KR20170034978A - Apparatus for solar energy generation - Google Patents

Abstract

The present invention relates to a photovoltaic power generation apparatus and, more specifically, to a photovoltaic power generation apparatus which automatically tracks the sun to improve photovoltaic power generation efficiency. According to the present invention, the photovoltaic power generation apparatus comprises: a solar battery panel unit consisting of a plurality of unit solar battery panels; a panel support unit which supports the solar battery panel unit to be rotated in a left and a right direction along a daily path of the sun, and mounts the unit solar battery panels to be separated in the left and the right direction to eliminate shade interference during rotation; an illumination sensor unit including a first illumination sensor mounted on a right corner of each unit solar battery panel and a second illumination sensor mounted on a left corner of each unit solar battery panel to sense shade interference between the unit solar battery panels in the left and the right direction; and a panel control unit to rotate the solar battery panel unit in the left and the right direction to allow the solar battery panel unit to follow the daily path of the sun, and recognize shade interference to control a rotational operation if a difference in illuminance between first illumination sensors adjacent to each other in the left and the right direction occurs, or a difference in illuminance between second illumination sensors adjacent to each other in the left and the right direction occurs.

Description

[0001] APPARATUS FOR SOLAR ENERGY GENERATION [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar power generation apparatus, and more particularly, to a solar power generation apparatus capable of automatically tracking a sun to improve solar power generation efficiency.

Generally, most photovoltaic devices are of a fixed type. That is, the solar panel is fixed by fixing the solar panel on the metal structure. Considering that the efficiency of a commercially available solar cell panel is 18% or less, it is not possible to secure the efficiency of the solar cell panel by constructing a solar cell having a low power generation efficiency fixedly, and there is a problem of wasting an expensive solar cell panel have.

In recent years, devices and facilities for tracking the trajectory of the sun have been attempted in order to increase the power generation efficiency of the solar panel. However, in the conventional tracking solar PV devices, the efficiency of the solar panel itself is high, The efficiency is not higher than that of the stationary power generation facilities, and there are problems such as frequent breakdown due to complicated structure and malfunction.

Korean Registered Patent No. 10-0721002 (May 16, 2007)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solar power generation device capable of improving power generation efficiency by optimizing an incident angle of sunlight to a solar cell panel by tracking a day- have.

It is another object of the present invention to provide a photovoltaic power generation apparatus capable of accurately and reliably tracing a day trajectory of sunlight through a correction operation.

Another object of the present invention is to provide a solar power generation apparatus capable of accurately and reliably tracking the annual altitude of sunlight to improve power generation efficiency.

Another object of the present invention is to provide a photovoltaic power generation apparatus capable of accurately rotating the solar cell panel in the left and right direction at a constant time per unit time so as to accurately perform a turning operation according to the daytime trajectory.

It is another object of the present invention to provide a solar power generator capable of improving condensing efficiency and cooling efficiency by using a reflective panel and preventing wind resistance in a reflective panel and achieving air cooling efficiency.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems to be solved by the present invention, which are not mentioned here, As will be appreciated by those skilled in the art.

A solar photovoltaic device according to the present invention includes: a solar cell panel unit comprising a plurality of unit solar cell panels; A panel support unit that supports the solar cell panel so as to be rotatable in the left and right direction according to the sun's daily trajectory and mounts the unit solar cell panels in the left and right direction away from each other in order to exclude shadow interference during the rotation operation; A first illuminance sensor mounted on the right corner of each unit solar battery panel and a second illuminance sensor mounted on the left corner of each unit solar battery panel to detect shadow interference between the unit solar battery panels in the left and right direction A light intensity sensor unit; And the solar panel section is rotated in the left and right direction so as to follow the sun's day trajectory. However, the illuminance value difference between the first illuminance sensors adjacent to each other in the left-right direction occurs, or the illuminance value between the neighboring second illuminance sensors And a panel control unit for recognizing the occurrence of shadow interference and controlling the turning operation when a difference occurs.

In addition, the panel control unit of the present invention may include a first control operation for turning the initial solar cell panel unit horizontally to the right so as to determine the sunrise when the light intensity sensor unit detects light having a predetermined light quantity or more, A second control operation of stopping the rotation of the right side of the solar panel part when the illuminance value difference occurs between the first illuminance sensors and repeating turning the right side again when the illuminance value difference does not occur between the first illuminance sensors, When the solar panel section reaches the preset maximum rightward turning angle and no illuminance value difference occurs between the first illuminance sensors in the second control operation, it is determined that the solar panel section is at the first time point when the sunlight starts to be vertical A third control operation of rotating the solar cell panel portion to the left side by 1 degree every 4 minutes from the first time point so as to follow the daytime trajectory of the sun And that is characterized.

The panel control unit of the present invention determines the second time point when the vertical state of the solar panel unit and the sunlight finishes when the solar panel unit reaches the preset maximum left turn angle in the third control operation, The second control unit stops the right rotation of the solar panel unit when the illuminance value difference occurs between the second illuminance sensors and stops the rotation of the solar panel unit between the second illuminance sensors A fifth control operation for repeating turning the solar panel unit back to the right when no light having a predetermined light quantity is detected by the illuminance sensor unit; Or a sixth control operation for ending the daily solar power generation when the solar panel unit is horizontal left and right in the fifth control operation.

In addition, the maximum left turning angle and the maximum right turning angle of the present invention are set to be the maximum angle at which shadow interference does not occur according to the distance between the unit solar cell panels in the left and right direction, .

Further, the photovoltaic device of the present invention is provided in the periphery of the solar cell panel portion to detect sunlight in real time, information on the amount of sunlight, information on whether or not the incident angle of sunlight is optimized, Further comprising a solar photodetector for generating solar photodetection data including information on a direction for changing the solar photodetector to an optimized state, And corrects the left-and-right rotation position of the panel support unit by reflecting the change in incident angle of light in real time.

The solar power generation apparatus of the present invention further includes a height adjustment unit that is coupled to the panel support unit and adjusts the height of the panel support unit to adjust the inclination angle of the solar panel unit with respect to the ground according to the change in the altitude of the sun, ; And a solar data storage unit for storing the solar altitude change data, wherein the panel control unit receives the annual altitude conversion data stored in the solar data storage unit and optimizes the incident angle of sunlight to the solar panel unit The control unit controls the height adjusting operation of the height adjusting unit so that the height adjusting position of the height adjusting unit is corrected by reflecting the incident angle change of the sunlight in real time using the sunlight sensing data received by the sunlight sensing unit.

In addition, the solar photodetector of the present invention has a triangular section in cross section, a first vertex facing the solar cell panel portion, a first surface facing the first vertex facing the sun, a dark interior formed therein, And a solar cell module for generating electricity when solar light is incident on the surface through the pinhole and detecting that the sunlight is perpendicular to the solar cell panel portion and is the optimum incident angle A first solar cell sensor formed on the second surface of the triangular shape and generating electricity when solar light is incident on the surface through a pinhole, and is not in an optimum incident angle, and is rotated forward of the second surface, A second solar cell sensor for detecting whether solar light is incident on the third surface of the triangular shape and generating electricity when solar light is incident on the surface through a pinhole, It said first characterized in that it comprises a third sensor for sensing the solar cell may be an optimal angle of incidence to be rotated in front of the third surface.

In addition, the photovoltaic power generation device of the present invention includes a rotation guide bar mounted vertically to a rotation shaft of a panel support portion and rotated in conjunction with a rotation operation of the rotation shaft, A rotation guide pad formed in an arc along a rotation radius of the guide bar and having an angle adjusting hole formed at an interval of a predetermined angle on an arc surface corresponding to an end of the rotation guide bar, The LED lighting device further includes an angle adjusting unit including an optical sensor that is coupled to the rotation guide bar and is opposed to the LED illumination with a rotation guide pad interposed therebetween so as to detect a case where light of the LED illumination passes through the angle adjustment hole, The panel controller stops the turning operation when detecting light passing through the angle adjusting hole in the optical sensor during the operation of rotating the panel supporting portion, When a certain period of time by rotating the panel support again by repeating the control operation to reach the next hole of the angle adjustment, characterized in that for rotating the solar panels per hour at an angle section.

In addition, the panel support portion of the present invention mounts the unit solar battery panels so as to be spaced apart from each other in the front-rear direction, and the solar power generation device of the present invention extends to the front and rear sides of the unit solar battery panel, And a reflective panel unit for concentrating the light to the solar panel unit.

The reflective panel unit of the present invention is characterized in that a plurality of unit reflection panels are alternately stacked on the upper and lower sides along the edge of one unit solar cell panel and are spaced apart in the vertical direction between neighboring unit reflection panels do.

According to the solution of the above-mentioned problem, the solar power generation apparatus of the present invention has an effect of improving the power generation efficiency by tracking the day trajectory of the sunlight to optimize the incident angle of sunlight to the solar cell panel.

In addition, the photovoltaic device of the present invention has the effect of accurately and reliably tracking the day-to-day trajectory of the sunlight through the correcting operation.

Further, the solar photovoltaic device of the present invention has the effect of improving power generation efficiency by accurately and reliably tracking the annual altitude of sunlight.

In addition, since the solar cell device of the present invention can rotate the solar cell panel in the left and right direction at a constant time per hour, it is possible to perform an accurate pivoting operation in accordance with the daytime trajectory.

Further, the photovoltaic device of the present invention improves the light-condensing efficiency and the cooling efficiency by using the reflective panel, and further has the effect of preventing air resistance on the reflective panel and achieving the air-cooling cooling efficiency.

1 is a front view of a photovoltaic generator according to an embodiment of the present invention.
2 is a rear view of the photovoltaic device according to one embodiment of the present invention.
3 is a side view of a panel support of a solar power generator according to an embodiment of the present invention.
FIG. 4 is a view for explaining operational characteristics of a panel supporting portion of a photovoltaic power generating apparatus according to an embodiment of the present invention.
5 is a plan view showing a panel supporting portion of a solar cell apparatus according to an embodiment of the present invention.
6 is a view for explaining distances between solar battery panel groups of a solar cell apparatus according to an embodiment of the present invention.
FIG. 7 and FIG. 8 are rear views illustrating a height adjusting unit of the solar photovoltaic device according to an embodiment of the present invention.
FIG. 9 is a side view illustrating a height adjusting unit of a solar cell apparatus according to an embodiment of the present invention.
FIG. 10 and FIG. 11 are top and top views of a height regulating unit of a solar cell power generating apparatus according to an embodiment of the present invention.
12 and 13 are views showing a lower end portion of a height adjuster of the solar cell apparatus according to an embodiment of the present invention.
FIGS. 14A and 14B are perspective views illustrating a reflection panel unit of the photovoltaic device according to an embodiment of the present invention.
15 is a side view showing a reflection panel unit of the photovoltaic device according to an embodiment of the present invention.
FIG. 16 is a perspective view illustrating a solar panel unit and an illuminance sensor unit mounted thereon for explaining operation characteristics of the solar photovoltaic device according to an embodiment of the present invention. Referring to FIG.
FIG. 17 is a block diagram for explaining operation characteristics of the photovoltaic device according to an embodiment of the present invention. Referring to FIG.
FIG. 18 is a schematic view for explaining operational characteristics of the photovoltaic device according to an embodiment of the present invention. FIG.
19 is a block diagram for explaining operational characteristics of a photovoltaic device according to another embodiment of the present invention.
20 is a block diagram for explaining operational characteristics of a photovoltaic device according to another embodiment of the present invention.
FIGS. 21 to 23 are schematic views for explaining a solar photodetection unit of the photovoltaic device according to another embodiment of the present invention.
FIG. 24 is a view for explaining an angle adjusting unit of the photovoltaic generator according to an embodiment of the present invention. FIG.

The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail with reference to the accompanying drawings.

1 to 15, an example of a structure of a photovoltaic power generation apparatus capable of realizing this will be described before explaining the turning operation characteristics of the solar cell panel according to the locus of the sun, which is a feature of the present invention .

1 to 13 are views for explaining a photovoltaic generator according to an embodiment of the present invention. 1 is a front view of a solar cell apparatus according to an embodiment of the present invention; FIG. 2 is a rear view of the solar cell apparatus according to an embodiment of the present invention; FIG. 4 is a view for explaining operational characteristics of a panel supporting portion of a solar cell power generating apparatus according to an embodiment of the present invention, and FIG. 5 is a cross- 6 is a view for explaining a separation distance between solar battery panel groups of the solar cell apparatus according to an embodiment of the present invention, and FIGS. 7 and 8 are views 8 is a rear view illustrating a height adjusting unit of the solar power generating apparatus according to an embodiment of the present invention, FIG. 9 is a side view showing a height adjusting unit of the solar power generating apparatus according to an embodiment of the present invention, 11 It is a view of the height-adjustable part the upper end of the photovoltaic power generation apparatus according to an embodiment of the present invention, Figure 12 and Figure 13 is a view of the lower end parts of the height adjustment of the solar power generation device according to an embodiment of the present invention.

1 to 13, a photovoltaic device according to an embodiment of the present invention includes a solar cell panel 100, a front pedestal 200, a rear pedestal 300, a panel support (not shown) 400 and a height adjusting unit 500. [

The solar panel section 100 includes a plurality of unit solar battery panels 111. In addition, the unit solar battery panels 111 are continuously formed in the forward and backward directions to form one solar battery panel group 110. 14A to 15, the unit solar cell panels 111 may be spaced apart from each other in the front-rear direction within one solar cell panel group 110 to mount the reflective panel unit described below.

The front pedestal portion 200 is formed in the shape of a pedestal extending to the left and right and is provided for supporting the front lower end of the solar cell panel portion 100 from the ground.

The rear-side pedestal 300 is formed as a pedestal extending in the left-right direction and is provided for supporting the rear-bottom side of the solar cell panel 100 from the ground. Also, the upper end of the rear pedestal 300 may be formed higher than the upper end of the front pedestal 200.

The panel supporting part 400 is provided between the front pedestal part 200 and the rear pedestal part 300 and supports the solar cell panel part 100 so as to be rotatable in the left and right direction according to the daytime trajectory of the sun, 111 are continuously mounted in the forward and backward directions to form one solar cell panel group 110 and the solar cell panel groups 110 in the left and right direction, Thereby eliminating shadow interference between the solar panel groups 110 during the turning operation.

In detail, the panel supporting part 400 according to an embodiment of the present invention is formed in a bar shape extending in the left and right direction and includes a front end support part 410 A rear end support 420 which is formed in a bar shape extending in the left and right direction and which is coupled to an upper end of the height adjuster 500 so as to be rotatable in forward and backward directions, And a panel support 430 which is coupled to the front stage support 410 and the rear stage support 420 so as to be rotatable in the left and right direction so as to be mounted on the solar panel assembly 110 and spaced apart from each other in the left- do.

And is rotatably coupled to the panel support 430 between the shear support 410 and the panel support 430 and to the panel support 430 and the panel support 430 with an axis 421.

The rear end support 420 is formed with a connecting hole 521 for connecting the rear end support 420 and the rear round bar 520.

The panel supporting part 400 includes an angle adjusting protrusion 440 protruding downward from the front end of the panel supporting part 430 and configured to pivot the panel supporting part 430 in the left and right direction by a protruded one- An angle adjusting guide 440 which is coupled to one end of the angle adjusting protrusion 440 and which rotates the angle adjusting protrusion 440 in the left and right direction by a left and right moving operation, And an angle adjusting lateral axis 460 mounted to the left and right sides of the angle adjusting lateral axis 460. The angle adjusting lateral axis 460 is connected to one end of the angle adjusting lateral axis 460 and converts the rotational motion into linear motion in the left and right direction, It is possible to further include a motor 470. The angle adjusting protrusion 440 follows the angle adjusting guide 450 and directly controls the movement of the solar panel group 110 by the panel support 430. That is, as the angle adjusting motor 470 rotates forward or reverse, the angle adjusting guide 450 moves left and right, and the angle of the panel changes according to the position of the angle adjusting guide 450.

Further, a first caster 461 for supporting the angle adjusting lateral axis 460 is formed on the angle adjusting lateral axis 460.

A motor support 471 for supporting the left and right movement of the angle adjustment motor 470 in accordance with the rotation of the angle adjustment motor 470 and a motor support 471 for connecting the rotation axis of the angle adjustment motor 470 to the roundness line bolt 473 A nut 474 connected to and fixed to an end of the tangential line bolt 473 for converting the rotational motion of the angle adjusting motor 470 into a rectilinear motion, And a second joint 475 that does not transmit the rotational force to the second joint 475. Here, an electric device, a hydraulic device, or the like may be used to provide kinetic energy for operation of the angle-controlled abscissa.

In addition, a first fixing member 476 is fixed to the nut 474 and connected to the motor support 471, and a limit 480 for limiting the leftward movement of the angle adjusting lateral shaft 460 is formed.

Here, in order to prevent shadow interference, the ratio of the horizontal distance between the solar cell panel groups 110 to the lateral width of the unit solar cell panel 111 is set in the range of 0.16 to 0.4 in the embodiment of the present invention It is preferable to mount it. Specifically, when the maximum water receiving angle of the solar cell panel facing the sun is 270 °, the horizontal width of the unit solar cell panel 111: the distance between the solar cell panel groups 110 should be 1: 0.4, The width of the unit solar cell panel 111 in the left and right direction is set to be equal to the distance between the solar cell panel groups 110 when the maximum water receiving angle of the solar cell panel facing the sun is 240 °, 1: 0.16 can be formed at the minimum interval without shadow interference. Here, the maximum water-receiving angle is the surface of the solar cell panel 100 when the solar cell panel 100 is vertically rotated with respect to the solar cell panel 100 and the solar cell panel 100 when rotated as far as possible, (100) surface.

That is, the maximum left turning angle and the maximum right turning angle of the solar cell panel section 100 are set such that the distance between the unit solar cell panels 111 in the left and right direction Is determined as the maximum angle at which shadow interference does not occur.

The height adjuster 500 is provided between the rear pedestal 300 and the panel support 400 and adjusts the inclination angle of the solar cell panel 100 with respect to the ground according to the annual altitude change of the sun, The height of the panel support portion 400 is adjusted from the rear pedestal portion 300 so as to be set.

Specifically, the height adjusting unit 500 according to an embodiment of the present invention is formed in an X-link shape for height adjustment, and has an upper end connected to the rear end of the panel supporting unit 400, and a lower end connected to the rear supporting unit 300 And a height adjuster 510 for adjusting the angle between the height adjuster 510 and the panel supporter 400 during the height adjusting operation, A lower end of the height adjuster 510 is movably mounted to the left and right of the height adjuster 510 and the height adjuster 510 510) to the upper end of the rear pedestal (300).

In addition, a second caster 511 which is movable in the lateral direction while supporting the load of the structure by supporting the round bar 520 is formed, and as a connecting member capable of adjusting the angle, a cylindrical member 3 castor 512 is formed and a second fixing member 522 is formed to fix the height adjuster 510 and the round bar 520 so as not to be separated.

In addition, the structure of the lower portion of the height adjuster 510 is rotatable only forward, and a cylindrical caster is further provided to form a structure resistant to warping and breakage. (513) so as to form a structure resistant to bending or breakage. A height adjusting nut 514 for supporting the height adjusting bolt 540 is formed on the lower portion of the fourth caster 513. A trolley caster 515 is provided below the height adjusting nut 514 to prevent the hitch 530 from escaping.

The height adjuster 500 extends in the left-right direction and penetrates through the lower end of the height adjuster 510. The height adjuster 500 has screw threads having different directions on the left and right sides with respect to the middle portion, A height adjusting bolt 540 for adjusting the height of the adjusting bar 510 by moving the adjusting bar 510 in the left and right direction and a height adjusting motor 550 for fastening the height adjusting bolt 540 to the one end of the height adjusting bolt 540, It is possible to include.

In addition, the height adjusting portion 500 may be formed with a separation preventing wire 560 to prevent the vertical adjustment portion 500 from vertically separating from the height adjusting portion 500, and a third joint 541 is formed at the center of the height adjusting bolt.

Meanwhile, in an embodiment of the present invention, it is possible to further include the reflection panel unit 600. FIGS. 14A and 14B are perspective views illustrating a reflection panel unit of a solar cell power generation apparatus according to an embodiment of the present invention, and FIG. 15 is a side view illustrating a reflection panel unit of a solar cell power generation apparatus according to an embodiment of the present invention.

14A to 15, the panel supporting unit 400 according to an embodiment of the present invention includes unit solar cell panels 111 mounted in a spaced-apart relation in the front-rear direction, It is possible to further include a reflection panel unit 600 extending to the front and rear sides, respectively, for reflecting solar light and condensing the sunlight to the solar cell panel unit 100.

The plurality of unit reflection panels 601 are alternately stacked on the upper and lower surfaces along the ends of one unit solar cell panel 111 so that the adjacent unit reflection panels 601 In the vertical direction. That is, in order to prevent the reflection panel unit 600 from being bent or bent due to the resistance of the wind when the reflection panel unit 600 is formed of one plate, a plurality of unit reflection panels 601 are arranged And is attached to the front end or the rear end of the unit solar cell panel 111 alternately on the upper and lower sides. Accordingly, it is possible to minimize the resistance of the wind by forming a space through which the air passes between the neighboring unit reflection panels 601, and it is also possible to cool the reflection panel unit 600 by forming an air flow .

The reflecting panel unit 600 includes a plurality of unit reflecting panels 601 and includes a reflecting panel 610 coupled to the unit solar cell panel 111 so as to be rotatable in the forward and backward directions, A cooling water supply pipe (not shown) mounted on one side of the solar panel unit 100 to cool the solar panel unit 100 by flowing water on the surface of the reflection panel 610 by evaporation of water, It is possible to include a reflection panel motor (not shown) that rotates the reflection panel 610 to be used as the light source.

Specifically, since the solar panel tracks the altitude of the southern part and is always perpendicular to the sunlight, the light amount equivalent to the vertical projection area of the reflector can be added to the solar panel.

On the other hand, the efficiency of the solar panel is directly proportional to the solar radiation amount and the amount of sunshine, and is in inverse proportion to the temperature rise of the solar panel. Therefore, the solar panel plays a role of a reflector when the solar radiation is insufficient, It can be used as a evaporation plate to lower the temperature of the solar cell panel to lower the temperature of the battery panel. When used as a vaporization plate, a nonwoven fabric or the like may be further formed on the surface of the reflection panel so as to collect the flowing water and increase the evaporation efficiency.

In addition, when the climate such as typhoon, heavy snowfall, and heavy rains is likely to damage the solar panel, it is possible to protect the solar panel by covering the front and rear reflective panels toward the solar panel in the shape of an equilateral triangle Lt; / RTI >

Hereinafter, the configuration and operation of driving the panel support unit 400 and the height adjusting unit 500 to improve the power generation efficiency by optimizing the incident angle of sunlight to the solar cell panel by tracking the altitude and locus of the sunlight The characteristics will be described below.

FIG. 16 is a perspective view illustrating a solar panel unit and an illuminance sensor unit mounted thereon in order to explain operation characteristics of the solar photovoltaic device according to an embodiment of the present invention. FIG. FIG. 18 is a schematic diagram for explaining operational characteristics of the photovoltaic device according to an embodiment of the present invention. Referring to FIG. In FIG. 17, the unit solar cell panels 111 neighboring in the left-right direction are shown as being laid sideways. In FIG. 18, the photovoltaic devices are seen from the front, with the right side being the east side and the left side being the west side, It is to the south and the rear to the north.

16 to 18, the photovoltaic device according to an embodiment of the present invention includes a first illuminance sensor 710 mounted on the right corner of each unit solar battery panel 111, And a second illuminance sensor 720 mounted on the left corner of the unit solar cell panel 111 to detect shadow interference between the unit solar cell panels 111 in the left and right direction .

The photovoltaic power generation apparatus according to an embodiment of the present invention includes a first light intensity sensor (hereinafter, referred to as " first light intensity sensor " And a panel controller 800 for recognizing the occurrence of shadow interference and controlling the turning operation when a difference in illuminance value between the first illuminance sensor 720 and the second illuminance sensor 720 occurs in the left and right direction do.

Specifically, when the light intensity sensor unit 700 senses light having a predetermined light amount, the panel controller 800 determines that the solar panel unit 100 is in an initial state, (Fig. 18 (a)) in which the first light intensity sensor 710 rotates the first light intensity sensor 710 and the first light intensity sensor 710 and the first light intensity sensor 710, The second control operation (Fig. 18 (b)) in which the solar panel panel 100 reaches the maximum rightward rotation angle previously set by the solar panel panel 100 If the illuminance value difference does not occur between the first illuminance sensors 710, it is determined that the solar panel section 100 and the sunlight start to be perpendicular to each other at a first point in time, The battery panel unit 100 is rotated to the left side, The controlled to follow a trajectory 3 it is possible to perform a control operation ((c) in FIG. 18).

In other words, when the sunrise starts in a horizontal state for the first time, although the solar panel and the solar light do not form a vertical state, the solar panel starts rotating at an angle capable of receiving sunlight, This operation is repeated according to the rotation of the motor. Then, the maximum solar power generation efficiency is started at a maximum right turning angle corresponding to the interval of the unit solar cell panels, for example, when the solar cell panel and the solar cell panel are perpendicular to each other in the right turning state at 45 degrees from the horizontal, It is possible to automatically and precisely follow the daily orbit while maintaining the vertical state between the sunlight and the solar panel portion by rotating the solar panel by 1 degree every 4 minutes in consideration of the day rotation cycle of the sun rotating 360 °.

When the solar panel section 100 reaches the preset maximum left rotation angle in the third control operation, the panel control section 800 controls the solar panel section 100 and the sunlight (D) of FIG. 18) that rotates the solar cell panel unit 100 to the right by 1 degree every 4 minutes and the second illuminance sensor 720 A fifth control operation (FIG. 18 (a) of FIG. 18) in which the rotation of the right side of the solar panel unit 100 is stopped and the second roughness sensor 720 is rotated rightward e) detecting an amount of light of less than a predetermined amount of light from the illuminance sensor unit 700, terminating solar power generation for a day after turning the solar panel unit 100 to an initial state, When the solar panel unit 100 is horizontally positioned to the left and right, 6 it is possible to perform a control operation ((f) in FIG. 18).

That is, in the step of finishing the day-to-day power generation, when the maximum solar power generation efficiency ends at the maximum left rotation angle corresponding to the interval of the unit solar battery panels, for example, . After that, although the solar panel and the solar light do not form a vertical state, they start to rotate at an angle that can receive the sunlight while disturbing the interference between the solar panels as much as possible and repeat this operation according to the change of the sun's locus. Turn again. The turning operation for power generation is completed in a state in which the amount of light during the rotation reaches a certain amount less than a certain level at which power generation is hardly performed or is already horizontal.

19 is a block diagram for explaining operational characteristics of a photovoltaic device according to another embodiment of the present invention.

19, the photovoltaic device according to another embodiment of the present invention is provided around the solar cell panel 100 and detects sunlight in real time, and displays information on the amount of sunlight, Further comprising a solar light sensing unit (900) for generating solar light sensing data including information on whether the incident angle is in an optimized state and information on a direction for changing an incident angle of sunlight to an optimized state, The control unit 800 can control to correct the left-and-right rotation position of the panel support unit 400 by reflecting the incident angle change of the sunlight in real time using the sunlight sensing data received from the sunlight sensing unit 900 .

16 to 18, the panel control unit 800 may control the solar panel unit to rotate by using the solar photodetection data received from the solar photodetector unit 900, It is possible to control to correct the left and right turning positions of the panel supporting portion 400 by reflecting the change in real time.

20 is a block diagram for explaining operational characteristics of a photovoltaic device according to another embodiment of the present invention.

20, the photovoltaic device according to another embodiment of the present invention includes the solar cell panel 100 coupled with the panel supporting part 400 as described above, And a height adjusting part 500 for adjusting the height of the panel supporting part 400 to adjust the inclination angle with respect to the ground or to lay it down when not in use.

In addition, the photovoltaic device according to another embodiment of the present invention further includes a solar data storage unit 1000 for storing solar altitude change data.

Accordingly, the panel control unit 800 receives the annual altitude conversion data stored in the solar data storage unit 1000 and controls the height adjustment operation of the height adjustment unit so as to optimize the incident angle of sunlight to the solar panel unit 100 However, it is possible to control the height adjustment position of the height adjustment unit to be corrected by reflecting the change in the incidence angle of sunlight in real time using the sunlight sensing data received from the sunlight sensing unit 900.

That is, it is possible to correct not only the daily trajectory tracking but also the height adjusting operation according to the annual altitude in real time.

FIGS. 21 to 23 are schematic views for explaining a solar photodetection unit of the photovoltaic device according to another embodiment of the present invention.

21 to 23, a solar photodetector 900 according to another embodiment of the present invention has a triangle-shaped cross section, and a first vertex is directed toward the solar cell panel section 100, A case 910 having a first surface facing the sun point facing the sun and having a dark interior formed with a pinhole 911 facing the first apex at the center of the first surface, A first solar cell sensor 920 that generates electricity when solar light is incident on the surface through the first solar cell sensor 911 and detects electricity when the sunlight is perpendicular to the solar panel unit 100 to determine an optimum incident angle, And a second solar cell sensor (not shown) for sensing that solar light is incident on the surface through the pinhole 911 to generate electricity to be in an optimal angle of incidence, (930) and a third surface on the triangle A third solar cell sensor 940 that senses that the sunlight is incident on the surface through the hole 911 to generate electricity, It is possible to include.

Specifically, a small pinhole is drilled in a triangular frame, and the current phase is accurately recognized on one axis of the sun through a signal generated when the light passing through the pinhole reaches the solar cell attached to the corner of the triangle. 21, when the first solar cell sensor 920 generates electricity, the operation of the motor such as the angle adjusting motor 470 and the height adjusting motor 550 is stopped. As shown in FIG. 22, when electricity is generated in the second solar cell sensor 930, the motor is rotated counterclockwise. When electricity is generated in the third solar cell sensor 940 as shown in FIG. 23 Rotate the motor clockwise.

In order to prevent malfunction due to diffraction or scattering of light, it is also possible to provide a convex lens in the pinhole portion so that the light can reach only one point precisely. When the sun light sensing part 900 is placed one by one in the horizontal and vertical directions of the solar cell panel part 100, the trajectory of the sun can be accurately tracked.

On the other hand, building an automation system that relies solely on sensors increases the installation cost, but there is a possibility of sensor malfunction due to climate change. Therefore, by using the control through programming that generates signals based on the sunrise data, Thereby reducing malfunctions and increasing reliability.

In another embodiment, it is possible to add manual control to cope with climate change that suddenly arrives at an unspecified time. In other words, after installing a rod that is perpendicular to the solar panel on the top of the solar panel and installing a camera device to see the shadow of the rod and the start of the solar panel, real-time control and control .

FIGS. 24 and 25 are views for explaining an angle adjusting unit of a photovoltaic generator according to an embodiment of the present invention. 24 is a side view of the angle adjusting unit of the solar power generating apparatus according to the embodiment of the present invention, and FIG. 25 is a perspective view of the angle adjusting unit of the solar power generating apparatus according to an embodiment of the present invention.

24 and 25, the photovoltaic device according to an embodiment of the present invention includes an angle adjusting unit 220 for implementing a control operation for automatically rotating the solar cell panel unit by one degree every four minutes, (1100).

Specifically, the angle adjusting unit 1100 includes a rotation guide bar 1110 vertically mounted on the rotation axis of the panel support unit 400 and rotated in conjunction with a rotation operation of the rotation axis, And is formed as an arc along the rotation radius of the rotation guide bar 1110. The rotation guide bar 1110 has an angle adjusting hole And a rotation guide pad 1120 which is fastened to the rotation guide bar 1110 and which is disposed between the rotation guide bar 1110 and the rotation guide bar 1110, And an optical sensor 1140 provided opposite to the LED illumination 1130 to sense when the light of the LED illumination 1130 passes through the angle adjustment hole 1121. [

Accordingly, when the light sensor 1140 senses light passing through the angle adjusting hole 1121 during the operation of rotating the panel supporting unit 400, the panel controlling unit 800 stops the turning operation, It is possible to rotate the solar cell panel unit 100 at a predetermined angle per hour by repeating the control operation of rotating the panel support unit 400 again and reaching the next angle adjusting hole 1121 after a lapse of time.

That is, when the angle adjusting holes are formed at intervals of 1 degree and the predetermined time is set to 4 minutes, when the rotation guide bar stopped in any angle adjusting hole elapses for 4 minutes, And turn to the next angle adjustment hole. Then, when the next angle adjusting hole is reached, the optical sensor recognizes the light of the LED illumination, and the recognition signal is transmitted to the panel control unit. As a result, the panel control unit performs the stop control, and again counts four minutes and generates the operation control signal.

As described above, according to the embodiment of the present invention, the angle adjusting unit can be automatically and precisely adjusted, and the cost can be reduced by a combination of a general motor and an inexpensive sensor.

The solar photovoltaic device according to an embodiment of the present invention has an advantage of improving power generation efficiency by tracking the day trajectory of sunlight to optimize the angle of incidence of sunlight on the solar cell panel.

In addition, the photovoltaic device according to an embodiment of the present invention can accurately and reliably track the sun's locus of the sun through the correcting operation and accurately and reliably track the annual altitude of the sunlight to improve the power generation efficiency There are advantages to be able to.

In addition, since the solar cell according to the embodiment of the present invention can rotate the solar cell panel in the left and right direction with a constant time per hour, it is possible to perform an accurate turning operation in accordance with the daytime trajectory, Further, the cooling efficiency is improved, and the reflective panel is advantageous in preventing wind resistance and cooling efficiency.

As described above, it is to be understood that the technical structure of the present invention can be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention.

Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, All changes or modifications that come within the scope of the present invention should be construed as being included within the scope of the present invention.

100: Solar panel section
110: Solar panel group
111: Unit solar panel
200: front support part
300:
400: panel support
410: shear support
420: rear end support
421: Axis
430: panel support
440: Angle adjustment projection
450: Angle adjustment guide
460: Angle adjustment axis
461: 1st caster
470: Angle adjustment motor
471: motor base
472: First joint
473: Tangent line bolt
474: Nuts
475: second joint
476:
480: Limit
500:
510: Height adjuster
511: 2nd caster
512: 3rd caster
513: Fourth caster
514: height adjustment nut
515: Trolley casters
520: Round bar
521: End connection
522:
530: H. beam
540: height adjusting bolt
541: Third joint
550: height adjustment motor
560: Leaving prevention wire
600:
610: Reflective panel
700: illuminance sensor unit
710: 1st illuminance sensor
720: Second illuminance sensor
800:
900: Solar light sensing part
910: Case
911: Pinhole
920: first solar cell sensor
930: Second solar cell sensor
940: Third solar cell sensor
1000: solar data storage unit
1100:
1110: Rotation guide bar
1120: Rotary guide pads
1121: Angle adjustment hole
1130: LED lighting
1140: Light sensor

Claims (10)

A solar cell panel unit comprising a plurality of unit solar cell panels;
A panel supporting part for supporting the solar cell panel in a horizontal direction according to a sun's daily trajectory and for mounting the unit solar cell panels in a lateral direction apart from each other to exclude shadow interference during a turning operation;
A first illuminance sensor mounted on a right corner of each of the unit solar battery panels and a second illuminance sensor mounted on a left corner of each of the unit solar battery panels, An illumination sensor unit for detecting interference; And
The solar panel unit is rotated in the left-right direction so as to follow the sun's day trajectory, but the illuminance value difference between the first illuminance sensors adjacent to each other in the left-right direction occurs, or between the second illuminance sensors A panel controller for recognizing the occurrence of shadow interference and controlling the turning operation when the illuminance value difference occurs;
And a photovoltaic device. The method according to claim 1,
Wherein the panel control unit comprises:
A first control operation for rotating the solar cell panel unit in the initial state horizontally to the right so as to determine sunrise when the light intensity sensor unit detects light having a predetermined light amount or more and to face the east direction;
A second control operation for stopping the right turn of the solar panel unit when the illuminance value difference occurs between the first illuminance sensors and turning the right turn again when the illuminance value difference does not occur between the first illuminance sensors ,
In the second control operation, when the solar cell panel section reaches a predetermined maximum rightward rotation angle and a difference in illumination value does not occur between the first illuminance sensors, the solar panel section and the sunlight start to become vertical The control unit performs a third control operation for determining that the solar cell panel unit is rotated to the left by 1 degree every 4 minutes from the first time point so as to follow the sun's daytime trajectory, . 3. The method of claim 2,
Wherein the panel control unit comprises:
When the solar panel section reaches the predetermined maximum left rotational angle in the third control operation, it is determined that the solar panel section is at the second time point when the vertical state of the solar light is terminated, A fourth control operation for rotating the solar panel section to the right again,
A fifth control operation for repeating turning the right rotation of the solar panel unit when the illuminance value difference occurs between the second illuminance sensors and turning the right side again when the illuminance value difference does not occur between the second illuminance sensors ,
When the light intensity sensor unit detects light of less than the predetermined amount of light, it is determined that the solar panel unit is in a sunset state and the solar panel unit is rotated in the initial state and then the solar power generation for a day is terminated, And a sixth control operation for ending the daily solar power generation when the solar cell is horizontal. The method of claim 3,
The maximum left rotation angle and the maximum right rotation angle are determined as a maximum angle at which shadow interference does not occur according to the distance between the unit solar cell panels in the left and right direction in a state in which the solar cell panel unit and solar light are perpendicular to each other Wherein the solar cell is a solar cell. The method of claim 3,
The solar panel unit is provided around the solar panel unit and senses sunlight in real time. The information about the amount of solar light, information about whether or not the incident angle of sunlight is optimized, and the direction for changing the incident angle of sunlight to an optimized state Further comprising a solar photodetector for generating solar photodetection data including information on the photodetector,
Wherein the panel control unit controls to correct the left-and-right turning position of the panel support unit by reflecting the incident angle change of sunlight in real time using the sunlight sensing data received by the solar light sensing unit . 6. The method of claim 5,
A height regulating unit coupled to the panel supporting unit to adjust a height of the panel supporting unit to adjust an inclination angle of the solar cell panel unit with respect to the ground according to a change in the altitude of the sun during an annual altitude change, And
And a solar data storage unit for storing the solar altitude change data of the sun,
Wherein the panel control unit controls the height adjustment operation of the height adjustment unit to receive the annual altitude conversion data stored in the solar data storage unit and optimize the incident angle of sunlight to the solar panel unit, And controls the height adjustment position of the height adjusting unit to be corrected by reflecting the incident angle change of the sunlight in real time using the solar detection data received from the solar control unit. The method according to claim 5 or 6,
The solar-
The first surface facing the solar cell panel, the first surface facing the solar cell panel facing the sun, the interior being formed as a dark room, the pinhole facing the first apex at the center of the first surface, And a case
A first solar cell sensor formed on the first vertex and generating electricity when solar light is incident on the surface through the pinhole, and detecting that the solar light is perpendicular to the solar panel unit and is at an optimum incident angle;
And an electric field is generated when solar light is incident on the surface through the pinhole, thereby detecting an optimal angle of incidence when the solar cell is pivoted forward of the second surface 2 solar cell sensor,
A triangular shape formed on the third surface and generating electricity when solar light is incident on the surface through the pinhole, and detecting that it can not be an optimum incidence angle but can be an optimal incidence angle when it is pivoted forward of the third surface 3 < / RTI > solar cell sensor. The method according to claim 1,
A rotation guide bar mounted vertically to a rotation shaft of the panel supporting portion and rotating in conjunction with a rotation operation of the rotation shaft,
And an angle adjusting unit for adjusting an angle of the arc guide plate at an interval of a predetermined angle with respect to an arc surface corresponding to an end of the rotation guide bar along a rotation radius of the rotation guide bar, A rotation guide pad on which a hole is formed,
An LED lighting unit mounted on an end of the rotation guide bar,
And an optical sensor coupled to the rotation guide bar and opposed to the LED illumination with the rotation guide pad interposed therebetween for sensing when the light of the LED illumination passes through the angle adjustment hole, ,
The panel control unit stops rotating when the light sensor senses light passing through the angle adjusting hole during an operation of rotating the panel supporting unit, and when the predetermined period of time elapses, the panel supporting unit rotates again And repeating the control operation for reaching the next angle adjusting hole to rotate the solar cell panel unit at a predetermined angle of time. The method according to claim 1,
Wherein the panel supporting portion mounts the unit solar cell panels so as to be spaced apart from each other in the front-
Further comprising a reflection panel unit extending from both the front and rear sides of the unit solar cell panel and reflecting the sunlight to condense the solar light to the solar cell panel unit. 10. The method of claim 9,
The reflective panel unit includes:
Wherein a plurality of unit reflection panels are alternately mounted on the upper and lower surfaces along one end of the one unit solar cell panel so as to be vertically spaced between adjacent unit reflection panels.

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