KR20220026102A - Tracking structure of solar cell - Google Patents

Abstract

The present invention relates to a tracking structure for a solar cell, which comprises: a first shaft supporting portion joined to a support portion to be able to turn horizontally on a longitudinal shaft center; a second shaft supporting portion joined to the first shaft supporting portion to be able to turn vertically on a transverse shaft center; and a plurality of variable frame portions joined to the second shaft supporting portion and arranged to accommodate solar cells inside, wherein a planar area thereof varies in case of strong wind, heavy rain, and rainstorm. The tracking structure for a solar cell according to the present invention can be immediately folded by means of the variable frame portion when exposed to a harsh environment such as rain, hail, snow, dust, wind, a storm, a typhoon, and the like to reduce physical and mechanical damage to the solar cells, thereby minimizing the decrease in efficiency of power generation and maintaining the solar cell's life expectancy. In addition, a joint portion between the variable frame portions is linked by a rod end link to provide both mechanical rigidity and flexibility at the same time, so that a folding process and an unfolding process can be smoothly varied and costs for operation and maintenance of the tracking structure can be saved.

Description

Solar cell tracking structure {TRACKING STRUCTURE OF SOLAR CELL}

The present invention relates to a photovoltaic cell tracking structure, and more particularly, a photovoltaic cell capable of protecting the photovoltaic cell from external natural environments such as rain and wind, yellow sand, etc. because the plate area of a plurality of photovoltaic cells can be three-dimensionally varied as needed. It relates to a tracking structure.

In recent years, solar energy and solar heat have been spotlighted as clean and eco-friendly energy sources along with wind power and hydroelectric power, and are being recognized as almost the only alternative means of fossil raw materials such as petroleum.

Accordingly, various equipment or facilities that utilize solar energy are emerging. Solar panels, solar cell modules, etc. that collect solar heat and directly convert it into electrical energy, or solar heat storage (collection of heat) that collect light energy and use it as a heat source for hot water and heating ) is being largely divided into devices and is being developed.

Among them, the so-called solar cell is directly exposed to sunlight and can be said to be a key component to generate current, and a plurality of conventional solar cells are fixedly connected to each other and are arranged to maintain a state always exposed to the sun. .

However, conventional solar cells are inevitably exposed to rain, hail, snow, yellow dust, etc. directly, and are vulnerable to strong winds or typhoons, so there is a high risk of physical and mechanical damage. There is a problem with losing.

In addition, in order to secure the mechanical rigidity of the solar cell tracking structure, the folding part between the solar cells is strong and the structure is strong, so it is not flexible, so the variability is reduced, such as being easily damaged or not completely folded during the actual folding or unfolding process. There is a problem in that the operation and maintenance cost of the device is increased.

The present invention has been proposed to solve the above problems, and it is possible to instantly fold through the variable frame part in a weak environment such as rain, hail, snow, yellow sand, strong wind or typhoon, thereby reducing physical and mechanical damage to the solar cell and generating power. The reduction in efficiency can be minimized and the life expectancy can be maintained, and by connecting the connecting parts between the variable frame parts with a rod-end link body, mechanical rigidity and flexibility can be satisfied at the same time. And it provides a solar cell tracking structure that can reduce maintenance costs.

Photovoltaic cell tracking structure according to the present invention for achieving the above object, the one-axis support coupled to the support and horizontally rotatably coupled along the longitudinal axis; a two-axis support part coupled to the one-axis support part to be vertically rotatable along a horizontal axis; and a plurality of variable frame parts coupled to the two-axis support part and provided to accommodate a solar cell therein, and the plate area of which is variable in case of strong winds, heavy rains, or rainstorms.

It may further include a rod end link body provided between the plurality of the variable frame portion for guiding the folding / unfolding of the variable frame portion.

The variable frame unit may include: a frame body for accommodating and mounting the solar cell; and link support arms provided at both ends of the frame body to which the rod end link body is rotatably coupled.

The link support arm portion may include a main body support arm coupled to the frame body; a torsion support arm provided in parallel with the body support arm to withstand a torsion load; a reinforcing connection block interposed between the main body support arm and the torsion support arm; and a coupling block provided between the reinforcing connection blocks to which one end of the rod end link body is coupled.

The rod end link body, the rod end body; and a link connecting body provided to be accommodated in the rod end body to ensure play.

The rod end body may be provided with a jar-shaped receiving curved portion, and the link connecting body may be provided with a spherical outer spherical portion corresponding to the receiving curved portion.

A through hole may be provided in the link connecting body, and the coupling block may be rotatably coupled to the through hole.

The photovoltaic cell tracking structure according to the present invention enables immediate folding through the variable frame unit in a weak environment such as rain, hail, snow, yellow sand, strong wind or typhoon, thereby reducing physical and mechanical damage to the photovoltaic cell, thereby minimizing the decrease in power generation efficiency and the life expectancy can be maintained, and the mechanical rigidity and flexibility can be satisfied at the same time by connecting the connecting parts between the variable frame parts with a rod end link body, so that the folding or unfolding process can be varied smoothly and the operation and maintenance costs of the device can be reduced. can be reduced

1 is a perspective view of a solar cell tracking structure according to an embodiment of the present invention.
2 is a side view of a solar cell tracking structure according to an embodiment of the present invention.
3 is a rear view of the variable frame part in the solar cell tracking structure according to an embodiment of the present invention.
4 is an enlarged view of the link support arm and the rod end link body in FIG. 3 .
5 is a perspective view and a side view of a rod-end rank body in a solar cell tracking structure according to an embodiment of the present invention.
6 is a view schematically showing a folded state of the solar cell tracking structure according to an embodiment of the present invention.

Hereinafter, an embodiment of the solar cell tracking structure according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a solar cell tracking structure according to an embodiment of the present invention, FIG. 2 is a side view of a solar cell tracking structure according to an embodiment of the present invention, and FIG. 3 is a solar cell tracking structure according to an embodiment of the present invention is a rear view of the variable frame part, FIG. 4 is an enlarged view of the link support arm and the rod end link body in FIG. 3, and FIG. 5 is a perspective view and a side view of the rod end rank body in the solar cell tracking structure according to the embodiment of the present invention. am.

As shown in FIGS. 1 to 5, the solar cell tracking structure according to an embodiment of the present invention is coupled to the support unit 10 and is coupled to a horizontal rotatable axis along the longitudinal axis of the support unit 100; Doedoe coupled to the one-axis support part 100, a two-axis support part 110 coupled to be vertically rotatable along the axis in the horizontal direction; and a plurality of variable frame units connected to the two-axis support unit 110 and provided to accommodate the photovoltaic cells 20 therein, and the plate area of which is variable in case of strong winds, heavy rains, or rainstorms; and a rod end link body 300 provided between the plurality of variable frame units 200 to guide folding/unfolding of the variable frame unit 200 .

The support part 10 may be firmly fixedly installed on the ground floor.

Referring mainly to FIGS. 1 and 2 , the uniaxial support part 100 may be rotatably coupled to the end of the support part 10 . One-axis support unit 100 may be provided to be able to rotate horizontally along the axis in the vertical direction. A uniaxial rotation unit 101 may be provided adjacent to the uniaxial support unit 100 . Accordingly, the variable frame unit 200 including the photovoltaic cell 20 may be able to yaw in response to the diurnal motion of the sun.

A biaxial support part 110 may be provided at the upper end of the uniaxial support part 100 . The two-axis support part 110 is a part coupled to the single-axis support part 100 so as to be vertically rotatable along the axial center in the horizontal direction. In addition, the support frame part 120 extending longitudinally in the longitudinal direction may be provided on the biaxial support part 110 . In addition, adjacent to the two-axis support part 110 and the support frame part 120, the two-axis rotation part 111 may be provided. The variable frame unit 200 including the photovoltaic cell 20 by the biaxial support 110 may be capable of pitching rotation with respect to the uniaxial support 100 .

Two-axis tracking is possible according to the diurnal motion of the sun by the single-axis support part 100 and the two-axis support part 110, so that solar power generation can be facilitated.

On the other hand, the conventional solar cell 20 has no choice but to be directly exposed to rain, hail, snow, yellow sand, etc., and is vulnerable to strong winds or typhoons, so there is a high risk of physical and mechanical damage. There was a problem that life expectancy was shortened.

In addition, in order to secure the mechanical rigidity of the photovoltaic cell tracking structure, there was a problem that the folding part between the photovoltaic cells 20 was strong and the structure was not flexible.

Accordingly, in this embodiment, a plurality of variable frame parts 200 and the load end link body 300 in which the total plate area of the photovoltaic cell 20 varies while approaching and spaced apart from the support frame part 120 may be provided. . The variable frame unit 200 mainly includes, as shown in FIGS. 1 to 4, a frame body 210 for accommodating and mounting the photovoltaic cell 20; and link support arm parts 220 provided at both ends of the frame body 210 to which the rod end link body 300 is rotatably coupled.

The frame body 210 is a skeleton part in which the photovoltaic cell 20 is substantially accommodated therein.

A link support arm 220 may be provided at the upper end and lower end of the frame body 210 . Link support arm 220 is mainly referring to Figures 3 and 4, the main body support arm 221 coupled to the frame body 210; a torsion support arm 222 provided in parallel with the body support arm 221 to withstand a torsional load; a reinforcing connection block 223 interposed between the body support arm 221 and the torsion support arm 222; and a coupling block 224 provided between the reinforcing connection blocks 223 to which one end of the rod end link body 300 is coupled.

The body support arm 221 may be coupled to the upper end and lower end of the frame body 210 .

The torsion support arm 222 may be provided on the main body support arm 221 in parallel to the main body support arm 221 . The torsion support arm 222 uniformly distributes the external force applied through the rod end link body 300 to the entire area of the frame body 210 during the folding and unfolding process of the variable frame unit 200 to form the variable frame unit ( 200) to relieve the torsional load.

The torsion support arm 222 may be connected through a reinforcing connection block 223 interposed between the body support arm 221 and the torsion support arm 222 .

And a coupling block 224 disposed between the reinforcing connection blocks 223 is provided, and one end of the rod end link body 300 is connected to the coupling block 224 .

Meanwhile, as shown in FIG. 3 , a plurality of solar tracking sensors 400 , raindrop sensors 410 , and wind vanes 420 may be provided around the periphery.

The plate area of the plurality of variable frame units 200 needs to be smoothly varied. Accordingly, in this embodiment, the rod end link body 300 may be provided. The rod end link body 300 is mainly referring to Figs. 1 to 5, the rod end body 310; and a link connecting body 320 provided to be accommodated in the rod end body 310 to ensure play.

The rod end body 310 is provided with a jar-shaped receiving curved portion 311, and the link connecting body 320 has a spherical outer spherical portion 322 on the inner wall to correspond to the receiving curved portion 311. can be provided.

A through hole 321 is provided in the link connector 320 , and the coupling block 224 may be rotatably coupled to the through hole 321 .

Through this rod-end link body 300, a predetermined degree of play is secured even when the variable frame unit 200 is rotated or twisted at a predetermined angle in the process of folding/unfolding the variable frame unit 200, and the link can be connected. Therefore, it is possible to simultaneously satisfy mechanical rigidity and flexibility, so that the folding or unfolding process can be smoothly varied, and device operation and maintenance costs can be reduced.

Through this configuration, it is possible to instantly fold through the variable frame unit 200 in a weak environment such as rain, hail, snow, yellow sand, strong wind or typhoon, thereby reducing physical and mechanical damage to the solar cell 20, thereby lowering power generation efficiency. can be minimized and the life expectancy can be maintained, and by connecting the connecting parts between the variable frame parts 200 with the rod end link body 300, mechanical rigidity and flexibility can be simultaneously satisfied, so that the folding or unfolding process can be varied smoothly. and device operation and maintenance costs can be reduced.

6 is a view schematically showing a folded state of the solar cell tracking structure according to an embodiment of the present invention.

Hereinafter, the folding operation of the solar cell tracking structure according to the present embodiment will be described in detail with reference to FIGS. 1 to 6 .

First, according to the operation of the 1-axis rotation unit 101 and the 2-axis rotation unit 111, solar power generation may be performed while the solar cell 20 is tracked according to the diurnal motion of the sun. At this time, the variable frame unit 200 is provided in a fully unfolded state as shown in FIGS. 1 and 3 .

Next, when a weak environment such as rain, hail, snow, yellow sand, strong wind or typhoon is predicted to occur, a folding process is performed, and it operates when the input value through the rain sensor and the weather vane is greater than or equal to the preset value.

The length of the rod end link body 300 disposed between the plurality of variable frame units 200 is shortened.

At this time, as the receiving curved portion 311 of the rod end body 310 provided in the rod end link body 300 and the outer spherical surface portion 322 of the link connecting body 320 are in surface contact with each other, there is a gap or Torsional clearance can be accommodated.

Accordingly, mechanical rigidity and flexibility can be satisfied at the same time, so that the folding or unfolding process can be smoothly varied and device operation and maintenance costs can be reduced.

Through this operation process, it is possible to instantly fold through the variable frame unit 200 in a weak environment such as rain, hail, snow, yellow sand, strong wind or typhoon, thereby reducing physical and mechanical damage to the solar cell 20 and improving power generation efficiency. It has the advantage of minimizing deterioration and maintaining life expectancy.

As mentioned above, although the present invention has been described in detail using preferred embodiments, the scope of the present invention is not limited to specific embodiments and should be construed according to the appended claims. In addition, those skilled in the art will understand that many modifications and variations are possible without departing from the scope of the present invention.

10: support 20: solar cell
100: 1-axis support part 101: 1-axis rotation part
110: 2-axis support part 111: 2-axis rotation part
120: support frame part 200: variable frame part
210: frame body 220: link support arm part
221: body support arm 222: torsion support arm
223: reinforcing connection block 224: coupling block
300: rod end link body 310: rod end body
311: receiving curved portion 320: link connection body
321: through hole 322: outer spherical part
330: road link 400: solar tracking sensor
410: rain sensor 420: wind vane

Claims (7)

One-axis support part coupled to the support part so as to be horizontally rotatable along the longitudinal axis;
a two-axis support part coupled to the one-axis support part to be vertically rotatably coupled along the axial center in the horizontal direction; and
Solar cell tracking structure, characterized in that it comprises a plurality of variable frame parts coupled to the two-axis support is provided to accommodate the photovoltaic cell therein, the plate area is variable in case of strong winds, heavy rains, or winds. According to claim 1,
a support frame portion rotatably coupled to the two-axis support portion to support the variable frame portion; and
Photovoltaic cell tracking structure, characterized in that it further comprises a rod end link body provided between the plurality of the variable frame portion for guiding the folding / unfolding of the variable frame portion. 3. The method of claim 2,
The variable frame unit,
a frame body for accommodating and mounting the solar cell; and
Photovoltaic cell tracking structure provided at both ends of the frame body, characterized in that it comprises a link support arm to which the rod end link body is rotatably coupled. 4. The method of claim 3,
The link support arm part,
a body support arm coupled to the frame body;
a torsion support arm provided in parallel with the body support arm to withstand a torsion load;
a reinforcing connection block interposed between the body support arm and the torsion support arm; and
Photovoltaic cell tracking structure, characterized in that the coupling block provided between the reinforcement connection block is coupled to one end of the rod end link body. 5. The method of claim 4,
The rod end link body,
rod end body; and
Photovoltaic cell tracking structure, characterized in that it is provided to be accommodated in the rod end body comprises a link connection body to secure the clearance. 6. The method of claim 5,
The rod end body is provided with a jar-shaped receiving curved portion,
Solar cell tracking structure, characterized in that the link connector is provided with a spherical outer spherical portion to correspond to the receiving curved portion. 6. The method of claim 5,
The link connection body is provided with a through hole,
Solar cell tracking structure, characterized in that the coupling block is rotatably coupled to the through hole.

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