JP2012182322A - Solar cell module and solar cell system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily conduct the attachment work of a solar cell module while realizing vibration control of the solar cell module.SOLUTION: A solar cell module 1 includes: a cover glass 11 and a back sheet 12 that face each other; solar cells 2, 2,... provided between the cover glass 11 and the back sheet 12, and a frame body 4 enclosing peripheries of the cover glass 11 and the back sheet 12. Attachment parts 5, each of which is formed by rubber so as to be integrated with the frame body 4 and is used for attaching the solar cell module 1 to a folded-plate roof 7, are provided in the frame body 4.

Description

  The present invention relates to a solar cell module and a solar cell system including the same.

  In recent years, solar cell modules have been rapidly spread due to increasing environmental awareness. Solar cell modules are often installed on the roofs and roofs of buildings. For example, a solar cell module is installed on the rooftop of a building, etc. via a mount (see Patent Document 1).

JP 2009-130183 A

  However, in the configuration according to Patent Document 1, first, a solar cell module is installed on a base that forms a part of the gantry. At this time, the buffer member is interposed between the base and the solar cell module. Next, a fixing member is disposed on the solar cell module. Also at this time, the buffer member is interposed between the solar cell module and the fixing member. Subsequently, the fixing member is screwed. Thus, in the structure which concerns on patent document 1, it takes much effort to attach a solar cell module.

  Moreover, since the solar cell module is generally installed outdoors, it is exposed to wind and rain. When wind and rain hit the solar cell module, vibration may occur in the solar cell module. In order to prevent this vibration, it is necessary to firmly fix the solar cell module via the gantry, and the gantry is indispensable.

  This invention is made | formed in view of this point, The place made into the objective is to perform attachment of a solar cell module easily, implement | achieving the vibration isolation of a solar cell module.

  A solar cell module disclosed herein includes a top sheet and a back sheet that face each other, a solar cell element provided between the top sheet and the back sheet, and a frame that surrounds the top sheet and the back sheet. And. And the said frame is comprised with rubber | gum, and the attachment part for attaching a solar cell module to installation object shall be provided integrally with this frame.

  The solar cell system disclosed herein includes a plurality of solar cell modules, and each of the solar cell modules is provided between a top sheet and a back sheet facing each other and between the top sheet and the back sheet. A solar cell element, a frame body surrounding the top sheet and the back sheet, and a cable electrically connected to the solar cell element, the frame body made of rubber, and a solar cell module Is attached integrally with the frame body, and between the adjacent solar cell modules, the frame body of one solar cell module and the solar cell module of the other It is assumed that an arrangement space for arranging the cable sandwiched between the frames is formed.

  According to the solar cell module, the mounting portion of the solar cell module is provided integrally with the frame body and is made of rubber, so that it is not necessary to separately provide a gantry and the solar cell module can be easily mounted. The vibration of the battery module can be absorbed by the mounting portion.

  Further, according to the solar cell system, the mounting portion of the solar cell module is provided integrally with the frame body and is made of rubber, so that it is not necessary to separately provide a gantry and the solar cell module can be easily mounted. In addition, the vibration of the solar cell module can be absorbed by the mounting portion, and in addition, a cable installation space can be secured between the adjacent solar cell modules.

It is sectional drawing of the solar cell system which concerns on embodiment. It is an expanded sectional view of a solar cell system. It is sectional drawing of the frame which concerns on other embodiment, and an attaching part. It is sectional drawing of the frame which concerns on another other embodiment, and an attaching part. It is an expanded sectional view of the solar cell system concerning other embodiments. It is an expanded sectional view of the solar cell system concerning another other embodiment. It is an expanded sectional view of the solar cell system concerning other other embodiments.

  Hereinafter, exemplary embodiments will be described in detail with reference to the drawings.

  1 is a cross-sectional view of the solar cell system according to Embodiment 1, and FIG. 2 is an enlarged cross-sectional view of the solar cell system.

  The solar cell system 100 includes a plurality of solar cell modules 1, 1,. The plurality of solar cell modules 1, 1,... Are installed on the folded plate roof 7. The folded plate roof 7 is an example of an installation target.

  The solar cell module 1 includes a module main body 10, a heat insulating material 18 provided on the back side of the module main body 10, and attachment portions 5 and 5 for attaching the module main body 10 to the folded plate roof 7. . The solar cell module 1 is formed in a flat plate shape as a whole.

  The module body 10 includes a cover glass 11, a back sheet 12 facing the cover glass 11, a plurality of solar cells 2, 2,... Provided between the cover glass 11 and the back sheet 12, The sealing material 13 filled between the cover glass 11 and the back sheet 12, the resin plate 15 provided between the cover glass 11 and the solar cells 2, 2,... A reinforcing sheet 16 provided on the peripheral edge of the cover glass 11 and the reinforcing sheet 16, and a junction box 14. The module main body 10 is formed in a substantially rectangular shape in plan view.

  The cover glass 11 is made of a transparent glass material. The cover glass 11 is made of, for example, a flat glass having a size of 1 mm or less. This cover glass 11 constitutes a top sheet.

  The back sheet 12 is a sheet-like member that prevents permeation of water, water vapor, and the like, and is a member for protecting the solar battery cell 2. The back sheet 12 is composed of a laminated sheet of an aluminum thin film and a resin thin film. The back sheet 12 may be a laminated sheet obtained by laminating a PET sheet, an aluminum sheet, and a polyethylene film, or a laminated sheet obtained by laminating a PET sheet, an aluminum sheet, and a fluororesin film.

  The solar battery cell 2 is not limited to a specific cell. For example, the solar battery cell 2 is made of silicon. The solar battery cell 2 may be made of crystalline silicon (including single crystal silicon and polycrystalline silicon), or may be made of amorphous silicon. The solar battery cell 2 may be made of thin film silicon, tandem silicon, spherical silicon, or the like, and the shape thereof is not limited. Further, as the solar battery cell 2, a dye-sensitized solar battery cell may be adopted. That is, the solar battery cell 2 can employ any solar battery cell as long as the solar battery cell is sandwiched between the top sheet and the back sheet. This solar cell 2 constitutes a solar cell element.

  The sealing material 13 is a member that protects substances such as liquid and gas from entering the solar battery cell 2. The sealing material 13 also has a function of bonding the cover glass 11 and the back sheet 12. The sealing material 13 is also filled between the cover glass 11 and the resin plate 15. The sealing material 13 is made of an ethylene vinyl acetate copolymer resin (EVA). The sealing material 13 may be composed of methyl methacrylate resin (PMMA), polyvinyl butyral resin (PVB), polyurethane resin, or the like.

  The resin plate 15 is made of a transparent resin. The resin plate 15 is a plate for relieving stress concentration on the cover glass 11. The resin plate 15 is provided on the back side of the cover glass 11 (the solar cell 2 side of the cover glass 11) with the sealing material 13 interposed. The resin plate 15 has substantially the same planar shape as the cover glass 11 and has substantially the same area. The resin plate 15 has higher rigidity than the sealing material 13. The resin plate 15 preferably has a higher bending rigidity than the sealing material 13. Furthermore, it is preferable that the resin plate 15 has a bending rigidity higher than that of the cover glass 11. The resin plate 15 is thicker than the cover glass 11.

  By providing the resin plate 15, stress concentration on the cover glass 11 can be relaxed. That is, in the module main body 10, the solar cells 2, 2,... Are not bent so much, the portion between the solar cells 2, 2,. Bend. Therefore, an uneven bending stress is generated in the cover glass 11. However, by providing the resin plate 15 between the solar cells 2, 2,... And the cover glass 11, the overall angular deformation of the solar cells 2, 2,. After being relaxed at 15, the light is transmitted to the cover glass 11. As a result, stress concentration in the cover glass 11 can be suppressed. Thereby, damage to the cover glass 11 due to stress concentration is prevented. Therefore, the cover glass 11 can be made thinner than the case where the resin plate 15 is not provided. When the cover glass 11 becomes thin, the weight of the solar cell module 1 can be reduced. Although the weight increases by the amount of the resin plate 15, since the resin has a specific gravity smaller than that of the glass, the effect of reducing the weight of the thin cover glass 11 is greater. The resin plate 15 is made of, for example, hard vinyl chloride, acrylic, polyethylene, polyester, polycarbonate, polyethylene terephthalate, polypropylene, urethane, polybutylene terephthalate, polystyrene, polyvinyl acetal, polyvinyl butyral, or the like.

  The reinforcing sheet 16 is for improving the weather resistance of the back sheet 12 and reinforcing the strength of the solar cell module 1. The reinforcing sheet 16 has substantially the same area as the back sheet 12. The reinforcing sheet 16 is bonded to the back sheet 12 via an adhesive tape made of butyl rubber. Specifically, the reinforcing sheet 16 includes a vinyl chloride waterproof sheet, a polyolefin waterproof sheet, a metal plate such as an aluminum alloy or a galvalume steel plate, a sandwich panel of the metal plate, a resin and the metal plate, and a metal for the waterproof sheet. It is composed of a laminate of plates or sandwich panels, or a metal or resin honeycomb board.

  The back sheet 12 bears waterproofness and moisture resistance, and its strength is not so great. Further, since the frame body 4 is made of rubber as will be described later, it is difficult to reinforce the rigidity of the solar cell module 1 only by the frame body 4. Therefore, the rigidity of the solar cell module 1 is improved by providing the reinforcing sheet 16. Preferably, the rigidity of the reinforcing sheet 16 is higher than the rigidity of the back sheet 12. Furthermore, since the back sheet 12 is covered with the reinforcing sheet 16 by providing the reinforcing sheet 16, the weather resistance of the solar cell module 1 can be improved.

  The junction box 14 has a substantially rectangular parallelepiped box shape. When the solar cell module 1 is viewed in a direction orthogonal to the solar cell module 1, the battery region X in which the solar cells 2, 2, ... are disposed, and the peripheral portion surrounding the battery region X Y. In the present embodiment, two junction boxes 14 are provided. The junction boxes 14 and 14 are provided on the reinforcing sheet 16 at the peripheral edge Y on the back side of the module body 10. From the junction box 14, the cable 14a for taking out the electric power from the photovoltaic cells 2, 2,. The cable 14a is electrically connected to the solar cells 2, 2,.

  The frame body 4 is a member that extends along the peripheral edges of the cover glass 11, the back sheet 12, and the reinforcing sheet 16. The frame body 4 is a substantially rectangular frame body along the periphery of the solar cell module 1 as a whole, and the cross section is formed in a substantially U shape (or U shape). Specifically, the frame body 4 includes a front surface portion 41 that contacts the cover glass 11, a back surface portion 42 that contacts the reinforcing sheet 16, and a connecting portion 43 that connects the front surface portion 41 and the back surface portion 42. . The frame 4 is composed of silicone rubber, ethylene propylene rubber (EPDM), or rubber containing a metal plate as a core material. The frame body 4 is fitted into the peripheral portions of the cover glass 11, the back sheet 12 and the reinforcing sheet 16 with an adhesive tape made of butyl rubber interposed. The frame body 4 may be attached to the peripheral portions of the cover glass 11, the back sheet 12, and the reinforcing sheet 16 via an adhesive or the like instead of the moisture-proof tape.

  The mounting portions 5 and 5 are made of the same rubber material as that of the frame body 4 and are formed integrally with the frame body 4. The attachment portions 5 and 5 are respectively provided in a pair of opposing sides of the rectangular frame 4. Each attachment portion 5 is provided over the entire length of one side of the frame body 4. Each mounting portion 5 has a substantially L-shaped cross section. Specifically, the attachment portion 5 is connected to a standing wall portion 51 continuously extending downward from the connection portion 43 of the frame body 4 and a lower end of the standing wall portion 51, and an angle formed by the standing wall portion 51 is fixed at a substantially right angle. Part 52. That is, the attachment portion 5 extends downward from the lower end of the coupling portion 43 of the frame body 4 and then bends at a substantially right angle to the side opposite to the front surface portion 41 and the back surface portion 42 (that is, outward from the module body 10). is doing. A through hole 53 through which the cable 14 a from the junction box 14 is inserted is formed in the standing wall portion 51. A through hole 54 for inserting a screw (or screw) 55 is formed in the fixing portion 52.

  The connecting portion 43 of the frame body 4 is provided with a flap portion 44 that protrudes outward from the frame body 4 in plan view. The flap portion 44 is formed in a flat plate shape and is provided over the entire length of the connecting portion 43 in the longitudinal direction. The angle formed by the flap portion 44 and the connecting portion 43 is substantially a right angle. The protruding amount of the flap portion 44 from the connecting portion 43 is less than half of the protruding amount of the fixed portion 52 from the standing wall portion 51 (that is, the connecting portion 43).

  The heat insulating material 18 is provided on the back side of the module main body 10 and in a space surrounded by the reinforcing sheet 16, the standing wall portion 51 of the one mounting portion 5, and the standing wall portion 51 of the other mounting portion 5. ing. The heat insulating material 18 is made of a deformable foamed plastic. For example, the heat insulating material 18 is composed of phenol foam, polystyrene foam, urethane foam, or the like. The heat insulating material 18 is formed in a substantially flat plate shape. The heat insulating material 18 is bonded to the reinforcing sheet 16. At this time, the heat insulating material 18 and the fixing portions 52 and 52 of the mounting portions 5 and 5 are substantially flush with each other. Strictly speaking, as will be described later, the heat insulating material 18 is equal to the thickness of the butyl rubber 61 interposed between the fixing portion 52 and the ridge portion 71 when the attachment portion 5 is attached to the ridge portion 71 of the folded plate roof 7. This protrudes downward from the fixed portion 52.

  The plurality of solar cell modules 1, 1,... Configured in this way are arranged side by side on the folded plate roof 7, and the attachment portions 5, 5,. Specifically, first, the fixing portion 52 of the attachment portion 5 of one adjacent solar cell module 1 is installed on the ridge portion 71 of the folded plate roof 7 via the butyl rubber 61. Next, the fixing portion 52 of the attachment portion 5 of the other solar cell module 1 is overlaid on the fixing portion 52 of the one solar cell module 1. Subsequently, the butyl rubber 62 and the metal plate 63 are installed in this order on the fixing portion 52 of the other solar cell module 1. The butyl rubbers 61 and 62 and the metal plate 63 extend over the entire length of the fixed portion 52 in the longitudinal direction. Similarly, through holes are formed at positions corresponding to the through holes 54 of the fixing portion 52 in the butyl rubbers 61 and 62 and the metal plate 63. In this state, the screws 55 are inserted into the through holes 54 and 54 of the two fixing portions 52 and 52, and the screws 55 are fastened to the ridge portion 71 of the folded plate roof 7. Thus, one attachment portion 5 and the other attachment portion 5 are attached to the ridge portion 71 of the folded plate roof 7 by screw fastening. When the solar cell module 1 is thus attached to the folded roof 7, the heat insulating material 18 is in contact with the ridges 71, 71,. In addition, the height of the standing wall portion 51 of one attachment portion 5 is lowered by the thickness of the fixing portion 52 so that the module bodies 10 and 10 of the adjacent solar cell modules 1 and 1 have substantially the same height. ing.

  Here, a space sandwiched between the one frame body 4 and the attachment portion 5 and the other frame body 4 and the attachment portion 5 is formed between the adjacent solar cell modules 1 and 1. This space becomes an arrangement space 19 in which the cables 14a and 14a are arranged. That is, the cable 14 a from the junction box 14 passes through the through hole 53 of the standing wall portion 51 of the attachment portion 5 and is exposed to the outside of the attachment portion 5. The space outside the mounting portion 5 is just the installation space 19, and the cable 14 a is positioned in the installation space 19.

  The upper portion of the arrangement space 19 is partitioned by flap portions 44 and 44. Specifically, in a space sandwiched between the one frame body 4 and the attachment portion 5 and the other frame body 4 and the attachment portion 5, the flap portion 44 provided on the one frame body 4 and the other frame body 4 The provided flap portion 44 is in a state where the tips of the flaps 44 are close to each other, and the upper portion of the space is generally closed. Since the flap portion 44 is located above the through hole 53 of the standing wall portion 51, the cable 14 a is located in the arrangement space 19 defined by the flap portion 44.

  In this way, by making the upper portion of the arrangement space 19 substantially closed by the flap portions 44, 44, it is possible to prevent rain, dust, and dust from entering the arrangement space 19. Since the flap portions 44 and 44 are made of rubber and have flexibility, the flap portion 44 is turned when attaching the attachment portions 5 and 5 with the screws 55 or when working on the cables 14a and 14a. Work can be performed by raising or lowering.

  Therefore, according to this embodiment, the solar electromagnetic module 1 can be easily attached only by screwing the attachment portion 5 provided integrally with the frame body 4. In addition, the vibration of the solar cell module 1 can be damped by the mounting portion 5 by configuring the mounting portion 5 with rubber.

  Further, in the adjacent solar cell modules 1, 1, a space sandwiched between one frame body 4 and the attachment portion 5 and the other frame body 4 and the attachment portion 5 is used as an arrangement space 19 for the cables 14 a and 14 a. Thus, the cables 14a and 14a can be arranged in an orderly manner. At this time, it is possible to prevent rain, dust, and dust from entering the installation space 19 by providing the frame body 4 with the flap portion 44 and covering the upper portion of the installation space 19 with the flap portion 44. it can. Furthermore, workability at the time of attaching the attaching portion 5 and working the cable 14a can be improved by making the flap portion 44 made of rubber.

  Moreover, the load of the solar cell module 1 which acts on the attachment parts 5 and 5 can be reduced by providing the heat insulating material 18 which contact | abuts the folded-plate roof 7 used as installation object in the back side of the solar cell module 1. FIG. . That is, the load of the solar cell module 1 is transmitted not only to the folded plate roof 7 via the attachment portions 5 and 5 but also to the folded plate roof 7 via the heat insulating material 18. Therefore, even if it is the rubber attachment parts 5 and 5, the solar cell module 1 can be attached firmly.

  Furthermore, since the member that contacts the folded plate roof 7 is the heat insulating material 18, the conduction of heat from the folded plate roof 7 to the solar cell module 1 can be suppressed. That is, since the sunlight is directly irradiating the portion of the folded roof 7 where the solar cell module 1 is not provided, the temperature becomes high. The heat is transmitted through the folded plate roof 7, and the portion located below the solar cell module 1 also becomes high temperature. However, since the heat insulating material 18 exists between the module body 10 and the folded plate roof 7, heat conduction from the folded plate roof 7 to the solar cell module 1 is suppressed. As a result, it is possible to prevent the efficiency of the solar cell module 1 from being lowered due to a high temperature.

  Furthermore, in the present embodiment, by adopting the solar cell module 1 that is lightened by providing the resin plate 15 inside the cover glass 11, the rubber mounting portions 5, 5,... The solar cell module 1 can be firmly attached. That is, by providing the resin plate 15 inside the cover glass 11, it is possible to make the cover glass 11 difficult to break, and thus the cover glass 11 can be made thin. As a result, the solar cell module 1 can be reduced in weight. Thus, if the light-weight solar cell module 1 is used, the strength required for the mounting structure is low, so that the solar cell module 1 can be mounted with sufficient strength even with the rubber mounting portions 5, 5,. Can do. However, depending on the strength of the attachment portion 5, the solar cell module 1 can be firmly attached even if it is not the lightened solar cell module 1 as described above.

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  For example, the solar cell module 1 is not limited to the above configuration. The resin plate 15, the reinforcing sheet 16, or the heat insulating material 18 may be omitted. Further, instead of the cover glass 11, a resin top sheet may be employed.

  Moreover, the solar cell module 1 is not restricted to what is attached to the folded-plate roof 7, The structure attached to the roof part of a slate roof, a tile roof, or a concrete building may be sufficient. Further, the solar cell module 1 may be configured to be attached to a wall surface or the ground.

  Moreover, in the said embodiment, although the two junction boxes 14 and 14 are provided with respect to one solar cell module 1, it is not restricted to this. There may be one junction box 14 or three or more. The junction box 14 is not limited to the back side of the module body 10 and may be provided on the surface side of the module body 10. Alternatively, the junction box 14 may be provided at the small edge of the module body 10 (that is, the side peripheral surface connecting the front surface and the back surface of the module body 10).

  Furthermore, the frame 4 is not limited to the above configuration. For example, in the frame body 4, a cut extending in the longitudinal direction is formed on the outer surface of the surface portion 41 and / or the connecting portion 43, and rubber or resin harder than the surface portion 41 and / or the connecting portion 43 is formed in the cut. It may be a loaded configuration. By carrying out like this, while the surface part 41 and / or the connection part 43 are extended so that an outer surface may extend, an inner surface shrinks, and it can improve the adhesiveness of the frame 4, the cover glass 11, and the reinforcement sheet 16. .

  The attachment portion 5 is formed continuously with the connecting portion 43 of the frame body 4, but is not limited thereto. For example, the attachment portion 5 may extend from the back surface portion 42 of the frame body 4, and any configuration can be adopted as long as the attachment portion 5 is configured integrally with the frame body 4. Here, the integral configuration is not limited to the case where the frame body 4 and the attachment portion 5 are integrally formed of a rubber material, but the frame body 4 and the attachment portion 5 that are formed separately are bonded or bonded. This includes the case where they are integrally coupled by screw fastening or the like. For example, the structure which couple | bonded the attachment part 5 made from rubber | gum with the resin-made or metal frame 4 may be sufficient.

  The metal plate 63 and butyl rubber are not essential and may be omitted. Further, the metal plate 63 may be a resin plate.

  Moreover, in the structure which attaches the attaching part 5 to the inclined surface of the folded-plate roof 7 instead of the ridge part 71 of the folded-plate roof 7, the fixing | fixed part 52 is comprised so that it may become an attitude | position along an inclined surface instead of horizontal. May be. Furthermore, the structure which attaches the fixing | fixed part 52 to the beam 73 via the bis | screw 55 instead of the ridge part 71 of the folded-plate roof 7 may be sufficient. That is, the folded-plate roof 7 mounts the roof material 70 on the beam 73, and bolts the roof material 70 with respect to the beam 73 (refer FIG. 1). Therefore, the fixing portion 52 may be attached to the beam 73 instead of the roof material 70.

  Furthermore, the attachment portion 5 is not limited to the one provided over the entire length of one side of the rectangular frame 4, and may be provided partially on one side of the frame 4. In addition, the rectangular frame 4 is provided with two attachment portions 5 and 5 on a pair of opposing sides, but the attachment portions 5 may be provided on all four sides. The attachment portion 5 may be provided on three of the sides.

  Furthermore, in the said embodiment, the standing wall part 51 of one attachment part 5 and the standing wall part 51 of the other attachment part 5 are so that the module main bodies 0 and 10 of the adjacent solar cell modules 1 and 1 may become substantially the same height. Is different by the thickness of the fixing portion 52, but is not limited thereto. It is not always necessary to make the heights of adjacent module bodies 10 and 10 uniform.

  Moreover, the flap part 44 is not restricted to the said structure. Although the flap part 44 is provided in the connection part 43 of the frame 4, it is not restricted to this. The flap portion 44 may be provided on the attachment portion 5. However, it is preferable that the flap portion 44 is provided above the through-hole 53 through which the cable 14 a is inserted in the attachment portion 5. Further, the flap portion 44 extends horizontally, that is, vertically from the connecting portion 43 of the frame body 4, but is not limited thereto. For example, the flap portion 44 may extend so as to become lower toward the distal end side, or conversely, may extend so as to become higher toward the distal end side.

  Further, although the two flap portions 44 and 44 in the arrangement space 19 are not in contact with each other, the two flap portions 44 and 44 may be in contact with each other. For example, a configuration in which the tip of one flap portion 44 rides on the tip of the other flap portion 44 may be employed. In the case of such a configuration, it is possible to further suppress rain, dust and dust from entering the arrangement space 19. Alternatively, one flap portion 44 and the other flap portion 44 are provided at different positions in the vertical direction (that is, in a step difference), and the front end portion of one flap portion 44 and the front end portion of the other flap portion 44 are upward. You may be comprised so that it may overlap when it sees from. Even in such a configuration, it is possible to further suppress rain, dust, and dust from entering the installation space 19.

  Further, although two flap portions 44, 44 are provided in one arrangement space 19, the present invention is not limited to this. In the adjacent frames 4, 4, the flap portion 44 may be provided only on one frame 4, and the flap portion 44 may not be provided on the other frame 4. In this case, it is preferable that the flap portion 44 extends to the frame body 4 where the flap portion 44 is not provided. In this way, even with only one flap portion 44, the upper portion of the arrangement space 19 can be substantially covered.

  In addition, the flap part 44 does not need to be provided in the frame 4 and the attachment part 5. In that case, the arrangement space 19 is open upward. If the waterproof performance of the cable 14a and the waterproof performance of the mounting structure of the mounting portion 5 are high, this may be left as it is. In order to prevent rain, dust, and dust from entering the installation space 19, a lid member that covers the upper side of the installation space 19 may be separately provided.

  In addition, in the adjacent solar cell modules 1 and 1, the fixing portion 52 of one attachment portion 5 and the fixing portion 52 of the other attachment portion 5 are attached in an overlapped manner, but they are attached separately without overlapping both. You may do it.

  Moreover, the structure as shown in FIG. 3 may be sufficient as an attaching part. Specifically, the attachment portion 205 is reinforced with a metal plate 256. The metal plate 256 is bent similarly to the standing wall portion 51 and the fixed portion 52 and has an L-shaped cross section. The metal plate 256 is bonded to the standing wall portion 51 and the fixed portion 52.

  Or a structure as shown in FIG. 4 may be sufficient as an attaching part. Specifically, the attachment portion 305 is reinforced with a metal plate 356. The metal plate 356 is bent in the same manner as the standing wall portion 51 and the fixed portion 52, and further bent along the back surface portion 42 of the frame body 4. The metal plate 356 is bonded to the back surface portion 42, the standing wall portion 51, and the fixing portion 52. At this time, a folded portion 42a that is folded downward is provided at the tip of the back surface portion 42, and one end edge of the metal plate 356 is fitted into the folded portion 42a.

  Further, the solar cell module may be configured as shown in FIG. Specifically, in the solar cell module 201, the heat insulating material 218 extends to below the fixing portion 52 of the attachment portion 5. More specifically, among the two attachment portions 5 and 5 of the solar cell module 201, in the attachment portion 5 on which the attachment portion 5 of the adjacent solar cell module 201 is placed, the heat insulating material 218 is below the fixing portion 52. The heat insulating material 218 does not extend below the fixed portion 52 in the mounting portion 5 that is placed on the mounting portion 5 of the adjacent solar cell module 201. By doing so, the attachment portions 5 and 5 of the adjacent solar cell modules 201 and 201 are attached to the folded plate roof 7 in a state where the two fixing portions 52 and 52 are stacked on the heat insulating material 218. In the case of such a configuration, since the heat insulating material 218 has a certain degree of rigidity, even if the position of the fixing parts 52, 52 is not located on the ridge part 71 of the folded plate roof 7, It can be attached to the folded plate roof 7. In the case of this configuration, the screw 55 may be fastened to the valley portion 72 of the folded plate roof 7 or may be fastened to the beam 73. In addition, when attaching the fixing | fixed part 52,52 to the ridge part 71 of the folded-plate roof 7, the lower part of the fixing | fixed part 52 is the heat insulating material of two adjacent solar cell modules 201,201 among the heat insulating materials 18. FIG. 18 and 18 may be separate heat insulating materials.

  Moreover, as shown in FIG. 6, the solar cell module may have a configuration in which a cable installation space is not provided. Specifically, in the frame 304 of one of the two adjacent solar cell modules 301, 301, the attachment portion 305 is fixed so as to form a flat plate together with the back surface portion 342 from the lower end of the connection portion 343. A portion 352 extends outward from the frame 304. In the frame 304 of the other solar cell module 301, the upright wall portion 351 of the attachment portion 305 extends by the thickness of the fixed portion 352 from the lower end of the connecting portion 343, and the fixed portion 352 extends from the lower end of the upright wall portion 351. It extends outward from the frame 304 so that the angle formed with 352 is substantially a right angle. The frame 304 is not provided with the flap portion 44 of the above embodiment. The heat insulating material 218 has the same configuration as described above, and extends to the lower side of the fixed portion 352. In such a configuration, the cable 14 a extending from the junction box 14 is disposed below the heat insulating material 218 through the heat insulating material 218 in the thickness direction.

  Further, the solar cell module may be configured as shown in FIG. Specifically, in the solar cell module 401, the attachment portion 405 includes an upper wall portion 451, a lower wall portion 452, and a connecting portion 453 that connects the upper wall portion 451 and the lower wall portion 452, and as a whole. The flat plate is bent in two. End portions of the upper wall portion 451 and the lower wall portion 452 on the side opposite to the connecting portion 453 protrude outward from the frame body 404. That is, the attachment portion 405 has a U-shaped cross section and opens toward the outside of the frame body 404. The lower wall portion 452 is formed integrally with the back surface portion 442 of the frame body 404. The attachment portion 405 is configured to sandwich the metal plate 63 between the upper wall portion 451 and the lower wall portion 452. Then, the metal plate 63 sandwiched between the two adjacent attachment portions 405 and 405 is attached to the folded plate roof 7 via the screws 55. The heat insulating material 218 has the same configuration as described above, and extends below the attachment portion 405 and the metal plate 63.

  Further, a protective sheet may be provided on the outer peripheral surface of the heat insulating material 18. The protective sheet is a sheet for protecting the heat insulating material 18, for example, a sheet obtained by bonding a metal plate such as an aluminum alloy or a galvalume steel plate to a vinyl chloride waterproof sheet or a polyolefin waterproof sheet, and the metal plate A sandwich panel of resin and the metal plate is bonded to the waterproof sheet, or a laminated sheet in which a PET sheet, an aluminum sheet, and a fluororesin film are laminated. It is preferable that this protective sheet can be easily cut. That is, when the solar cell module 1 is installed on the roof, it is preferable that the portion of the protective sheet corresponding to the protruding portion such as a bolt or a nut can be easily cut to expose the heat insulating material 18 at the site. .

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a solar cell module and a solar cell system including the solar cell module.

1 Solar cell module 11 Cover glass (top sheet)
12 Back sheet 13 Sealing material 14a Cable 15 Resin plate 19 Space 2 Solar cell (solar cell element)
4 Frame 44 Flap part 5 Attachment part 7 Folded plate roof 100 Solar cell system

Claims (4)

Opposing topsheet and backsheet;
A solar cell element provided between the top sheet and the back sheet;
A solar cell module comprising a frame body surrounding the top sheet and the back sheet,
The solar cell module which is comprised with rubber | gum, and the attachment part for attaching a solar cell module to installation object is integrally provided in the said frame with the said frame. The solar cell module according to claim 1, wherein
The frame body is provided with a flap portion protruding outward from the frame body,
A solar cell module in which a disposition space for disposing a cable electrically connected to the solar cell element is formed below the flap portion. A solar cell system including a plurality of solar cell modules,
Each of the solar cell modules is
Opposing topsheet and backsheet;
A solar cell element provided between the top sheet and the back sheet;
A frame surrounding the top sheet and the back sheet;
A cable electrically connected to the solar cell element;
The frame body is made of rubber, and an attachment portion for attaching the solar cell module to an installation target is provided integrally with the frame body,
Between the adjacent solar cell modules, an arrangement space for arranging the cable, which is sandwiched between the frame body of one solar cell module and the frame body of the other solar cell module, is formed. Solar cell system. In the solar cell system according to claim 3,
A solar cell module in which at least one of the frame bodies of the adjacent solar cell modules is provided with a flap portion that protrudes outward from the frame body and covers an upper portion of the arrangement space.

Images