JP4840539B2 - Solar power panels with roofing materials and eaves materials with roofing materials - Google Patents

Description

  The present invention relates to a solar power generation panel with a roof material and an eaves material with a roof material, in which a solar power generation panel and a roof material are integrated.

The prior art will be described with reference to FIG. FIG. 10 shows a technique described in Japanese Patent Application Laid-Open No. 2007-217904.
In the abstract, the subject is “A waterproof module that does not have a waterproof / fireproof structure and uses a low-cost solar cell module. Thus, a solar cell module, a method for mounting and installing a solar cell module with a higher degree of freedom in selecting a roof shape and a roofing material is provided. "
And in the column of means for solving the problem, “a wave roof covering material having a plurality of ridges is arranged on the surface of the building base plate in a range wider than the solar cell module to be attached, and the wave roof covering material After fixing a pedestal for mounting the solar cell module on the ridge, the roof covering material is fixed to the base plate so as to surround the periphery of the solar cell module fixed to the pedestal. ing. The gantry refers to the mounting bracket E.
In paragraph number 0014, “According to the present invention, since the gantry is formed in relation to the side surface shape of the frame of the solar cell module, the solar cell module can be easily fixed. It is installed on the ridges of the timber, and the frame is fixed to the base plate with mounting members such as wood screws and nails. It can be fixed to the base plate at the same time. "

JP 2007-217904 A

In the structure shown in FIG. 10, the solar cell module 1 ′ and the corrugated roof covering material 2 ′ formed with the ridges 21 ′ are separated. For this reason, first, the trouble of attaching only the corrugated roofing material 2 ′ to the base material D is required. Next, the solar cell module 1 ′ is attached via the attachment fitting E.
The trouble of attaching the corrugated roofing material 2 ′ and the trouble of attaching the solar cell module 1 ′ are necessary.
In addition, as in paragraph 0014, an attempt is made to fix the mounting bracket E and the corrugated roofing material 2 ′ to the base material D at the same time. If it does so, since two points which have not stopped must be stopped simultaneously, there was a possibility that the corrugated roof covering 2 'may slide to the eaves side before the mounting bracket E is stopped.
Furthermore, as described in paragraph 0015, “the fixing position is the mounting pitch related to the solar cell module”, and therefore it is necessary to mark the mounting bracket E to be installed on the upper stage. In addition, the gap between the mounting brackets E and E is large, the power generation area is reduced, a joint cap for closing the gap is necessary, and parts and labor are also required.

The present application integrates the photovoltaic power generation panel and the roofing material in advance, so that it does not require the trouble of attaching the roofing material, and does not require mounting brackets or mounts. The object is to provide a photovoltaic panel with a roofing material and an eaves material with a roofing material that can be attached simply by wearing them.
In addition, on the roof, a solar power generation panel with roofing material and an eaves with roofing material that can be attached with a fastening tool without using a mounting bracket on the roof and does not require a joint cap are provided. For the purpose.

The solar power generation panel with a roof material shown in claim 1 of the present application is obtained by integrating a solar power generation panel and a roof material.
The photovoltaic power generation panel consists of a module main body and a frame attached to each side of the module. A water fitting part is formed on the underwater side of the photovoltaic power generation panel, and the water fitting is on the water upper side. The part is formed. The underwater fitting part and the overwater fitting part are shaped so that the underwater fitting part of the upper roofed photovoltaic panel fits into the overwater fitting part of the lower roofed photovoltaic panel. Is formed.
The roofing material has a mountain part and a valley part, and a space communicating in the eaves-ridge direction is formed. A wavy shape in which peaks and valleys are alternately formed may be used, or the valleys may be widened or the valleys may be narrowed.
A fastening portion is formed on the water side of the roofing material.
The eaves-ridge direction of the photovoltaic power generation panel with a roof material has a length in which the fastening portion protrudes from the water fitting portion.
By integrating the roofing material and the photovoltaic power generation panel with such a configuration, driving a fastening tool into the fastening part and fixing it, and fitting the lower water fitting part and the upper water fitting part together It is a solar power generation panel with a roof material that can be constructed simultaneously with a roof material and a solar power generation panel.

The eaves material with a roof material shown in claim 2 of the present application is an eave material when the solar power generation panel with a roof material is attached, and the eave material and the roof material are integrated.
This roof material has a mountain part and a valley part, and a space communicating in the eaves-ridge direction is formed. And the fastening part is formed in the water side, and the fastening part has the length which protrudes rather than a fitting part.
The eaves material with roofing material has a fitting part formed on the water side and a folded part is formed on the water side, and the fitting part of the eaves material with the roofing material and the photovoltaic panel with the roofing material The underwater fitting part can be fitted.
In addition, the folded portion has a shape that envelops the underwater side end surface of the roofing material.
A fastening tool is driven into and fixed to the fastening portion of the eaves-end material with the roof material, and the underwater fitting portion of the photovoltaic power generation panel with the roof material is fitted into the fitting portion.

Since mounting brackets and mounts are not required on the roof, field work can be simplified.
A fireproof structure can be obtained by using a metal roofing material.
The roofing material and the photovoltaic panel are integrated, and the eaves ridge direction is fixed by driving a fastening tool into the fastening part and fitting the lower water fitting part and the upper water fitting part. Thus, the roofing material and the photovoltaic power generation panel can be constructed at the same time. Therefore, it is possible to provide a photovoltaic power generation panel with a roof material and an eaves material with a roof material that have good workability.

It is explanatory drawing of the Example of the roofing material 2 used for this invention. It is explanatory drawing of the Example of the roofing material 2 used for this invention. It is explanatory drawing of the Example of the photovoltaic power generation panel 1 used for this invention. It is explanatory drawing of the Example of the photovoltaic power generation panel 1 used for this invention. It is explanatory drawing of the Example of the eaves material B1 used for this invention. It is explanatory drawing of the Example of Claim 1 of this invention, and is a top view. It is explanatory drawing of the Example of Claim 1 of this invention, and is sectional drawing of an eaves-ridge direction. It is explanatory drawing of the attachment state of the Example of Claim 1 of this invention, and is sectional drawing of a carry direction. It is explanatory drawing of the attachment state of the Example of Claim 1 of this invention, and is sectional drawing of a flow direction. It is explanatory drawing of the Example of Claim 2 of this invention, and is sectional drawing of an eaves-ridge direction. It is explanatory drawing of the attachment state of the Example of Claim 2 of this invention, and is sectional drawing of a flow direction. It is explanatory drawing of a prior art.

  Examples of members constituting the solar power generation panel A with a roof material shown in claim 1 of the present application will be described with reference to FIGS. 1A, 1B, 2A, and 2B. FIG. 1A and FIG. 1B are explanatory views of an example of the roof material 2 constituting the solar power generation panel A with a roof material. 2A and 2B are explanatory views of an embodiment of the photovoltaic power generation panel 1 constituting the photovoltaic power generation panel A with a roof material.

Next, the Example of the solar power generation panel A with a roof material of this application is demonstrated in the example using the roof material 2 of FIG. 1A and FIG. 1B and the solar power generation panel 1 of FIG. 2A and FIG. 2B.
As shown in FIGS. 1A and 1B, the roofing material 2 is formed by alternately forming mountain portions 21 and valley portions 22, and has a space communicating in the eaves-ridge direction. A wavy shape in which peaks and valleys are alternately formed may be used, or a shape in which valleys are widened or a shape in which valleys are narrowed may be used.
And the fastening part 23 is provided in the water upper side of the roofing material 2 , and the fastening hole 23a is formed.
When the roofing material 2 and the photovoltaic power generation panel 1 to be described later are connected, the waterside of the roofing material 2 has such a length that the fastening portion 23 protrudes from the water fitting portion 13.

  As shown in FIGS. 2A and 2B, the photovoltaic power generation panel 1 is composed of a module body 11 and a frame body attached to the four sides thereof, and a water fitting portion 12 is formed on the water side. A water fitting portion 13 is formed on the water upper side.

  Next, the attachment state of the Example of the solar power generation panel A with a roof material is demonstrated with reference to FIGS. FIG. 4 is an explanatory view of an embodiment of the present invention, and is a plan view. FIG. 5 is an explanatory diagram of an embodiment of the present invention, and is a cross-sectional view in the eaves-ridge direction. FIG. 6 is an explanatory view of the mounting state of the embodiment of the present invention, and is a cross-sectional view in the carry direction. FIG. 7 is an explanatory view of the mounting state of the embodiment of the present invention, and is a sectional view in the flow direction.

The photovoltaic power generation panel A with a roofing material is attached in the direction of the eaves from the water side to the water side. First, the fastening tool C is driven into the fastening portion 23 of the eaves material B with the roof material and fixed to the base material D at the eaves. The underwater fitting portion 12 of the photovoltaic power generation panel A with the roof material is fitted into the fitting portion B1a of the eaves material B with the roof material, and the fastening tool C is driven into the fastening portion 23, so that the solar with the roof material is obtained. The photovoltaic panel A is fixed to the base material D.
And the underwater fitting part 12 of the photovoltaic power generation panel A with an upper roof material is made to fit in the water fitting part 13 of the photovoltaic power generation panel A with the roof material.

In the case of the present embodiment, when the photovoltaic power generation panel A with a roof material is combined in the eaves-ridge direction, the upper photovoltaic power generation panel 1 is designed to cover the lower fastening portion 23. ing. Therefore, the joint cap between the photovoltaic power generation panels 1 in the eaves ridge direction and the metal fitting for stopping the joint cap are unnecessary.
Moreover, when fixing the roofing material 2 to the base material D, since the fastening tool C is stopped from the peak part 21, a water-stopping property is better than a general fixing method. Furthermore, the waterproof property is enhanced as compared with the case where the fastening tool C is exposed.

Thus, in the eaves ridge direction, the fastening tool C is driven and fixed to the lower fastening portion 23, and the upper water fitting portion 12 is fitted to the lower water fitting portion 13.
By repeating this procedure, both the roofing material 2 and the photovoltaic power generation panel 1 can be constructed.

  Next, the Example of the member which comprises the eaves material B with a roof material shown in Claim 2 of this application is demonstrated with FIG. FIG. 3 is an explanatory diagram of an example of the eaves edge material B1 constituting the eaves edge material B with the roof material.

Next, the example of the eaves material B with the roof material of this application is demonstrated in the example using the roof material 2 of FIG. 1A and FIG. 1B, and the eaves material B1 of FIG.
As shown in FIGS. 1A and 1B, the roofing material 2 is formed by alternately forming mountain portions 21 and valley portions 22, and has a space communicating in the eaves-ridge direction. A wavy shape in which peaks and valleys are alternately formed may be used, or a shape in which valleys are widened or a shape in which valleys are narrowed may be used.
And the fastening part 23 is provided in the water side of the roofing material 2 , and the fastening hole 23a is formed there .
When the roof material 2 and the eaves material B1 are connected, the waterside of the roof material 2 has such a length that the fastening portion 23 protrudes from the fitting portion B1a.

  As shown in FIG. 3, the eaves material B1 has a fitting part B1a formed on the water side and a folded part B1b formed on the water side. Between the folded-down part B1b and the underwater side end surface of the roofing material 2 is connected while ensuring a gap enough to discharge rainwater or the like, and the folded-down part B1b wraps the tip of the roofing material 2 It has a shape.

  Next, the attachment state of the Example of the eaves material B with a roof material is demonstrated with reference to FIGS. FIG. 8 is an explanatory diagram of an embodiment of the present invention, and is a cross-sectional view in the eaves-ridge direction. FIG. 9 is an explanatory view of the mounting state of the embodiment of the present invention, and is a sectional view in the flow direction.

The eaves material B with the roof material is arranged on the base material D of the eaves, and the fastening tool C is driven into the fastening part 23 to fix the eaves material B with the roof material to the base material D.
And the underwater fitting part 12 of the photovoltaic power generation panel A with a roofing material is fitted to the fitting part B1b of the eaves material B with a roofing material.

In the case of the present embodiment, when the solar power generation panel A with the roof material is fitted to the eaves material B with the roof material, the solar power generation panel 1 is placed on the fastening portion 23 of the eaves material B with the roof material. Designed to be covered. Therefore, the joint cap between the eaves material B1 and the photovoltaic power generation panel 1 and the metal fitting which stops the joint cap are unnecessary.
Moreover, since the fastening tool C is stopped from the peak part 21 when fixing the eaves material B with a roof material to the base material D, a water-stopping property is better than a general fixing method. Furthermore, the waterproof property is enhanced as compared with the case where the fastening tool C is exposed.

  Thus, the fastening tool C is driven and fixed to the fastening part 23 of the eaves material B with the roof material, and the underwater fitting part 12 of the photovoltaic power generation panel A with the roof material is fitted to the fitting part B1a. Let it attach.

The solar power generation panel 1 described so far has been described with an example of a frame body in which a fitting portion is formed. However, another member in which a fitting portion is formed may be integrated with the frame of the existing photovoltaic power generation panel 1.
Moreover, the photovoltaic power generation panel A with a roofing material demonstrated in the example mounted on the base material D directly. However, you may construct on the existing roof.
In the roofing solar photovoltaic panel A of the present application, the roofing material 2 has a space communicating in the direction of the eaves, so that it can be ventilated from the eaves side to the building side. And the rainwater which permeated can be drained to the lower water side by the space. It is good to stick an elastic water stop material to the water fitting part 12 and the water fitting part 13, and to reduce the amount of infiltration.
Furthermore, by using the fireproof roof material 2, a fireproof structure can be obtained without using the expensive solar power generation panel 1.
In addition, the height can be kept low as compared to the case where the roofing material 2 is installed and a frame or support material is attached to the solar power generation panel 1.
In the case of a close-up roof, it is preferable to construct a roof material 2 cut into a triangle. The construction cost can be further reduced as compared with the case of constructing the peripheral roof material 2 ″ different from the corrugated roof covering material 2 ′ as in the prior art of FIG.

A Solar Photovoltaic Panel with Roof Material 1 Photovoltaic Power Generation Panel 11 Module Main Body 12 Underwater Fitting Portion 13 Overwater Fitting Portion 1 ′ Solar Cell Module 2 Roofing Material 21 Mountain Portion 21 ′ Convex Strip 22 Trough Portion Fastening Portion 23a fixing hole
2 'Corrugated roofing material 2 "Peripheral roof material B Eaves with roof material B1 Eaves material B1a Fitting part B1b Folding part C Fastening tool D Base material E Mounting bracket

Claims (2)

Solar power panels and roofing materials
An integrated photovoltaic panel with roofing material,
The photovoltaic panel is
It consists of a module body and a frame attached to all four sides.
The frame is
Under the water,
Underwater fitting part is formed,
On the water side,
Water fitting portion is formed,
Underwater fitting and overwater fitting
In the water fitting part of the solar power generation panel with the roof material at the bottom,
It is formed in a shape that fits underwater fitting part of the solar power generation panel with roof material on the upper stage,
The roofing material is
It has a mountain and a valley,
A space communicating in the direction of the eaves building is formed,
A fastening part is formed on the water side,
The fastening portion is
It has a length that protrudes from the water fitting part ,
Fix the fastening tool by driving it into the lower fastening part,
A solar power generation panel with a roof material, wherein the lower water fitting portion is fitted into the lower water fitting portion . It is the eaves material of the photovoltaic power generation panel with a roof material according to claim 1,
The eaves and roofing materials
It is an eaves material with an integrated roofing material,
The eaves material is
On the water side,
Fitting portion is formed,
The fitting portion is
The upper part of the solar panel with roofing material has a shape that fits under water,
The roofing material is
It has a mountain and a valley,
A space communicating in the direction of the eaves building is formed,
A fastening part is formed on the water side,
The fastening portion is
It has a length that protrudes from the fitting part,
Under the water,
Section lower folding roof material ends are wrapped are formed,
A fastening tool is driven into and fixed to the fastening part,
An eaves-end material with a roof material , wherein the fitting portion is fitted with an underwater fitting portion of the solar power generation panel with a roof material.

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