JP5490621B2 - Solar cell module fixture and roof structure - Google Patents

Description

  The present invention relates to a solar cell module fixture for fixing a solar cell module on a roof, and a roof structure using the fixture.

  In order to quickly recover the cost required for installing the solar cell module, it is required to install as many solar cell modules as possible on the roof surface and increase the amount of power obtained by solar power generation. In order to install such a large number of solar cell modules on the roof, it is only necessary to arrange the solar cell modules from the first stage of the eaves. In this way, the solar cell modules from the first stage of the eaves When arranging the above, it is necessary to firmly prevent the wind blowing toward the eaves from blowing up the first-stage solar cell module.

  In the roof structure disclosed in Patent Document 1 below, the solar cell module is locked to the solar cell module by locking the eave side end portion (locking piece of the front cover) of the solar cell module arranged at the eave edge with the eaves tip blowing prevention tool. It resists the wind load that acts. That is, when a wind load is generated by the wind blown to the eaves edge, the eaves edge blow-off prevention tool receives the locking pieces of the front cover, so that the wind load is applied to the front cover rather than the solar cell panel body. On the other hand, the solar cell module used in the roof structure described in Patent Document 1 is provided with a reinforcing member made of foamed resin on the back side of the solar cell panel. And the reinforcement part of the beam direction of this reinforcement member is formed in thickness, and is provided so that a roof surface may be touched. For this reason, even when snow is piled up on the solar cell module, the above-mentioned girder direction reinforcing portion receives this snow load, and it is avoided that the snow load directly acts on the solar cell panel body. Conceivable.

JP 2009-299450 A

  However, when a solar cell module that does not have a girder reinforcement as described above is employed, the solar cell module is pushed downward by the snow load described above, and the locking piece of the front cover of this solar cell module is At the lower position of the tip of the blow-up prevention tool, it tries to move further downward from the initial position. As a result, there is a possibility that the eaves tip blowing prevention tool will hit, for example, a solar cell panel body which is a portion other than the locking piece in the solar cell module. That is, when a solar cell module that does not include the above-described beam direction reinforcing portion is employed, there is a possibility that a snow load may be applied to the solar cell panel body due to the eaves tip blowing prevention device.

  This invention makes it a subject to provide the solar cell module fixing tool and roof structure which can transmit both the wind load and snow load when installing a solar cell module in a roof to the frame part of a solar cell module.

  In order to solve the above problems, the solar cell module fixture of the present invention includes a locking piece holding portion into which a locking piece provided on a frame portion of the solar cell module is inserted, and the above locking piece holding portion. And an installation fixing portion that installs and fixes the engagement piece on the roof. The engagement piece clamping portion includes a first load receiving portion that receives the lower surface of the engagement piece, and an upper surface of the engagement piece. And a second load receiving portion.

  If it is the said structure, although the snow load when snow accumulates on a solar cell module will be a force which presses down a solar cell module, the lower surface of the latching piece in the frame part of this solar cell module receives a 1st load receiving Since the portion receives the snow load, the snow load is transmitted from the locking piece of the solar cell module to the frame portion. In addition, the wind load when the wind blows to the eaves is a force that lifts the solar cell module upward, but the second load receiving portion receives the upper surface of the locking piece, so the wind load is the solar cell module. Is transmitted from the locking piece to the frame portion. Thus, this solar cell module fixture can transmit both a snow load and a wind load from the latching piece of a solar cell module to a frame part by having the 1st load receiving part and the 2nd load receiving part. Thus, it is possible to prevent an excessive force from being applied to the solar cell panel body.

  In the above solar cell module fixture, the first load receiving portion and the second load receiving portion may be alternately arranged. Such an alternately arranged structure can be obtained, for example, by performing shearing and pressing on a single flat plate portion. That is, the first load receiving portion and the second load receiving portion can be obtained without using extrusion molding. And about the solar cell module fixture of such a structure, since it becomes easy to concentrate stress on the boundary line of the said 1st load receiving part and said 2nd load receiving part arrange | positioned alternately, on this boundary line It is preferable to form reinforcing ribs.

  On the other hand, the first load receiving portion and the second load receiving portion may be arranged to face each other instead of the alternate arrangement as described above. Such a face-to-face structure can be formed by, for example, extrusion molding.

  In these solar cell module fixtures, the installation fixing part has a first part located on the roof surface and a second part straddling the horizontal rail located on the roof surface, and the back surface of the first part A convex portion that forms a gap between the back surface and the roof surface may be formed. If it is such a structure, the raindrop which propagates on the roof surface can be transmitted to the eaves under the said 1st site | part, without being interrupted | blocked by said solar cell module fixing tool. In such a solar cell module fixture, the horizontal rail may be fixed to the second portion.

  Further, in these solar cell module fixtures, the installation fixing portion may be provided with a positioning portion for positioning the solar cell module fixture in contact with a horizontal rail disposed on the roof surface. According to this, the solar cell module fixture can be neatly arranged at the correct position with the horizontal rail as a reference.

  Further, the roof structure of the present invention is a roof structure for fixing the solar cell module fixture described above to the roof, and fixing the solar cell module having a locking piece on the frame portion with the solar cell module fixture, The solar cell module is arranged at the first stage of the eaves, and the locking piece of the solar cell module is inserted into a locking piece holding portion of the solar cell module fixture.

  If it is said structure, even if it arrange | positions a solar cell module in the 1st step | level of an eaves edge, the wind load by the wind which blows on an eave edge will be the latching piece of a solar cell module by the 2nd load receiving part of a solar cell module fixture. Since the snow load is transmitted from the locking piece of the solar cell module to the frame portion by the first load receiving portion, it is prevented that an excessive force is locally applied to the solar cell panel body. It will be.

  According to the present invention, when the solar cell module is installed on the eaves side of the roof, the wind load received by the solar cell module can be transmitted from the locking piece of the solar cell module to the frame portion by the solar cell module fixture, As for the snow load, this solar cell module fixture can transmit the solar cell module from the locking piece to the frame, so that excessive wind is locally applied to the solar cell panel body due to the wind load and snow load. There is an effect that it can be prevented.

It is the perspective sectional view showing an example of the solar cell module fixed by the solar cell module fixture of the present invention. It is the figure which showed the solar cell module fixture which concerns on one Embodiment of this invention, Comprising: (A) of the figure is a side view of a solar cell module fixture, (B) of the figure is the perspective view It is. It is the block diagram which showed the roof structure using the solar cell module fixing tool shown in FIG. It is the block diagram which showed the roof structure using the solar cell module fixing tool of other embodiment. It is the block diagram which showed the roof structure using the solar cell module fixing tool of other embodiment. It is the block diagram which showed the roof structure using the solar cell module fixing tool of other embodiment.

  Next, a solar cell module fixture and a roof structure according to an embodiment of the present invention will be specifically described with reference to the accompanying drawings. In addition, the solar cell module fixture and the roof structure according to the present invention are not limited to those shown in the following embodiments, and can be implemented with appropriate modifications within a range not changing the gist thereof.

  As shown in FIG. 1, a tile-type solar cell module (hereinafter simply referred to as a solar cell module) 1 has a structure in which a peripheral edge of a solar cell panel portion 14 is surrounded by a frame 11. The solar cell panel unit 14 includes a glass plate unit sandwiching the photovoltaic layer, a reinforcing unit that reinforces the glass plate unit, a wiring unit that extracts electric power generated in the photovoltaic layer, and the like. ing. The reinforcing part does not include the girder reinforcing part in contact with the roof surface as described in the conventional section. The frame 11 has a facing portion that sandwiches the solar cell panel portion 14 from the front and back sides, and a side plate portion that faces the end surface of the solar cell panel portion 14. A side plate portion extension portion 11 a is formed in the side plate portion of the underwater portion of the frame 11. A locking piece 12 is fixed to the side plate portion extension portion 11 a with screws 13. The locking piece 12 has a substantially L-shape having a joint portion that contacts the side plate portion extension portion 11a and a locking portion that folds and enters from the joint portion to the lower side of the solar cell panel portion 14. Yes. When a load is applied to the locking piece 12, the load is applied to the side plate portion in a direction parallel to the surface via the side plate portion extension portion 11a. The locking piece 12 is not limited to the screw 13 and may be fixed to the side plate portion extension portion 11a by, for example, a rivet, or may be formed integrally with the frame 11.

  Locking projections 15, 15 are provided at positions above the side plate portion extension 11 a in the frame 11, and the front cover 16 is locked to the locking projections 15, 15.

  The frame 11 is not limited to a U-shaped cross section as shown in FIG. 1, and is not limited to a frame having a step between the facing portion of the frame 11 and the surface of the solar cell panel portion 14. Absent. Moreover, although it does not show in figure about the water upper part in said solar cell module 1, what is necessary is just to provide the existing module latching structure. This existing module locking structure includes, for example, a back surface recessed portion that is locked to a roof tile disposed on the roof, a back surface side fixing portion that is locked and fixed to the roof tile by screws or the like, and a solar cell module on the upper stage side. It is provided with a surface side locking metal fitting for locking a locking piece provided in the frame portion. And the said solar cell module 1 is arrange | positioned at the 1st step | level of an eaves, About the solar cell module arrange | positioned after the 2nd step | paragraph of an eaves point, it is the same as the said solar cell module 1 above. The side plate part extension part 11a and the locking piece 12 may not be provided.

  As shown in FIGS. 2A and 2B and FIG. 3, the solar cell module fixture 2 according to this embodiment is a latch into which a latch piece 12 provided on the frame 11 of the solar cell module 1 is inserted. It has the piece clamping part 21 and the installation fixing | fixed part 22 which fixes this latching piece clamping part 21 to the roof 101. FIG. The locking piece sandwiching portion 21 includes a first load receiving portion 21A that receives the lower surface of the locking piece 12 and a second load receiving portion 21B that receives the upper surface of the locking piece 12.

  In the solar cell module fixture 2 described above, the first load receiving portions 21A and the second load receiving portions 21B are alternately arranged. Such an alternately arranged structure can be obtained, for example, by performing shearing and pressing on the flat plate portion before the locking piece holding portion 21 is obtained.

  Since stress tends to concentrate on the boundary line between the first load receiving portion 21A and the second load receiving portion 21B that are alternately arranged in this manner, in this embodiment, the first load receiving portion 21A and the second load receiving portion 21B are arranged. One reinforcing rib 23 having an arc-shaped cross section that crosses the boundary with the load receiving portion 21B is formed. The reinforcing rib 23 can be formed by the above press working. In addition, instead of such a single reinforcing rib 23, reinforcing ribs may be individually provided at positions on each boundary line.

  On the distal end side of the second load receiving portion 21B, there is formed a rising inclined portion 21C that is raised slightly in front of the distal end of the first load receiving portion 21A and inclined upward. When the solar cell module 1 is fixed by the solar cell module fixture 2, when the end of the locking piece 12 of the solar cell module 1 is placed and slid on the rising inclined portion 21 </ b> C, the locking piece 12. Is guided by the rising inclined portion 21C, and it becomes easy to guide the locking piece 12 to the locking piece holding portion 21. Further, a receiving portion 21D that is bent so as to be substantially parallel to the second load receiving portion 21B is formed on the tip end side of the rising inclined portion 21C.

  The installation fixing portion 22 of the solar cell module fixture 2 is provided in contact with the upper surface of a pedestal 102 (in this application, Hiroko Mai is also a form of the pedestal) 102 disposed on the roof 101, and screw nails 103. To be fixed to the pier 102. The installation fixing portion 22 has a through hole 25 through which the screw nail 103 is inserted. Further, the installation fixing portion 22 is provided with a positioning portion 24 for positioning the solar cell module fixture 2 in contact with the pier 102. The positioning part 24 is formed by shearing a part of the installation fixing part 22 and bending the part by connecting to the installation fixing part 22. By having such a positioning part 24, the solar cell module fixture 2 can be skillfully arranged at a correct position with reference to the pier 102.

  A nose cover 104 is disposed on the eaves side of the roof 101, and a gutter 105 is fixed to the nose cover 104 with a nail 106. The rain gutter 105 is located below the underwater side of the solar cell module 1 arranged at the first stage of the eaves.

  Here, the snow load when the snow is accumulated on the solar cell module 1 is a force for pressing the solar cell module 1 downward. In this embodiment, while the snow load is light, the receiving portion 21D hits the frame 11 of the solar cell module 1, so the receiving portion 21D receives the load of the solar cell module 1. When the rising slope portion 21C becomes heavier, the first load receiving portion 21A receives the lower surface of the locking piece 12 formed on the frame 11 of the solar cell module 1, so that the snow load is the solar cell module. 1 is transmitted from one locking piece 12 to the frame 11. Further, the wind load when the wind blows to the eaves is a force that lifts the solar cell module 1 upward, but the second load receiving portion 21B receives the upper surface of the locking piece 12, so the wind load is It is transmitted from the locking piece 12 of the solar cell module 1 to the frame 11. As described above, the solar cell module fixture 2 includes the first load receiving portion 21A and the second load receiving portion 21B, so that both the snow load and the wind load can be separated from the locking piece 12 of the solar cell module 1. 11 can be prevented from being applied to the solar cell panel unit 14 with excessive force.

  The roof structure using the solar cell module 1 is a roof structure in which the solar cell module fixture 2 described above is fixed to the roof 101 and the solar cell module 1 is fixed by the solar cell module fixture 2. The solar cell module 1 is arranged at the first stage of the eaves, and the locking piece 12 in the solar cell module 1 is inserted into the locking piece holding portion 21 in the solar cell module fixture 2. . And if it is this roof structure, even if it arrange | positions the solar cell module 1 in the 1st step | level of an eaves edge, the wind load by the wind which blows to an eave edge will be a solar cell by the 2nd load receiving part 21B of the solar cell module fixture 2. FIG. The snow load is transmitted from the locking piece 12 of the module to the frame 11 and the snow load is transmitted from the locking piece 12 of the solar cell module 1 to the frame 11 by the first load receiving portion 21A. Excessive force is prevented from being applied.

  FIG. 4 is a cross-sectional view showing a roof structure using the solar cell module fixture 3 of another embodiment. The solar cell module fixture 3 includes a locking piece holding portion 31 and an installation fixing portion 32 that fixes the locking piece holding portion 31 to the roof 101. And said latching piece clamping part 31 is the 1st load receiving part 31A which receives the lower surface of the locking piece 12 of the solar cell module 1, The 2nd load receiving part 31B which receives the upper surface of the said locking piece 12, Have The first load receiving portions 31A and the second load receiving portions 31B are alternately arranged. The distal end side of the second load receiving portion 31B forms a rising inclined portion 31C that is raised at a position before the distal end of the first load receiving portion 31A and is inclined upward. In addition, a receiving portion 31D that is bent so as to be substantially parallel to the second load receiving portion 31B is formed on the distal end side of the rising inclined portion 31C. A reinforcing rib 33 is formed on the boundary line between the first load receiving portion 31A and the second load receiving portion 31B. As described above, the locking piece holding portion 31 of the solar cell module fixture 3 has the same structure as the locking piece holding portion 21 of the solar cell module fixture 2.

  On the other hand, the installation fixing part 32 of the solar cell module fixture 3 has a first part 32A located on the roof 101 and a second part 32B straddling the horizontal rail 30 located on the roof 101. An inverted frustoconical convex portion 34 is formed on the back surface of the first portion 32A to form a gap between the back surface and the surface of the roof 101. The convex portion 34 can be formed by pressing the installation fixing portion 32. In the case of this pressing, the convex portion 34 has a shape opposite to the inverted truncated cone shape on the surface side of the first portion 32A. A certain mortar-shaped recess is formed. If it is the structure which has such a convex part 34, the raindrop which propagates on the roof 101 passes below the said 1st site | part 32A, without being blocked | interrupted by the installation fixing | fixed part 32 of said solar cell module fixing tool 3. Can be passed on. In addition, a through hole through which the screw nail 103 is inserted is formed at a central portion of the convex portion 34 and a predetermined portion of the second portion 32B.

  The crosspiece 30 is made of, for example, the same material as that of the solar cell module fixture 3 (for example, steel), and is formed by bending a flat plate of this material to form three surfaces so that the cross section is substantially U-shaped. It was made to become. The horizontal rail 30 is arranged on the roof 101 with the edge portion on the opening side facing down. A slit (not shown) is formed in the edge portion so that the raindrop can pass therethrough.

  The horizontal rail 30 may be fixed to the second portion 32B. With such a configuration, the installation work of the solar cell module fixture 3 on the roof 101 can be performed quickly. The fixing can be performed using rivets or welding. Further, the horizontal rail 30 is also formed with a through hole corresponding to the nail through hole formed in the second portion 32B.

  Moreover, in the roof structure shown in FIG. 4, the water stop member 107 is provided between the lower surface of the solar cell panel part 14 in the solar cell module 1 and the solar cell module fixture 3, and the first load receiving part 31A. And intrusion of rainwater from a gap generated at the base portion between the first load receiving portion 31B and the second load receiving portion 31B. The water stop member 107 is made of a rubber material having flexibility. The water stop member 107 is not limited to the case where the solar cell module fixture 3 is used, but can be provided when a solar cell module fixture of another form is used.

  FIG. 5 is a cross-sectional view showing a roof structure using the solar cell module fixture 4 of another embodiment. The solar cell module fixture 4 includes a locking piece holding portion 41 and an installation fixing portion 42 that fixes the locking piece holding portion 41 to the roof 101. And said latching piece clamping part 41 is the 1st load receiving part 41A which receives the lower surface of the locking piece 12 of the solar cell module 1, The 2nd load receiving part 41B which receives the upper surface of the said locking piece 12, Have The first load receiving portions 41A and the second load receiving portions 41B are alternately arranged. Further, a reinforcing rib 43 is provided on the boundary line between the first load receiving portion 41A and the second load receiving portion 41B.

  The installation fixing portion 42 of the solar cell module fixture 4 is provided so as to be in contact with the upper surface of the pier (Hiro Komai) 102 ′ disposed on the roof 101, and is fixed to the pier 102 ′ by screw nails 103. The installation fixing portion 42 has a through hole (not shown) through which the screw nail 103 is inserted. Further, the installation fixing portion 42 is formed with a positioning portion 44 for positioning the solar cell module fixture 4 in contact with the pier 102 '. The positioning portion 44 is a step portion formed by bending a predetermined portion of the installation fixing portion 22. By having such a positioning portion 44, the solar cell module fixture 2 can be skillfully arranged at the correct position with reference to the pier 102 '. The crosspiece 102 'is lighter than the crosspiece 102 by having a recess (cavity).

  FIG. 6 is a cross-sectional view showing a roof structure using the solar cell module fixture 5 of another embodiment. The solar cell module fixture 5 is made of an aluminum material, and includes a locking piece holding portion 51 and an installation fixing portion 52 that fixes the locking piece holding portion 51 to the roof 101. And the said latching piece clamping part 51 is the 1st load receiving part 51A which receives the lower surface of the locking piece 12 of the solar cell module 1, The 2nd load receiving part 51B which receives the upper surface of the said locking piece 12, Have The first load receiving portion 51A and the second load receiving portion 51B are disposed facing each other. Such a face-to-face structure can be formed by, for example, extrusion molding.

  The installation fixing part 52 of the solar cell module fixture 5 has an inclined shape corresponding to a crosspiece (Hiro Komai), and is fixed to the roof 101 by screw nails 103. The installation fixing portion 52 has a through hole (not shown) through which the screw nail 103 is inserted.

  Since the solar cell module fixture 5 has the installation fixing portion 52 having an inclined shape corresponding to a crosspiece (Hiro Komai), the solar cell module fixture 5 can be quickly and quickly arranged without placing the crosspiece on the roof 101. Can be installed on the roof 101.

DESCRIPTION OF SYMBOLS 1 Solar cell module 11 Frame part 12 Locking piece 14 Solar cell panel part 2 Solar cell module fixing tool 21 Locking piece clamping part 21A 1st load receiving part 21B 2nd load receiving part 21C Upright inclined part 21D Receiving part 22 Installation Fixing part 23 Reinforcing rib 24 Positioning part 3 Solar cell module fixture 31 Locking piece clamping part 31A First load receiving part 31B Second load receiving part 31C Upward inclined part 31D Receiving part 32 Installation fixing part 32A First part 32B First 2 parts 33 Reinforcing rib 4 Solar cell module fixture 41 Locking piece holding part 41A First load receiving part 41B Second load receiving part 42 Installation fixing part 43 Reinforcing rib 44 Positioning part 5 Solar cell module fixing tool 51 Locking piece holding Part 51A First load receiving part 51B Second load receiving part 52 Installation fixing part

Claims (8)

  A locking piece holding portion into which a locking piece provided in the frame portion of the solar cell module is inserted, and an installation fixing portion for installing and fixing the locking piece holding portion on the roof. A solar cell characterized in that a first load receiving portion for receiving the lower surface of the locking piece and a second load receiving portion for receiving the upper surface of the locking piece are formed in the locking piece holding portion. Module fixture.   2. The solar cell module fixture according to claim 1, wherein the first load receiving portion and the second load receiving portion are alternately arranged.   The solar cell module fixture according to claim 2, wherein a reinforcing rib is formed on a boundary line between the first load receiving portion and the second load receiving portion arranged alternately. Module fixture.   2. The solar cell module fixture according to claim 1, wherein the first load receiving portion and the second load receiving portion are arranged to face each other.   5. The solar cell module fixture according to claim 1, wherein the installation fixing part is a first bridge that straddles a first part located on the roof surface and a horizontal rail located on the roof surface. The solar cell module fixture according to claim 1, wherein a convex portion that forms a gap between the back surface and the roof surface is formed on the back surface of the first portion.   6. The solar cell module fixture according to claim 5, wherein the horizontal rail is fixed to the second portion.   The solar cell module fixture according to any one of claims 1 to 4, wherein the solar cell module fixture is positioned on the installation fixture in contact with a horizontal rail disposed on the roof surface. A solar cell module fixture having a positioning part to be provided.   The roof structure which fixes the solar cell module fixture of any one of Claims 1-7 to a roof, and fixes the solar cell module which has a locking piece in a frame part with the said solar cell module fixture. The solar cell module is arranged in the first stage of the eaves, and the locking piece in the solar cell module is inserted into the locking piece holding portion in the solar cell module fixture. Roof structure.

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