JP2016073076A - Jig for installation of solar panel unit, and installation method for solar panel unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a jig for installation capable of easily aligning heights of solar panel units when installing the solar panel unit structured to be coupled with a pile that is driven into the ground.SOLUTION: The jig for installation of the solar panel unit includes: a through-hole 41b in which a strut 19 of the solar panel unit is inserted from an upper side; positioning parts 41c and 42 which are abutted to an upper end of a pile 20 to determine a position in the height direction; and mounting parts 41d and 43b for supporting a support member from a lower side in the state where the strut 19 is inserted into the through-hole 41b.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a solar panel unit installation jig and a solar panel unit installation method using the same.

  In a solar power generation system in which a plurality of solar panels are installed, a solar panel unit provided with an actuator and a solar panel unit not provided with an actuator are connected by a link mechanism, and a plurality of solar panels are formed by one actuator. (For example, refer to Patent Document 1).

  When such a link mechanism is employed, it is convenient to align the solar panel units at the same height. For this reason, in the example of Patent Document 1, a through hole through which laser light is transmitted is provided in the support supporting each solar panel unit, and the position of the support is determined so that the laser beam having a straight traveling property passes through each through hole. ing.

JP 2013-249616 A

  By the way, in a solar panel unit, it is possible to employ | adopt the structure which fastens a solar panel unit with a clamp later with respect to the pile previously installed in the ground. By adopting such a structure, when the solar panel unit is installed on the farmland, it can be easily moved or removed.

  However, when a fastening structure using such a clamp is adopted, the position adjustment (height adjustment) of the solar panel unit is required during fastening work, and installation work is not easy.

  This invention is made paying attention to said problem, and when installing the solar panel unit of the structure fastened with the pile driven into the ground, so that the height of a solar panel unit can be arranged easily. The purpose is to do.

In order to solve the above-described problems, the first invention provides a photovoltaic power generation panel (11), a support member (14) for swingably supporting the photovoltaic power generation panel (11), and the support member (14 In a jig for installing a solar panel unit comprising a post (19) fixed by a pile (20) and a fastening member (30) fixed to
A through hole (41b) into which the column (19) is inserted from above is formed,
Positioning part (41c, 42) that determines the position in the height direction by being abutted against the upper end of the pile (20),
In a state where the support column (19) is inserted into the through hole (41b), a mounting portion (41d, 43b) that supports the support member (14) from below;
It is provided with.

  In this configuration, when the solar panel unit is installed, the relative position in the height direction of the solar panel unit and the pile (20) is determined by placing the solar panel unit on the jig. Therefore, it becomes easy to adjust the position (height adjustment) of the solar panel unit during installation.

The second invention is the first invention, wherein
It has a halved structure that can be attached to and detached from the solar panel unit.

  In this configuration, the jig can be removed from the solar panel unit or the pile (20) by dividing the jig after installation.

The third invention is the first or second invention, wherein
The placement portion (41d, 43b) includes a rotation prevention portion (43a) for restricting rotation of the photovoltaic power generation panel (11) around the support column (19) by contacting the support member (14). It is characterized by.

  In this configuration, if the direction of the jig is determined in a predetermined direction, the position of the solar panel unit in the rotational direction is also determined thereby.

In addition, a fourth invention is any one of the first to third inventions,
The placement portion (41d, 43b) supports the support member (14) at a predetermined inclination angle.

  In this configuration, the inclination angle of the solar panel unit is determined by the jig.

The fifth invention is fixed to the solar power generation panel (11), the support member (14) for swingably supporting the solar power generation panel (11), and the support member (14). In the installation method of the solar panel unit comprising the pillar (19) fastened by the pile (20) driven into the ground and the fastening member (30),
A step of driving the plurality of piles (20) into the ground while aligning the height of the upper ends;
A positioning hole (41c, 42) that determines a position in the height direction by forming a through hole (41b) into which the column (19) is inserted from above and being abutted against the upper end of the pile (20). ) And a mounting part (41d, 43b) for supporting the support member (14) from below with the support post (19) inserted into the through hole (41b). And steps to
Setting the jig (40) so that the upper end of the pile (20) abuts the positioning part (41c, 42);
Inserting the support column (19) from above the through hole (41b) and placing the support member (14) to a position where the support member (14) is mounted on the mounting portion (41d, 43b);
Fastening the strut (19) and the pile (20) with the fastening member (30);
It is characterized by having.

  In this installation method, the relative position in the height direction of the solar panel unit and the pile (20) is determined by the jig (40).

  According to 1st invention, when installing the solar panel unit of the structure fastened with the pile driven into the ground, it becomes possible to arrange | equalize the height of a solar panel unit easily.

  Moreover, according to 2nd invention, a jig | tool can be collect | recovered easily after installation.

  Moreover, according to 3rd invention, it becomes possible to determine the direction of the rotation direction of a solar panel unit easily.

  Moreover, according to 4th invention, it becomes possible to determine the inclination-angle of a solar panel unit easily.

  Moreover, according to 5th invention, when installing the solar panel unit of the structure fastened with the pile driven into the ground, it becomes possible to arrange | equalize the height of a solar panel unit easily.

FIG. 1 shows a schematic configuration of a photovoltaic power generation system according to the embodiment. FIG. 2 is a side view of the first solar panel unit according to the embodiment. FIG. 3 is a perspective view of a jig used for installing the solar panel unit. FIG. 4 is a side view of the jig. FIG. 5 shows the usage state of the jig. FIG. 6 is a diagram for explaining the installation procedure of the solar panel unit.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

<< Embodiment of the Invention >>
In this embodiment, an example of a photovoltaic power generation system in which a solar panel unit provided with an actuator and a solar panel unit not provided with an actuator are connected by a link mechanism and a plurality of solar panels are driven by one actuator. Will be explained. This solar power generation system is installed on farmland such as a paddy field or a greenhouse.

<Overall system configuration>
FIG. 1 shows a schematic configuration of a photovoltaic power generation system (1) according to the embodiment. FIG. 2 is a side view of the first solar panel unit (10a) according to the embodiment. As shown in FIGS. 1 and 2, the photovoltaic power generation system (1) includes one first solar panel unit (10a) and a plurality of (two in the example of FIG. 1) second solar panel units ( 10b). Although not shown, the solar power generation system (1) is provided with a power conditioner that converts DC power generated by these solar panel units (10a, 10b) into AC power. .

  These solar panel units (10a, 10b) are arranged in a straight line in the east-west direction (details will be described later). The difference between the first solar panel unit (10a) and the second solar panel unit (10b) is whether or not an actuator unit (50) described later is included. The actuator unit (50) is provided in the first solar panel unit (10a), but is not provided in the second solar panel unit (10b). In the following description, when it is not necessary to distinguish between the first solar panel unit (10a) and the second solar panel unit (10b), a solar panel is provided with “10” as a reference symbol. This is expressed as unit (10).

<Solar panel unit>
Each solar panel unit (10) has a photovoltaic power generation panel (11) and a support frame (12).

  The solar power generation panel (11) is formed in a plate shape, and one surface is a sunlight receiving surface (11a). Each photovoltaic power generation panel (11) is disposed such that the light receiving surface (11a) is the upper surface, and receives sunlight on the light receiving surface (11a) to generate DC power. Two crosspieces (15a, 15b) are fixed to the back surface of the photovoltaic power generation panel (11). These crosspiece members (15a, 15b) are arranged in parallel to each other in a direction perpendicular to a rotation axis (S) described later.

  The support frame (12) rotatably supports the photovoltaic power generation panel (11). As shown in FIG. 2, the support frame (12) has two joint members (13) and a support member (14). The support member (14) is a member that supports the photovoltaic power generation panel (11), and is formed of a lip groove type rope (C type rope) or channel steel having a predetermined length. In this example, C-shaped steel is used so that the opening side is the upper side.

  The two joint members (13) are rotatably mounted near both ends of the support member (14) so as to be aligned on the same straight line, and are fixed to the crosspiece members (15a, 15b). Thereby, the photovoltaic power generation panel (11) can rotate around a predetermined rotation axis (S).

  A support (19) is fixed to the support member (14). This support | pillar (19) is fastened by the clamp (30) to the pile (20) previously driven into the ground. In this example, the column (19) is a cylindrical steel pipe having an outer diameter of about 48.6 mm. Moreover, the pile (20) is also a cylindrical steel pipe, and an outer diameter of 60.5 mm was used as an example.

  The clamp (30) of the present embodiment sandwiches the support (19) and the pile (20) arranged in parallel, and is fixed by a screw mechanism. For the clamp (30), various clamps such as a general-purpose clamp for fastening a building material can be employed. The adoption of the fastening structure with the clamp (30) facilitates the transfer and removal of the photovoltaic power generation system (1). The clamp (30) is an example of the fastening member of the present invention.

<Actuator unit>
As shown in FIG. 2, the actuator unit (50) has an actuator (51) and a transmission mechanism (53). The actuator (51) of this embodiment is a rotary pneumatic actuator, and rotates the output shaft (51a) by air pressure. The rotation angle of the output shaft (51a) can be controlled by controlling the air supply amount. The transmission mechanism (53) is specifically a crank mechanism, and swings the photovoltaic power generation panel (11) around the rotation axis (S) according to the rotation of the output shaft (51a). The configuration of the actuator (51) is an example, and is not limited to a rotary type, and is not limited to a pneumatic type.

<Link mechanism (60)>
A link mechanism (60) is connected to the solar panel unit (10), and the solar power generation panel (11) of each second solar panel unit (10b) is the sun of the first solar panel unit (10a). It is driven in synchronism with the operation of the photovoltaic panel (11).

  In this example, the link mechanism (60) includes a link member (17) and a connecting rod (61). As shown in FIG. 2, the link member (17) is formed of a plate-like member, and is fixed to the crosspiece member (15b). The tip of the link member (17) extends downward generally perpendicular to the photovoltaic power generation panel (11).

  The connecting rod (61) is a tubular member that connects the link members (17) to each other. Each connecting rod (61) is rotatably pin-connected near the lower end of the link member (17). In the first solar panel unit (10a), when the photovoltaic power generation panel (11) swings, the link member (17) swings around the rotation axis (S) together with the photovoltaic power generation panel (11), The connecting rod (61) is displaced in the east-west direction (see FIG. 1). As a result, the solar power generation panel (11) also swings in each second solar panel unit (10b).

<Installation status of solar panel unit>
As shown in FIG. 1, the solar panel units (10) are arranged in a straight line in the east-west direction, and the rotation axes (S) of the solar power generation panels (11) are parallel to each other. That is, the rotation axis (S) faces in the north-south direction. Moreover, each photovoltaic power generation panel (11) is inclined and supported by the support frame (12) so as to be higher toward the north side. The solar panel units (10) are configured to change the inclination angle of the solar power generation panels (11) in synchronization with each other by the link mechanism (60).

  As described above, in the photovoltaic power generation system (1), since the plurality of solar panel units (10) are connected by the connecting rod (61), the height between the solar panel units (10), more specifically, the link member. It is preferable that the heights of the pin connecting portions in (17) are uniform.

  In the present embodiment, a plurality of piles (20) are installed in advance such that the heights of the upper ends are aligned, and the heights of the solar panel units (10) are aligned based on the upper ends of the piles (20). In the present embodiment, the following installation jig is used in order to align the heights.

<Installation jig>
FIG. 3 is a perspective view of a jig (40) used for installing the solar panel unit (10), and FIG. 4 is a side view of the jig (40). FIG. 5 shows the usage state of the jig (40). The jig (40) is made of, for example, iron or resin, and includes a main body (41), a top plate (42), and a vertical plate (43) as shown in FIG.

  The main body (41) has a rectangular parallelepiped shape. A through hole (41b) and a pile insertion hole (41c) are formed in the main body (41). A support column (19) is inserted into the through hole (41b) (see FIG. 5). The through hole (41b) has an inner diameter slightly larger than the outer diameter of the support column (19), and the inner diameter dimension is set so that the support column (19) can be easily inserted.

  On the other hand, the pile insertion hole (41c) is a hole for inserting the pile (20) (see FIG. 5). The pile insertion hole (41c) is a circular through hole whose inner diameter is slightly larger than the outer diameter of the pile (20), and the inner diameter dimension is set so that the pile (20) can be easily inserted.

  Moreover, in this embodiment, the top plate part (42) is provided on the upper surface of the main body part (41) so as to close the pile insertion hole (41c) (see FIGS. 4 and 5). Therefore, when the pile (20) is put into the pile insertion hole (41c), the end of the pile (20) will abut against the top plate (42). That is, the position of the jig (40) in the height direction can be determined based on the height of the pile (20) by the top plate portion (42) being abutted against the upper end of the pile (20). The top plate portion (42) and the pile insertion hole (41c) constitute an example of the positioning portion of the present invention.

  The vertical plate portion (43) is a plate-like member and stands vertically on the top plate portion (42). The jig (40) includes an edge portion (43b) on the through hole (41b) side on the upper end surface of the vertical plate portion (43) and an edge portion on the through hole (41b) side on the upper surface of the main body portion (41). The support member (14) is placed in an inclined state at two locations (41d) to support the support member (14) from below. Generally, the position of the column (19) is determined so that the center of gravity of the solar panel unit (10) is near the center line of the column (19). The portions (41d, 43b) are positioned so as to sandwich the column (19) from each other (see FIG. 5). By doing so, the solar panel unit (10) can be supported in a balanced manner by the jig (40). The height of the vertical plate portion (43) (the difference in height between the edge portion (41d) and the edge portion (43b)) is set based on the inclination angle of the photovoltaic power generation panel (11) in the installed state. These edge portions (41d, 43b) are an example of the placement portion of the present invention.

  The vertical plate portion (43) is formed with two detent portions (43a). As shown in FIG. 3, the anti-rotation portion (43a) is a plate-like portion facing each other at the upper end of the vertical plate portion (43). The interval (W) between the two detent portions (43a) is set to be slightly larger than the width of the support member (14) (the width in the direction that becomes the east-west direction after installation). When the support member (14) is placed on the jig (40), even if the support member (14) tries to rotate around the support column (19), these detents (43a) are supported by the support member (14 ) To regulate its rotation.

  And as shown in FIG. 3, the jig | tool (40) can be divided into two division bodies in the division | segmentation surface (X). The dividing surface (X) is a plane including the center line of the through hole (41b) and the center line of the pile insertion hole (41c), and the jig (40) can be divided in the direction of the arrow in FIG. A plurality of bolt holes (41a) are formed in the main body (41) of the jig (40), and the divided parts of the jig (40) are fixed to each other by bolts passed through these bolt holes (41a). can do.

<Installation work>
In order to install each solar panel unit (10), first, a plurality of piles (20) are driven into the ground so that the heights of their upper ends are aligned. In order to align the heights of these piles (20), for example, all the piles (20) are provided with through-holes (20a) at the same position (see FIG. 2), and the laser is irradiated in the horizontal direction. It is only necessary to adjust the driving amount of the pile (20) so that passes through the through holes (20a) of all the piles (20). Of course, other methods can be used to align the height of the pile (20). For example, the level of pile (20) is checked while checking the height difference between the piles (20) with a level. It may be possible to adjust this.

-Fastening column (19) and pile (20)-
After installing the pile (20), the solar panel unit (10) and the pile (20) are fastened with a clamp (30). FIG. 6 is a diagram for explaining the installation procedure of the solar panel unit (10). In this figure, the example which fastens a 2nd solar panel unit (10b) and a pile (20) is shown.

  As shown in FIG. 6, the jig (40) is in a state in which the divided bodies are fastened with bolts (45). Next, the jig (40) is set on the upper end of the pile (20). Specifically, the pile (20) is inserted into the pile insertion hole (41c) until the upper end of the pile (20) hits the top plate part (42). At this time, the solar panel (11) is directed in the normal direction by appropriately rotating the jig (40) around the pile (20). In this example, the direction of the jig (40) is adjusted so that the end surface (A) (see FIG. 3) on the edge part (41d) side faces south. Thereby, a photovoltaic power generation panel (11) is installed so that the north side may become higher.

  Next, the solar panel unit (10) is placed on the jig (40). For this purpose, first, the support column (19) of the solar panel unit (10) is inserted into the through hole (41b) of the jig (40) from above the jig (40). Since the through hole (41b) is set to have an inner diameter slightly larger than the outer diameter of the support column (19), the support member (14) is placed on the two edge portions (41d, 43b) of the support column (19). Will get into. Then, a support | pillar (19) and a pile (20) are fastened with a clamp (30). In this example, two clamps (30) are used. After fastening these clamps (30), remove the bolts (45) and divide the jig (40) into two parts. From the solar panel unit (10) and the pile (20) to the jig (40) Remove.

  By performing the above operation for each solar panel unit (10), it is possible to easily align the heights of all the solar panel units (10). In addition, since the jig (40) has the non-rotating portion (43a), the orientation of each photovoltaic panel (11) can be obtained by aligning the orientation of the jig (40) as described above. Will also be available. In this example, the rotation axis (S) faces the north-south direction.

<Effect in this embodiment>
As described above, when the solar panel unit (10) is installed, the solar panel unit (10) and the pile (20) are placed in the height direction by placing the solar panel unit (10) on the jig (40). The relative position of is determined. Therefore, the position adjustment (height adjustment) of the solar panel unit (10) becomes easy at the time of installation. Thereby, it is possible to easily install the solar panel unit (10).

<< Other Embodiments >>
Note that the jig (40) is not necessarily divided. If the split structure is not used, the jig (40) may remain attached to the solar panel unit (10) or pile (20) after the solar panel unit (10) is installed. It is done. In this case, determine the shape of the jig (40) so that the solar power generation panel (11) and the support member (14) do not interfere with the jig (40) when the solar power generation panel (11) is in operation. deep. In the above embodiment, since the joint member (13) is sufficiently above the support member (14), the solar power generation panel (11) is rotated even when the jig (40) is attached. There is no possibility of interference between the photovoltaic panel (11) and the jig (40).

  Moreover, the installation number of the solar panel unit (10) which comprises a solar power generation system (1) is an illustration, for example, one unit of a 1st solar panel unit (10a) and a 2nd solar panel unit (10b) Each of the solar power generation systems (1) may be configured using three or more second solar panel units (10b) together with one first solar panel unit (10a). Good.

  The present invention is useful as a solar panel unit installation jig and a solar panel unit installation method using the same.

DESCRIPTION OF SYMBOLS 1 Photovoltaic power generation system 10 Photovoltaic panel unit 11 Photovoltaic power generation panel 14 Support member 19 Post 20 Pile 30 Fastening member 40 Jig 41b Through-hole 41c Pile insertion hole (positioning part)
42 Top plate (positioning part)
41d Edge part (mounting part)
43b Edge part (mounting part)

Claims (5)

A solar power generation panel (11), a support member (14) for swingably supporting the solar power generation panel (11), and a pile fixed to the support member (14) and driven into the ground ( 20) In a jig for installing a solar panel unit provided with a column (19) fastened by a fastening member (30),
A through hole (41b) into which the column (19) is inserted from above is formed,
Positioning part (41c, 42) that determines the position in the height direction by being abutted against the upper end of the pile (20),
In a state where the support column (19) is inserted into the through hole (41b), a mounting portion (41d, 43b) that supports the support member (14) from below;
A solar panel unit installation jig characterized by comprising: In claim 1,
A solar panel unit installation jig characterized by having a halved structure that can be attached to and detached from the solar panel unit. In claim 1 or claim 2,
The placement portion (41d, 43b) includes a rotation prevention portion (43a) for restricting rotation of the photovoltaic power generation panel (11) around the support column (19) by contacting the support member (14). A solar panel unit installation jig characterized by In any one of Claims 1-3,
The placement part (41d, 43b) supports the support member (14) at a predetermined inclination angle, and is a jig for installing a solar panel unit. A solar power generation panel (11), a support member (14) for swingably supporting the solar power generation panel (11), and a pile fixed to the support member (14) and driven into the ground ( 20) In the installation method of the solar panel unit provided with the support | pillar (19) fastened by the fastening member (30),
A step of driving the plurality of piles (20) into the ground while aligning the height of the upper ends;
A positioning hole (41c, 42) that determines a position in the height direction by forming a through hole (41b) into which the column (19) is inserted from above and being abutted against the upper end of the pile (20). ) And a mounting part (41d, 43b) for supporting the support member (14) from below with the support post (19) inserted into the through hole (41b). And steps to
Setting the jig (40) so that the upper end of the pile (20) abuts the positioning part (41c, 42);
Inserting the support column (19) from above the through hole (41b) and placing the support member (14) to a position where the support member (14) is mounted on the mounting portion (41d, 43b);
Fastening the strut (19) and the pile (20) with the fastening member (30);
A solar panel unit installation method characterized by comprising:

Images