JP2018023213A - Support for solar panel mounting base - Google Patents

Abstract

An object of the present invention is to provide a support for a solar cell panel mounting base that can contribute to a reduction in the installation cost of the solar cell panel.
A solar cell panel mounting base support body 2 for supporting a solar cell panel mounting base 3 to which the solar panel 1 is mounted has a base portion 212 on which the solar cell panel mounting base 3 is placed. Main strut 21 that is driven substantially perpendicular to the ground so that the portion 212 and the portion near the base portion 212 remain on the ground, and obliquely with respect to the ground while penetrating the portion near the base portion 212 of the main strut 21 Sub struts 22 to be driven.
[Selection] Figure 1

Description

  The present invention relates to a support for a solar cell panel mounting base for supporting a panel mounting base to which a solar cell panel is mounted.

  As a conventional technique of this type of support, a support for supporting a gantry of a solar cell panel described in Patent Document 1 by the present applicant is known. The solar cell panel support column support column includes a column member that is placed in a substantially perpendicular direction with respect to the ground, and a column member that is partially intersected with the column member placement direction. A plurality of reinforcing struts placed therein. The support member has a tapered tip formed in the ground, and the base end of the support member is provided with a mounting surface for mounting the solar cell panel and a support member for reinforcement. A bowl-shaped base portion is provided. Moreover, the intermediate support part is provided in the intermediate part surrounding surface left on the ground of the said support | pillar member. Each reinforcing column is inserted through the reinforcing column supporting part and the intermediate supporting part.

JP 2016-46889 A

  In recent years, photovoltaic power generation has attracted more and more attention as clean energy. For this reason, the number of installed solar cell panels has also increased significantly, and accordingly, a technique that can further reduce the installation cost of the solar cell panel is desired.

  Then, an object of this invention is to provide the support body of the solar cell panel mounting stand which can contribute to the further reduction of the installation cost of a solar cell panel.

  According to one aspect of the present invention, there is provided a support for a solar cell panel mounting frame that supports a solar cell panel mounting frame to which the solar cell panel is mounted. The support body of the solar cell panel mounting base has a base portion on which the solar cell panel mounting base is placed, and is substantially perpendicular to the ground so that the base portion and a portion in the vicinity of the base portion are exposed to the ground surface. And a sub strut that is driven obliquely with respect to the ground in a state of penetrating a portion of the main strut near the base portion.

  In the support body of the solar cell panel mounting base, the main strut and the sub strut need only have a relatively simple shape, so that the component cost can be reduced as compared with the conventional case. Further, the support for the solar cell panel mounting base can be installed simply by driving the sub-column through the main column after driving the main column, and the installation is very easy. For this reason, it can contribute to the reduction of the installation cost of a solar cell panel. Furthermore, the pull-out resistance force of the main column is greatly increased by the sub-columns which are driven obliquely with respect to the ground. For this reason, the solar cell panel mounting frame to which the solar cell panel is mounted can be stably supported by firmly fixing the solar cell panel mounting frame to the base portion.

It is a figure which shows the example of installation of a solar cell panel. It is a figure which shows the structure of the support body of the solar cell panel mounting base which concerns on one Embodiment of this invention, (a) is a front view of the said support body, (b) is a side view of the said support body. It is a figure which shows the main support | pillar which comprises the said support body, (a) is a front view of the said main support | pillar, (b) is a side view of the said main support | pillar, (c) is a top view of the said main support | pillar. .

  Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 shows an installation example of a solar cell panel using a support for a solar cell panel mounting base according to an embodiment of the present invention. The installation example shown in FIG. 1 is an installation example in the case of installing a solar cell panel mainly on a ground such as a resting place or a vacant lot. In this installation example, the solar cell panel 1 is attached to a solar cell panel mounting base (hereinafter simply referred to as “base”) 3 supported by a plurality of supports 2. In the figure, GL indicated by a two-dot chain line indicates the position of the ground surface.

  Each of the plurality of supports 2 is installed at a predetermined position by being driven into the ground so that the upper portion thereof remains on the ground (exposed). The gantry 3 includes a panel mounting portion 31 that is inclined at a predetermined angle, a plurality of leg portions (mounting column support) 32 that extends downward from the panel mounting portion 31, and a plurality of reinforcing members 33 that connect the leg portions 32 to each other. . In the gantry 3, each leg portion 32 is fastened and fixed to the upper portion of the corresponding support 2 left (exposed) by fastening members (here, bolts 11 and nuts 12). In the present embodiment, the gantry 3 has four leg portions 32, and the four support bodies 2 are installed so as to correspond to the four leg portions 32 of the gantry 3, respectively. Then, the solar cell panel 1 is configured to be attached to the panel mounting portion 31 of the gantry 3 in which each leg portion 32 is fixed to the upper portion of each support 2 by a dedicated mounting bracket (not shown).

  FIG. 2 shows the configuration of the support 2. FIG. 2A is a front view of the support 2, and FIG. 2B is a side view of the support 2. As shown in FIGS. 2A and 2B, in this embodiment, the support 2 is driven substantially perpendicularly to the ground so that a part of the support 2 remains on the ground (exposed). And sub struts 22 that are driven obliquely with respect to the ground in a state of penetrating through the remaining (exposed) portions of the main struts 21 on the ground.

  FIG. 3 is a diagram showing a configuration of the main column 21. FIG. 3A is a front view of the main column 21, FIG. 3B is a side view of the main column 21, and FIG. 3C is a plan view of the main column 21.

  As shown in FIG. 3, in the present embodiment, the main support column 21 includes a support column body 211 and a base portion 212 on which the gantry 3 is placed. The column main body 211 is formed of a steel circular pipe, and the base portion 212 is formed of a steel circular plate having a larger diameter than the column main body 211. However, it is not restricted to these, The support | pillar main body 211 may be formed with a steel rectangular tube, a steel shaft of a middle shaft, etc., and the base part 212 may be formed with a steel rectangular plate.

  The dimensions of the column main body 211 and the base portion 212 can be appropriately set according to the size of the gantry 3 or the installation location of the solar cell panel 1. Although not particularly limited, the column main body 211 may be, for example, a circular tube having an outer diameter d of about 60 mm and a wall thickness t of about 3 mm, and a length L of about 1000 mm. In addition, the base portion 212 may have, for example, an outer diameter d of about 160 mm and a thickness t of about 4.5 mm.

  One end 211a of the column main body 211 is formed in a tapered shape. The base portion 212 is fixed to the other end 211b of the column main body 211 by welding, for example. The one end 211a of the column main body 211 constitutes the tip of the main column 21 driven into the ground, and the base 212 fixed to the other end 211b of the column main body 211 constitutes the rear end of the main column 21. ing. In the present embodiment, at least one (four in this case) fin portion 211c is provided at one end 211a of the column main body 211 constituting the tip of the main column 21. The fin part 211c mainly has a function of preventing the rotation of the main column 21 driven into the ground.

  An insertion portion 213 through which the sub-column 22 is inserted is formed at a predetermined position near the base portion 212 of the column main body 211. The insertion portion 213 is formed so as to penetrate the main column 21 with a predetermined angle α with respect to the axis X of the main column 21 (see FIG. 3B). The predetermined angle α is not particularly limited, but is preferably 45 ± 15 °.

  In the present embodiment, the insertion portion 213 has a first hole portion 213a that opens to the front surface side, and opens to the back surface side, and is closer to one end 211a of the column main body 211 than the first hole portion 213a (the front end side of the main column 21). And the second hole portion 213b disposed in the inner space. The first hole portion 213a and the second hole portion 213b are formed to have a hole diameter slightly larger than the outer diameter of the sub-support post 22. At least one of the first hole 213a and the second hole 213b may be formed as a vertically long slot. When the column main body 211 is not a hollow tube but a solid shaft or the like, the insertion portion 213 can be formed as a through hole that penetrates the column main body 211 obliquely downward.

  The upper surface of the base portion 212 forms a placement surface on which the gantry 3 (the leg portion 32) is placed. A round hole 212a mainly used for positioning is formed at the center of the base part 212, and the base 3 (the leg part 32) is fastened and fixed to the base part 212 around the round hole 212a. A plurality (four in this case) of long holes 212b through which the bolts 11 are inserted are formed (see FIG. 3C).

  And the main support | pillar 21 is substantially perpendicular | vertical with respect to the ground from the one end 211a side of the support | pillar main body 211 so that the base part 212 and the site | part near the base part 212 including the insertion part 213 in the support | pillar main body 211 may remain on the ground. It is configured to be driven. Therefore, in the main column 21, the base portion 212 above the ground surface GL and the portion (including the insertion portion 213) in the vicinity of the base portion 212 of the column main body 211 constitute a ground surface exposed portion that is exposed to the ground surface. Many portions of the lower column main body 211 constitute an underground burying portion embedded in the ground.

  Returning to FIG. 2, the sub column 22 is formed of a steel circular tube, like the column main body 211 of the main column 21. However, the present invention is not limited to this, and the sub strut 22 may be formed of a steel rectangular tube or a solid steel shaft.

  The sub strut 22 is formed so that its outer diameter is smaller than the outer diameter of the strut body 211 of the main strut 21 (more specifically, the inner diameter of the insertion portion 213). Moreover, the length of the sub column 22 is longer than the length of the main column 21. Although not particularly limited, the sub-post 22 may have, for example, an outer diameter d of about 35 mm, a thickness t of about 2.5 mm, and a length of 1200 mm.

  As described above, the sub column 22 is inserted into the insertion portion 213 formed in the column main body 211 of the main column 21. Specifically, the sub strut 22 is inserted into the insertion portion 213 so that one end 22a constituting the tip portion driven into the ground passes in order of the first hole portion 213a and the second hole portion 213b formed in the strut body 211. It is inserted. Therefore, the sub strut 22 is inclined at the predetermined angle α with respect to the main strut 21 by being inserted into the insertion portion 213.

  In addition, a stopper portion 22 b is provided at the other end of the sub column 22, that is, at the rear end portion of the sub column 22. The stopper portion 22b is a column main body 211 of the main column 21 (specifically, around the first hole 213a) when the sub column 22 is driven into the ground in a state where the sub column 22 is inserted through the insertion unit 213 of the main column 21. This prevents the sub-post 22 from being driven further into the ground. In the present embodiment, the stopper portion 22b is formed by expanding the diameter of the other end (the rear end portion) of the sub column 22. However, the present invention is not limited to this, and a stopper portion 22b formed as a separate part from the sub-column 22 may be fixed to the other end (rear end portion) of the sub-column 22 or in the vicinity thereof.

  Next, installation work of the solar cell panel 1 using the support 2 will be described. First, the installation position (installation direction) of the gantry 3 is determined so that the solar panel 1 faces in an appropriate direction, and the determined installation position of the gantry 3 (specifically, the position of each leg 32 of the gantry 3) ) To determine the installation position of the support 2.

  When the installation position of the support body 2 is determined, the main support column 21 is driven substantially perpendicularly to the ground at the determined installation position of the support body 2. Specifically, one end 211a of the column main body 211 constituting the distal end portion of the main column 21 is directed downward, and the base portion 212 and the insertion portion 213 formed in the column main body 211 are left on the ground, so that the main column 21 is driven substantially perpendicular to the ground.

  When the driving of the main column 21 is completed, the sub column 22 is inserted into the insertion portion 213 of the main column 21 so that one end 22a (tip portion) of the sub column 22 passes through the first hole 213a and the second hole 213b in this order. After that, the sub strut 22 is driven into the ground. The sub column 22 is inclined at an angle of (90−α) ° with respect to the ground by being inserted through the insertion portion 213 of the main column 21. For this reason, the sub strut 22 is driven obliquely with respect to the ground. Then, when the sub column 22 is driven into the ground until the stopper portion 22b of the sub column 22 contacts the main column 21, the driving of the sub column 22 is completed. Thereby, installation of the support body 2 is completed.

  When the same number of supports 2 as the legs 32 of the gantry 3 are installed, each leg 32 of the gantry 3 assembled in advance is placed on the base portion 212 of the main column 21 of the corresponding support 2, and bolts 11 and nut 12 are used to fasten and fix each leg 32 to the base 212 of the main column 21 of the corresponding support 2. Alternatively, each leg 32 is placed on the base 212 of the main support 21 of the corresponding support 2, and the base 32 of the main support 21 of the support 2 is supported using the bolt 11 and the nut 12. The panel mounting portion 31 and the plurality of reinforcing members 33 are assembled and fastened to the portion 212, and the gantry 3 is completed on the support 2. In this way, the gantry 3 is installed on the support body 2 (the gantry 3 is supported by the plurality of support bodies 2). Then, the installation of the solar cell panel 1 is completed by attaching the solar cell panel 1 to the panel attachment portion 31 of the gantry 3.

  As described above, the support body 2 according to the present embodiment includes the main column 21 and the sub column 22. The main column 21 has a base portion 212 on which the gantry 3 (the leg portion 32) is placed and fixed, and the base column 212 and a portion including the insertion portion 213 in the vicinity thereof remain on the ground. It is driven almost vertically. The sub column 22 is driven obliquely with respect to the ground in a state where the sub column 22 is inserted through the insertion portion 213 of the main column 21 (that is, a state where the sub column 22 penetrates the main column 21). For this reason, the pullout resistance of the main column 21 is greatly increased by the sub column 22, and the frame 3 to which the solar cell panel 1 is attached is firmly fixed to the base 212 of the main column 21. Is supported stably. That is, the gantry 3 to which the solar cell panel 1 is attached is prevented from falling down due to wind or the like. In addition, since the support body 2 according to the present embodiment can be configured by only the main support column 21 and the sub support column 22, the number of components is small, and the main support column 21 and the sub support column 22 can have a relatively simple shape. Cost is reduced. Furthermore, the support body 2 according to the present embodiment can be installed simply by driving the main column 21 into the ground, and then inserting the sub column 22 through the insertion portion 213 of the main column 21 and driving it into the ground. Its installation is very easy. For this reason, the support body 2 which concerns on this embodiment can contribute to the reduction of the installation cost of the solar cell panel 1. FIG.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to the above-mentioned embodiment, Based on the technical idea of this invention, a further deformation | transformation and change are possible. For example, in the above-described embodiment, one sub column 22 is provided, but two sub columns 22 may be provided. In this case, one of the sub struts 22 can be configured to penetrate the main strut 21 in the front-rear direction, and the other sub strut 22 can be configured to penetrate the main strut 21 in the left-right direction. Moreover, the stopper part 22b does not necessarily need to be integrated with the sub strut 22, and can be configured to be attached to the other end (rear end part) of the sub strut 22, for example, by screwing. In this case, the stopper portion 22b may be attached to the other end of the sub column 22 at the installation site, or may be attached to the other end of the sub column 22 in advance.

DESCRIPTION OF SYMBOLS 1 ... Solar cell panel 2 ... Support body 3 ... Solar cell panel mounting stand 21 ... Main support | pillar 22 ... Sub support | pillar 211 ... Support | pillar body 211a ... One end of the support | pillar body (tip part of a main support | pillar)
211b ... the other end of the column body 211c ... the fin portion 212 ... the base portion 213 ... the insertion portion 22a ... one end of the sub column (the tip of the sub column)
22b ... Stopper

Claims (5)

A solar cell panel mounting base supporting a solar panel mounting base to which the solar panel is mounted,
A main column that has a base part on which a solar cell panel mounting base is placed, and is driven substantially perpendicularly to the ground so that the base part and the part in the vicinity of the base part remain on the ground;
A sub strut that is driven obliquely with respect to the ground in a state of penetrating a portion near the base portion of the main strut;
A support for a solar cell panel mounting base. The main strut has a base portion at a rear end portion opposite to the front end portion, and a front end portion which is driven into the ground is formed in a tapered shape.
The support body for a solar cell panel mounting base according to claim 1, wherein an insertion portion through which the sub-column is inserted is formed in a portion near the base portion of the main column.   The support body of the solar cell panel mounting stand according to claim 2, wherein at least one fin portion for preventing rotation of the main column after being driven into the ground is provided at the tip of the main column. .   The sub strut has a stopper portion at or near the rear end portion opposite to the tip portion to be driven into the ground, and the stopper portion comes into contact with the periphery of the insertion portion when the sub strut is driven in. The support body of the solar cell panel mounting base of Claim 2 or 3 which prevents that the said sub support | pillar is driven further by this.   The support body of the solar cell panel mounting base according to any one of claims 1 to 4, wherein the sub-column is formed longer than the main column.