JP7146313B1 - Unevenness adjustment tool, solar cell module stand, and construction method for solar cell module stand - Google Patents

Abstract

An object of the present invention is to provide an unevenness adjustment tool that has a large unevenness adjustment width and can easily perform unevenness adjustment even in a solar cell module stand after installation. A frame component member (3a) forming a mounting frame on which a solar cell module is mounted, and a foundation pile that is driven into the ground in a substantially vertical direction and has an opening (33) at the pile head (32). The unevenness adjustment tool (5) for connecting the foundation pile (2) comprises a threaded portion (12) and a fixing portion (13) provided at the head of the threaded portion and fixed to the frame component member (3a). and a threaded hole (25) into which the threaded portion (12) is threaded, for rotating the threaded hole (25) relative to the threaded portion (12). and a guide portion (24) that fits into the opening (33) of the pile head (32) and rotates the screw hole (25) coaxially with the pile head (32). The above problem is solved by providing two members (21). [Selection drawing] Fig. 4

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an unevenness adjustment tool, a solar cell module stand, and a method for constructing a solar cell module stand.

In a photovoltaic power generation system, a large number of solar panels (also referred to as solar cell modules) are arranged side by side in a predetermined direction (eg, east-west direction). The solar panel is installed on the solar panel frame with the light-receiving surface on which the cells are arranged facing the sky. The solar panel mount can adjust the height and inclination of the solar panel in order to install the solar panel at a predetermined inclination angle in order to increase the light receiving efficiency of the solar panel. As a technology related to such a solar panel stand, there are, for example, the following technologies.

In Patent Document 1, a foundation pile is driven into the ground leaving a predetermined length in a substantially vertical direction, and a mounting frame is joined to the head of the foundation pile and a mounting frame on which a solar panel is mounted. A solar panel mount is disclosed. The solar panel stand includes a vertical and horizontal rotation shaft mechanism arranged between the mounting frame and the head of the foundation pile and capable of vertically and/or horizontally rotating the mounting frame. . The up-down horizontal rotation shaft mechanism is configured including a ball joint. The solar panel mounting frame has a vertical horizontal rotation shaft mechanism for each of a plurality of foundation piles. As a result, solar panels can be installed robustly and flexibly on slopes with different slope angles.

Also, US Pat. No. 6,200,003 discloses an adjustment fitting used to attach a profile rail or support rail to a stand profile that is fixed on the bottom side. The support rails preferably have a U-shaped cross-sectional shape. Stand profile means in this case a (U-shaped) profile rod or profile tube to be fixed on the bottom side, which can consist in particular of metal. The adjustment fitting is a leg segment having a first mounting flange and extending from the mounting flange on one side of the mounting flange for attaching the leg segment to the stand molding. and a leg segment having a mounting section for use. The adjustment fitting has a head segment having a second mounting flange for abutting and attaching the head segment to the first mounting flange of the leg segment. is doing. The head segment is provided for partial introduction into the support rail, and the two side walls, which are arranged opposite each other, are provided with through-cuts in the form of slots. Both slots extend into each side wall of the head segment, respectively axially with respect to the longitudinal axis of the head segment. This makes it possible to attach the (straight) support rail to the stand profile at the end.

Patent No. 6562748 Japanese Patent Publication No. 2021-536208

In the construction of today's solar cell module mounts, it is costly to evenly level the ground on which housing land is to be constructed. Therefore, in recent years, due to the impact of lower business feasibility due to an increase in initial cost, it is becoming more common to install a trestle on the ground using simple leveling or natural topography.

In addition, a pile construction method in which piles are driven into the ground as a foundation for supporting the pedestal on the ground has become mainstream. However, the smaller the tolerance of the top position of the pile when driving the pile into the ground surface, the more accuracy is required, and the pile must be carefully constructed. ing.

As a result, the adjacent module surfaces of the solar cell modules mounted on the solar cell module mount do not align with each other, and the overall appearance of the solar cell module mount becomes unsightly, and in some cases the landscape is affected. It will also be

Many mounting frame manufacturers use unevenness adjustment plates to adjust the height of the crest of each pile driven into the ground surface, or, as in Patent Document 2, We are developing a mount that can be adjusted for unevenness using unevenness adjustment metal fittings that have long holes that can be fixed vertically.

However, even if an unevenness adjusting plate or an unevenness adjusting fitting is used, the height difference of unevenness that can be absorbed is limited, and is considered to be, for example, about ±10 mm to ±20 mm. Further, in the adjustment method using the unevenness adjustment plate, it is necessary to lift the installed frame with a jack or the like in order to insert the plate. It has also been reported that the bolts used to maintain the height of the unevenness adjustment metal fittings are displaced when an external load such as snow load is applied.

Therefore, in the present invention, an unevenness adjustment tool, a solar cell module stand, and construction of a solar cell module stand that have a large unevenness adjustment range and can easily adjust unevenness even in the installed stand for the solar cell module. provide a way.

Frame constituent members (3a, 3b) constituting a mounting frame on which a solar cell module (4, 44) is mounted, according to one aspect of the present invention, and driven substantially vertically into the ground (6, 46) The unevenness adjusting device (5, 45) for connecting the foundation pile (2) having an opening (33) in the pile head (32) is a screw having a screw thread on the outer periphery. a first member (11, 11a) having a portion (12) and a fixing portion (13, 13a) provided at the head of the screw portion and fixed to the frame component members (3a, 3b); a threaded hole (25) into which the threaded portion (12) is screwed; a flange portion (23) for rotating the threaded hole (25) relative to the threaded portion (12); A second member (21) having a guide portion (24) that fits into the opening (33) of the pile head (32) and rotates the screw hole (25) coaxially with the pile head (32). , wherein the guide part (24) has an outer diameter that can be rotated along the inner diameter of the opening (33) of the pile head (32) .

The fixing part (13) is characterized by being substantially U-shaped or planar.

The unevenness adjusting device (5, 45) further includes the pile head (32) and the second member ( 21) is provided with a friction reducing member (35) arranged between.

The inner diameter surface of the opening (33) of the pile head (32) and the outer diameter surface of the guide portion (24) are coated or surface-treated .

The second member (21) is fixed by being rotated by a predetermined angle with respect to the fitted opening (33).

The solar cell module stand (1, 41) is characterized in that the unevenness adjusting device (5, 45) is attached to each of the pile heads (32).

A method for constructing a solar cell module stand (1, 41) according to one aspect of the present invention, wherein the solar cell module stand (1, 41) is mounted with a solar cell module (4, 44). A frame constituent member (3a, 3b) constituting a mounting frame, a foundation pile (2) driven into the ground (6, 46) in a substantially vertical direction, and the foundation having an opening (33) in the pile head (32). An unevenness adjusting device (5, 45) for connecting the pile head (32) of the pile (2) and the frame component members (3a, 3b), wherein the unevenness adjusting device (5, 45) a threaded portion (12) having a screw thread on its outer periphery; fixing portions (13, 13a) provided at the head portion of the threaded portion (12) and fixed to the frame component members (3a, 3b); a first member (11, 11a) having a, a threaded hole (25) into which the threaded portion (12) is screwed, and the threaded hole (25) relative to the threaded portion (12) and a guide portion that fits into the opening (33) of the pile head (32) and rotates the screw hole (25) coaxially with the pile head (32). and a second member (21) having (24), wherein the guide portion (24) is rotatable along the inner diameter of the opening (33) of the pile head (32). In the construction method of a solar cell module mounting frame (1, 41) having a The guide portion (24) is fitted into the opening (33) to attach the unevenness adjusting device (5, 45) to the pile head (32), and the frame component members (3a, 3b) are attached to the pile head The screw rotated by fixing the fixing portion (13) of the first member (11) of the unevenness adjusting device (5, 45) attached to (32) and rotating the flange portion (23). The position of the solar cell module (4, 44) is adjusted by relatively rotating the threaded portion (12) screwed into the hole (25).

ADVANTAGE OF THE INVENTION According to the one aspect of this invention, unevenness adjustment width is large, and unevenness adjustment can be easily performed even in the stand for solar cell modules after installation.

1 is a perspective view of a solar cell module stand in one embodiment (Example 1) of the present invention. FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view of a solar cell module stand that is installed on the ground and on which solar cell modules are mounted according to an embodiment (Example 1) of the present invention; 1 is a perspective view of an unevenness adjusting device installed between a pile head of a foundation pile and a mounting frame in one embodiment (Example 1) of the present invention. FIG. 1 is an exploded perspective view of an unevenness adjusting device installed between a pile head of a foundation pile and a mounting frame in one embodiment (Example 1) of the present invention. FIG. It is a figure explaining the state of expansion|extension of the screw part accompanying rotation operation of the unevenness adjusting instrument in one Embodiment (Example 1) of this invention. It is a perspective view of the stand for farming type solar cell modules in one embodiment (Example 2) of this invention. FIG. 7 is an enlarged exploded perspective view of the portion surrounded by symbol A in FIG. 6; FIG. 10 is an exploded perspective view of an unevenness adjusting device installed between the pile head of the foundation pile and the mounting frame in one embodiment (Example 2) of the present invention.

FIG. 1 is a perspective view of a solar cell module stand in one embodiment (Example 1) of the present invention. The solar cell module mount 1 is a mount for mounting one or more solar cell modules 4 in a predetermined direction and at a predetermined angle. In addition, in the example of FIG. 1, only one solar cell module 4 is shown for convenience of explanation.

A solar cell module stand 1 is mainly composed of a foundation pile 2 and a mounting frame 3 . The foundation piles 2 are driven into the ground 6 of uneven slopes such as hills. The type of the foundation pile 2 is not limited, and may be, for example, a single pipe pile, a screw pile, a C-shaped pile, or the like. Moreover, the material of the foundation pile 2 is not limited, and may be, for example, stainless steel, steel, aluminum, other metals, or a resin member having a certain strength.

The mounting frame 3 constitutes a frame for mounting the solar cell module 4 by combining the frame constituent members 3a and the frame constituent members 3b in a grid pattern. The frame constituent member 3a and the frame constituent member 3b are elongated members, and may be made of, for example, stainless steel, steel, aluminum, other metals, or resin members having a certain strength.

The frame constituent member 3a is supported by the foundation pile 2. As shown in FIG. A plurality of frame-constituting members 3b are arranged on the frame-constituting member 3a perpendicularly to the frame-constituting member 3a, and the solar cell modules 4 are installed on the frame-constituting members 3b.

Depending on the design, the frame component 3b is supported by the foundation piles 2, a plurality of frame components 3a are arranged on the frame component 3b perpendicularly to the frame component 3b, and a solar cell is mounted on the frame component 3a. A module 4 may be installed.

FIG. 2 is a side view of a solar cell module stand that is installed on the ground and on which solar cell modules are placed, in one embodiment (Example 1) of the present invention. A plurality of foundation piles 2 are driven into the ground 6 by a predetermined length so that their heads remain vertically or substantially vertically in the longitudinal direction. An unevenness adjusting device 5 is provided between the pile head of the foundation pile 2 and the mounting frame 3 (specifically, the frame constituent member 3a). The unevenness adjusting device 5 can connect the pile head of the foundation pile 2 and the mounting frame 3 to adjust the gap between the pile head of the foundation pile 2 and the mounting frame 3 in the vertical direction.

Regarding the driven foundation pile 2, the height from the ground 6 to the head of the foundation pile 2 (the height of the foundation pile 2 exposed from the ground 6) is preferably a predetermined height. , Since the ground 6 is uneven, it is difficult to drive the foundation pile 2 with strict accuracy. Therefore, the height of the portion of the foundation pile 2 exposed from the ground 6 may be a preset approximate height.

The final adjustment of the height and angle of inclination of the exposed portion is performed by adjusting the unevenness provided between the foundation pile 2 and the mounting frame 3 (specifically, the frame component 3a). It can be performed by rotating the adjusting tool 5 .

That is, the mounting frame 3 can be raised or lowered with respect to the pile head of the foundation pile 2 by rotating the unevenness adjusting device 5, thereby increasing the height of the surface of the solar cell module 4 that receives sunlight. and tilt angle can be adjusted.

FIG. 3 is a perspective view of an unevenness adjusting device installed between the pile head of the foundation pile and the mounting frame in one embodiment (Example 1) of the present invention. FIG. 3 shows an example in which the unevenness adjusting device 5 is installed on the pile head of the foundation pile 2 and fixed to the frame component 3a, but for the convenience of explanation, the description of the frame component 3a is omitted. It is

The unevenness adjustment tool 5 is mainly composed of a first member 11 and a second member 21 . The first member 11 is fixed to the mounting frame 3 (specifically, the frame-constituting member 3a). The second member 21 is installed rotatably with respect to the pile head of the foundation pile 2 . Materials for the first member 11 and the second member 21 are not particularly limited as long as they have a certain level of strength and durability, but they may be made of metal, for example.

The first member 11 has a threaded portion 12 and a fixed portion 13 . The threaded portion 12 is provided with a thread on its outer periphery. The fixing portion 13 is provided at the head portion of the screw portion 12 and has a substantially U shape. The fixed portion 13 has a substantially U-shaped bottom portion that is integrally joined to the head portion of the screw portion 12 , and a substantially U-shaped side portion that is attached to the mounting frame (specifically, by a bolt 14 and a nut 15 ). is fixed with the frame component 3a).

The second member 21 has a screw receiving portion 22 and a flange portion 23 . The screw receiving portion 22 is a structure for receiving the threaded portion 12, and the inner wall forming the inner diameter (that is, the threaded hole) is provided with a screw thread into which the threaded portion 12 is screwed. The flange portion 23 is a structure for applying a rotational force to the screw portion 12 screwed into the screw hole to rotate the screw hole. be. When the second member 21 does not need to be rotated with respect to the pile head of the foundation pile 2 , it can be fixed with a bolt 31 so as not to rotate with respect to the foundation pile 2 .

FIG. 4 is an exploded perspective view of an unevenness adjusting device installed between the pile head of the foundation pile and the mounting frame in one embodiment (Example 1) of the present invention. In the example of FIG. 4, between the pile head 32 of the foundation pile 2 and the frame component member 3a, mainly the first member 11, the second member 21, and the unevenness adjustment device including the friction reduction member 35 Decomposition is shown.

The first member 11 has a threaded portion 12 and a fixed portion 13 . The threaded portion 12 is provided with a thread on its outer periphery. The fixed portion 13 is provided at the head portion of the threaded portion 12 and is fixed to the mounting frame (specifically, the frame component member 3a) by a bolt 14 and a nut 15. As shown in FIG.

The second member 21 has a screw receiving portion 22 , a flange portion 23 and a guide portion 24 . The screw receiving portion 22 is a structure for receiving the threaded portion 12, and the inner wall forming the inner diameter (that is, the threaded hole 25) of the screw receiving portion 22 is provided with a thread into which the threaded portion 12 is screwed. ing.

The flange portion 23 is a structure for applying a rotational force to the screw portion 12 screwed into the screw hole 25 so as to rotate the screw hole 25 relatively. A side surface of the flange portion 23 that is perpendicular to the axial direction of the screw hole 25 is provided with gear-shaped unevenness so that the second member 21 can be easily rotated by hand. In addition, the shape of the side surface of the flange portion 23 is not limited to such a gear-shaped unevenness, and may be formed with a protrusion that facilitates manual rotation of the second member 21, or may have a certain frictional resistance. The surface may be processed so that

Further, the shape of the flange portion 23 when viewed from above is not limited to a disk shape, and may be an elliptical disk shape, a polygonal shape such as a triangle or a square, a five-pointed star or a six-pointed star. It may be a disk shape of a busy star such as , or a graphical disk shape such as linear symmetry or point symmetry.

The guide portion 24 is a structure that forms a guide member that fits into the opening 33 of the pile head 32 of the foundation pile 2 and rotates coaxially along the inner diameter of the foundation pile 2 . One or more bolt holes 26 for inserting bolts 31 are formed in the side surface of the guide portion 24 .

In addition, since the guide portion 24 is fitted with the opening 33 of the pile head 32 of the foundation pile 2 and is rotated coaxially along the inner diameter of the foundation pile 2, the outer diameter surface of the guide portion 24 is aligned with the pile head 32. It is desirable to avoid contact with the inner diameter surface of the However, the outer diameter surface of the guide portion 24 and the inner diameter surface of the pile head 32 may contact each other. Therefore, the outer diameter surface of the guide part 24 and the inner diameter surface of the pile head 32 are coated or surface treated so that they can rotate while in contact with each other, even if the frictional resistance is reduced. good.

When the second member 21 is fitted to the edge forming the opening 33 of the pile head 32 along the guide portion 24 , the pile head 32 is brought into contact with the flange portion 23 near the base of the guide portion 24 . However, when the pile head 32 is brought into contact with the flange portion 23, when the second member 21 is rotated with respect to the foundation pile 2, the second member 21 becomes difficult to rotate due to the frictional resistance of this contact portion. . Therefore, in order to reduce the frictional resistance, an annular friction reducing member 35 may be arranged between the edge of the opening 33 of the pile head 32 of the foundation pile 2 and the flange portion 23 . Although the material of the friction reducing member 35 is not particularly limited, it may be made of, for example, ABS resin (a general term for acrylonitrile, butadiene, and styrene copolymer synthetic resins). .

A bearing such as a ball bearing or a roller bearing may be used as the friction reduction member 35, for example.

The second member 21 can be fixed to the foundation pile 2 with a bolt 31 when it is not necessary to rotate it with respect to the pile head 32 of the foundation pile 2 . That is, when the cylindrical guide portion 24 is viewed from the cross-sectional direction, four bolt holes 26 through which the bolts 31 are inserted are formed in 90-degree directions. When the cylindrical foundation pile 2 is viewed from the cross-sectional direction, four bolt holes 34 through which bolts 31 are inserted are formed in 90-degree directions. Therefore, by aligning the bolt hole 26 of the guide portion 24 with the bolt hole 34 of the foundation pile 2 , the bolt 31 can be inserted through the overlapping bolt holes 26 and 34 . 21 can be controlled.

5A and 5B are diagrams for explaining the state of extension of the threaded portion associated with the rotation operation of the unevenness adjusting device in one embodiment (Example 1) of the present invention. FIG. FIG. 5A shows the unevenness adjustment tool 5 in a state in which the threaded portion 12 is closed (a state in which the threaded portion 12 is embedded in the threaded hole 25). FIG. 5(B) shows the unevenness adjustment tool 5 in a state in which the threaded portion 12 is open (a state in which the threaded portion 12 is exposed from the threaded hole 25).

FIG. 5 shows an example in which the unevenness adjusting device 5 is installed on the pile head of the foundation pile 2 and the fixing portion 13 is fixed to the frame component 3a. is omitted. The bolt 31 is removed so that the second member 21 of the unevenness adjusting device 5 can rotate with respect to the pile head 32 of the foundation pile 2 .

For example, FIG. 5A shows the state of the unevenness adjusting device 5 immediately after the second member 21 is fitted to the pile head 32 of the foundation pile 2 and the fixing portion 13 is fixed to the frame component member 3a ( state of the unevenness adjusting device 5). When the flange portion 23 is rotated rightward from this state, the first member 11 rises relative to the second member 21 according to the principle of screwing, and the unevenness adjusting device 5 changes to the state shown in FIG. 5(B). Become.

Further, when the flange portion 23 is rotated leftward from the state of FIG. The state of 5(A) is reached.

The unevenness adjustment tool 5 can be used not only for the solar cell module mount 1 but also for other types of solar cell module mounts. Below, as an example of another type of solar cell module stand, a farming type solar cell module stand will be described.

FIG. 6 is a perspective view of a farming type solar cell module stand in one embodiment (Example 2) of the present invention. Unlike the solar cell module mount 1 of FIG. 1, the farming type solar cell module mount 41 is a mount for effectively utilizing the area above the farmland. Therefore, crops are grown in the area covered by the farming type solar cell module stand 41, and the environment needs to be such that sunlight reaches the crops for growing. Therefore, the farming-type solar cell module stand 41 is arranged at intervals such that the solar cell modules 44 have a certain gap. The farming type solar cell module stand 41 will be described in detail below. In addition, the same code|symbol is provided about the structure same as Example 1, and the description is abbreviate|omitted.

The farming type solar cell module pedestal 41 is a pedestal for mounting one or more solar cell modules 44 in a predetermined direction at a predetermined angle and at predetermined intervals so as to form a predetermined gap.

The farming type solar cell module stand 41 is mainly composed of a foundation pile 42 and a mounting frame 43 . The foundation piles 42 are driven into the ground 46 of agricultural land such as cultivated land. The type of foundation pile 42 is not limited, and may be, for example, a single pipe pile, a screw pile, a C-shaped pile, or the like. The material of the foundation piles 42 is not limited, and may be, for example, stainless steel, steel, aluminum, other metals, or resin members having a certain strength.

The mounting frame 43 constitutes a frame for mounting the solar cell module 44 by combining the frame constituent members 43a and the frame constituent members 43b in a grid pattern. The frame constituent member 43a and the frame constituent member 43b are elongated members, and may be made of, for example, stainless steel, steel, aluminum, other metals, or resin members having a certain strength. The frame constituent members 43 a and 43 b are supported by foundation piles 42 .

An unevenness adjusting device 45 is provided between the pile head of the foundation pile 42 and the mounting frame 43 . The unevenness adjusting device 45 can connect the pile head of the foundation pile 42 and the mounting frame 43 to adjust the distance between the pile head of the foundation pile 42 and the mounting frame 43 in the vertical direction.

FIG. 7 is an enlarged exploded perspective view of the portion surrounded by symbol A in FIG. FIG. 7 illustrates a configuration in which an unevenness adjusting device 45 is installed at the pile head of the foundation pile 42, and the fixing portion 13a of the unevenness adjusting device 45 supports the frame constituent member 43a and the frame constituent member 43b. .

FIG. 8 is an exploded perspective view of an unevenness adjusting device installed between the pile head of the foundation pile and the mounting frame in one embodiment (Example 2) of the present invention. The unevenness adjusting device 45 is mainly composed of a first member 11a and a second member 21. As shown in FIG. The first member 11a is a member fixed to the mounting frame 3 (specifically, the frame constituent member 3a and the frame constituent member 3b), and replaces the fixed portion 13 of the first embodiment with the fixed portion 13a. be.

The second member 21 is a member that is rotatably installed with respect to the pile head of the foundation pile 2, and is the same as in the first embodiment. Materials for the first member 11 and the second member 21 are not particularly limited as long as they have a certain level of strength and durability, but they may be made of metal, for example.

The first member 11 has a threaded portion 12 and a fixed portion 13a. The threaded portion 12 is provided with a thread on its outer periphery.

The fixing portion 13a is provided on the head portion of the screw portion 12 and has a planar shape. The fixed portion 13a is integrally joined to the head portion of the screw portion 12 at the center or center of gravity of the flat plate shape. The fixing portion 13a is provided with grooves 52 along two sides in the same direction. The grooves 52 are provided for fixing the frame component 3a and the frame component 3b with bolts and nuts. A member having grooves similar to the groove 52 may be installed so that the grooves are orthogonal to each other, and bolts may be installed so as to slide in the respective grooves to form an orthogonal slide structure. This facilitates adjustment in the planar direction.

Note that the shape of the fixing portion 13a when viewed from above is not limited to a rectangular shape, and may be any shape. For example, the shape may be a disk shape, an elliptical disk shape, a gear shape, a polygonal shape such as a triangle or a square, or a busy star disk shape such as a pentagram or a hexagram. However, it may be a figure board shape such as linear symmetry or point symmetry.

The second member 21 has a screw receiving portion 22 and a flange portion 23 . Since the second member 21 is the same as that of the first embodiment, description of its configuration and function is omitted. Although the exploded view between the second member 21 and the pile head is omitted in FIG. 8, this is also the same as the first embodiment, and friction A reduction member 35 is also provided. Further, since the mode of operation of the unevenness adjusting device 45 in the second embodiment is the same as the mode of operation of the unevenness adjusting device 5 in the first embodiment described with reference to FIG. 5, the description thereof will be omitted.

In this embodiment (Example 1 and Example 2), as an example, it is assumed that the screw pitch is set to 6 mm. In this case, when the second member 21 is rotated rightward 360 degrees, the first member 11 rises by 6 mm relative to the second member 21, and when it is rotated leftward 360 degrees, the first member 11 It descends by 6 mm relative to the second member 21 . As a result, the unevenness adjusting tool 5 expands and contracts by the exposed width of the screw portion 12, and this width becomes the unevenness adjusting width. This unevenness adjustment width can be adjusted by changing the length (screw length) of the threaded portion 12 . By adjusting the screw length, it is also possible to adjust the unevenness adjustment width, for example, in the range of 50 mm to 100 mm.

After adjusting the unevenness adjustment width, the second member 21 is fixed to the foundation pile 2 with the bolts 31 . When fixed, the bolt holes 26 and 34 through which the bolts 31 are inserted are formed at four locations in the direction of 90 degrees when viewed from the cross-sectional direction of the foundation pile 2 . Therefore, the rotational position of the second member 21 can be fixed in units of ±90 degrees (that is, ±1/4 pitch (±1.5 mm)).

However, since the unevenness adjustment is to align the module surface of the solar cell module 4 with the adjacent module surface, the worst condition when the adjacent module surfaces are aligned is a hole in the 90 degree direction. This is the case of the 45-degree direction, which is the middle of . In that case, since the rotation is either +45 degrees or -45 degrees, the accuracy of unevenness adjustment for the module surface of the solar cell module 4 is ±0.75 mm.

In the present embodiment (Example 1 and Example 2), as an example, a single thread was used for the threaded portion 12, but the thread portion 12 is not limited to this. good.

As described above, the unevenness adjustment tool (5, 45) in the present embodiment (Example 1 and Example 2) connects the frame component members (3a, 3b) and the foundation pile (2). The frame constituent members (3a, 3b) constitute a mounting frame on which the solar cell modules (4, 44) are mounted. The foundation pile (2) is driven substantially vertically into the ground (6, 46) and has an opening (33) at the pile head (32). The unevenness adjusting device (5, 45) has a first member (11) and a second member (21). The first member (11) includes a threaded portion (12) having a screw thread on its outer periphery, and a fixing portion (13, 13a) and. The second member (21) has a threaded hole (25), a flange portion (23) and a guide portion (24). The screw portion (12) is screwed into the screw hole (25). The flange portion (23) is for rotating the threaded hole (25) relative to the screwed threaded portion (12). The guide portion (24) is fitted into the opening (33) of the pile head (32) to rotate the screw hole (25) coaxially with the pile head (32).

By configuring in this way, the unevenness adjustment range is greater than in the conventional case, and the unevenness adjustment can be easily performed even in the solar cell module stand after installation. As a result, the adjacent module surfaces of the solar cell modules mounted on the solar cell module stand are flush with each other, and the overall appearance of the solar cell module stand is improved and the scenery is friendly.

The fixing portion (13, 13a) may be substantially U-shaped or planar.

With this configuration, the fixing surface (fixing direction) of the fixing portions (13, 13a) can be changed according to the shape and direction of the fixing surface of the member to be fixed. Specifically, when the fixing portion is substantially U-shaped, the side portions of the U-shape can be fixed to the side surfaces of the frame components (3a, 3b) with bolts and nuts. That is, the frame component and the fixed portion can be fixed by passing the bolt through the hole provided in the frame component and the U-shaped side surface in the direction perpendicular to the rotation axis direction of the unevenness adjusting device. In addition, when the fixed portion has a planar shape, the planar portion can be fixed to the bottom surface of the frame constituent members (3a, 3b) with bolts and nuts. That is, the frame constituent member and the fixed portion can be fixed by passing the bolt through the hole provided in the frame constituent member and the plane portion in the same direction as the rotation axis direction of the unevenness adjusting device.

The unevenness adjusting device (5, 45) further includes the pile head (32) and the second member ( 21) may have a friction reducing member (35) disposed therebetween.

By configuring in this way, it becomes easier to rotate the second member (21) with respect to the pile head (32). Here, the friction reducing member (35) may be, for example, an ABS resin annular member arranged so as to cover the opening of the pile head (32). Further, the friction reducing member (35) may be, for example, a ball bearing arranged to cover the opening of the pile head (32), or a ball installed inside the pile head (32). It may be a bearing or roll bearing.

The guide portion (24) may have an outer diameter that is rotatable along the inner diameter of the opening (33) of the pile head (32).

By configuring in this way, the second member (21) can be rotated coaxially with the foundation pile (2).

The second member (21) may be rotated by a predetermined angle with respect to the fitted opening (33) and fixed.

By configuring in this way, the second member (21) can be fixed to the pile head (32) at the position where the unevenness is adjusted and positioned.

Further, the solar cell module mounts (1, 41) may be constructed by attaching such unevenness adjusting tools (5, 45) to the respective pile heads (32).

By configuring in this way, unevenness can be easily adjusted even in the solar cell module stand (1, 41) after installation.

Further, in the construction method of the solar cell module mount (1, 41) according to one embodiment of the present embodiment, the solar cell module mount (1, 41) includes the frame constituent members (3a, 3b), the foundation piles ( 2) and an unevenness adjustment device (5, 45). The frame constituent members (3a, 3b) constitute a mounting frame on which the solar cell modules (4, 44) are mounted. The foundation pile (2) is driven substantially vertically into the ground (6, 46). The unevenness adjusting device (5, 45) connects the pile head (32) of the foundation pile (2) having an opening (33) in the pile head (32) and the frame component members (3a, 3b). . The unevenness adjusting device (5, 45) has a first member (11), a second member (21), and a guide portion (24). The first member (11, 11a) has a threaded portion (12) and a fixed portion (13, 11a). The threaded portion (12) is threaded on its outer periphery. Fixing portions (13, 11a) are provided on the head portions of the screw portions (12) and fixed to the frame constituent members (3a, 3b). The second member (21) has a threaded hole (25), a flange portion (23) and a guide portion (24). The threaded portion (12) is screwed into the threaded hole (25). The flange portion (23) is for rotating the threaded hole (25) relative to the screwed threaded portion (12). The guide portion (24) is fitted into the opening (33) of the pile head (32) to rotate the screw hole (25) coaxially with the pile head (32). In the construction method of the solar cell module mount (1, 41) formed with such a configuration, the foundation pile (2) is driven into the ground (6, 46) in a substantially vertical direction. Then, the guide portion (24) is fitted into the opening (33) of the pile head (32) of the foundation pile (2), and the unevenness adjusting device (5, 45) is attached to the pile head (32). . Fixing portions (13, 13a) of the first members (11, 11a) of the unevenness adjustment tools (5, 45) attached to the pile heads (32) are attached to the frame components (3a, 3b). fixed. By rotating the flange portion (23), the screw portion (12) screwed into the rotated screw hole (25) is relatively rotated to adjust the position of the solar cell module (4, 44). do.

By configuring in this way, the unevenness adjustment range is greater than in the conventional case, and the unevenness adjustment can be easily performed even in the solar cell module stand after installation. As a result, the adjacent module surfaces of the solar cell modules mounted on the solar cell module stand are flush with each other, and the overall appearance of the solar cell module stand is improved and the scenery is friendly.

The present aspect has been described above based on the embodiments and modifications, but the above-described embodiments are intended to facilitate understanding of the present aspect, and do not limit the present aspect. This aspect may be modified and modified without departing from the spirit and scope of the claims, and this aspect includes equivalents thereof. Also, if the technical features are not described as essential in this specification, they can be deleted as appropriate.

REFERENCE SIGNS LIST 1 solar cell module stand 2 foundation pile 3 mounting frame 3a, 3b frame constituent member 4 solar cell module 5 unevenness adjustment tool 6 ground 11, 11a first member 12 screw portion 13, 13a fixing portion 21 second member 22 screw Receiving portion 23 Flange portion 24 Guide portion 25 Screw hole 26 Bolt hole 31 Bolt 32 Pile head 33 Opening 34 Bolt hole 35 Friction reduction member 41 Farming type solar cell module stand 42 Foundation pile 43 Mounting frame 43a, 43b Frame constituent member 44 Solar cell module 45 Unevenness adjustment tool 46 Ground

Claims (7)

Frame constituent members (3a, 3b) constituting a mounting frame on which a solar cell module (4, 44) is mounted, and foundation piles (2) driven substantially vertically into the ground (6, 46) An unevenness adjusting device (5, 45) for connecting the foundation pile (2) having an opening (33) in the pile head (32),
A first screw part (12) having a screw thread on its outer periphery and fixing parts (13, 13a) provided at the head of the screw part and fixed to the frame components (3a, 3b) members (11, 11a);
a threaded hole (25) into which the threaded portion (12) is screwed; a flange portion (23) for rotating the threaded hole (25) relative to the threaded portion (12); A second member (21 )When,
with
The guide part (24) has an outer diameter that can rotate along the inner diameter of the opening (33) of the pile head (32).
An unevenness adjustment tool (5, 45) characterized by: The unevenness adjusting device (5) according to claim 1, wherein the fixing part (13) is substantially U-shaped or planar. The unevenness adjusting device (5, 45) further includes:
A friction reducing member (35) disposed between the pile head (32) and the second member (21) so as to facilitate rotation of the second member (21) with respect to the pile head (32). )
An unevenness adjustment device (5, 45) according to claim 1, characterized in that it comprises: A surface of the inner diameter of the opening (33) of the pile head (32) and a surface of the outer diameter of the guide portion (24) are coated or surface-treated. An unevenness adjusting device (5, 45) according to 1. The unevenness adjustment tool (5, 45). A solar cell module mount (1, 41), wherein the unevenness adjusting device (5, 45) according to any one of claims 1 to 5 is attached to each of the pile heads (32). ). Frame constituent members (3a, 3b) constituting a mounting frame on which the solar cell module (4) is mounted, a foundation pile (2) driven into the ground (6, 46) in a substantially vertical direction, and a pile head ( 32) has an unevenness adjusting device (5, 45) for connecting the pile head (32) of the foundation pile (2) having an opening (33) and the frame component members (3a, 3b);
The unevenness adjusting instrument (5) is
A threaded portion (12) having a screw thread on its outer periphery, and fixing portions (13, 13a) provided on the head portion of the threaded portion (12) and fixed to the frame components (3a, 3b) a first member (11, 11a) having;
a threaded hole (25) into which the threaded portion (12) is screwed; a flange portion (23) for rotating the threaded hole (25) relative to the threaded portion (12); A second member (21 )When,
has
The guide part (24) has an outer diameter that can rotate along the inner diameter of the opening (33) of the pile head (32).
A method for constructing a solar cell module stand (1, 41), comprising:
Driving the foundation pile (2) into the ground (6) in a substantially vertical direction,
Fitting the guide part (24) into the opening (33) of the pile head (32) of the foundation pile (2) and attaching the unevenness adjusting device (5, 45) to the pile head (32),
Fixing portions (13, 13a) of the first members (11, 11a) of the unevenness adjusting device (5) attached to the pile head (32) are fixed to the frame constituent members (3a, 3b). ,
By rotating the flange portion (23), the screw portion (12) screwed into the rotated screw hole (25) is relatively rotated to adjust the position of the solar cell module (4). A construction method for a solar cell module stand (1, 41) characterized by:

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