JP4746650B2 - Mounting bracket for installation on roof and mounting structure for installation on roof - Google Patents

Description

  The present invention relates to an attachment fitting for attaching an installation object on a roof such as a solar cell panel or a greening panel to a vertical roof, and an attachment structure of the installation object on the roof using the fitting.

In recent years, in consideration of environmental problems, the installation of on-roof installations such as solar cell panels and greening panels on the roof is also increasing. In that case, it is desired that the installation object on the roof is stably attached to the roofing material.
There is a technique described in Japanese Patent No. 3332327 as a mounting bracket for an installation object on the roof and an installation structure of the installation object on the vertical roof (see FIGS. 7 (a) and 7 (a)).
As shown in FIG. 7A, the mounting bracket A shown here is composed of a pair of sandwiching bodies a and a and a mounting body b, and locking pieces b3 formed on the left and right of the mounting body b. A hook piece a1 formed on the sandwiching body a · a is engaged in the hole b3, whereby the sandwiching body a · a is swingably held on the mounting body b.

  Further, JP 2006-322305 A (see FIG. 8) states that “on a base body characterized by having a displacement support mechanism that displaces the receiving side within a predetermined range and supports the upper structure in the displaced state. A structure support apparatus "is disclosed.

The conventional technology described so far discloses a technology for stably mounting an installation on a roof in response to displacement such as a dimensional error or a construction error, but has the following problems.
First, in the mounting bracket A of Japanese Patent No. 3332327, when the clamping body a · a is fastened to the roofing material 9 by the fastening means t, and the installation object 7 on the roof is placed on the mounting body b, the mounting body b is , It moves together with the sandwiching body a. That is, when the roofing material 9 is in a poorly molded state or construction state, and the sandwiched body a · a is tilted and attached, the placing body b is also tilted in the same manner as the sandwiched body a · a. Couldn't keep up.
As a result, when the on-roof installation 7 is placed on a plurality of mounting brackets A adjacent in the carry direction, the on-roof installation 7 can be stably placed on the placement part b1. It was not possible, and an unreasonable stress was applied when trying to fix the on-roof installation 7 with the fixing means B, and stable installation could not be performed. When the mounting bracket A is tilted and attached, there is a possibility that the bolt breaks in an attempt to flatten and fix the on-roof installation 7.

As shown in FIG. 8, the mounting bracket A of Japanese Patent Laid-Open No. 2006-322305 is characterized in that the universal column body c has a displacement support mechanism. This application is aimed at dealing with displacement in the eaves direction. Although it is not disclosed to deal with displacement in the carry direction due to poor molding or construction failure of the roofing material 9, this technique will be compared as one corresponding to displacement in the carry direction.
The mounting bracket A has a certain height so that it can be displaced in the height direction, and there are many rotation shafts for displacing the free strut body c. It was stable and I was worried about strength.
Moreover, in order to adjust the displacement, it is necessary to adjust several rotation shafts of the free column body c, and since it extends to all the mounting brackets A, it takes time and labor to attach the roof installation object 7. It was.
Further, when the installation object 7 on the roof is placed on the mounting body b, the inclination of the installation object 7 on the roof can be made to follow via the rotation shaft. It cannot be locked. For this reason, the receiving part metal fitting c2 is rotated more than necessary with respect to the connecting plate c1, and the horizontal state cannot be maintained and cannot be stably placed. Furthermore, although it can be followed, the operation of tightening the bolt with the nut to prevent the movement of the rotating shaft between the connecting plate c1 and the receiving portion metal fitting c2 is very time-consuming. It was.

As described above, both of the above two conventional techniques are simple operations when the mounting fixture for installation on the roof is tilted and attached due to poor molding or construction failure of the vertical roof, It was not possible to keep the installation on the roof in a flat state while maintaining the strength.
The present application is intended to solve such a problem, and even when a mounting fixture is tilted and attached to a roof of a roof such as a solar panel on a vertical roof such as a folded plate, An object of the present invention is to provide a mounting bracket and a mounting structure which can keep an installation object in a stable state and which is simple and sufficient in strength.
Japanese Patent No. 3332327 JP 2006-322305 A

The mounting fixture for on-roof installations according to claim 1 is a mounting fixture for on-roof installations attached to a vertical roof, and is disposed on a ridge formed on the roof material and sandwiches the ridge A sandwiching body having left and right arms formed with a portion, a clamping means for bringing the sandwiching parts of the sandwiching body close to each other, a rotating shaft that pivotally supports the sandwiching parts so as to be openable and closable, and a pivot shaft supported by the pivoting shaft. And a mounting body on which a mounting portion for mounting the installation object on the roof is formed.
The said clamping body has the overlapping surface formed by bending inward from the eaves ridge side upper side of the side surface of the said left-right arm.
The said mounting body has the connection surface folded down from the eaves ridge side of the said mounting part.
The mounting body is connected to the holding body by the rotating shaft, and an overlapping portion between the overlapping surfaces of the holding body and the connecting surface of the mounting body is pivotally supported on the rotating shaft. ing.
Since the mounting body is pivotally supported by the rotation shaft, the mounting body can adopt a posture having a rotation direction element around the rotation shaft with respect to the sandwiching body.

In addition to claim 1, the mounting bracket for an installation on a roof according to claim 2 is provided around the rotation axis by pivotally supporting the mounting body in a loose state with respect to the rotation axis. It is characterized by the above-mentioned mounting body which can employ | adopt direction elements other than a rotation direction element.
In addition to a posture composed of rotational direction elements around the rotation axis, a posture having direction elements other than the rotation direction elements around the rotation axis can be adopted.

The mounting structure for an on-roof installation described in claim 3 is a mounting fixture for an on-roof installation that is attached to a vertical thatched roof, and is disposed on a ridge formed on the roof material and sandwiches the ridge A sandwiching body having left and right arms formed with a portion, a clamping means for bringing the sandwiching parts of the sandwiching body close to each other, a rotating shaft that pivotally supports the sandwiching parts so as to be openable and closable, and a pivoting shaft supported by the pivoting shaft. , Ri consists a mounting body for mounting unit for mounting the roof-installed object is formed, the clamping bearing member overlaps formed by bending inward from the eaves ridge side upper side of said left and right arms The mounting body has a connection surface that is folded from the eaves ridge side of the mounting section, and the mounting body is placed on the holding body by the rotating shaft. Connected to the rotating shaft, the overlapping surfaces of the clamping body and the connecting surface of the mounting body described above Collision overlap portion constitutes a mounting bracket for the roof-installed object that is rotatably supported, arranged clamping body on both sides of the ridge roof member, in close proximity by means tightening the pair of holding portions of the roofing material A mounting bracket is attached to the strip, and an installation object on the roof is attached to the mounting portion.
The mounting structure for an installation object on a roof according to claim 4 is configured such that a direction element other than a rotation direction element around the rotation shaft is supported by pivotally supporting the mounting body in a loose state with respect to the rotation shaft. It is characterized by having made the above-mentioned mounting body which can also be adopted.

According to the mounting bracket and mounting structure for rooftop installation of the present application, even if the bracket mounted on the vertical roof is tilted, the rooftop installation mounted on it is in a stable state by a simple mechanism. It can be held and strength is also obtained.
The mounting fixture for an installation on a roof according to claim 1 is a posture in which the mounting body has a rotation direction element around the rotation axis with respect to the sandwiching body by the mounting body being pivotally supported by the rotation shaft. Therefore, when the mounting bracket is attached with the left and right sandwiching bodies in close proximity by the tightening means, and the installation object on the roof is placed on the mounting part, the inclination can be reduced by simply placing the installation object on the roof. It can be modified to maintain a flat state.
Further, the mounting bracket is tightened by the proximity of the sandwiching body, and the installation object on the roof is stably attached to the placing portion, so that sufficient strength can be obtained.
Since the mounting body is pivotally supported by the holding body by the rotation shaft, a posture capable of tilting in the left-right direction can be obtained with a simple mechanism.
And since the clamping body and the mounting body are connected by the rotation shaft, it is easy to combine with the protrusions of the roof material by opening the clamping parts of the left and right arms, and easy to attach by closing. In addition to being able to be pivotally supported so that it can be freely opened and closed, the function of allowing the mounting body to adopt a posture having a rotational direction element around the rotational axis with respect to the sandwiching body is obtained at the same time.

  The mounting bracket for an installation on a roof according to claim 2 can adopt a posture having a direction element other than the rotation direction element around the rotation axis in addition to the posture made of the rotation direction element around the rotation axis. Therefore, in addition to the function of the first aspect, the mounting body can change the posture in a direction other than the rotation direction around the rotation axis.

The third aspect relates to a mounting structure for a roof installation using the mounting bracket for a roof installation according to claim 1, and can achieve the same effect as that of the first aspect.
A fourth aspect of the present invention relates to a mounting structure for an installation on the roof using the mounting bracket for an installation on the roof according to the second aspect, and can provide the same effect as that of the second aspect.

FIG. 1 is a perspective view of a mounting fixture A for a roof installation, FIG. 2 is a sectional view, FIG. 3 is a partially broken front view of the construction state, and FIGS. 4 and 5 are schematic views of the construction state. It shows a state where it is attached at an angle.
As shown in FIGS. 3 and 4, the roofing material 9 is formed by bending a metal plate, is formed long in the eaves direction, and has a ridge on the side edge in a direction perpendicular to the eaves direction. The flanges 93 and 93 are formed. Each of the flange parts 93 and 93 is formed by rising from the peak part 91. In the peak part 91, the side on which the flange part 93 is not formed is folded to be an inclined surface, and the inclined surface is a valley. A roof material 9 is formed continuously to the portion 92.

As shown in FIG. 3, the roof material 9 called a folded plate is usually fixed to a tight frame 6 attached to the beam at a predetermined interval. The roofing material 9 in FIG. 3 is connected by tightening the flanges 93 of the adjacent roofing materials 9 and 9.
However, the vertical roof to which the mounting bracket and the mounting structure of the present application are applied is not limited to the folded plate, and there are various embodiments for the mounting method.

First, an embodiment of the mounting bracket A will be described with reference to FIG. FIG. 1 is an embodiment of the mounting bracket 1 attached to the roofing material shown in FIG. 3, and this mounting bracket A has a sandwiching body a and a mounting body b penetrated in a direction that is the eaves-ridge direction. The rotary shaft j is connected to be tiltable.
In the sandwiching body a of this embodiment, a left arm 1 and a right arm 2 having a substantially U-shaped cross section are combined with their respective openings directed inward. The left arm 1 and the right arm 2 include upper surfaces 11 and 21, side surfaces 12 and 22 in which one side edge of the upper surfaces 11 and 21 is folded, and sandwiching portions 13 and 22 bent inward from the side surfaces 12 and 22. 23.
In the present embodiment, the bolts t1 and nuts t2 are used as the fastening means t for bringing the clamping parts 13 and 23 close to the clamped connection location, so that the side faces 12 and 22 have holes for penetrating the bolts. It has been opened.
In addition, the eaves side of the side surfaces 12 and 22 are folded upward in a substantially right angle toward the inner side to form overlapping surfaces 14 and 24. The ridge side overlap surface 14 of the left arm 1 and the ridge side overlap surface 24 of the right arm 2 are overlapped, and the eave side overlap surface 14 of the left arm 1 and the eave side overlap surface of the right arm 2 are overlapped. 24 are superimposed. The overlapping portions of the overlapping surfaces 14 and 24 are higher than the bolt t1 that is the fastening means t.

The mounting body b of the present embodiment has a mounting portion b1 on which a roof installation object 7 such as a solar battery panel can be mounted. And in the case of a present Example, the eaves ridge side of the mounting part b1 is folded at substantially right angle, and the connection surface b2 for connecting with the overlapping surfaces 14 and 24 of the clamping body a is formed. Moreover, the fixing means B for attaching the installation object 7 on the roof is attached to the mounting part b1.
Such a clamping body a and the mounting body b are connected as follows. First, the upper surfaces 11 and 21 of the sandwiching body a are combined with a space therebetween, and the mounting body b is put on the upper surface 11 and 21 and combined.

At this time, each connection surface b2 * b2 of the mounting body b is located outside the overlapping part of the overlapping surfaces 14 and 24 of the holding body a. Furthermore, the bolt penetrates the overlapping part of the overlapping surfaces 14 and 24 of the sandwiching body a and the overlapping part of the connecting surface b2 of the mounting body b, and the bolt penetrates in the eaves ridge direction. As the axis j, the clamping body a and the mounting body b are connected so as to be tiltable. Since there is a gap between the upper surfaces 12 and 22 of the sandwiching body a and the mounting portion b1 of the mounting body b, the mounting body b can be tilted about the rotation axis j.
The rotation axis j may be one at the overlapping portion between the eaves-side overlapping surfaces 14 and 24 and the connection surface b2, and may be one at the overlapping portion between the ridge-side overlapping surfaces 14 and 24 and the connection surface b2.
In addition, the mounting body b and the sandwiching body a are connected to the left and right arms 1 and 2 so as to be tiltable together by the rotation axis j, so that they do not fall apart, and inventory management is easy. In addition, by opening the holding portions 13 and 23, it can be easily combined with the flange portions 93 and 93. That is, the rotation axis j not only enables the mounting body b to tilt, but also serves as an axis for opening and closing the clamping portions 13 and 23. Thereby, not only attachment is easy, but the number of parts can also be reduced.
And when the clamping body a is attached to the flange parts 93 and 93 of the roof material 9 by being brought close to the fastening means t, the mounting body b can be tilted about the rotation axis j. That is, since it can be tilted via the rotation axis j, the left and right sides of the placement portion b1 can be lowered or raised.
Furthermore, for example, the rotation of the rotation axis j is prevented, and the mounting body b can be fixed to the rotation axis j, so that a stronger and more stable attachment can be achieved.

Subsequently, a method of attaching the mounting bracket A will be described with reference to FIG. First, the mounting bracket A is fixed by tightening so that the sandwiching portions 13 and 23 of the sandwiching body a sandwich the flange portions 93 and 93. Next, the installation object 7 on the roof is placed on the placement parts b1 and b1 of the adjacent mounting brackets A and A. Then, for example, the holding metal fitting 8 is fitted, and the on-roof installation object 7 is fixed to the attachment metal A by the fixing means B protruding from the placement portion b1.
At this time, by placing the on-roof installation 7 on the mounting part b1, the center of gravity moves due to the weight, and the mounting body b tilts, so that the mounting parts b1 and b1 adjacent in the left-right direction (shift direction) Tilt. In this state, when the roof installation object 7 having a flat bottom surface is attached to the mounting bracket A, the mounting portion b1 and the bottom surface of the roof installation object 7 are in surface contact and stably attached.

As shown in FIGS. 4 and 5, even if the sandwiching body a is attached with an inclination and the upper surfaces 11 and 21 thereof are inclined, the mounting body b is combined by the rotation axis j and can be tilted. Therefore, even if the installation object on the roof is placed on the placement part b1, the flat and almost horizontal state can be maintained.
In the case of FIG. 4A, the mountain parts 91 and 91 of the roofing material 9 are displaced, and the mounting bracket A is mounted such that the upper surface 21 of the right arm 2 is inclined higher than the upper surface 11 of the left arm 1. In the case of (A), conversely, the upper surface 11 of the left arm 1 is attached with a higher inclination.
In either case, since the mounting body b can tilt through the rotation axis j, the installation object 7 on the roof is placed on the mounting parts b1 and b1 of the mounting brackets A and A that are adjacent to each other in the cross direction. Then, the mounting portions b1 and b1 come into contact with the bottom surface thereof, and the mounting portions b1 and b1 that are adjacent to each other in the carry direction are substantially flush with each other.
Even if the mounting brackets A and A adjacent to each other in the girder direction are inclined in different directions, the mounting body b is not inclined in the same direction as the sandwiching body a. It is stably placed on the placement part b1 on the same surface.
Further, even when the upper surfaces 11 and 21 of the sandwiching body a are formed in a letter C shape as shown in FIG. 5A, or on the contrary, in a reverse letter C shape as shown in FIG. Since b is a separate body from the sandwiching body a and can be tilted via the rotation axis j, similarly, the on-roof installation 7 can be placed stably.
Thus, since the mounting body b is combined with the holding body a so as to be tiltable via the rotation axis j, the on-roof installation object 7 is attached in a flat state. For this reason, the installation object 7 on the roof is tilted and attached, so that excessive stress is not applied, and it is possible to prevent deformation and accumulation of water due to strain.
By simply placing the on-roof installation 7 on the placement portion b, the placement body b is naturally tilted by its weight and can maintain a horizontal state, so that workability is also good.
In the case of the present embodiment, the holding body a and the mounting body b are tiltably connected by the rotation axis j, and the upper surface of the holding body a when the mounting body b is tilted. The lower surface of the mounting portion b <b> 1 comes into contact with 11 and 21. For this reason, the mounting body b can be locked to the sandwiching body a, and the mounting body b does not tilt more than necessary as shown in FIG. 8, and therefore the mounting portion b1 is made flat in a stable state. It can be done easily.

FIGS. 6A, 6A, 6C, and 6E show another embodiment. The connecting surfaces b2 and b2 of the mounting body b of the mounting bracket A shown in FIG. For this reason, in addition to being able to tilt the mounting body b in the left-right direction, the height of the mounting part b1 can be changed.
The mounting bracket A of (a) has the connection surfaces b2 and b2 of the mounting body b of the mounting bracket A of (a) curved outward. For this reason, in addition to being able to tilt the mounting body b in the left-right direction, it can also be tilted to the eaves side or the ridge side, so that only the eaves side or the ridge side of the mounting body b can be raised. it can.
The mounting bracket A in (c) is obtained by making the long holes of the connection surfaces b2 and b2 of the mounting bracket A in (b) in the horizontal direction. For this reason, since the mounting body b can be tilted in the left-right direction and the mounting body b can be turned in the left-right direction, the horizontal angle of the mounting body b can be adjusted.
The connection surfaces b2 and b2 can be curved as shown in (c), or the connection surfaces b2 and b2 as shown in (a) can be slid in the left-right direction so that the position can be adjusted.
Moreover, you may make the hole for penetrating the rotating shaft j formed in connection surface b2 * b2 larger diameter than the rotating shaft j.
As described above, various examples are possible in which the mounting body b is pivotally supported with respect to the rotation axis j. In this way, by placing the mounting body b in a loose state with respect to the rotation axis j, the posture of the mounting body b is also adopted in directions other than the rotational direction element around the rotation axis j. It becomes possible.
Furthermore, the mounting body b of the mounting bracket A shown in FIG. Wiring such as a solar battery panel and an antenna can be accommodated in this recess. It is easy to install because it does not get in the way of installation on the roof. Even when the adjacent solar cell panels are pressed by the pressing metal fittings, the mounting is stable because the mounting portions b1 on both sides of the indentation are fixed and the cable is not hindered.

In addition to the embodiments described so far, the mounting body b is formed so that the ridge side of the mounting portion b1 is raised, and the installation object 7 on the roof is inclined to be placed on the mounting portion b1. You can also. In this case, the mounting parts b1 and b1 of the mounting brackets A and A adjacent to the left and right are not horizontal, but the mounting body b is attached to the holding body a so as to be tiltable, so that the mounting part b1 is mounted. B1 is located on substantially the same plane. Therefore, the on-roof installation 7 placed thereon can also be placed in a flat state on substantially the same surface, and the attached state is stabilized.
Furthermore, the mounting body b is positioned inside the sandwiching body a, and the mounting surface b is slid in the eaves ridge direction by keeping a space between the connection surface b2 and the overlapping surfaces 14 and 24, thereby adjusting the position. You can also Further, in order to adjust the position by sliding the mounting body b in the eaves ridge direction, the length of the mounting body b is increased, and the interval between the connection surfaces b2 and b2 and the overlapping surfaces 14 and 24 is increased. It is possible.
In the present application, it is only necessary that the mounting body b can tilt at least in the left-right direction with respect to the sandwiching body a. The means for allowing the mounting body b to tilt with respect to the sandwiching body a is not limited to the embodiments described so far.

It is explanatory drawing which shows one Example of the attachment metal fitting A which concerns on this application. It is sectional drawing of the attachment metal fitting A of FIG. It is explanatory drawing which shows the construction state of the attachment metal fitting A which concerns on this application. It is the construction state schematic diagram which shows the state in which the attachment metal fitting A is inclined and attached. It is the construction state schematic diagram which shows the state in which the attachment metal fitting A is inclined and attached. It is explanatory drawing which shows another Example. It is explanatory drawing of a prior art. It is explanatory drawing of a prior art.

Explanation of symbols

A mounting bracket a holding body a1 hook piece 1 left arm 11 upper surface 12 side surface 13 holding portion 14 overlapping surface 2 right arm 21 upper surface 22 side surface 23 holding portion 24 overlapping surface b mounting body b1 mounting portion b2 connecting surface b3 locking piece c Free strut body c1 Connecting plate c2 Receiving metal fitting t Tightening means t1 Bolt t2 Nut j Rotating shaft 6 Tight frame 7 Roof installation object 8 Holding metal 9 Roofing material 91 Mountain part 92 Valley part 93 Bing part B Fixing means

Claims (4)

A mounting bracket for an installation on a roof that can be attached to a vertical thatched roof,
A sandwiching body having left and right arms arranged on the ridges formed on the roofing material and forming a clamping part for clamping the ridges;
Clamping means for bringing the clamping parts of the clamping body close to each other;
A rotating shaft that pivotally supports the holding portions so as to be freely opened and closed;
Is supported by a the pivoting axis, Ri consists a mounting body for mounting unit for mounting the roof-installed object is formed,
The sandwich body is
It has an overlapping surface formed by bending inward from the upper side of the eaves ridge side of the left and right arms,
The above-mentioned figurine is
It has a connection surface that is folded down from the eaves ridge side of the mounting section,
The placing body is connected to the holding body by the rotating shaft;
On the pivot axis,
The overlapping surfaces of the sandwiching bodies
A mounting bracket for an installation on a roof, characterized in that an overlapping portion with the connection surface of the mounting body is pivotally supported . By pivotally supporting the mounting body in a loose state with respect to the rotation shaft,
The mounting bracket for on-roof installation according to claim 1, wherein the mounting body is capable of adopting a direction element other than a rotational direction element around the rotation axis. A mounting bracket for an installation on a roof that can be attached to a vertical thatched roof,
A sandwiching body having left and right arms arranged on the ridges formed on the roofing material and forming a clamping part for clamping the ridges;
Clamping means for bringing the clamping parts of the clamping body close to each other;
A rotating shaft that pivotally supports the holding portions so as to be freely opened and closed;
Is supported by a the pivoting axis, Ri consists a mounting body for mounting unit for mounting the roof-installed object is formed,
The sandwich body is
It has an overlapping surface formed by bending inward from the upper side of the eaves ridge side of the left and right arms,
The above-mentioned figurine is
It has a connection surface that is folded down from the eaves ridge side of the mounting section,
The placing body is connected to the holding body by the rotating shaft;
On the pivot axis,
The overlapping surfaces of the sandwiching bodies
The overlapping part with the connection surface of the above-mentioned body is pivotally supported. <br/>
Arrange the sandwich on both sides of the roof ridge,
Attach the mounting bracket to the roof material ridge by bringing the pair of clamping parts close by the fastening means,
An installation structure for an installation on the roof, wherein the installation on the roof is attached to the mounting portion. By pivotally supporting the mounting body in a loose state with respect to the rotation shaft,
The mounting structure for an installation object on a roof according to claim 3 , wherein the mounting body is capable of adopting a direction element other than a rotation direction element around the rotation axis.

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