JP2020172742A - Photovoltaic power generation system for residence and construction method thereof - Google Patents

Abstract

To provide a photovoltaic power generation system for residence capable of preventing fire from spreading to a roof when a module or a cable ignites, and to provide a construction method thereof.SOLUTION: A photovoltaic power generation system for residence including a building material-integrated type solar cell module 1 has, between the solar cell module 1 and a roofing 7, a non-inflammable board 41 for eaves and a general use non-inflammable board 42, as fire prevention boards. being separate members from the solar cell module 1 and arranged separately from the solar cell module 1. On the fire prevention boards, cable 11 drawn out of the solar cell module 1 and connectors 12 are placed.SELECTED DRAWING: Figure 9

Description

The present invention relates to a residential photovoltaic power generation system using a solar cell module integrated with building materials and a method for laying the same.

A residential photovoltaic power generation system is formed by installing a solar cell module on the roof of a house using a gantry, installation fittings, or the like. As a solar cell module used in a residential photovoltaic power generation system, a solar cell module integrated with a building material (a solar cell module is incorporated in a roof material) has become widespread (for example, Patent Documents 1 and 2). The roof of a general house has a structure in which roofing materials such as roof tiles and slate are placed on members such as rafters, field boards (roof base) and roofing (tarpaulin). The building material integrated solar cell module can be installed by roofing tiles on the roofing.

The solar cell modules are roughly classified into four types: "roof-standing type", "steel plate laying type", "steel plate incidental type", and "steel plate-less type". Of these, three types, "steel plate laying type", "steel plate incidental type", and "steel plate-less type" correspond to building material-integrated solar cell modules.

In the "steel plate laying type" tile type solar cell module, a non-combustible material such as a steel plate is laid on the roofing surface directly under the module, and the module is installed on the roofing material. The tile-type solar cell module of the "steel plate or the like incidental type" is a module in which a non-combustible material such as a steel plate is attached to the back surface of the module, and the module with the steel plate or the like is directly installed on the roofing. The "steel plate-less type" tile-type solar cell module is a module in which a module having no steel plate or the like attached to the back surface of the module is directly installed on the roofing.

On January 28, 2019, the Consumer Safety Investigation Committee published a search report (Non-Patent Document 1). Non-Patent Document 1 reports an example in which the process of spreading fire from a module to a roof (field board) was confirmed by an experiment when it was estimated that the module ignited in a "steel plate-less type" solar cell module. , The need for fire prevention measures to prevent such fire spread is described.

Japanese Unexamined Patent Publication No. 2014-147286 Japanese Unexamined Patent Publication No. 2013-249582

Consumer Safety Investigation Committee "Self-cause investigation report based on the provisions of Article 23, Paragraph 1 of the Consumer Safety Law / Fire accidents caused by residential photovoltaic power generation systems, etc."

In the unlikely event that a fire occurs from a solar cell module integrated with building materials or a cable drawn from the module, there is a risk of serious damage because the source of the fire is close to the roof. Since there is a possibility that the fire spreads to the roofing plate or roofing of the "steel plate-less type" solar cell module, it is important to improve the safety as proposed in Non-Patent Document 1.

In addition, in the "attached type such as steel plate" tile type solar cell module, the cable is installed directly on the roof roofing. For this reason, Non-Patent Document 1 describes that there is a risk of fire spreading to the roof if the cable ignites even in the “incidental type such as steel plate” tile-type solar cell module.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a residential photovoltaic power generation system capable of preventing the spread of fire to the roof in the event of a fire from a module or cable, and a method for laying the same. ..

In order to solve the above problems, the residential photovoltaic power generation system according to the first aspect of the present invention is a residential photovoltaic power generation system including at least one solar cell module integrated with building materials. Between the solar cell module and the roofing, a fireproof non-combustible plate which is a separate member from the solar cell module and is arranged apart from the solar cell module is provided, and the solar cell module and the solar cell module are described. It is characterized in that a cable member drawn out from the solar cell module is arranged between the non-combustible plate for fire protection.

According to the above configuration, a fireproof incombustible plate is arranged below the solar cell module, and the fireproof incombustible plate is a separate member from the solar cell module and is separated from the solar cell module. Since the cable member is also placed on the fireproof noncombustible plate, if the solar cell module is a "steel plate-less type", even if the module or cable member catches fire, the fireproof noncombustible plate will be used to cover the roof. It is possible to make a residential photovoltaic power generation system with high fire prevention performance by preventing the spread of fire. Further, even when the solar cell module is an "incidental type such as a steel plate", it is possible to prevent the spread of fire to the roof when the cable member ignites.

Further, in the residential photovoltaic power generation system, the fireproof non-combustible plate may be arranged so as to be separated from the roofing.

According to the above configuration, since the fireproof noncombustible plate is arranged apart from the roofing, the fireproof noncombustible plate does not obstruct the flow of water on the roofing. In addition, the heat dissipation is improved as compared with the case where the non-combustible plate for fire prevention is in contact with the roofing, and it can be expected that the safety in case of ignition is improved.

Further, in the residential photovoltaic power generation system, the ridge-side end of the solar cell module is attached to the roof via a rear fixing member, and the eaves-side end of the fireproof noncombustible plate is rearward. By placing it on the fixing member, it can be configured to be separated from the roofing.

According to the above configuration, the fireproof non-combustible plate can be easily separated from the roofing.

Further, in the residential photovoltaic power generation system, the ridge-side end of the solar cell module is attached to the roof via a rear fixing member, and the fireproof noncombustible plate is integrated with the rear fixing member. It can be configured as.

According to the above configuration, it is possible to reduce the number of members in the residential photovoltaic power generation system.

Further, the residential photovoltaic power generation system according to the second aspect of the present invention is a photovoltaic power generation system for housing including at least one solar cell module integrated with a building material, and is on the building side of the solar cell module. The end portion is attached to the roof via a rear fixing member, and the rear fixing member has a holding tray portion on which a cable member drawn from the solar cell module is placed, and the solar cell. A fireproof noncombustible plate, which is a separate member from the solar cell module, is provided between the module and the roofing, and the eaves-side end of the fireproof noncombustible plate is placed on the rear fixing member. It is characterized by that.

According to the above configuration, since the cable member is placed on the holding tray portion, ignition occurs from the cable member when the solar cell module is a "steel plate-less type" or a "steel plate incidental type". However, the holding tray portion prevents the spread of fire to the roof, and a residential photovoltaic power generation system with high fireproof performance can be obtained. Furthermore, when the solar cell module is a "steel plate-less type", even if a fire occurs from the module member, the fire-prevention non-combustible plate prevents the spread of fire to the roof, making it a residential photovoltaic power generation system with high fire-prevention performance. can do.

Further, the method of laying a residential photovoltaic power generation system according to a third aspect of the present invention is a method of laying a residential photovoltaic power generation system including at least one solar cell module integrated with building materials. The ridge-side end of the solar cell module is attached to the roof via a rear fixing member, and is a member separate from the solar cell module between the solar cell module and the roofing, and the solar cell. The first step of placing the fireproof noncombustible plate arranged apart from the module on the roofing, and the solar cell module after the solar cell module are placed on the fireproof noncombustible plate mounted in the first step. It is characterized by including a second step of mounting it together with a fixing member and fixing the eaves-side end portion of the fireproof noncombustible plate and the rear fixing member together with a wood screw to the roof.

According to the above configuration, the fireproof non-combustible plate only needs to be placed on the roof before the installation of the solar cell module, and the residential photovoltaic power generation system having high fireproof performance without causing a significant increase in the laying process. Can be laid.

In the residential photovoltaic power generation system of the present invention and its laying method, a fireproof non-combustible plate or a holding tray portion can prevent the spread of fire to the roof when a module or cable ignites, and the residential photovoltaic power generation system has high fireproof performance. It has the effect of providing a system.

It is a top view which shows the schematic structure of the solar cell module used in the residential photovoltaic power generation system of this invention. It is sectional drawing which includes the eaves side and the ridge side end of the solar cell module of FIG. It is sectional drawing explaining the intermediate state of the laying work of the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is a top view and a cross-sectional view of the noncombustible plate for eaves used in the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is sectional drawing explaining the intermediate state of the laying work of the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is a figure which shows the rear fixing member used in the residential photovoltaic power generation system which concerns on Embodiment 1, (a) is a plan view, (b) is the AA sectional view of (a). It is sectional drawing explaining the intermediate state of the laying work of the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is a plan view and sectional view of the general-purpose noncombustible plate used in the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is sectional drawing explaining the intermediate state of the laying work of the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is sectional drawing explaining the intermediate state of the laying work of the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is a top view which shows the overlapping condition of a solar cell module and a non-combustible plate for fire prevention. It is sectional drawing explaining the intermediate state of the laying work of the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is sectional drawing explaining the intermediate state of the laying work of the residential photovoltaic power generation system which concerns on Embodiment 1. FIG. It is sectional drawing which shows one structural example of the residential photovoltaic power generation system which concerns on Embodiment 2. FIG. It is sectional drawing which shows one structural example of the residential photovoltaic power generation system which concerns on Embodiment 3. FIG. It is sectional drawing which shows one structural example of the residential photovoltaic power generation system which concerns on Embodiment 4. FIG. It is sectional drawing which shows one structural example of the residential photovoltaic power generation system which concerns on Embodiment 4. FIG. It is sectional drawing which shows one structural example of the residential photovoltaic power generation system which concerns on Embodiment 4. FIG. It is sectional drawing which shows one structural example of the residential photovoltaic power generation system which concerns on Embodiment 4. FIG.

[Embodiment 1]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Solar cell module configuration>
First, the basic configuration of the solar cell module 1 used in the residential photovoltaic power generation system of the present invention will be described with reference to FIGS. 1 and 2. The solar cell module 1 is a building material-integrated solar cell module that can be installed on the roofing by roofing tiles. Further, the solar cell module 1 is referred to as a "steel plate-less type" solar cell module here. Since the solar cell module 1 itself has a known configuration, the configuration of the solar cell module 1 will be briefly described below.

FIG. 1 is a plan view showing a schematic configuration of the solar cell module 1. The solar cell module 1 is composed of a rectangular solar cell panel 2 that photoelectrically converts sunlight and a frame 3 arranged on the peripheral edge of the solar cell panel 2. The frame 3 is composed of four module frames attached to each of the four sides of the solar cell module. In the solar cell module 1, the front frame 31 attached to the eaves side and the rear frame 32 attached to the ridge side have different shapes on the two sides facing each other along the water flow direction of the roof.

The solar cell panel 2 is sealed by sandwiching a solar cell between, for example, one glass plate and a protective layer (back sheet). Alternatively, a solar cell in which a transparent electrode film, a photoelectric conversion layer (semiconductor layer), and a back surface electrode film are sequentially laminated is sandwiched between two glass plates, and the end of each glass plate is sealed. Good. To explain the solar cell panel 2 in more detail, a transparent electrode, a photoelectric conversion layer composed of a semiconductor layer, and a back surface electrode layer are laminated in this order on a glass substrate which is a translucent substrate to form a solar cell. The structure is such that a transparent glass substrate, which is a protective plate, is attached to the back surface electrode layer side to seal between the glass substrates.

FIG. 2 is a cross-sectional view including the eaves side and ridge side ends of the solar cell module 1. The front frame 31 and the rear frame 32 are made of, for example, an aluminum material, and the shape of the cross section perpendicular to the longitudinal direction is basically the same at any location. The cross-sectional structures of the front frame 31 and the rear frame 32 shown in FIG. 2 are merely examples, and the present invention is not limited to this structure.

At the upper end of the front frame 31, a panel front end holding portion 311 having a substantially U-shaped cross section with an opening on the ridge side is formed. The front end portion of the solar cell panel 2 is fitted and held in the panel front end holding portion 311. The panel front end holding portion 311 and the solar cell panel 2 are adhered to each other by an adhesive or the like, and the front frame 31 is fixed to the solar cell panel 2 by this adhesion. At the lower end of the front frame 31, a first engaging portion 312 extending substantially horizontally toward the ridge side is formed.

At the upper end on the front surface side of the rear frame 32, a panel rear end holding portion 321 having a substantially U-shaped cross section with an opening on the eaves side is formed. The rear end portion of the solar cell panel 2 is fitted and held in the panel rear end holding portion 321. The panel rear end holding portion 321 and the solar cell panel 2 are adhered to each other by an adhesive or the like, and the rear frame 32 is fixed to the solar cell panel 2 by this adhesion.

The upper surface 32a of the rear frame 32 is formed with a second engaging portion 322 having a substantially L-shaped cross section, which is erected upward from the upper surface 32a and further bent toward the eaves side. On the lower surface 32b of the rear frame 32, a third engaging portion 323 having a substantially L-shaped cross section is formed, which is erected downward from the lower surface 32b and further bent toward the eaves side.

Further, a reinforcing bar 33 for connecting and reinforcing the front frame 31 and the rear frame 32 may be provided on the back surface of the solar cell module 1. The reinforcing bar 33 prevents the front frame 31 and the rear frame 32 from coming off from the solar cell panel 2 by connecting the front end side to the front frame 31 and the rear end side to the rear frame 32.

Subsequently, the structure and laying procedure of the residential photovoltaic power generation system according to the first embodiment, that is, the roof mounting structure and installation procedure of the solar cell module 1 will be described with reference to FIGS. 3 to 9.

In the residential photovoltaic power generation system according to the present embodiment, a plurality of solar cell modules 1 can be installed by roofing tiles along the water flow direction A of the sloped roof. Further, a plurality of solar cell modules 1 are arranged in an array not only in the water flow direction A but also in the horizontal direction (direction orthogonal to the water flow direction A). The solar cell modules 1 arranged in the horizontal direction in this way are also connected by the frame 3, but since a well-known structure can be used for this connection structure, detailed description thereof will be omitted here. The residential photovoltaic power generation system of the present invention is not limited to a configuration in which a plurality of solar cell modules 1 are arranged in an array, and is configured to include at least one solar cell module 1. It should be.

When a plurality of solar cell modules 1 are installed along the water flow direction A, they are installed in order from the eaves side to the ridge side. Therefore, in the following description, the solar cell module 1 installed on the eaves side of the residential photovoltaic power generation system is counted as the first row, and is counted as the second row, the third row, and the like toward the ridge side. ..

On the roof on which the residential photovoltaic power generation system is laid, roofing 7 is laid on the roofing board 6, and roof tiles 5 and piers 8 for hooking the solar cell module 1 are arranged on the roofing 7 at predetermined intervals. There is.

In the first stage of the laying work of the residential photovoltaic power generation system, as shown in FIG. 3, the roof tile 5 is attached to the most eaves side of the roof. Specifically, the rear end of the roof tile 5 is hooked on the crosspiece 8 and fixed to the crosspiece 8 by a wood screw or the like. At this time, the front fixing metal fitting 91 is placed on the rear end portion of the upper surface 5a of the roof tile 5, and the front fixing metal fitting 91 is fastened together with the roof tile 5 by a wood screw or the like. The front fixing bracket 91 fastened together with the roof tile 5 forms a gap with the eaves side open between the roof tile 5 and the upper surface 5a of the roof tile 5, and engages the first engaging portion 312 of the front frame 31 with this gap. It has become.

When the roof tile 5 and the front fixing bracket 91 are installed, the eaves noncombustible plate 41 is placed on the ridge side of the roof tile 5, as also shown in FIG. The eaves non-combustible plate 41 is arranged below the solar cell module 1 in the first row, and is used to prevent the spread of fire to the roof when the module or cable of the solar cell module 1 ignites. It is a board. The material of the non-combustible plate 41 for eaves is not particularly limited as long as it is non-combustible, but a steel plate or the like can be preferably used.

FIG. 4 is a plan view and a cross-sectional view of the eaves noncombustible plate 41. At the front end (eave side end portion) of the eaves noncombustible plate 41, a bent portion 411 having a substantially L-shaped cross section is formed which is erected upward and further bent toward the eaves side. At the rear end (building side end) of the eaves noncombustible plate 41, a convex portion 412 having a convex shape upward and a substantially U-shaped cross section is formed. A flat plate portion 413 is connected and formed further behind the convex portion 412 (on the ridge side). Further, the eaves noncombustible plate 41 may be appropriately provided with a drainage groove or a drainage hole for draining rainwater or the like flowing on the eaves noncombustible plate 41.

The non-combustible plate 41 for eaves is placed so that the bent portion 411 is placed on the rear end of the roof tile 5 and the convex portion 412 is placed on the crosspiece 8. The non-combustible plate 41 for eaves placed in this way can be installed with a certain space between the roofing plate 7 and the roofing plate 7 (that is, separated from the roofing roof 7). Further, since the convex portion 412 is caught on the crosspiece 8, the non-combustible plate 41 for eaves is prevented from slipping down due to gravity on the sloped roof during the construction, which has the effect of improving the workability.

The separation distance between the eaves noncombustible plate 41 and the roofing 7 is, for example, 1 to 14 mm. Further, by setting the separation distance to 3 mm or more, water can easily flow on the roofing 7, and the safety at the time of ignition can be improved as compared with the case where the roofing 7 is in contact with the roofing 7. Further, since the height of the general crosspiece 8 is about 15 mm, the convex portion 412 can be more easily caught on the crosspiece 8 by setting the separation distance to 10 mm or less.

When the non-combustible plate 41 for eaves is placed, the solar cell module 1 in the first row is installed on the non-combustible plate 41 for eaves, as shown in FIG. At this time, the cable 11 and the connector 12 pulled out from the solar cell module 1 in the first row are also placed on the eaves noncombustible plate 41. Here, the cable 11 and the connector 12 correspond to the cable members described in the claims.

A rear fixing bracket 92 is used for installing the solar cell module 1 in the first row. 6A and 6B are views showing the rear fixing bracket 92, where FIG. 6A is a plan view and FIG. 6B is a sectional view taken along the line AA of FIG. 6A.

At the front end (eave side end) of the rear fixing bracket 92, a fourth engaging portion 921 having a substantially L-shaped cross section is formed which is erected upward and further bent toward the ridge side. .. As shown in FIG. 6A, a plurality of notches may be formed in the fourth engaging portion 921. At the rear end (building side end) of the rear fixing bracket 92, an engaging piece 922 erected downward is formed. The engaging piece 922 is formed by making a plurality of slit-shaped notches at the rear end of the rear fixing bracket 92 and bending the portion sandwiched between the notches downward.

As shown in FIG. 5, a rear fixing bracket 92 is attached to the solar cell module 1 as a preliminary step for installing the solar cell module 1. Specifically, the rear fixing bracket 92 is attached to the solar cell module 1 by engaging the fourth engaging portion 921 of the rear fixing bracket 92 with the third engaging portion 323 of the rear frame 32.

The solar cell module 1 to which the rear fixing bracket 92 is attached is arranged so that the first engaging portion 312 of the front frame 31 is engaged with the front fixing bracket 91 and the rear fixing bracket 92 is placed on the crosspiece 8. Ru. At this time, the engaging piece 922 of the rear fixing bracket 92 is located on the ridge side of the crosspiece 8 to prevent the arranged solar cell module 1 from sliding down due to gravity. The arranged solar cell module 1 is installed (fixed) by tightening the rear fixing bracket 92 together with the eaves noncombustible plate 41 on which the rear fixing metal fitting 92 was previously placed together with the crosspiece 8 with a wood screw or the like. Therefore, a plurality of screw holes 414 are formed at predetermined intervals in the eaves noncombustible plate 41 (see FIG. 4), and a plurality of screw holes 923 are formed at predetermined intervals in the rear fixing bracket 92 (FIG. 4). 6).

When the solar cell module 1 in the first row is installed, as shown in FIG. 7, a general-purpose noncombustible plate 42 is placed on the ridge side of the solar cell module 1 in the first row. The general-purpose non-combustible plate 42 is arranged below the solar cell module 1 in the second and subsequent rows, and is for fire prevention to prevent the spread of fire to the roof when the module or cable of the solar cell module 1 ignites. It is a non-combustible plate. Similar to the eaves noncombustible plate 41, the material of the general noncombustible plate 42 is not particularly limited as long as it is nonflammable, but a steel plate or the like can be preferably used.

FIG. 8 is a plan view and a cross-sectional view of the general-purpose noncombustible plate 42. At the rear end (building side end) of the general-purpose noncombustible plate 42, a convex portion 421 having a convex shape upward and a substantially U-shaped cross section is formed. A flat plate portion 422 is connected and formed behind the convex portion 421 (on the ridge side). Further, the general-purpose non-combustible plate 42 may also be appropriately provided with a drain ditch or a drain hole for draining rainwater or the like flowing on the general-purpose non-combustible plate 42. Further, also in the general-purpose non-combustible plate 42, a plurality of screw holes 423 are formed at predetermined intervals.

The general-purpose non-combustible plate 42 is placed so that its front end (eave-side end) is placed on the flat plate portion 413 of the eaves non-combustible plate 41 and the convex portion 421 is placed on the crosspiece 8. The general-purpose non-combustible plate 42 placed in this way can be installed with a certain space between it and the roofing 7. Further, since the convex portion 421 is caught on the crosspiece 8, the general-purpose non-combustible plate 42 is prevented from slipping down due to gravity on the sloped roof during the construction, which has the effect of improving the workability.

The separation distance between the general-purpose non-combustible plate 42 and the roofing 7 is, for example, 1 to 14 mm. Further, by setting the separation distance to 3 mm or more, water can easily flow on the roofing 7, and the safety at the time of ignition can be improved as compared with the case where the roofing 7 is in contact with the roofing 7. Further, since the height of the general crosspiece 8 is about 15 mm, the convex portion 421 is more likely to be caught on the crosspiece 8 by setting the separation distance to 10 mm or less.

When the general-purpose non-combustible plate 42 is placed, the solar cell module 1 in the second row is installed on the non-combustible plate 42 for general use, as shown in FIG. The cables and connectors drawn out from the solar cell module may be arranged on the lower side (back side) of the module, or may be pulled up to the module building side (that is, not arranged on the lower side of the module). is there. At this time, if the cable 11 and the connector 12 are arranged on the lower side (back side) of the solar cell module 1, the cable 11 and the connector 12 pulled out from the solar cell module 1 in the second row are also general-purpose noncombustible plates. It can be placed on top of 42.

Further, even if the cable 11 and the connector 12 are arranged on the lower side (back side) of the solar cell module 1, the configuration is limited to the configuration in which the cable 11 and the connector 12 are placed on the general-purpose noncombustible plate 42. Not done. For example, the cable 11 or the connector 12 may be attached to the back surface of the solar cell panel 2 by using some member so as to be arranged between the solar cell module 1 and the non-combustible plate for fire prevention. Even with such a configuration, the general-purpose noncombustible plate 42 still exists between the cable 11 and the connector 12 and the roof.

The installation method of the second row solar cell module 1 is almost the same as that of the first row solar cell module 1, but the first engaging portion 312 of the front frame 31 is the rear frame of the first row solar cell module 1. The only difference is that it engages with the second engaging portion 322 of 32. The solar cell modules 1 in the third and subsequent rows are installed in the same manner as the solar cell modules 1 in the second row. Further, as shown in FIG. 10, a roof tile 5 may be installed on the ridge side of the solar cell module 1 in the final row (most ridge side).

As described above, in the residential photovoltaic power generation system according to the first embodiment, the eaves noncombustible plate 41 or the general noncombustible plate 42, which is a fireproof noncombustible plate, is arranged below the solar cell module 1. These fireproof non-combustible plates are separate members from the solar cell module 1 and are separated from the solar cell module 1. The cable 11 and the connector 12 can also be placed on these fireproof non-combustible plates. FIG. 11 is a plan view showing how the solar cell module 1 and the non-combustible plate for fire prevention are overlapped with each other. In FIG. 11, the non-combustible plate for fire prevention (here, the non-combustible plate for general use 42) is shown by diagonal hatching. As shown in FIG. 11, these fireproof non-combustible plates are interposed between the solar cell module 1 and the roof so as to completely cover the arrangement area of the solar cell module 1.

Therefore, when the solar cell module 1 is a "steel plate-less type", even if a fire occurs from the module or cable, the non-combustible plate for fire prevention prevents the spread of fire to the roof, and the solar power for housing with high fire prevention performance. It can be a power generation system. The cable 11 and the connector 12 do not necessarily have to be placed on the fireproof noncombustible plate, and may be arranged between the solar cell module 1 and the fireproof noncombustible plate. Even in this case, the same effect as described above can be obtained.

In the present invention, the solar cell module 1 is not limited to the "type without steel plate or the like". That is, even when the solar cell module 1 is an "incidental type such as a steel plate", the spread of fire to the roof when the cable ignites is prevented, and the application of the present invention is effective.

Further, the eaves non-combustible plate 41 and the general non-combustible plate 42 drain water on the eaves non-combustible plate 41 and the general-purpose non-combustible plate 42, which are fire-preventive non-combustible plates, and water is discharged on these fire-proof non-combustible plates. It is desirable to have a drainage ditch (or drainage hole) to prevent accumulation. That is, the water on the fireproof noncombustible plate flows along the water flow direction A, and the drainage groove of the other fireproof noncombustible plate installed from the drainage ditch provided in the fireproof noncombustible plate or on the eaves side thereof. It can be configured to be drained from. Further, since these non-combustible plates for fire prevention are arranged apart from the roofing 7, they do not obstruct the flow of water on the roofing 7. These drainage ditches are arranged between the screw holes 414 of the eaves noncombustible plate 41 and the screw holes 423 of the general noncombustible plate 42 in the horizontal direction of the roof (direction orthogonal to the water flow direction A). Is preferable. At the screw holes 414 and 423, the wood screws are inserted into the field board 6, so this is the weakest waterproof groove, and these drains are as far away from these screw holes as possible. It is preferable that it is provided.

In the residential photovoltaic power generation system described above, a normal roof tile 5 is installed on the eaves side of the solar cell module 1 in the first row, but the present invention is not limited to this. As shown in 12, the solar cell module 1 in the first row from the eaves side of the roof may be installed. In this case, first, the front fixing bracket 93 and the non-combustible plate 43 for the eaves are fastened together to the roof with wood screws or the like, and then the solar cell module 1 in the first row is installed. The installation method of the solar cell modules 1 in the second and subsequent rows is the same as the above description. Further, in FIG. 12, the eaves non-combustible plate 43 is arranged under the front fixing bracket 93, and the eaves non-combustible plate 43 and the front fixing bracket 93 are fastened together to the roof, but as shown in FIG. 13, the front Only the fixing bracket 93 may be fixed to the roof with a wood screw or the like, and the eaves noncombustible plate 43'may be placed on the front fixing bracket 93. Further, although not shown, a member in which the eaves noncombustible plate 43 and the front fixing bracket 93 are integrated may be used.

Further, in a residential photovoltaic power generation system, it is necessary to ground each solar cell module 1. In the conventional residential photovoltaic power generation system, the included solar cell modules are connected to each other by ground, but in the residential photovoltaic power generation system according to the first embodiment, the fixing brackets (front fixing bracket 91, 93 and rear fixing bracket 92) and fireproof non-combustible plates (eave non-combustible plates 41, 43 and general non-combustible plates 42) are in contact with each other, and since these are continuously conductive, these fixing brackets and By using a non-combustible plate for fire protection as an earth path, a more reliable earth can be obtained.

When using a fixing bracket or a fireproof non-combustible plate as a grounding path, provide grounding spikes (projections) (see FIGS. 4 and 8) at arbitrary locations (preferably multiple locations) on the contact surface with other members. It may be configured. At the place where such a grounding spike is provided, a pressure contact force is generated between the members in contact with each other, and the continuity between the members can be made more reliable.

[Embodiment 2]
In the first embodiment, the front fixing bracket 91 and the eaves non-combustible plate 41 are used as separate members, and the rear fixing bracket 92 and the general-purpose non-combustible plate 42 are used as separate members. It can also be used as a member to reduce the number of members. That is, it is also possible to equip the non-combustible plate for fire prevention with the functions of the front fixing bracket and the rear fixing bracket.

As shown in FIG. 14, the residential photovoltaic power generation system according to the second embodiment has a non-combustible plate 44 for eaves having a function of a front fixing bracket and a general non-combustible plate 45 having a function of a rear fixing bracket. Is using.

The eaves non-combustible plate 44 is used as a fire-preventive non-combustible plate for the first-row solar cell module 1 and as a front fixing bracket for the first-row solar cell module 1. Further, the general-purpose non-combustible plate 45 is used as a fire-preventive non-combustible plate for the solar cell modules 1 in the second and subsequent rows, and is also used as a rear fixing bracket for the solar cell module 1 on the eaves side thereof.

However, when the general-purpose non-combustible plate 45 is used as a rear fixing bracket, it is premised that the solar cell module 1 is further installed on the ridge side, so that the general-purpose non-combustible plate 45 is the solar cell module 1 in the final row. It is not used as a rear fixing bracket. As the rear fixing bracket of the solar cell module 1 in the final row, the rear fixing bracket 92 described in the first embodiment is used.

[Embodiment 3]
In the first embodiment, the cable 11 and the connector 12 drawn out from the solar cell module 1 are placed and held on the eaves noncombustible plate 41 and the general noncombustible plate 42, which are fireproof noncombustible plates. On the other hand, in the third embodiment, the front fixing bracket and the rear fixing bracket have a function of holding the cable 11 and the connector 12.

As shown in FIG. 15, the residential photovoltaic power generation system according to the third embodiment uses a front fixing bracket 94 and a rear fixing bracket 95 having a function of holding the cable 11 and the connector 12. Specifically, the front fixing bracket 94 and the rear fixing bracket 95 are provided with a holding tray (holding tray portion) 941 and a holding tray (holding tray portion) 951 on the ridge side of the portion screwed to the crosspiece 8. There is. The cable 11 and the connector 12 are placed and held on the holding tray 941 and the holding tray 951.

Further, in the residential photovoltaic power generation system according to the third embodiment, the general-purpose non-combustible plate 46 is used as the non-combustible plate for fire prevention. The general-purpose non-combustible plate 46 can be placed so that its front end is hooked on the rear wall of the holding tray 941 or the holding tray 951. Also in the third embodiment, the rear fixing bracket 92 described in the first embodiment is used as the rear fixing bracket of the solar cell module 1 in the final row.

In the residential photovoltaic power generation system according to the third embodiment, when the solar cell module 1 is a "non-steel plate or the like type", a general-purpose non-combustible plate 46 is used, but the solar cell module 1 is "attached to a steel plate or the like". In the case of "mold", the general-purpose non-combustible plate 46 can be omitted. This is because in the "steel plate or the like incidental type" solar cell module 1, it is sufficient to prevent the spread of fire to the roof when the cable 11 or the connector 12 ignites, and the effect is provided on the front fixing bracket 94 and the rear fixing bracket 95. This is because it can be obtained only with the holding tray 941 and the holding tray 951.

Further, in the residential photovoltaic power generation system according to the third embodiment, only one type of non-combustible plate for general use 46 may be used as the non-combustible plate for fire prevention, and in this case, there is an advantage in terms of cost.

[Embodiment 4]
In the first to third embodiments, the case where the crosspiece 8 is provided on the roof on which the residential photovoltaic power generation system is laid has been illustrated, but the present invention is not limited to this, and the residential photovoltaic power generation system is not limited to this. The power generation system can also be installed on a roof on which the pier 8 is not provided. A configuration example of the residential photovoltaic power generation system in this case is shown in FIGS. 16 to 19 below.

The residential photovoltaic power generation system shown in FIG. 16 is configured by using a solar cell module 1, a rear fixing bracket 96, a holding tray plate (holding tray portion) 97, and a general-purpose non-combustible plate 47. As a procedure for laying this residential photovoltaic power generation system, the general-purpose non-combustible plate 47 (rear end), the rear fixing bracket 96, and the holding tray plate 97 are fixed together with the field plate 6 and the roofing 7 with wood screws or the like. Then, the next row of non-combustible plates 47 for general use will be placed on the ridge side. A step portion 471 is provided at the front end of the general-purpose non-combustible plate 47, and by hooking the step portion 471 on the rear end of the holding tray plate 97, it is possible to prevent the general-purpose non-combustible plate 47 from slipping off before being fixed. Further, the solar cell module 1 in the next row is installed on the general-purpose non-combustible plate 47 in the next row. By repeating these steps, the residential photovoltaic power generation system shown in FIG. 16 can be laid.

The residential photovoltaic power generation system shown in FIG. 17 is configured by using a solar cell module 1, a rear fixing bracket 98, and a general-purpose non-combustible plate 47. The rear fixing bracket 98 is a member in which the rear fixing bracket 96 and the holding tray plate 97 shown in FIG. 16 are integrated. Therefore, the procedure for laying the residential photovoltaic power generation system shown in FIG. 17 is basically the same as that for the residential photovoltaic power generation system shown in FIG.

The residential photovoltaic power generation system shown in FIG. 18 is configured by using a solar cell module 1 and a general-purpose non-combustible plate 48. Further, the residential photovoltaic power generation system shown in FIG. 18 is configured by using the solar cell module 1 and the general-purpose non-combustible plate 49. The general-purpose non-combustible plate 48 and the general-purpose non-combustible plate 49 have the function of a rear fixing bracket for the solar cell module 1 in the front row. Further, the general-purpose non-combustible plate 48 is arranged so as to come into contact with the roofing 7 almost as a whole, but the general-purpose non-combustible plate 49 can be arranged apart from the roofing 7 except for the portion to be screwed. There is.

As a procedure for laying these residential photovoltaic power generation systems, the general-purpose non-combustible plate 48 or the general-purpose non-combustible plate 49 is fixed to the field plate 6 and the roofing 7 with wood screws or the like, and the solar cell module 1 is installed on the field plate 6 and the roofing 7. .. By repeating these procedures, the residential photovoltaic power generation system shown in FIG. 18 or FIG. 19 can be laid.

The embodiments disclosed this time are exemplary in all respects and do not provide a basis for limited interpretation. Therefore, the technical scope of the present invention is not construed solely by the above-described embodiments, but is defined based on the description of the claims. It also includes all changes within the meaning and scope of the claims.

1 Solar cell module 11 cable (cable member)
12 connector (cable member)
2 Solar cell panel 3 Frame 31 Front frame 32 Rear frame 41, 43, 44 Non-combustible board for eaves (non-combustible board for fire protection)
42, 45, 46, 47, 48, 49 General-purpose non-combustible plate (fire-proof non-combustible plate)
5 Roof tile 6 Field board 7 Roofing 8 Pier 91, 93, 94 Front fixing bracket 92, 95, 96, 98 Rear fixing bracket 97 Holding tray plate (holding tray part)
941,951 Holding tray (holding tray part)

Claims (6)

A residential photovoltaic power generation system that includes at least one solar cell module integrated with building materials.
Between the solar cell module and the roofing, a fireproof non-combustible plate which is a separate member from the solar cell module and is arranged away from the solar cell module is provided.
A residential photovoltaic power generation system, characterized in that a cable member drawn from the solar cell module is arranged between the solar cell module and the fireproof non-combustible plate. The residential photovoltaic power generation system according to claim 1.
A residential photovoltaic power generation system in which the fireproof noncombustible plate is arranged apart from the roofing. The residential photovoltaic power generation system according to claim 2.
The ridge-side end of the solar cell module is attached to the roof via a rear fixing member.
A residential photovoltaic power generation system characterized in that the eaves-side end portion of the fireproof non-combustible plate is separated from the roofing by being placed on the rear fixing member. The residential photovoltaic power generation system according to claim 2.
The ridge-side end of the solar cell module is attached to the roof via a rear fixing member.
The fireproof non-combustible plate is a residential photovoltaic power generation system characterized in that it is integrally configured with the rear fixing member. A residential photovoltaic power generation system that includes at least one solar cell module integrated with building materials.
The ridge-side end of the solar cell module is attached to the roof via a rear fixing member.
The rear fixing member has a holding tray portion on which a cable member drawn from the solar cell module is placed.
A fireproof non-combustible plate, which is a separate member from the solar cell module, is provided between the solar cell module and the roofing.
A residential photovoltaic power generation system characterized in that the eaves-side end portion of the fireproof noncombustible plate is placed on the rear fixing member. It is a method of laying a residential photovoltaic power generation system including at least one solar cell module integrated with building materials.
The ridge-side end of the solar cell module is attached to the roof via a rear fixing member.
The first step of placing a fireproof non-combustible plate on the roofing between the solar cell module and the roofing, which is a member separate from the solar cell module and is arranged apart from the solar cell module. ,
The solar cell module is placed together with the rear fixing member on the fireproof noncombustible plate mounted in the first step, and the eaves side end portion of the fireproof noncombustible plate and the rear fixing member are made of wood. A method of laying a residential photovoltaic power generation system, which comprises a second step of fixing the roof together with screws.

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