KR20130009191A - Apparatus for supporting solar energy collecting modules - Google Patents

Abstract

PURPOSE: An apparatus for supporting a solar energy collecting module is provided to enhance the supporting force of a solar cell module by inserting a supporting shaft into a casing. CONSTITUTION: A casing(200) includes a flange part. A supporting shaft(300) is formed in the end portion of a structure. The supporting shaft is sided up and down to be inserted into the casing. A fixing unit(400) fixes the supporting shaft at a position. A height controlling unit(500) controls the height of the supporting shaft.

Description

Solar cell module support device {APPARATUS FOR SUPPORTING SOLAR ENERGY COLLECTING MODULES}

The present invention relates to a solar cell module support apparatus constituting a solar power system.

In general, solar cells convert the sun's light energy into electrical energy. The smallest unit that generates power using the photoelectric effect is called a cell, and a plurality of cells are connected in series or in parallel to generate a predetermined amount of power. Generally, a solar power plant (also called a solar power generation system) is a collection of solar cell modules in which a plurality of solar cell modules are connected in series or in parallel.

Solar power systems are usually installed on land. The solar cell module is mounted on a module support structure, which is installed onshore. The solar cell module and the module support structure are called unit photovoltaic power generation systems.

The conventional apparatus for installing the unit photovoltaic power generation system on land is as follows.

As shown in FIG. 1, the conventional apparatus includes a concrete structure 10 embedded in a predetermined depth from the ground, anchor bolts 20 embedded in the concrete structure 10, and the anchor bolts 20. Each nut 30 is fastened to each other. The concrete structure 10 has a hexahedron shape having a horizontal cross section of a rectangle, and has a large area to height. The anchor bolts 20 protrude from the top surface of the concrete structure 10.

A flange 41 is provided on a lower surface of the module support structure 40, and through holes are provided in the flange 41. The nuts 30 are fastened to the anchor bolts 20 with the anchor bolts 20 inserted into the through holes of the flange 41 of the module support structure 40.

The solar cell module 50 is installed on the module support structure 40.

In general, when installing a solar power generation system in Yasan will install a solar power generation system in a short period of time to reduce construction costs. At this time, the mountain is to be installed on a flat plain and the flat is installed after the construction of the photovoltaic power generation system is installed in a short period of time, but it is raining over time, the ground freezes and melts the ground erosion This will occur.

In the conventional apparatus as described above, when the ground on which the unit photovoltaic system is installed is submerged and the unit photovoltaic system is lowered or tilted, the angle of the solar cell module is not maintained at the set angle and is structurally unstable. In addition, the connection state of the transmission lines connected to each other becomes unstable due to the positional difference between the unit photovoltaic system that is set down and the adjacent unit photovoltaic system. When the unit solar power generation system that has been settled down is moved to its original position, the repair work is difficult because the existing concrete structure must be removed, a new concrete structure must be made, and a unit solar power generation system must be installed.

An object of the present invention is to minimize the fall of the unit photovoltaic system when the site on which the photovoltaic system is installed is settled.

Another object of the present invention is to easily return the unit photovoltaic system to its original position when the unit photovoltaic system is settled down.

In order to achieve the object of the present invention, a concrete shaft embedded in the ground; A casing inserted into the concrete shaft and having a flange portion exposed on the upper surface of the concrete shaft; A support shaft provided at an end of the structure and slidably inserted up and down inside the casing; A fixing unit for fixing the support shaft to a flange portion of the casing at an arbitrary position; And it is provided a solar cell module support device comprising a height adjustment unit for adjusting the height of the support shaft.

Preferably, the concrete shaft has a circular cross-sectional shape.

The casing preferably includes a cylindrical portion having a set length and the support shaft is slidably inserted therein, a flange portion bent to the upper end of the cylindrical portion, and a bottom plate coupled to block the lower end of the cylindrical portion.

Preferably, the support shaft includes a cylindrical portion slidably inserted into the casing, a bottom plate covering the lower end of the cylindrical portion, and a coupling plate provided at an upper end of the cylindrical portion and coupled to a lower end of the structure. .

The fixing unit preferably includes a plurality of fastening bolts passing through the flange portion of the casing and a portion of the support shaft, and fastening nuts fastened to the bolts, respectively.

Preferably, the height adjusting unit includes an injection tube provided on the support shaft so as to pass through the bottom surface of the support shaft, and a filling powder filled between the bottom surface of the support shaft and the bottom surface of the casing.

It is preferable that a fixed bar having a predetermined length is connected to the lower portion of the casing.

A cylindrical mash formed of a wire mesh may be connected to the lower portion of the casing.

Preferably, a plurality of reinforcing iron plates connecting the structure and the support shaft are provided between the lower portion of the structure and the support shaft, and through holes for inserting the support bars into the reinforcing iron plates are preferably provided.

The present invention is to firmly install the structure in which the solar cell module is installed. In particular, since the support shaft is fixed while being inserted into the casing, external forces caused by wind or the like act on the structure and the solar cell module so that a lateral force acts on the support shaft by the inner circumferential surface of the casing. Force is distributed. Therefore, it increases the bearing capacity of the solar cell module and structure.

In addition, the present invention is because the concrete shaft has a smaller cross-sectional area and a longer length than the conventional concrete structure so that it is embedded in the ground deeply, the ground is generated from the ground thickness corresponding to the length of the concrete shaft when the rain is frozen and the ground is settled according to the greening The settlement does not affect the concrete shaft and only the ground settlement occurring below the concrete shaft tends to affect the concrete shaft, thus minimizing the settlement of the concrete shaft due to ground settlement.

Since the present invention has a minimal effect on ground subsidence, it is possible to make a flat hill and then to dig a hole in the flat and to make a concrete shaft in the hole, so that it is required for the process of compacting the ground and the process of ground subsidence of the flat for a long time. The elimination of time will not only significantly reduce the cost of installing the solar power system, but also significantly shorten the construction period.

On the other hand, after installing a unit photovoltaic power generation system equipped with the present invention on the site after a long time, if the concrete shaft falls slightly due to ground subsidence, the height of the solar cell module is returned to the original height by using the height adjustment unit. You can do it.

1 is a side view showing a conventional apparatus for installing a unit photovoltaic power generation system on land;
Figure 2 is a side view showing a unit photovoltaic power generation system equipped with an embodiment of a solar cell module support apparatus according to the present invention,
Figure 3 is a side cross-sectional view showing an embodiment of a solar cell module support apparatus according to the present invention,
Figure 4 is a longitudinal cross-sectional view showing an embodiment of a solar cell module support apparatus according to the present invention,
5 and 6 are side cross-sectional views respectively showing the operation of the height adjustment unit constituting the solar cell module support apparatus according to the present invention.

Hereinafter, an embodiment of a solar cell module support apparatus according to the present invention will be described with reference to the accompanying drawings.

Figure 2 is a side view showing a unit photovoltaic power generation system equipped with an embodiment of a solar cell module support apparatus according to the present invention. 3 is a front sectional view showing an embodiment of the solar cell module support apparatus. 4 is a plan sectional view of the solar cell module support apparatus.

As shown in Figures 2, 3, 4, first, an embodiment of the solar cell module support apparatus according to the present invention is a concrete shaft 100, casing 200, support shaft 300, fixed unit 400 And it includes a height adjustment unit (500).

The concrete shaft 100 is embedded in the ground so that the upper surface is exposed to the ground. The lower end portion of the concrete shaft 100 is preferably embedded in a high bearing capacity. Preferably, the concrete shaft 100 has a set length and has a circular cross-sectional shape. The cross-sectional shape of the concrete shaft 100 may be a square or hexagon.

The casing 200 is inserted and fixed inside the concrete shaft 100. The casing 200 has a cylindrical portion 210 in which the support shaft 300 is slidably inserted, a flange portion 220 bent and extended at an upper end of the cylindrical portion 210, and the cylindrical portion 210. It is preferable to include a bottom plate 230 coupled to block the bottom of the. The cylindrical portion 210 has a set length. It is preferable that the thickness of the cylindrical portion 210 is uniform, and the outer diameter is smaller than the outer diameter of the concrete shaft 100. The bottom plate 230 is a disc having a uniform thickness. The bottom plate 230 is preferably coupled to the end surface of the cylindrical portion 210 by welding.

The casing 200 is inserted into the concrete shaft 100 such that only the upper portion of the flange portion 220 and the cylindrical portion 210 is exposed over the upper surface of the concrete shaft 100.

It is preferable that a fixed rebar 250 having a predetermined length is connected to a lower surface of the bottom plate 230 of the casing 200. The fixed reinforcing bar 250 is preferably formed in a T-shape, both ends of the upper portion of the T-shaped is fixed to the bottom surface of the bottom plate (230). The fixed reinforcing bar 250 serves to extend the length of the casing 200 to increase the fixing force of the casing 200 as well as to reinforce the strength of the concrete shaft 100. Instead of the fixed reinforcement 250, a cylindrical mesh of a wire mesh may be connected to the bottom plate 230 of the casing 200.

The method of coupling the concrete shaft 100 and the casing 200 is as follows.

Pour the appropriate amount of concrete dough into the formed hole (H) corresponding to the concrete shaft (100) in the ground. The casing 200 or the casing 200 to which the fixed rebar 250 is coupled is inserted into the concrete dough filled in the hole H, and the flange 200 and the upper portion of the cylindrical portion 210 are exposed. . The concrete dough is hardened in the state where the casing 200 is fixed.

As another method of coupling the concrete shaft 100 and the casing 200, a suitable amount of concrete dough is poured into a cylindrical formwork (not shown). The casing 200 or the casing 200 in which the fixed reinforcing bar is coupled is inserted into the concrete dough filled in the formwork, and the flange 200 and the upper portion of the cylindrical part 210 are inserted to be exposed. The concrete dough is hardened in the state where the casing 200 is fixed. The concrete shaft 100 to which the casing 200 is coupled is separated from the formwork. The concrete shaft 100 to which the casing 200 is coupled is inserted into the hole H formed in the ground.

The support shaft 300 is provided at the end of the structure 600. The support shaft 300 is inserted into the casing 200 to be slidable up and down.

The support shaft 300 is provided on a cylindrical portion 310 slidably inserted into the casing 200, a bottom plate 330 that blocks the lower end of the cylindrical portion, and an upper end of the cylindrical portion 310. It includes a coupling plate 320. The cylindrical portion 310 of the support shaft 300 has a set length, it is preferable that the thickness is uniform. The bottom plate 330 of the support shaft 300 is preferably a disk having a uniform thickness is coupled to the bottom of the cylindrical portion 310 by welding. The cylindrical portion 310 of the support shaft 300 is slidably inserted into the cylindrical portion 210 of the casing 200. Coupling plate 320 of the support shaft 300 is preferably a rectangular plate having a uniform thickness. The lower surface of the coupling plate 320 is preferably fixed to the upper surface of the cylindrical portion 310 of the support shaft 300 by welding. The size of the coupling plate 320 is larger than the cross-sectional area of the cylindrical portion 310. The lower surface of the structure 600 is fixedly coupled to the upper surface of the coupling plate 320 by welding.

The fixing unit 400 fixes the support shaft 300 to the flange portion 220 of the casing 200 at an arbitrary position. The fixing unit 400 includes a plurality of fastening bolts 410 passing through the flange portion 220 of the casing 200 and the coupling plate 320 of the support shaft 300, and the fastening bolts 410. Fastening nuts 420 fastened to each. The coupling plate 320 of the support shaft 300 and the flange portion 220 of the casing 200 in a state where the cylindrical portion 310 of the support shaft 300 is inserted into the cylindrical portion 210 of the casing 200. ) Face each other, and the fastening bolts 410 and the fastening nuts 420 may be fastened while the coupling plate 320 and the flange portion 220 are in contact with each other, and the coupling plate 320 and the plan may be fastened. The fastening bolts 410 and the fastening nuts 420 may be fastened in a state where the branch 220 is spaced apart.

The height adjusting unit 500 is to adjust the height of the support shaft 300. The height adjustment unit 500 is injected through the injection tube 510 provided on the support shaft 300, the injection tube 510 and the bottom plate and the casing (330) of the support shaft 300 Filling powder 520 is filled between the top surface of the bottom plate 230 of 200. The injection tube 510 is preferably a straight tube having a set length. The injection tube 510 penetrates the coupling plate 320, the cylindrical portion 310, and the bottom plate 330 of the support shaft 300. When the filling powder 520 is inserted through the inlet of the injection tube 510, the filling powder 520 is casing 200 with the bottom surface of the bottom plate 330 of the support shaft 300 through the injection tube 510. It is filled between the upper surface of the bottom plate (230) of. The upper end of the injection tube 510 is preferably provided with a stopper 530 that opens and closes the inlet of the injection tube 510.

Preferably, a plurality of reinforcing steel plates 610 connecting the structure 600 and the support shaft 300 are provided between the lower portion of the structure 600 and the support shaft 300. The reinforcing iron plate 610 is preferably four, two of which are located next to each other on one side of the coupling plate 320, the other two are located next to each other on the other side of the coupling plate 320. . Through holes 611 for inserting support bars (not shown) are provided in two reinforcing iron plates 610 respectively positioned on both sides of the coupling plate 320. The support bar is described later.

Operation of the height adjustment unit 500 is as follows.

When the concrete shaft 100 is slightly settled down, as shown in FIG. 5, the support bar B is inserted into the through hole 611 of the two reinforcing steel plates 610, and the other two reinforcing steel plates ( Another support bar B is inserted into the through hole 611 of 610, and then the two support bars B are supported by the jacks F, respectively. Loosen the fixing unit 400. Jack up the support shaft 300 as the concrete shaft 100 is settled down. The filling powder 520 is filled in the space between the bottom surface of the bottom plate 330 of the support shaft 300 and the top surface of the bottom plate 230 of the casing 200 through the injection tube 510. After filling the filling powder 520 into the space through the injection tube 510, it is preferable to add a small amount of water so that the filling powder 520 is compacted. As shown in FIG. 6, after the jack F is removed, the coupling plate 320 of the support shaft 300 and the flange portion 220 of the casing 200 are fixed to the fixing unit 400. In this process, the height of the support shaft 300 increases as the concrete shaft 100 falls. Pushing up the support shaft 300 may be used other equipment than the jack (F).

The solar cell module 700 is installed on the structure 600. The structure 600 and the solar cell module support device are module support structures for supporting the solar cell module 700. The module support structure and the solar cell module 700 constitute a unit photovoltaic power generation system. The unit photovoltaic power generation systems are installed at regular intervals on the site. Transmission lines are connected between the unit photovoltaic systems.

Hereinafter, the operation and effects of the solar cell module support apparatus according to the present invention.

According to the present invention, the concrete shaft 100 is deeply embedded in the ground and the casing 200 is inserted into and fixed to the concrete shaft 100 and the support shaft 300 connected to the structure 600 is inserted into the casing 200 and the casing 200 ) And the support shaft 300 is fixed by the fixing unit 400. As a result, the structure 600 in which the solar cell module 700 is installed is firmly installed. In particular, since the support shaft 300 is fixed while being inserted into the casing 200, an external force by wind or the like acts on the structure 600 and the solar cell module 700, thereby causing a lateral force on the support shaft 300. In this case, since the outer circumferential surface of the support shaft 300 is supported by the inner circumferential surface of the casing 200, the force is dispersed. Therefore, the supporting force of the solar cell module 700 and the structure 600 is increased.

In addition, the present invention is because the concrete shaft 100 is smaller than the conventional concrete structure 10, the cross-sectional area is long and the length is embedded until the ground strength is high, the rain is raining and the ground freezes and the ground is settled according to the concrete shaft ( Ground subsidence generated in the ground thickness corresponding to the length of 100) does not affect the concrete shaft (100). If, even if the lower end of the concrete shaft is stuck to a portion close to the ground with high bearing capacity, only the ground subsidence that occurs below the end of the concrete shaft 100 affects the concrete shaft 100, so the concrete shaft due to ground subsidence ( Settling of 100 is extremely minimal. In general, ground subsidence is mainly generated in the upper part of the ground, ground subsidence generated below the end of the concrete shaft 100 is very minimal. The support shaft 300 inserted into the casing 200 and the structure 600 and the solar cell module 700 connected to the support shaft 300 are mainly caused by their own weight when the lateral external force is not applied. Since the vertical load acts on), the cross-sectional area of the concrete shaft 100 fully supports at least the acting vertical load.

As described above, the present invention has a minimal effect on the ground subsidence, so that the mountain can be made flat, and a hole can be dug directly in the flat and the concrete shaft 100 can be made in the hole. This shortens the process and time. That is, in the related art, in consideration of the ground subsidence, the mountain is made flat and the ground flattened and then the unit solar power generation system is installed on the flat after a certain time so that the flat land is naturally settled. Although it takes a lot, the present invention can eliminate such a work process and time can reduce a lot of costs and also shorten the construction period.

On the other hand, if the concrete shaft 100 is slightly settled due to the ground subsidence after a long time after installing the unit photovoltaic power generation system equipped with the present invention, the height of the solar cell module using the height adjustment unit 500 Will return to its original height.

100; Concrete axis 200; Casing
250; Fixed rebar 300; Support shaft
400; Fixed unit 500; Height adjustment unit
600; Structure 610; Reinforcement sheet

Claims (10)

Concrete shaft embedded in the ground;
A casing inserted into the concrete shaft and having a flange portion exposed on the upper surface of the concrete shaft;
A support shaft provided at an end of the structure, the support shaft being slidably inserted up and down inside the casing;
A fixing unit for fixing the support shaft to a flange portion of the casing at an arbitrary position; And
Solar cell module support device comprising a height adjustment unit for adjusting the height of the support shaft. The apparatus of claim 1, wherein the concrete shaft has a circular cross-sectional shape. The casing according to claim 1, wherein the casing has a set length and includes a cylindrical portion in which the support shaft is slidably inserted, a flange portion bent to the upper end of the cylindrical portion, and a bottom plate coupled to block a lower end of the cylindrical portion. Solar cell module support device comprising. The support shaft of claim 1, wherein the support shaft includes a cylindrical part slidably inserted into the casing, a bottom plate blocking the lower end of the cylindrical part, and a coupling plate provided at an upper end of the cylindrical part and coupled to a lower end of the structure. Solar cell module support device comprising. The solar cell module support apparatus of claim 1, wherein the fixing unit comprises a plurality of fastening bolts passing through a flange portion of the casing and a portion of the support shaft, and fastening nuts fastened to the bolts, respectively. The solar cell module support of claim 1, wherein the height adjusting unit comprises an injection tube provided on the support shaft so as to pass through the bottom surface of the support shaft, and a filling powder filled between the bottom surface of the support shaft and the bottom surface of the casing. Device. 7. The solar cell module support apparatus according to claim 6, wherein the filling powder is sand. According to claim 1, The solar cell module support device, characterized in that the fixed reinforcing bar having a predetermined length is connected to the lower portion of the casing. According to claim 1, The solar cell module support device, characterized in that the cylindrical mesh-shaped cylinder is connected to the lower portion of the casing. The method of claim 1, wherein a plurality of reinforcing steel plates for connecting the structure and the support shaft between the lower portion and the support shaft of the structure is provided, characterized in that the through holes for inserting the support bars, respectively, characterized in that the reinforcing steel plates Solar cell module support device.

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