JP5909754B2 - Solar panel fixing structure - Google Patents

Description

  The present invention relates to, for example, a solar panel fixing structure for fixing a solar panel on a mounting base such as a rooftop or a balcony. More specifically, the fixed portion is provided at each of the opposing edges of the solar panel, and the fixed portion is provided. A panel fixing portion corresponding to the above is provided on the mounting base, and the fixed portion is connected to the panel fixing portion to fix the solar panel to the mounting base.

Conventionally, as this type of solar panel fixing structure, as shown in FIG. 11, a fixed portion H is provided on each of the inclined upper hand edge PL and the inclined lower hand edge PL of the solar panel P fixed in an inclined state, The mounting base 2 is provided with a panel fixing portion 1 corresponding to each fixed portion H, and the solar panel P is moved up and down only for the fixed portion H of the inclined upper edge portion PL and the corresponding panel fixing portion 1. There are some which are connected by a pivot connecting portion J which is supported so as to be swingable.
Incidentally, the fixed part H of the inclined lower edge part PL and the corresponding panel fixing part 1 are simply connected in a fixed state.
Further, as shown in FIG. 11, the structure of the pivot connecting portion J includes a half-cracked pipe-like inner fitting portion 30 provided in the fixed portion H and a half-cracked pipe-like outer fit provided in the panel fixing portion 1. The portion 31 is fitted inside and outside, and the plate portion 33 of the fixed portion H rises from the slit portion 32 formed in the outer fitting portion 31, and the inner fitting portion 30 with respect to the outer fitting portion 31. The solar panel P is pivotally connected so as to be swingable by rotating in the circumferential direction.

JP 2007-224538 A (FIGS. 4 and 9)

According to the conventional solar panel fixing structure described above, the pivot connecting portion is provided at the fixed portion and the panel fixing portion at the inclined upper edge portion of the solar panel, so the pivot shaft of the pivot connecting portion is provided. It is possible to swing the solar panel up and down around the core.
Therefore, when performing various maintenance work on the back side of the solar panel (for example, wiring attachment / detachment and maintenance work, repair work and maintenance work on the waterproof layer of the mounting base, etc.), the solar panel should be pivotally connected. By swinging around, the space on the back side of the solar panel can be opened to facilitate the maintenance work.

However, according to the conventional solar panel fixing structure, the back space on the inclined lower hand edge side of the solar panel can be completely opened, but the pivot connection part is located on the inclined upper hand edge side. Therefore, the space between the solar panel and the mounting base is left as it is in a small space, and there is a problem that it is difficult to perform maintenance work and other work in that place.
For example, with regard to wiring and connectors on the back side of the solar panel, depending on the panel, there are cases where it is located on the inclined upper edge side, so wiring-related attachment and detachment work and maintenance work can be done with the solar panel and the mounting base. It is necessary to carry out in the narrow space between, and there exists a possibility that work efficiency may fall easily.
The same applies to the repair work and maintenance work of the waterproof layer of the mounting base, and there is a possibility that the work efficiency is likely to be lowered.

  Accordingly, an object of the present invention is to provide a solar panel fixing structure that solves the above-described problems and can efficiently perform various maintenance operations at any location on the back side of the solar panel.

The first characteristic configuration of the present invention is that a fixed portion is provided at each facing edge of the solar panel, a panel fixing portion corresponding to the fixed portion is provided on a mounting base, and the fixed portion is attached to the panel fixing portion. A solar panel fixing structure in which the solar panel is fixed to a mounting base by connecting the respective parts, wherein the panel fixing part is in a state along the longitudinal direction of the opposing edge of the solar panel and in parallel A pair of support rails that are respectively fixed to the mounting base in a state of being fixed, and a pivot piece that is supported by the support rail in a state of being movable along the longitudinal direction. The fixed portion is a portion around the fastener by fastening the fastener over the pivot piece and the fixed portion along the longitudinal direction on either side of the pair of support rails. The solar panel is connected in a swingable state, and the solar panel is attached to the other side of the pair of support rails by removing the fastener on the support rail side of either side of the pair of support rails. The fastener on the side of the support rail is capable of swinging with the pivot axis.
Further, the second characteristic configuration of the present invention is that a fixed portion is provided at each facing edge of the solar panel, a panel fixing portion corresponding to the fixed portion is provided on a mounting base, and the panel fixing portion A solar panel fixing structure in which the solar panel is fixed to a mounting base by connecting fixed parts, respectively, wherein the panel fixing part and the fixed part are pivotable about a pivot axis. The pivot connecting portions are respectively connected by a branch connecting portion, and the pivot supporting portion is formed so that the pivot axis is along the longitudinal direction of the facing edge of the solar panel. By removing one of the pivot connection parts, the pivot connection part is attached in a swingable manner around the pivot axis of the other pivot connection part, and the pivot connection part is a detachable pivot shaft member The panel fixing part A pivot piece for attaching the pivot shaft member; and a support rail for movably supporting the pivot piece along the longitudinal direction of the opposing edges of the solar panel; and A movement restricting mechanism for restricting the movement of the pivot piece with respect to the support rail is provided in conjunction with the operation of attaching to the pivot piece .

According to the second characteristic configuration of the present invention, since each panel fixing portion and the fixed portion are connected by the pivot connection portion, one of the pivot connection portions of the opposite edges of the solar panel can be removed. For example, the solar panel can be swung around the pivot axis of the other pivot joint, and if one pivot joint is kept connected and the other pivot joint is removed, The solar panel can be swung around the pivot axis of the pivot connection portion.
That is, since the solar panel can be swung around the pivot axis at any pivot connecting portion, any part on the back side of the solar panel can be opened. Maintenance work (for example, wiring-related attachment / detachment, maintenance work, repair work of the waterproof layer on the mounting base, maintenance work, etc.) can be performed efficiently.
In addition, when solar panels are installed in multiple rows with each pivot axis parallel (or almost parallel), the solar panels located in adjacent rows are connected to the pivot axis. If it is swung upwards so that it becomes a “C” shape when viewed from the direction, the space opened below each adjacent solar panel becomes a continuous wide open space, and the above-mentioned various maintenance operations are performed more efficiently. be able to.
Moreover, the solar panel can be fixed to the mounting base in a stable supporting state without swinging by connecting the pivot connecting portions of the opposing edge portions of the solar panel.

Further , the swinging action state in the pivot connecting portion can be easily switched by simply attaching and detaching the pivot shaft member.
In other words, the pivot shaft member can have a function as a pivot shaft in the pivot connection portion and a function of integrally connecting and fixing the panel fixing portion and the fixed portion, thereby realizing the sharing of parts. Can do.
Also, it is possible to easily perform maintenance of parts such as removing the pivot shaft member and checking the degree of deterioration easily, or replacing a new one in some cases.
Examples of the pivot shaft member include a bolt and a pin.

In addition , the pivot piece can be moved along the longitudinal direction of the support rail (longitudinal direction of the opposite edge of the solar panel) while the pivot piece is supported by the support rail.
Therefore, the mounting position can be moved along the support rail in a state where the solar panel is mounted on the mounting base, and the position adjustment can be easily performed even after mounting.
Therefore, the efficiency of the solar panel mounting operation can be improved.

In addition , the movement restricting mechanism acts in accordance with the operation of attaching the pivot shaft member to the pivot piece, and the position of the pivot piece on the support rail can be locked.
That is, the position of the solar panel can be locked only by a series of operations for attaching the pivot shaft member to the pivot piece, and a complicated operation is unnecessary.
Therefore, further efficiency improvement of the solar panel mounting operation can be achieved.

Perspective view showing how solar panels are fixed Exploded perspective view showing the installation of the fixing device Perspective view showing the installation status of the fixing device Exploded perspective view showing frame member installation status The perspective view which shows the installation condition of a frame member Sectional view showing the installation status of the fixing device Explanatory drawing showing the swinging situation of solar panels Sectional view showing movement restriction mechanism Sectional drawing which shows another embodiment of a movement control mechanism Sectional drawing which shows another embodiment of a movement control mechanism Explanatory drawing which shows the fixed situation of the solar panel of the conventional example

  Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the parts indicated by the same reference numerals as those in the conventional example indicate the same or corresponding parts.

  FIG. 1 shows an embodiment of a solar panel fixing structure of the present invention. A solar panel P is fixed to an attachment base 2 by a fixing device (corresponding to a panel fixing portion) 1.

In the present embodiment, the mounting base 2 is configured by laying a waterproof layer 2B on a concrete roof slab 2A. An example of the waterproof layer 2B is a sheet made of vinyl chloride.
However, the mounting base 2 is not limited to such a configuration. For example, the mounting base 2 may have a configuration in which a heat insulating material is disposed between the roof slab 2A and the waterproof layer 2B, or may be folded instead of the concrete roof slab 2A. Various measures such as one using a folded plate (metal plate) used for the plate roof and one provided with a heat insulating material on it are conceivable.

The fixing device 1 includes a grounding member 1C fixed on the mounting base 2 with a lateral interval, a support rail 1B mounted on the grounding members 1C, and a longitudinal direction with respect to the support rail 1B. And a pivot piece 1A supported so as to be movable along the axis.
The fixed portion H of the solar panel P is attached to the pivot piece 1A.

As shown in FIG. 2, the grounding member 1 </ b> C includes a disk-shaped bottom surface portion 5 a, a cylindrical portion 5 b erected at the center of the bottom surface portion 5 a, and a bottom surface portion arranged in a cross-sectional view on the outer periphery of the cylindrical portion 5 b. A retaining wall portion 5c formed over 5a and a bolt 5d embedded in the cylindrical portion 5b are integrally provided. A waterproof sheet 6 that is slightly larger than the bottom surface 5a is bonded to the bottom surface 5a. By bonding the waterproof sheet 6 to the upper surface of the waterproof layer 2B on the roof slab 2A, the grounding member 1C is bonded. The waterproof property of the installation part is improved. The bottom surface portion 5a, the cylindrical portion 5b, and the retaining wall portion 5c are made of hard synthetic resin.
Further, among the four retaining wall portions 5c, the two retaining wall portions 5c arranged orthogonal to the support rail 1B are screwed into the roof slab 2A and fixed to the grounding member 1C as shown in FIG. Insertion portions 8 for inserting 7 are respectively provided. And after installing the said screw member 7 in this insertion part 8, while filling with a sealing material, the cap 9 is installed.
On these caps 9, the support rail 1B is installed in the mounting state.

In this embodiment, the support rail 1B is made of a long metal shape steel formed by extrusion as shown in FIGS.
The support rail 1 </ b> B includes a pair of standing wall portions 10 that are erected at intervals on the left and right sides, and a connecting plate portion 11 that integrally connects the upper and lower intermediate portions of the pair of standing wall portions 10. is there.
On the inner surface of the upper edge portion of each standing wall portion 10, a dovetail groove portion 10 a that allows sliding in a state in which the pivot piece 1 </ b> A is fitted is provided in an opposing state.
The lower edge portion of each standing wall portion 10 is placed on the cap 9 as described above.
The connecting plate portion 11 is formed with a bolt insertion hole 11a corresponding to the bolt 5d of the grounding member 1C. By inserting the bolt 5d into the bolt insertion hole 11a and tightening the nut, the support rail 1B is fixed. It is fixed.

As shown in FIGS. 3 and 4, the pivot piece 1 </ b> A has a bulging protruding portion that can be fitted into the dovetail groove portion 10 a of the support rail 1 </ b> B at the left and right side edges in the axial direction of the support rail 1 </ b> B. 12a is provided, and a piece main body portion 12b having an A-shaped cross section that rises upward from the base end portion of the protruding portion 12a and connects the protruding portions 12a is provided.
A bolt through-hole h0 that penetrates along the axial direction of the support rail 1B is formed in the upper half of the piece body 12b. A bolt (corresponding to a pivot shaft member) B, which will be described later, is inserted into the bolt through hole h0 (see FIGS. 4, 5, and 7), and the frame member 3 of the solar panel P is swung around the bolt axis. It can be supported so as to be movable.

As shown in FIG. 1, the solar panel P is configured in a rectangular plate shape, and the surface portion is configured as a light receiving unit that receives sunlight (see FIGS. 6 and 7).
Two cross-shaped metal frame members 3 are bolted to the back surface in parallel to the short side and at intervals in the long side direction. The attachment position in the long side direction is set to a position that enters the center side from both ends. This makes it difficult for rainwater to be applied to the frame member 3, thereby improving durability by preventing corrosion. it can.
Although not shown in the drawing, connectors, wirings, and the like are provided on the back side of the solar panel P.

  As shown in FIG. 8, the frame member 3 includes a web 3A, an upper flange 3B bent from the upper edge of the web 3A to the center side of the solar panel P, and a side opposite to the upper flange 3B from the lower edge of the web 3A. It is composed of a lower flange (an example of a movement restriction mechanism) 3C that is bent on the short side edge PS side of the solar panel P.

  The upper flange 3B is bolted along the back surface of the solar panel P.

As shown in FIG. 7, the web 3A is formed in a trapezoidal shape such that the height dimension gradually decreases from one end to the other end in the longitudinal direction of the frame member 3, and the solar panel P is inclined. It is comprised so that it can be attached to.
Further, bolt through portions 3a and 3b through which bolts (corresponding to pivot shaft members) B can be inserted are formed on both end sides in the longitudinal direction of the web 3A. Incidentally, the bolt B can constitute the pivot coupling portion J by coupling the frame member 3 and the pivot piece 1A of the fixing device 1. The axis of the bolt B becomes the pivot axis X of the pivot connection portion J (see FIG. 6).
The bolt through portions 3a and 3b are respectively provided with round bolt through holes h1 that match the outer diameter of the bolt B.
In the present embodiment, the bolt penetrating portion 3a and the bolt penetrating portion 3b are provided on both end sides of the series of frame members 3 so as to correspond to the opposing long side edge portions PL of the solar panel P. It corresponds to such a fixed part H. That is, the two bolt penetrating portions 3a and 3b are provided so as to be shared by one frame member 3, and the number of parts is reduced. Therefore, it is also possible to adopt a configuration in which the two bolt penetrating portions 3a and 3b are provided separately from the frame member 3 separately.

Incidentally, as shown in FIG. 8, the upper flange 3B and the web 3A are bent so that the crossing angle is a right angle, whereas the lower flange portion 3C and the web 3A have an obtuse angle ( For example, it is bent to be about 95 degrees.
Accordingly, when the solar panel P is set on the support rail 1B of the fixing device 1, the solar panel P comes into contact with the support rail 1B from the tip of the lower flange portion 3C. When the solar panel P descends until the web 3A comes into contact with the support rail 1B, the lower flange portion 3C bends upward, and the frame member 3 elastically deforms in a direction in which the intersection angle between the lower flange portion 3C and the web 3A is close to a right angle. Therefore, a frictional force is generated between the lower flange portion 3C and the support rail 1B by the action of the elastic restoring force. In this state, when the bolt B from the pivot piece 1A is inserted through the bolt through hole h1 and fixed, the movement of the pivot piece 1A relative to the support rail 1B can be restricted by the action of the frictional force described above.
The movement restricting mechanism K is configured by the frame member 3 formed in this way.

Next, the installation procedure of the solar panel P will be described.
[1] The grounding members 1C are respectively arranged at predetermined positions on the roof slab 2A (see FIG. 2) so as to be arranged in at least two rows (see FIG. 1), and the screw member 7 is inserted through the insertion portion 8 to form the roof slab 2A. And screw in (see FIG. 6).
Thereafter, the waterproof sheet 6 is bonded to the waterproof layer 2B of the roof slab 2A.
Further, the cap 9 is installed by filling the insertion portion 8 with a sealing material. By this process, it becomes possible to maintain the waterproofness of the installation part of the fixing device 1.

[2] The support rail 1B is disposed above the installed grounding member 1C (see FIGS. 2 and 3). In the arrangement, the support rail 1B is aligned so that the bolt 5d protruding upward from the grounding member 1C penetrates the bolt insertion hole 11a of the support rail 1B, and the nut 5e is screwed into the penetrated bolt 5d. Fix together (see FIG. 2). The support rails 1B are provided in at least two rows.

[3] The protrusions 12a of the pivot piece 1A are fitted into the pair of dovetail grooves 10a of the support rail 1B, and are slid to a predetermined position in the longitudinal direction of the support rail 1B. In order to fix one solar panel P, at least four pivot pieces 1A are used corresponding to the bolt penetration portions 3a and 3b of each frame member 3.

[4] The solar panel P with the frame member 3 attached to the back surface is placed over the two support rails 1B, and the bolt through holes h1 of the bolt through portions 3a and 3b and the bolt through holes h0 of the pivot piece 1A are placed. The solar panel P is fixed at the four pivot joints J by inserting the bolts B in the penetrating state and tightening the nut Ba (see FIGS. 4 and 5). When the nut Ba is tightened, as shown in FIG. 8, when the solar panel P is pressed downward, the frame member 3 is lowered along the long bolt through hole h1, and the lower flange 3C of the frame member 3 is the support rail. It is pressed in a state along the upper surface of 1B. By fixing in this state, the frictional resistance between the frame member 3 and the support rail 1B can be increased to prevent the solar panel P from shifting.

With the above procedure, the solar panel P can be fixed on the mounting base 2, but when performing work such as maintenance on the back side of the solar panel P, as shown by the solid line in FIG. When the bolt B corresponding to the support rail 1B on one side is removed, the solar panel P can be swung upward with the bolt B corresponding to the support rail 1B on the other side as a pivot axis. Further, as shown by a two-dot chain line in FIG. 7, when the bolt B corresponding to the other side support rail 1B is removed, the solar panel P is moved upward with the bolt B corresponding to the one side support rail 1B as the pivot axis. The solar panel P can be swung upward in a direction that facilitates the work according to the work location on the back side of the solar panel P, and the work efficiency can be improved. .
In order to maintain the state in which the solar panel P is swung upward, for example, between the swing end portion of the solar panel P (or the frame member 3) and the support rail 1B, as shown in the figure. Although not shown, it is preferable to take a method such as arranging a support rod.

[Another embodiment]
Other embodiments will be described below.

<1> The installation target of the solar panel P is not limited to the roof slab described in the previous embodiment, and may be a similar roof slab or may have a different structure or form. In addition to the roof slab, for example, a roof or a wall can be set as the installation target.
These are collectively referred to as the mounting base 2.
<2> The panel fixing portion 1 is not limited to the fixing device described in the previous embodiment. For example, the panel fixing portion 1 includes a pivot piece 1A and a support rail 1B, and directly fixes the support rail 1B to the mounting base 2. You may comprise as follows. Moreover, the shape of each part can be changed as appropriate.
<3> The to-be-fixed part H is not restricted to the structure each provided in the both ends of the one frame member 3, You may provide individually.
<4> The movement restricting mechanism K is not limited to the one configured by the frame member 3 described in the previous embodiment. For example, the bolt through hole h1 formed in the web 3A is a vertically long slot as shown in FIG. And the bolt B and the frame member 3 may be configured to be relatively movable up and down. In this case, as shown in FIG. 9A, the frame member 3 can be floated with the bolt B temporarily fixed in the bolt through hole h1, and the pivot piece 1A is smoothly slid along the support rail 1B. Thus, the movement adjustment of the fixed position can be easily performed. When the position is determined, the friction between the lower flange portion 3C and the support rail 1B is achieved by lowering the frame member 3 along the elongated bolt through hole h1 and finally tightening the bolt B (see FIG. 9B). The force acts and the function as the movement restricting mechanism K can be exhibited.
Further, as another embodiment of the movement restricting mechanism K, for example, as shown in FIG. 10, the crossing angle between the upper flange 3B and the web 3A is obtuse as well as the crossing angle between the lower flange 3C and the web 3A. Even if it is formed, the lower flange 3C may be pressed against the support rail 1B while pulling the web 3A to the pivot piece 1A as the screw B and the nut Ba are deepened. Good.

  In addition, as mentioned above, although the code | symbol was written in order to make contrast with drawing convenient, this invention is not limited to the structure of an accompanying drawing by this entry. In addition, it goes without saying that the present invention can be carried out in various modes without departing from the gist of the present invention.

1 Fixing device (equivalent to panel fixing part)
1A pivot piece 1B support rail 2 mounting base B bolt (equivalent to pivot shaft member)
H Fixed part J Pivot connection part K Movement control mechanism P Solar panel PL Long edge (opposite edge)
X pivot axis

Claims (2)

Provide fixed parts at opposite edges of the solar panel,
A panel fixing portion corresponding to the fixed portion is provided on the mounting base,
A solar panel fixing structure in which the fixed portion is connected to the panel fixing portion and the solar panel is fixed to a mounting base,
The panel fixing portion is movable along the longitudinal direction and a pair of support rails that are respectively fixed to the mounting base in a state along the longitudinal direction of the opposing edges of the solar panel. A pivot piece supported by the support rail in a state,
The pivot piece and the fixed part are fastened to the pivot piece and the fixed part along the longitudinal direction on either side of the pair of support rails. , Connected in a swingable manner around the fastener,
The solar panel removes the fastener on the support rail side of one of the pair of support rails, thereby pivoting the fastener on the other support rail side of the pair of support rails. Solar panel fixing structure that can swing as a core . Provide fixed parts at opposite edges of the solar panel,
A panel fixing portion corresponding to the fixed portion is provided on the mounting base,
A solar panel fixing structure in which the fixed portion is connected to the panel fixing portion and the solar panel is fixed to a mounting base,
The panel fixing portion and the fixed portion are respectively connected by a pivot connecting portion that can swing around a pivot axis,
The pivot connection part is formed so that the pivot axis is along the longitudinal direction of the opposite edge of the solar panel;
The solar panel is attached so that it can swing around the pivot axis of the other pivot connection part by removing any one of the pivot connection parts ,
The pivot connection portion includes a pivot shaft member that is detachable.
The panel fixing portion includes a pivot piece to which the pivot shaft member is attached, and a support rail that supports the pivot piece movably along a longitudinal direction of opposing edges of the solar panel,
A solar panel fixing structure in which a movement restricting mechanism for restricting movement of the pivot piece relative to the support rail is provided in conjunction with an operation of attaching the pivot shaft member to the pivot piece .

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