b). And a binding band (27). The first cable (23a) includes a third cable (23a1), a fourth cable (23a2), a plurality of fifth cables (26a), and a plurality of sixth cables (26b). The third cable (23a1) is for the plus electrode of the plurality of solar cell panels (1). The fourth cable (23a2) is for the minus electrode of the plurality of solar cell panels (1). The plurality of fifth cables (26a) are connected at one end to the third cable (23a1) and at the other end to the positive electrodes of the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). Connected. The plurality of sixth cables (26b) are connected to the fourth cable (23a2) at one end, and the other ends are different from the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). To the negative electrode of the second solar cell panel (1). The second cable (23b) is connected to the minus electrode of the adjacent first solar cell panel (1) and the plus electrode of the second solar cell panel (1).

  In the solar cell construction method described above, the frame (10) has a rectangular shape, and is a reinforcement that joins the central part of one long side and the central part of the other long side so as not to be separated by a predetermined distance or more. Members (51, 52) are provided.

  In order to solve the above problems, a solar cell construction method of the present invention includes (h) a step of arranging and fixing a plurality of solar cell panels (1) on a roof (2), and (i) a plurality of solar cell panels ( 1), electrically connecting the grounding cable (22). The solar cell panel (1) is provided so as to surround the solar cell module (12) that generates power by light, and the solar cell module (12), and includes a conductive frame and (10). The grounding cable (22) includes a cable (22) connected to the ground and a plurality of terminals (41) electrically connected in the middle of the cable (22). Each of the plurality of terminals (41) is fitted into the frame (10) and electrically connected to the fitting parts (42, 43, 44), the fitting parts (42, 43, 45), and the cable ( 22) and a crimp terminal part (46) for connecting the terminal 22).

  In order to solve the above problems, a solar cell construction method of the present invention includes (j) a step of preparing a plurality of solar cell panels (1), and (k) a wiring for a plurality of solar cell panels (1) ( 21) laying on the roof; (l) connecting the wiring (21) to the plurality of solar cell panels (1), passing the wiring (21) through the notch (11), and Securing the panel (1) on the roof (2). Here, the solar cell panel (1) includes a solar cell module (12) that generates electricity by light, and a conductive frame (10) provided so as to surround the solar cell module (12). The frame (10) has a notch (11) provided so that the wiring (21) of the solar cell module (12) can easily pass when the solar cell panel (1) is fixed to the roof.

  In order to solve the above problems, the solar cell construction method of the present invention includes (m) laying a connection cable (23) on the roof (2) as wiring for a plurality of solar cell panels (21), and (N) connecting the connection cable (23) to the plurality of solar cell panels (1) and fixing the plurality of solar cell panels (1) on the roof (2). Here, the connection cable (23) includes a first cable (23a), a second cable (23), and a plurality of binding bands (27) for binding the first cable (23a) and the second cable (23b). It comprises. The first cable (23a) includes a third cable (23a1), a fourth cable (23a2), a plurality of fifth cables (26a), and a plurality of sixth cables (26b). The third cable (23a1) is for the plus electrode of the plurality of solar cell panels (1). The fourth cable (23a2) is for the minus electrode of the plurality of solar cell panels (1). The plurality of fifth cables (26a) are connected at one end to the third cable (23a1) and at the other end to the positive electrodes of the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). It is connected. The plurality of sixth cables (26b) are connected to the fourth cable (23a2) at one end, and the other ends are different from the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). Connected to the negative electrode of the second solar cell panel (1). The second cable (23b) is connected to the minus electrode of the adjacent first solar cell panel (1) and the plus electrode of the second solar cell panel (1).

  In order to solve the above problems, a solar cell construction method of the present invention includes (o) a step of preparing a plurality of solar cell panels (1), and (p) a plurality of solar cell panels (1) on a roof (2 ) Fixing on top. Here, the solar cell panel (1) is provided so as to surround the solar cell module (12) that generates power by light, the solar cell module (12), a rectangular conductive frame (10), and a frame ( And 10) a reinforcing member (51, 52) for connecting the central part of one long side and the central part of the other long side so as not to be separated from each other by a predetermined distance or more.

  In order to solve the above problems, a solar cell system according to the present invention includes a plurality of solar cell panels (1) fixed to a roof and an adjacent solar cell panel (1) among the plurality of solar cell panels (1). And a protective plate (30) provided so as to cover the gap between them. The solar cell panel (1) includes a solar cell module (12) that generates electricity by light, and a conductive frame (10) that is provided so as to surround the solar cell module (12). The protective plate (30) includes a conductive flat plate (31) and a coupling portion (32) provided on one surface of the flat plate (31). The flat plate (31) is electrically connected to the frame (10), and the coupling portion (32) is coupled to at least one frame (10) of the two solar cell panels (1).

  The solar cell system further includes a grounding cable (22) for electrically connecting a set of the plurality of solar cell panels (1) electrically connected by the protection plate (30). The grounding cable (22) includes a cable (22) connected to the ground and a plurality of terminals (41) electrically connected in the middle of the cable (22). A plurality of terminals (each of the terminals (41) is fitted into the frame (10) of one solar cell panel (1) in the set and electrically connected to the fitting parts (42, 43, 44), A crimp terminal portion (46) for connecting the joint portion (42, 43, 44) and the cable (10) is provided.

  In the solar cell system described above, the frame (10) has a notch provided for passing the connection cable (21/23) of the solar cell module (12) when the solar cell panel (1) is fixed to the roof. (11)

  The solar cell system further includes a connection cable (23) connected to the terminal box (13) in each of the plurality of solar cell panels (1). The connection cable (23) includes a first cable (23a), a second cable (23b), and a plurality of binding bands (27) for binding the first cable (23a) and the second cable (23b). . The first cable (23a) includes a third cable (23a1), a fourth cable (23a2), a plurality of fifth cables (26a), and a plurality of sixth cables (26b). The third cable (23a1) is for the plus electrode of the plurality of solar cell panels (1). The fourth cable (23a2) is for the minus electrode of the plurality of solar cell panels (1). The plurality of fifth cables (26a) are connected at one end to the third cable (23a1) and at the other end to the positive electrodes of the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). It is connected. The plurality of sixth cables (26b) are connected to the fourth cable (23a2) at one end, and the other ends are different from the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). Connected to the negative electrode of the second solar cell panel (1). The second cable (23b) is connected to the minus electrode of the adjacent first solar cell panel (1) and the plus electrode of the second solar cell panel (1).

  In the solar cell system described above, the frame (10) has a rectangular shape, and a reinforcing member that joins the central part of one long side and the central part of the other long side so as not to be separated by a predetermined distance or more. 51, 52).

  In order to solve the above problems, a solar cell system of the present invention is connected to each of a plurality of solar cell panels (1) and a plurality of solar cell panels (1) fixedly arranged on a roof (2), A grounding cable (22) connected to ground. The solar cell panel (1) includes a solar cell module (12) that generates electricity by light, and a conductive frame (10) that is provided so as to surround the solar cell module (12). The grounding cable (22) includes a cable (22) connected to the ground and a plurality of terminals (41) electrically connected in the middle of the cable (22). Each of the plurality of terminals (41) has a fitting portion (42, 43, 44) that fits into the frame (10), and a crimp that connects the fitting portion (42, 43, 44) and the cable (10). Terminal portion (46).

  In order to solve the above problems, a solar cell system of the present invention includes a plurality of solar cell panels (1) arranged in a fixed manner on a roof (2), and a terminal box in each of the plurality of solar cell panels (1) ( And a connection cable (23) connected to 13). The connection cable (23) includes a first cable (23a), a second cable (23b), and a plurality of binding bands (27) for binding the first cable (23a) and the second cable (23b). . The first cable (23a) includes a third cable (23a1), a fourth cable (23a2), a plurality of fifth cables (26a), and a plurality of sixth cables (26b). The third cable (23a1) is for the plus electrode of the plurality of solar cell panels (1). The fourth cable (23a2) is for the minus electrode of the plurality of solar cell panels (1). The plurality of fifth cables (26a) are connected at one end to the third cable (23a1) and at the other end to the positive electrodes of the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). It is connected. The plurality of sixth cables (26b) are connected to the fourth cable (23a2) at one end, and the other ends are different from the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). Connected to the negative electrode of the second solar cell panel (1). The second cable (23b) is connected to the minus electrode of the adjacent first solar cell panel (1) and the plus electrode of the second solar cell panel (1).

  In order to solve the above-described problems, a solar cell panel of the present invention includes a solar cell module (12) that generates electricity by light, and a conductive frame (10) provided so as to surround the solar cell module (12). It has. The frame (10) has a notch (11) provided for passing the wiring of the solar cell module (12) when the frame (10) is fixed to the roof (2).

  In order to solve the above problems, a solar cell panel of the present invention is provided so as to surround a solar cell module (12) that generates power by light and a solar cell module (12), and has a rectangular conductive frame (10 ) And a reinforcing member (51, 52) for connecting the central portion of one long side of the frame (10) and the central portion of the other long side so as not to be separated from each other by a predetermined distance or more.

  In order to solve the above problem, the protective plate (30) of the present invention includes a conductive flat plate (31) and a coupling portion (32) provided on one surface of the flat plate (31). The flat plate (31) is fixed to the roof (2) and electrically connected to the conductive frame (10) in the two adjacent solar cell panels (1), and the gap between the two solar cell panels (1). Cover. The coupling portion (32) is coupled to at least one frame (10) of the two solar cell panels (1).

  In order to solve the above problems, a grounding cable of the present invention includes a cable (22) connected to the ground and a plurality of terminals (41) electrically connected in the middle of the cable (22). . Each of the plurality of terminals (41) is fitted to a conductive frame (10) in a plurality of solar cell panels (1) fixedly arranged on the roof (2) (42, 43, 44). And a crimp terminal part (46) for connecting the fitting parts (42, 43, 44) and the cable (22).

  In order to solve the above problems, the connection cable (23) of the present invention binds the first cable (23a), the second cable (23b), and the first cable (23a) and the second cable (23b). A plurality of binding bands (27). The first cable (23a) includes a third cable (23a1), a fourth cable (23a2), a plurality of fifth cables (26a), and a plurality of sixth cables (26b). The third cable (23a1) is for the plus electrode of the plurality of solar cell panels (1). The fourth cable (23a2) is for the minus electrode of the plurality of solar cell panels (1). The plurality of fifth cables (26a) are connected at one end to the third cable (23a1) and at the other end to the positive electrodes of the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). It is connected. The plurality of sixth cables (26b) are connected to the fourth cable (23a2) at one end, and the other ends are different from the plurality of first solar cell panels (1) among the plurality of solar cell panels (1). Connected to the negative electrode of the second solar cell panel (1). The second cable (23b) is connected to the minus electrode of the adjacent first solar cell panel (1) and the plus electrode of the second solar cell panel (1).

  According to the present invention, the solar cell panel can be constructed more easily, safely and more reliably, and the work efficiency at the construction site can be improved. Moreover, the connection of the ground cable is facilitated, the weather resistance of the connection cable is improved, and the connection cable can be connected more easily and reliably. And the whole intensity | strength can be raised at low cost.

  Hereinafter, embodiments of a solar cell panel and a solar cell panel construction method of the present invention will be described with reference to the accompanying drawings.

(First embodiment)
1st Embodiment of the construction method of the solar cell panel and solar cell panel of this invention is described with reference to an accompanying drawing. First, the structure of 1st Embodiment of the construction method of the solar cell panel of this invention and a solar cell panel is demonstrated.

  Fig.1 (a) is the schematic when the solar cell panel of this invention is mounted on the roof. The plurality of solar cell panels 1 are generally arranged in a matrix in the row direction (X direction in the drawing) and the column direction (Y direction in the drawing). Each solar cell panel 1 is arranged on the tile adjacent to each other solar cell panel 1 by a jig (not shown) installed on the tile (not shown) on the roof 2. Each solar cell panel 1 is provided with a predetermined wiring by a connection cable or a ground cable (not shown).

  FIG.1 (b) is a block diagram which shows the solar cell panel of this invention. They are a top view, AA sectional view, and BB sectional view, respectively, of a basic solar cell panel 1. The solar cell panel 1 includes a solar cell module 12 that generates power by light, a frame 10 that holds (supports) the power, and a terminal box 13 that stores terminals (plus and minus) from which power is extracted. The frame 10 is formed of a conductive material, for example, a metal including aluminum. Since the surface is coated with a predetermined paint in order to improve weather resistance (corrosion resistance), the surface is insulative.

Fig.2 (a) is a perspective view which shows 1st Embodiment of the solar cell panel of this invention.
The solar cell panel 1 of the present embodiment includes a decorative board 30 in addition to the configuration of FIG. The decorative plate 30 electrically connects the frames 10 of the adjacent solar cell panels 1 to each other. At the same time, the gap between adjacent solar cell panels 1 is covered, and the connection cable 21 passing through the lower side of the solar cell panel 1 is prevented from being exposed to sunlight, wind, rain, and snow in the gap portion.

FIG.2 (b) is a perspective view which shows the detail of the attachment part of a decorative board.
The decorative board 30 will be further described. The decorative board 30 is formed of a conductive material, for example, a metal such as aluminum. The surface is painted to improve corrosion resistance. The decorative board 30 includes a decorative board main body 31 and a fitting portion 32. The decorative plate body 31 is a rectangular flat plate. It has a long side substantially equal to the short side of the solar cell panel 1 and a short side longer than the gap between adjacent solar cell panels 1. Near the center of both long sides, a hole 33 penetrating from one surface to the other surface and a hole 34 are provided. The hole 33 and the hole 34 correspond to the hole 10 c and the hole 10 d provided near the center of the short side end portion 10 a of the frame 10 of the solar cell panel 1. The decorative board 30 is fixed to the solar cell panel 1 by passing the two screws 35 through the hole 33-hole 10c and the hole 34-hole 10d, respectively. The screw 35 is also made of metal. The fitting portion 32 is a member having a substantially L-shaped cross section provided on one surface of the decorative board main body 31 so as to extend substantially parallel to the long side from one short side to the other short side. . Since such a decorative board 30 is formed by extrusion molding, it can be manufactured at substantially the same cost as in the case of a normal flat plate.

  Adjacent solar cell panels 1 have a panel 10-hole 10 c (metal is exposed on the inner surface)-screw 35-hole 33 (metal is exposed on the inner surface)-decorative plate 30-hole 34 (metal is exposed on the inner surface)-screw 35 -It is electrically connected by the route of the hole 10d-panel 10.

Next, with reference to FIG. 2, the construction method of the solar cell panel of this invention is demonstrated.
(1) First, a solar cell panel 1 as shown in FIG. 2B is prepared (manufactured). The solar cell panel 1 is provided with a hole 10c and a hole 10d in the vicinity of the center of the short side end portion 10a of the frame 10 and at a position corresponding to the hole 33 and the hole 34 when the decorative plate 30 is attached. . The metal of the frame 10 is exposed on the inner surfaces of the holes 10c and 10d.
(2) Next, the prepared plurality of solar cell panels 1 are attached to the roof as shown in FIG. As a method of attaching to the roof, a conventional method or a method described later can be used.
(3) Subsequently, the decorative plate 30 is placed in the gap between the adjacent solar cell panels 1 with the fitting portion 32 facing down. Then, the decorative plate 30 is slid and the end portion 10 a is fitted into the space formed by the decorative plate main body 31 and the fitting portion 32.
(4) Then, the decorative board 30 is fixed with the screw 35 in the hole 33-hole 10c and the hole 34-hole 10d. Since the hole 34 is long in the long side direction of the frame 10, it is possible to flexibly cope with an installation error of the solar cell panel 1.

  In this way, the solar cell panel is constructed. However, although the screw 35 is used, a bolt-nut can also be used. Further, the number and position of the holes are not limited to the example of FIG.

  FIG. 3 shows electrical connection between the solar battery panels 101 by a conventionally known method. In this case, since the ground cable 131 is fixed on the side surface of the frame 110 in order to electrically connect the solar cell panels 101 to each other, the connection cable 121a that hits the gap between the solar cell panels 101 is sunlight, wind, rain, It is easily exposed to snow and easily deteriorates. In addition, there is a possibility that the ground cable 131 may fall when screwing during construction.

  According to the present invention, when the solar cell panels 1 are constructed, the adjacent solar cell panels 1 are electrically connected by the decorative plate 30, so that a ground cable for connecting the solar cell panels 1 becomes unnecessary. Further, since one end of the decorative plate 30 is fitted into the frame 10 of the solar cell panel 1 when the decorative plate 30 is attached, the decorative plate 30 can be prevented from falling before the screw 35 is fixed. Since the hole 34 of the decorative plate 30 is a long hole, the mounting dimension tolerance of the solar cell panel 1 can be absorbed. They make it easier, safer and more reliable. And the work efficiency in a construction site can be improved.

  In this invention, since the clearance gap between the solar cell panels 1 is lose | eliminated and the connection cable 21 by sunlight becomes difficult to be exposed to sunlight, a wind, rain, and snow, degradation of the coating | covering material of the connection cable 21 can be prevented. Moreover, since the space | gap between the solar cell panels 1 is lose | eliminated and the blowing of the wind below the solar cell panel 1 can be prevented, the wind-resistant performance of the solar cell panel 1 can be improved. And the clearance gap between the solar cell panels 1 is lose | eliminated, and the design property can be improved.

(Second Embodiment)
2nd Embodiment of the construction method of the solar cell panel and solar cell panel of this invention is described with reference to an accompanying drawing. First, the structure of 2nd Embodiment of the construction method of the solar cell panel of this invention and a solar cell panel is demonstrated.

  Since FIG. 1 is the same as that of the first embodiment, a description thereof will be omitted.

FIG. 4A is a perspective view showing a second embodiment of the solar cell panel of the present invention.
The plurality of solar cell panels 1 arranged in a matrix on the roof 2 are connected to each other in the row direction (X direction) as the ground electrical connection by the method described in the first embodiment. ing. The second embodiment relates to a connection method in the column direction (Y direction) at the end of the column.

  Referring to FIG. 4A, a single ground cable 22 is connected in the column direction at the end of each row of the matrix solar cell panel. As shown in the enlarged view of the M1 and M2 portions, the ground cable 22 is pre-attached with crimp terminals 41 corresponding to the number of rows of the solar cell panel 1 at a predetermined interval. And electrical connection is performed by inserting the crimp terminal 41 in the edge part 10b of the flame | frame 10 of the solar cell panel 1. FIG.

  FIG. 4B is a perspective view showing the configuration of the crimp terminal. The crimp terminal 41 includes a crimp part 46, a first flat plate part 44, a second flat plate part 43, and a presser part 42. The crimping portion 46 has a cylindrical shape and connects the crimp terminal 41 and the ground cable 22 by being crushed (crimped) with the ground cable 22 inside. The 1st flat plate part 44 and the 2nd flat plate part 43 oppose, and comprise a substantially U shape. It is connected to the crimping part 46 at the bottom of the U-shape. The presser portion 42 has a semi-cylindrical shape, is connected to the second flat plate portion 43, and faces the first flat plate portion 44.

  FIG.4 (c) is sectional drawing which shows a mode when a crimp terminal is inserted in a solar cell panel. The crimp terminal 41 connected to the ground cable 22 is fitted from below the end portion 10b of the frame 10. When sandwiched between the presser portion 42 and the first flat plate portion 44. At this time, the first flat plate portion 44, the second flat plate portion 43, and the presser portion 42 that are substantially U-shaped are elastically deformed, and the crimp terminal 41 and the ground cable 22 are fixed to the end portion 10b by elastic force. At this time, if the surface of the contact surface 45 or the inner surface of the first flat plate portion 44 is roughened (provided with unevenness), the contact surface 45 scrapes the surface coating of the end portion 10b when fitting, and the metal surface is exposed. The electrical connection can be improved.

Next, with reference to FIG. 4, the construction method of the solar cell panel of this invention is demonstrated.
(1) First, the ground cable 22 to which a predetermined number of crimp terminals 41 (FIG. 4B) are connected at predetermined intervals as shown in FIG. The predetermined interval and number are calculated based on the installation position and number of solar cell panels 1.
(2) Next, a plurality of solar cell panels 1 shown in FIG. 1 (b) are attached to the roof as shown in FIGS. 1 (a) and 4 (a). As a method of attaching to the roof, a conventional method or a method described later can be used.
(3) Subsequently, the frames 10 are electrically connected to each other in the row direction (X direction) of the plurality of solar cell panels 1 by the method of the first embodiment.
(4) Then, the ground cable 22 is fixed to the solar cell panel 1 by fitting the crimp terminal 41 of the ground cable 22 prepared in advance to the end portion 10b of the solar cell panel 1 in the first row. .

  In this way, the solar cell panel is constructed. However, the shape of the crimp terminal 41 is not limited to this example, and may be any shape that can be fitted into the frame 10.

  FIG. 5 shows electrical connection between the solar cell panels 101 at the end of the row by a conventionally known method. In this case, in order to electrically connect the solar cell panels 101 to each other, a conventional crimp terminal 137 is used, and the ground cable 122 is fixed on the side surface of the frame 110 with screws 135. Therefore, the number of cables is large, the number of screwing steps is large, and the ground cable 122 and the screw 135 may be dropped.

  According to the present invention, the ground cable 22 can be easily attached simply by fitting the crimp terminal 41 into the frame 10 of the solar cell panel 1. Since the number of ground cables 22 to be used is one, operational errors can be reduced. In addition, it is not necessary to process the ground cable 22 on site. That is, the operation can be performed as easily as possible, more safely, and reliably. It becomes possible to improve the work efficiency at the construction site.

(Third embodiment)
3rd Embodiment of the construction method of the solar cell panel and solar cell panel of this invention is described with reference to an accompanying drawing. First, the structure of 3rd Embodiment of the construction method of the solar cell panel of this invention and a solar cell panel is demonstrated.

  Since FIG. 1 is the same as that of the first embodiment, a description thereof will be omitted.

Fig.6 (a) is a perspective view which shows 3rd Embodiment of the solar cell panel of this invention.
The solar cell panel 1 of the present embodiment has a notch 11 through which the connection cable 21 passes in the frame 10. The notch 11 includes a notch 11 a provided on the long side of the frame 10 and a notch 11 b provided on the short side. By providing the notch 11, it is not necessary to provide a gap through which the connection cable 21 passes under the solar cell panel 1. Thereby, the solar cell panel 1 can be brought closer to the roof. The position, size, interval, and number of the notches 11 are not limited to the example in this figure, and are determined based on the number of solar cell panels and the wiring design.

  FIG. 6B is a diagram showing the shape of the notch 11a. The shape of the notch 11a is not a simple rectangular shape but a predetermined roundness at the corners in order to reduce the stress concentration due to the strength of the frame 10. For example, in the figure, a curve with a predetermined radius R is drawn. However, the shape as shown in FIG.

  FIG. 6C shows the shape of the notch 11b. The shape of the notch 11b is not a simple rectangular shape but has a predetermined angle with respect to the bottom surface of the frame 10 in order to reduce stress concentration due to the strength of the frame 10. For example, in the figure, the angle is approximately 45 degrees. However, the shape as shown in FIG.

  FIG.6 (d) is the schematic seen from the X direction at the time of mounting the solar cell panel of this invention on a roof. A plurality of solar cell panels 1 are arranged in the column direction (Y direction in the figure). Each solar panel 1 is arranged on the roof tile adjacent to the other solar panel panels 1 by a jig (not shown) installed on the roof tile 63 fixed to the crosspiece 62 of the roof base plate 61. Has been. Each solar cell panel 1 is provided with a predetermined wiring by a connection cable 21. At that time, since the connection cable 21 passes through the notch 11a and the notch 11b, the distance D between the roof tile 63 and the solar cell panel 1 can be made closer.

Next, with reference to FIG. 6, the construction method of the solar cell panel of this invention is demonstrated.
(1) First, a solar cell panel 1 as shown in FIGS. 6A to 6C is prepared (manufactured). The solar cell panel 1 is provided with notches 11a and 11b at predetermined positions, sizes, intervals, and numbers on the long side and the short side of the frame 10, respectively.
(2) Next, in order to attach a plurality of solar cell panels 1 to the roof as shown in FIGS. 1B and 6A to 6C, connection cables 21 for those solar cell panels 1 are provided. Lay on the roof tile 63.
(3) Subsequently, a plurality of solar cell panels 1 are attached to the roof as shown in FIGS. 1 (a) and 6 (d) while connecting the laid connection cable 21 and the solar cell panel 1. FIG. As a method of attaching to the roof, a conventional method or a method described later can be used.
(4) Thereafter, the decorative plate 30 and the ground cable 22 of the first and second embodiments are connected between the solar cell panels 1.

  In this way, the solar cell panel is constructed.

  FIG. 7A is a perspective view showing a conventional solar cell panel 101. In this case, the frame 110 of the solar cell panel 101 has no notch. Therefore, the connection cable 121 needs to pass below the space occupied by the frame 110. FIG.7 (b) is the schematic seen from the X direction at the time of mounting the conventional solar cell panel on a roof. Thus, since it is necessary to pass the connection cable 121 below the solar cell panel 101, the solar cell panel 101 is separated from the roof tile 163 by that amount. The distance D ′ is larger than the distance D in FIG. When the distance D ′ increases, the wind pressure resistance decreases due to the blowing of wind toward the lower side of the solar cell panel 101. Therefore, a member for ensuring the wind pressure resistance performance is required, which causes an increase in cost.

  According to the present invention, the distance D between the solar cell panel 1 and the roof tile 63 is reduced, the blowing of wind to the lower side of the solar cell panel 1 is suppressed, and the wind pressure resistance can be improved. Thereby, during the construction work, the work can be performed as easily, safer and surely as possible, and after the construction work, a more stable solar cell system with improved wind pressure resistance can be obtained. And since the blowing load by a wind reduces by the distance D becoming small, the cost of a member can be reduced.

  According to the present invention, the passage of the connection cable 21 can be specified by specifying the position of the notch 11. Thereby, standardization of connection cable laying can be performed, and thereby the work efficiency at the construction site can be improved. And the level | step difference of the solar cell panel 1 and the roof tile 63 decreases, and the design property can be improved.

(Fourth embodiment)
A fourth embodiment of the solar cell panel and solar cell panel construction method of the present invention will be described with reference to the accompanying drawings. First, the structure of 4th Embodiment of the construction method of the solar cell panel of this invention and a solar cell panel is demonstrated.

  Since FIG. 1 is the same as that of the first embodiment, a description thereof will be omitted.

Fig.8 (a) is a block diagram which shows the connection cable used for 4th Embodiment of the solar cell panel of this invention.
The connection cable 23 of the present embodiment is grouped for each of the plurality of solar cell panels 1. In the figure, the connection cable 23 used for the solar cell panel 1 arranged in 2 rows and 4 columns is illustrated. The connection cable 23 includes a parallel cable 23a, a series cable 23b, a branch terminal 26, a connector 24, a connector 25, and a binding band 27.

  FIG. 8B is a diagram showing details of the connection cable. The parallel cable 23a includes a positive electrode cable 23a1 and a negative electrode cable 23a2. The output of each solar cell panel 1 is connected in parallel. The series cable 23b connects electrodes between adjacent solar cell panels 1 in series. The branch terminal 26 connects the output of the solar cell panel 1 in parallel to the parallel cable 23a. That is, one end is connected to the cable 23a1, the other end is connected to the positive electrode of the solar cell panel 1, and one end is connected to the cable 23a2 and the other end is connected to the negative electrode of the other solar cell panel 1. Cable 26b. The binding band 27 binds the parallel cable 23a and the serial cable 23b together. The connector 24 is a terminal for taking out the electric power of the solar cell panel 1 collected by the parallel cable 23a to the outside. It has a connector 24a connected to the cable 23a1 and a connector 24b connected to the cable 23a2. The connector 25 is a terminal connected to the terminal box 13 for extracting power from the solar cell panel 1. It has a connector 25a connected to the cable 26a and the serial cable 23b, and a connector 25b connected to the cable 23b and the serial cable 23b.

  FIG. 9 is a diagram showing details of the binding band 27. The binding band 27 includes a band A27a and a band B27c. As shown on the right side of the figure, the band B27c is brought closer to the band A27a from a predetermined direction. As a result, as shown on the left side of the figure, the hanging portion 27d of the band B27c is inserted into the slit 27b of the band A27a, and both are fixed to each other.

Next, with reference to FIGS. 8-10, the construction method of the solar cell panel of this invention is demonstrated. FIG. 10 is a configuration diagram showing the connection between the solar cell panel and the connection cable in the present invention. Here, the case where the solar cell panel 1 of 2 rows 4 columns is constructed is demonstrated.
(1) First, a connection cable 23 as shown in FIGS. 8A to 8B and FIG. 9 is prepared (manufactured). Here, the length and number of parallel cables 23a and series cables 23b, the position and number of branch terminals 26, the number of connectors 24 and connectors 25, and the position and number of binding bands 27 are determined based on the layout design of the solar cell panel 1. Is done.
(2) Next, a solar cell panel 1 as shown in FIGS. 6A to 6C described in the third embodiment is prepared (manufactured). The solar cell panel 1 is provided with notches 11a and 11b at predetermined positions, sizes, intervals, and numbers on the long side and the short side of the frame 10, respectively.
(3) Then, based on the allocation drawing for allocating the solar cell panel 1 on the roof 2 (tile), the position of the terminal box 13 of the solar cell panel 1 is marked on the roof 2 (tile).
(4) Next, in order to attach the plurality of solar battery panels 1 to the roof 2, the prepared connection cable 23 is laid on the roof 2 (tile). At that time, the binding band 27 near the connector 25 in the connection cable 23 is aligned with the mark. By doing so, the two cables bend at the position of the binding band 27, and the previous connector 25 becomes the position of the terminal box 13. The connection cable 23 may be fixed to a jig (not shown) for attaching the solar cell panel 1 with another type of binding band or the like.
(5) Subsequently, while connecting each connector 25 of the connection cable 23 to the terminal box 13 of each solar cell panel 1, the plurality of solar cell panels 1 are attached to the roof as shown in FIG.
(6) Thereafter, the decorative plate 30 and the ground cable 22 of the first and second embodiments are connected between the solar cell panels 1. In addition, the connection cable 21 wired on the roof tile 63 and the solar cell panel 1 are connected.

  In this way, the solar cell panel is constructed.

  FIG. 11A shows a conventional parallel cable 123a. FIG.11 (b) is a figure which shows the conventional serial cable 123b. As described above, it has been necessary to perform a connection work using a plurality of types of cables simultaneously in a conventional construction site. This complicates work such as cable sorting and positioning. As a result, the work efficiency is lowered and erroneous wiring occurs. Moreover, since each cable is laid in the space between the solar cell panel 1 and the roof 2, it must be laid before the solar cell panel 1 is installed. Therefore, it is necessary to work before installing the solar cell panel 1 to which each cable is connected, and it takes time and effort to position the cable.

  According to the present invention, since the connection cable 23 in which four cables are bundled in advance is used, it is not necessary to sort the cables in the field. In addition, the connection cable 23 can be easily laid by aligning the mark on the roof in advance with the position of the binding band 27 of the connection cable 23. Furthermore, since the connection work of the connection cable becomes easy, erroneous connection can be suppressed. That is, the construction work is easy, safer and more reliable, and the work efficiency at the construction site can be improved.

(Fifth embodiment)
5th Embodiment of the construction method of the solar cell panel and solar cell panel of this invention is described with reference to an accompanying drawing. First, the structure of 5th Embodiment of the construction method of the solar cell panel of this invention and a solar cell panel is demonstrated.

  Since FIG. 1 is the same as that of the first embodiment, a description thereof will be omitted.

Fig.12 (a) is a perspective view which shows 5th Embodiment of the solar cell panel of this invention.
In the solar cell panel 1 of the present embodiment, a through hole is provided in the vicinity of the center between both long sides of the frame 10 facing each other. Then, the metal rod 51 passes through the through hole, and the rod 51 is fixed by the lock pin 52, thereby connecting the long sides facing each other of the frame 10. Thereby, it can prevent that the flame | frame 10 is distorted and the distance of both long sides which face each other spreads. In FIG. 12 (a), one rod 51 is provided at the center of the long side, but the present invention is not limited to this, and the position and number are changed according to the force received by the frame 10. It is also possible to do. It can also be used as a ground terminal. Further, instead of the lock pin 52, a method of cutting a male screw at the end of the rod 51 and locking it with a nut, or other locking methods can be used.

  FIG.12 (b) shows the EE cross section in Fig.12 (a). A solar cell module 121 is fitted into the frame 10. The rod 51 is fixed by a lock pin 52 slightly away from the cross section. By fixing, the frame 10 is distorted and spreads, and the solar cell module 12 can be prevented from being detached from the frame.

  FIG.12 (c) is the figure seen from the F direction in FIG.12 (b). The lock pin 52 is inserted into the rod 51 and fixed by the rod 51 and the frame 10. Thereby, the rod 51 is also fixed.

Next, with reference to FIG. 12, the construction method of the solar cell panel of this invention is demonstrated.
(1) First, a connection cable 23 as shown in FIGS. 8A to 8B and FIG. 9 described in the fourth embodiment is prepared (manufactured).
(2) Next, the rod 51 and the lock pin 52 as shown in FIG. 12 are reinforced around the center of the long side, as shown in FIGS. 6A to 6C described in the third embodiment. A solar cell panel 1 provided with a notch 11 is prepared (manufactured).
(3) Then, based on the allocation drawing for allocating the solar cell panel 1 on the roof 2 (tile), the position of the terminal box 13 of the solar cell panel 1 is marked on the roof 2 (tile).
(4) Next, in order to attach the plurality of solar battery panels 1 to the roof 2 as shown in FIG. 1B, the prepared connection cable 23 is laid on the roof 2 (tile). At this time, the binding band 27 near the connector 25 in the connection cable 23 is aligned with the mark.
(5) Subsequently, while connecting each connector 25 of the connection cable 23 to the terminal box 13 of each solar cell panel 1, as shown in FIG. As a method of attaching to the roof, a conventional method or a method described later can be used.
(6) Thereafter, the decorative plate 30 and the ground cable 22 of the first and second embodiments are connected between the solar cell panels 1. In addition, the connection cable 21 wired on the roof 63 and the solar cell panel 1 are connected.

  In this way, the solar cell panel is constructed.

  FIG. 13A is a perspective view showing a conventional solar cell panel 101. When constructing the solar cell panel 101, an operator often holds the solar cell panel 101 by placing a finger on the long side of the frame 110. In this case, a load P1 is applied to the frame 110 in the in-plane direction on the long side. As a result, the frame 110 due to the bending is curved outward. FIG. 13B is a cross-sectional view showing a conventional solar cell panel 101. This corresponds to the AA cross section of FIG. When a load P <b> 2 is applied to the surface of the solar cell panel 101 at a right angle, a component force S <b> 1 is generated in the in-plane direction of the frame 10. Thereby, the frame 110 is curved outward, and the solar cell module 12 may fall off the frame 110 when the load is large.

  According to the present invention, even when a load in the in-plane direction is applied to one frame of the solar cell panel, the load is shared by the two frames facing each other, so that the frame can be prevented from being bent during handling or weather. Thereby, the cross-sectional area of the frame can be reduced and the cost can be reduced. That is, the overall strength can be increased at low cost. There is a method of adding an intermediate frame as the same effect, but since the rod can be attached without using a tool, the assembly work efficiency is high.

  As a method of attaching the solar cell panel 1 to the roof, various methods (including conventionally known methods) can be used. For example, the solar cell module mounting method described in Japanese Patent Application No. 2004-055617 can be used.

  The solar cell module mounting method of Japanese Patent Application No. 2004-055617 will be outlined. FIG. 14 is a perspective view showing a roof tile used in the method for attaching the solar cell module. When the roof tile 201 is constructed on a roof base plate, the head K is on the eaves side, the bottom L is on the ridge side, and the roof tile 201 is inserted under the side surface of the adjacent roof tile 201. Covering the side of the embedded portion M and the adjacent roof tile 201 is the crosspiece N, and the rain exposed portion J is exposed to the outside near the center.

  The roof tile 201 includes a nail hole 203, a bottom water return 204, a locking protrusion 205, a water return 206a, a water return 206b, a locked portion 207, a water return 208, side heads 9a and 9b, a central head 9c, an opening. 210 a, a locking protrusion 210, and a supporting protrusion 211. Two (or more) nail holes 203 are provided in the vicinity of the bottom L, and penetrate the roof tile 201. The roof tile 201 is fixed by driving nails. The bottom water return 204 is provided on the bottom L and has a platform shape higher than the rain exposed portion J. The rainwater is exposed to rain and flows to part J. The locking projection 205 is provided on the bottom L, and has a hook-like shape facing the crosspiece N. When the roof tile 201 is constructed on the roof base plate and a part of the head K of another roof tile 201 adjacent to the ridge side overlaps a part of the bottom L, the locked part 207 of the head K is The locking protrusions 205 are caught and locked to each other.

  Water return 206a, 206b is provided in the insertion part M, and is the shape of a stand higher than the rain exposure part J. The rainwater is exposed to rain and flows to part J. When the roof tile 201 is constructed on the roof base plate, and the crosspiece N of the other adjacent roof tile 201 overlaps the insertion part M, the water return 208 of the crosspiece N is the water return 6a, 6b, the locked part. 207 (including the hooked locking projection 205) is covered. The locked portion 207 is provided in the insertion portion M and has a shape in which the tip of the locking protrusion 205 of the other roof tile 201 is easily caught.

  The water return 208 is provided on the crosspiece N and has a platform shape higher than the rain exposure part J. The rainwater is exposed to rain and flows to part J. When the roof tile 201 is constructed on the roof base plate, and the crosspiece N overlaps with the insertion portion M of the other adjacent roof tile 201, the water return 6a, 6b of the insertion portion M, the locked portion 207 (included) The hooking protrusion 205) is inserted under the water return 208.

  The side heads 9a and 9b are provided on the head K and have an inclination that gently falls downward from the rain exposure part J. Rainwater is exposed to rain and then flows from part J down to the eaves. The central head portion 209c is provided in the head portion K, and unlike the side head portions 9a and 9b, a flat surface K1 having a predetermined width W extends to the rain exposed portion J. On the flat surface K1, a connection fitting 220 described later that holds the solar cell panel is placed. The central head portion 209c is undercut so that the connecting fitting 220 can be easily locked, and the water return 208 of the roof tile 201 adjacent to the lower side of the eaves can be easily overlapped.

  The locking projection 210 is provided on the flat surface K1 and has a hook-like shape facing the bottom L. The connecting fitting 220 is locked. Four support protrusions 211 are provided on the flat surface K1 so as to surround the locking protrusions 210 at substantially the same height. The connecting fitting 220 is stably supported at four points from below, and the deviation in the vertical and horizontal directions is suppressed. In addition, the pressing force of the connection fitting is not affected by variations in the surface level accuracy of the rain exposure portion J.

  FIG. 15 is a perspective view showing a connection fitting used in the method for attaching the solar cell module. The connection fitting 220 includes a bottom surface part 230, a long side wall part 240, a first short side wall part 250, and a second short side wall part 260. It is formed like a box without an upper lid. The bottom surface portion 230 has a rectangular shape that can be installed on the flat surface K1. The long side wall portions 240 are two long side surfaces that rise substantially vertically from the bottom surface portion 230. The first short side wall portion 250 and the second short side wall portion 260 are two surfaces on the short side that rise substantially vertically from the bottom surface portion 230.

  The bottom surface portion 230 includes an opening 231, a first tongue-like elastic portion 232, and a second tongue-piece upper elastic portion 233. The opening 231 is near the approximate center of the bottom surface 230, and the locking protrusion 210 of the roof tile 201 is engaged with the opening 231. The first tongue-like elastic portion 232 is a portion in which a portion near the short side wall portion 250 is cut out in a substantially U-shape. The first tongue-like elastic body 232 faces downward from the bottom surface portion 230, and the distal end portion 232a faces further outward. When installed on the roof tile 201, the tip 232a is engaged with the undercut portion of the central head 209c. The second upper tongue piece elastic portion 233 faces downward from the bottom surface portion 230, and the distal end portion 233a faces inward. When installed on the roof tile 201, the tip 233a is pressed against the flat surface K1 and elastically holds the connection fitting 220.

  The long side wall portion 240 has a tip opposite to the bottom surface portion 230 side facing outward and a cross section formed in an inverted L shape. The flat surface portion 241 is not damaged even if the solar cell panel 1 comes into contact. The vertical surface 242 is partially cut away so that the connection cable 23 can pass therethrough.

  The first short side wall portion 250 includes a locking claw 252 that hooks a protrusion provided on the frame 10 of the solar cell panel 1 and a first short side wall portion main body 251 that supports the locking claw 252. The configuration of the second short side wall portion 260 is the same as that of the first short side wall portion 250.

  FIG. 16 is a perspective view showing the roof tile attached to the roof by the method of attaching the solar cell module. The roof tile 201 can be installed on the pier 202a provided on the field board 202 of the roof 2 so that a part of each other overlaps. That is, with respect to the roof tile 201 adjacent in the direction of the pier 202a, a part of one (N on the left side) tip part N overlaps to cover a part of the other (on the right side) insertion part M. Installed. Regarding the roof tiles 201 adjacent to each other in the direction from the ridge to the eaves, a part of the upper head K is arranged so as to cover a part of the lower buttocks L. The connection fitting 220 is fixed on the flat surface K1 by inserting the locking projection 210 of the roof tile 201 into the opening 231.

  FIG. 17 is a cross-sectional view showing a solar cell panel mounted on a roof tile by a solar cell module mounting method. The connection fitting 220 is fixed to the locking protrusion 210 of the roof tile 201. The solar cell panel 1 is attached to the connecting metal fitting 252 by engaging the protrusion 10-1 provided on the frame 10 with the engaging claw 252 of the connecting metal fitting 220.

  FIG. 18 is a schematic view showing a solar cell panel (solar cell system) mounted on a roof tile by a solar cell module mounting method. Here, a 2 × 2 solar cell panel 1 installed on a plurality of roof tiles 201 is shown. For ease of understanding, some members are shown through. The solar cell panel 1 uses the techniques of the first to fifth embodiments.

  According to the present invention, these solar cell panels (solar cell systems) can be constructed more easily, more safely, more reliably, and work efficiency at the construction site can be improved. Moreover, the connection of the ground cable is facilitated, the weather resistance of the connection cable is improved, and the connection cable can be connected more easily and reliably. And the whole intensity | strength can be raised at low cost.

Fig.1 (a) is the schematic when the solar cell panel of this invention is mounted on the roof. FIG.1 (b) is a block diagram which shows the solar cell panel of this invention. Fig.2 (a) is a perspective view which shows 1st Embodiment of the solar cell panel of this invention. FIG.2 (b) is a perspective view which shows the detail of the attachment part of a decorative board. FIG. 3 shows electrical connection between solar cell panels by a conventionally known method. FIG. 4A is a perspective view showing a second embodiment of the solar cell panel of the present invention. FIG. 4B is a perspective view showing the configuration of the crimp terminal. FIG.4 (c) is sectional drawing which shows a mode when a crimp terminal is inserted in a solar cell panel. FIG. 5 shows the electrical connection between the solar cell panels at the end of the row by a conventionally known method. Fig.6 (a) is a perspective view which shows 3rd Embodiment of the solar cell panel of this invention. FIG. 6B is a diagram showing the shape of the notch. FIG. 6C is a diagram showing the shape of the notch. FIG.6 (d) is the schematic seen from the X direction at the time of mounting the solar cell panel of this invention on a roof. Fig.7 (a) is a perspective view which shows the conventional solar cell panel. FIG.7 (b) is the schematic seen from the X direction at the time of mounting the conventional solar cell panel on a roof. Fig.8 (a) is a block diagram which shows the connection cable used for 4th Embodiment of the solar cell panel of this invention. FIG. 8B is a diagram showing details of the connection cable. FIG. 9 is a diagram showing details of the binding band. FIG. 10 is a configuration diagram showing the connection between the solar cell panel and the connection cable in the present invention. Fig.11 (a) is a figure which shows the conventional parallel cable. FIG.11 (b) is a figure which shows the conventional serial cable. Fig.12 (a) is a perspective view which shows 5th Embodiment of the solar cell panel of this invention. FIG.12 (b) shows the EE cross section in Fig.12 (a). FIG.12 (c) is the figure seen from the F direction in FIG.12 (b). FIG. 13A is a perspective view showing a conventional solar cell panel. FIG.13 (b) is sectional drawing which shows the conventional solar cell panel. FIG. 14 is a perspective view showing a roof tile used in the method for attaching the solar cell module. FIG. 15 is a perspective view showing a connection fitting used in the method for attaching the solar cell module. FIG. 16 is a perspective view showing the roof tile attached to the roof by the method of attaching the solar cell module. FIG. 17 is a cross-sectional view showing a solar cell panel mounted on a roof tile by a solar cell module mounting method. FIG. 18 is a schematic view showing a solar cell panel mounted on a roof tile by a solar cell module mounting method.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,101 Solar cell panel 2 Roof 3 10 and 13 which accommodated the terminal (plus and minus) which takes out electric power
10, 110 Frame 10a, 10b End portion 10c, 10d Hole 11, 11a, 11b Notch 12, 112 Solar cell module 13 Terminal box 21, 121, 121a Connection cable 22, 122 Ground cable 23 Connection cable 23
23a, 123a Parallel cable 23a1, 23a2 Cable 23b, 123b Series cable 24, 24a, 24b, 25, 25a, 25b, 124a, 124b, 125a, 125b Connector 26 Branch terminal 26a, 26b Cable 27 Binding band 28 Binding band 27
27a Band A
27b Slit 27c Band B
27d Hook 30 Decorative plate 31 Decorative plate body 32 Insertion portion 33, 34 Hole 35, 135 Screw 41, 137 Crimp terminal 42 Presser 43 Second flat plate portion 44 First flat plate portion 45 Contact surface 46 Crimp portion 51 Rod 52 Lock pin 61, 161 Field plate 62, 162 Crosspiece 63, 163 Tile 131 Ground cable 201 Roof tile 202 Field plate 202a Crosspiece 203 Nail hole 204 Bottom water return 205 Lock projection 206, 206a, 206b, 208 Water return 207 Locked portion 208
209a, 209b Water return side head 209c Central head 210 Locking protrusion 210a Opening 211 Supporting protrusion 220 Connecting bracket 230 Bottom face part 231 Opening part 232 First tongue piece elastic part 233 Second tongue piece upper elastic part 232a, 233a tip part 240 long side wall 241 flat surface 242 vertical surface 250 first short side wall 251 first short side wall main body 252 locking claw 260 second short side wall

Claims (13)

(A) fixing a plurality of solar cell panels to the roof;
(B) between adjacent solar cell panels of the plurality of solar cell panels, covering a gap between the adjacent solar cell panels, and installing a protective plate so as to be electrically connected;
The solar cell panel is
A solar cell module that generates electricity by light;
A frame that is provided so as to surround the solar cell module and has conductivity;
The protective plate is
A conductive plate;
A coupling portion provided on one surface of the flat plate,
The flat plate is electrically connected to the frame in two adjacent solar cell panels,
The coupling portion is a solar cell construction method in which the coupling portion is coupled only to one of the frames of the two solar cell panels . In the construction method of the solar cell according to claim 1,
(C) further comprising a step of electrically connecting a plurality of sets of solar cell panels electrically connected by the protective plate with a grounding cable;
The grounding cable is
A cable connected to ground,
A plurality of terminals electrically connected in the middle of the cable,
Each of the plurality of terminals is
A fitting portion that fits and is electrically connected to the frame in one solar cell panel in the set;
The construction method of the solar cell containing the crimp terminal part which connects the said fitting part and the said cable. In the construction method of the solar cell according to claim 1 or 2,
(D) preparing the plurality of solar cell panels;
Here, the solar cell panel is
The frame has a notch provided for passing a connection cable of the solar cell module when the solar cell panel is fixed to the roof;
(E) laying the connection cables for the plurality of solar cell panels on the roof;
(G) A method for constructing a solar cell, further comprising: connecting the connection cable to the plurality of solar cell panels and passing the plurality of solar cell panels on the roof through the notch. In the construction method of the solar cell according to any one of claims 1 to 3,
A connection cable connected to each of the plurality of solar cell panels ,
A first cable;
A second cable;
A plurality of binding bands for binding the first cable and the second cable;
The first cable is:
A third cable for positive electrodes of the plurality of solar cell panels;
A fourth cable for the negative electrode of the plurality of solar cell panels;
A plurality of fifth cables having one end connected to the third cable and the other end connected to the plus electrodes of the plurality of first solar cell panels of the plurality of solar cell panels;
A plurality of second terminals having one end connected to the fourth cable and the other end connected to the negative electrodes of a plurality of second solar cell panels different from the plurality of first solar cell panels among the plurality of solar cell panels. With 6 cables,
The said 2nd cable is the construction method of the solar cell connected to the minus electrode of the said 1st solar cell panel and the plus electrode of the said 2nd solar cell panel which adjoin. In the construction method of the solar cell according to any one of claims 1 to 4,
The frame has a rectangular shape, a solar cell with a reinforcing member in which one of the at least one location of at least one location and the other long side opposite to the long side is fixed so as not away more than a predetermined distance Construction method. A plurality of solar panels fixed to the roof;
A protective plate provided so as to cover a gap between adjacent solar cell panels among the plurality of solar cell panels;
The solar cell panel is
A solar cell module that generates electricity by light;
Provided so as to surround the solar cell module, and comprising a conductive frame,
The protective plate is
A conductive plate;
A coupling portion provided on one surface of the flat plate,
The flat plate is electrically connected to the frame in two adjacent solar cell panels ,
The coupling portion includes a solar cell system that binds only to the frame of the hand of the two solar panels. The solar cell system according to claim 6 , wherein
Further comprising a grounding cable for electrically connecting a plurality of sets of solar cell panels electrically connected by the protective plate;
The grounding cable is
A cable connected to ground,
A plurality of terminals electrically connected in the middle of the cable,
Each of the plurality of terminals is
A fitting portion that fits and is electrically connected to the frame in one solar cell panel in the set;
A solar cell system provided with the crimp terminal part which connects the said fitting part and the said cable. In the solar cell system according to claim 6 or 7 ,
The said frame is a solar cell system which has a notch part provided in order to let the connection cable of the said solar cell module pass, when fixing the said solar cell panel to a roof. In the solar cell system according to any one of claims 6 to 8 ,
Further comprising a connected connecting cable each to the plurality of solar panels,
The connection cable is
A first cable;
A second cable;
A plurality of binding bands for binding the first cable and the second cable;
The first cable is:
A third cable for positive electrodes of the plurality of solar cell panels;
A fourth cable for the negative electrode of the plurality of solar cell panels;
A plurality of fifth cables having one end connected to the third cable and the other end connected to the plus electrodes of the plurality of first solar cell panels of the plurality of solar cell panels;
A plurality of second terminals having one end connected to the fourth cable and the other end connected to the negative electrodes of a plurality of second solar cell panels different from the plurality of first solar cell panels among the plurality of solar cell panels. Including 6 cables,
The second cable is a solar cell system in which a minus electrode of the adjacent first solar cell panel and a plus electrode of the second solar cell panel are connected to each other. In the solar cell system according to any one of claims 6 to 9 ,
The frame has a rectangular shape, the sun with the one and at least one portion of the other long side opposite to the at least one location of the long sides, and a reinforcing member for fixing so as not away more than a predetermined distance Battery system. A conductive plate;
A coupling portion provided on one surface of the flat plate,
The flat plate is fixed to the roof and electrically connected to a conductive frame in two adjacent solar cell panels, covering a gap between the two solar cell panels,
The coupling portion includes a protective plate that binds only to the frame of the hand of the two solar panels. The protection plate according to claim 11, wherein the coupling portion is a member having a substantially L-shaped cross section provided so as to extend substantially parallel to a long side of the flat plate. The flat plate is provided with a long hole formed long in the long side direction of the frame,
The protection plate according to claim 11 or 12, wherein the flat plate is fixed to the frame by a screw penetrating the elongated hole.

Images