KR20210070085A - Pole type solar energy generation system - Google Patents

Abstract

According to the present invention, a pole type solar energy generation system comprises: a pole fixed to stand on the ground; a solar panel slantly installed on an upper end of the pole to generate solar electricity; and a rotating device installed between the pole and the solar panel to provide a rotational force to the solar panel, wherein the rotating device comprises a vertical rotation unit having one end connected to a rear surface of the solar panel and having a driving motor for rotating the solar panel around a rotation axis parallel to the ground and the solar panel is slantly disposed with respect to the rotation axis and an inclination angle with respect to the sun is adjusted by the vertical rotation unit.

Description

Post-type solar power generation system {POLE TYPE SOLAR ENERGY GENERATION SYSTEM}

The present invention relates to a photovoltaic power generation system, and more particularly, to a post-type photovoltaic power generation system having a structure in which a photovoltaic panel is gradually rotated to improve the amount of power generation during photovoltaic power generation.

In general, photovoltaic power generation systems are constructed in a complex form by collecting a number of photovoltaic panels on sites such as forests, fallow land, building roofs, reservoirs, and salt fields.

When the photovoltaic power generation site is forest or farmland, it is necessary to install frame structures and solar panels after clearing the site by performing logging or civil works, etc., so it is inevitable that trees and soil will be damaged on a large scale. occurs Due to these side effects, the reality is that forests, etc., are not easy to use as photovoltaic power generation sites even if they meet the site conditions required for solar power generation.

Patent Document 1 discloses a self-weighting solar power generator that can be installed in a non-destructive manner, such as on the roof of a building or on an embankment. The self-weight solar power generation device includes a pillar assembly in which at least one or more pillars are continuously connected, and a light collecting plate coupled to the upper portions of the pillar assembly, wherein the pillar is provided with an inclined surface on its upper surface and a filler is accommodated therein. A space for accommodating the filler material is provided.

Patent Document 2 relates to a method of installing a solar module without occupying the field or field, and the lower support, installation fixed frame and post so that the solar module can be easily installed in the field and field during the off-season after harvest. Disclosed is a photovoltaic module and method installed in a paddy field having a frame. In addition, Patent Document 2 is connected to one side of the protection frame of the simple construction photovoltaic module and the installation fixed frame of the simple construction photovoltaic module by a Korean paper means so that a plurality of simple construction photovoltaic modules are overlapped and installed when used. Disclosed is a photovoltaic module having a structure that can be

However, since the conventional photovoltaic system still has a problem in that the frame structure supporting the photovoltaic panel occupies a large area, serious damage to nature occurs during construction, so an alternative is required.

In addition, the conventional photovoltaic power generation system usually has a disadvantage in that the photovoltaic panel is fixedly installed and thus the photovoltaic power generation efficiency is low. Although a system for moving a solar panel by tracking the movement of the sun has been disclosed for solar power generation, it is difficult to construct the system because the device is complex and expensive.

Patent Document 1: Korean Patent Publication No. 2011-0024887 Patent Document 2: Korean Patent Application Laid-Open No. 2016-0086729

The present invention was devised in consideration of the above problems, and by rotating the solar panel with a simple driving device to adjust the inclination angle of the solar panel, it is possible to improve the solar power generation efficiency. is to do

Another object of the present invention is to provide a post-type photovoltaic power generation system having a structure capable of further improving photovoltaic power generation efficiency by controlling both the azimuth and inclination angles of the photovoltaic panel using a driving motor.

In order to achieve the above object, the present invention includes a pole fixed to be erected on the ground; a solar panel installed at an angle to the top of the pole to generate solar electricity; and a rotation device installed between the pole and the solar panel to provide a rotational force to the solar panel, wherein the rotation device has one end connected to the rear surface of the solar panel and the solar panel to the ground Comprising a vertical rotation unit having a driving motor for rotating about a rotation axis parallel to the solar panel, the solar panel is disposed inclined with respect to the rotation axis and the inclination angle with respect to the sun is adjusted by the vertical rotation unit Post type A solar power system is provided.

The rotating device is connected to the other end of the vertical rotating unit and disposed under the vertical rotating unit, the horizontal rotating unit having a driving motor for rotating the vertical rotating unit about a rotation axis perpendicular to the ground; further comprising, The solar panel may have an azimuth angle with respect to the sun adjusted by the horizontal rotation unit.

The horizontal rotation unit includes a driving motor that provides rotational force to the rotation gear, a rotation counter plate disposed under the rotation gear and having irregular patterns periodically formed while going in the circumferential direction, and a fixed gear fixed to the rotation gear of the rotation gear. It may be provided with a limit switch that maintains contact with the rotation counter plate during rotation.

In the horizontal rotation unit, a first contact point and a second contact point for transmitting power or a signal by maintaining contact with each other during rotation of the rotation gear may be installed at a contact portion between the rotation gear and the fixed gear.

The horizontal rotating unit may be connected to an electric wire for transmitting power or a signal between the tubular bodies accommodating the rotating gear and the fixed gear.

The present invention includes a microcomputer for step-by-step driving control and sensing of the rotation of the solar panel from the operation of the limit switch turned on/off according to the concave-convex pattern of the rotation counter plate, wherein the microcomputer drives the horizontal rotation unit Therefore, it is preferable to rotate the solar panel in only one direction.

Additionally, the main controller may further include; sensing the wind direction in case of rain and rotating the solar panel in a direction facing the raindrops to perform control to clean the solar panel.

The post-type solar power generation system according to the present invention has the following effects.

First, by rotating the solar panel with a simple driving device, it is possible to efficiently increase the amount of solar power generation without using an expensive solar tracking device.

Second, since both the azimuth and inclination angles of the solar panel can be freely adjusted by the vertical rotation unit and the horizontal rotation unit, the solar power generation efficiency can be further improved.

Third, since the rotation device can be miniaturized and the configuration is simple, the return on investment is fast, and the frequent failure rate and high price problems, which were disadvantages of the existing solar tracking device, can be solved.

Fourth, since the solar panel is sufficiently spaced from the ground and well ventilated due to the nature of the solar panel being supported by the pole, it is possible to suppress the temperature rise of the solar panel and increase the solar power generation efficiency.

Fifth, solar power generation can be performed with high efficiency by rotating the solar panel stably without shaking by the rotating device installed on the pole.

Sixth, when the photovoltaic power generation site is in a mountainous or forested area, it is possible to keep the trees around the pole supporting the photovoltaic panel as it is, thus minimizing damage to nature.

1 is a partial perspective side view showing the configuration of a post-type photovoltaic power generation system according to an embodiment of the present invention.
FIG. 2 is a rear view illustrating an example of vertical rotation driving of the solar panel in FIG. 1 .
3 is a perspective view of FIG. 2 ;
4 is a side view showing the configuration of a post-type photovoltaic power generation system according to another embodiment of the present invention.
5 is a perspective view illustrating an example of horizontal rotation driving of the solar panel in FIG. 4 .
Figure 6 is a partial perspective perspective view showing the configuration of the rotation counter plate and the limit switch provided in the rotary device in FIG.
FIG. 7 is a cross-sectional view of FIG. 6 .
FIG. 8 is a partially enlarged cross-sectional view taken along line “A” of FIG. 7 .
9 is a cross-sectional view illustrating a modified example of FIG. 7 .

1 is a partial perspective side view showing the configuration of a post-type photovoltaic power generation system according to an embodiment of the present invention.

Referring to FIG. 1 , a post-type photovoltaic power generation system according to an embodiment of the present invention includes a pole 10 that is erected and fixed on the ground, such as a photovoltaic site, and a photovoltaic system installed on the upper end of the pole 10 . The panel 20 and a vertical rotation unit installed under the solar panel 20 and gradually rotating the solar panel 20 in a direction substantially perpendicular to the ground (vertical direction with respect to the ground) to adjust the inclination angle ( 30a) including a rotating device 30 having.

The pole 10 is installed vertically and the lower end is fixed to the upper end of a predetermined weight block by fastening means such as an anchor bolt. Preferably, the pole 10 may be made of a metal tubular body with a round outer circumferential surface like a conventional street lamp post, and may be configured in various other materials and shapes.

When the photovoltaic power generation site is a place where trees exist, such as a mountain, forest, or fallow land, a plurality of poles 10 are arranged to be spaced apart from each other at a predetermined interval so that trees can be located around the solar power generation system. can In addition, as a photovoltaic power generation site to which the present invention can be applied, if at least one predetermined weight block is buried and only a small vacant lot is secured where the pole 10 can be erected on the weight block, around a factory or a residential area, Various places may be employed, such as around a park.

The solar panel 20 is installed on the top of the pole 10 to produce solar electricity. The photovoltaic panel 20 is fixed to a cross-section or a predetermined flange inclined at the end of the rotating device 30 and is installed to be inclined with respect to the ground.

The rotating device 30 has one end (front end) connected to the rear surface of the solar panel 20 to rotate the solar panel 20 about a rotation axis (rotation center) A1 parallel to the ground. ) is provided. To this end, the vertical rotation unit 30a preferably includes a driving motor 30b horizontally arranged such that the rotation shaft is parallel to the ground.

The solar panel 20 is disposed inclined with respect to the rotation axis A1 and rotated by the vertical rotation unit 30a so that the inclination angle with respect to the sun can be adjusted. To this end, the driving motor 30b may be connected to the rear surface of the solar panel 20 via a predetermined tubular member having a center coincident with the rotation axis A1 of the solar panel. Preferably, the driving motor 30b may be arranged side by side on the ground so that the rotating shaft provided therewith coincides with the rotating shaft A1, but the present invention is not limited to this configuration, of course. Alternatively, various known gear assemblies for power transmission may be added between the driving motor 30b and the solar panel 20 .

The installation angle (θ) of the solar panel 20 is preferably installed obliquely, for example, about 15 degrees with respect to the rotation axis (A1).

The vertical rotation unit 30a adjusts the inclination angle of the solar panel 20 with respect to the sun by gradually rotating the solar panel 20 when the driving motor 30b is operated. An example in which the inclination angle of the solar panel 20 is adjusted is shown in FIGS. 2 (a) to (c) and FIGS. 3 (a) to (c) corresponding thereto, respectively. Specifically, in FIGS. 2 and 3 (a), the solar panel 20 is rotated counterclockwise by the vertical rotation unit 30a, for example, in a state in which the inclination angle is adjusted so that it is inclined toward the east, 2 and 3 (b) shows a state in which the inclination angle is adjusted to be horizontal with respect to the ground, and in FIGS. 2 and 3 (c), the solar panel 20 is rotated clockwise to face the west The state in which the inclination angle is adjusted to be inclined is shown.

4 is a side view showing the configuration of a post-type photovoltaic power generation system according to another embodiment of the present invention.

Referring to FIG. 4 , the post-type photovoltaic power generation system according to another embodiment of the present invention includes a pole 10 that is erected and fixed on the ground such as a photovoltaic site, and the solar power installed on the top of the pole 10 . The panel 20 and the vertical rotation part 30a installed under the solar panel 20 and gradually rotating the solar panel 20 in a direction substantially perpendicular to the ground to adjust the inclination angle, and the solar panel and a rotating device 30 having a horizontal rotation unit 30c for adjusting the azimuth angle by gradually rotating the 20 in a substantially horizontal direction with respect to the ground. In this embodiment, the pole 10 and the solar panel 20 may be configured in the same manner as in the above-described embodiment, so a detailed description thereof will be omitted.

The solar panel 20 is fixed to an inclined end surface or a predetermined flange at one end of the vertical rotation unit 30a of the rotating device 30 and is installed to be inclined with respect to the ground.

The rotating device 30 includes a vertical rotating unit 30a and a horizontal rotating unit 30c disposed below the vertical rotating unit 30a. The vertical rotation unit 30a has one end connected to the rear surface of the solar panel 20 to provide a rotational force in a direction perpendicular to or substantially perpendicular to the ground with respect to the solar panel 20 . The horizontal rotation unit 30c is installed on the pole 10 so as to be connected to the other end of the vertical rotation unit 30a to provide a rotational force in a direction horizontal to the ground with respect to the vertical rotation unit 30a and the solar panel 20 .

The vertical rotation unit 30a has one end (front end) connected to the rear surface of the solar panel 20 to gradually rotate the solar panel 20 about a rotation axis (rotation center) A1 parallel to the ground. To this end, the vertical rotation unit 30a preferably includes a driving motor 30b horizontally arranged such that the rotation shaft is parallel to the ground.

The solar panel 20 is disposed to be inclined with respect to the rotation axis A1 and rotated by the vertical rotation unit 30a so that the inclination angle with respect to the sun can be adjusted. To this end, the driving motor 30b may be connected to the rear surface of the solar panel 20 via a predetermined tubular member having a center coincident with the rotation axis A1 of the solar panel. Preferably, the driving motor 30b may be arranged side by side on the ground so that the rotating shaft provided therewith coincides with the rotating shaft A1, but the present invention is not limited to this configuration. Alternatively, various known gear assemblies for power transmission may be added between the driving motor 30b and the solar panel 20 .

The installation angle (θ) of the solar panel 20 is preferably installed obliquely, for example, about 15 degrees with respect to the rotation axis (A1).

The horizontal rotation part 30c is connected to the lower part of the vertical rotation part 30a and gradually rotates the vertical rotation part 30a and the solar panel 20 about the rotation axis (rotation center) A2 perpendicular to the ground to the sun. Adjust the azimuth for To this end, the horizontal rotating unit 30c includes a driving motor 30d in which the rotating shaft is vertically disposed with respect to the ground.

The driving motor 30b of the vertical rotation unit 30a and the driving motor 30d of the horizontal rotation unit 30c are vertically intersected with each other for simplification of the apparatus. Accordingly, the vertical rotation unit 30a and the horizontal rotation unit 30c are connected to each other so as to have a 'L'-shaped outer shape as a whole. Alternatively, the disposition angle between the driving motor 30b of the vertical rotation unit 30a and the driving motor 30d of the horizontal rotation unit 30c may be variously modified within an appropriate range. In addition, it is most preferable that the two axes A1 and A2 on which the solar panel 20 rotates form a 90 degree angle with each other.

5 (a) to (c) shows an example in which the azimuth angle of the solar panel 20 is adjusted. Specifically, in FIG. 5(a), the solar panel 20 is rotated counterclockwise by the horizontal rotation unit 30c and the azimuth is adjusted toward the east, for example, in FIG. 5(b) ) shows a state in which the azimuth is adjusted so that the solar panel 20 faces south, and in FIG. 5 ( c ), the solar panel 20 rotates clockwise and the azimuth is adjusted to face the west. is shown.

As described above, the azimuth of the solar panel 20 is adjusted by the horizontal rotation unit 30c and the inclination angle of the solar panel 20 is adjusted by the vertical rotation unit 30a as in the above-described embodiment.

6 and 7 show the configuration of the horizontal rotation unit 30c in detail.

6 and 7, the horizontal rotating part 30c is detachable at the center of the flange 31, which is obliquely inclined at a predetermined angle, and the flange 31 to open and close the inner space of the horizontal rotating part 30c. The waterproof cover 32, the first tubular body 33 connected to the lower part of the flange 31, and the second assembled to the lower part of the first tubular body 33 and the lower end fixed to the pole 10 It includes a tubular body 34 and a driving motor 30d controlled by a microcomputer (not shown) and installed inside the second tubular body 34 to provide a rotational force to the first tubular body 33 .

The first tubular body 33 is connected to the lower end of the flange 31 and is a pipe-like structure having a circular circumferential surface. The first tubular body 33 and the flange 31 may be integrally configured, alternatively, it is also possible that the flange 31 is integrally formed with the upper end of the first tubular body 33 by welding.

The second tubular body 34 is assembled to be positioned below the first tubular body 33 and is a pipe-like structure having a circular circumferential surface. A circular slot into which the upper pipe structure of the pole 10 can be fitted may be added to the lower end of the second tubular body 34 . As the pawl is fitted in the hollow, the second tubular body 34 is fixed to the top of the pawl 10 .

A bearing is interposed between the first tubular body 33 and the second tubular body 34 , so that structurally stable and smooth rotation can be achieved. The bearing includes an upper ring connected to the first tubular body 33 to rotate integrally, and a lower ring assembled to a lower portion of the upper ring and connected to the second tubular body 34, the upper ring and A plurality of balls may be interposed between the lower rings.

As shown in FIG. 6 , the horizontal rotation unit 30c includes a rotation gear 62 substantially connected to the first tubular body 33 and a fixed gear 61 substantially connected to the second tubular body 34, A driving motor 30d installed to be connected to the fixed gear 61 to provide rotational force to the rotational gear 62, and a rotation counter plate disposed under the rotational gear 62 to rotate integrally with the rotational gear 62 (63) and a limit switch (60) fixed to the fixed gear (61) and maintaining contact with the rotation counter plate (63) when the rotation gear (62) rotates.

The rotation gear 62 is installed to be relatively rotatable with respect to the fixed gear 61 by receiving rotational force from the driving motor 30d. The rotating gear 62 and the fixed gear 61 may be composed of various known gear assemblies.

The driving motor 30d is preferably fixed to be erected coaxially with the second tubular body 34 inside the second tubular body 34 to provide a rotational force to the rotating gear 62 .

The rotation counter plate 63 is fixed to the lower part of the rotation gear 62 and rotates simultaneously with the rotation gear 62, and the concave-convex pattern consisting of a valley (or groove) and a crest (or protrusion) structure is periodically formed on the lower part in the circumferential direction. is formed with

The limit switch 60 has one side fixed to the fixed gear 61 and the other side in contact with the rotation counter plate 63 to continuously maintain contact with the concave-convex pattern at the same time as the rotation counter plate 63 rotates. Accordingly, as the rotation count plate 63 rotates, the ON/OFF signal from the limit switch 60 is repeatedly output.

As shown in FIGS. 7 and 8, in the contact portion of the first tubular body 33 and the second tubular body 34, first contacts 36a and 36b and second contacts (36a and 36b) for power and/or signal transmission ( 38a, 38b) are installed. The first contact points 36a and 36b and the second contact points 38a and 38b are each composed of at least one conductor ring and are respectively fixed to the first tubular body 33 and the second tubular body 34 to face each other in the vertical direction. is laid out While the first tubular body 33 rotates with respect to the second tubular body 34 , the first contact points 36a and 36b are elastically biased downward by the coil spring 37 to the second contact points 38a and 38b. ) to maintain contact with Alternatively, one of the first and second contacts is configured in the form of a roll and the other is configured as a conductor ring on which the roll can be rolled, so that when the first tubular body 33 rotates, the first contact and the second contact The two contacts may be configured to maintain a contact state while rolling relatively.

Alternatively, as shown in FIG. 9 , a wire 39 for transmitting power or a signal may be connected between the first tubular body 33 and the second tubular body 34 .

The microcomputer determines the daily rotation amount of the solar panel 20 based on a predetermined illuminance sensor, seasonal rotation setting time, GPS time information provided by the satellite communication module, and the like, and uses it to drive motors 30b and 30d. Rotation control can be performed by applying to on/off control of The microcomputer may be built into the rotating device 30 or built into the pole 10, or it may be built into a separate enclosure.

When the illuminance value of sunlight output from the illuminance sensor is greater than a predetermined value, the microcomputer recognizes that the blade is bright and operates the driving motor 30b of the vertical rotating unit 30a and the driving motor 30d of the horizontal rotating unit 30c. The solar panel 20 is slowly rotated in seconds in one direction for a preset rotation step and/or time. Here, the driving motor 30b of the vertical rotating unit 30a and the driving motor 30d of the horizontal rotating unit 30c may operate simultaneously, and may be individually operated in a preset time period, respectively. It is preferable that the path in which the solar panel 20 rotates is set to be sufficiently exposed to the sun as much as possible in consideration of the amount of sunlight. When the solar panel 20 is rotated at a constant speed for a predetermined time, even if a solar tracking device having a complex structure is not separately used, the amount of solar power generation compared to the case where the solar panel 20 is placed in a stationary state toward one side can increase

The microcomputer drives and senses the rotation of the solar panel 20 step by step from the operation of the limit switch 60 turned on/off by the change of the uneven pattern according to the rotation of the rotation counter plate 63 . Here, the first step of rotation of the solar panel 20 is one cycle of the rotation count plate 63, that is, the limit switch 60 is in contact with any one groove included in the concave-convex pattern and then in contact with the next groove. It can be defined by counting.

In particular, the microcomputer controls the driving motor 30d of the horizontal rotation unit 30c to set the number of rotation steps for each season differently to control the daily rotation amount (rotation angle) for the solar panel 20 differently. can Considering the amount of sunshine by season, it is desirable to perform rotation control by setting the largest number of rotation steps for summer (setting to rotate the most) and the least setting for winter (setting to rotate the least) among the four seasons. Specifically, the microcomputer performs rotation control by setting the number of rotation steps of the rotation count plate 63 to 1 to 11 steps in spring/autumn, 0 to 12 steps in summer, and 2 to 10 steps in winter. To this end, the memory of the microcomputer stores data on the rotation step setting value.

Additionally, the main controller communicates with each of the microcomputers by wire and wirelessly to manage the different solar panels 20 and the rotating device 30 in an integrated manner so that all the solar panels 20 are substantially the same pattern. control to rotate.

Additionally, the main controller senses the wind direction in case of rain and performs control to rotate the solar panel 20 in a direction facing the raindrops. That is, by directly exposing the surface of the solar panel 20 to raindrops, it is possible to effectively remove fine dust or foreign substances accumulated on the surface of the solar panel 20 .

The present invention having the above configuration is a complex structure by gradually rotating the solar panel 20 in the vertical and horizontal directions with respect to the ground using the vertical rotation part 30a and the horizontal rotation part 30c in the process of producing solar electricity. Even if you do not separately use the solar tracking device, it is possible to significantly increase the amount of solar power generation compared to the case where the solar panel 20 faces one side in a stationary state.

On the other hand, the present invention can maintain the trees around the pole 10 supporting the solar panel 20 as it is, so that it is possible to build an eco-friendly solar power generation facility while minimizing damage to nature. The trees located around the pole 10 can also serve as a windbreak, so that the solar panel 20 can be installed more stably.

At the time of construction, after digging a predetermined hole at each point where the pole 10 is to be installed, the weight block is embedded and fixed, and then the lower end of the pole 10 is placed on the top of the weight block and fixed with an anchor bolt to complete the construction easily. do.

When the pole type photovoltaic power generation system is operated, the photovoltaic panel 20 may be rotated at a preset time and speed by the rotating device 30 to increase the amount of photovoltaic power generation.

The solar panel 20 is gradually rotated in the vertical direction with respect to the ground about the rotation axis A1 by the vertical rotation unit 30a provided in the rotating device 30, so that the inclination angle with respect to the sun can be adjusted. In addition, the solar panel 20 is gradually rotated in the horizontal direction with respect to the ground about the rotation axis A2 by the horizontal rotation unit 30c provided in the rotating device 30, so that the azimuth angle with respect to the sun can be adjusted.

A rotation counter plate 63 is fixed to a lower portion of the rotation gear 62 provided in the rotation device 30 and rotates integrally with the rotation gear 62, and a limit switch 60 is located at a lower portion of the rotation counter plate 63. By continuously maintaining contact and detecting the uneven pattern of the rotation count plate 63, the rotation amount can be detected step by step. The microcomputer controls the rotation device 30 based on the output signal of the limit switch 60 turned on/off by the change of the uneven pattern according to the rotation of the rotation counter plate 63 by controlling the vertical of the solar panel 20 . And the horizontal direction rotation is driven step by step, and whether the solar panel 20 rotates in seconds without error is also detected and reflected in the control operation.

As described above, in the post-type solar power generation system according to the present invention, both the azimuth and inclination angles of the solar panel 20 are freely precise by the vertical rotation part 30a and the horizontal rotation part 30c constituting the rotation device 30 . Since it can be adjusted, there is a remarkable effect that can further improve the solar power generation efficiency. In addition, by rotating the solar panel with a simple driving device, it is possible to efficiently increase the amount of solar power generation without using an expensive solar tracking device.

In the above, although the present invention has been described with reference to limited embodiments and drawings, the present invention is not limited thereto and will be described below with the technical idea of the present invention by those of ordinary skill in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims.

10: pole 20: solar panel
30: rotating device 30a: vertical rotating unit
30b, 30d: drive motor 30c: horizontal rotating part
60: limit switch 61: fixed gear
62: rotation gear 63: rotation counter plate

Claims (7)

In the post-type solar power generation system,
poles fixed to stand on the ground;
a solar panel installed at an angle to the top of the pole to generate solar electricity; and
A rotating device installed between the pole and the solar panel to provide a rotational force to the solar panel; includes,
The rotating device is
A vertical rotation unit having one end connected to the rear surface of the solar panel and having a driving motor for rotating the solar panel about a rotation axis parallel to the ground,
The solar panel is arranged to be inclined with respect to the rotation axis, and the inclination angle with respect to the sun is adjusted by the vertical rotation unit. According to claim 1, wherein the rotating device,
A horizontal rotation part connected to the other end of the vertical rotation part and disposed under the vertical rotation part, the horizontal rotation part having a driving motor for rotating the vertical rotation part about a rotation axis perpendicular to the ground; further comprising,
The solar panel is a post-type solar power generation system, characterized in that the azimuth with respect to the sun is adjusted by the horizontal rotation unit. The method of claim 2, wherein the horizontal rotation unit,
A driving motor for providing a rotational force to the rotational gear, a rotation counter plate disposed under the rotational gear and having an uneven pattern periodically formed while going in the circumferential direction; A post-type photovoltaic power generation system, characterized in that it is provided with a limit switch that maintains contact with the plate. According to claim 3, The horizontal rotation unit,
A post-type photovoltaic power generation system, characterized in that a first contact point and a second contact point for transmitting power or a signal by maintaining contact with each other during rotation of the rotary gear are installed in the contact portion between the rotary gear and the fixed gear. According to claim 3, The horizontal rotation unit,
A post-type photovoltaic power generation system, characterized in that an electric wire for transmitting power or a signal is connected between the rotating gear and the tubular bodies accommodating the fixed gear. 4. The method of claim 3,
and a microcomputer for step-by-step driving control and sensing of the rotation of the solar panel from the operation of the limit switch turned on/off according to the concave-convex pattern of the rotation counter plate,
The microcomputer drives the horizontal rotation unit to rotate the solar panel in only one direction. 4. The method of claim 3,
A post-type photovoltaic power generation system further comprising a; by sensing the wind direction in case of rain and rotating the photovoltaic panel in a direction facing the raindrops to perform control to clean the photovoltaic panel.

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