KR101230539B1 - Photovoltaic power generation apparatus - Google Patents

Abstract

PURPOSE: A solar power generating device is provided to easily move wind and snow by separately arranging a central solar cell module between two solar cell modules. CONSTITUTION: A support frame is mounted to change the combination location of solar cell modules. A pair of vertical frames are vertically arranged on the lower side of the support frame. A first horizontal frame connects each center of the vertical frame. A second support unit(150) is hinged to the lower side of a first support unit(120). A power transmitting unit(160) includes a lift arm.

Description

Photovoltaic power generation apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar power generation device, and more particularly, to a solar power generation device capable of changing the arrangement angle and arrangement direction of the solar cell module according to the altitude and direction of the sun.

Currently, as fossil fuels such as oil and coal are depleted, development of alternative energy is progressing. In particular, energy resources utilizing solar energy are being actively developed.

Power generation technologies that produce electricity using solar energy include solar power generation that generates electricity by driving heat engines using solar heat, and solar power generation that generates electricity from solar cells using sunlight.

Here, the solar cell used for photovoltaic power generation includes a semiconductor compound device that converts sunlight directly into electricity.

As the solar cell used for the photovoltaic power generation, usually silicon and a composite material are usually used. Specifically, the solar cell is used by bonding a P-type semiconductor and an N-type semiconductor to use a photoelectric effect of producing electricity by receiving sunlight.

Most solar cells consist of a large area P-N junction diode, and the electromotive force generated at the anode end of the P-N junction diode is connected to an external circuit.

The minimum unit of such a solar cell is called a cell, and in practice, the solar cell is rarely used as it is.

This is because the voltage from one cell is very small, about 0.5V, compared to several tens or hundreds of volts (V) at actual voltage. It is connected and used.

In addition, when the solar cell is used outdoors, it may be subjected to various harsh environments, so that a plurality of cells may be packaged as a solar cell module in order to protect a plurality of cells connected to a required unit capacity in a harsh environment. Configure and use.

However, since the solar cell module has to be used in large quantities in order to obtain a constant power, there is a limitation in the installation place, and the deformation of the lower support structure according to the arrangement of the solar cell module is not only limited. When installed in outdoor facilities, there is no problem, but when installed in a multi-unit housing, which occupies a large number of houses, there is a problem that individual installation in the household is difficult.

In addition, the support structure for supporting a conventional solar cell module is a position once once the main frame and the support for supporting the solar cell module, the support pillar for supporting the main frame to the ground are often joined by welding, respectively. After welding was completed, it was difficult to adjust the arrangement.

In particular, in the case of a fixed support structure that supports a large number of solar cell modules, the arrangement angle is fixed, and thus there is a limit in adjusting the arrangement angle of the solar cell module according to the change in solar altitude according to the seasonal change, so that the condensing efficiency and There is still a problem of low electricity production efficiency.

In Korea, when looking at the latitude (38 °) in consideration of the season's southern mid-high altitude, the equinox or autumn equinox is about 52 ° south of the sun, 75.5 ° in the lower summer, and 28.5 ° in the winter solstice.

However, the conventional photovoltaic device is installed with a fixed angle toward the south facing the situation, so it is urgent to take measures against large variations in the electricity production by season.

In addition, the eco-friendly energy business is becoming visible, and attention is focused on solar power generation, and facilities for large-capacity solar power generation are needed. However, the solar power generating device that rotates along the sun's movement path is stable for large-scale solar cell modules. There is a limit to the need for equipment that can be supported.

The present invention is to solve such a problem, it is possible to change the arrangement angle and direction of the solar cell module seasonally in response to changes in the altitude and direction of the sun, it is possible to safely and easily install the solar cell module The purpose is to provide a photovoltaic device.

The present invention for performing the above object is a plurality of solar cell modules; A support frame to mount the solar cell modules so as to change a coupling position of the solar cell modules; A first support unit provided below the support frame to distribute and support the load of the support frame; A second support unit coupled to the lower side of the first support unit such that the first support unit can rotate in a vertical direction; And a power transmission unit provided at a lower side of the second support unit, the power transmission unit including a driving motor to rotate the second support unit in the vertical and horizontal directions.

The support frame may be formed with a shielding duct groove in at least one or more of the side or bottom surface of the support frame to accommodate the power line drawn from the solar cell module.

The first support unit includes a pair of vertical frames disposed in the vertical direction below the support frame; A first horizontal frame connecting the vertical frames to each center of the vertical frame; And a second horizontal frame and a third horizontal frame connecting each end of the vertical frames to the first horizontal frame in parallel.

The first horizontal frame may be formed to have a larger cross-sectional area than the cross-sectional areas of the second horizontal frame and the third horizontal frame.

The first support unit may include a first fixing member provided at both ends of each of the vertical frames; A plurality of first connecting rods having one end rotatably coupled to the first fixing member and extending in a vertical direction of the vertical frame; It may further include an auxiliary support provided on the lower side of the support frame including a second fixing member for rotatably coupling the other end of the first connecting rods.

The auxiliary support may be formed so that the position at which the first connecting rod supports the support frame is adjustable.

The second support unit includes a pair of brackets respectively provided at both lower ends of the first horizontal frame, and a plurality of second connection rods coupled to connect the second horizontal frame and the third horizontal frame from the bracket, respectively. It may include.

The first support unit may include a first extension frame extending in both sides of the second horizontal frame, and a second extension frame respectively extending in both sides of the third horizontal frame.

The first extension frame and the second extension frame are formed to protrude in the vertical direction of each of the vertical frame, it may be disposed on the bottom surface of the support frame to distribute and support the load of the solar cell module.

The power transmission unit rotates the first support unit and the second support unit by a drive motor provided therein, and a case having a cam groove formed on an outer circumferential surface thereof, and corresponding to the shape of the cam groove according to the rotation of the drive motor. It may include a lift arm reciprocating in the vertical direction, one end is slidably disposed in the cam groove, the other end is rotatably coupled on the first horizontal frame.

In addition, the photovoltaic device may further include an altitude control unit provided between the first horizontal frame and the other end of the lift arm so that the solar cell module can correct the seasonal difference in altitude displacement of the sun.

The altitude control unit includes a plurality of knobs extending radially to allow the user to rotate in a clockwise or counterclockwise direction by holding the altitude of the season manually; A first fastening portion having a predetermined length so as to extend in both directions perpendicular to the center of the handle portion of a radial shape and a female screw on an outer circumferential surface or a female screw on an inner circumferential surface; When the handle portion rotates in one direction away from the center of the handle portion, when the handle portion rotates in the other direction is fastened to both sides of the first fastening member to be closer to the center of the handle portion, respectively, the first fastening The second fastening part may include a female thread or a male thread to correspond to the portion.

The solar cell module may be formed in a plurality of patterns in a lattice structure, and the solar cell module disposed at the center may be spaced upwardly from other solar cell modules disposed at both sides so that wind or snow may move.

The solar cell module disposed in the center may be spaced laterally so as to form a gap between the solar cell modules disposed on both sides.

According to the solar cell apparatus according to the present invention,

First, since the support frame supporting the solar cell module is supported by the first support unit and the second support unit, it is possible to prevent the solar cell module and the frame from being deformed due to an external force such as a strong wind.

Second, since the altitude control unit can correct the altitude difference of the sun by season, the light collecting efficiency and power generation efficiency of the solar cell module can be maximized,

Third, since the altitude and azimuth of the solar cell module can be adjusted through a cam groove formed in the case in response to the change of the altitude and the azimuth of the sun, there is also an advantage that the light collecting efficiency and power generation efficiency of the solar cell module can be maximized. .

1 is a rear perspective view of a photovoltaic device according to an embodiment of the present invention.
2 is a side view of the photovoltaic device shown in Fig.
3 is an exploded perspective view of the photovoltaic device shown in FIG. 1.
4 is a partially enlarged view of the photovoltaic device shown in FIG. 1.
5 is a rear perspective view of a solar cell apparatus according to another embodiment of the present invention.
FIG. 6 is a plan view of the first support unit illustrated in FIG. 5.
7 is a side view illustrating the power transmission unit shown in FIG. 1.
FIG. 8 is a plan view of the support bearing shown in FIG. 7 as viewed from above. FIG.
FIG. 9 is an exploded view illustrating the altitude adjusting unit shown in FIG. 3.
10 to 12 are side views showing that the arrangement angle of the solar cell module shown in FIG. 1 changes according to the altitude change of the sun.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms and words used in the specification and claims should not be construed to be limited to ordinary or dictionary meanings, and the inventor should appropriately define the concept of the term to describe its invention in the best way possible It should be construed in the meaning and concept consistent with the technical idea of the present invention.

1 is a rear perspective view of a photovoltaic device 100 according to an embodiment of the present invention, FIG. 2 is a side view of the photovoltaic device 100 shown in FIG. 1, and FIG. 3 is a photovoltaic power source shown in FIG. 1. An exploded perspective view of the device 100.

1 to 3, the photovoltaic device 100 includes a plurality of solar cell modules 10, a support frame 110 supporting the solar cell module 10 from below, and the support frame. The first support unit 120 supporting the 110, the vertical frame 150 and the first support unit 120 and the vertical frame 150 to support the first support unit 120 to be rotatable It includes a power transmission unit 160 is provided with a drive motor (M) for providing a driving force to rotate.

The photovoltaic device 100 of the embodiment of the present invention is characterized in that the solar cell modules 10 are arranged horizontally long and four vertically arranged in three by three in total so that a total of twelve solar cell modules 10 are provided, 3 kW, and the number of the solar cell modules 10 is related to the total solar cell power generation capacity, so that the arrangement and shape of the solar cell modules 10 can be changed accordingly.

The support frame 110 is assembled so as to have a vertical length corresponding to the size of the solar cell module 10, And is formed to have a length smaller than or equal to the width.

The support frame 110 is shaped like a beam having a square cross section and its size is determined according to the number of the solar cell modules 10 required according to the power generation capacity according to solar power generation, The size of the support frame 110 can be varied flexibly.

The plurality of solar cell modules 10 are patterned in a lattice structure and laterally spaced so as to form an interval between adjacent solar cell modules so that wind or snow can move.

In addition, the solar cell module 10 is spaced apart from each other to generate a height difference between the adjacent solar cell module in the zigzag direction to move the wind or snow.

Accordingly, as shown in FIG. 3, the solar cell module ② is disposed higher so that the height difference is formed between the solar cell module ① and the adjacent solar cell module ②, and thus, between the solar cell module ① and the solar cell module ②. Wind can pass through the space due to the height difference of the wind pressure can reduce the resistance.

The solar cell module ④ is disposed to be laterally spaced apart from the adjacent solar cell module ⑤ so that the gap is formed, and the height difference is formed. This not only prevents a shadow from being generated in the solar cell module ⑤ by the height of the solar cell module ④, but also allows the wind to pass through the height difference and the interval, thereby reducing the resistance due to wind pressure. Snow accumulated on the upper surface of the solar cell modules can be expected to flow or pass through.

Here, the even-numbered solar cell modules ②, ④, ⑥, ⑧, ⑩, and the solar cell module⑫ are disposed at a high position by the height difference, and the solar cell modules ④, ⑥, ⑩, and the solar cell module⑫ are disposed at the center. The solar cell modules ⑤ and the solar cell modules are spaced apart from each other so as to form the gap in the lateral direction, respectively.

As shown in FIG. 2, a lightning arrester 400 is provided at an upper edge portion of the support frame 110. The lightning arrester 400 is disposed at a position higher than an upper surface of the solar cell module 10 to prevent a lightning strike directly on the solar cell module 10.

In this case, although the lightning arrester 400 is provided as an example in the upper corner portion of the support frame 110, in the place where the solar cell panel is laid in the horizontal direction in each corner portion of the support frame 110 The lightning arrester 400 may be installed to prevent the solar cell module 10 from being damaged from lightning.

The lightning arrester 400 includes a plurality of coupling members 410 coupled to the support frame 110, a plurality of insulator members 420 coupled to the outside of the coupling members 410, and the insulator. Extension members 430 coupled to the outside of the members 420 and a lightning induction member 440 made of metal fastened to connect the upper ends of the extension members 430, respectively.

The coupling member 410 is fastened to the end of the sub-frame 330 and the connection frame 350 in a 'U' shape, the connection frame (in consideration of the inclination angle of the solar cell module 10) At the end of 350 it is coupled perpendicular to the ground.

The insulator member 420 has one side coupled to the coupling member 410, the other side coupled to the extension member 430, and preventing the coupling member 410 and the extension member 430 from energizing. An empty space is formed in the center of the interior.

The insulator member 420 is formed of porcelain, glass or plastic synthetic resin to have an insulating function, and to increase the surface distance by making one or more wrinkles (not shown) to have sufficient electrical insulation strength. It is preferably formed to be.

In addition, when the wrinkles are formed, it is effective to prevent the insulation strength from deteriorating when the surface humidity of the insulator member is high, particularly when salt or dust is attached. More preferably, the insulator member may be made of a hard magnetic group having excellent corrosion resistance, heat resistance, and strength.

One end of the extension member 430 is coupled to the other side of the insulator member 420, and the other end is bent to allow the lightning induction member 440 to be coupled thereto. The extension member 430 extends the arrangement position of the lightning induction member 440 upward from the insulator member 420 and increases the height of the lightning induction member 440 from the top surface of the solar cell module 10. Place it in a higher position. Therefore, there is an advantage that can secure the safety of the solar cell module 10 from lightning.

The lightning induction member 440 is coupled to connect the upper end of each of the extension member 430, the lightning induction member 440 and the extension member 430 is formed of a metal material and energize each other, the extension At least one or more of the members 430 are grounded to the ground.

Therefore, it is possible to prevent the electrical shock due to lightning through the support frame 110 is transmitted to the solar cell module 10.

The first support unit 120 provided on the bottom of the support frame 110 is a pair of vertical frames 150 provided to be spaced apart from each other in the vertical direction, and connecting the central portion of the vertical frame 150 The first horizontal frame 122 and the second horizontal frame 123 and the third horizontal frame 124 connecting both ends of the vertical frame 150, respectively.

The vertical frames 150 are spaced apart from each other in a hollow rectangular beam shape and are supported by the load of the support frame 110 and the wind pressure due to wind and the load of snow accumulated on the upper surface of the solar cell module 10 Therefore, it is made of a material having a relatively large cross-sectional area and a high rigidity.

The first horizontal frame 122 is provided to connect the centers of the vertical frames 150 and the first horizontal frame 122 is also subjected to a large load and is designed in consideration of various stresses.

The second horizontal frame 123 and the third horizontal frame 124 are provided to connect one end and the other end of the vertical frame 150, respectively, and the vertical frame 150 and the first horizontal frame 122 can be formed into a rectangular beam having a small cross-sectional area because the load is small.

Since the first support unit 120 has a smaller overall size than the support frame 110, the first support unit 120 may be formed from both ends of the pair of vertical frames 150 so as to generally support the support frame 110. It includes an auxiliary support 126 that can additionally support the support frame 110.

The auxiliary support 126 is a rod having a first end fixed to the first fixing member 127 is provided on the bottom surface adjacent to both ends of the vertical frame 150, and the first fixing member 127 to be rotatable And a second fixing member 129 provided on a bottom surface of the first connecting rod 128 and the support frame 110 to be rotatably coupled to the other end of the first connecting rod 128.

The auxiliary support part 126 may be additionally changed in position to support the auxiliary support part 126 according to the size of the first support unit 120 with respect to the size of the support frame 110, and the length of the first connection rod 128 is also changed. Can be.

The first fixing member 127 has a through-hole to fasten one end of the first connection rod 128 in a hinge structure, respectively.

The first connection rod 128 is bolted to the through hole formed in the first fixing member 127, and more securely supports the support frame 110 in the horizontal direction from the first support unit 120 Has

The other end of the first connecting rod 128 is bolted to another through hole formed in the second fixing member 129, the second fixing member 129 according to the length of the first connecting rod 128 The position of can be fixed flexibly.

The second fixing member 129 may be fixed to the bottom or side of the support frame 110, the sliding groove (not shown) so that the second fixing member 129 on the support frame 110 can slide. ) Is formed.

The second support unit 150 includes a pair of brackets 151 fixed downward to the bottom of the first horizontal frame 122 and the second horizontal frame 123 from the respective brackets 151. And a second connection rod 152 connecting and supporting the third horizontal frame 124.

Here, the second connection rod 152 is a pair of upper connection rods 152a for connecting and supporting the second horizontal frame 123 from the bracket 151, respectively, and the third from the bracket 151. It includes a pair of lower connection rods (152b) for connecting and supporting the horizontal frame (124), respectively.

The bracket 151 is preferably provided in a trapezoidal shape, and one end of the upper connection rod 152a and the lower connection rod 152b is preferably coupled to a portion adjacent to an edge of the bracket 151. Do.

By providing the upper connection rod 152a and the lower connection rod 152b as described above, the first support unit 120 is more firmly supported from below, and concentrated in heavy snow or wind with heavy winds. Due to the snow weight, the load of the first support unit 120 may be distributed and supported, and the coupling state of the support frame 110 may be prevented from being deformed or damaged.

The power transmission unit is provided with a driving motor (M) at the lower side and a cam groove 162 formed on the outer circumferential surface and the cam motor 162 according to the rotation of the drive motor (M) corresponding to the shape of the cam groove (162). A lift arm 165 reciprocating in the vertical direction.

In addition, the cam groove 162 is formed as a closed curve to form a height difference so that the position of the lift arm 165 can be changed in the vertical direction.

The case 161 is provided with a plurality of gear members (not shown) which are engaged with the driving motor M and rotated. The upper side of the case 161 is horizontally in accordance with the rotation of the driving motor M. The hinge coupling frame 141 is disposed to rotate.

One end of the lift arm 165 is coupled to slide inside the lift arm 165, and the other end thereof is coupled to the first horizontal frame 122.

Accordingly, when the driving motor M rotates in the case 161, the hinge coupling frame 141 rotates, and the lift arm 165 rotates simultaneously with the hinge coupling frame 141 while the cam is rotated. The second support unit 150 is rotated in the vertical direction while reciprocating in the vertical direction along the shape of the groove 162.

As the lift arm 165 vertically reciprocates in response to the height difference between the cam grooves 162 and the lift arm 165, the elevation angle of the solar cell module 10 is adjusted according to time of day. Accordingly, the support frame 110 is rotated relative to the hinge coupling frame 141 in the vertical direction.

Here, the rotation for adjusting the altitude angle of the solar cell module 10 is performed by the vertical reciprocating movement of the lift arm 165 according to the rotation of the hinge coupling frame 141, the solar cell module 10 The support frame 110, the first support unit 120 and the second support unit 150 are rotated in the horizontal direction at the same time, wherein the case 161 including the case 161 is provided on the lower side Since the main body 300 is fixed to the ground and does not rotate, the configuration disposed above the second support unit 150 makes a relative rotational movement in the horizontal direction with respect to the case 161.

The main body 300 includes a controller 180 for controlling the driving motor M to adjust the azimuth and altitude angles of the solar cell module 10 according to the movement trajectory of the sun over time.

The dustproof pad 171 is provided on the bottom of the main body 300.

The anti-vibration pad 171 not only prevents vibration from being transferred from the ground to the photovoltaic device 100, but also has a function of preventing the vibration caused by the rotation of the power transmission unit from being transmitted to the ground.

The dust pad 171 is preferably formed of a compressed synthetic rubber material having a thickness of about 5 ~ 12mm.

In addition, since rubber chips are used as a base material and bonded with urethane binders, they have excellent impact energy absorption that general rubbers do not have due to the frictional resistance of fine chips and the excellent viscosity resistance of materials. .

Also, carbonized cork board for dustproofing, raw materials are crushed the bark of oak or oak for oak for oak to make particles that can pass through Ø2 ~ Ø22mm, put them in metal mold and compress them by heat or steam. Natural materials made by heating and firing may be used. The carbonized cork material has a long lifespan and excellent chemical resistance, moisture resistance, thermal insulation dustproofness, elasticity, tissue invariability, and furthermore, have harmless features and effects.

In addition, an orientation display unit 310 is provided on the main body 300.

The orientation display unit 310 is a guide member 311 provided on the power transmission unit, the orientation display member is formed on the outer peripheral surface of the main body 300 to indicate the orientation that the solar cell module 10 is facing 312.

The guide member 311 is provided to the upper side of the power transmission unit is provided to rotate simultaneously with the component to rotate by the rotation of the drive motor (M).

The orientation display member 312 is not rotated because the main body 300 is fixed to the ground, and one side of the guide member 311 is rotated on the orientation display member 312 the aspect The orientation of the battery module 10 currently pointing is displayed.

In this way, by displaying the orientation that the solar cell module 10 is currently facing by the orientation display unit 310, the user can know that the photovoltaic device 100 is operating efficiently, There is an effect that can roughly determine the operation error of the photovoltaic device 100 according to the sunrise and sunset of the.

4 is a partially enlarged view of the photovoltaic device 100 shown in FIG. 1.

3 and 4, a hinge coupling part 140 is provided below the first support unit 120 to engage the first support unit 120 in a vertical direction.

The hinge coupler 140 includes a hinge coupling frame 141 hinged to the bottom of the first horizontal frame 122, an upper surface of the hinge coupling frame 141, and a bottom surface of the first horizontal frame 122. Interposed in the hinge coupling structure is formed, and includes three fastening members 142 for supporting the load of the first support unit 120 distributed.

The hinge coupling frame 141 supports the support frame 110, the first support unit 120, and the second support unit 150 as a whole so that a maximum load is applied to the hinge coupling frame 141. It is formed relatively larger than the first support unit 120 and the second support unit 150, the fastening member 142 is disposed on the upper surface of the hinge coupling frame 141 at equal intervals.

The support frame 110 to which the solar cell module 10 is coupled is disposed to be inclined at a predetermined inclination angle with respect to the ground. The first support unit 120 and the second support unit 150 rotate relative to the hinge coupling frame 141 disposed below the first support unit 120 in the vertical direction.

This relative rotation causes the horizontal rotational motion to the vertical rotational motion in accordance with the rotation of the power transmission unit.

The support frame 110 has a duct groove 111 formed therein along the longitudinal direction of the support frame 110 to facilitate storage of the power line drawn out from the solar cell module 10.

One or more duct grooves 111 are formed on side, top and bottom surfaces of the support frame 110.

In addition, the duct groove 111 may be formed at least on the bottom surface of the support frame 110 in consideration of the arrangement and assembly of the solar cell module 10 on the support frame 110.

The duct groove 111 is provided with a duct cap 112 to prevent dust or rain water from flowing into the interior after receiving the power line. The duct cap 112 may be fastened in a sliding or interference fit manner at the end of the duct groove 111.

FIG. 5 is a rear perspective view of the solar cell apparatus 100 'according to another embodiment of the present invention, and FIG. 6 is a plan view showing the first support unit 120' shown in FIG.

5 and 6, the first support unit 120 ′ is configured to connect a pair of vertical frames 150 provided to be spaced apart from each other in a vertical direction, and a center portion of the vertical frames 150. And a first horizontal frame 122, a second horizontal frame 123 'and a third horizontal frame 124' connecting both ends of the vertical frame 150, respectively.

The second horizontal frame 123 'and the third horizontal frame 124' are connected to the vertical frame 150 from the second horizontal frame 123 'and the third horizontal frame 124'. The first extension frame 123a and the second extension frame 124a extend in both longitudinal directions, respectively.

The first extension frame 123a and the second extension frame 124a have a function similar to that of the auxiliary support part (refer to FIG. 3 and 126) shown in FIG. 1 and the bottom of the support frame (refer to FIG. 1 and 110). The effect of distributing the load can be expected at.

The first extension frame 123a extends in both sides of the second horizontal frame to support an upper bottom surface of the support frame 110 arranged in a horizontal direction, and is generated at an edge portion of the support frame 110. It extends to distribute the load.

In addition, the second extension frame 124a extends in both sides of the third horizontal frame to support a lower bottom surface of the support frame 110 arranged in a horizontal direction, but occurs at an edge portion of the support frame 110. It is extended to distribute and support the load.

Therefore, the first extension frame 123a and the second extension frame 124a are about 1/3 to 2/3 of the distance between both ends of the support frame 110 from each end of the vertical frame 150. It is preferably arranged to support the point.

In addition, as shown in FIG. 5, the solar cell module 110 ′ is disposed such that the solar cell module disposed in the vertical direction at the center thereof is spaced upwardly from other solar cell modules disposed in the vertical direction at both sides thereof. This reduces the wind pressure caused by the wind into the space spaced between the solar cell module disposed in the vertical direction in the center and the other solar cell modules disposed in the vertical direction on both sides, so that the accumulated snow can flow An effect that can prevent deformation and breakage of the battery module occurs.

In addition, although not shown in the drawing, the solar cell module disposed in the vertical direction in the center and the other solar cell module disposed in the vertical direction on both sides are installed to be spaced apart laterally, the solar cell disposed in the vertical direction in the center The module and the other solar cell modules arranged in the vertical direction on both sides are arranged to be spaced apart in the vertical direction and the horizontal direction, respectively, to have an effect of more effectively reducing the damage caused by wind pressure and snow.

FIG. 7 is a side view illustrating the power transmission unit illustrated in FIG. 1, and FIG. 8 is a plan view of the support bearing 170 illustrated in FIG. 7 as viewed from above.

In addition, the power transmission unit includes a support bearing 170 that can support the load applied to the portion of the upper portion of the case 161 and the hinge coupling frame 141 is auxiliary.

The support bearing 170 distributes the stress generated between the case 161 and the hinge coupling frame 141 while the rotational force provided from the driving motor M is transmitted to the hinge coupling frame 141, It has a function to improve the durability of the power transmission unit.

At this time, the support bearing 170 is preferably made of a three-point support structure in the interior as shown in Figure 8, of course, can be changed to a structure of four or more supports.

This is to distribute the pressure received on the support surface of the support bearing 170 evenly due to the external force such as the external wind pressure received while the hinge coupling frame 141 is rotated on the case 161.

9 is an exploded view showing the altitude control unit 200 shown in FIG.

9, an altitude adjusting unit 200 is provided between the other end of the lift arm 165 and the first horizontal frame 122.

The altitude control unit 200 is a handle portion 210 that the user can grip and rotate, a first fastening portion 220 protruding in both vertical directions from the center of the handle portion 210, and the first It is coupled to the fastening portion 220 includes a second fastening portion 230 which is fastened to reciprocate on the first fastening portion 220.

In addition, the altitude control unit 200 includes a diffraction member 125 connecting the second fastening unit 230 and the first horizontal frame 122.

Here, the altitude control unit 200 is rotated by the user manually to correct the difference in altitude according to the altitude of the sun by season, and gives a different driving force to the altitude control unit 200 automatically the difference in the altitude of the sun according to the season Of course, it can be finely corrected.

First, the handle 210 has a rod-shaped handle 212 is formed in a plurality of radially, the first fastening portion 220 extending in the vertical direction from the center of each of the handle 212 is integrally formed. In this case, it is preferable that at least three handles 212 are provided at equal intervals in the vertical direction of the first fastening part 220 with the first fastening part 220 as a central axis.

Therefore, when the handle 212 is rotated in the horizontal direction, the first fastening portion 220 becomes an axis to rotate simultaneously.

The first fastening part 220 is composed of an upper fastening member 221 and a lower fastening member 222. A right hand thread is formed on the outer circumferential surface of the upper fastening member 221, and a left hand thread is formed on the outer circumferential surface of the lower fastening member 222. Of course, although not shown in the drawings, the first fastening part 220 may be formed in a thread buckle in a different direction at each end of the inner circumferential surface in the form of a turn buckle rather than a bolt shape.

Furthermore, the screws formed on the outer circumferential surfaces of the upper fastening member 221 and the lower fastening member 222 are formed in opposite directions to each other, and left screws are formed on the outer circumferential surface of the upper fastening member 221, and the lower fastening is performed. Of course, the right hand thread may be formed on the outer circumferential surface of the member 222.

In addition, the second fastening portion 230 includes an upper coupling member 231 and a lower coupling member 232.

Then, the second coupling part 230 connected to both sides of the first fastening part 220 may correspond to a screw shape respectively formed on the first fastening part 220. A coupling hole 231a having a right screw is formed to be coupled to the coupling member 221, and the lower coupling member 232 has a coupling hole 231b having a left screw formed to be coupled to the lower coupling member 222. Is formed.

Therefore, when the first fastening portion 220 is rotated in the clockwise direction, the upper coupling member 231 and the lower coupling member 232 is the central direction of the first fastening portion 220, that is, the radial handle 212 When the linear movement close to the center portion, and the first fastening portion 220 is rotated in the counterclockwise direction, the upper coupling member 231 and the lower coupling member 232 is the first fastening portion ( 220 is a linear movement in a direction away from each other.

A coupling hole 233a is formed at one side of the upper coupling member 231 so as to be rotatable from the diffraction member 125 in the vertical direction of the coupling hole 231a in which the right screw is formed.

Here, the diffraction member 125 is coupled to the upper coupling member 231 at a position deviating from the vertical rotation center of the first horizontal frame 122, and the upper coupling member 231 is coupled to be rotatable. Accordingly, the diffraction member 125 is configured such that the inclination angle of the solar cell module (see FIGS. 2 and 10) is adjusted according to the seasonal altitude angle of the sun as the handle 210 rotates clockwise or counterclockwise. It has a function of converting the linear motion of the second fastening portion 230 to the rotational motion of the solar cell module (see FIG. 4: 10).

In addition, a coupling hole 233b is formed at one side of the lower coupling member 232 so as to be rotatable from an end of the lift arm 165 in the vertical direction of the coupling hole 231b in which the left screw is formed.

As such, when the altitude control unit 200 is used, the user can adjust the altitude angle of the solar cell module (see FIG. 1 and 10) according to the altitude angle of the seasonal sun alone.

In addition, the altitude control unit 200 includes an altitude display unit 240. The altitude display unit 240 is displayed on the first fastening unit 220 in at least two steps so that the user can recognize the eye.

The altitude display may allow the user to recognize the difference in the altitude angle of the seasonal sun, and to rotate the altitude control unit 200 to a predetermined angle in accordance with the appropriate altitude angle. The altitude display unit 240 may display a seasonal altitude angle by limiting the number of revolutions of the first fastening unit 220 or by changing a color by drilling a groove or a hole in the first fastening unit 220.

At this time, the altitude display unit 240 is set to display in three steps, it is preferable to display to adjust the altitude angle of the sun according to spring / autumn, summer and winter.

Hereinafter, with reference to the drawings will be described in detail the operational effects of the photovoltaic device 100 according to the present invention.

10 to 12 are side views showing that the arrangement angle of the solar cell module 10 shown in FIG. 1 changes according to the altitude change of the sun. Like reference numerals denoted below denote like components.

The straight line L connecting the surface of the solar cell module 10 from the sun S should be in a vertical state to maximize the light collecting efficiency.

As shown in FIG. 10, the altitude h1 of the sun at the sunrise is maintained at the lowest state. In this case, the arrangement angle θ1 of the solar cell module 10 should be the largest inclination angle from the ground.

To this end, the lower end of the lift arm 165 should be bitten at the lowest portion of the cam groove 162.

In this case, since the diffraction member 125 coupled to the upper end of the altitude adjusting part 200 is pulled downward to the maximum, the arrangement angle of the solar cell module 10 achieves the largest inclination angle.

At this time, the direction toward which the solar cell module 10 is directed should be the east direction where sunrise begins.

As shown in FIG. 11, as time passes, the sun moves from east to southeast, thus raising altitude h2.

Reflecting such a change in the direction and altitude of the sun, when the controller (see FIG. 2, 180) controls the driving motor M, the solar cell module 10 is moved southeast by the rotation of the driving motor M. Will rotate to look at

On the other hand, the height of the cam groove 162, the lower end of the lift arm 165 is bite is disposed in a higher state than in the case of Figure 10, accordingly the lift arm 165 also with the altitude control unit 200 To rise.

When the lift arm 165 is raised, the upper end of the solar cell module 10 is flipped backward, and the placement angle θ2 is smaller than the ground in FIG. 10.

As shown in FIG. 12, as time elapses and the sun reaches the highest altitude h3, the sun is located south.

At this time, the solar cell module 10 is rotated to face south, the lower end of the lift arm 165 is located in the portion of the cam groove 162 is the maximum height.

In this case, since the diffraction member 125 coupled to the upper end of the altitude control part 200 is pushed upward to the maximum, the inclination angle of the solar cell module 10 is the smallest.

Therefore, the arrangement angle θ3 of the solar cell module 10 may maximize the light collection efficiency by forming the smallest inclination angle.

As time passes, the sun moves southwest, and the altitude of the solar cell module 10 is also lowered. Accordingly, the horizontal rotating frame rotates so that the solar cell module 10 faces southwest. Perform the exercise.

In addition, the height of the cam groove 162 meshed with the lower end of the lift arm 165 is also lowered than the case of FIG. 11 to reflect the lowered altitude, so that the arrangement angle of the solar cell module 10 is shown in FIG. The angle of inclination is greater than that.

As the sunset approaches, the sun is on the west side, and the altitude of the solar cell module 10 is also lower.

Reflecting this, the support frame 110 performs a rotational movement so that the solar cell module 10 faces the west direction.

In addition, the lower end of the lift arm 165 is located at the lowest part of the height of the cam groove 162 to reflect the sun altitude of the state.

Therefore, the arrangement angle of the solar cell module 10 forms a maximum inclination angle. And after the sun is set after sunset, the solar cell module 10 is rotated to face the east direction before the start of the next sunrise so that the solar cell module 10 can focus again at the next sunrise.

Therefore, the photovoltaic device 100 according to the present invention automatically rotates to maximize the condensing efficiency according to the change in the altitude of the sun and the change in the azimuth angle of the sun over time, and also according to the change of the season. In response to the change in the altitude of the sun, the user can manually adjust the seasonal altitude angle.

In addition, the first support unit and the second support unit is installed on the lower side of the support frame as the power generation scale of the photovoltaic device increases, the effect that can be supported more stably the solar cell module is expected.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

100, 100 ′: solar power generator 110: support frame
120: first support unit 140: hinge coupling portion
150: second support unit 160: power transmission unit
170: support bearing 180: control unit
200: altitude control unit 300: main body
310: bearing display unit 400: lightning protection unit

Claims (14)

A plurality of solar cell modules;
A support frame mounted to change the coupling positions of the solar cell modules and having a shielding duct groove formed on at least one or more of a side surface or a bottom surface thereof to accommodate a power line drawn from the solar cell module;
A pair of vertical frames disposed in a vertical direction under the support frame so as to distribute and support the load of the support frame, and a first horizontal connecting the vertical frames, respectively connecting the centers of the vertical frames A first support unit comprising a frame, a second horizontal frame and a third horizontal frame connecting the ends of the vertical frames to the first horizontal frame in parallel;
A second support unit hinged to a lower side of the first support unit such that the first support unit can rotate in a vertical direction; And
The case is coupled to the lower side of the second support unit, and rotates the first support unit and the second support unit by a drive motor provided therein, the cam groove is formed on the outer peripheral surface and the rotational motion of the drive motor Therefore, a power including a lift arm reciprocating in a vertical direction corresponding to the shape of the cam groove, one end of which is slidably disposed in the cam groove, and the other end of which is rotatably coupled on the first horizontal frame. Delivery unit;
Photovoltaic device comprising a. delete delete The method according to claim 1,
The first horizontal frame,
The solar cell apparatus is formed to have a larger cross-sectional area than the cross-sectional area of the second horizontal frame and the third horizontal frame. The method according to claim 1,
The first support unit,
First fixing members provided at both ends of each of the vertical frames;
A plurality of first connecting rods having one end rotatably coupled to the first fixing member and extending in a vertical direction of the vertical frame;
A second fixing member provided below the support frame to rotatably couple the other ends of the first connecting rods.
Photovoltaic device further comprising an auxiliary support. The method according to claim 5,
The auxiliary support,
The first photovoltaic device is formed so that the position where the support rod supports the support frame is adjustable. The method according to claim 1,
Wherein the second support unit comprises:
A pair of brackets provided at both lower ends of the first horizontal frame;
And a plurality of second connection rods coupled to connect the second horizontal frame and the third horizontal frame, respectively, from the bracket. The method according to claim 1,
The first support unit,
And a first extension frame extending in both sides of the second horizontal frame, and a second extension frame extending in both sides of the third horizontal frame. The method according to claim 8,
The first extended frame and the second extended frame,
It is formed to protrude in the vertical direction of each of the vertical frame, the solar cell apparatus is disposed on the bottom surface of the support frame to distribute and support the load of the solar cell module. delete Claim 11 was abandoned upon payment of a setup registration fee. The method according to claim 1,
The solar cell module further comprises an altitude control unit provided between the first horizontal frame and the other end of the lift arm so that the solar cell module can correct the seasonal difference in the elevation angle of the sun. Claim 12 is abandoned in setting registration fee. The method of claim 11,
The altitude control unit,
A plurality of handle portions formed radially extending to allow the user to rotate manually in a clockwise or counterclockwise direction so as to manually adjust the seasonal elevation angles;
A first fastening portion having a predetermined length so as to extend in both directions perpendicular to the center of the handle portion of a radial shape and a female screw on an outer circumferential surface or a female screw on an inner circumferential surface;
When the handle portion rotates in one direction away from the center of the handle portion, when the handle portion rotates in the other direction is fastened to both sides of the first fastening member to be closer to the center of the handle portion, respectively, the first fastening A second fastening portion in which a female thread or a male thread is formed to correspond to the portion;
Photovoltaic device comprising a. Claim 13 was abandoned upon payment of a registration fee. The method according to claim 1,
In the solar cell module,
A plurality of patterns are formed in a lattice structure, the solar cell module disposed in the center so that the wind or snow can move is spaced apart from the other solar cell modules arranged on both sides to the upper side. Claim 14 has been abandoned due to the setting registration fee. The method according to claim 13,
The solar cell module disposed in the center,
The solar cell apparatus is spaced apart laterally so that a gap is formed between the other solar cell modules disposed on both sides.

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