JP6364673B2 - Corrugated fixing bracket and roof mounting structure - Google Patents

Description

The present invention relates to a corrugated sheet fixing bracket for fixing a corrugated sheet to a field plate, and a roof mounting structure using the corrugated sheet fixing bracket.
More specifically, a corrugated plate fixing bracket for connecting and fixing corrugated plates in which valley portions and peak portions are alternately formed in the width direction (shift direction), and the corrugated plate fixing bracket are used. It relates to a roof mounting structure.

  When attaching a solar cell module to a corrugated roof (hereinafter also referred to as a corrugated sheet), for example, Japanese Unexamined Patent Application Publication No. 2012-149441 (Patent Document 1) proposes a solar panel mounting base for a slate roof. Has been.

In the invention described in Patent Document 1, a base support bracket is hung between two peaks of a slate roof that is corrugated at a mountain and a valley, and is fixed to the slate roof with bolts. After arranging the solar panel base made of C-shaped steel in the vertical direction, the solar panel base is fixed at the valley portion of the slate roof,
Next, horizontal rails are mounted on the solar panel base at predetermined intervals, and a grid is formed by the solar panel base and the horizontal rail, and the solar panel can be fitted into the grid. It is.

  Furthermore, Patent Documents 2 to 5 disclose examples of other methods for attaching solar cell modules.

In JP 2011-106121 A (Patent Document 2),
A structure for mounting a functional panel on a roof in which a plurality of support bars are installed on the roof with a predetermined interval, and the frames on both ends of the function panel are installed across the adjacent support bars.
L-shaped locking portions each having an L-shape upwardly viewed from the side are projected from the outer end surfaces of the frames at both ends of the functional panel,
A mounting bracket is provided to attach the frame of the functional panel to the support bar.
While fixing the center side of the fixing bracket to the support bar with a fixture,
Provided on one end side of the fixing bracket is a downward pressing portion for restricting the upward movement of the L-shaped locking portion on the one end portion side of the functional panel placed on the upper surface on one side of the support bar,
On the other end of the fixing bracket, an upper horizontal piece that is spaced upward from the upper surface of the other side of the support bar is provided,
A functional panel to the roof, characterized in that a storage recess for storing an L-shaped locking portion on the other end side of the functional panel is formed between the upper horizontal piece and the upper surface of the other side of the support bar. A mounting structure has been proposed.

  As a result, the frame at both ends of the functional panel can be firmly attached to the support bar by the combination of the insertion storage in the storage recess and the holding by the fixing bracket. It is said that the work of attaching the functional panel is possible without riding on (paragraph 0010).

In Japanese Patent No. 4380543 (Patent Document 3),
A first protruding piece protruding in the ridge direction and a second protruding piece protruding in the eave direction are integrally provided on the upper surface side of the eaves side edge of the base plate,
The first protruding pieces and the second protruding pieces are alternately provided along the eaves side edge of the base plate,
A front frame and a rear frame are provided at the eaves side edge and the ridge side edge of the function panel, respectively.
A front locking recess that opens on the eave side is formed in the front frame, and a rear locking recess that opens on the ridge side is formed in the rear frame, respectively.
The base plate is fixed to the roof surface, and the front locking recess of the front frame of the functional panel is inserted and locked to the first projecting piece of the base plate, and the functional panel is arranged on the base plate. ,
The eaves side end of another base plate is overlaid on the ridge side end of this base plate to fix the other base plate to the roof surface, and the second protruding piece of this other base plate has the above function. There has been proposed a functional panel mounting structure characterized by being inserted and locked into a rear locking recess in the rear frame of the panel.

  The mounting structure is configured such that the front panel 5 and the rear frame 6 of the functional panel 4 are engaged with the first projecting piece 1 and the second projecting piece 2 that are integrally provided on the base plate 1, so It is said that the functional panel 4 can be mounted on the base plate 1 without requiring a separate member for fixing 4 (paragraph 0009).

In JP-A-2006-63688 (Patent Document 4),
It is a functional panel installation roof that is formed by placing a functional panel on a roof base and attaching it, and by forming a roofing material on the roof base around the functional panel,
A fixture that supports and attaches the functional panel is mounted and fixed on a roof base with a base plate provided on the upper surface,
The upper surface of both side edges spans between the lower surface of the side end portion of the base plate on the side of the base plate and the lower surface of the side end portion of the base plate side of the roofing material disposed adjacent to the base side of the base plate. There has been proposed a water treatment structure for a functional panel-installed roof which is provided with a side draining plate which is folded back to form a draining piece.

In this water treatment structure, draining between the base plate 5 and the roof material 3 adjacent to the wife side can be performed by providing a side draining plate 7 between the lower surfaces of both.
In addition, draining between the base plate 5 and the roof material 3 adjacent to the ridge side is performed by overlapping the eaves side end portion of the upper draining plate 8 on the ridge side end portion of the base plate 5 and removing the roof material 3 from the upper drain side. It can be performed by superimposing on the plate 8 (paragraph 0010).
Furthermore, when arranging a plurality of functional panels 2 side by side, it is possible to ensure waterproofness between adjacent functional panels 2 with a simple structure in which the ends of the base plate 5 for attaching the functional panels 2 are overlapped. (Paragraph 0015).

In Japanese Patent No. 3829799 (Patent Document 5),
A metal corrugated base plate with alternating peaks and valleys in the left-right direction is placed on the roof tile,
Place the metal fixed frame on the top of the base plate so as to lie in the left-right direction of the base plate, with the longitudinal direction facing the direction perpendicular to the longitudinal direction of the peaks and valleys,
Fixing fixtures such as screws and nails from the fixed frame to the base of the roof via the peak of the base plate and roof tiles, fixing the fixed frame and the base plate,
Place roof functional panels such as solar panels, solar heat collection panels, greening panels on the base plate via the fixed frame,
There has been proposed a roof functional panel mounting structure in which the peripheral edge of the roof functional panel is fixed by mounting brackets fixed to the base plate.

In this attachment structure, a draining plate 7 is used between the base plate 1 and the roof tile 6 on the ridge side of the base plate 1 (paragraph 0019).
In addition, this mounting structure has a plurality of corrugated base plates arranged on the left and right, and the corrugated shapes of the left and right base plates are overlapped and connected between the left and right base plates, so that they are adjacent to each other on the left and right. It is said that it can be connected in a waterproof manner by overlapping the left and right ends of the base plate (paragraph 0031).

JP 2012-149441 A (Claims, FIG. 1) Japanese Patent Laying-Open No. 2011-106121 (Claims, FIG. 1) Japanese Patent No. 4380543 (Claims, FIG. 1) JP 2006-63688 A (Claims, FIG. 1) Japanese Patent No. 3829799 (Claims, FIGS. 4 and 7)

Conventionally, when laying the slate corrugated plates, the slate corrugated plates adjacent to each other on the left and right are overlapped and connected to each other.
Therefore, in the laying of the slate corrugated sheet, the width of the corrugated sheet is determined in units of pitch, and if the width does not match the corrugated sheet laying, it is greatly overlapped. was there.

Even in the mounting structures disclosed in Patent Documents 4 and 5, the base plates adjacent to each other on the left and right are connected to each other so that the width of the corrugated plate, the pitch of the peaks, and the width of the functional panel must be matched. there were.
However, since the functional panels have various widths, it has been difficult to produce corrugated sheets that match each of them.

  Further, there is a need for a slate corrugated plate fixing bracket that has a simpler structure and can be firmly attached to a functional panel than the fixing brackets disclosed in Patent Documents 2 and 3.

In view of the present situation, the present invention is intended to provide a slate corrugated plate fixing bracket that makes it possible to lay a slate corrugated plate easily and accurately at a predetermined position.
Furthermore, a roof mounting structure having such a slate corrugated plate fixing bracket and having a functional panel fixing bracket that makes it possible to easily and firmly attach a functional panel such as a solar cell module to a slate roofing material is provided. It is something to be done.

That is, the invention according to claim 1 according to this invention is
A fixing bracket for connecting and fixing corrugated plates in which valleys and peaks are alternately formed in the width direction,
The fixing bracket is
An underlap portion having an upper open trapezoidal shape that comes into contact with the top of at least one trough at the end of the beam direction of the corrugated plate laid at one end thereof,
For the corrugated plate, the other end is provided with an overlapped portion having a lower open trapezoidal shape that abuts the top of at least one peak of another corrugated plate adjacent to the corrugated plate in the left-right direction. It is a fixture.

The invention according to claim 2 of the present invention is
The corrugated sheet fixture according to claim 1,
The underlap portion is
The terminal end stands up to form a rising portion at the top of the peak portion of the laid corrugated sheet.

The invention according to claim 3 of the present invention is
The corrugated sheet metal fitting according to claim 1 or 2,
The overlap portion is
The end is in close contact with the surface of the crest of the corrugated sheet.

The invention according to claim 4 of the present invention is
A plurality of corrugated plates in which valleys and peaks are alternately formed in the width direction;
A roof mounting structure comprising the corrugated sheet metal fitting according to any one of claims 1 to 3.

The invention according to claim 5 of the present invention is
The roof mounting structure according to claim 4,
In the corrugated plate,
A fixing bracket having a substantially L-shaped cross section for fixing the eaves side edge of the eaves side lowermost functional panel, or the ridge side edge of the uppermost function panel of the ridge side,
A fixing bracket for fixing a functional panel other than these functional panels, having a substantially T-shaped cross section for fixing an eaves side edge of one functional panel and both edges of a ridge side edge of another functional panel A fixing metal fitting is provided.

The invention according to claim 6 of the present invention is
In the roof mounting structure according to claim 4 or 5,
The roof is
The eaves end is provided with a snow stopper made of a rail material having a substantially U-shaped cross section opened in the ridge direction.

  The corrugated metal fitting according to the present invention includes an underlap portion having an upper open trapezoidal shape that abuts the top of at least one trough at the end of one corrugated plate in the spar direction, And an overlapping portion having a trapezoidal shape with a lower open portion that abuts against the top of at least one peak portion of another corrugated plate adjacent thereto.

Therefore, according to the corrugated sheet fixing bracket of the present invention and the roof mounting structure including the corrugated sheet fixing apparatus, a plurality of corrugated sheets can be easily and accurately laid at predetermined positions on the roof.
In particular, since the end of the underlap portion rises at the top of the peak portion of the one corrugated plate to form a rising portion, rainwater or the like can enter the gap between the corrugated plates adjacent to the left and right. It becomes possible to prevent.

In the mounting structure according to the present invention, the eaves side edge and the ridge side edge of the functional panel of the ridge side uppermost functional panel of the functional panel such as the solar cell module at the eave side lowermost are fixed by a fixing bracket having a substantially L-shaped cross section. For other than the functional panel, the eaves side edge of one functional panel and the both edges of the ridge side edge of the other functional panel are fixed by a fixing bracket having a substantially T-shaped cross section. Is preferred.
Thereby, in the attachment structure concerning this invention, functional panels, such as a solar cell module, can be fixed to a corrugated sheet (roof material) easily and firmly.

Furthermore, in the mounting structure according to the present invention, it is preferable that a rail material having a substantially U-shaped cross section opened in the ridge direction is provided at the eaves of the roof to provide a snow stop.
As a result, it is possible to prevent snow from falling from a roof having a functional panel such as a solar cell module.

FIG. 1 is a perspective view showing an embodiment of a corrugated sheet fixture according to the present invention. FIG. 2 shows one embodiment of the corrugated sheet metal fitting according to the present invention. FIG. 2 is a schematic explanatory view showing a state in which two corrugated plates are connected and fixed using the corrugated sheet metal fitting of FIG. is there. FIG. 3 shows an embodiment of the present invention, and is a perspective view showing a state in which two corrugated plates are connected and fixed using the corrugated fixing bracket of FIG. FIG. 4 is a perspective view showing a state where the connected and fixed corrugated plates of FIG. FIG. 5 shows an embodiment of the present invention, and is a perspective view showing a state in which a functional panel mounting bracket is attached to a corrugated plate. FIG. 6 shows an embodiment of the present invention, and is a side cross-sectional view showing a state in which a functional panel is attached to a corrugated plate using a functional panel mounting bracket. FIG. 7 shows an embodiment of the present invention, and is a side cross-sectional view showing a state in which the functional panel is attached to the corrugated plate using the functional panel mounting bracket. FIG. 8 is a perspective view showing another embodiment of the corrugated sheet fixture according to the present invention. FIG. 9 is a perspective view showing another embodiment of the corrugated sheet fixture according to the present invention.

Hereinafter, an example of the implementation of the corrugated metal fitting according to the present invention will be described in detail with reference to the accompanying drawings.
In addition, this invention is not limited only to the Example demonstrated below, In the range which does not change the summary of invention, it can change variously.

The corrugated sheet ST to which the corrugated sheet fixing bracket 1 of the present invention is attached has a valley V and a peak T alternately arranged as shown in FIG.
The corrugated plate ST is composed of a natural slate using slate or an artificial cosmetic slate made of asbestos cement, or a galvanium steel plate, a polycarbonate resin, or a vinyl chloride resin.
Further, these corrugated plates include types such as round waves and square waves.

As shown in FIG. 2, corrugated sheet metal fittings 1 of the present invention are connected to corrugated plates ST ₁ , ST ₂ adjacent to the left and right when installing a plurality of them in the direction of the gradient roof. And can be fixed to a frame structure such as a rafter or a purlin.

The corrugated plate fixing bracket 1 has a required width in a girder direction made of a steel material of galvanium steel plate or polycarbonate resin, and has a required depth.
In the following embodiments, the corrugated sheet fixing bracket 1 is assumed to have a short side width of about 200 mm, and a long side length of about 1020 mm, which is equivalent to the long side length of the slate corrugated plate. doing.
The width of the wave plate for fixing tool 1, by changing the width of the feature panel, it is possible to adjust a distance between the ST ₂ and ST _1, can correspond to various functions panel.

As shown in FIG. 1, one end of the slate corrugated plate fixing bracket 1 is in contact with the top of a plurality of troughs V ₁ , V ₁ , V _{1 at} the end of the one corrugated plate ST _{1 in} the digit direction. A plurality of crests T ₂ , T ₂ , T ₂ are formed in a trapezoidal shape with an open top so as to come into contact with each other, and the other ends of the other corrugated plates ST ₂ adjacent to the corrugated plate ST ₁ in the left-right direction. It is formed in a trapezoidal shape that is open at the bottom so as to contact the top.

In other words, this wave plate for fixing tool 1 is made to correspond to the valley portions V and crests T of the wave plate, one end, it can be mounted at least one valley portion V of one corrugated sheet ST ₁ it is formed as underlap portion 2, the other end, and is formed as an overlap portion 4 which can cover at least one mountain portion T of the other corrugated sheet ST _2.

With such a configuration, it is possible to prevent water leakage from overlapping of the corrugated plates in the left-right direction.
Moreover, since the ventilation path formed between a corrugated board and a field board is not blocked, there also exists an effect that ventilation between a corrugated board and a field board can fully be performed.

As shown in FIG. 1, the connecting portions 5 between the underlap portion 2 and the overlap portion 4, one that is inclined in underlap portion 2 side, the surface of the mountain portion T ₂ of the corrugated sheet ST ₂ Close contact with.

Since the above structure, underlap portion 2, while restricting the movement in the lateral direction of the corrugated sheet ST _1, the overlap portions 4, to restrict the movement of the lateral direction of the corrugated sheet ST _2, a plurality of waves It is possible to lay the plate at a predetermined position easily and accurately.

As shown in FIG. 1, the end of the underlap portion 2 rises to form a rising portion 3 at the top position of the peak portion T ₁ of the corrugated plate ST ₁ .
As a result, rainwater or the like falling from the gap is reliably received by the underlap portion 2 to ensure a necessary and sufficient water-stopping effect.

Hereinafter, a connection / fixation example of the corrugated plate ST using the corrugated plate fixing bracket 1 shown in FIG. 1 will be described.
FIG. 3 shows an embodiment of the present invention, and is a perspective view showing a state in which two corrugated plates are connected and fixed using the corrugated metal fitting of FIG. 1, and FIG. FIG. 4 is a perspective view showing a state where the connected and fixed corrugated plates of FIG.

First, as shown in FIGS. 2 and 3, a corrugated sheet ST ₂ by using a mounting screw (not shown), is fixed to the sheathing roof board 12.
Then, to engage the crests T ₂ of the corrugated sheet ST _2, covered with the overlap portion 4 of the corrugated plate for fixing tool 1, the underlap portion 2 of the corrugated plate for fixing tool 1, another wave plate ST ₁ Is placed so that the valley portion V ₁ engages with the underlap portion 2.

In FIGS. 3 and 4, insertion holes for mounting screws 8 are provided at both edges in the longitudinal direction of the corrugated sheet fixture 1 to be attached to the crests of the corrugated sheet ST.
Further, upon attachment to the corrugated sheet ST ₂ of the wave plate for fixing tool 1 can also keep attached together in advance rivets.
Moreover, it can attach to corrugated sheet ST using this insertion hole (not shown).

As shown in FIG. 4, the corrugated plate ST1 connected and fixed using the corrugated plate fixing bracket 1 of FIG. ₁ is laid in an overlapping manner in the vertical direction.
At that time, a gap is easily generated by floating the seams between the corrugated plates in the vertical direction. Therefore, in FIG. 4, the holding metal fitting 6 is bridged between the adjacent corrugated plates via the corrugated metal plate 1.
It is more preferable that the holding metal fitting 6 is attached so as to hold the eaves side on the upper surface of the corrugated plate ST.
Thereby, the fluttering caused by the wind of the corrugated plate can be reduced.
The holding metal fitting 6 is attached by a fixing means 7 such as a screw, for example.

As shown in FIG. 5, a functional panel mounting bracket 9 is disposed on the top surface of the corrugated plate ST, and is fixed by a fixing means (not shown) such as a rivet, for example.
The functional panel mounting bracket 9 is disposed on the upper surface of the corrugated plate ST in the vertical direction and the girder direction with predetermined intervals.
For example, a functional panel such as a solar cell module is disposed on the upper surface of the functional panel mounting bracket 9 to form a solar power generation device.

  In FIG. 5, the functional panel mounting bracket 9 is arranged so that the working width D is ½ of the width of the functional panel 10 and the working length d is equal to the length of the functional panel 10. This space | interval can be changed by selecting the width | variety of the corrugated sheet metal fitting according to the magnitude | size of the function panel 10 selected.

6 and 7 show a state in which the functional panel 10 is attached to the corrugated plate ST using the functional panel mounting bracket 9, and the eaves side edge of the eaves side lowermost functional panel 10 has a substantially L-shaped cross section. It is fixed by a fixed fixture 14.
Although not shown, the ridge side edge of the functional panel 10 at the top of the ridge side can also be fixed by the fixing bracket 14 having a substantially L-shaped cross section as described above.

Further, as shown in FIG. 7, for the functional panels other than the functional panel 10, the eaves side edge of one functional panel 10a and the both edges of the ridge side edge of the other functional panel 10b have a cross section of approximately T. It is fixed by a letter-shaped fixing bracket 15.
According to these configurations, the functional panel 10 can be easily and firmly fixed to the corrugated sheet (roof material).

In FIG. 6, a rail member 22 having a substantially U-shaped cross section is disposed at the eaves of the roof on which the corrugated sheet ST is wound, with its opening directed in the ridge direction, and used as a snow stop.
As a result, it is possible to prevent snow falling from the roof including the functional panel 10 such as a solar cell module.
The opening width of the rail member 22 is preferably larger than the height to the upper surface of the functional panel 10.

  Further, since the moisture between the field plate and the corrugated plate can be discharged by the air passage 11, the solar cell module or the like prevents the field plate under the corrugated plate that is shaded throughout the year from becoming a high moisture content. It can prevent the decay of the main plate.

  In the embodiment of the present invention, the corrugated sheet fixing bracket 1 has been described with reference to FIG. 1, but it may have other configurations.

For example, as shown in FIG. 8, the same as the corrugated plate (corrugated plate portion 23) is connected to the overlap portion 4 of the corrugated plate fixing bracket 1 shown in FIG. It is also possible to apply a structure in which the overlapping portion 4 of the corrugated sheet fixing bracket 1 is replaced with the same corrugated sheet (corrugated sheet portion 23).

  The corrugated sheet fixing bracket and the roof mounting structure including the corrugated sheet fixing structure according to the present invention are configured such that a plurality of corrugated sheets are easily and accurately laid at predetermined positions on the roof, and rainwater in a gap between adjacent corrugated sheets on the left and right Therefore, it can be effectively used on many roofs.

Furthermore, according to the roof mounting structure according to the present invention, the solar cell module can be easily and easily mounted on many roofs, so that the obtained power can be effectively used as private power consumption. Become.

DESCRIPTION OF SYMBOLS 1 Corrugated metal fitting 2 Underlap part 3 Standing part 4 Overlap part 5 Connection part 6 Holding metal part 7 Fixing means 8 Fixing screw 9 Functional panel attachment metal 10, 10a, 10b Functional panel 11 Ventilation path 12 Field plate 13 Rafter 14 Fixing bracket with a substantially L-shaped cross section 15 Fixing bracket with a substantially T-shaped cross section 16 Windbreak plate 17 Makeup windbreak 18 Drainage 19 Screw 20 Bolt 21 Washer 22 Rail material (snow stopper)
23 Corrugated part ST Corrugated sheet (roofing material)
_T, T _1, T ₂ crest _V, V _1, V ₂ valley D length work working width d

Claims (6)

A fixing bracket for connecting and fixing corrugated plates in which valleys and peaks are alternately formed in the width direction,
The fixing bracket is
An underlap portion having an upper open trapezoidal shape that comes into contact with the top of at least one trough at the end of the beam direction of the corrugated plate laid at one end thereof,
For the corrugated plate, the other end is provided with an overlapped portion having a lower open trapezoidal shape that abuts the top of at least one peak of another corrugated plate adjacent to the corrugated plate in the left-right direction. securing bracket. The underlap portion is
2. The corrugated sheet metal fitting according to claim 1, wherein a terminal end of the corrugated sheet is erected to form a rising portion at a top portion of the corrugated sheet. The overlap portion is
3. The corrugated sheet fixing bracket according to claim 1, wherein a terminal end of the corrugated sheet is in close contact with the surface of the crest of the corrugated sheet. A plurality of corrugated plates in which valleys and peaks are alternately formed in the width direction;
A roof mounting structure comprising the corrugated metal fitting according to any one of claims 1 to 3. In the corrugated plate,
A fixing bracket having a substantially L-shaped cross section for fixing the eaves side edge of the eaves side lowermost functional panel, or the ridge side edge of the uppermost function panel of the ridge side,
A fixing bracket for fixing a functional panel other than these functional panels, having a substantially T-shaped cross section for fixing an eaves side edge of one functional panel and both edges of a ridge side edge of another functional panel The roof mounting structure according to claim 4, wherein a fixing bracket is provided. The roof is
The roof mounting structure according to claim 4 or 5, wherein a snow stopper made of a rail material having a substantially U-shaped cross section that opens in the ridge direction is provided at the eaves.