JP2001055782A - Assembling building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To utilize the constituent material of a roof framework to be proper wired by providing wiring paths housing a cable extending from solar battery module constituting roofing materials on a support and the roof framework respectively. SOLUTION: A roof framework 4 is formed from a support 3, a beam 11, a horizontal material 12, a front frame 13, a rear frame 14, a side frame 15 and a roofing material suppressor 16. In addition, a plurality of solar battery cells are provided on a glass substrate, a solar battery module comprising a roofing material 5 is formed, and the roofing material 5 is supported by the roof framework 4 to form a shed roof part 2 in the horizontal direction. The roof part 2 is supported with the support 3. Furthermore, the cable 6 of the solar battery module of the roofing material 5 of the roof part 2 is wired in the hollow part 3a of the support 3 from the beam groove part of the beam 11 of the roof framework 4, and exposed from the lower part of the support 3 to be connected to an inverter 7. Thereby the cable 6 of the solar battery module of the roofing material 5 can be suitably wired by utilizing the constitution material of the roof framework 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a prefabricated building such as a carport, a terrace roof, a balcony roof and the like, in which a solar cell module is incorporated into a roofing material.

[0002]

2. Description of the Related Art Conventionally, as a carport (assembled building) incorporating a solar cell module, for example, Japanese Utility Model Publication No. 6-34.
No. 521 and Japanese Utility Model Laid-Open No. 5-57229 are known. In this carport, a plurality of solar cell modules are incorporated as a roofing material, and the electric power generated by the solar cell modules is stored in a battery and is appropriately used for lighting of the carport.

[0003]

In this type of solar cell power generation, it is necessary to connect a plurality of solar cell modules in series. However, if the cable extending from the terminal box of each photovoltaic module is simply connected and wired, the cable will be exposed on the attic of the carport and will hang down, so that the cable will be obstructed or accidentally cut off. Problems arise.

[0004] It is an object of the present invention to provide an assembled building in which a cable of a solar cell module can be appropriately wired by using components of a roof frame.

[0005]

The prefabricated building according to the present invention comprises a support, a roof frame supported by the support, and a roofing material supported by the roof frame, and the roofing material is constituted by a solar cell module. In the assembled building, a wiring route for accommodating a cable extending from the solar cell module is provided in each of the support pillar and the roof frame.

[0006] According to this configuration, the cable extending from the terminal box of the solar cell module is wired by using a roof frame component such as a purlin or a beam closest to the terminal box and accommodated in the wiring path. Can be. In addition, the base end of the cable can be wired so as to be accommodated in a wiring path formed in the column, and finally connected to an inverter or the like. As described above, the cables are appropriately routed in the wiring paths formed in the columns and the roof frame, so that the cables are not exposed to the attic for a long distance and do not hang down.

In this case, the solar cell module is formed of a flat plate having a plurality of solar cells laid on a glass substrate, and the roof frame sandwiches the edge of the solar cell module to make it watertight. It is preferred to have a supporting rafter member.

According to this configuration, the solar cell module can be assembled in a watertight manner in a manner similar to the case where a panel type roofing material is attached to a rafter member, and an existing roof frame component is used. The solar cell module can be easily assembled. Conversely, a panel type roofing material can be incorporated as a dummy module of the solar cell module. In addition, the rafter members are integrated,
Regardless of the body, it is composed of rafters and a roofing material retainer, and has a function of keeping the roofing material watertight.

[0009] In these cases, the roof frame forming material constituting the roof frame includes at least a beam and a rafter member among the beam, the girder, the purlin and the rafter member. And a component groove formed on the side of the component main body and having an open upper end, and the wiring path is preferably provided in the component groove.

According to this configuration, when the cable is wired, the cable is accommodated in the component groove formed on the side of the component main body of the roof frame component.
Since the upper end of the component groove is open, the cable can be easily taken in and out of the component groove from this open portion. For this reason, the new wiring can be easily maintained from the beginning. Further, by housing the cable in the component material groove, the cable can be concealed so as not to be seen from the outside and to protect it.

In these cases, it is preferable that the component groove also serves as a gutter for collecting water leakage from the roofing material.

[0012] According to this configuration, it is not necessary to form a dedicated housing for the cable in each of the roof frame members such as the purlin and the beams, and it is possible to suppress an increase in cost. It is more preferable that the inside of the component material groove is divided into two parts by a partition plate, and the gutter part and the cable accommodation part are separately provided.

In these cases, it is preferable that the column has a hollow portion, and the wiring route of the column is provided inside the hollow portion.

According to this structure, the hollow portion of the column is used as a wiring path, so that the hollow portion can be effectively used and the cable can be appropriately concealed.

[0015]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of an assembled building according to an embodiment of the present invention applied to a carport. This carport is of a type in which a roof portion is supported by a cantilever by a column, and FIG. 1 is a perspective view of the carport seen from obliquely below. As shown in FIG. 1, the carport 1 includes a roof portion 2 having a single flow in the front-rear direction,
It consists of three pillars 3 that support the roof 2,
The roof portion 2 includes a roof frame 4 and a plurality of roofing materials 5 supported by the roof frame 4. In this case, each roofing material 5 is constituted by a solar cell module,
A cable 6 extending from the solar cell module 5 is guided to an inverter 7 or a house through a wiring path A provided on the roof frame 4 and a wiring path A provided on the support 3 to be described later. In addition, the column 3 is provided with a downspout 8 for guiding rainwater on the roof 2 to the ground.

The roof frame 4 comprises three beams 11 extending forward from the upper end of each column 3, three cross members 12, a front frame 13 and a rear frame 14 laid in parallel with the three beams 11. , Beam 11
And a pair of side frames 15 at the outer end of the roof portion 2 laid in parallel with the roof member 2 and a roofing material retainer 16 arranged in a lattice on the upper surface of these constituent members. The beams 11 and the side frames 15 have a function of rafters that directly support the roofing material 5, and have a plurality of rectangular shapes constituted by the beams 11, the cross members 12, the front frames 13, the rear frames 14, and the side frames 15. In the space, a roofing material (solar cell module) 5 is placed so as to close the space, and in this state, the roofing material 5 is
, So that four rounds are pressed, so that it is kept watertight. The rear frame 14 has a horizontal gutter connected to the vertical gutter 8 (not shown).

As shown in FIGS. 2 and 3, the beam 11
A hollow beam main body 21, a screwing portion 22 formed at the center of the upper surface of the beam main body 21 for holding a roofing material, and a screwing portion 22
Are formed integrally with a pair of seal mounting portions 23 formed on the upper surface of the beam main body 21 with the pair of beam groove portions 24 formed protruding on the side surface of the beam main body 21. A lower seal member 25 is mounted on each seal mounting portion 23, and a roofing material (solar cell module) 5 is placed on the upper surface of the lower seal member 25. Each of the beam grooves 24 has the above-described wiring path A whose upper end is opened between the side surface of the beam main body 21 and the cable 6 of the solar cell module 5 wired to this wiring path A. Each beam groove 24 also serves as a gutter for collecting water leakage from the roofing material 5. In addition,
Both side frames 15 provided in parallel with the beam 11 also have the same basic form as the beam 11 (not shown) in order to keep the roofing material 5 watertight.

The cross member 12 has the functions of a rafter and a purlin, and has a hollow cross member main body 27, a screw receiving portion 28 formed on the upper surface of the cross member main body 27 for the roofing material presser 16, and a screw receiving portion. A pair of seal mounting portions 29 formed on the upper surface of the horizontal member main body 27 with the portion 28 interposed therebetween and a pair of gutter portions 30 formed on the side surface of the horizontal member main body 27 are integrally formed. The gutter portion 30 is connected to the beam groove portion 24. A lower seal member 25 is mounted on each seal mounting portion 29, and a roofing material (solar cell module) 5 is placed on the upper surface of the lower seal member 25. In addition, horizontal material 1
The front frame 13 and the rear frame 14 provided in parallel with 2 also have the same basic form as the cross member 12 in order to keep the roofing material 5 watertight (not shown).

As shown in FIG.
Is integrally formed with a presser main body 32 having a pair of fin pieces on the lower surface, and a pair of seal mounting portions 33 formed on the lower surface of the presser main body 32. Each seal mounting portion 33 has an upper seal member 3 corresponding to the lower seal member 25 described above.
4 is attached. In this case, for example, for the beam 11, the fin pieces of the roof
2 (positioned), and screws are screwed in from the upper side, whereby the edge of the roofing material (solar cell module) 5 is sandwiched between the upper seal member 34 and the lower seal member 25, The roofing material 5 is kept watertight.

Next, the solar cell module as the roofing material 5 will be described in detail with reference to FIG. As shown in the figure, the solar cell module 5 includes a rectangular glass substrate 41 made of tempered glass, and a large number of solar cells 42 laid on the glass substrate 41 from the back side in a matrix.
And a back cover 43 for protecting the solar cell 42. That is, the solar cell module 5 of the present embodiment has a flat plate shape with no frame material on all four sides. The solar cells 42 are connected by interconnectors (not shown), and their output terminals are connected to a pair of plus and minus cables 6 via a terminal box 44 projecting from the back side. A connector 45 is connected to the end of each cable 6.
5, all the solar cell modules 5 are connected in series.

As described above, the wiring path A of the cable 6
Are formed inside a beam groove 24 formed in the beam 11. On the other hand, although not particularly shown in cross section, the column 3 has a rectangular hollow cross section, and the wiring path A of the column 3 is formed in the hollow portion 3a. Therefore, the cable 6 of the solar cell module 5, which is entirely connected in series via the connector 45, is wired from the beam groove 24 of the beam 11 to the hollow portion 3 a of the column 3, and finally exposed from the lower portion of the column 3. Connected to the inverter 7 (see FIG. 1). Alternatively, it is led from the lower part of the column 3 to the house through the underground (wiring tube).

In such a configuration, since the cable 6 of the solar cell module 5 is concealed by the beam 11 constituting the roof frame 4 and the support column 3 supporting the same, the cable 6 is not likely to be damaged, and The design of the carport 1 is not impaired. Further, since a solar cell module 5 having a frame shape without a frame is used, the same mounting form as that of an acrylic panel or the like can be adopted.
For this reason, it is not necessary to manufacture the framing material constituting the roof frame 4 exclusively for the solar cell module 5, and the solar cell module can be easily incorporated as the roofing material 5 by the same construction method as in the related art.

Next, referring to FIG. 5, FIG. 6 and FIG.
A second embodiment will be described. The roof frame 4 of the roof portion 2 in the carport 1 includes three beams 51 extending forward from the upper end of each column 3, three purlins 52 erected in parallel with the three beams 51, and a front frame 53. And rear frame 54, beam 5
1 includes three rafters 55 laid in parallel to the same position as 1, a pair of side frames 56 positioned at the outer end of the roof 2, and a roofing material presser 57 arranged in a grid on the upper surface of these components. Have been. The purlin 52, the front frame 53, and the rear frame 54 have a rafter function of directly supporting the roofing material 5, and the rafter 55, the purlin 52, the front frame 53, the rear frame 54, and the side frame 56.
, A roofing material (solar cell module) 5 is placed on each of the plurality of rectangular spaces constituted by the roofing material, and in this state, the roofing material 5 is
7, the outer periphery is pressed water-tightly.

The beam 51 is formed integrally with a rectangular hollow beam main body 61 and a pair of beam groove portions 62 projecting from side surfaces of the beam main body 61. Further, each beam groove 62 is provided with a partition plate 6.
3 divides the inner gutter part 64 and the outer cable housing part 65 into two parts.
One wiring path A is configured. That is, the cable housing 65 has an open upper end, and the cable 6 of the solar cell module 5 is routed inside.

The rafter 55 is formed integrally with a hollow rafter main body 67 and a pair of gutters 68 projecting from side surfaces of the rafter main body 67. Although not shown in the drawing, a screw receiving portion for the roofing material presser 57 is formed in the center of the upper surface of the rafter main body 67, and a pair of seal mounting portions to which a lower seal member is mounted are formed on both sides thereof. Then, the roofing material (solar cell module) 5 is placed on the upper surface of the rafter main body (lower seal member) 67. In this case, the gutter 68
It communicates with a purlin groove 72 of a purlin 52 to be described later. The both side frames 56 provided in parallel with the rafters 55 have the same basic form as the rafters 55 (not shown) in order to keep the roofing material 5 watertight.

The purlin 52 supports the rafter 55 and its upper surface is disposed flush with the rafter 55. Like the rafter 55, the purlin 52 is formed so as to protrude from a hollow purlin main body 71 and side surfaces of the purlin main body 71. The pair of purlin grooves 72 are integrally formed. Also in this case, although not shown in the drawing, a screw receiving portion for the roofing material presser 57 is formed at the center of the upper surface of the purlin main body 71, and a pair of seal mounting portions to which a lower seal member is mounted are formed on both sides thereof. Have been. Then, a roofing material (solar cell module) 5 is placed on the upper surface of the main body (lower seal member) 71.

Each purlin groove 72 is, like the beam groove 62,
The partition 73 is divided into an inner gutter 74 and an outer cable accommodating portion 75, and a wiring path A of the purlin 52 is formed inside the cable accommodating portion 75. The cable housing 75 of the purlin 52 and the cable housing 6 of the beam 51
5 communicates at the intersection. Also, purlin 52
The gutter portion 74 communicates with the gutter portion 64 of the beam 51. Note that a front frame 53 and a rear frame 54 provided in parallel with the purlin 52.
Also has the same basic form as the purlin 52 (not shown) to keep the roofing material 5 watertight.

The roofing material presser 57 is formed integrally with a presser main body 77 and a pair of seal mounting portions 78 formed on the lower surface of the presser main body 77, similarly to the roofing material presser 16 of the first embodiment. I have. An upper seal member 79 corresponding to the lower seal member is mounted on each seal mounting portion 78. In this case, for example, with respect to the rafter 55, the fin piece of the roofing material presser 57 is applied (positioned) to the screw receiving portion 69 of the rafter 55 and a screw is screwed from the upper side, so that the upper seal member is formed. The edge of the roofing material (solar cell module) 5 is sandwiched between 79 and the lower seal member, and the roofing material 5 is kept watertight.

As described above, the wiring route A of the cable 6
Are formed inside a cable housing portion 65 formed in the beam 51 and inside a cable housing portion 75 formed in the purlin 52. Also in this embodiment, the column 3 has a rectangular hollow cross section, and the wiring path A of the column 3 is formed in the hollow portion 3a. Therefore, the cable 6 of the solar cell module 5 connected in series as a whole is wired from the purlin groove 72 of the purlin 52 to the hollow portion 3 a of the column 3 through the beam groove 62 of the beam 51, and finally to the column 3 of the column 3. It is exposed from the lower part and connected to the inverter 7 (see FIG. 4). Or, it is led to the house from under the pillar through the underground (wiring tube).

In such a configuration, the cable 6 of the solar cell module 5 is appropriately concealed by the purlin 52 and the beam 51 constituting the roof frame 4 and the support 3, so that there is no possibility that the cable 6 is damaged. In addition, the design of the carport 1 is not impaired. In addition, since the solar cell module 5 is a panel-shaped one without a frame, it can be mounted in the same manner as an acrylic panel or the like. The solar cell module can be incorporated as the roofing material 5 by the same construction method as in the related art. In addition, since the gutter portions 64 and 74 are separated from the cable housing portions 65 and 75 forming the wiring path A, there is no trouble such as electric leakage due to water leakage.

Needless to say, the present invention can be applied to a terrace roof, a balcony roof, a greenhouse, and the like, in addition to a carport. In addition, the structure of the roof frame and the combination of its constituent members are arbitrary.

[0032]

As described above, according to the prefabricated building of the present invention, the cables of the solar cell modules are routed so as to be accommodated in the wiring route provided in the roof frame. Without being exposed or sagging, the cable 6 can be prevented from being damaged, and the design of the entire assembled building can be prevented from deteriorating. Therefore, the solar cell module can be appropriately incorporated as a roofing material.

[Brief description of the drawings]

FIG. 1 is an overall perspective view of a carport according to a first embodiment of the present invention.

FIG. 2 is a partially enlarged perspective view of a roof portion of the carport of the first embodiment.

FIG. 3 is a partially enlarged sectional view of a roof of the carport of the first embodiment.

FIG. 4 is a structural diagram of a solar cell module.

FIG. 5 is an overall perspective view of a carport according to a second embodiment of the present invention.

FIG. 6 is a partially enlarged perspective view of a roof of a carport according to a second embodiment.

FIG. 7 is a partially enlarged sectional view of a roof of a carport according to a second embodiment.

[Explanation of symbols]

1 carport, 3 pillars, 4 roof frame, 5 roofing material (solar cell module), 6 cables, 11
Beams, 12 cross members, 16 roofing material retainers, 24 beam grooves,
44 Terminal box, 51 beams, 52 purlin, 55 rafters, 57 roofing material holder, 62 beam groove, 65 cable storage, 72 purlin groove, 75 cable storage,
A Wiring path

Claims (5)

[Claims] 1. An assembled building comprising a support, a roof frame supported by the support, and a roofing material supported by the roof frame, wherein the roofing material is configured by a solar cell module. An assembled building, wherein a wiring path for accommodating a cable extending from the solar cell module is provided in the roof frame. 2. The solar cell module is formed of a flat plate having a plurality of solar cells laid on a glass substrate, and the roof frame sandwiches an edge of the solar cell module and The prefabricated building according to claim 1, further comprising a rafter member that supports watertightly. 3. The roof framing member constituting the roof framing includes at least a beam and a rafter member among a beam, a girder, a purlin and a rafter member. And a component groove formed on a side portion of the component main body and having an open upper end, wherein the wiring path is provided in the component groove. Assembled building as described. 4. The prefabricated building according to claim 1, wherein said component material groove also serves as a gutter for collecting water leakage from said roofing material. 5. The prefabricated building according to claim 1, wherein the support has a hollow portion, and a wiring route of the support is provided inside the hollow portion.