KR20110009023U - Apparatus Condensing for Solar Photovoltaic Generation - Google Patents

Abstract

The present invention aims to provide a photovoltaic condenser for minimizing energy consumption during operation by reducing the initial facility cost by simultaneously reflecting sunlight on a plurality of solar cell modules and operating separately from the solar cell module. .
Concentrating device for a solar generator of the present invention, the base is provided with a solar cell; An angle adjusting unit mounted on the base and rotating in a horizontal direction or a vertical direction; A reflection plate mounted on the angle adjusting unit and rotating in a left-right direction or a vertical direction and reflecting sunlight in the direction of the solar cell; A control module for controlling the rotation angle of the angle adjusting unit; It is made, including.

Description

Condensing device for solar generators {Apparatus Condensing for Solar Photovoltaic Generation}

The present invention relates to a solar generator concentrator, and more particularly, to a solar generator concentrator that tracks the position of the sun and reflects sunlight to the solar cell.

In general, a solar generator is a fixed power generation system that allows a plurality of solar cell module to look at a certain direction irrespective of the position of the sun, and the position of the sun by changing the angle and position of the solar cell module by a tracker (tracker) It is classified as a tracked power generation system that can increase power generation efficiency by tracking.

The stationary power generation system has the advantages of simple initial structure cost and low maintenance cost due to its simple structure. However, since the solar cell module always faces a certain direction, it is not efficient to collect solar light according to the change in the position of the sun. There is a falling problem.

In addition, the power generation can be made only for an average time of about 3.5 hours in the day, there is a problem that the efficiency is greatly reduced.

In order to solve this problem, a tracked generation system has been devised.

The tracking power generation system is a system that receives the sunlight efficiently by changing the position of the solar cell module in response to the change in the altitude of the sun.

1 is a view showing a tracking solar generator according to the prior art, which is disclosed in the registration room 20-0405716.

With reference to this tracking solar generator in detail as follows.

As shown in FIG. 1, the support pillar 10 is vertically erected on the lower part of the solar cell panel 2, and the solar cell panel 2 is placed on the upper part of the support column 10 according to the change of the position of the sun. Rotation drive means 12 is provided to rotate to enable tracking.

Altitude driving means including a screw jack for adjusting the inclination angle according to the altitude change of the solar panel 2 is also provided.

This registration scheme operates the rotation driving means 12 to rotate the solar panel 2 to track the orientation of the sun, and operate the altitude driving means 15 in the vertical direction of the solar panel 2 The angle is adjusted.

However, since the conventional solar generator generates power using solar light transmitted directly from the sun to the solar cell, there is a limit to increase the power generation efficiency without increasing the size of the solar cell.

In addition, since the solar cell module needs to be moved directly, the energy consumption during driving is large due to the weight of the solar cell module.

The present invention is to solve the above problems, to improve the power generation efficiency by concentrating sunlight on the solar cell using a reflector, and to minimize the energy consumption during driving by adjusting the angle of the reflector separately from the solar cell module. It is an object of the present invention to provide a light collecting device for a solar generator.

In order to achieve the above object, the solar cell condenser of the present invention includes a base provided with a solar cell; An angle adjusting unit mounted on the base and rotating in a horizontal direction or a vertical direction; A reflection plate mounted on the angle adjusting unit and rotating in a left-right direction or a vertical direction and reflecting sunlight in the direction of the solar cell; A control module for controlling the rotation angle of the angle adjusting unit; It is made, including.

The angle adjustment unit, the first rotating shaft is formed long in the vertical direction rotatably mounted on the base; A support protruding from the upper end of the first rotating shaft in left and right directions; A second rotating shaft formed in a left and right direction, one end of which is connected to the reflecting plate and the other end of which is rotatably mounted on the support; It is made, including.

The control module is made of a manual control module, the manual control module, the first locking member is mounted to the base to slide in the direction of the first rotation axis; A first elastic member elastically supporting the first locking member in the first rotation axis direction; A second catching member mounted on the first support to be slidably moved in the second rotation axis direction; A second elastic member elastically supporting the second locking member in the direction of the second rotation axis; It includes, but is formed in the first rotation shaft a plurality of first locking grooves in which the first locking member is inserted in the circumferential direction, the second locking groove is inserted into the second rotation shaft the second locking groove It is formed in a plurality in the circumferential direction, so that the first rotation shaft and the second rotation shaft is stopped at an angle rotated when the rotational force is removed from the first rotation shaft and the second rotation shaft.

The control module is composed of an automatic control module, the automatic control module, the sensor for tracking the position of sunlight; A first driving motor mounted to the base and connected to the first rotation shaft to rotate the first rotation shaft; A second driving motor mounted to an upper end of the support and connected to the second rotating shaft to rotate the second rotating shaft; A control unit configured to control the rotation angle of the first rotational shaft and the second rotational shaft by operating the first driving motor and the second driving motor according to the position of the sun tracked by the sensor; It is made, including.

The reflective plate is formed such that one surface of the solar cell is concave in the opposite direction of the solar cell.

As described above, the solar cell condenser of the present invention has the following effects.

The angle adjusting unit is mounted on the base and rotates in the horizontal direction or the vertical direction, thereby adjusting the angle of the reflector according to the position of the sun to concentrate the sunlight on the solar cell, thereby improving the power generation efficiency of the reflector. When the angle is adjusted, driving separately from the solar cell has the effect of reducing energy consumption.

The first rotating shaft is formed to be elongated in the vertical direction to be mounted on the base, and the second rotating shaft is formed to be elongated in the left and right direction to be mounted to the support, thereby sufficiently adjusting the angle adjusting range of the reflecting plate while the reflecting plate is provided. Rotating in the left and right and up and down directions to minimize the moving range of the reflecting plate, thereby reducing the installation space of the light collecting device.

The first rotating shaft has a plurality of first locking grooves in which the first locking member is inserted in the circumferential direction, and the second rotating shaft has a plurality of second locking grooves in which the second locking member is inserted in the circumferential direction. Thus, when the rotational force is removed from the first rotational shaft and the second rotational shaft, the first rotational shaft and the second rotational shaft are stopped at the rotated angle so that the angle of the reflecting plate can be kept constant, and the rotation is arbitrarily performed. It is effective to prevent.

The control module is made of the manual control module, thereby manually rotating and adjusting the rotation angles of the first and second rotary shafts without a separate driving device, thereby simplifying the overall structure and reducing energy consumption.

The control unit operates the first driving motor and the second driving motor in accordance with the position of the sun tracked by the sensor to control the angle of rotation of the first and second rotation shaft, the first rotation shaft and The angle of the second axis of rotation is automatically adjusted according to the position of the sun has the effect of convenient use.

The reflective plate is formed in one surface of the solar cell concave in the opposite direction of the solar cell, so that the sunlight is more concentrated in the solar cell direction to improve the power generation efficiency of the solar generator.

1 is a structural diagram of a tracking solar generator according to the prior art,
2 is a perspective view of a light collecting device for a solar generator according to an embodiment of the present invention,
3 is an exploded perspective view of a light collecting device for a solar generator according to an embodiment of the present invention,
4 is a cross-sectional view taken from AA of FIG. 2;
5 is a cross-sectional view seen from BB of FIG. 2,
6 and 7 is an operation process of the solar cell condenser device according to an embodiment of the present invention,

2 is a perspective view of a solar generator condenser according to an embodiment of the present invention, Figure 3 is an exploded perspective view of the solar generator condenser according to an embodiment of the present invention, Figure 4 is a cross-sectional view seen from AA of FIG. Figure 5 is a cross-sectional view as seen from BB of Figure 2, Figure 6 and Figure 7 is a view of the operation of the solar generator condensing device according to an embodiment of the present invention.

2 to 6, the solar cell condenser according to an embodiment of the present invention comprises a base 100, an angle adjusting unit 200, a reflector 300 and a control module.

The base 100 has a rectangular wide plate shape and is installed on the ground.

The first mounting part 110 on which the first rotating shaft 210 is mounted is protruded and formed on the upper portion of the base 100.

The first mounting portion 110 is formed in a cylindrical shape, protrudes upward, and is disposed at the rear of the central portion of the base 100.

The first mounting portion 110 has an upper portion is formed open, the lower end of the first rotation shaft 210 is inserted into the interior as will be described later.

In addition, the control module is mounted inside the first mounting unit 110 as described later.

Meanwhile, the solar cell 120 is mounted to the front of the first mounting part 110 on the base 100.

The solar cell 120 converts energy of solar light into electrical energy and generates electricity using two types of semiconductors, a P-type semiconductor and an N-type semiconductor.

Of course, the solar cell 120 may be installed separately from the base 100.

In addition, the angle adjusting unit 200 is installed in the base 100.

The angle adjusting unit 200 is mounted to the base 100 to rotate in the left and right direction or up and down direction.

Specifically, as shown in FIG. 3, the angle adjusting unit 200 includes a first rotation shaft 210, a support 220, and a second rotation shaft 230.

The first rotation shaft 210 has a cylindrical shape, is formed long in the vertical direction, the lower end is inserted into the first mounting portion 110 of the base 100 to be rotated.

That is, the first rotation shaft 210 is inserted into the first mounting portion 110 is mounted to rotate in the circumferential direction.

In addition, a plurality of first locking grooves 211 are formed at a lower end of the first rotation shaft 210 in the circumferential direction.

The first concave groove is concave in the direction of the center of the first rotary shaft 210, as described below is inserted into the first locking member 410 of the control module in accordance with the rotation of the first rotary shaft 210 Is placed.

The support 220 is formed on the upper end of the first rotation shaft 210 and are formed to protrude in both the left and right directions.

In addition, the support 220 is formed in an arc shape is formed symmetrically in the left and right direction, the lower end is connected to the upper end of the first rotary shaft 210, respectively, the upper end is disposed spaced in the left and right direction, respectively.

Second mounting parts 221 on which the second rotation shaft 230 is installed are formed at upper ends of the left and right sides of the support 220, respectively.

The second mounting portion 221 is formed in a cylindrical shape, is disposed long in the left and right direction, consisting of two are provided on the upper left and right of the support 220, respectively.

In addition, the second mounting portions 221 are formed to be open in a direction facing each other, that is, left and right, respectively, and the second rotation shaft 230 and the control module are installed therein.

The second rotation shaft 230 has a cylindrical shape and is formed long in the left and right direction.

In addition, the second rotating shaft 230 is formed of two and disposed in a direction facing each other on the second mounting portion 221 of the support 220.

In addition, one end of the second rotating shaft 230 is connected to the reflecting plate 300, and the other end of the second rotating shaft 230 is rotatably mounted to the second mounting portion 221 to rotate in the circumferential direction of the second rotating shaft 230.

In this case, one end of the second rotation shaft 230 is an end in the direction of the reflecting plate 300, and the other end means an end in the upper direction of the support 220.

In addition, a plurality of second locking grooves 231 are formed at one end of the second rotation shaft 230 in the circumferential direction.

The second locking groove 231 is formed concave in the direction of the center of the second rotary shaft 230, the second locking member 430 of the control module in accordance with the rotation of the second rotary shaft 230 as will be described later ) Is inserted and placed.

As described above, the first rotation shaft 210 is formed to be elongated in the vertical direction to be mounted on the base 100 to be rotated, and the second rotation shaft 230 is formed to be elongated in the left and right directions to be mounted to the support 220. By doing so, while fully adjusting the angle adjustment range of the reflecting plate 300 to rotate the reflecting plate 300 in the left and right and up and down directions to minimize the moving range of the reflecting plate 300, thereby reducing the installation space of the light collecting device It can be effective.

In addition, a plurality of first catching grooves 211 into which the first catching member 410 is inserted are formed in the first rotation shaft 210 in the circumferential direction, and the second catching member (2) is formed on the second rotating shaft 230. A plurality of second catching grooves 231 into which the 430 is inserted are formed in the circumferential direction, so that when the rotational force is removed from the first rotating shaft 210 and the second rotating shaft 230, the first rotating shaft 210 and the first rotating shaft 210 are formed. The second rotation shaft 230 may be stopped at a rotated angle to maintain the angle of the reflector 300 at a constant level, and may be prevented from rotating arbitrarily.

The reflecting plate 300 is formed of a mirror of a circular shape, is mounted to the angle adjusting unit 200 and rotates in the left or right direction or up and down direction.

In addition, as shown in FIG. 5, the reflective plate 300 is formed such that one surface of the solar cell 120 is concave in the opposite direction of the solar cell 120.

The reflection plate 300 reflects the sunlight toward the solar cell 120.

As described above, the reflective plate 300 is formed such that one surface of the solar cell 120 is concave in the opposite direction of the solar cell 120 so that the solar light is more concentrated in the solar cell 120 direction. Has the effect of improving the power generation efficiency.

On the other hand, the control module is a device for controlling the rotation angle of the angle adjusting unit 200, it consists of a manual control module 400 and the automatic control module 500.

3 to 5, the manual control module 400 includes a first catching member 410, a first elastic member 420, a second catching member 430, and a second elastic member 440. )

The first catching member 410 is inserted into the first mounting part 110 of the base 100 and is mounted to slide in the direction of the first rotation shaft 210.

In addition, one end of the first catching member 410 is formed to protrude in a triangular shape and is inserted into the first catching groove 211.

The first elastic member 420 is disposed at the other end of the second locking member 430.

The first elastic member 420 is made of a coil spring, is inserted into the first mounting portion 110 of the base 100, is mounted to surround the other end of the first locking member 410.

One end of the first elastic member 420 is in contact with the first locking member 410, and the other end is in contact with the inner surface of the first mounting unit 110 to contact the first locking member 410 with the first rotation shaft. Elastic support in the (210) direction.

The second catching member 430 is inserted into the upper end of the support 220 and is mounted to slide in the direction of the second rotation shaft 210.

In addition, one end of the second catching member 430 is formed to protrude in a triangular shape and is inserted into the second catching groove 231.

The second elastic member 440 is disposed at the other end of the second locking member 430.

The second elastic member 440 is made of a coil spring, is inserted into the upper end of the support 220, is mounted to surround the other end of the second locking member 430.

The second elastic member 440 has one end in contact with the second locking member 430 and the other end is in contact with the inner surface of the support 220 to contact the second locking member 430 with the second rotation shaft 230. Elastic support in the) direction.

The first catching member 410 and the second catching member 430 respectively have the first catching groove 211 and the first catching according to the rotation of the first rotating shaft 210 and the second rotating shaft 230. It is inserted into the second locking groove 231, so that the first rotary shaft 210 and the second rotary shaft 230 is stopped at the rotated angle.

Thus, the control module is made of the manual control module 400, it is possible to manually adjust the rotation angle of the first rotary shaft 210 and the second rotary shaft 230 without a separate drive device to simplify the overall structure It has the effect of reducing energy consumption.

Meanwhile, as shown in FIG. 4, the automatic control module 500 includes a sensor 510, a first driving motor 520, a second driving motor 530, and a controller 540.

The sensor 510 is mounted on the reflective plate 300, and tracks the position of the sun as the position of the sun changes and transmits the position value to the controller 540.

The first driving motor 520 is inserted into and mounted in the first mounting unit 110 of the base 100, is disposed in the vertical direction, is connected to the first rotating shaft 210, and the first rotating shaft 210. Rotate).

The second driving motor 530 is inserted into the upper end of the support 220, is disposed in the left and right direction, is connected to the second rotary shaft 230 to rotate the second rotary shaft 230.

The control unit 540 operates the first driving motor 520 and the second driving motor 530 according to the position of the sun tracked through the sensor 510 to operate the first rotation shaft 210 and the first driving shaft 210. The angle of rotation of the two rotary shafts 230 is controlled.

That is, the controller 540 rotates the first and second rotation shafts 210 and 230 so that the sunlight reflected by the reflector 300 is directed toward the solar cell 120 as the sun moves. Rotate

As such, the control unit 540 operates the first driving motor 520 and the second driving motor 530 according to the position of the sun tracked through the sensor 510 and the first rotation shaft 210. By controlling the angle of rotation of the second rotary shaft 230, the angle between the first rotary shaft 210 and the second rotary shaft 230 is automatically adjusted according to the position of the sun to facilitate the use. .

Of course, in some cases, the control module may be made of any one of the manual control module 400 and the automatic control module 500.

It describes the operation of the solar cell condenser device according to an embodiment of the present invention made of the above configuration.

FIG. 7A is a cross-sectional view illustrating a state of the manual control module 400 when the first rotation shaft 210 is stopped.

As shown in FIG. 7A, when the first rotation shaft 210 is stopped, the first locking member 410 is inserted into the first locking groove 211 so as to be inserted into the first rotation shaft 210. And the second rotation shaft 230 is not arbitrarily rotated.

When the second rotary shaft 230 is stopped, the same as when the first rotary shaft 210 is stopped, detailed description thereof will be omitted.

FIG. 6 is a perspective view of a state in which the first rotation shaft 210 and the second rotation shaft 230 are rotated, and FIGS. 7 (b) and 7 (c) show an operating state of the manual control module 400 at this time. It is sectional drawing shown.

As the sun's position changes, the sensor 510 tracks the sun's position in real time and sends the measured value to the controller 540.

Then, the control unit 540 drives the first driving motor 520 and the second driving motor 530 as shown in FIG. 6 to operate the first rotating shaft 210 and the second rotating shaft 230. Rotate

As shown in FIG. 7B, when the first rotation shaft 210 rotates, the first catching member 410 compresses the first elastic member 420 and the outside of the first mounting part 110. It moves in the direction and is separated from the first locking groove 211.

Thereafter, when the first rotation shaft 210 further rotates, as illustrated in FIG. 7C, the first locking member 410 is adjacent to another first elastic member by the elastic restoring force of the first elastic member 420. It is inserted into the locking groove 211.

Since the operation of the second locking member 440 is the same as that of the first locking member 410 when the second rotation shaft 230 rotates, a detailed description thereof will be omitted.

The process is repeated as the first rotary shaft 210 and the second rotary shaft 230 continue to rotate.

According to this process, the controller 540 controls the rotation angles of the first rotation shaft 210 and the second rotation shaft 230 so that the sunlight reflected through the reflector 300 is directed toward the solar cell 120. Face it.

In some cases, the first rotating shaft 210 and the second rotating shaft 230 may be manually rotated by the controller 540 instead of automatically rotating.

As described above, the angle adjusting unit 200 including the first rotating shaft 210 and the second rotating shaft 230 is mounted to the base 100 and rotates in a left or right direction or an up and down direction, thereby positioning the sun. As a result, the power generation efficiency is improved by concentrating sunlight on the solar cell 120 by adjusting the angle of the reflector 300, and driving the lens 110 separately from the solar cell 120 when adjusting the angle of the reflector 300. Energy consumption can be reduced, and a single light collecting device can reflect sunlight on the plurality of solar cells 120, thereby reducing the initial installation cost.

The solar collector concentrator of the present invention is not limited to the above-described embodiment, and can be variously modified and implemented within the range in which the technical idea of the present invention is allowed.

100: base, 110: first mounting portion, 120: solar cell, 200: angle adjusting portion, 210: first rotating shaft, 211: first locking groove, 220; Support, 221: second mounting portion, 230: second rotary shaft, 231: second locking groove, 300: reflector, 400: manual control module, 410: first locking member, 420: first elastic member, 430: second locking Member, 440: second elastic member, 500: automatic control module, 510: sensor, 520: first drive motor, 530: second drive motor, 540: controller,

Claims (5)

A base provided with a solar cell;
An angle adjusting unit mounted on the base and rotating in a horizontal direction or a vertical direction;
A reflection plate mounted on the angle adjusting unit and rotating in a left-right direction or a vertical direction and reflecting sunlight in the direction of the solar cell;
A control module for controlling the rotation angle of the angle adjusting unit; Condensing device for a solar generator, characterized in that consisting of. The method of claim 1,
The angle adjustment unit,
A first rotation shaft formed to be elongated in an up and down direction, the lower end being rotatably mounted on the base;
A support protruding from the upper end of the first rotating shaft in left and right directions;
A second rotating shaft formed in a left and right direction, one end of which is connected to the reflecting plate and the other end of which is rotatably mounted on the support; Condensing device for a solar generator, characterized in that consisting of. The method of claim 2,
The control module is made of a manual control module,
The manual control module,
A first catching member mounted on the base to slide in the first rotational axis direction;
A first elastic member elastically supporting the first locking member in the first rotation axis direction;
A second catching member mounted on the first support to be slidably moved in the second rotation axis direction;
A second elastic member elastically supporting the second locking member in the direction of the second rotation axis; Including but not limited to,
The first rotary shaft is formed with a plurality of first locking groove in the circumferential direction is inserted into the first locking member,
The second rotating shaft has a plurality of second locking grooves in the circumferential direction are inserted in the circumferential direction, the first rotary shaft and the second rotary shaft when the rotational force is removed from the first rotary shaft and the second rotary shaft Condensing device for solar generator, characterized in that to be stopped at this rotated angle. The method of claim 2,
The control module is composed of an automatic control module,
The automatic control module,
A sensor for tracking the position of sunlight;
A first driving motor mounted to the base and connected to the first rotation shaft to rotate the first rotation shaft;
A second driving motor mounted to an upper end of the support and connected to the second rotating shaft to rotate the second rotating shaft;
A control unit configured to control the rotation angle of the first rotational shaft and the second rotational shaft by operating the first driving motor and the second driving motor according to the position of the sun tracked by the sensor; Condensing device for solar generator, characterized in that comprises a. The method according to any one of claims 1 to 4,
The reflecting plate is a solar cell condenser device, characterized in that one surface in the solar cell direction is formed concave in the opposite direction of the solar cell.

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