KR101629388B1 - Apparatus for controlling an height of solar energy receiving pannel - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar energy collector plate height adjusting device, A strut that is height-adjustably inserted into the connecting member; A solar energy collecting plate connected to the strut and having a height adjusted according to a height of the strut; A first side support plate provided on an upper surface of the base plate and supporting one side of the strut, and a second side support plate provided on the upper side of the base plate, And a second side support plate provided on an upper surface of the base plate at an interval from the first side support plate and supporting the lower portion of the support column together with the first side support plate, As shown in FIG. According to the present invention, the height of the solar cell module can be adjusted, and it is easy to manufacture and install.

Description

[0001] APPARATUS FOR CONTROLLING AN HEIGHT OF SOLAR ENERGY RECEIVING PANEL [0002]

The present invention relates to a solar energy collector plate height adjusting device.

The photovoltaic system converts the sun's light energy into electrical energy to produce electricity. A photovoltaic power generation system is a collection of solar cell modules connected in series or in parallel with a plurality of solar cell modules (plates), and the solar cell module is made up of cells of the smallest unit to generate electricity by photoelectric effect, They are connected in parallel.

In another form of the photovoltaic power generation system, a plurality of condenser plates in a collecting tower equipped with a steam turbine generator reflects the infrared rays of solar energy to a collecting tower, and the steam turbine generator is operated by energy collected in the collecting tower, Produce.

On the other hand, a plurality of heat collecting plates are provided, and heat energy is collected by collecting solar energy and heat from the heat collecting plates, thereby producing hot water.

Hereinafter, the solar battery module collecting the solar energy, the light collecting plate and the heat collecting plate will be collectively referred to as a solar collecting plate, and the solar battery module will be described as an example of a solar collecting plate.

Photovoltaic systems are generally installed onshore, where the solar modules are supported by a module support structure mounted onshore. It is efficient for the solar cell modules supported and arranged by the module support structures to be located on the same plane.

Generally, the concrete foundation blocks with anchor bolts protruding from the ground constructed when the solar power generation system is constructed are installed in a plurality of columns and the support shaft is connected to the anchor bolts of the concrete foundation block. A support frame is connected to the support shafts and the solar cell module having a square area is fixed to the support frame. An angle adjusting device for adjusting the angle of the solar cell module is provided on the supporting shaft and the supporting frame depending on the place where the solar power generation system is installed. The support shafts and the support frame constitute the module support structure.

Korean Unexamined Utility Model Publication No. 2009-0009732 (published on September 29, 2009) (hereinafter referred to as prior art) discloses a unit solar photovoltaic generation system equipped with an angle adjusting device.

In the prior art, a concrete foundation block having anchor bolts is disposed at intervals and a frame (support shaft) is coupled to a concrete foundation block, and a flange portion is provided at a lower end of the frame so that the anchor bolts of the concrete foundation block pass through the flange portion A nut is fastened to each of the anchor bolts, the frame is coupled to the concrete base block, the support frame is coupled to the frame, and the solar panel part (solar cell module) is mounted on the support. That is, the frames and the supports constitute a module supporting structure to support the solar panel part.

However, in the prior art, when the solar power generation system is installed on a hill or a flat ground, the height of the module support structure is not uniformed when the concrete foundation block installed on the module support structure is settled or the height of the concrete foundation blocks is not uniform, (Solar cell module) is bent or a step is generated. Also, in the prior art, the solar electron plate (solar cell module) is bent or a step is generated even when a machining dimensional error is generated for each length of the frames coupled to the concrete base block. If warping of the solar panel part occurs or a level difference occurs, the damage of the solar panel part occurs and the power generation efficiency of the solar panel part is lowered.

The frame of the prior art is composed of a flange portion, a support portion, and rib plate portions connecting the flange portion and the support portion. The flange portion is welded to the support portion and the rib plate portions are connected to the support portion and the flange portion It is easy to cause corrosion in the welded portion of the frame, and in order to prevent the corrosion, the entire frame needs to be plated, which is time and costly.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a height adjustable solar energy collector plate height adjustment device for a solar energy collection plate.

Another object of the present invention is to provide a solar energy collector height regulating device that is simple to manufacture and install.

In order to achieve the object of the present invention, there is provided a connector comprising: a connecting member coupled to a base member; A strut that is height-adjustably inserted into the connecting member; A solar energy collecting plate connected to the strut and having a height adjusted according to a height of the strut; A first side support plate provided on an upper surface of the base plate and supporting one side of the strut, and a second side support plate provided on the upper side of the base plate, And a second side support plate provided on an upper surface of the base plate at an interval from the first side support plate and supporting the lower portion of the support column together with the first side support plate, The solar energy collector plate height adjusting device according to claim 1,

The first and second side support plates are respectively formed in a diagonal shape and have a bent support plate portion supporting one side of the support and penetrating the fastening unit, a front reinforcing plate portion bent and extended at one end of the bent support plate portion, And a rear reinforcing plate portion bent and extended at the other end of the bent support plate portion.

It is preferable that the horizontal cross-sectional shape of the support inserted between the bent support plate of the first side support plate and the bent support plate of the second side support plate is a square or H type.

The first and second side support plates are each formed in a curved shape and have a curved support plate portion supporting one of the support pillars and passing through the fastening unit, a front reinforcement plate portion bent and extended at one end of the curved support plate portion, And the other reinforcing plate portion of the curved supporting plate portion may be extended to the other side.

The horizontal cross-sectional shape of the support inserted between the curved support plate of the first side support plate and the curved support plate of the second side support plate is preferably circular.

Preferably, the front reinforcing plate portion and the rear reinforcing plate portion of the first and second side support plates are positioned in the front-rear direction of the solar energy collecting plate.

It is preferable that an interval between the upper ends of the bent support plates of the first and second side support plates is larger than a width of the support when the fastening unit is fastened and is equal to the width of the support and without fastening the fastening unit.

Preferably, the solar energy collecting plate is one of a solar cell module, a condenser plate, or an heat collecting plate.

The present invention can adjust the height of the pillar, so that when the length of the pillar is short or long due to an error in the height of the concrete foundation block or a machining dimensional error with respect to the length of the pillar, When the concrete foundation block sinks due to the subsidence after the photovoltaic system is installed, the heights of the solar energy collecting plates (solar cell modules) can be maintained uniform by raising the height of the pillar.

According to the present invention, the first and second side support plates of the connecting member, to which the lower end of the strut is inserted, are spaced apart from each other, and the front and rear reinforcing plate portions of the first and second side support plates are connected to the support. The wind direction acts on the front and rear surfaces of the solar energy collecting plate so as to firmly support the strut when the force is transmitted to the strut, and the open portion of the strut, the first and second side supporting plates It is possible to prevent the water generated by the condensation due to the temperature difference from being easily discharged and the corrosion to occur.

In addition, since the connecting member and the strut are made to be separated from each other, since the connecting member and the strut are separated from each other, the base plate constituting the connecting member and the first and second side supporting plates are welded to each other. . In addition, since the component parts are small in size, they are easily transported, and the support is inserted into the connecting member in the field and the height of the support is adjusted to fasten the fastening unit.

In addition, since the connecting member and the strut are made to be separated from each other, the present invention excludes the welding operation on the strut, so that the material of the strut can be variously selected and the tolerance range with respect to the length of the strut can be increased. It can be applied variously according to the conditions.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view of a unit solar photovoltaic generation system having an embodiment of a solar energy collector height regulating device according to the present invention;
FIG. 2 is a perspective view of a solar energy collector plate height adjusting apparatus according to an embodiment of the present invention,
3 is a perspective view showing a connecting member constituting an embodiment of a solar energy collector plate height adjusting device according to the present invention,
FIG. 4 is a perspective view explaining another embodiment of a connection member and a strut constituting an embodiment of the apparatus for adjusting the height of a solar energy collector plate according to the present invention, FIG.
FIG. 5 is a perspective view showing another embodiment of a connecting member constituting an embodiment of the apparatus for adjusting the height of a solar energy collector plate according to the present invention,
FIG. 6 is a front view showing a height adjustment state of the solar energy collection plate height adjusting device according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a solar energy collector height adjusting device according to the present invention will be described with reference to the accompanying drawings.

1 is a side view of a unit photovoltaic generation system having an embodiment of a solar energy collector height regulating device according to the present invention. FIG. 2 is a perspective view explaining an embodiment of a solar energy collector height regulating device according to the present invention.

1 and 2, a unit solar photovoltaic generation system having a temporal example of a solar energy collector height adjusting device according to the present invention includes a solar battery module M for generating electric power, A module supporting structure F supporting the module support structure M and a concrete base block 10 supporting the module supporting structure F, As shown in FIG. The concrete foundation block 10 is provided with anchor bolts 11 on its upper surface.

One embodiment of the apparatus for adjusting the height of a solar energy collector plate according to the present invention includes a connecting member 100, a strut 200, and a fastening unit 300.

The connecting member 100 is coupled to the anchor bolts 11 of the concrete foundation block 10 and the nuts 12 are fastened to the anchor bolts 11 respectively. The concrete foundation block 10 provided with the anchor bolts 11 corresponds to a foundation member. In addition to the concrete foundation block 10, the base member may be a long lined structure such as a soundproof wall, a guard rail, a fence, or a rockfall prevention net.

2 and 3, the connecting member 100 includes a base plate 110 coupled to the base member 110, and a plurality of first supporting members 110, which are provided on the upper surface of the base plate 110 and support one side of the supporting pillars 200, A second side supporting plate 120 and a second side supporting plate 120 disposed on the upper surface of the base plate 110 at an interval from the first side supporting plate 120 and supporting the lower portion of the strut 200 together with the first side supporting plate 120, (130). The base plate 110 is preferably rectangular. Holes 111 through which the anchor bolts 11 are respectively inserted into four corner portions of the base plate 110 are provided. The base plate 110 may be embodied in various shapes.

Each of the first side support plates 120 is formed in a diagonal shape and has a bent support plate portion 121 for supporting one side of the support pillars 200 and through which the fastening unit 300 is inserted A front reinforcing plate portion 122 bent at one end of the bent support plate portion 121 and a rear reinforcing plate portion 123 bent and extended at the other end of the bent support plate portion 121; The bent-type support plate 121 is formed in a diagonal shape, and therefore has a middle plate and two side plates connected to both ends of the middle plate. And the fastening unit 300 may be passed through the long hole 124. [ The front reinforcing plate portion 122 and the rear reinforcing plate portion 123 are preferably bent at 90 degree angles to both side plates of the bent support plate portion 121, respectively. It is preferable that the front reinforcing plate portion 122 and the rear reinforcing plate portion 123 are located on the same line. The lower side length of the front side reinforcing plate portion 122 and the rear side reinforcing plate portion 123 of the first side support plate 120 is preferably longer than the upper side length. The first side support plate 120 may be formed by bending a plate having a uniform width into a plurality of stages to form the bent support plate 121, the front reinforcing plate 122, and the rear reinforcing plate 123.

Each of the second side support plates 130 is formed in a diagonal shape so as to support one side of the struts 200 and has a bent support plate portion 131 through which the fastening unit 300 passes A front reinforcing plate portion 132 which is bent at one end portion of the bent support plate portion 131 and a rear reinforcing plate portion 133 which is bent and extended at the other end portion of the bent support plate portion 131; The bending type support plate 131 is formed in a diagonal shape and therefore has a middle plate and two side plates connected to both ends of the middle plate. It is preferable that the fastening unit 300 is passed through the long hole 134. [ It is preferable that the front reinforcing plate portion 132 and the rear reinforcing plate portion 133 are respectively bent at 90 degrees to both side plates of the bent support plate portion 131. [ It is preferable that the front reinforcing plate portion 132 and the rear reinforcing plate portion 133 are located on the same line. The lower side length of the front side reinforcing plate portion 132 and the rear side reinforcing plate portion 133 of the second side support plate 130 is preferably longer than the upper side length. The second side support plate 130 may be formed by bending a plate having a uniform width in multiple stages to form the bent support plate 131, the front reinforcing plate 132, and the rear reinforcing plate 133.

The first side support plate 120 and the second side support plate 130 may be formed in the same shape and size. The first side support plate 120 and the second side support plate 130 are spaced apart from each other.

The front reinforcing plate portion 122 and the rear reinforcing plate portion 123 of the first side support plate 120 are spaced apart from the front reinforcing plate portion 132 and the rear reinforcing plate portion 133 of the second side support plate 130 .

The spacing between the two side plates in the bent support plates 121 and 131 of the first and second side support plates 120 and 130 is defined as a length interval a, The interval between the middle plate of the first side plate 121 and the middle plate of the bent support plate 131 of the second side plate 130 is referred to as a width spacing b. It is preferable that the length interval a is larger than the width interval b. The length interval a and the width interval b may be the same.

The pillar 200 is inserted into the connecting member 100 in a height-adjustable manner, and the solar cell module M is connected. In addition, a light collecting plate and a heat collecting plate may be connected to the upper part of the support 200 in addition to the solar cell module. In one embodiment of the pillars 200, the pillars 200 preferably have a rectangular cross-sectional shape in the transverse section with respect to the longitudinal direction and are rectangular. Or may be a square pipe having a square cross-sectional shape in the transverse direction with respect to the longitudinal direction of the pillars 200. Further, it may be an H-shaped steel having a H-shaped cross-sectional shape in the transverse direction with respect to the longitudinal direction of the pillars 200.

One end of the support 200 is inserted between the bendable support plate 121 of the first side support plate 120 of the connection member 100 and the bendable support plate 131 of the second side support plate 130.

The width of the column 200 is preferably slightly smaller than the width b of the first and second side support plates 120 and 130. It is preferable that the width b of the first and second side support plates 120 and 130 has an elastic force and is narrowed by fastening the fastening unit 300. A plurality of through holes 201 are formed in a line in a vertical direction on the ends of the pillars 200 located between the bent support plates 121 and 131 of the first and second side support plates 120 and 130 of the connection member 100. [ Are preferably provided. A plurality of through holes (201) are formed at positions facing the slots (124) and (134). The through holes (201) formed in the column (200) penetrate both sides of the column (200). The material of the pillars 200 is preferably the same as the material of the connecting member 100. The material of the struts 200 may be different from the material of the connecting member 100. The material of the support 200 may be a non-metallic material such as fiber-reinforced plastic, wood, as well as metallic materials such as general steel, zinc-plated steel, alloy steel and aluminum.

A support frame is connected to an upper portion of the support 200 and a solar cell module M is mounted on the support frame. It is preferable that the directions of the front reinforcing plate portions 122 and 132 and the rear reinforcing plate portions 123 and 133 of the first and second side support plates 120 and 130 are positioned in the front and rear direction of the solar cell module M .

As shown in FIGS. 4 and 5, the first and second side support plates 120 'and 130' of the connection member 100 may be formed as a pair of the first and second side support plates 120 and 130, Shaped support plate portions 125 and 135 which are formed in curved shapes and support one side of the strut 200 'and through which the fastening unit 300 is inserted, curved support plate portions 125 and 135' And a rear reinforcing plate portion 123 and 133 which are bent and extended at the other end of the curved supporting plate portions 125 and 135. The rear reinforcing plate portions 123 and 133 are bent at a predetermined angle. It is preferable that elongated holes 126 and 136 having a length in the vertical direction are provided in the middle portion of the curved support plate portions 125 and 135 so that the fastening unit 300 is passed through the long holes 126 and 136 . It is preferable that the front reinforcing plate portions 122 and 132 and the rear reinforcing plate portions 123 and 133 are located on the same line. It is preferable that the lower side lengths of the front side reinforcing plate portions 122 and 132 and the rear side reinforcing plate portions 123 and 133 of the first and second side support plates 120 'and 130' are longer than the upper side length. The first and second side support plates 120'and 130'bend the curved plates 125, 135, the front reinforcing plate portions 122, 132, It is preferable that the plate portions 123 and 133 are formed.

The first side support plate 120 'and the second side support plate 130' are not connected to each other but are spaced apart from each other.

The front reinforcing plate portion 122 and the rear reinforcing plate portion 123 of the first side support plate 120 'are spaced apart from the front reinforcing plate portion 132 and the rear reinforcing plate portion 133 of the second side support plate 130' It is preferable to be placed side by side.

In another embodiment of the post 200, the post 200 'is preferably a circular tube having a circular cross-sectional shape in the longitudinal direction. One end of the support 200 'is positioned between the curved support plate 125 of the first side support plate 120' of the connection member 100 and the curved support plate 135 of the second side support plate 130 ' .

The inner diameter of the curved support plate 125 of the first side support plate 120 and the curved support plate 135 of the second side support plate 130 is preferably larger than the outer diameter of the support 200 ' It is preferable that the fastening unit 300 is fastened to the first and second side support plates 120 'and 130', thereby having elasticity and narrowing. A plurality of through holes are formed in the vertical direction in a direction perpendicular to the end of the struts 200 'positioned between the curved support plates 125 and 135 of the first and second side support plates 120' and 130 ' Holes 202 are preferably provided. The plurality of through holes 202 are formed at positions facing the slots 126 and 136. The through holes 202 formed in the pillar 200 'pass through the pillar 200'.

The material of the support 200 'is preferably the same as the material of the connecting member 100. The material of the strut 200 'may be different from the material of the connecting member 100. The material of the support 200 'may be a non-metallic material such as fiber reinforced plastic, wood, as well as metallic materials such as general steel, zinc-plated steel, alloy steel and aluminum.

The fastening unit 300 is preferably a bolt 310 and a nut 320. The fastening unit 300 may be variously applied to rivets and the like.

A support frame is connected to an upper portion of the support 200 and a solar cell module M is mounted on the support frame.

The operation and effect of the apparatus for adjusting the height of the solar collector plate according to the present invention will be described as follows. Hereinafter, the case where the solar energy collecting plate is a solar cell module will be described.

First, the concrete foundation block 10 having the anchor bolts 11 is installed by placing the concrete on the flat or hill mountain where the solar power generation system will be installed. The connecting member 100 is coupled to the concrete foundation block 10 such that the anchor bolts 11 of the concrete foundation block 10 are respectively inserted into the through holes 111 of the base plate 110 of the connection member 100 And the nut 12 is fastened to the anchor bolts 11, respectively. 6, one end of the strut 200 is inserted between the bent support plates 121 and 131 of the first and second side support plates 120 and 130 of the connection member 100 . The bolts 310 of the fastening unit 300 are inserted into the through holes 201 of the support 200 and the slots 124 of the connecting member 100 and the bolts 310 are fastened with the nuts 320 After the coupling, the height of the strut 200 is adjusted and the nut 200 is fastened to the connecting member 100 by tightening the nut 320. The first and second side support plates 120 and 130 of the connection member 100 are elastically biased by tightening the nut 310 of the fastening unit 300 so that the gap between the first and second side support plates 120 and 130 is reduced, 200 are fixedly coupled to the connecting member 100.

On the other hand, when the first and second side supporting plates of the connecting member are different from the supporting pillars, one end of the supporting pillars 200 'is connected to the curved surface of the first and second side supporting plates 120' Shaped support plates 125 and 135 and the bolts 310 of the fastening unit 300 are inserted into the through holes 124 and 134 of the connecting member 100 and the through holes And the nut 320 is coupled to the bolt 310. The height of the support 200 is adjusted and the nut 200 is fastened to the support member 100 by fastening the nut 320. [ The first and second side support plates 120 'and 130' of the connection member 100 are elastically biased by tightening the nut 320 of the fastening unit 300 so that the spacing is narrowed to press the support 200 ' So that the post 200 'is fixedly coupled to the connecting member 100. The lower end of the support 200 'is supported by the first and second side support plates 120' and 130 'of the connection member 100 and is fastened and tightly coupled by the fastening unit 300.

A support frame is connected to the upper ends of the supports 200 and 200 ', and the solar cell module M is mounted on the support frame. At this time, the solar cell module (plate) M is inclined and the front and rear directions of the solar cell module (plate) M are aligned with the first and second side support plates 120 ', 130' 132, 133 of the front and rear reinforcing plate portions 122, 123, 132, 133 of the front and rear reinforcing plates 120, 130, respectively.

When a part of the concrete foundation blocks 10 is settled, the tightening unit 300 fastening the connecting member 100 and the pillars 200 and 200 'is unfastened and the pillars 200 and 200' And then the nut 200 is fastened to the connecting member 100 by tightening the nut 320 again.

As described above, according to the present invention, it is possible to adjust the height of the pillars 200 and 200 'so that the height of the pillars 200 and 200' The length of the pillar 200 'can be set to a set height when the length of the pillar 200' is short or long. Also, since the concrete foundation block 10 The height of the pillars 200 and 200 'can be increased to keep the height of the solar cell modules M (solar energy collecting plates) uniform.

The first and second side support plates 120, 130, 120 'and 130' of the connecting member 100, to which the lower ends of the struts 200 and 200 'are inserted, The direction of the front and rear reinforcing plate portions 122, 123, 132 and 133 of the first and second side support plates 120, 130, 120 'and 130' is connected to the support 200 When the force acts on the front and rear surfaces of the solar cell module M and the force is transmitted to the struts 200 and 200 ' When water is introduced into the openings of the upper part of the column or between the first and second side support plates 120, 130, 120 'and 130', or water generated by condensation due to a temperature difference is easily Thereby preventing corrosion and discharge.

Since the connecting member 100 and the pillars 200 and 200 'are manufactured separately from each other, the base plate 110 and the first and second side support plates 120 and 130' ) 120 ', 130' are welded to each other to prevent corrosion, the plating operation is easy and the plating time is shortened. In addition, since the component parts are small in size and easy to carry, the support members 200 and 200 'are inserted into the connection member 100 at the site, and the height of the support members 200 and 200' It is possible to simplify the installation on the site and shorten the construction period.

In addition, since the connecting member 100 and the struts 200 and 200 'are manufactured to be separated from each other, the welding operation is eliminated in the struts 200 and 200', and the material of the struts 200 and 200 ' Can be selected in various ways and an error range with respect to the length of the supports 200 and 200 'can be increased, so that it can be applied variously according to installation conditions of the photovoltaic power generation system.

100; A connecting member 110; Base plate
120; A first side support plate 130; The second side support plate
200; Landing 300; Tightening unit
M; Solar cell module

Claims (8)

A connecting member coupled to the base member;
A strut that is height-adjustably inserted into the connecting member;
A solar energy collecting plate connected to the strut and having a height adjusted according to a height of the strut;
And a fastening unit for fastening the connecting member and the strut,
The connecting member includes a base plate coupled to the base member, a first side support plate provided on the upper surface of the base plate to support one side of the support, and a second side support plate disposed on the upper surface of the base plate And a second side support plate provided to support the lower portion of the strut together with the first side support plate, wherein the tightening unit is fastened through the first and second side support plates,
The first and second side support plates are respectively formed in a diagonal shape and each have a vertical elongated hole for supporting one of the struts and inserted with the fastening unit. And a rear reinforcing plate portion extending and bending at the other end of the bent support plate portion,
The front and rear reinforcing plate portions of the first and second side support plates are positioned in the forward and backward directions of the solar energy collecting plate,
The horizontal cross-sectional shape of the support inserted between the bendable support plate portion of the first side support plate and the bendable support plate portion of the second side support plate is a square or H type,
Wherein a distance between the upper ends of the bent support plates of the first and second side support plates is equal to a width of the support when the fastening unit is fastened and is greater than a width of the support when the fastening unit is not fastened. Height adjuster for solar collector plate. delete delete A connecting member coupled to the base member;
A strut that is height-adjustably inserted into the connecting member;
A solar energy collecting plate connected to the strut and having a height adjusted according to a height of the strut;
And a fastening unit for fastening the connecting member and the strut,
The connecting member includes a base plate coupled to the base member, a first side support plate provided on the upper surface of the base plate to support one side of the support, and a second side support plate disposed on the upper surface of the base plate And a second side support plate provided to support the lower portion of the strut together with the first side support plate, wherein the tightening unit is fastened through the first and second side support plates,
The first and second side support plates are each formed in a curved shape and include a curved support plate portion having a vertical slot into which the support unit is inserted and which supports one side of the support, And a rear reinforcement plate portion extending from the other end of the curved support plate portion,
The front and rear reinforcing plate portions of the first and second side support plates are positioned in the forward and backward directions of the solar energy collecting plate,
The horizontal cross-sectional shape of the support inserted between the curved support plate of the first side support plate and the curved support plate of the second side support plate is circular,
Wherein the first and second side support plates have a larger inner diameter than the outer diameter of the support, and the first and second side support plates are coupled with each other when the coupling unit is not fastened, And the upper ends of the portions contact the outer peripheral surface of the support. delete delete delete The apparatus of claim 1 or 4, wherein the solar energy collecting plate is one of a solar cell module, a light collecting plate, or an heat collecting plate.

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