JP3158425U - Solar module roofing tools - Google Patents

Abstract

There is provided a roof tool for a solar cell module in which there is no protrusion of a fixing bracket such as a screw to the attic, and corrosion of a base plate due to the protrusion is prevented. A metal support member 14 is fixed to a pair of adjacent rafters 11 via a field plate 13 by a fixing fitting inserted into a predetermined insertion hole. Next, after moving the module support bracket 16 in the length direction of the long hole and positioning it at a predetermined position, the solar module 15 is fixed to the module support bracket. Thereby, there is no protrusion of fixed metal fittings, such as a screw, to an attic, and corrosion of a field board caused by this can be prevented. Therefore, it is possible to prevent a decrease in the strength of fixing the module support bracket to the roof, and even when the module support bracket is fixed at the bottom of the eaves, the appearance of the roof due to the protrusion of the fixing bracket to the attic is not impaired. . [Selection] Figure 1

Description

  The present invention relates to a roof tool for a solar cell module, and more particularly to a roof tool for a solar cell module for constructing a solar cell module on a roof of a wooden house.

In recent years, interest in the global warming problem and energy saving due to CO ₂ gas emission has increased, and the spread of power generation systems using solar energy, which is a kind of natural energy, to houses has been accelerated.
A residential solar power generation system installs a solar cell module on a roof, converts solar energy into electric power, and reduces household electrical load. In general solar battery modules, a plurality of solar battery cells are connected in series or in parallel, and these are sandwiched from the front and back sides by tempered glass, encapsulating resin, and a weather resistant film to form a rectangular main body. Thereafter, the strength of the entire module is increased by mounting the main body on a metal frame such as hard aluminum.

When constructing such a solar cell module on the roof of a house, conventionally, a solar cell module roofing tool is used (for example, Patent Document 1).
As shown in FIG. 6, a conventional solar cell module roof tool 100 includes a wooden and horizontally long fixed substrate 103 whose both ends are fixed to a pair of adjacent rafters 101 via a field plate 102, and a fixed substrate 103. And a module support fitting 106 to which a base part of the solar cell module 104 is attached at a tip part thereof. The module support fitting 106 is a J-shaped member that is substantially lateral when viewed from the side.

Hereinafter, a method for constructing the solar cell module 104 on the tiled roof using the conventional solar cell module roof tool 100 will be described in detail. The roof tile 107 has a front hanging portion that protrudes downward on the back surface of the end portion on the eaves side, and a rectangular portion in a plan view in which a ridge portion 107a that is parallel to the eaves is formed on the back surface of the end portion on the ridge side. It is of shape.
First, in the adjacent tiles 107, the ridges 107a of the roof tiles 107 are overlapped on the front hanging portions of the eaves tiles 107, and a large number of tiles 107 are laid on the roof of the house. At that time, a draining portion between the upper and lower roof tiles 107 is constituted by the protrusion 107a. Among the laid roof tiles 107, one row of roof tiles 107 are removed every predetermined stage. Thereafter, both ends of a plurality of horizontally long fixed substrates 103 are fixed to the pair of adjacent rafters 101 with screws 110 via the base plate 102. Next, the base part of the module support fitting 106 is fixed to the substantially intermediate part in the length direction of the fixed substrate 103 with the screws 110, and then the removed tile 107 is returned to the original position of the roof. At this time, a part of the protruding portion 107a is cut by a disc grinder so that the tip of the module support fitting 106 can protrude upward from the gap between the draining portions (overlapping portions) of the upper and lower roof tiles 107. Next, the base 105 of the solar cell module 104 is fixed to the tip of each module support fitting 106 with a bolt and nut structure, and then the solar cell module 104 is laid on the base 105.
JP 2008-204218 A

However, in such a solar cell module roof tool 100 described in Patent Document 1, the base part of the module support fitting 106 is fixed to a substantially intermediate part in the length direction of the fixed substrate 103 by a metal screw 110. It was. At that time, the tip of the screw 110 penetrated the base plate 102 and protruded into the attic. Therefore, for example, in the rainy season and winter season, condensation occurs on the screw 110 due to a temperature difference between the roof and the attic, and this condensation promotes the corrosion of the base plate 102 due to the long-term use of the solar cell module 104. The fixing strength to the roof of the support fitting 106 and, consequently, the roofing tool 100 of the solar cell module has been reduced.
In addition, when the screwing position of the metal screw 110 is under the eaves, the aesthetic appearance of the roof (house) is impaired, so that the module support bracket 106 cannot be screwed, and the fixing strength of the roofing tool 100 of the solar cell module is low. There was also a risk that the solar cell module 104 could not be installed on the roof.

  Moreover, in the roofing tool 100 of the solar cell module of patent document 1, a part of protrusion 107a is cut with a disc grinder with respect to the roof tile 107 which opposes the module support bracket 106 in the field, and a module support bracket 106 insertion grooves 107b had to be formed. Therefore, cutting scraps of the ridge 107a are scattered around during the groove processing, dust is ashed on the entire surface of the roof, and the surface (upper surface) of the roof tile 107 is slippery, resulting in poor scaffolding for the worker. .

  Therefore, as a result of diligent research, the inventor fixed the metal support material to a pair of adjacent rafters instead of the wooden fixed substrate, and the module support metal fitting in the length direction of the metal support material with respect to this metal support material. It was found that all the above-mentioned problems could be solved if it was configured to be movably mounted, and the device was completed.

The object of the present invention is to provide a roofing tool for a solar cell module in which there is no protrusion of a fixing bracket such as a screw to the attic, and the corrosion of the base plate due to this protrusion can be prevented. .
In addition, since this device makes a part of the module support bracket protrude above the roof tile, it is not necessary to cut a part of the roof tile facing the module support bracket, and an operator caused by dust generated during this cutting An object of the present invention is to provide a solar cell module roofing tool that can eliminate the deterioration of the scaffolding.

  The idea of claim 1 is that a solar module is fixed to a pair of adjacent rafters in a roof of a wooden house, a rail-like metal support member fixed through a field plate by a fixing bracket, and A module support fitting attached to the metal support material, wherein the metal support material is formed with a plurality of insertion holes of the fixing bracket spaced apart in the length direction of the metal support material, and the length direction The module support fitting is a roofing tool for a solar cell module that is attached to the metal support material so as to be movable in the length direction within the long hole.

  According to the first aspect of the present invention, the metal support member is fixed to the pair of adjacent rafters via the ground plate by the fixing fitting inserted into the predetermined insertion hole. Thereafter, the module support fitting is moved in the length direction of the long hole and positioned at a predetermined position, and the solar module is fixed to the module support fitting. Thereby, there is no protrusion of the screw (fixing metal fitting) to the attic as in the prior art, and corrosion of the base plate due to this protrusion can be prevented. Moreover, even if the support position of the module support fitting is under the eaves, the tip of the screw protrudes under the eaves as in the conventional case, and the aesthetic appearance of the roof (house) is not impaired. Therefore, it is possible to avoid the installation of the solar cell module on the roof due to the decrease in aesthetics.

The roofing tool of the solar cell module is a tool for fixing the solar cell module to the roof of the wooden house.
A wooden house is a residential building that uses timber for its major structural strength.
As the roof, for example, a tiled roof, a tin thatched roof, a slate thatched roof and the like can be employed. However, in the case of a tin thatched roof, a positioning member for positioning the module support bracket at a predetermined position of the metal support member is required.
A rafter is a structural material of a hut in a building such as a wooden house, and is passed over the eaves girder, main building, and purlin at equal intervals. On the rafters, field boards and structural plywood are laid and often used as the roof base. For example, a roofing sheet may be laid on the surface of the base plate.

As the fixing bracket, for example, a screw, a nail, or the like can be employed.
“Rail-shaped metal support” means that the metal support is a member that is long in one direction like a rail.
As a material for the metal support material, for example, iron, stainless steel, aluminum or the like can be employed. Examples of the shape of the metal support material include a strip shape and an elliptical shape in plan view. The length of the metal support is arbitrary as long as it is equal to or greater than the width (interval) of a pair of adjacent rafters. The number of metal support materials used is arbitrary.
The formation positions of the insertion holes (plurality) in the metal support material are arbitrary. The insertion hole may be a circular hole or a long hole. The number of insertion holes formed in the metal support material is arbitrary.
The length direction of the long hole is the length direction of the metal support material, but when roofing the solar module, the metal support material is in the direction parallel to the eaves (the direction perpendicular to the eaves building direction). Is fixed to the roof so that the length direction of the long hole at the time of construction is parallel to the eaves.

The structure of the solar module is arbitrary. For example, connect a plurality of solar cells in series or in parallel, hold them from the front and back with tempered glass, encapsulating resin, and weather resistant film, and then use the one with the main body attached to a metal frame. Can do. A junction box for obtaining output power is provided on the back surface of the solar cell module.
As a solar cell (cell) incorporated in the solar module, for example, a single crystal silicon solar cell, a polycrystalline silicon solar cell, an amorphous silicon solar cell, or the like can be employed. In addition, thin film silicon solar cells, HIT (Heterojunction with Intrinsic Thin-layer) solar cells, CIGS thin film solar cells, cadmium tellurium (CdTe) solar cells, multi-junction solar cells, dye-sensitized solar cells, organic thin film solar cells, etc. Good.

As a material for the module support bracket, for example, iron, stainless steel, aluminum, or the like can be used.
The structure of the module support metal fitting is arbitrary as long as it has a fixed part of the solar module and a part attached to the metal support so as to be movable in the length direction within the long hole.
As a fixing structure to the module support bracket of the solar module, for example, a hole penetrating the front and back surfaces is formed in a part of the roof tile, and a bolt constituting a part of the bottle module support bracket is inserted into the through hole, A bolt and nut structure for fixing the roof tile and the module support bracket can be adopted by screwing the nut onto the bolt. In addition, a clamp structure that grips the edge of the roof tile can be employed.
As a structure for slidably mounting the module support bracket to the metal support member, for example, a bolt-nut structure with a loosened fastening force can be employed. In addition, a fitting-type metal fitting etc. can be adopted.

  The invention according to claim 2 is characterized in that the metal support member has an upper plate arranged in parallel to the base plate, and upper ends of the upper plate are connected to both ends of the metal support member in the width direction. A pair of side plates and a pair of flanges connected in parallel to the upper plate at the lower ends of the side plates, and a connecting portion between the upper plate and each side plate includes Reinforcing ribs extending over the entire length are formed in a state of projecting outward, and the elongated holes are formed so as to be biased toward one of the length directions of the metal support member of the upper plate, and the plurality of insertion holes are The both flanges are disposed at one place on the opposite side of the long hole and at two places on the same side as the long hole that are spaced apart in the length direction of the flange. Item 12. A solar cell module roof tool according to Item 1.

According to the second aspect of the present invention, the metal support member has a long hole formed on one of the upper plates in the length direction of the metal support member, and the insertion hole of the fixing bracket has both flanges. Of these, one is located at the end opposite to the long hole, and two are spaced apart in the length direction of the flange among the end on the same side as the long hole. Therefore, it is possible to change the fixing position of the metal support member by the fixing bracket in response to the variation in the interval between the rafters.
Moreover, since the reinforcing ribs are projected outwardly over the entire length of the metal support material at the connecting portion between the upper plate and each side plate, and this metal support material is reinforced, a long hole is formed in the upper plate. Nevertheless, no significant reduction in strength occurs in the metal support material.
In addition, since the long hole is formed on one side of the length direction of the metal support member in the upper plate, compared to the case where the long hole is formed over substantially the entire length of the upper plate, Strength reduction can be prevented. In addition, even if the module support bracket must be disposed at the end of the upper plate opposite to the long hole where the long hole is not formed, the metal support member is rotated 180 degrees. This can be dealt with by reversing the direction of both ends of the metal support.

The material of the reinforcing rib can be the same material as the upper plate and each side plate of the metal support material.
The length of the long hole is arbitrary, but for example, 30% to 50% of the total length of the upper plate is preferable.
“The long hole is formed on one side of the length direction of the metal support member in the upper plate” means that the intermediate point in the length direction of the long hole is the intermediate point in the length direction of the metal support member. In other words, it is formed by being displaced in one of the length directions of the metal support material.
“A plurality of insertion holes are arranged in one of the two flanges on one side of the opposite side of the long hole and two in the end on the same side as the long hole, spaced apart in the length direction of the flange. “Established” means the following. That is, the insertion hole formed in both flanges has one long hole at the end in the opposite direction (the other) to the one in which the long holes are formed in the length direction of the metal support material. Are formed at two positions on one end portion where they are formed in a biased manner. In addition, these two places are positions spaced apart in the length direction of the flange in one end portion.

  According to a third aspect of the present invention, the roof is tiled, and the roofing tool of the solar cell module is connected to the module support bracket and has a dummy tile used as a part of the roof tile. The dummy tile is a metal tile body, a raised portion formed in a part of the tile body, and an insertion hole of the module support bracket is formed in a top portion, and the tile body, It is a roof tool of the solar cell module of Claim 1 or Claim 2 which has the cyclic | annular drain groove formed in the circumference | surroundings of the protruding part.

  According to the third aspect of the present invention, since the tile is made of a metal dummy tile and the module support bracket can be inserted into the insertion hole of the raised portion at the time of construction on the tiled roof, the module support bracket has been conventionally used. When fixing the roof to the roof, it was necessary to cut a part of the draining portion of the tile facing the module support bracket, but the processing work becomes unnecessary. Thereby, the deterioration of an operator's scaffold resulting from the dust which generate | occur | produced at the time of the cutting of the draining part can be eliminated. In addition, since an annular drain groove is formed around the raised portion, rainwater can flow down along the peripheral surface of the raised portion, and then reach the annular drain groove and be smoothly discharged out of the dummy roof tile. it can.

As the tiled roof, for example, ceramic tile, smoldering tile, cement tile, slate and the like can be employed.
A dummy tile is a pseudo-tile made of metal resembling a roof tiled on the roof to be constructed.
As a material of the tile body, for example, a metal such as an aluminum casting can be adopted in addition to aluminum die casting.
The shape of the tile body is changed in accordance with the shape of the tile laid on the roof.
The insertion hole is a hole having an opening area through which the module support fitting is inserted, and is formed on, for example, a flat top surface of the raised portion. The module support fitting is moved along the long hole so as to be inserted into the insertion hole.
The raised portion is a portion protruding upward of the tiles arranged on the upper surface of the inclined roof. The raised portion and the roof tile may be integrally formed of the same material, or may be formed separately from the same material or different materials. The formation position and number of the raised portions are arbitrary.
As long as the annular drain groove is formed around the raised portion, the groove shape, the number of formation, and the like are arbitrary.

  According to the first aspect of the present invention, the metal support member is fixed to a pair of adjacent rafters instead of the wooden fixed substrate, and the module support bracket is attached to the metal support member in the length direction of the metal support member. Because it is configured to be mounted so that it can be moved to, the protrusion of the screw (fixing bracket) to the attic, which was a problem of the conventional method, does not occur, and corrosion of the field plate due to the protrusion of this screw can be prevented it can. Moreover, even if the support position of the module support bracket is under the eaves, the tip of the screw protrudes under the eaves as in the conventional method, and the roof does not impair the appearance of the house. For this reason, it is possible to avoid the postponement of installation of the solar cell module due to a decrease in aesthetics.

  According to the second aspect of the invention, the metal support member is formed with a long hole that is biased toward one of the upper plates in the length direction of the metal support member. In addition, the insertion hole of the fixing bracket has one place on the opposite side of the long hole of both flanges, and two places on the same side as the long hole that are spaced apart in the length direction of the flange. Therefore, it is possible to change the fixing position of the metal support member by the fixing bracket in response to the variation in the interval between the rafters.

In addition, since the reinforcing ribs are projected outwardly over the substantially entire length of the metal support material at the connecting portion between the upper plate and each side plate, the metal support material is formed despite the formation of a long hole in the upper plate. There is no significant decrease in strength.
Furthermore, since the long hole is formed on one side of the length direction of the metal support material in the upper plate, the strength of the metal support material is higher than when the long hole is formed over the entire length of the upper plate. Decline can be prevented. In addition, even if the module support bracket must be disposed at the end of the upper plate opposite to the long hole where the long hole is not formed, the metal support member is rotated 180 degrees. This can be dealt with by reversing the direction of both ends of the metal support.

  Furthermore, according to the invention described in claim 3, since the tile is a dummy tile and the module support bracket can be inserted into the insertion hole of the raised portion when constructing the tiled roof, the conventional method uses the module support bracket. When fixing to the roof, it was necessary to cut a part of the draining portion of the tile facing the module support bracket, which is not necessary. As a result, it is possible to eliminate the deterioration of the worker's scaffold due to the dust generated during the cutting of the draining portion. Further, since the annular drain groove is formed around the raised portion, the rain that flows down along the peripheral surface of the raised portion can be smoothly discharged through the annular drain groove.

It is a principal part expanded longitudinal sectional view which shows the use condition of the roof tool of the solar cell module which concerns on Example 1 of this invention. It is a top view of the dummy tile laid on the roof where the roof tool of the solar cell module concerning Example 1 of this invention is constructed. It is S3-S3 sectional drawing of FIG. It is a principal part expansion perspective view which shows the use condition of the roof tool of the solar cell module which concerns on Example 1 of this invention. It is a principal part expanded longitudinal sectional view which shows the use condition of the roof tool of the solar cell module which concerns on Example 1 of this invention. It is a principal part expanded longitudinal sectional view which shows the use condition of the roofing tool of the solar cell module which concerns on the conventional means.

  Hereinafter, embodiments of the present invention will be specifically described.

  In FIG. 1, 10 is a roof tool for a solar cell module according to Embodiment 1 of the present invention. The roof tool 10 for this solar cell module is connected to a pair of adjacent rafters 11 on the roof of a wooden house. A rail-like metal support member 14 fixed by a (fixing bracket) 12 via a base plate 13 and the solar cell module 15 are fixed and attached to the metal support member 14 so as to be movable in the length direction. A module support bracket 16 is provided. Hereinafter, these components will be described in detail.

  First, the solar cell module 15 will be described with reference to FIG. The solar cell module 15 is housed in a weather-resistant package in which a plurality of solar cells that convert sunlight into electric energy are connected, and a transparent film, a transparent resin, an insulating resin, a reinforcing material, etc. are arranged on the front surface. It is configured in a flat plate shape. The shape of the solar cell module 15 in a plan view is a rectangular shape, and one side is formed to be 500 to 2000 mm, for example. A plurality of solar cell modules 15 are arranged on the roof and connected in series and in parallel to form a solar cell array. The outer periphery of the solar cell array is reinforced by a rectangular frame (frame) 51 in which a vertical beam 50 and a horizontal beam are assembled in a frame shape.

On the roof where the solar cell module 15 is installed, rafters 11 whose length direction is directed toward the eaves are arranged at a constant pitch (450 mm) in a direction parallel to the eaves. On each rafter 11, a base plate 13 covering the entire roof is nailed. A roofing sheet 17 is laid on the surface of the field board 13. On the surface of the roofing sheet 17, piers 18 that are long in a direction parallel to the eaves are arranged at a predetermined pitch in the eaves ridge direction.
Porcelain tiles 19 are spread on the roof, and dummy tiles 20 that are used in place of the ceramic tiles 19 are disposed on the roof where the roofing tool 10 of the solar cell module is applied. .

Next, the dummy roof tile 20 will be described in detail with reference to FIGS.
The dummy roof tile 20 is a pseudo roof tile having a roof body 21 made of aluminum die-casting that is curved in a substantially square shape when viewed from the eaves-ridge direction. The tile main body 21 is integrally provided with a circular raised portion 22 in a plan view on the upper plate (top) of the above-mentioned hem shape in the tile main body 21 at a substantially intermediate portion in the eaves ridge direction of the tile main body 21. Is formed. An insertion hole 22 a for a bolt 23 described later is formed in the module support bracket 16 at the center of the upper plate of the raised portion 22. In addition, an annular drain groove 24 for smoothly discharging rainwater is formed around the raised portion 22 in the tile main body 21. Further, a leg portion 25 on which the dummy roof tile 20 is placed in parallel with the roofing sheet 17 is integrally formed on the surface of the roofing sheet 17 at the center of the back side of the roof tile body 21. The insertion hole 22a is opened at an inclination angle of 6 to 7 degrees toward the draining portion (eave side) of the tile main body 21 with respect to a virtual line orthogonal to the surface of the flat portion of the tile main body 21. . This is because an overlapping portion with the ceramic tile 19 exists in a part of the dummy tile 20, so that the angle difference between the inclination of the base plate 13 and the inclination angle of the dummy tile 20 installed on the base plate 13 is almost equal. It is a treatment for being.

Next, the metal support member 14 will be described in detail with reference to FIGS. 1, 4, and 5.
The metal support member 14 is formed by pressing a strip-shaped steel plate having a length of 520 mm, a width of about 80 mm, and a thickness of 3 mm. The metal support member 14 includes an upper plate 26 arranged in parallel to the base plate 13, a pair of side plates 27 whose upper ends are coupled to both ends of the metal support member 14 in the width direction, and both sides of the upper plate 26. The lower end of the plate 27 has a pair of flanges 28 connected in parallel with the upper plate 26. In addition, a pair of reinforcing ribs 29 are formed at the connecting portion between the upper plate 26 and the side plates 27 so as to protrude outward over the entire length of the metal support member 14.

  A long hole 30 that is long in the length direction of the metal support member 14 is formed in the upper plate 26 so as to be biased to one side in the length direction of the metal support member 14. That is, the long hole 30 is a long hole that is disposed in the middle of the upper plate 26 in the width direction and extends from one end portion in the length direction of the upper plate 26 to a substantially middle portion in the length direction of the upper plate 26. . Further, in both flanges 28, one end portion on the opposite side of the long hole 30 and two end portions on the same side as the long hole 30 are spaced apart in the length direction of the flange 28, respectively. Three insertion holes 28a for a total of nine screws (fixed metal fittings) 12 are formed. The three insertion holes 28a arranged at each location are spaced apart in the length direction of the flange 28 at a pitch of 25 mm. That is, on the basis of a set of three insertion holes 28a arranged at the end opposite to the long hole 30 of the flange 28, another three-one is positioned at a position 300 mm away from the flange 28 in the length direction. A pair of insertion holes 28a is formed, and another set of three insertion holes 28a is formed at a position further spaced 150 mm in the longitudinal direction of the flange 28.

Next, the module support bracket 16 will be described in detail with reference to FIG. 1, FIG. 4, and FIG.
The module support bracket 16 is attached to the metal support member 14 so as to be movable in the longitudinal direction within the long hole 30. The module support bracket 16 is disposed between a bolt 23 inserted from below into the elongated hole 30 of the metal support member 14 with the screw portion facing upward, and the head of the bolt 23 and the back surface of the upper plate 26. Both ends in the width direction are bent upward and inserted into the lower space of the reinforcing ribs 29 of the metal support member 14 and the lower end of the bolt 23, and placed on the upper surface of the upper plate 26. A flat washer 32, a pair of upper and lower roof tile washers 33 that are inserted through the middle part of the bolt 23 and applied to the upper and lower surfaces of the raised portion 22 of the dummy roof tile 20, and the roof tile washer 33 A pair of nuts 34 that sandwich the dummy roof tile 20 from above and below, a spring washer 35 that is inserted between the upper nut 34 and the upper roof washer 33 and is inserted between the bolt 23 and the rectangular frame. 51 A flat washer 32 inserted into the upper end portion of the bolt 23 inserted into the bolt hole formed in the crosspiece 50 and applied to the front and back surfaces of the vertical crosspiece 50, and the vertical crosspiece is moved in the vertical direction via the two flat washers 32. And a pair of nuts 34 sandwiched between the two.

Next, with reference to FIG. 1, FIG. 4, and FIG. 5, the usage method of the roof tool 10 of the solar cell module which concerns on Example 1 of this invention is demonstrated.
As shown in FIG. 1, first, in adjacent tiles, a large number of ceramic tiles 19 are laid on the roof of a house, with the front hanging portion of the ridge side ceramic tiles 19 superimposed on the upper surface of the eaves side ceramic tiles 19. . Among the laid ceramic tiles 19, the horizontal rows of ceramic tiles 19 are removed every predetermined level. Next, in this removal region, a metal support member 14 having a length direction parallel to the eaves is placed on the pair of adjacent rafters 11 via the field plate 13. Among the three insertion holes 28a arranged at both ends in the length direction, screws 12 (total of four) are inserted into the insertion holes 28a arranged in the center, and the length of the metal support member 14 in the length direction Both ends are screwed to the rafters 11. The reason for selecting these insertion holes 28a is that the separation width of the adjacent rafters 11 is 450 mm, and the insertion holes of both flanges 28 are made to coincide with this. Thereby, the metal support material 14 is fixed to the roof.

  Next, the removed ceramic tile 19 is returned to the original position of the roof. At this time, the module support fitting 16 is moved in the length direction of the long hole 30, and the bolt 23 is arranged at a preset connection position. Thereafter, the raised portion 22 of the dummy roof tile 20 is inserted into the bolt 23 of the module support bracket 16 through the insertion hole 22 a of the raised portion 22. Next, the dummy roof tiles 20 are sandwiched from above and below by both nuts 34, and the dummy roof tiles 20 are inserted between the two adjacent ceramic roof tiles 19. Next, the insertion hole of the vertical beam 50 of the rectangular frame 51 is passed through the tip of the bolt 23, and then the vertical beam 50 is clamped by a pair of bolt and nut structures from the front and back sides. Then, the solar cell module 15 is laid on the rectangular frame 51.

  In this way, the metal support member 14 is screwed to the pair of adjacent rafters 11 via the field plate 13, and then the module support bracket 16 is moved and positioned in the length direction of the long hole 30, thereby supporting the module. Since the solar cell module 15 is fixed to the metal fitting 16, there is no protrusion of the screw to the attic as in the prior art, and corrosion of the base plate 13 caused by the protrusion of the fixing metal fitting can be prevented. Moreover, even if the support position of the module support bracket 16 is under the eaves, the tip of the screw protrudes under the eaves as in the conventional case, and the aesthetic appearance of the roof (house) is not impaired. Thereby, it is possible to avoid the installation of the solar cell module 15 on the roof due to a decrease in aesthetics.

Further, the metal support member 14 is formed with a long hole 30 that is biased to one of the length directions of the metal support member 14 of the upper plate 26, and the insertion hole 28 a of the screw 12 is formed between the flanges 28. One end of the end opposite to the long hole 30 and two ends of the end on the same side as the long hole 30 are spaced apart in the length direction of the flange 28. Therefore, the fixing position of the metal support member 14 with the screw 12 can be changed in response to the variation in the interval between the rafters 11.
Moreover, since the reinforcing ribs 29 protrude outwardly at the connecting portions of the upper plate 26 and the side plates 27 over the entire length of the metal support member 14 and the metal support member 14 is reinforced, Despite the formation of the long hole 30, the metal support member 14 does not significantly decrease in strength.
Moreover, since the long hole 30 is formed in one side of the length direction of the metal support material 14 among the upper plates 26, compared with the case where the long holes 30 are formed over the substantially entire length of the upper plate 26. Moreover, the strength reduction of the metal support material 14 can be prevented. Further, even if the module support bracket 16 must be disposed at the end of the upper plate 26 opposite to the long hole 30 where the long hole 30 is not formed, the metal support member 14 is attached. This can be dealt with by rotating 180 degrees and reversing the direction of both ends of the metal support material 14.

  Since the ceramic tile 19 is a metal dummy tile 20 and the bolt 23 of the module support bracket 16 can be inserted into the insertion hole 22a of the raised portion 22 when the tile roof is constructed, the module support bracket is conventionally used. When fixing to the roof, it was necessary to cut a part of the drained portion of the ceramic tile facing the module support bracket, but this work becomes unnecessary. Thereby, the deterioration of an operator's scaffold resulting from the dust which generate | occur | produced at the time of the cutting of the draining part can be eliminated. Further, since the annular drain groove 24 is formed around the raised portion 22, the rainwater flows down along the peripheral surface of the raised portion 22, and then reaches the annular drain groove 24 and is smoothly discharged out of the dummy roof tile 20. can do.

  This device is useful when installing a solar cell module on a dry wipe, a slate roof, a tin roof, or the like.

10 Roofing tool for solar cell module,
11 Rafters,
12 screws (fixing bracket),
13 Field board,
14 metal support material,
15 Solar module,
16 Module support bracket,
19 Ceramic tile (tile),
20 dummy roof tiles,
21 tile body,
22 ridges,
22a insertion hole,
24 drain groove,
26 Upper plate,
27 side plates,
28 flanges,
28a insertion hole,
29 Reinforcing ribs,
30 long hole.

Claims (3)

Of the roof of the wooden house, to a pair of adjacent rafters, a rail-shaped metal support that is fixed by a fixing bracket through a field plate,
A module support bracket to which a solar module is fixed and attached to the metal support,
In the metal support member, a plurality of insertion holes of the fixing bracket are formed apart in the length direction of the metal support member, and a long hole is formed in the length direction,
The module support fitting is a roofing tool for a solar cell module that is attached to the metal support so as to be movable in the longitudinal direction within the elongated hole. The metal support material includes an upper plate arranged in parallel to the base plate, a pair of side plates of which the upper ends are coupled to both ends in the width direction of the metal support material, and the both side plates. A pair of flanges connected to the upper plate in parallel with each other at the lower end thereof, and a reinforcing rib extending over the entire length of the metal support member protrudes outward at the connection portion between the upper plate and each side plate. Formed in the state
The long hole is formed to be biased to one of the length directions of the metal support member of the upper plate,
The plurality of insertion holes are spaced apart in the length direction of the flange among one of the flanges on one side of the end opposite to the long hole and the end on the same side as the long hole. The roof tool of the solar cell module according to claim 1, which is disposed at a location. The roof is tiled,
The roofing tool of the solar cell module is connected to the module support bracket and has a dummy tile used as a part of the roof tile,
The dummy tile includes a metal tile main body, a raised portion formed in a part of the tile main body, and an insertion hole of the module support bracket formed in a top portion, and the raised portion of the tile main body. The roof tool of the solar cell module according to claim 1, further comprising an annular drain groove formed around the periphery of the solar cell module.

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