JP5404354B2 - Draining structure for solar cell module - Google Patents

Description

  The present invention relates to a draining structure when a solar cell module is attached to a roof or the like.

In recent years, solar cells have been installed in various places such as public facilities and general households due to environmental concerns and policies.
When installing solar cells outdoors, many are assumed to be installed on the roof of a facility or house, but a structure that can sufficiently withstand wind and rain is required. For this reason, bolts, screws, and the like are used to fix solar cells to the laying surface such as a roof.

On the other hand, many laying surfaces such as roofs are not originally made on the assumption that solar cells are attached. Therefore, when installing the solar cell, it is necessary to consider that rainwater intrudes from the mounting surface or the like and does not cause rain leakage in the house.
In addition, the addition of the waterproof function has so far relied on sealing, but there is room for improvement, such as aging degradation of the sealing material and variations in the finish due to the skill level of the operator.

In this regard, in Patent Document 1, the roof mounting apparatus is configured to mount the roof equipment on the roof surface via the first mounting rail, and the first mounting rail is on the roof surface. There has been proposed a structure composed of a long fixing member to be fixed and a long draining plate fixed from above to the fixing member.
Moreover, in patent document 2, it is the solar energy utilization system which arrange | positioned the metal plate from which rainwater flows down on the inclined roof, and arrange | positioned the roof installation stand which installs solar energy utilization equipment on this metal plate, The roof installation stand includes a support body for fixing the solar device and a cover body that covers the support body, and the metal plate is folded at an upstream portion of the roof installation stand in the metal plate. A solar light utilization system has been proposed in which an eave portion is formed and an end portion of the cover body is inserted under the eave portion.

JP 2003-155804 A JP 2006-89978 A

However, in the technique described in Patent Document 1, the fixing member that is fixed on the roof surface and to which the draining plate is attached is a member that is as long as the mounting width of all the solar cell modules that are mounted on the roof surface. For this reason, the weight is increased, the load on the mounting house and the like is large, and the material procurement cost is also increased.
Moreover, in the technique of patent document 2, since the waterproof cover is only adhere | attached with the adhesive agent on the base part of a fixing metal fitting, since a waterproof cover peels off with progress of time, a waterproof effect reduces. There was a problem that.
Furthermore, in both Patent Documents 1 and 2, local pressure is applied to the laying surface of the roof or the like at the corners of the fixing member or the fixing bracket, and there is a possibility that the laying surface may be breached, rainwater on the laying surface, etc. No special consideration was given to preventing sideways running.

Therefore, an object of the present invention is to prevent rainwater from entering a house from a mounting surface of a mounting bracket of the solar cell module on a laying surface such as a roof on which the solar cell module is installed.
In addition, an object of the present invention is to provide a draining structure that can withstand deterioration over time and reduce the burden on a house or a roof to which a solar cell module is attached.

  In order to achieve the above-mentioned object, the drainage structure of the laying surface to which the solar cell module is attached, and a base portion in which a mounting hole for mounting to the laying surface is formed by a mounting screw, and the solar cell module are placed A solar cell module mounting bracket having a first mounting portion, a second mounting portion on which the solar cell module mounting bracket is mounted, and the second mounting portion. When the solar cell module mounting bracket is mounted on the second mounting portion, outside the portion where the mounting hole of the solar cell module mounting bracket is located, a right angle to the laying surface A draining plate provided with a projecting portion formed to project in any direction, and a draining cover having an opening surface on the lower surface side, the draining plate is placed on the laying surface, The solar cell module mounting bracket is The base portion is placed on the second placement portion of the draining plate, and is attached to the laying surface via the draining plate by the attachment screw through the attachment hole. The solar cell module installation metal fitting is covered, and the solar cell module is placed on the first placement portion via the draining cover and a predetermined solar cell module installation member. .

Further, the laying surface forms a predetermined gradient, and the projecting portion is along the outer peripheral shape of the base portion of the mounting part for mounting the solar cell module among the second mounting portions. It is good also as what is formed in the beam row direction ridge side and both sides of the column direction.

  Further, the outer peripheral surface of the draining cover on the beam row direction ridge side may be inclined toward the eaves side toward both ends while the central portion protrudes toward the ridge side.

  Further, the ridge side portion of the projecting portion in the beam direction may be inclined toward the eave side toward both ends while the central portion protrudes toward the ridge side.

  The laying surface is a horizontal roof in which a plurality of roof boards are rolled up in the beam row direction, and the plurality of roof boards are adjacent to each other, and the end portions of the roof boards on the beam row direction ridge side are Further, a step may be formed in the up and down direction covering the end portion of the roof plate on the eaves side, and the ridge side end portion of the draining plate may be inserted into the step.

  In addition, a folded portion folded back toward the eave side is formed at the ridge side end of the draining board, and the folded portion inserted into the step is in contact with the lower surface of the roof plate on the beam row direction ridge side. It may be in contact.

  Further, at least a portion of the protruding portion on the beam row direction ridge side and an inner peripheral surface of the draining cap that contacts the portion may be sealed.

  In addition, when the solar cell module mounting bracket is mounted on the second mounting portion on the lower surface side of the second mounting portion of the draining plate, the solar cell module mounting bracket It is good also as what is equipped with the space | gap part which the eaves side edge part of this depression opened toward the exterior on the outer side of the location in which an attachment hole is located, while being dented in the shape of an upper surface toward the eaves side edge part. .

  Moreover, the said space | gap part is good also as what is formed in the lower surface side of the 2nd mounting part of the said draining board along the said protrusion part.

  The draining cover may be formed of a hollow cap-like body having an opening surface on the lower surface side.

  Further, the drainage cover is formed of a hollow, substantially rod-like body that opens in the length direction on the lower surface side, and a plurality of the solar cell module mounting brackets are inserted by inserting mounting screws into the mounting holes of the base portion. A plurality of solar cell module mounting brackets, which are attached in a row at a predetermined installation interval on the laying surface, and the draining cover is installed in a row on the laying surface from the opening surface. It may be covered.

  Moreover, it is good also as what is sealed with the sealing material between the said installation surface and the said draining board.

ADVANTAGE OF THE INVENTION According to this invention, it can prevent that rainwater penetrate | invades into a house from the installation surface of the mounting bracket of a solar cell module, etc. in installation surfaces, such as a roof in which the solar cell module was installed.
Furthermore, the draining structure according to the present invention can withstand aging deterioration and reduce the burden on a house or a roof to which a solar cell module is attached.

In the draining structure which concerns on 1st embodiment of this invention, it is an external appearance perspective view which shows the state which installs a solar cell module in a laying surface. It is a sectional side view which shows the draining structure which concerns on this embodiment. It is the (a) top view and (b) front view which show the draining structure concerning this embodiment. It is an external appearance perspective view which shows the draining board used in the draining structure which concerns on this embodiment, (a), (b) shows a respectively different example. It is an external appearance perspective view which shows the installation metal fitting used in the draining structure which concerns on this embodiment. It is a disassembled perspective view which shows the draining structure which concerns on this embodiment. It is a sectional side view which shows the draining structure which concerns on 2nd embodiment of this invention. It is the (a) top view and (b) front view which show the draining structure concerning this embodiment. It is a disassembled perspective view which shows the draining structure which concerns on this embodiment.

Hereinafter, the draining structure according to the first embodiment of the present invention will be described with reference to the drawings.
In the draining structure according to the present embodiment, as shown in FIG. 1 and FIG. 2, a draining plate 4 is applied on a laying surface 1 such as a roof, on which an installation fitting 5, a draining cover 6, and a vertical member. A solar cell module 3 is attached via 2.

As shown in FIG. 2, the laying surface 1 in this example is a horizontal metal in which a plurality of metal plates 12 are rolled up in a beam direction (y direction) on a field plate 11 having a predetermined gradient. It is a roof.
Here, the metal plate 12 forms a jaw portion 12a folded back to the lower surface side in the ridge side direction at the eave side end portion, and a jaw portion 12b folded back to the upper surface side in the eave side direction at the ridge side end portion. Is forming. In the roof plates adjacent in the vertical direction, the jaw portion 12a of the metal plate 12 on the ridge side and the jaw portion 12b of the metal plate 12 on the eave side are engaged with each other. A step is formed so that the roof plate in the direction (y direction) ridge covers the roof plate on the eaves side.
A backing material such as foamed styrene or foamed polystyrene is appropriately laminated on the back surface of the metal plate 12.

The vertical member 2 is a member for mounting the solar cell module 3 thereon, and is fixed on the installation metal 5 via a draining cover 6.
As shown in FIG. 6, the vertical member 2 is a rod-like body having a hollow rectangular parallelepiped shape.
An opening 21a that is open in the length direction is formed on the upper surface, and horizontal surfaces on both sides of the opening 21a constitute a mounting portion 21 for mounting the solar cell module. Further, a side surface portion 22 extends from the side end portion of the placement portion 21 toward the laying surface 1, and a horizontal base portion 23 is formed at the lower end portion of the side surface portion 22. A hollow portion 21 b is formed surrounded by the placement portion 21, the side surface portion 22, and the base portion 23.
In addition, the base portion 23 is provided with a fastening hole 2a for inserting a fastening bolt 5b attached to the installation fitting 5 according to the installation interval of the installation fitting 5.

Further, the vertical member 2 is placed on the installation fitting 5 via the draining cover 6, and the fastening bolt 5b attached to the installation fitting 5 is inserted into the fastening hole 2a of the base portion 23 and screwed with a nut or the like. By combining, it is fixedly installed on the installation metal fitting 5.
Moreover, the solar cell module 3 is mounted on the mounting portion 21, and a predetermined fastening bolt is inserted into a fastening hole provided in a frame of the solar cell module 3 in advance and an opening 21 a between the mounting portions 21. The solar cell module 3 is fixedly installed on the vertical member 2 by screwing with a nut or the like in the hollow portion 21b.

  In this example, the vertical member 2 having the opening 21a formed on the upper surface is used. However, the present invention is not limited to this, and a vertical member having the opening formed on the lower surface can also be used. In this case, the fastening bolt 5b attached to the vertical member and the installation metal fitting 5 is inserted through the opening of the base portion, and is screwed into the hollow portion with a nut or the like to be fastened. On the other hand, a fastening hole for inserting a fastening bolt for fastening the solar cell module 3 and the vertical member in advance is provided in the mounting portion on the upper surface, and a fastening hole provided in advance in the frame of the solar cell module 3. The solar cell module 3 can be installed on the vertical member by inserting a fastening bolt through the fastening hole of the mounting portion and fastening with a nut or the like. In addition, the fastening bolts that fasten the installation bracket 5 and the vertical member 2 and the vertical member 2 and the solar cell module 3 may be fastened together with the same fastening bolt without using separate fastening bolts.

The solar cell module 3 is formed by surrounding a photoelectric conversion element that generates power by receiving light with a frame. The type of element is silicon, compound, organic, or the like, and is not particularly limited in the practice of the present invention.
A fastening hole for installing the solar cell module 3 in the longitudinal member 2 is provided in the frame of the solar cell module 3 in advance, and an opening 21 a between the fastening hole and the base portion 21 of the longitudinal member 2 is provided. The solar cell module 3 is fixed on the vertical member 2 by inserting a fastening bolt and screwing a nut or the like.

The draining plate 4 cushions the force applied to the laying surface 1 at the corners of the installation bracket 5, and rainwater or the like that runs laterally on the installation surface 1 travels along the place where the installation bracket 5 of the laying surface 1 is attached. It is a member for preventing it from entering.
As shown in FIG. 4A, the draining plate 4 is formed by molding a single rectangular metal plate, and is placed on the laying surface 1 and the installation fitting 5 is placed thereon. The mounting portion 41 and a folded portion 42 formed by folding one side edge portion of the mounting portion 41 to the upper surface side.

Further, on the upper surface side of the mounting portion 41, a protruding portion 41a protruding so as to rise from the laying surface 1 is formed along the outer peripheral shape of the base portion 51 of the mounting bracket 5 to be mounted. As shown in FIG. 3 (a) or FIG. 4 (a), the projecting portion 41a is a pair of beam-side projecting portions formed on the row direction (x direction) side of the mounting bracket 5 to be placed. 41x and a beam row side protruding portion 41y formed on the ridge side in the beam row direction (y direction). In FIG. 3 (a), the hatched portion indicates the projecting portion 41a, and each member is mounted on the laying surface 1 in both the column direction (x direction) and the beam direction (y direction). Indicates the direction.
Here, the columnar projecting portion 41x is formed straight in the beam row direction (y direction). On the other hand, the beam-row-side projecting portion 41y has a central portion projecting toward the beam-row direction (y-direction) ridge side, and is inclined toward the beam-row direction (y-direction) eaves toward both ends. Thus, even when rainwater or the like runs sideways on the laying surface, intrusion of rainwater or the like is hindered by the projecting portion 41a, and a hole formed in the laying surface 1 by being attached to the laying surface 1 by the mounting bolt 51b ( Hereinafter, it is possible to prevent rainwater or the like from entering from a place where the mounting bolt 51b is attached to the laying surface 1).

  Further, as shown in FIG. 4A, a gap 41 b is formed on the lower surface side of the mounting portion 41 so as to be recessed in a groove shape from the bottom surface to the upper surface side. The gap 41b is formed on the lower surface side of the protruding portion 41a along the protruding portion 41a. Moreover, the space | gap part 41b is formed to the eaves side edge part of the mounting part 41, and this eaves side edge part is opened toward the outer side. As a result, even if rainwater or the like has entered the lower surface of the draining plate 4, the rainwater is drained from the eaves side end through the gap 41 b, and rainwater or the like is discharged from the mounting surface. Infiltration can be prevented.

  Moreover, the folding | returning part 42 is inserted in the engaging part of the adjacent metal plate 12, as FIG. 2 shows. At this time, the folded portion 42 has a lower surface abutting on the eaves-side metal plate 12 and an upper surface abutting the jaw portion 12 a of the ridge-side metal plate 12. By being inserted in this way, rainwater from the building side, for example, rainwater flowing down from the metal plate 12 on the building side, enters between the laying surface 1 or the metal plate 12 and the draining plate 4 into the mounting surface. Can be prevented. Further, when the folded portion 42 contacts the eave-side metal plate 12 and the jaw portion 12a of the ridge-side metal plate 12, rainwater or the like enters and enters the engaging portion from the contact surface. Can be prevented.

  In addition, although the draining plate 4 in this example forms the space | gap part 41b in the back surface side of the protrusion part 41a, it is not restricted to this, The protrusion part 41a and the space | gap part 41b are at least the attachment surface of the installation metal fitting 5 The other example of such a draining board 4 is shown in FIG.4 (b).

Similarly to the draining plate 4, the draining plate 7 is formed by molding a single rectangular metal plate, placed on the laying surface 1, and a placement portion 71 on which the installation fitting 5 is placed. The folded portion 72 is formed by folding one side edge portion of the mounting portion 71.
On the other hand, unlike the draining plate 4, the draining plate 7 is provided with a gap 71 b at a position different from the protruding portion 71 a. That is, the gap 71b is formed straight in the beam row direction (y direction) outside the protruding portion 71a. Even with the draining plate 7 having such a shape, rainwater or the like that runs laterally on the laying surface is prevented from entering by the projecting portion 71a, and rainwater or the like that enters the lower surface of the draining plate 7 is the gap portion 71b. The water is drained to the eaves side, and rainwater and the like can be prevented from entering from the mounting surface.

The draining plate 4 having the above configuration is provided with a folded portion 42 at an engagement portion of adjacent roof plates so as to be in a line in the column direction (x direction) and the beam direction (y direction) while providing a predetermined interval. Is installed.
In addition, the draining board 4 in this example is attached on the laying surface 1 so as to form an interval for supporting one solar cell module 3 with two vertical members 2 in the column direction (x direction). Yes. Moreover, in the beam direction (y direction), it attaches for every level | step-difference part of an adjacent roof board. However, the installation interval of the installation plate 5 attached via the draining plate 4 or the draining plate 4 is not limited to the above-described example, and one sheet is provided by three or more vertical members 2 in the crossing direction (x direction). The installation interval for supporting the solar cell module 3 can also be set, or in the beam direction (y direction), some of the stepped portions of the roof plate can be skipped, and the installation interval can be set, for example, every two. it can.

  In addition, between the draining board 4 and the laying surface 1 contact | abutted to this may be sealed. The sealing agent used in this case is not particularly limited as long as it has adhesiveness. For example, silicone-based, modified silicone-based, polysulfide-based, acrylic urethane-based, polyurethane-based, modified polysulfide-based, acrylic-based, SBR-based Those having excellent moisture shielding properties such as butyl rubber-based oil caulking agents are suitable.

  As shown in FIGS. 2 and 3, the installation metal fitting 5 is a metal fitting attached to the installation surface 1 in order to place the vertical member 2 and the solar cell module 3 on the installation surface 1. A metal such as aluminum, iron or stainless steel can be applied to the material of the installation metal fitting 5 and is not particularly limited, but a material having good weather resistance is suitable.

  The mounting bracket 5 is formed by molding a metal. As shown in FIG. 5, as shown in FIG. 5, the mounting bracket 5 is close to each other from a position at a certain distance from both ends of the rectangular base 51. A pair of diagonally formed portions 52 formed obliquely in the direction to be oriented, a hanging portion 53 formed integrally by bending end portions of the obliquely disposed portions 52 so as to face each other, and the obliquely disposed portion 52. A pair of upright portions 54 formed to extend from the ends of the base portion 51 in a direction perpendicular to the base portion 51 and the hanging portion 53, and parallel to the base portion 51 and the hanging portion 53, respectively, at the tips of the compatible portion 54. And a pair of mounting portions 55 formed in the above.

  Attachment holes 51a for inserting attachment screws 51b are formed in the vicinity of both end portions of the base portion 51, respectively. And the installation metal fitting 5 mounts the base 51 in the part enclosed by the protrusion part 41a among the mounting parts 41 of the draining board 4, and the installation screw 51b penetrated by the attachment hole 51a is laid surface It is screwed into 1 and mounted on the laying surface 1.

A hollow portion 5 a surrounded by the hanging portion 53, the standing portion 54, and the placement portion 55 is formed on the upper surface side of the hanging portion 53. Further, the width between the mounting portions 55 formed above the hollow portion 5a is slightly larger than the diameter of the shaft of the fastening bolt 5b, and smaller than the diameter of the head portion of the fastening bolt 5b. An opening 55a is formed.
As shown in FIG. 2, the head portion of the fastening bolt 5b is inserted into the hollow portion 5a, and the shaft of the fastening bolt 5b is oriented from the opening portion 55a in a direction facing the base portion 51 or the hanging portion 53. The part sticks out.
The fastening bolt 5b that protrudes from the hollow portion 5a and the opening 55a of the installation metal fitting 5 and is inserted into the fastening hole 6a of the draining cover 6 and the fastening hole 2a of the vertical member 2 is screwed into the nut 5c, and these are integrated. Fixed.

  The installation fitting 5 having the above configuration is attached on each draining plate 4. In attachment, the attachment holes 51a are attached so as to be positioned on the eaves side or the ridge side in the beam row direction (y direction), or so that the opening 55a is parallel to the row direction (x direction).

  The draining cover 6 is a cover that prevents moisture from entering the attachment surface of the installation fitting 5 to the laying surface 1. The material of the draining cover 6 may be a pressed product of sheet metal such as aluminum, iron or stainless steel, or a resin molded product such as polycarbonate, but is not particularly limited.

As shown in FIG. 3 or FIG. 6, the draining cover 6 has a hollow cap shape in which a lower surface, which is a surface directed to the laying surface 1, is opened, and the opening surface of the draining plate 4 has a protruding portion 42. It has a shape along the outer periphery. That is, when the installation bracket 5 is covered in the opening surface, the portion corresponding to the beam row direction (y direction) ridge side has the center portion projecting to the beam row direction (y direction) ridge side, and at both ends. It is inclined toward the eaves side in the beam direction (y direction).
Further, a fastening hole 6 a for inserting a fastening bolt 5 b protruding from the installation fitting 5 is formed in the center of the draining cover 6.
In addition, in (a) top view of FIG. 3, (b) front view, in order to show the shape etc. of the installation metal fitting 5 covered with the draining cover 6, the draining cover 6 is shown with the broken line.

  The drainage cover 6 has at least a depth corresponding to the height of the installation fitting 5, that is, the length from the base portion 51 to the placement portion 55, and the installation fitting 5 is covered with the drainage cover 6. At that time, the entire installation fitting 5 is covered with the draining cover 6.

  Here, at least the inner surface of the ridge side portion of the draining cover 6 and the draining plate 4 in contact with this portion are sealed. The sealing agent used for sealing is not particularly limited as long as it has adhesiveness. For example, silicone, modified silicone, polysulfide, acrylic urethane, polyurethane, modified polysulfide, acrylic, SBR, A butyl rubber-based oily caulking agent or the like having excellent moisture shielding properties is suitable. In addition, it is also possible to seal between the draining cover 6 and the draining plate 4 in contact therewith.

Further, with reference to FIG. 6, a series of steps for sequentially attaching the draining plate 4, the installation fitting 5, the draining cover 6, and the vertical member 2 on the laying surface 1 will be described.
First, on the laying surface 1, the draining plate 4 is installed by inserting the folded portion 42 of the draining plate 4 between a plurality of roof boards laid side by side. At this time, the draining plates 4 are inserted in a row in the beam direction (y direction) and for each step portion of the roof plate. Moreover, in the column direction (x direction), it attaches with a predetermined space | interval so that the two vertical members 2 may support the solar cell module 3. FIG.
In addition, when installing the draining plate 4 on the laying surface 1, as described above with reference to FIG. 2, the folded portion 42 of the draining plate 4 abuts the lower surface side on the eaves side metal plate 12, The upper surface side is inserted into the engaging portion of the metal plate 12 so that the upper surface side contacts the jaw portion 12a of the metal plate 12 on the ridge side.
Moreover, you may seal between the draining board 4 and the laying surface 1 contact | abutted to this at this time. The sealing agent used here is not particularly limited as long as it has adhesiveness as described above.

  Next, the mounting bracket 5 is mounted on the portion of the mounting portion 41 of the draining plate 4 surrounded by the protruding portion 41a. Then, as shown in FIG. 2, a mounting screw 51 b such as a tapping screw is inserted into the mounting hole 51 a of the installed mounting bracket 5 and is screwed into the laying surface 1 through the draining plate 4. And the draining plate 4 are integrally attached to the laying surface 1.

Next, a draining cover 6 is attached so as to cover the installation fitting 5. At the time of attachment, the fastening bolt 5 b protruding from the installation fitting 5 is inserted into the fastening hole 6 a of the draining cover 6.
At this time, it is preferable to seal at least between the inside of the ridge side portion of the draining cover 6 and the draining plate 4 in contact with this portion. The sealing agent used here is not particularly limited as long as it has adhesiveness as described above. In addition, it is also possible to seal between the draining cover 6 and the draining plate 4 in contact therewith.

  Next, the vertical member 2 is attached from above the draining cover 6. At the time of attachment, the fastening bolt 5 b protruding from the fastening hole 6 a of the installation fitting 5 and the draining cover 6 is inserted into the fastening hole 2 a of the vertical member 2.

  Finally, the nut 5c is screwed into the fastening bolt 43b inserted through the fastening hole 6a of the draining cover 6 and the fastening hole 2a of the longitudinal member 2, whereby the installation metal fitting 5, the draining cover 6 and the longitudinal member 2 are integrated. Attached.

  The solar cell module 3 is placed on the vertical member 2, and a predetermined fastening bolt is inserted through a fastening hole provided in advance in a predetermined position of the frame and an opening 21a between the mounting portions 21, It is installed on the vertical member 2 by screwing with a nut or the like. Thereby, the solar cell module 3 is fixedly installed on the mounting portion 55 of the installation metal fitting 5 through the draining cover 6 and the vertical member 2. In addition, the fastening bolts that fasten the installation bracket 5 and the vertical member 2 and the vertical member 2 and the solar cell module 3 may be fastened together with the same fastening bolt without using separate fastening bolts.

  In addition, when attaching the attachment screw 51b and the fastening bolt 5b, it is preferable to insert a washer as appropriate in order to protect the seat surface.

By attaching each member as described above, in the laying surface 1 such as the roof where the solar cell module 3 is installed, rainwater can be prevented from entering the indoor from the mounting surface of the installation fitting 5 of the solar cell module 3. can do. Moreover, it can endure deterioration over time and can reduce the burden on a house or the like to which the solar cell module 3 is attached.
Further, since the draining plate 4 is sandwiched between the installation fitting 5 and the laying surface 1, the force applied locally to the laying surface such as a roof can be buffered at the corner portion of the installation fitting 5. Surface breakage can be prevented. Further, since the projecting portion 41a is provided on the draining plate 4, it is possible to prevent rainwater and the like from entering the indoor surface or the like from the mounting surface due to lateral running of rainwater or the like on the laying surface. In addition, since the gap 41b is provided in the draining plate 4, even if rainwater or the like runs sideways on the lower surface of the draining plate 4, the rainwater travels through the gap 41b to the eaves side. It is drained and rain water and the like can be prevented from entering from the mounting surface.

Next, a second embodiment of the present invention will be described with reference to the drawings.
As shown in FIGS. 7 and 9, the draining structure according to the present embodiment uses an elongated draining cover 8 different from the draining cover 6 of the first embodiment, and the beam running direction on the laying surface 1. A plurality of installation fittings 5 installed in a single row are integrally covered.
The configuration other than the draining cover 8 is the same as that of the first embodiment, and as shown in FIG. 7, the draining plate 4 is placed on the laying surface 1 such as a roof, and installed thereon. The metal fitting 5, the drainage cover 8, and the vertical member 2 are attached. Moreover, the solar cell module 3 is attached on the vertical member 2 similarly to FIG. 1 of 1st embodiment.

As shown in FIG. 8 or FIG. 9, the draining cover 8 is a long member having a substantially hat-shaped cross section formed by bending a single metal plate, and rises obliquely with respect to the laying surface 1. A pair of inclined portions 81 provided on the upper surface, a pair of standing portions 82 erected perpendicularly to the laying surface 1 from the inclined portions 81, and a single bent portion formed from the standing portions 82. The mounting portion 83 is made.
Further, on the mounting portion 83 on which the vertical member 2 is mounted on the upper surface, a fastening hole 8a for inserting the fastening bolt 5b protruding from the installation fitting 5 is drilled according to the mounting interval of the installation fitting 5. ing.
8A is a plan view, and FIG. 8B is a front view, the drainage cover 6 is indicated by a broken line in order to show the shape of the installation fitting 5 covered by the drainage cover 8.

The draining cover 8 has at least the height of the installation fitting 5, that is, the height corresponding to the length from the lower end of the base portion 51 to the placement portion 55, and the width corresponding to the lateral width of the installation fitting 5. When the drainage cover 6 is put on the installation fitting 5, the entire installation fitting 5 is covered with the drainage cover 8.
Furthermore, the drainage cover 8 has a length that can integrally cover the plurality of installation fittings 5 installed in a row in the beam row direction (y direction) on the laying surface 1.
In this example, the end of the draining cover 8 is in contact with the mounting portion 41 of the draining plate 4, but not limited to this, the width of the draining cover 8 is formed wider than this example. Thus, the end of the drainage cover 8 may be configured to contact the laying surface 1 outside the draining plate 4.

  Here, you may seal between the surface inside the inclination part 81 of the draining cover 8, and the draining board 4 contact | abutted to this part. The sealing agent used for sealing is not particularly limited as long as it has adhesiveness. For example, silicone, modified silicone, polysulfide, acrylic urethane, polyurethane, modified polysulfide, acrylic, SBR, A butyl rubber-based oily caulking agent or the like having excellent moisture shielding properties is suitable.

Further, with reference to FIG. 9, a series of steps for sequentially attaching the draining plate 4, the installation fitting 5, the draining cover 8, and the vertical member 2 on the laying surface 1 will be described.
First, as in the first embodiment, the draining plate 4 is installed on the laying surface 1 by engaging the folded portion 42 of the draining plate 4 into the stepped portions of the plurality of roofboards laid sideways. At this time, the draining plates 4 are inserted in a row in the beam row direction (y direction) and for each step portion. Moreover, in the column direction (x direction), it attaches with a predetermined space | interval so that the two vertical members 2 may support the solar cell module 3. FIG.

  Further, as shown in FIG. 7, the installation fitting 5 is placed on the portion of the placement portion 41 of the draining plate 4 surrounded by the protruding portion 41 a. Then, a mounting screw 51b such as a tapping screw is inserted through the mounting hole 51a of the installed mounting bracket 5 and screwed into the laying surface 1 through the draining plate 4, so that the mounting bracket 5 and the draining plate 4 are laid on the mounting surface. 1 is attached integrally.

Next, a plurality of installation fittings 5 installed in a row in the beam direction (y direction) on the laying surface 1 are integrally covered, and a draining cover 8 is attached. At the time of attachment, the fastening bolts 5 b protruding from the corresponding installation fittings 5 are inserted into the fastening holes 8 a of the draining cover 6. Thereby, the plurality of installation fittings 5 installed in a row are covered together by one draining cover 8.
At this time, at least the inner surface of the inclined portion 81 of the draining cover 8 and the draining plate 4 in contact with this portion may be sealed. The sealing agent used here is not particularly limited as long as it has adhesiveness as described above.

  Next, the vertical member 2 is attached from above the draining cover 8. At the time of attachment, the fastening bolts 5 b protruding from the fastening holes 8 a of the installation fitting 5 and the draining cover 8 are inserted into the fastening holes 2 a of the longitudinal member 2.

  Finally, the nut 5c is screwed into the fastening bolt 43b inserted through the fastening hole 8a of the draining cover 8 and the fastening hole 2a of the longitudinal member 2, whereby the installation metal fitting 5, the draining cover 8, and the longitudinal member 2 are integrated. Attached.

  As in the first embodiment, the solar cell module 3 is placed on the vertical member 2, and is provided with a fastening hole provided in advance at a predetermined position of the frame and an opening 21 a between the placement portions 21. A predetermined fastening bolt is inserted and screwed with a nut or the like to be installed on the vertical member 2. Thereby, the solar cell module 3 is fixedly installed on the mounting portion 55 of the installation metal fitting 5 through the draining cover 8 and the vertical member 2. Further, the fastening bolts that fasten the installation bracket 5 and the vertical member 2 and the vertical member 2 and the solar cell module 3 may be fastened together with the same fastening bolt without using separate fastening bolts, When attaching the mounting screw 51b and the fastening bolt 5b, in order to protect the seat surface, a washer may be sandwiched as appropriate, as in the first embodiment.

  According to this embodiment, since only one draining cover 8 needs to be attached to the plurality of installation fittings 5, the number of construction steps can be reduced.

DESCRIPTION OF SYMBOLS 1 Laying surface 11 Base plate 12 Metal plate 12a Jaw part 12b Jaw part 2 Vertical member 2a Fastening hole 21 Mounting part 21a Opening part 21b Hollow part 22 Side part 23 Base part 3 Solar cell module 4 Draining board 41 Mounting part 41a Protrusion Installation part 41b Gap part 41x Carrying-side projecting part 41y Beam-side projecting part 42 Folding part 5 Installation metal fitting 5a Hollow part 5b Fastening bolt 5c Nut 51 Base part 51a Installation hole 51b Installation screw 52 Slanting part 53 Hanging part 54 Standing portion 55 Mounting portion 55a Opening portion 6 Draining cover 6a Fastening hole 7 Draining plate 71 Mounting portion 71a Protruding portion 71b Gap portion 72 Folding portion 8 Draining cover 8a Fastening hole 81 Inclining portion 82 Standing portion 83 Mounting portion x Digit row direction y Beam row direction

Claims (12)

A draining structure of the laying surface to which the solar cell module is attached,
A solar cell module mounting bracket comprising: a base portion in which a mounting hole for mounting on the laying surface by a mounting screw; and a first mounting portion on which the solar cell module is mounted;
The second mounting portion on which the solar cell module mounting bracket is mounted, and the second mounting portion on which the solar cell module mounting bracket is mounted on the second mounting portion A draining plate provided with a projecting portion formed to project in a direction perpendicular to the laying surface on the outside of the location where the mounting hole of the solar cell module mounting bracket is located,
A drainage cover having an opening surface on the lower surface side,
The draining plate is placed on the laying surface,
The solar cell module mounting bracket allows the base portion to be mounted on the second mounting portion of the draining plate, and the laying surface through the mounting hole and through the draining plate through the mounting hole. Attached to the
The drainer cover covers the solar cell module mounting bracket,
The solar cell module is placed on the first placement portion via the drainage cover and a predetermined solar cell module installation member.
A draining structure characterized by that. The laying surface forms a predetermined gradient,
The projecting portion is formed on both the beam row direction ridge side and the beam row direction along the outer peripheral shape of the base portion of the mounted solar cell module mounting bracket among the second mounting portions. Yes,
The draining structure according to claim 1. The outer peripheral surface of the water draining cover on the ridge side in the beam direction is inclined toward the eaves side toward both ends while the central portion protrudes toward the ridge side.
The draining structure according to claim 1 or 2. The ridge side part of the projecting part in the beam direction is inclined toward the eaves side toward both ends while the central part protrudes toward the ridge side.
The draining structure according to any one of claims 1 to 3. The laying surface is a horizontal roof in which a plurality of roof boards are rolled up in the beam direction,
The plurality of roof boards, in the adjacent roof boards, the end of the roof board on the beam row direction ridge side covers the end of the roof board on the eaves side, forming a step up and down,
The ridge side end of the draining plate is inserted into the step,
The draining structure according to any one of claims 1 to 4. At the ridge side end of the draining board, a folded part is formed that is folded back to the eaves side.
The folded portion inserted into the step is in contact with the lower surface of the roof plate on the beam row direction ridge side,
The draining structure according to claim 5. At least a portion of the protruding portion on the beam row direction ridge side and the inner peripheral surface of the draining cap that contacts the portion are sealed.
The draining structure according to any one of claims 1 to 6. The mounting hole of the solar cell module installation bracket when the solar cell module installation bracket is mounted on the second mounting portion on the lower surface side of the second mounting portion of the draining plate. On the outside of the location where is located, is recessed in a groove shape toward the upper surface side toward the eaves side end, and the eaves side end of this recess is provided with a void portion opened toward the outside,
The draining structure according to any one of claims 1 to 7. The gap is formed on the lower surface side of the second mounting portion of the draining plate along the protruding portion.
The draining structure according to claim 8. The draining cover is composed of a hollow cap-like body having an opening surface on the lower surface side.
The draining structure according to any one of claims 1 to 9. The draining cover is composed of a hollow substantially rod-like body opened in the length direction on the lower surface side,
A plurality of the solar cell module installation brackets are attached in a row with a predetermined installation interval on the laying surface by inserting an attachment screw through the attachment hole of the base portion,
The draining cover integrally covers a plurality of solar cell module installation brackets installed in a row on the laying surface from the opening surface,
The draining structure according to any one of claims 1 to 9. Between the laying surface and the draining plate is sealed with a sealing material,
The draining structure according to any one of claims 1 to 11.

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