JP2009299465A - Solar cell module and roof structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solar cell module which hardly causes a breakage in a solar cell panel even if an external force acts on the eaves side of the solar cell module when the solar cell module is laid along the edge of the eaves of a building, and to provide a roof structure. <P>SOLUTION: This solar cell module 10 is laid on the top surface of the building so as to constitute a roof R. Characteristically, the solar cell module 10 includes the solar cell panel 12 which is formed in an approximately oblong planar shape by having a plurality of solar cells electrically and serially connected together, and a front cover 102 for covering the whole eaves-side end surface of the solar cell panel 12. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a solar cell module laid on the upper surface of a building and a roof structure on which the solar cell module is laid.

  Conventionally, there has been an increase in solar power generation systems that lay solar cell modules with solar cell panels on the top of a building, etc. to construct a roof, cover the power consumed by the building, and sell surplus power to power companies. ing. A solar cell panel is an integrated solar cell, in which a conductive film or a semiconductor film is laminated on a glass substrate, and a plurality of grooves are provided on the glass substrate to form a predetermined number of unit cells (solar cell). Are electrically connected in series, and it is also known that a voltage of 100 volts or more can be obtained. The following Patent Document 1 discloses a method for manufacturing such a solar cell panel.

Japanese Patent Laid-Open No. 11-298017

  In the conventional solar cell module, the end surface on the eaves side of the solar cell panel is not protected. Moreover, the solar cell panel is configured by combining members formed of a material that is vulnerable to impact, such as a glass substrate. Therefore, when the conventional solar cell module is arranged along the eaves edge, for example, when an external force acts on the eaves side of the solar cell module due to a ladder standing on the eaves edge, the solar cell panel may be damaged. .

  Further, in recent years, by increasing the length of the solar cell panel in the digit direction, the output per solar cell panel has been increased and the manufacturing cost per solar cell module has been reduced. However, when the length of the solar cell panel in the spar direction increases, when the solar cell module is actually laid on the top surface of the building, the area on which the wind blowing from the eaves side along the roof surface increases. In particular, a large blowing force is applied to the solar cell module arranged at the eaves, and the solar cell module may be lifted or scattered. Therefore, it has been difficult to lay the conventional solar cell module along the eaves of the roof.

  Therefore, the present invention provides a solar cell module and a roof that are less likely to damage the solar cell panel even when an external force acts on the eaves side of the solar cell module when the solar cell module is laid along the eaves of the building. It is an object to provide a structure. It is another object of the present invention to provide a solar cell module and a roof structure that can strongly resist the blowing force acting on the solar cell module.

  The invention of claim 1 provided to solve the above problem is a solar cell module laid on the upper surface of a building to constitute a roof, wherein a plurality of solar cells are electrically connected in series and are substantially rectangular. A solar cell module comprising: a solar cell panel formed in a planar shape; and a front cover that covers the entire eaves side end surface of the solar cell panel.

  In the solar cell module of the present invention, the entire end surface on the eaves side of the solar cell panel is protected by the front cover. Therefore, even if an external force acts on the solar cell module from the eaves side, such as when a ladder is leaned against the solar cell module placed on the eaves of the roof, most of the external force is absorbed by the front cover. Therefore, it is hardly transmitted to the solar cell panel. Therefore, the solar cell module of the present invention is less likely to be damaged by the external force acting from the eaves side.

  The invention of claim 2 is characterized in that, in the invention of claim 1, the front cover is provided with a drain hole.

  Thereby, the solar cell module of this invention can discharge | emit the water which flows from the ridge side to the eaves side from a drain hole, and can prevent that water accumulates in a solar cell module.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the front cover extends over a part of the light receiving surface of the solar cell panel.

  Thereby, the solar cell module of this invention can improve the rigidity of a front cover. Therefore, the solar cell module of the present invention can reliably protect the solar cell panel from an external force acting from the eaves side. In particular, in the solar cell module of the present invention, since the front cover extends to a part of the light receiving surface (upper surface) of the solar cell panel, the solar cell panel is surely secured even when an external force is applied from above the eaves side. Can be protected.

  The invention of claim 4 is characterized in that, in the invention of claim 3, a gap having a predetermined width is provided between the front cover and the light receiving surface of the solar cell panel.

As a result, in the solar cell module of the present invention, the front cover that covers the light receiving surface of the solar cell panel effectively prevents snow falling on the solar cell panel.
In the solar cell module of the present invention, a gap having a predetermined width is provided between the front cover and the light receiving surface of the solar cell panel. It is possible to prevent thermal cracking from occurring in the battery panel.

  According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, the front cover extends to a part of the lower surface of the solar cell panel to form a locking piece, and the locking piece It is characterized in that it can be engaged with a blow-up prevention device arranged.

Thereby, the solar cell module of this invention can improve the rigidity of a front cover. Therefore, the solar cell module of the present invention can reliably protect the solar cell panel from an external force acting from the eaves side.
Further, when the solar cell module of the present invention is laid on the upper surface of a building, it can be firmly fixed to the building by engaging the locking piece of the front cover with the lower blowing prevention tool. Therefore, even when wind blows along the roof surface from the eaves side, and the blowing force acts on the solar cell module, the solar cell module of the present invention has the eaves side end firmly held by the blowing prevention tool. Therefore, it is possible to strongly resist the blowing force, and the floating and scattering are effectively prevented.

  The invention of claim 6 is a roof structure characterized in that the solar cell module according to any one of claims 1 to 5 is laid on the upper surface of a building.

  As a result, the roof structure of the present invention, even when an external force is applied from the eaves side, since the eave side of the solar cell module is protected by the front cover, the solar cell panel of the solar cell module is damaged by the external force. Can be effectively prevented.

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

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

  The solar cell module and the roof structure of the present invention can prevent the solar cell panel of the solar cell module from being damaged even when an external force is applied from the eaves side of the building.

It is a perspective view which shows the solar cell module of this embodiment. It is a disassembled perspective view of the solar cell module of FIG. It is a perspective view which shows the structure of the back surface side of the solar cell module of FIG. It is sectional drawing of the connector of the solar cell module of FIG. It is sectional drawing which shows the state in which the solar cell module of FIG. 1 was attached to the eaves of the upper surface of a building. It is a perspective view of a hook metal fitting. It is a fragmentary perspective view of a front cover. It is a perspective view of an eaves tip blowing prevention metal fitting. It is a perspective view which shows the state which attaches an eaves tip blowing prevention metal fitting to the eaves tip of the upper surface of a building. It is a top view which shows the state which attached the eaves tip blowing prevention metal fitting to the eaves tip of the upper surface of a building. It is a perspective view for demonstrating the attachment of the solar cell module to the eaves of the upper surface of the building in the roof structure of this embodiment, (a) shows the state before attachment, (b) is the state after attachment. Indicates. It is a perspective view explaining attachment of the solar cell module after the 2nd step in the roof structure of this embodiment. It is a fragmentary sectional view explaining attachment of the solar cell module after the 2nd step in the roof structure of the present invention. It is a flowchart which shows the work procedure of the laying structure of a solar cell module. It is explanatory drawing which shows the state which laid the solar cell module on the roof of a building. It is a conceptual diagram which shows the module stage to which the solar cell module was correctly wired. It is a conceptual diagram which shows the module stage to which the solar cell module was wired accidentally. It is a circuit diagram when a solar cell module is correctly wired. It is a conceptual diagram which shows the laying structure of a solar cell module. (A) is a front view of a lead-in cable, (b) is sectional drawing of the mold part of a lead-in cable. It is a top view of a terminal protection member.

Next, the roof structure embodying the present invention will be described in detail with reference to the drawings. The roof structure of this embodiment is formed by laying a tile-shaped solar cell module on the upper surface of a newly built or existing building using an eaves tip blowing prevention metal fitting.
FIG. 1 is a perspective view showing a solar cell module used in the present invention. FIG. 2 is an exploded perspective view of the solar cell module of FIG. FIG. 3 is a perspective view showing the structure of the back surface side of the solar cell module of FIG. 4 is a cross-sectional view of the connector of the solar cell module of FIG. The positional relationship between the top, bottom, left and right is based on the positional relationship of the building as viewed from the eaves side.

  As shown in FIG. 1, the solar cell module 10 is configured by mounting a solar cell panel 12, a front cover 102, a hook metal fitting 84, and the like on a base 82 configured by attaching a reinforcing heat insulating material 90 to a base material 70. Is done.

  The solar cell panel 12 is an integrated solar cell and is formed in a substantially rectangular surface. In the solar battery panel 12, for example, a conductive film or a semiconductor film is laminated on a glass substrate, and a plurality of grooves are provided in the glass panel to form a predetermined number of unit cells (solar battery cells). Those connected in series can be used. One solar cell panel 12 of the present embodiment can obtain a voltage of about 100 volts.

  As shown in FIGS. 2 and 3, the solar cell panel 12 has a terminal box 14 attached to the back surface, and two cables 16 and 18 are extended from the terminal box 14. As shown in FIG. 1, the first cable 16 and the second cable 18 are a plus-side core wire 24 that is a coated conductor connected to the positive electrode of the solar cell panel 12 and a coated conductor connected to the negative electrode of the solar cell panel 12. And the negative side core wire 26. That is, the first cable 16 and the second cable 18 are obtained by bundling two covered conductors by the insulating tubes 16a and 18a.

  As shown in FIG. 1, the first cable 16 and the second cable 18 are long and short, one is long and the other is short. Specifically, the first cable 16 is shorter than the second cable 18. The total length of the first cable 16 is less than 50% of the length of the long side of the rectangular solar cell panel 12, and the total length of the second cable 18 is the length of the long side of the solar cell panel 12. 50 percent or more.

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

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

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

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

  As shown in FIG. 2, the base material 70 is a substantially rectangular plate material, and is formed by bending one or a plurality of metal plates into a predetermined shape. In the case where the base material 70 is formed of a single metal plate, it can be easily processed and the manufacturing cost can be suppressed, and a structure having no joining portion can be provided, which is advantageous in terms of strength. It becomes. Therefore, considering these advantages, it is desirable that the base material 70 be formed by bending a single metal plate.

  In the base material 70 formed as described above, a ridge for fixing the ridge side of the solar cell panel 12 arranged in the cover attaching portion 72, the solar cell arrangement portion 74, and the solar cell arrangement portion 74 in order from the eaves side. A side fixing portion 76, a solar cell module 10 disposed adjacent to the ridge side (upper stage), and a stacking portion 78 on which an eaves side end of the general roof tile is stacked are formed. A groove-shaped flange 80 is formed on the side of the base material 70. It is preferable to use a metal plate such as a steel plate, aluminum, and stainless steel for the base material 70. In this embodiment, a galvalume steel plate is used.

  As shown in FIG. 5, the cover attachment portion 72 is a portion to which a front cover 102 described later is attached, and is formed by bending the eaves side end portion of the base material 70 substantially at right angles to the back surface side.

  The solar cell arrangement portion 74 is a planar portion on which the solar cell panel 12 is arranged, and is formed to have approximately the same size as the solar cell panel 12. As shown in FIG. 2, an opening 74 a for inserting the terminal box 14 of the solar cell panel 12 is provided at substantially the center of the solar cell arrangement portion 74. In the solar cell module 10 of the present embodiment, the solar cell panel 12 is mounted from the surface side of the substrate 70, and the terminal box 14, the cables 16, 18 and the connectors 20, 22 have openings 74a as shown in FIG. It is disposed on the back side of the base material 70.

  As shown in FIG. 5, the ridge side fixing portion 76 is a portion that fixes the ridge side of the solar cell panel 12 arranged in the solar cell arrangement portion 74. The ridge-side fixing part 76 is formed by bending the base material 70 at a predetermined position to the front surface side at a substantially right angle, and by bending the base material 70 at the predetermined position from the base end of the rising part 76a. A surface pressing portion 76b. The rising portion 76a is a portion where the ridge side end surface of the solar cell panel 12 abuts, and the surface pressing portion 76b covers a part of the surface (light receiving surface) of the solar cell panel 12 and applies a pressing force from the surface side. Part.

  The loading portion 78 is a planar portion formed by folding the base material 70 toward the ridge side at a predetermined position from the base end of the surface pressing portion 76b of the ridge side fixing portion 76. As shown in FIG. 2, a through hole 78 a for attaching a hook 84 to be described later is provided at a predetermined position of the stacking portion 78, and a solar cell module is provided at a predetermined position on the ridge side of the through hole 78 a. A through hole 78b is provided for driving a screw for fixing 10 to the building.

  As shown in FIG. 6, the hook metal 84 is a metal plate bent into a crank shape, and is fixed between a fixed portion 86 fixed at a predetermined position on the surface of the stacking portion 78 and the surface of the stacking portion 78. And an engaging portion 88 that forms a gap. The hook metal fitting 84 is fixed to the stacking portion 78 with the fixing portion 86 disposed on the ridge side and the engaging portion 88 disposed on the eaves side. The fixing portion 86 is provided with a slit 86a having one open end, and the hook metal 84 can be fixed to the stacking portion 78 by tightening a rivet or fixing screw 122 inserted into the slit 86a. . Further, by moving the hook metal 84 along the slit 86a, the hook metal 84 can be easily detached from the stacking portion 78.

  As shown in FIG. 3, the reinforcing heat insulating material 90 is a foamed resin member that is attached to the back surface of the base material 70 in order to ensure the strength and heat insulating properties of the solar cell module 10. The reinforcing heat insulating material 90 extends in the eave direction from both ends of the girder direction reinforcing portion 92 extending in the girder direction along the long side of the base material 70 on the ridge side, and the girder direction reinforcing portion 92 along the short side of the base material 70. And an inclination direction reinforcing portion 94. The inclination direction reinforcing portion 94 is a portion that is stacked on the stacking portion 78 or the general roof tile of the solar cell module 10 disposed adjacent to the eave side (lower stage), and is formed thinner than the beam direction reinforcing portion 92. Has been.

  The reinforcing heat insulating material 90 is not attached to the entire back surface of the base material 70, but is disposed along the peripheral edge portion of the base material 70. Therefore, an accommodation space 96 is formed on the back surface of the base material 70 so as to be surrounded by the reinforcing heat insulating material 90 and open on the eaves side. A terminal box 14 is disposed substantially at the center of the accommodation space 96. The accommodation space 96 can accommodate the wired cables 16 and 18.

  Three cable grooves 98 are provided on the surface of the reinforcing heat insulating material 90 opposite to the surface attached to the base material 70 of the beam direction reinforcing portion 92. The cable groove 98 penetrates from the ridge side of the reinforcing heat insulating material 90 to the eaves side, and connects the inside and outside of the accommodation space 96. One of the cable grooves 98 is a central groove 98a that is disposed substantially at the center of the girder-direction reinforcing portion 92, and the other is a side groove 98b that is disposed on the left and right of the central groove 98a with a predetermined distance from the central groove 98a. 98b. In the solar cell module 10, the central groove 98 a and the terminal box 14 are arranged on substantially the same straight line, and the cables 16 and 18 extending from the terminal box 14 pass through the central groove 98 a from the accommodation space 96 to the ridge side. Has been pulled out of. The side grooves 98b and 98b are used for wiring with other solar cell modules 10 arranged adjacent to the upper and lower stages.

  As shown in FIG. 2, the front cover 102 is a long metal material, and has a substantially “U” cross-sectional shape in order to increase rigidity. As shown in FIG. 5 and FIG. 7, the front cover 102 includes a fixing portion 104 (end surface protection portion) disposed along the cover mounting portion 72 of the base material 70, and the solar cell panel 12 on the surface side of the base material 70. The eaves side fixing | fixed part 106 arrange | positioned so that a part of light-receiving surface may be covered, and the latching piece 108 arrange | positioned at the back surface side of the base material 70 are provided.

As shown in FIG. 5, when the fixing portion 104 of the front cover 102 and the cover mounting portion 72 of the base material 70 are fixed with screws 124, the surface of the solar cell placement portion 74 of the base material 70 and the front cover 102 A gap larger than the plate thickness of the solar cell panel 12 is formed between the eaves side fixing portion 106. The elongate side of the solar cell panel 12 is inserted into this gap. A gasket (not shown) is attached to the long side of the eaves side of the solar cell panel 12, and a gap generated between the eaves side fixing portion 106 of the front cover 102 and the light receiving surface of the solar cell panel 12 is sealed by the gasket. Has been. Since the pressing force of the eaves side fixing portion 106 of the front cover 102 acts on the solar cell panel 102 from the front surface side, the long side of the eaves side of the solar cell panel 12 is the surface of the eave side fixing portion 106 and the base material 70. It is sandwiched between and fixed.
At this time, the end surface on the eaves side of the solar cell panel 12 is covered and protected by the fixing portion 104 of the front cover 102.

  When the front cover 102 is attached to the base material 70, a predetermined width is provided between the locking piece 108 of the front cover 102 and the inclined direction reinforcing portion 94 of the reinforcing heat insulating material 90 attached to the back surface of the base material 70. A gap is formed. In this gap, an engaging portion 88 of the hook metal 84 and an engaged portion 112 of an eaves tip blowing prevention metal 110 described later are inserted.

  As shown in FIGS. 1, 5, and 7, a drain hole 104 a is provided at a predetermined position of the fixing portion 104 of the front cover 102. In the roof structure according to the present embodiment, when a plurality of solar cell modules 10 are arranged in the girder direction with the short sides adjacent to each other, the eaves side of the flange portion 80 of the solar cell module 10 by the front cover 102 of the adjacent solar cell module 10. The edge is covered. However, in the solar cell module 10 of the present embodiment, since the drain hole 104a is provided at a predetermined position of the fixing portion 104 of the front cover 102, the flow of water flowing through the flange 80 is caused by the adjacent solar cell module 10. Without being blocked by the front cover 102, the water is discharged to the eaves side through the drain hole 104a.

  In the roof structure of this embodiment, when the solar cell module 10 is laid on the eaves on the upper surface of the building, the eaves blowing prevention metal fitting 110 is fixed to the eaves on the upper surface of the building, and the eave side of the solar cell module 10 disposed on the eaves The solar cell module 10 is prevented from being blown up and scattered by holding the end portion on the eaves tip blow-up prevention metal fitting 110.

  As shown in FIG. 8, the eaves tip blowing prevention metal fitting 110 is a metal plate having an engaged portion 112 arranged to protrude from the eaves end to the outside of the building and a fixing portion 114 fixed to the upper surface of the building. It is. The fixing portion 114 is an area on the ridge side of the eaves-end blowing prevention metal fitting 110, and a plurality of long holes 116 extending in the girder direction are provided at predetermined positions. As shown in FIG. 5, the periphery of the long hole 116 protrudes to the back side of the eaves tip blowing prevention metal fitting 110 to form a convex portion 118, and is used for positioning the eaves tip blowing prevention fitting 110. As shown in FIG. 8, a through hole 114 a is provided at a predetermined position of the fixing portion 114 of the eaves tip blowing prevention metal fitting 110 so as to penetrate a screw for fixing the eaves tip blowing prevention fitting 110 to the building. The engaged portion 112 is a region on the eaves side of the eaves tip blowing prevention metal fitting 110, and is formed by bending the eaves tip blowing prevention metal fitting 110 to the back surface side by a predetermined angle. In addition, the eaves tip blowing prevention metal fitting 110 of the present embodiment is provided with a notch 120 having a predetermined size at the right end of the beam direction.

  As shown in FIG. 9 and FIG. 10, in the roof structure of the present embodiment, two types of eaves edge blowing prevention metal fittings 110 a and 110 b having different girder lengths are used as the eaves edge blowing prevention metal fitting 110. The eaves tip blowing prevention metal fitting 110a is a long member whose length in the girder direction is formed substantially the same as the length in the girder direction of the solar cell module 10, and the eaves tip blowing prevention metal fitting 110b has a length in the girder direction in the solar cell module. It is a short member formed in approximately half of the length in the 10 digit direction.

  Next, an operation procedure for laying the above-described solar cell module 10 on the upper surface of a building and a roof structure will be described. FIG. 14 is a flowchart showing a work procedure for laying the solar cell module 10 on the upper surface of a building.

As shown in FIG. 9, when laying the solar cell module 10, first, an eaves drainer 126 and a predetermined roofing material 128 are attached to the upper surface of the building to be laid. Inking is performed to display the shape and dimensions on the top of the building.
In subsequent step 2, vertical piers (sink bars) 130 are attached at predetermined intervals, and in step 3, Hirokomai (tile) 132 and horizontal piers (tile) 134 are attached. The horizontal crosspiece 134 is attached at a predetermined climbing interval. Next, in step 4, the eaves tip blowing prevention metal fitting 110 for preventing the solar cell module 10 attached to the eaves from blowing up is attached at a predetermined position.

  In the roof structure of this embodiment, when the solar cell module 10 is installed at the eaves, a plurality of eaves blow-up prevention fittings 110 are arranged and fixed in a row at the eaves of the building. As shown in FIG. 10, among the plurality of eaves tip blowing prevention metal fittings 110 arranged in a row, the eaves tip blowing prevention metal fittings 110 arranged at both ends of the row have a girder length in the girder direction of the solar cell module 10. The eaves tip blowing prevention metal fitting 110b is formed in approximately half of the length of the eaves tip blowing prevention metal fitting 110b. It is the eaves tip blowing prevention metal fitting 110a formed substantially the same as the length of the direction.

  As shown in FIG. 9, as an operation procedure, first, an eaves tip blowing prevention metal fitting 110 b is arranged at the right end of the eaves region of the building where the solar cell module 10 is fixed. As shown in FIG. 5, the eaves tip blowing prevention metal fitting 110 b can be easily positioned by bringing the projection 118 of the elongated hole 116 of the eaves tip blowing prevention metal fitting 110 b into contact with the end portion of the eaves side blowing 132. Can do. After the eaves tip blowing prevention metal fitting 110b is positioned, a fixing screw 136 is driven into the through hole 114a of the fixing portion 114 of the eaves tip blowing prevention metal fitting 110b, and the eaves tip blowing prevention metal fitting 110b is fixed to the building. At this time, in order to fix the eaves tip blowing prevention metal fitting 110b to the building more firmly, it is desirable that the fixing screw 136 penetrates the wide dance 132 and the field plate 138 to reach the nose cover 140 as shown in FIG.

  As shown in FIG. 9, the roof tile 142 disposed on the right side of the eaves tip blowing prevention metal fitting 110 b in the spar direction is fastened by a construction screw 144 and a 7-type nail 146. At this time, the 7-type nail 146 is driven into the notch portion 120 provided at the right end of the eaves tip blowing prevention metal fitting 110b in the digit direction.

  After the eaves tip blowing prevention metal fitting 110b is attached, a predetermined number of eaves tip blowing prevention metal fittings 110a are continuously arranged in the digit direction on the left side of the eaves tip blowing prevention metal fitting 110b. 110a are arranged in two). The eaves tip blowing prevention metal fitting 110a is also positioned in the same manner as the eaves tip blowing prevention metal fitting 110b, and is fixed to the building by the fixing screw 136. When all the eaves tip blowing prevention metal fittings 110a are attached, the eaves tip blowing prevention metal fittings 110b are fixed to the left end in the digit direction of the region where the solar cell module 10 at the eaves tip is fixed. After the eaves tip blowing prevention metal fitting 110b is attached, the operation shifts to Step 5.

  In step 5, the solar cell modules 10 are sequentially attached from the eaves side to the ridge side of the upper surface of the building, and the adjacent solar cell modules 10 and 10 are connected by the cables 16 and 18 to form the roof R. As shown in FIG. 15, the solar cell module 10 is attached by forming a row of module stages 36 by adjoining the short sides of the plurality of solar cell modules 10, and using screws or the like to attach each solar cell module 10 to the top surface of the building. It is done by fixing to. In the present embodiment, the module stage 36 has even-numbered stages (14 stages in FIG. 15) installed on the roof R. In the roof structure of the present embodiment, after the first module step 36 is formed along the eaves on the upper surface of the building, a plurality of module steps 36 are sequentially formed toward the ridge side. As shown in FIG. 11, the solar cell module 10 is attached to the first module stage 36 after the solar cell module 10 is engaged with the eaves tip blow-off preventing metal fitting 110 and then fixed to the building with screws. Is done.

  More specifically, as shown in FIG. 11A, the front cover 102 of the solar cell module 10 is arranged on the eaves side, and the engaged portions 112 of the eaves tip blowing prevention metal fittings 110a and 110b are connected to the solar cell module. 10 is inserted into the gap between the locking piece 108 and the reinforcing heat insulating material 90, and the entire solar cell module 10 is pulled up to the ridge side, whereby the solar cell module 10 and the eaves tip blowing prevention metal fitting 110 can be engaged. Yes (Figure 5).

  As shown in FIG. 10, among the solar cell modules 10 arranged in a row at the eaves, for the solar cell modules 10A arranged at both ends of the row, the eaves tip blowing prevention metal fitting 110b and the eaves tip blowing prevention metal fitting 110a The position of the boundary 148 between the eaves tip blowing prevention metal fitting 110b and the eaves tip blowing prevention metal fitting 110a is approximately the center of the solar cell module 10A. Of the plurality of solar cell modules 10 arranged in a row at the eaves, the solar cell module 10B arranged at a position other than both ends of the row is related to both of the two adjacent eaves tip blowing prevention metal fittings 110a and 110a. The position of the boundary 150 between two adjacent eaves tip blow-off prevention metal fittings 110a, 110a is approximately the center of the solar cell module 10B. Therefore, in the roof structure of the present embodiment, the resistance to wind blowing force can be further strengthened as compared with the case where the solar cell module 10 is engaged with only one eaves tip blowing prevention metal fitting.

  After the solar cell module 10 and the eaves tip blowing prevention metal fitting 110 are engaged, the solar cell module 10 is driven by the construction screws 152 being driven into the through holes 78b of the stacking portion 78, as shown in FIG. Fixed to the building. At this time, the cables 16 and 18 of the solar cell module 10 are extended to the ridge side.

  As shown in FIG. 16, during the formation of the module stage 36, in the adjacent solar cell modules 10, 10, the first connector 20 of one solar cell module 10 and the second connector 22 of the other adjacent solar cell module 10. Are connected, the two adjacent solar cell modules 10 and 10 can be electrically connected in parallel. That is, by connecting the white first connector 20 attached to the white first cable 16 and the black second connector 22 attached to the black first cable 18, the adjacent solar cell module 10, Ten parallel connections are possible. Therefore, in the roof structure of the present embodiment, all the solar cell modules 10 included in the module stage 36 are sequentially connected in parallel by connecting the solar cell modules 10 and 10 adjacent to the left and right using the cables 16 and 18. (FIG. 18).

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

  In the solar cell module 10 of the present embodiment, the total length of the first cable 16 is less than 50% of the length of the long side of the rectangular solar cell panel 12, and the total length of the second cable 18 is It is 50% or more of the length of the long side of the solar cell panel 12. Therefore, as shown in FIG. 17, the first connectors 20 and 20 attached to the first cable 16 cannot be connected to each other between the solar cell modules 10 and 10 that are adjacent to each other with their short sides being abutted. Therefore, the solar cell module 10 of the present embodiment can reliably prevent erroneous connection between the first connectors 20 and 20 between the adjacent solar cell modules 10 and 10.

  As shown in FIGS. 12 and 13, the solar battery module 10 is attached to the module stage 36 in the second and subsequent stages by placing the front cover 102 of the solar battery module 10C arranged in the upper stage on the eaves side. The locking piece 108 of the front cover 102 of 10C is inserted into a gap 156 formed between the engaging portion 88 of the hook metal fitting 84 of the solar cell module 10D and the surface of the stacking portion 78 of the base material 70, and the solar cell module. It is performed by pulling up the entire 10C to the building side and engaging the solar cell module 10C and the solar cell module 10D. Here, the sealing member 154 is attached to the locking piece 108 of the solar cell module 10 </ b> C, and the locking piece 108 is inserted into the gap 156 between the engaging portion 88 of the hook metal 84 and the base material 70. Since the sealing material 154 is disposed in the gap 156 without a gap, rattling at the engaging portion between the solar cell module 10C and the solar cell module 10D is prevented.

  After the latching piece 108 of the upper solar cell module 10C and the hook 84 of the lower solar cell module 10D are engaged, the upper solar cell module 10C extends the cables 16 and 18 to the building side. In this state, the construction screw 152 is driven into the through hole 78b of the loading portion 78 and fixed to the building. For the second and subsequent module stages 36 formed in this way, the solar cell modules 10 and 10 adjacent to the left and right are connected by cables 16 and 18 in the same procedure as the first module stage 36. Thus, all the solar cell modules 10 included in the module stage 36 can be connected in parallel (FIG. 18).

  As shown in FIG. 19, in the solar cell array 100 in the roof structure of the present embodiment, cables are connected between the odd-numbered module stages 36 a and 36 c and the even-numbered module stages 36 b and 36 d from the eave side (lower side). The connection order of 16 and 18 is reversed left and right. That is, the odd-numbered module stages 36a and 36c connect the second connector 22 of the right solar cell module 10 and the first connector 20 of the left solar cell module 10 to the second cable 18 and the first The cable 16 is connected. On the other hand, the even-numbered module stages 36b and 36d connect the first connector 20 of the right solar cell module 10 and the second connector 22 of the left solar cell module 10 to the first cable 16. The second cable 18 is connected.

  When all the solar cell modules 10 constituting the module stage 36 are connected by the cables 16 and 18, as shown in FIG. 16, the solar cells arranged at both ends of the plurality of solar cell modules 10 constituting the module stage 36. Among the battery modules 10, 10, the first connector 20 of the solar cell module 10 at one end is not used (not connected), and the second connector 22 of the solar cell module 10 at the other end is not used. Become in use. The unused first connector 20 and second connector 22 are used for electrical connection of the module stages 36 and 36 disposed above and below.

  For example, in the solar cell array 100 shown in FIG. 19, the odd-numbered module stages 36a and 36c and the even-numbered module stages 36b and 36d are electrically connected to form solar cell blocks 38a and 38b. Yes. Specifically, the solar cells 10a, 10c arranged at the left end of the odd-numbered module stages 36a, 36c are solar cells arranged at the left end of the even-numbered module stages 36b, 36d. The back surfaces of the solar cell panels 12 of the modules 10b and 10d are passed through, and the second connectors 22 of the solar cell modules 10a and 10c and the first connectors 20 of the solar cell modules 10b and 10d are connected.

  Thereby, all the solar cell modules 10 included in the module stage 36a and the module stage 36b are connected in parallel, and the solar cell block 38a is formed. Further, all the solar cell modules 10 included in the module stage 36c and the module stage 36d are also connected in parallel to form a solar cell block 38b. The solar cell blocks 38 a and 38 b formed as described above are electrically connected in series by the lead-in cable 40 to form the solar cell array 100.

  As shown in FIG. 20 (a), the lead-in cable 40 is connected to the first series connector 42 connected to the first connector 20 of the solar cell module 10 and the second connector 22 connected to the second connector 22 of the solar cell module 10. Two serial connectors 44, an output connector 46 that is connected to an indoor connection box (not shown) and outputs power converted by the solar cell panel 12 of the solar cell module 10, and a first serial connector 42. A first outdoor cable 48, a second outdoor cable 50 connected to the second serial connector 44, an indoor cable 52 connected to the output connector 46, and a mold portion 54.

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

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

  As shown in FIG. 20B, the first outdoor cable 48, the second outdoor cable 50, and the indoor side cable 52 are connected to the mold portion 54. More specifically, the plus side core wire 24 of the first outdoor cable 48 and the minus side core wire 26 of the second outdoor cable 50 are electrically connected, and the minus side core wire 26 of the first outdoor cable 48 and the indoor side cable 52 are connected. The negative side core wire 26 is electrically connected, and the positive side core wire 24 of the second outdoor cable 50 and the positive side core wire 24 of the indoor side cable 52 are electrically connected.

  As shown in FIG. 19, when the solar cell block 38a and the solar cell block 38b are connected in series using the lead-in cable 40, the white second series connector 44 of the lead-in cable 40 constitutes the solar cell block 38a. Connected to the black second connector 22 of the solar cell module 10f at the right end of the module stage 36b. The black first series connector 42 of the lead-in cable 40 is connected to the white first connector 20 of the solar cell module 10g at the right end of the module stage 36c constituting the solar cell block 38b.

  That is, the connection between the lead-in cable 40 and the solar cell blocks 38a and 38b may be made by connecting connectors of different colors, similarly to the connection between the adjacent solar cell modules 10 and 10, resulting in incorrect connection of wiring. Hateful. Further, as described above, the connection of the lead-in cable 40 to the solar cell blocks 38a, 38b is simply performed on the roof R by simply connecting the predetermined connectors 44 and 22, 42 and 20 in a predetermined combination. be able to.

  As shown in FIG. 19, with the solar cell blocks 38a and 38b connected in series, the first connector 16 of the solar cell module 10e at the right end of the module stage 36a and the solar cell module 10h at the right end of the module stage 36d. The second connector 18 is in an unused state (not connected). In the solar cell array 100 of this embodiment, the terminal protection member 58 shown in FIG. 21 is attached to these connectors 16 and 18. The terminal protection member 58 has substantially the same structure as the first connector 20 and the second connector 22 of the solar cell module 10 except that the cable is not connected. The solar cell array 100 of this embodiment prevents dust and water from adhering to the terminals 28 and 30 of the unused connectors 20 and 22 by attaching the terminal protection member 58 to the unused connectors 20 and 22. be able to.

  Moreover, the solar cell array 100 of this embodiment also attaches the terminal protection member 58 to the unconnected first connector 20 or the second connector 22 even when the laying operation is interrupted, so that the terminals 28, 22 of the connectors 20, 22 It is possible to prevent dust and water from adhering to 30.

  When the work in step 5 in FIG. 14 is completed as described above, the worker pulls in the indoor cable 52 of the lead-in cable 40 into the building in step 6. After that, construction of the surrounding tiles is performed (Step 7), and after the cleaning of the roof R (Step 8) is completed, after the inspection (Step 9) is performed, the lead-in cable 40 is bundled indoors (Step 10). Then, the output connector 46 is connected to a connection box (not shown) (step 11), and a series of operations is completed.

  In the solar cell module 10 of the present embodiment, the entire end surface on the eaves side of the solar cell panel 12 is protected by the front cover 102. Therefore, even when an external force is applied to the solar cell module 10 from the eaves side by, for example, placing a ladder on the solar cell module 10 disposed at the eaves of the roof R, most of the external force is the front cover 102. Is hardly transmitted to the solar cell panel 12. Therefore, even if the solar cell module 10 of this embodiment is a case where it is arrange | positioned at the eaves edge of the roof R, there is little possibility that the solar cell panel 12 will be damaged by the external force which acts from the eaves side.

  Moreover, since the eaves side fixing | fixed part 106 of the front cover 102 has extended to a part of light-receiving surface of the solar cell panel 12, the external force acts from the eave side upper side of the solar cell module 10 in the solar cell module 10 of this embodiment. Even if it is a case, the solar cell panel 12 can be protected reliably.

  In the solar cell module 10 of the present embodiment, as described above, a gap having a predetermined width is provided between the eaves side fixing portion 106 of the front cover 102 and the light receiving surface of the solar cell panel 12, and a gasket is provided in this gap. Has been inserted. Therefore, a certain height difference is provided between the solar cell panel 12 of the solar cell module 10 and the eaves side fixing portion 106 of the front cover 102. Thereby, the solar cell module 10 of this embodiment can hook the snow piled up on the solar cell panel 102 to the eaves side fixing | fixed part 106 of the front cover 102, and can prevent a snow slide effectively. Further, in the solar cell module 10 of the present embodiment, since a gap with a predetermined width is provided between the eaves-side fixing portion 106 of the front cover 102 and the light receiving surface of the solar cell panel 12, the front cover 102 and the solar cell It is possible to prevent thermal cracking from occurring in the solar cell panel 12 due to the difference in coefficient of thermal expansion from the panel 12.

  Further, in the roof structure of the present embodiment, when the solar cell module 10 is laid on the upper surface of the building, the locking pieces 108 of the front cover 102 of the solar cell module 10 are covered with the eaves tip blowing prevention metal fitting 110 fixed below. The engaging portion 112 is engaged with the engaging portion 88 of the hook member 84 of the solar cell module 10 disposed in the lower stage. Thereby, the roof structure of this embodiment is the case where the wind blows along the roof surface from the eave side and a large blowing force acts on the solar cell module 10, even when the eave side end portion of the solar cell module 10 is applied. However, the solar cell module 10 can be effectively prevented from being lifted up or scattered.

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

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

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

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

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

Next, the laying structure of the tile-type solar cell module 10 will be described.
FIG. 16 is a conceptual diagram when the tile-type solar cell module is correctly wired. FIG. 17 is a conceptual diagram when the tile-type solar cell module is mistakenly wired. FIG. 18 is a circuit diagram in the case where the tile solar cell module is accurately wired.
As shown in FIGS. 16 and 17, the above-described tile-shaped solar cell module 10 is laid on a structure such as a roof side by side.
Then, the connectors 20 and 22 of the adjacent tile type solar cell modules 10 are connected. When attention is paid to one tile-type solar cell module 10, the connector 22 of the tile-type solar cell module 10 and the connector 20 of the tile-type solar cell module 10 on the left are connected. Further, the connector 20 of the tile-type solar cell module 10 and the connector 22 of the tile-type solar cell module 10 on the right side are connected.
If it demonstrates paying attention to the length of a cable, the connector 22 of the long cable 18 of the said tile type solar cell module 10 and the connector 20 of the short cable 16 of the tile type solar cell module 10 on the left side will be connected. Further, the connector 20 of the short cable 16 of the tile-type solar cell module 10 and the connector 22 of the long cable 18 of the tile-type solar cell module 10 on the right side are connected.
As a result, the solar cells are connected in parallel as shown in FIG.

On the other hand, if the connection method is wrong and the connectors 22 of the long cable 18 are connected to each other as shown in FIG. 17, the other connectors 20 cannot be physically connected, so the operator notices the connection error. It becomes. That is, the other connector 20 is connected to a short cable 16, and the short cable 16 is less than half of the total length of the roof tile solar cell module 10. Moreover, since the cables 16 and 18 are extended from the center part of the tile-shaped solar cell module 10, even if it is going to connect the short cables 16, length is not enough and both cannot be connected.
Therefore, the tile-type solar cell module 10 of the present embodiment cannot cause wiring errors.

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

10 solar cell module 12 solar cell panel 84 hook metal fitting (prevention tool)
102 Front cover 104a Drain hole 108 Locking piece 110 Eaves tip blowing prevention metal fitting (blowing prevention tool)

Claims (6)

A solar cell module laid on the top surface of the building to form a roof,
A solar battery panel in which a plurality of solar battery cells are electrically connected in series and formed into a substantially rectangular surface,
A solar cell module comprising: a front cover that covers an entire end face of the eaves side of the solar cell panel.   The solar cell module according to claim 1, wherein a drain hole is provided in the front cover.   The solar cell module according to claim 1, wherein the front cover covers a part of a light receiving surface of the solar cell panel.   The solar cell module according to claim 3, wherein a gap having a predetermined width is provided between the front cover and a light receiving surface of the solar cell panel. The front cover extends to a part of the lower surface of the solar cell panel to form a locking piece,
The solar cell module according to any one of claims 1 to 4, wherein the locking piece is engageable with a blow-up preventing tool disposed below.   A roof structure comprising the solar cell module according to any one of claims 1 to 5 laid on an eaves portion on an upper surface of a building.

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