KR101309831B1 - Photovoltaic module angle control apparatus - Google Patents

Abstract

PURPOSE: A photovoltaic module angle control apparatus is provided to easily control an angle by preventing the change of a rotation angle. CONSTITUTION: A support unit supports one side of a photovoltaic module. An elevating unit raises the other side of the photovoltaic module. A second frame (210) is parallel to a first frame. A shaft (220) rotates in a mounting space. A drive motor (230) rotates the shaft.

Description

Photovoltaic module angle control apparatus

The present invention relates to a solar cell module angle adjusting device, and more particularly, to a photovoltaic module angle adjusting device that can uniformly and easily adjust the angle of the solar cell module.

In general, widely used fossil energy is limited in amount, and sometime it is exhausted and emits various pollutants, so most countries are developing alternative energy that can be used instead.

There are many kinds of energy that can replace fossil energy, tidal wave to generate energy using tidal difference, wave power to generate energy using waves, wind power to generate energy using wind power, And there is geothermal heat that generates energy using heat in the ground, and there is solar energy that is the source of these energy.

The use of these various alternative energy has been practically used, and one of them is the use of solar energy for power generation and heating.

The method of using solar energy is largely divided into a method using solar heat and a method using solar light. The method of using solar heat is to heat and generate electricity using water heated by the sun, and the method of using solar power generates electricity using the light of the sun so that various kinds of machines and appliances can be operated by this electricity. It is called solar power.

Among them, photovoltaic power generation is to convert the light energy of the sun directly into electrical energy using a photoelectric converter called a solar cell, and it is a stand-alone type that uses the generated electricity without connecting to the power grid, depending on whether the power system is connected or not. It is a system-connected type that connects the generated electricity to the power grid and sends it to the power supply company, and sells the surplus electricity to the power company. It is distinguished, and it can be used even on a cloudy day because it uses light in part, so the use efficiency of solar energy is higher than that of solar power generation.

Since the solar power generation uses unlimited, non-polluting solar energy, fuel costs are unnecessary, there is no air pollution or waste generation, and since the power generation part is a semiconductor device and the control unit is an electronic component, there is no mechanical vibration and noise. In addition, the solar cell has a long life of at least 20 years, easy to automate the power generation system, and has the advantage of minimizing the cost of operation and maintenance.

As the solar cell used for the photovoltaic power generation as described above, silicon and a composite material are usually used. Specifically, a solar cell uses a P-type semiconductor and an N-type semiconductor in combination, and utilizes a photoelectric effect to generate electricity by receiving sunlight. Most solar cells are composed of a large area P-N junction diode, and the electromotive force generated at the anode end of the P-N junction diode is connected to an external circuit.

The minimum unit of such a solar cell is called a cell, and practically, a solar cell is rarely used as it is. Although the voltage required for actual use is more than a few tens or hundreds of volts, the voltage output from one cell is about 0.5V, which is very small. have.

In addition, when solar cells are used outdoors, they are placed in various environments, so that a plurality of cells are packaged in a solar cell module to protect a plurality of cells connected in a required unit capacity in a harsh environment. Configure and use.

The solar cell module, because it must be used in large quantities to obtain a constant power is limited in the installation place. That is, the solar cell module does not have any problem when installed on the roof of the building or outdoor facilities, but when installed in a multi-unit housing that occupies a large number of houses, there is a problem that individual installation in the household is difficult. In addition, due to the characteristics of the photovoltaic power generation system having a change in efficiency according to the angle of solar light, the solar cell module should be installed on the roof of a building, a roof, or a separately set prop.

However, in the solar cell structure according to the prior art, due to the structural characteristics of combining the frame and the other frame by using a bracket, when a strong wind is blown or a big shock is applied, the screw fixing the bracket is loosened or the bracket is bent, The frame structure is warped, and there is a problem in that the frame is broken and the solar cell module is broken.

In addition, it has a change in power generation efficiency according to the angle of sunlight, because it is fixed type, it does not effectively cope with the domestic situation where the four seasons are distinct and there are altitude differences by region.

In order to solve the above problems, Korean Patent Publication No. 10-2010-0032501 discloses a solar cell module angle adjusting device, and Korean Patent Publication No. 10-2013-0006778 discloses a solar cell module holder. , Republic of Korea Patent No. 10-1035388 discloses a solar structure capable of adjusting the angle.

However, the solar cell module holder of the Republic of Korea Patent Publication No. 10-2013-0006778 and the solar structure that can be adjusted angle of the Republic of Korea Patent Registration No. 10-1035388 has a problem that the operator must directly manipulate the angle of the solar cell module.

On the other hand, the angle adjustment device of the solar cell module plate of the Republic of Korea Patent Publication No. 10-2010-0032501 is provided with a motor to automatically rotate the base horizontal axis by the motor, but fixed to the solar cell module plate rotated by the motor In order to do so, there is a problem in that the operator must directly operate as described above.

The present invention is to solve the conventional problem as described above, while being able to automatically rotate the solar cell module at an angle corresponding to the incident angle of solar light, the solar cell module so that the rotation angle of the solar cell module is not changed by external force It is an object of the present invention to provide a solar cell module angle control device that can be firmly supported.

Solar cell module angle adjusting device according to the present invention for achieving the above object is installed on the lower side of the edge of the solar cell module and a support unit for supporting one side of the solar cell module; And an elevating unit installed below the other edge of the solar cell module facing the support unit to elevate the other side of the solar cell module.

The support unit extends in a direction parallel to one side of the edge of the solar cell module and is fixed to a target surface on which the solar cell module is installed, and a lower portion of one side of the solar cell module with respect to the first frame. And a rotation support bracket installed between the first frame and the solar cell module so as to be rotatably supported, wherein the elevating unit extends in a direction parallel to the other edge of the solar cell module and is a predetermined distance from the first frame. A second frame disposed parallel to the first frame at a spaced apart position and having an upper portion open and a mounting space provided therein; and rotatably installed in the mounting space and opposite to each other on both sides of the length center A threaded shaft, a drive motor for rotating the shaft, and screwed to the shaft to First and second sliders rotatably coupled to each other relative to each other based on the length center of the shaft or moving away from each other based on the length center of the shaft; A first support link, the other end of which is rotatably coupled to the other side of the edge of the solar cell module, and the other end of the first support link, which is rotatably coupled to the second slider and crosses the first support link; And a second support link rotatably coupled to the other side of the edge of the solar cell module spaced apart from the other side of the support link by a predetermined distance.

Both ends of the shaft is characterized in that the coupling portion is formed so as to rotate in conjunction with the shaft is installed adjacent to each other in parallel with the shaft.

Both ends of the shaft are characterized in that the coupling portion is formed so as to rotate in conjunction with the shaft is installed adjacent to each other in the direction parallel to the shaft.

The shaft may include a first portion having a first threaded portion toward one end of the shaft based on the center of length of the shaft, and a second threaded portion toward the other end of the shaft based on the length of the shaft. And a second coupling portion, wherein the coupling portion includes a first coupling portion formed at an end portion of the first portion and a second coupling portion formed at an end portion of the second portion and fitted with the first coupling portion. It is done.

According to the solar cell module angle adjusting device according to the present invention, while being able to rotate the solar cell module uniformly and automatically at an angle corresponding to the angle of incidence of sunlight, the solar cell module is not changed by an external force. It can be firmly supported.

1 is a perspective view showing an installation state of a photovoltaic module using the solar cell module angle control device according to the present invention.
Figure 2 is a perspective view showing an operation example of the solar cell module angle adjustment device shown in FIG.
3 is a perspective view showing another operation example of the solar cell module angle adjustment device shown in FIG.

Hereinafter, a solar cell module angle control device according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail. 1 to 4 illustrate a solar cell module angle adjusting device according to the present invention.

1 to 4, the solar cell module angle adjusting device 1 according to the present invention is installed below one side of the edge of the solar cell module 10 to support one side of the solar cell module 10. Unit 100; And a lifting unit 200 installed below the edge of the solar cell module 10 facing the support unit 100 to lift the other side of the solar cell module 10.

The support unit 100 is configured to include a first frame 110 and the rotation support bracket 120. In addition, the first frame 110 is formed in a hollow rectangular pipe shape, and extends in a direction parallel to one side of the edge of the solar cell module 10, the installation target surface for installing the solar cell module 10 (2) It is fixed to the bottom surface (in this embodiment, the roof panel is applied), the upper side of one side of the four edges of the solar cell module 10 to support the lower side of the edge of the solar cell module 10 It extends alongside the sides.

Hereinafter, for convenience of description, one side of four edges of the solar cell module 10 is called a first side, and the other side of the solar cell module 10 parallel to the first side is called a second side.

The rotation support bracket 120 is disposed between the first frame 110 and the solar cell module 10 so as to rotatably support the lower side of the first side 11 of the solar cell module 10 with respect to the first frame 110. Installed in The rotation support bracket 120 is preferably applied to a conventional hinge.

Since the first edge side 11 of the solar cell module 10 is rotatable on the first frame 110 by one side edge of the support bracket 120, the second side side of the solar cell module 10 ( 12) can be lifted. That is, by adjusting the degree of lifting the second side 12 of the solar cell module 10 while fixing the first side 11 of the solar cell module 10 is incident to the solar cell module 10 The angle of incidence of sunlight can be adjusted.

Performing the degree of lifting the second side 12 of the solar cell module 10 will be described in detail in the lifting unit 200 described below.

The lifting unit 200 is for adjusting the angle of the solar cell module 10, that is, the incident angle of sunlight incident on the solar cell module 10, and the second frame 210, the shaft 220, and the driving motor ( 230, a first slider 240 and a second slider 250, a first support link 260, and a second support link 270, although not shown in the drawing, may include a driving motor 230. It includes a control panel for performing the control.

The second frame 210 extends in a direction parallel to the second side 12 of the solar cell module 10 and is parallel to the first frame 110 at a position spaced apart from the first frame 110 by a predetermined distance. It is arranged, the upper part is opened and a mounting space is provided inside.

The second frame 210 is connected to the first frame 110 by an extension frame 150 extending from both ends of the first frame 110 to both ends of the second frame 210.

One end and the other end of the shaft 220 are rotatably supported by the second frame 210, respectively, and are installed to be rotatable in a mounting space. The first screw part and the second screw part are formed on opposite sides of the shaft center with respect to the length center of the shaft 220.

The shaft 220 may include a first portion 221 having a first threaded portion formed toward the one end portion from the center of the length of the shaft 220 and a second threaded portion formed toward the other end portion from the length center of the shaft 220. It consists of the 2nd part 222 and the 3rd part 223 which has a circular cross section in which neither the 1st thread part nor the 2nd thread part is formed between the 1st part 221 and the 2nd part 222. As shown in FIG.

The first slider 240 and the second slider 250, which will be described later, are respectively screwed to the first portion 221 and the second portion 222, and the support plate 280, which will be described later, is attached to the third portion 223. The bearing member 290 for rotatably supporting the shaft 220 is installed.

The first threaded portion is formed in a direction corresponding to the clockwise direction from the center of the length of the shaft 220 toward one end, and the second threaded portion corresponding to the counterclockwise direction from the length of the shaft 220 toward the other end thereof. Is formed in the direction. Alternatively, the directions of the first threaded portion and the second threaded portion may be reversed.

Coupling portions are formed at both ends of the shaft 220 to rotate the shaft 220 of another solar cell module angle adjusting device adjacent through one solar cell module angle adjusting device.

Coupling portion is coupled to the first coupling portion 225 formed at the end of the first portion 221 of the shaft 220, the second coupling portion formed on the end of the second portion 222 and the rotating shaft of the drive motor 230 to be described later Part 226 is included.

The first coupling portion 225 has a coupling protrusion protruding from the end of the first portion 221 to be inserted into the second coupling portion, the second coupling portion 226 is the first coupling portion 225 A coupling groove corresponding to the shape of the coupling protrusion is formed so that the protrusion of the protrusion may be inserted.

Coupling projection of the first coupling portion 225 is formed to have a predetermined thickness and a sliding surface of a predetermined area in the direction orthogonal to the longitudinal direction of the first portion 221, the coupling groove of the second coupling portion 226 Silver is formed in a slot structure that can be fitted to the engaging projection.

Although not shown in the drawings, the coupling part is a coupling holding member for maintaining the coupling between the first coupling portion 225 and the second coupling portion 226 through the first coupling portion 225 and the second coupling portion 226. (Not shown), and the coupling holding member applies a piece member fastened to penetrate the second coupling portion 226 and the first coupling portion 225 from the outside of the second coupling portion 226. can do.

The first coupling part 225 installed in the first part 221 of the solar cell module angle adjusting device of one side is coupled to the second coupling part 226 of the driving motor 230, and to the second part 222. The installed second coupling part 226 is coupled to the first portion 221 of the shaft 220 installed in the angle adjusting device of the solar cell module 10 installed adjacent to the solar cell module angle adjusting device on one side. It is coupled to the first coupling portion 225.

Therefore, when the shaft 220 of the solar cell module angle adjusting device of one side rotates by the driving motor 230, the shaft 220 installed in the adjacent solar cell module angle adjusting device rotates together.

The control panel (not shown) controls the operation of the drive motor 230, and is capable of adjusting the forward / reverse rotation speed and the forward / reverse rotation speed of the drive motor 230, and the season of the drive motor 230 Forward / reverse rotation speed and forward / reverse rotation speed can be set differently. For example, in the summer, since the sun is higher than the winter, the rotation speed of the driving motor 230 may be set smaller than in the winter.

The driving motor 230 is installed on one side of the second frame 210 by rotating the shaft 220, the first coupling portion 225 formed on the first portion 221 of the shaft 220 on the rotating shaft A second coupling portion 226 coupled to the is coupled.

The first slider 240 and the second slider 250 are screwed to the first portion 221 and the second portion 222 of the shaft 220, respectively, and are operated in the forward / reverse rotation of the driving motor 230. Accordingly, the shaft 220 moves in a direction closer to each other based on the length center of the shaft 220, that is, the third portion 223, or moves away from each other based on the third portion 223. That is, the first slider 240 and the second slider 250 simultaneously move toward the third portion 223 or simultaneously away from the third portion 223 according to the operation of the driving motor 230. do.

The first support link 260 has a predetermined length, one end of which is rotatably coupled to the first slider 240 and the other end of which is rotatable to the second side 12 of the solar cell module 10. Are combined.

The second support link 270 has a length corresponding to the first support link 260, one end of which is rotatably coupled to the second slider 250, and the other end of the second support link 260 to intersect the first support link 260. It is rotatably coupled to the second side 12 of the solar cell module 10 spaced apart from the other side of the first support link 260 by a predetermined distance.

The lifting unit 200 is a bearing member 290 coupled to the center of the length of the shaft 220 and the second frame 210 is installed in the mounting space of the second frame 210 to the first of the shaft 220 And a support plate 280 partitioning into a first mounting space for rotatably receiving the portion 221 and a second mounting space for rotatably receiving the second portion 222 of the shaft 220.

The bearing member 290 is coupled to the third portion 223 of the shaft 220 and is coupled to a hole provided in the support plate 280 to rotatably support the shaft 220 to the support plate 280.

Hereinafter, the operation of the solar cell module angle control device according to the present invention having the above-described technical configuration in detail.

When the shaft 220 is rotated forward through the driving motor 230, the first slider 240 and the second slider (screwed to the first portion 221 and the second portion 222 of the shaft 220, respectively) 250 is simultaneously moved toward the third portion 223 of the shaft 220, the first support link 260 and the second support link (260) coupled to the first slider 240 and the second slider 250 ( As the crossing angle of the 270 is narrowed, the second side 12 of the solar cell module 10 coupled to the ends of the first support link 260 and the second support link 270 is the first side 11. Will rise higher.

On the contrary, when the shaft 220 is rotated reversely through the driving motor 230, the first support link 240 and the second slider 250 simultaneously move in a direction away from the third portion 223. The crossing angle of the 260 and the second support link 270 is increased, so that the second side of the solar cell module 10 is lowered downward.

As described above, the drive motor 230 is rotated forward and backward to easily adjust the angle of the solar cell module 10 according to the altitude of the sun, and in any case when the drive motor 230 does not operate. There is no change in the angle of the solar cell module 10 has the advantage of high reliability.

On the other hand, although not shown in the drawings, the solar cell module angle adjusting device according to the present invention may further include a sensor unit including a wind volume sensor or a wind speed sensor for measuring the air volume or wind speed so as to prevent damage due to strong winds.

The sensor unit is connected to a control panel for controlling the drive motor, the control panel is further provided with a microcomputer having a memory. The sensor unit transmits the measured airflow or wind speed to the control panel, and the microcomputer adjusts the tilt angle of the solar cell module to the minimum by automatically driving the driving motor when the measured value is higher than the reference value compared with the transmitted measured value and the reference value stored in the memory. do.

As such, the solar cell module angle adjusting device including the sensor unit continuously prevents the solar cell module from being damaged by a strong wind or a typhoon caused by sudden wind speed and wind volume.

The solar cell module angle adjusting device according to the present invention described above has been described with reference to an example shown in the drawings, but this is only an example, and those skilled in the art can make various modifications and equivalents therefrom. It will be appreciated that other embodiments are possible.

Therefore, the true technical protection scope of the present invention will be defined by the appended claims.

10: solar cell module 100: support unit
110: first frame 120: rotation support bracket
150: extension frame 200: lifting unit
210: second frame 220: shaft
225: first coupling portion 226: second coupling portion
230: drive motor 240: first slider
250: second slider 260: first support link
270: second support link 280: support plate
290: bearing member

Claims (5)

A support unit installed below the edge of one side of the solar cell module and supporting one side of the solar cell module;
And an elevating unit installed below the other edge of the solar cell module facing the support unit to elevate the other side of the solar cell module.
The support unit extends in a direction parallel to one side of the edge of the solar cell module and is fixed to a target surface on which the solar cell module is installed, and a lower portion of one side of the solar cell module with respect to the first frame. It includes a rotation support bracket installed between the first frame and the solar cell module to rotatably support,
The elevating unit extends in a direction parallel to the other edge of the solar cell module and is disposed side by side with the first frame at a position spaced apart from the first frame by a predetermined distance, and an upper portion thereof is opened and a mounting space is provided therein. A frame, a shaft rotatably installed in the mounting space and formed with threads in opposite directions on both sides of the length center, a drive motor for rotating the shaft, and a length of the shaft screwed to the shaft A first slider and a second slider which move in a direction closer to each other with respect to a center or in a direction away from each other based on a length center of the shaft, and one end rotatably coupled to the first slider, and the other end A first support link rotatably coupled to the other edge of the solar cell module; One end is rotatably coupled to the second slider and the other end is rotatably coupled to the other side of the edge of the solar cell module spaced apart from the other side of the first support link so as to cross the first support link. Solar cell module angle adjustment device comprising a second support link. delete The method of claim 1,
The elevating unit further comprises a bearing member coupled to the center of the length of the shaft, and a support plate installed on the second frame to partition the mounting space and supporting the bearing member. Device Solar Module Angle Adjuster. The method of claim 3, wherein
Both ends of the shaft, the solar cell module angle adjustment device, characterized in that the coupling portion is formed so as to rotate in conjunction with the shaft is installed adjacent to each other in parallel with the shaft. 5. The method of claim 4,
The shaft may include a first portion having a first threaded portion toward one end of the shaft based on the center of length of the shaft, and a second threaded portion toward the other end of the shaft based on the length of the shaft. Including a second part,
The coupling part includes a first coupling part formed at an end of the first part and a second coupling part formed at an end of the second part and fitted to the first coupling part. Device.

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