KR200423036Y1 - solar power plant having solar tracking apparatus - Google Patents

Abstract

According to the present invention, the photovoltaic device includes a main frame, a rotating shaft installed in the north-south direction on the main frame, a subframe supported on the rotating shaft, and at least one solar power module installed on the subframe. And a single axis tracking means installed on the main frame to rotate along the sun from the time of breaking down the rotation shaft installed in the north-south direction to the time of sunset.

PV, Tracking, Rotating Shaft, Azimuth

Description

Solar power plant having solar tracking apparatus

1 is a partial ablation perspective view of the present invention showing a photovoltaic device,

2 is a perspective view showing the uniaxial tracking means,

Figure 3 is a partial ablation perspective view showing a photovoltaic device according to the present invention,

4 is a perspective view showing another embodiment of the uniaxial tracking means,

Figure 5 is a perspective view showing another embodiment of the photovoltaic device according to the present invention,

6 is a side view of the solar cell apparatus shown in FIG.

The present invention relates to a photovoltaic device, and more particularly to a photovoltaic device that can increase the light collecting efficiency of the photovoltaic module.

In general, photovoltaic technology is distinguished from solar technology using radiant heat energy transmitted from the sun. Solar power generation uses infinite clean energy, which does not require additional energy or driving source, it is simple to construct large-scale and large-scale systems, and is not affected by installation limitations due to environmental problems.

On the other hand, the amount of power generation depends on the solar radiation time, in order to obtain a large power, a large number of photovoltaic power generation module is required, it is expensive compared to commercial power, it should be noted that DC power is obtained first.

The above-described photovoltaic module tracks the position of the sun through power or device manipulation so that the sun's direct sunlight always enters the front of the photovoltaic module vertically in order to maximize power generation efficiency. There are semi-fixed type where the position is changed up and down, and fixed type is fixed regardless of altitude with the sun.

Such a solar tracking device is a device for moving a collector or a lens to increase the light collecting ability while tracking a moving sun. The tracking methods are mainly program tracking and sensor tracking. Program tracking is a tracking method in which the light receiver is rotated by inputting the movement of the sun due to the rotation and revolution of the earth to the program in advance. Sensor tracking detects the movement of sunlight with a sensor to control the direction of the light receiver, and various improvements have been made in accordance with various related element technologies. Tracking device technology includes solar position detection method, tracking member, tracking driving method, driving power.

An example of a conventional solar tracking alignment method is disclosed in Korean Utility Model Model No. 277771. The disclosed solar tracking alignment method is integrated with a solar module that focuses sunlight and includes a tracker with an encoder that rotates the solar module and detects a rotational position.

Patent No. 044021 discloses a sun tracking method of an automatic sun tracking device. According to the disclosed solar tracking method, when the normal azimuth angle of the photovoltaic module becomes a first angle behind the azimuth angle of the sun, the azimuth angle of the normal line of the photovoltaic module is advanced by a second angle than the azimuth angle of the sun. It has a configuration for driving the power generation module.

Patent No. 0483291 discloses a solar position tracking method for solar-related facilities, and Patent No. 0369897 discloses a hybrid solar tracking control device for a condensing solar collector, and in Utility Model No. 0404291, A solar tracking device having a light collecting unit for photovoltaic power generation is disclosed, and Utility Model Publication No. 199-00186 discloses an angle adjusting device for a solar panel by radio call.

As described above, the position tracking apparatus of the solar tracker that tracks the position of the sunlight has a problem that its structure is relatively complicated and the position fixing is not made accurately. In particular, it is difficult to maintain the set sun tracking angle because the bearing capacity for strong winds is weak.

The present invention is to solve the problems described above to provide a photovoltaic device that can be relatively simple in structure, and improve the power generation efficiency using solar light by trekking the photovoltaic module along the sun in the east-west direction. Has its purpose.

Another object of the present invention is to improve the bearing capacity for the wind pressure of the photovoltaic module, and to provide a photovoltaic device having a relatively simple structure for driving a plurality of photovoltaic modules.

The solar cell apparatus of the present invention for achieving the above object,

A main frame, a rotation shaft installed in the north-south direction on the main frame, a subframe supported on the rotation shaft, at least one solar power generation module installed on the subframe,

It is characterized in that it is provided on the main frame and provided with a single-axis tracking means for rotating along the sun from the time of breaking down the rotation shaft installed in the north-south direction to the time of sunset.

In the present invention, the rotation shaft installed on the main frame is preferably installed inclined so that the solar power module can face the average altitude of the sun. The single axis trekking means includes a worm wheel installed at an end of the pivot shaft and a worm installed at a drive shaft of a driving source installed at the main frame and engaged with the worm wheel.

Alternative solar power means for achieving the above object

A main frame, a rotating shaft rotatably installed on the main frame, a subframe installed on the rotating shaft, solar power modules installed on the subframe,

It is characterized in that it is provided on the main frame provided with an angle adjusting means for rotating the rotating shaft to adjust the angle of the sub-frame in which the solar power generation module is installed.

In the present invention, the angle adjusting means is a lead screw hinged to the main frame, the main body is slidably installed on the main body and the end is hinged to the sub-frame, rotatably installed on the main body and the lead screw And a worm wheel screwed with the worm, and a worm installed in the main body and engaged with the worm wheel.

Between the main frame and the sub frame may further include a position fixing means for fixing the position of the sub frame with respect to the main frame, the position fixing means is a first rod installed in the sub frame, and A second rod for slidably supporting the first rod in a longitudinal direction, a turnbuckle provided between the second rod and the main frame, and a second rod installed on the second rod, And a position fixing portion for fixing the position.

Alternatively, the solar cell apparatus of the present invention for achieving the above object,

A plurality of mainframes installed inline in the north-south direction,

Pivoting shafts provided between the main frames, connecting means for interconnecting the pivoting shafts;

A subframe installed on the pivot shaft, a solar power module installed on the subframe,

A single axis tracking means installed on the main frame to rotate the subframe with respect to the main frame;

Installed between the sub-frame and the main frame is characterized in that it is provided with a position fixing means for fixing the rotational position of the photovoltaic module.

Hereinafter, a preferred embodiment of a photovoltaic device according to the present invention will be described in detail with reference to the accompanying drawings.

The photovoltaic device of the present invention is capable of generating electricity while following the sun while the sun is set in the copper and each other, and an embodiment thereof is shown in FIGS. 1 and 2.

Referring to the drawings, the photovoltaic device 10 includes a main frame 11 installed on the ground or a building structure, a rotating shaft 12 installed in the north-south direction on the main frame 11, and the rotating shaft. It is installed in the (12) and has a sub-frame (13) for supporting the photovoltaic module (100). The subframe 13 has a support member 13a which is supported by the pivot 12 and extends in both sides. The rotatable support of the pivot shaft 12 with respect to the main frame 11 is a pillow block 12a is installed on the upper part of the main frame 11 and the rotating support to the bearing supported on the pillow block 12a. The end of the coaxial 12 is rotatably supported. However, the support of the pivot shaft 12 with respect to the main frame 11 is not limited to the above-described embodiment, and a structure capable of supporting the main frame 11 so that the subframe can be rotated in the east-west direction Anything is possible. The pivot shaft 12 with respect to the main frame 11 sets the altitude that can receive the most sunlight in consideration of the solar altitude of the four seasons, the angle that the solar power module 100 can be installed at this altitude It is preferable to set so as to maintain.

In addition, the main frame 11 is provided with a single-axis tracking means 20 for tracking the rotating shaft 12 in the east-west direction. This uniaxial tracking means 20 is provided on the worm wheel 21 provided at the end of the rotation shaft 12 and the drive shaft of the drive source 22 provided on the main frame 11, as shown in FIG. And a worm 23 for rotating the worm wheel 21 forward and backward. The drive unit 22 includes a motor 22a and a reducer 22b for reducing the rotational force of the motor 22a and transmitting the deceleration force to the worm 23. And a controller 24 having a timer for driving the motor 22a for each time zone. The control unit 24 may further include a sensor 24a that tracks the position of the sun all day and may drive the solar power module 100 to follow the sun according to the tracking unit. . The sensor may be a light amount sensor. The single axis tracking means 20 is not limited to the above-described embodiment, and any structure may be used as long as the rotating shaft 12 can be rotated forward and backward according to the position of the sun.

On the other hand, the photovoltaic device 10 according to the present invention is the main frame 11 is installed inline in the north-south direction as shown in Figure 3, the main frame 11 is connected to the main frame supported The rotating shafts 12 are coaxially connected by means 30 and the rotating shafts 12 are rotated forward and reverse by the single axis tracking means 40. The connecting means 30 connecting the pivot shafts 12 is connected to a bearing on a main frame 11 positioned at a center portion of the pivot shaft 12, that is, a main frame 11 positioned between the pivot shafts 12. It has a connecting shaft 31 which is supported by and coupled to both ends of the corresponding shaft of the rotating shaft 12 to be connected coaxially. Coupling of the end of the rotation shaft 12 to the connecting shaft 31 is coupled by a separate fixing means, the fixing means is a pin penetrating the end of the rotating shaft 12 is coupled to the connecting shaft 31 ( 32). When the single-axis tracking means 40 is installed at the end of the rotating shaft of one side has the same structure as the above embodiment. However, the uniaxial tracking means 40 may be installed in the connecting means 30 to minimize the torsional force on the connected pivot shafts 12. Although the single-axis tracking means is not shown in the drawing, a worm driven by a drive unit for installing the worm wheel and driving the connecting shaft may be engaged. The single axis tracking means may be formed of a drive gear by a drive having a gear installed on the connecting shaft, meshed with the gear, and having a brake means.

5 and 6 show another embodiment of the photovoltaic device according to the present invention.

Referring to the drawings, the photovoltaic device 50 includes a main frame 51, a rotation shaft 52 rotatably installed on the main frame 51, on which the sub frame 53 is supported, and the sub frame ( 53 is provided with a solar power module 100 is installed. Here, the rotation shaft 52 with respect to the main frame 51 is preferably installed in the east-west direction.

In addition, the main frame 51 is provided with an angle adjusting means 60 for rotating the rotating shaft 52 to adjust the angle of the sub-frame 53 in which the photovoltaic module of the rotating shaft 52 is installed. do. The angle adjusting means 60 may be composed of a worm wheel installed at the end of the rotating shaft 52 and the worm wheel meshed with the worm wheel and driven by a driving unit, such as a single axis tracking means. The angle adjusting means 60 is not limited to the above-described embodiment, any structure that can adjust the angle of the photovoltaic module 100 by rotating the pivot shaft 52 according to the altitude of the seasonal sun. It is possible.

For example, the angle adjusting means 60 is a lead screw (65a) is hinged to the main frame 51, slidably installed on the main body (65a) and the end screw hinged to the sub-frame (53) 65b), a worm wheel 65c rotatably installed on the main body 65a and screwed with the lead screw 65b, and a worm 65d installed on the main body 65a and engaged with the worm wheel 65c. It is provided. Here, the upper portion of the main body (65a) is provided with a housing (65e) is coupled to the worm wheel (65c) and the worm (65d) and protrudes out of the housing of the rotation shaft of the worm can be driven by a handle or a separate drive motor have.

Meanwhile, in the above embodiments, a position fixing means 70 may be further provided to protect the photovoltaic module from strong winds. The position fixing means 70 may be installed at the subframe 53. A first rod 71, a second rod 72 for slidably supporting the first rod 71 in the longitudinal direction, and a turnbuckle installed between the second rod 72 and the main frame ( 73 and a position fixing part 75 installed on the second rod 72 to fix the position of the first rod 73 with respect to the second rod 72. The position fixing part 75 may be formed of a pin or a bolt and a nut penetrating the first and second rods 71 and 72.

Slidable coupling of the first and second rods 71 and 72 should be able to slide without deviating from each other within an angle range in which the rotation shaft is rotated. In particular, in the case of the single-axis trekking means it should be able to fix the relative position of the first and second rods by the position fixing unit 75 in the emergency while maintaining the sliding state.

Referring to the operation of the photovoltaic device according to the present invention configured as described above are as follows.

The solar cell apparatus 10 according to the present invention is driven by the drive unit of the single-axis tracking means 20 when the sun rises in the copper to rotate the rotating shaft 12 clockwise to correspond to the sun. Therefore, since the photovoltaic module 100 installed in the subframe 13 corresponds to the sun, the solar power module 100 may be exposed to sunlight as much as possible and may receive a large amount of light from the sun.

In this state, the azimuth angle changes as the sun moves along the ecliptic over time, and the azimuth angle of the solar light emitting module and the azimuth angle of the sun are recognized by the sensor, and the motor is driven according to the information of the sensor. The rotating shaft 12 is rotated at a predetermined angle. Therefore, as the solar power generation module 100 follows the sun all day, the power generation efficiency may be maximized.

In this process, since the rotation shaft 12 supported by the main frame 11 is installed in the north-south direction, the solar power generation module 100 supported by the subframe 13 thereof is rotated in the east-west direction. That is, as the sun moves along the ecliptic, the sun rotates in the east-west direction, so that the sun can follow the sun in the east-west direction while the sun is floating, thereby enabling the most efficient power generation. Such tracking of the sun can maximize the efficiency of the photovoltaic module 100 while the structure is relatively simple compared to the estimation in consideration of the orientation and altitude of the sun as in the prior art. In particular, as shown in FIG. 3, when the shaft rotated in the north-south direction is connected by the connecting means, the rotating shaft 12 may be rotated by one single axis tracking means 20.

Meanwhile, as shown in FIGS. 5 and 6, when the rotation shaft 52 is installed in the east-west direction, the best elevation angle for each season or period may be maintained by rotating the rotation shaft 52 in consideration of the elevation angle of the sun.

In addition, since the main frame 11 has a position fixing means 70 for fixing the position of the sub-frame 13 in which the solar power generation module 100 is installed with respect to the main frame when a super strong wind blows, such as a position typhoon. In addition, it is possible to prevent the generator from being damaged by strong winds. That is, the second rod 72 is fixed to the first rod 71 by the fixing unit 75 and the tension is adjusted using the turnbuckle, so that the angle adjusting means and the position fixing means are shown in FIG. As a result, the position of the subframe 13 can be fixed.

As described above, the photovoltaic device according to the present invention can follow the sun in the trajectory of the ecliptic, i.e., the east-west direction, by installing a rotation axis in the north-south direction, thus increasing the light condensing efficiency of the photovoltaic monthly or seasonally. As the angle of the photovoltaic module according to the altitude of the sun can be adjusted manually or automatically, it can maximize the amount of power generated. In addition, it is possible to increase the degree of freedom of design because the structure of the solar tracking is simple.

 Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments are possible.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

Claims (7)

A main frame, a rotation shaft installed in the north-south direction on the main frame, a subframe supported on the rotation shaft, at least one solar power generation module installed on the subframe, And a single axis tracking means installed on the main frame to rotate along the sun from the time of breaking down the rotation shaft installed in the north-south direction to the time of sunset. The method of claim 1, The rotating shaft installed on the main frame is installed to be inclined so that the solar power module can face the average altitude of the sun. The single axis trekking means has a worm wheel installed on the end of the rotating shaft, and a worm is installed on the drive shaft of the drive source is installed on the main frame and the worm wheel is characterized in that it is provided with the worm wheel. A main frame, a rotating shaft rotatably installed on the main frame, a subframe provided on the rotating shaft, solar power modules installed on the subframe, The solar cell apparatus, characterized in that provided with an angle adjusting means for rotating the rotating shaft to adjust the angle of the sub-frame is installed in the main frame the solar power generation module is installed. The method of claim 3, wherein The angle adjusting means is a main body hinged to the main frame, the lead screw is slidably installed on the main body and the end is hinged to the sub-frame, rotatably installed on the main body and screwed with the lead screw And a worm wheel, and a worm installed on the main body and having a worm engaged with the worm wheel. The method according to claim 3 or 4, A first rod installed on the subframe, a second rod slidably supporting the first rod in a longitudinal direction, a turnbuckle provided between the second rod and the mainframe, and the second rod And a position fixing means having a position fixing portion installed to fix the position of the first rod with respect to the second rod. A plurality of mainframes installed inline in the north-south direction, Pivoting shafts provided between the main frames, connecting means for interconnecting the pivoting shafts; A subframe installed on the pivot shaft, a solar power module installed on the subframe, Single axis tracking means installed on the main frame for rotating the sub-frame relative to the main frame, And a position fixing means installed between the subframe and the main frame to fix the rotation position of the photovoltaic module. The method of claim 6, A first rod installed on the subframe, a second rod slidably supporting the first rod in a longitudinal direction, a turnbuckle provided between the second rod and the mainframe, and the second rod And a position fixing means having a position fixing portion installed to fix the position of the first rod with respect to the second rod.

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