JP2017131029A - Variable type photovoltaic panel installation base - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem in which photovoltaic panels are basically used for a long time at certain places and are strongly made mainly considering the environmental conditions such as wind pressure resistance and it is difficult to frequently install and move repeatedly.MEANS FOR SOLVING THE PROBLEM: The photovoltaic panel base stacked at a time of movement and kept as minimum as possible is configured to expand a range of receiving solar light and increase a generating capacity by sliding at a moving destination. In order to further increase power generation efficiency, an angle is configured to be directed to the sun. As a result, it is possible to easily move and install the photovoltaic power generation panels which have been difficult to move so far, and it is possible to increase power generation efficiency.SELECTED DRAWING: Figure 3

Description

  The present invention is an installation base for a photovoltaic power generation panel that can be easily moved and installed.

  Conventional solar power generation panels are made on the premise that they are fixed once in place, and there are some things that can change the direction and angle, but basically only one place It is made.

The reason is considered to be that solar panels are basically used for a long time in a certain place.
For this purpose, the pedestal used for installation is mainly made in consideration of environmental conditions such as wind pressure resistance.
It is difficult to repeat installation and movement frequently because it is made firmly.

  Items that are assumed to be carried in the past are limited to those that have a small installation area and therefore a very small amount of power generation.

JP2015-231325A

  Conventional solar power panels are made on the premise that they are fixed once, and there are things that can change the direction and angle, but basically in one place It is made to stay.

  For this reason, there is no installation stand for solar power generation panels that can be moved to ensure a certain amount of power generation.

  The present invention is a stand for a photovoltaic power generation panel for the purpose of realizing installation by movement and simple work.

  The movable photovoltaic power generation panel installation stand of the present invention has a plurality of photovoltaic power generation panels arranged on the same plane having the same outer dimensions, and four sides of the photovoltaic power generation panel for fixing the same. A plurality of gantry frames composed of the arranged frames, and a slide mechanism that slides the photovoltaic power generation panel attached to the frame in a direction parallel to the surface thereof, the photovoltaic power generation The feature is that the light receiving area of the entire photovoltaic power generation panel changes depending on the slide position of the panel.

  In order to achieve the above-mentioned purpose, it is structured such that it can be received in a large area when installed while being stored small during movement.

  Multiple photovoltaic panels that are stacked when moving are connected by slide rails and slide rollers, and the installed photovoltaic panel frame slides during installation to increase the light receiving area. It was set as the structure which can do.

  In addition, the angle can be adjusted toward the sun during use.

  Installation of slide and variable angle solar panels allows quick and simple operation without the need for tools for movement and installation.

  Further, in a natural environment such as a storm, it can be stored in a form that is not easily affected by rain or wind so that the equipment itself is not easily damaged.

The upper surface figure (sunlight panel light-receiving surface) at the time of storage of the mount frame of this invention, and the upper side figure at the time of expansion | deployment. The figure which looked at the time of the storage, deployment, and installation (elevation angle 10 degrees, 20 degrees, and 30 degrees) from the side. The figure which looked at the time of the storage, the time of expansion | deployment, and the installation from the diagonal upper surface. The figure which looked from the diagonal upper surface when the number of the panel which slides and overlaps is increased by 1 sheet compared with FIG. Partial sectional detail view of the sliding mechanism perpendicular to the sliding direction Partial sectional detail view of the sliding mechanism parallel to the sliding direction

  Hereinafter, embodiments of the present invention will be described with reference to FIGS.

FIG. 1A is a plan view of a photovoltaic power generation panel 2 and a frame frame (support frame upper frame) 1 for holding it on the same plane, as viewed from the light receiving surface side during storage. is there.
FIG. 1B is a plan view seen from the sunlight receiving surface when the frame (support frame upper frame) 1 and the frame (support frame lower frame) 3 are slid and expanded.

FIG. 2A is a view seen from a side surface orthogonal to the light receiving surface of the photovoltaic power generation panel 2 and orthogonal to the sliding direction.
The gantry frame (support frame upper frame) 1 has the same outer dimensions as the gantry frame (support frame lower frame) 3.
The gantry frame (base frame) 10 has the same outer dimensions as the support frames 1 and 3, and is configured so that it can be accommodated in a plane size that is the size of the gantry frame when stored.
The gantry frame (support frame upper frame) 1 has a mechanism that slides parallel to the gantry frame (support frame lower frame) 3.
When the gantry frame (support frame upper frame) 1 is slid and unfolded, the light receiving area of the photovoltaic power generation panel expands to 1.5 times that of the storage. Fig. 2 (b)
The gantry frame (pedestal frame) 10 and the gantry frame (support frame) 3 are pivotally supported by a rotating shaft (hinge) 5 so that the angle toward the sun is increased in order to increase the power generation efficiency of the solar panel. Can be installed.
An elevation angle adjusting member 4 is attached to a side surface orthogonal to the sliding direction of the gantry frame (support frame lower frame) 3 and is fixed and stored by an elevation angle holding member fastener (for storage) 14 during storage.
On the side surface perpendicular to the sliding direction of the gantry frame (pedestal frame) 10, there are an elevation angle holding member fastener (10 degrees) 11, an elevation angle holding member fastener (20 degrees) 12, and an elevation angle holding member fastener (30 degrees) 13. By attaching the elevation angle adjustment member 4 to each of the elevation angle adjustment member fasteners 11, 12, and 13, the frame frames 1 and 3 are adjusted so as to be fixed at a fixed angle.
FIG. 2 (c) is a view when the elevation angle holding member 4 is fixed to the elevation angle holding member fastener (10 degrees) 11. At this time, the gantry frame (support frame upper frame) 1 and the gantry frame (support frame) The lower frame 3 and the solar power generation panel 2 attached to the above are fixed at an angle of 10 degrees from the time of storage.
FIG. 2 (d) is a view when the elevation angle holding member 4 is fixed to the elevation angle holding member fastener (20 degrees) 12. At this time, the gantry frame (support frame upper frame) 1 and the gantry frame (support frame) The lower frame 3 and the solar power generation panel 2 attached to the above are fixed at an angle of 20 degrees from the time of storage.
FIG. 2 (e) is a view when the elevation angle holding member 4 is fixed to the elevation angle holding member fastener (30 degrees) 13. At this time, the gantry frame (support frame upper frame) 1 and the gantry frame (support frame) Lower frame 3 and the photovoltaic power generation panel 2 attached to the above are fixed at an angle of 30 degrees from the time of storage.

FIG. 3A is a perspective view from obliquely above the light receiving surface during storage. The gantry frame (support frame upper frame) 1, the gantry frame (support frame lower frame) 3, and the gantry frame (base frame) 10 have the same outer dimensions, and are below the horizontal projection area of the gantry frame (support frame upper frame) 1. It is a storage form that fits compactly.
FIG. 3B is a perspective view from obliquely above the light receiving surface during deployment. The gantry frame (support frame upper frame) 1 slides parallel to the gantry frame (support frame lower frame) 3 in the horizontal direction so that the light receiving area of the entire photovoltaic power generation panel 2 in the present invention is increased by 1.5 times. It is set to.
FIG.3 (c) is a perspective view from the diagonally upper direction of the light-receiving surface at the time of installation. The gantry frame (support frame lower frame) 3 is pivotally supported by a gantry frame (base frame) 10 and a rotation shaft (hinge) 5. The gantry frame (support frame middle frame) 6 and the gantry frame (support frame lower frame) 3 are adjusted by the elevation angle holding member 4 so as to be fixed.

FIG. 4 (a) shows the present invention when the frame shown in FIG. 3 is increased from two in the above to three, and the light receiving surface is oblique at the time of storage in the movable solar power panel installation frame. It is a perspective view from the top. The gantry frame (support frame upper frame) 1, the gantry frame (support frame lower frame) 3, the gantry frame (support frame middle frame) 6, and the gantry frame (base frame) 10 have the same external dimensions. This is a storage configuration that fits compactly under the horizontal projection area of 1 frame upper frame).
FIG. 4 (b) shows the present invention when the frame shown in FIG. 3 is increased from two in the above to three, and the light receiving surface is slanted when deployed in the movable solar power panel installation frame. It is a perspective view from the top. When the gantry frame (support frame upper frame) 1 slides in parallel in the horizontal direction from the gantry frame (support frame middle frame) 6, and further slides in parallel in the horizontal direction from the gantry frame (support frame lower frame) 3. The light receiving area of the entire photovoltaic power generation panel 2 in the present invention is set to be doubled.
FIG. 4 (c) shows the present invention when the frame shown in FIG. 3 is increased from two in the above to three, and the light receiving surface is oblique at the time of installation in the movable solar power panel installation frame. It is a perspective view from the top. The gantry frame (support frame lower frame) 3 is pivotally supported by a gantry frame (base frame) 10 and a rotation shaft (hinge) 5. The installation angle of the gantry frame (support frame middle frame) 6 and the gantry frame (support frame lower frame) 3 is adjusted by the elevation angle holding member 4 so as to be fixed.
By increasing the number of panels in this way, the area of each stacked panel can be increased by 0.5 times the original panel.

FIG. 5A is a detailed cross-sectional view perpendicular to the slide direction, showing a joint portion between the gantry frame (support frame upper frame) 1 and the gantry frame (support frame lower frame) 3.
A slide rail 8, the position of which is adjusted by a spacer 7, is attached to the gantry frame (support frame upper frame) 1, and a slide roller 9 that moves inside the slide rail 8 is provided.
The slide roller 9 is connected to the gantry frame (support frame lower frame) 3 by a slide mounting bolt 16 and a slide mounting nut 17.
The cradle frame (support frame lower frame) 3 is stored while being overlapped with the gantry frame (pedestal frame) 10 with the cushion rubber 15 sandwiched between the frames.
FIG. 5B is a detailed cross-sectional view orthogonal to the sliding direction when the number of frame frames is increased from two to three in FIG. 5A.
A slide rail 8 whose position is adjusted by a spacer 7 is attached to the gantry frame (support frame upper frame) 1, and a movable slide roller 9 is provided inside the slide rail 8.
The slide roller 9 is connected to a gantry frame (support frame middle frame) 6 by a slide mounting bolt 16 and a slide mounting nut 17.
A slide rail 8, the position of which is adjusted by a spacer 7, is attached to the gantry frame (support frame middle frame) 6, and a slide roller 9 that moves inside the slide rail 8 is provided.
The slide roller 9 is connected to the gantry frame (support frame lower frame) 3 by a slide mounting bolt 16 and a slide mounting nut 17.
The cradle frame (support frame lower frame) 3 is stored while being overlapped with the gantry frame (pedestal frame) 10 with the cushion rubber 15 sandwiched between the frames.

FIG. 6A is a detailed cross-sectional view parallel to the slide direction, showing a joint portion between the gantry frame (support frame upper frame) 1 and the gantry frame (support frame lower frame) 3.
A slide rail 8 whose position is adjusted by a spacer 7 is attached to the gantry frame (support frame upper frame) 1, and a movable slide roller 9 is provided inside the slide rail 8.
The slide roller 9 is connected to the gantry frame (support frame lower frame) 3 by a slide mounting bolt 16 and a slide mounting nut 17.
The cradle frame (support frame lower frame) 3 is stored while being overlapped with the gantry frame (pedestal frame) 10 with the rotation shaft (hinge) 5 and the cushion rubber 15 being stored therebetween, when stored.
FIG. 6 (b) is a detailed cross-sectional view at the time of installation of FIG. 6 (a).
The inside of the slide rail 8, which is attached to the gantry frame (support frame upper frame) 1 and whose position is adjusted by the spacer 7, is attached to the gantry frame (support frame lower frame) 3, slide mounting bolts 16 and slide mounting nuts 17. When the slide roller 9 attached by the slide is slid, it is adjusted so that the photovoltaic power generation panel 2 attached to the gantry frame (support frame lower frame) 3 can receive light.
In addition, the gantry frame (support frame lower frame) 3 is pivotally supported by a gantry frame (pedestal frame) 10 and a rotation shaft 5, and is angled toward the sun to increase the power generation efficiency of the solar panel. Can be installed with

1 Mounting frame (support frame upper frame)
2 Solar power generation panel
3 Mounting frame (lower frame of support frame)
4 Elevation angle adjustment member
5 Rotating shaft (hinge)
6 Mounting frame (support frame middle frame)
7 Spacer
8 Slide rail
9 Slide roller
10 Mounting frame (pedestal frame)
11 Elevation angle retaining member (10 degrees)
12 Elevation angle retaining member fastener (20 degrees)
13 Elevation angle retaining member fastener (30 degrees)
14 Elevation angle retaining member fastener (for storage)
15 Cushion rubber when stored
16 Slide mounting bolt
17 Slide mounting nut

Claims (2)

  A plurality of gantry frames composed of a plurality of photovoltaic panels arranged on the same plane having the same outer dimensions and frames arranged on four sides of the photovoltaic panels to fix the panels. And a slide mechanism that slides the photovoltaic power generation panel attached to the frame in a direction parallel to the surface thereof, and the light receiving area of the entire photovoltaic power generation panel depending on the slide position of the photovoltaic power generation panel Movable photovoltaic power generation panel installation stand characterized by changing. The lowermost pedestal frame is pivotally supported by a rotation shaft and is supported between a support frame attached with a photovoltaic power generation panel, and the support frame and the lowermost pedestal frame. The movable solar power generation panel installation stand according to claim 1, further comprising a holding member that holds the frame to which the solar panel is attached at a predetermined angle.