KR101309542B1 - Solar and windpower generation system - Google Patents

Abstract

PURPOSE: A sunlight windpower polyhedral angle fusion development system for a next generation distribution type smart power generation system and a manufacturing method thereof are provided to frequently pass wind between photovoltaic modules, thereby maintaining generation efficiency by keeping optimal temperature. CONSTITUTION: A top polyhedral angle photovoltaic module (100) comprises a top perpendicular frame (111), a top photovoltaic module (110), a top module upper end fitting, a top module lower end fitting (112, 113), a top upper end frame, a top bottom end frame (114, 115) and a top junction box (116). A central part polyhedral angle photovoltaic module (200) comprises a central part perpendicular frame (211), a central part photovoltaic module (210), a ventilation hole (217), a central part module upper end fitting, a central part lower end fitting (212, 213), a central part upper frame end, a central part bottom frame (214, 215) and a central part junction box (216). A lower part polyhedral angle photovoltaic module (300) comprises an underlying junction box (313), a lower part photovoltaic module (310) and a photovoltaic module (311). A module frame (400) comprises a calumniation addition furnace frame (431), a middle and lower part horizontal frame (441), a lower part horizontal frame (461) and a longitudinal frame (470). An aerogenerator (700) rotates with a wing around a rotary shaft (707). A cylinder (600) is combined with the frame of the lower part photovoltaic module. A sub-motor (603) of a cylinder rotates around a circulation (500) and descends and ascends. A sunlight windpower polyhedral angle hunting fusion generator (10) including the lower part polyhedral angle photovoltaic module is connected in series and parallel to a power conversion device (20) by a system interconnection line (23). [Reference numerals] (AA) Cross arm; (BB) Neutral line; (CC) Concrete block; (DD) 16M KEPCO telephone post

Description

The Korea Electric Power Corporation's network power grid that does not require a power generation site due to the new renewable energy supply mandatory system. windpower generation system}

The present invention is the next generation decentralized smart energy generation supply mass system utilizing the KEPCO network grid residential space (approximately 8.5 million KEPCO distribution volume) that does not require a power generation site in accordance with the new renewable energy supply obligation (RPS) system. The present invention relates to a multi-purpose solar wind tracking converged power generation system and a method of manufacturing the same. More specifically, the multi-directional solar wind tracking converged power generation system is installed in an existing KEPCO distribution grid, and is generated by serial or parallel connection between power generation systems. It is a foldable solar module with solar tracking function that rises and descends according to the moving trajectory of Highly efficient power generation increases and more power can be obtained using wind turbines Supplying next-generation distributed smart energy generation using electric poles of KEPCO network grid that does not require a power generation site according to the implementation of new renewable energy supply mandatory system. It is about.

Today, telegraph poles play an indispensable role in the passage of special high voltage lines, automatic switchgear, transformers, communication lines, and various power lines. Telegraph poles, however, are embedded in various places between the city center and the island of Sok, not only having a role of passing railroads, but also not worth any more, and are not aesthetically pleasing, and are gradually recognized as concrete pillars occupying sidewalks and driveways. Therefore, in today's city centers, a method of removing utility poles with low utility value and laying various tracks underground is in operation, and is considering how to utilize existing telegraph poles.

The present invention has been made to solve the above problems, the purpose is to utilize the pole columnar space of the pole of the utility pole is less useful value, the high efficiency solar light in the 8 to 16-segment parallel configuration of the photovoltaic module in the place where the projection shadow occurs It is possible to generate power and keep the static temperature on the surface of the solar module by allowing the air to pass through the space between the solar modules well. It is equipped with a Savonius wind generator inside to enable wind power generation when solar power is not available. The wind generator installed on the upper side is installed inside the solar module to eliminate projection shadows, and consists of various shapes such as typhoons or Its purpose is to protect wind power generators due to strong winds and to reduce wind pressure and side load of structures.

The upper polyhedral photovoltaic module with the inclined angle of the upper photovoltaic module is arranged in a circle and the central photovoltaic solar module with the inclination angle in the middle and a plurality of circularly arranged central polyhedral solar modules is located in the lower part. The lower photovoltaic module in which a plurality of photovoltaic modules are coupled to a rectangular frame is vertically arranged, and the lower side photovoltaic modules arranged in a plurality of circular positions are located, and a central coupling portion formed vertically in the center is located and the center coupling portion is centered. From the top to the bottom, the circular upper circular ring frame, the upper and lower circular ring frame, the middle and lower circular ring frame, and the polygonal middle and lower polygonal ring frame and the lower polygonal ring frame are located. The upper horizontal frame, the upper middle frame and the lower middle frame are combined with the lower horizontal frame. The heavy load in the frame part a plurality of longitudinal frames in the frame and the lower horizontal frames are coupled. The upper and lower parts of the upper polyhedral solar module are coupled to the upper circular ring frame and the upper and lower circular ring frames. The rotating body is coupled to each side of the frame, and the lower side solar module is coupled to one side of the rotating body. The coupling is coupled to the rear of the lower photovoltaic module, the coupling is coupled to the vertical frame, one end of the housing is coupled to the coupling coupled to the vertical frame, one end of the shaft is coupled to the coupling coupled to the lower photovoltaic module, and the servo The motor is coupled.

The upper circular fixing plate is formed in the upper coupling plate and a plurality of holes, the lower circular fixing plate is formed in the lower position, the housing is coupled to the hole of the upper circular fixing plate, the generator is coupled to the inside of the housing, The rotary shaft is vertically coupled to the lower end of the generator, the horizontal disk is coupled to the upper and lower to the rotary shaft and has a curved shape between the horizontal disk and comprises a plurality of wings are arranged around the rotating shaft is a wind power generator.

The upper circular fixing plate and the lower circular fixing plate of the wind power generator are coupled to the middle lower part horizontal frame and the lower horizontal frame.

The solar wind multi-directional tracking fusion generators configured as described above are coupled to the upper poles of each pole, and connected to the power converter by connecting a plurality of solar wind multi-directional tracking fusion generators in series or parallel, and connected to the grid connection line through a meter and a transformer. It is configured to be connected.

Multi-Purpose Tracking Wind Power Convergence Power Generation System for Next Generation Distributed Smart Energy Power Supply Mass System Using KEPCO Network Grid Space without Power Generation Sites in accordance with the New Renewable Energy Supply Mandatory System of the Invention The wind passes through the space between the solar modules in various directions, so that the heat generated in the solar cell module during the summer due to the large flow wind speed is rapidly cooled to maintain the proper temperature so that the power generation efficiency is not reduced. This small and inclined surface prevents snow from accumulating on the surface of multi-sided solar cell modules in winter, and increases the amount of power generated by rising and lowering of the foldable solar cell modules according to the sun's movement trajectory. Spawning and scattering at places receiving It is possible to generate electricity by reflecting solar rays, and it can generate additional power by operating wind power generator by opening up the inner space by rising foldable solar module on windy day or at night, and typhoon or strong wind prevent the wind generator from being burned out. It has the advantage of eliminating the unbalanced load in the polyhedral form, having an excellent surface dominant effect in the wind, and reducing the wind pressure load such as typhoons and strong winds.

1 is a pole installation of a multi-track tracking fusion generator solar wind.
2 is a perspective view of a solar wind multi-directional tracking fusion generator.
Figure 3 is a side cross-sectional view of a solar wind multi-directional tracking fusion generator.
Figure 4 is a perspective view of the module frame.
Figure 5 is a multi-faceted solar tracking module perspective view.
6 is an exploded view of a part of the upper polyhedral solar module.
Figure 7 is a top cross-sectional view of the polygonal solar module.
Figure 8 is a partial exploded view of the central polyhedral solar module.
Figure 9 is a plan view of the central polyhedral solar module.
10 is a partial exploded view of the lower photovoltaic module.
Figure 11 is a bottom cross-sectional photovoltaic module plan view.
12 is a bottom side photovoltaic module and cylinder detailed view.
13 is a wind turbine perspective view.
14 is a side view of the wind generator.
15 is an overall circuit diagram (1).
16 is an overall circuit diagram (2).
17 is a block diagram.
18 is a program circuit configuration diagram.
19 is an overall schematic diagram.
20 is an exemplary view illustrating the operation of the solar wind multi-directional tracking fusion generator.
21 is an exemplary view installed on a traffic light column.

Or less, multi-track tracking convergence power generation system for the next generation distributed smart energy generation supply mass system using the Korea Electric Power Corporation network power grid pole space that does not require a power generation site in accordance with the new renewable energy supply obligation system according to the present invention and The manufacturing method will be described in detail with reference to the accompanying drawings.

1 is an installation view of the pole pole space of the solar wind multi-directional tracking fusion generator, Figure 2 is a perspective view of the solar wind multi-directional tracking fusion generator, Figure 3 is a side cross-sectional view of the solar wind multi-directional tracking fusion generator, Figure 4 Figure 5 is a perspective view of the module frame, Figure 5 is a perspective view of a multi-sided solar tracking module, Figure 6 is a partial exploded view of the upper polyhedral solar module, Figure 7 is a flat sectional view of the upper polyhedral solar module, Figure 8 is a central polyhedral solar Partial exploded view of the optical module, Figure 9 is a cross-sectional view of the central polyhedral solar module, Figure 10 is an exploded view of the lower photovoltaic module, Figure 11 is a flat cross-sectional view of the lower side photovoltaic module, Figure 12 is a bottom side solar FIG. 13 is a perspective view of the wind turbine, FIG. 14 is a side cross-sectional view of the wind turbine, and FIG. 15 is a circuit diagram (1) of the solar wind multi-directional tracking fusion generator. 16 is a circuit diagram (2) of a solar wind multi-directional tracking fusion generator, FIG. 17 is a block diagram of a solar wind multi-directional tracking fusion generator, FIG. 18 is a control program circuit configuration, FIG. 19 is a schematic diagram, and FIG. 20 is an exemplary view illustrating the operation of the solar wind multi-directional tracking fusion generator, and FIG. 21 is an exemplary view of the solar wind multi-directional tracking fusion generator installed in a traffic light column.

1 to 14, the configuration of the present invention, the multi-sided solar wind tracking fusion generator 10 is the upper polyhedral solar module 100 is located at the top and the upper polyhedral solar module 100 The central polyhedral solar module 200 is located below the central polyhedral solar module 200 and the lower polyhedral solar module 300 composed of a plurality of lower photovoltaic modules 301 below the central polyhedral solar module 200. It consists of a module frame 400 and a cylinder 600.

The upper polygonal photovoltaic module 100 has a vertical configuration and a plurality of upper vertical frames inclined at a predetermined angle by being arranged in parallel with an interval therebetween symmetrically formed with coupling grooves 118 formed in one longitudinal direction ( The upper photovoltaic module 110 is coupled to the coupling groove 118 between the upper and lower vertical frames 111 arranged in a circle at a predetermined interval, and the parallel upper photovoltaic module ( An empty space is formed between the 110 and the vent hole 117. In addition, an upper module upper fixing body 112 having a protrusion and a groove is coupled to an upper end of each upper solar module 110, and an upper module lower end having a protrusion and a groove formed at a lower end of the upper solar module 110. The stagnation 113 is coupled to prevent the upper photovoltaic module 110 from being separated from the upper vertical frame 111, and the upper top of the upper surface of the upper module upper fixing body 112 having a plurality of coupling grooves 119 formed therein. The frame 114 is padded and fixed so that the upper end of the upper vertical frame 111 is inserted into the coupling groove 119, and the upper lower frame having a plurality of coupling grooves 120 formed on the lower surface of the lower module fixing body 113, respectively. 115 is padded and fixed to the lower end of the upper vertical frame 111 is inserted into the coupling groove (120). In addition, the upper junction box 116 is attached to the upper and lower portions of the upper photovoltaic module 110 to serve as terminal blocks.

The central polyhedral photovoltaic module 200 is vertically configured, and a plurality of central vertical frames 211 are inclined at a predetermined angle by forming coupling grooves 218 in one longitudinal direction and symmetrically spaced in parallel to each other. ) Are circularly arranged at regular intervals, the central photovoltaic module 210 is coupled to the coupling groove 218 in between the middle vertical frame 211 arranged in parallel, the combined central photovoltaic module 210 An empty space is formed between the holes and constitutes a vent hole 217. In addition, the upper end of each of the central solar module 210 is a central module upper fixing body 212 is formed with a protrusion and a groove is coupled to the lower end of the central module module with a protrusion and groove formed at the bottom of the central solar module 210 The stagnant 213 is coupled to prevent the central photovoltaic module 210 from being separated from the central vertical frame 211, and the upper portion of the central module upper fixing body 212 has a plurality of coupling grooves 219 formed therein. The frame 214 is padded and fixed so that the upper end of the middle vertical frame 211 is inserted into the coupling groove 219, and the lower lower frame having a plurality of coupling grooves 220 formed on the lower surface of the lower module 213 of the central module. 215 is padded and fixed so that the lower end of the central vertical frame 211 is inserted into the coupling groove 220. In addition, the central junction box 216, which serves as a terminal block, is attached to the upper and lower portions at the rear of each of the central solar modules 210.

The lower side photovoltaic module 300 is configured to vertically comprise a lower photovoltaic module 310 coupled to a plurality of photovoltaic modules 311 in a rectangular frame 312, the lower photovoltaic module 310 is It is configured to be arranged in a large number in a circle. In addition, the lower junction box 313 which functions as a terminal block is attached to the upper and lower portions of the rear of each solar module 311.

The upper photovoltaic module 100, the central photovoltaic module 200, and the photovoltaic module 311 have a function of converting light energy into electrical energy, and are typically configured to produce electrical energy when receiving sunlight on a surface. It is.

In the center of the multi-faceted solar tracking module 11 is a central coupling portion 410 formed in a vertical cylindrical shape, the central coupling portion 410 is divided into half vertically so that it can be coupled to poles, such as poles and poles. The upper circular ring frame 420 is formed in a circular shape on the upper portion of the central coupling portion 410 is fixed to the upper end of the upper polyhedral solar module 100, the upper circular ring frame (from the central coupling portion 410) 420 is horizontally coupled to the upper horizontal frame 421 in the form of spokes. In addition, a circular middle upper circular ring frame 430 is positioned with a predetermined interval below the upper circular ring frame 420, so that the lower end of the upper polyhedral solar module 100 and the upper end of the central polyhedral solar module 200 are positioned. It is fixed, the middle upper portion circular frame 431 in the shape of the spokes horizontally from the center coupling portion 410 to the upper middle circular annular frame 430 is coupled. In addition, the lower and lower circular annular frame 440 of the circular middle and lower circular circular frame 440 is located at a constant interval below the fixed to the bottom of each of the central solar module 200, the central coupling portion 410 The middle lower circular ring frame 440 horizontally to the middle lower circular ring frame 440 is coupled. In addition, a lower and lower polygonal ring frame 450 formed of polygons having a predetermined interval below the middle and lower circular ring frame 440 is located, and the rotating body 500 for each side of the middle and lower polygonal ring frame 450. Is coupled to the upper surface of the solar module 300 if the lower side is coupled to the rotating body (500).

The lower polygonal ring frame 460 composed of the same polygon as the lower and lower polygonal ring frame 450 is arranged at regular intervals below the lower and lower polygonal ring frame 450, and the lower surface of the solar module 300 is lower. Located in the horizontal coupling from the central coupling portion 410 to the lower polygonal ring frame 460 horizontally shaped lower wheel frame 461 is formed.

A plurality of vertical frames 470 are vertically coupled between the upper and middle horizontal frame 431, the middle and lower horizontal frame 441, and the lower horizontal frame 461, and are configured to be overall robust.

The cylinder 600 is coupled to the lower surface solar module 300 and the module frame 400. The cylinder 600 has a combination 610 is coupled to the inner side of the lower photovoltaic module 310, one side end of the shaft 602 inserted into the housing 601 is coupled to the combined combination 610, vertical One end of the housing 601 is coupled to the assembly 610 coupled to the frame 470, and the servo motor 603 is coupled to the end of the housing 601.

The cylinder 600 configured as described above automatically tracks sunlight by a program so that the servo motor 603 is operated so that the shaft 602 is drawn out and drawn out from the housing 601. This will be a folding or unfolding action.

The configuration of the wind power generator 700 has an upper circular fixing plate 701 is located at the top and a lower circular fixing plate 702 is located at the bottom, and a center coupling at the center of the upper circular fixing plate 701 and the lower circular fixing plate 702. A coupler 703 is formed to be inserted into the portion 410, and a plurality of holes 704 are formed around the coupler 703. A housing 705 capable of coupling the generator 706 is coupled to each of the holes 704, and a generator 706 is coupled to the inside of the housing 705, and a vertical axis of rotation is formed at the bottom of the generator 706. 707 is coupled, a plurality of wings 712 of a curved shape around the rotation axis 707 is arranged in a circular shape, the horizontal disk 711 is configured to be coupled to the upper and lower portions of the wing 712. .

The wind turbine 700 has a coupling hole 703 is inserted into the central coupling portion 410 of the module frame 400 and the upper circular fixing plate 701 in the lower middle frame 444 and the lower horizontal frame 461 and Lower circular fixing plate 702 is configured to be coupled and fixed.

Referring to FIGS. 15 to 19, the wind generator 700 is configured in series and connected to the power converter 20 through the regulator 26 due to the large width of the voltage variation. 100 and the central polyhedral photovoltaic module 200 and the lower polyhedral photovoltaic module 300 are connected in series and in parallel to the harvesting circuit 24, the power conversion device 20 in the harvesting circuit 24 It is configured to be connected to, is configured to be a variety of control by the PLC program, it is configured to be connected to the grid connection line 23 through the power meter 21 and the transformer 22 in the power converter 20.

Referring to FIG. 20, in the solar wind multi-directional tracking fusion generator 10, the lower surface solar module 300 rises and falls in accordance with the south-high altitude that changes with time from sunrise to sunset of the sun 30. It is configured to be.

Referring to FIG. 21, the solar wind multi-directional tracking fusion generator 10 is configured to be installed on the upper part of the traffic light 32 as well as the electric pole.

The multi-sided solar wind tracking fusion generator 10 can be configured in various sizes by increasing the division or capacity according to the required generation voltage and power generation.

10: solar wind multi-directional tracking fusion generator
11: multi-sided solar tracking module
20: power converter (PCS) 21: power meter 22: transformer
23: grid connection line 24: harvesting circuit 25: connector 26: regulator
30: sun 31: pole 32: traffic light pole
100: upper polygonal solar module
110: upper photovoltaic module 111: upper vertical frame 112: upper module upper fixture
113: upper module lower fixed body 114: upper upper frame 115: upper lower frame
116: upper junction box 117: vent 118: coupling groove 119: coupling groove
120: coupling groove
200: central polyangular solar module
210: central solar module 211: central vertical frame 212: central module upper stationary body
213: middle module lower fixed body 214: middle upper frame 215: middle lower frame
216: central junction box 217: vent 218: coupling groove 219: coupling groove
220: coupling groove
300: lower side photovoltaic module 310: lower side photovoltaic module
311: solar module 312: frame 313: junction box
400: module frame 410: central coupling portion
420: upper circular ring frame 421: upper horizontal frame
430: upper middle circular frame 431: upper middle frame
440: middle and lower circular frame 441: middle and lower circular frame
450: middle and lower polygonal round frame
460: lower polygonal round frame 461: lower horizontal frame
470: vertical frame
500: the body
600: cylinder 601: housing 602: axis 603: servo motor
610: conjugate
700: wind power generator
701: upper circular fixing plate 702: lower circular fixing plate 703: coupler 704: hole
705: housing 706: generator 707: axis of rotation
710: wind power wing 711: horizontal disc 712: wing

Claims (2)

A plurality of upper vertical frames 111 are vertically arranged and the coupling grooves 118 are formed in one longitudinal direction and are symmetrical to each other and are arranged in a circular manner at a predetermined interval in parallel and inclined at a predetermined angle, and the parallel upper vertical A plurality of upper photovoltaic modules 110 coupled to the coupling grooves 118 between the frames 111, vent holes 117 formed between the combined upper photovoltaic modules 110, and the upper portion; The upper module upper fixing body 112 and the upper photovoltaic module is coupled to the upper end of the solar module 110 to form a protrusion and a groove to prevent the upper photovoltaic module 110 from being separated from the upper vertical frame 111. It is coupled to the lower end of the 110 is formed with a protrusion and a groove so that the upper photovoltaic module 110 to prevent the departure from the upper vertical frame 111 and the upper module lower fixing 113 and the upper module upper fixing 112 A plurality of coupling grooves (1) fixed to the upper surface of 19 is formed so that the upper upper frame 114, the upper end of the upper vertical frame 111 is coupled to the coupling groove 119, and the plurality of coupling grooves 120 fixed to the lower surface of the upper module lower fixing body 113 The upper lower frame 115 is formed and the lower end of the upper vertical frame 111 is coupled to the coupling groove 120, and the upper junction box 116 attached to the upper and lower portions of the rear of the upper photovoltaic module 110. The upper polyhedral solar module 100, including;
A plurality of central vertical frames 211 which are vertically formed and the coupling grooves 218 are formed in one longitudinal direction and are symmetrical to each other and are arranged in a circular manner at parallel intervals and inclined at a predetermined angle, and the parallel vertical verticals The central photovoltaic module 210 including a plurality of solar cells coupled to the coupling groove 218 between the frames 211, and the ventilation holes 217 having a space formed between the combined central photovoltaic modules 210. And, the upper part of the central module module 212 is coupled to the upper end of the central photovoltaic module 210 is formed with a protrusion and a groove to prevent the central photovoltaic module 210 is separated from the central vertical frame 211, A central module lower end fixing body 213 and a central module upper end coupled to the lower end of the central solar module 210 to form a protrusion and a groove to prevent the central solar module 210 from being separated from the central vertical frame 211. Fixed to the upper surface of the fixture 212 The plurality of coupling grooves 219 are formed, the upper middle frame 214 is inserted into the upper end of the middle vertical frame 211 and the plurality of coupling grooves 220 fixed to the lower surface of the lower module 213 of the central module Is formed and the bottom surface of the middle vertical frame 211 is inserted into the lower middle frame 215, and the central polyhedron including a central junction box 216 attached to the middle and the middle of the rear of the central solar module 210 Optical module 200,
The lower photovoltaic module 310 is vertically formed by combining a plurality of photovoltaic modules 311 having a lower junction box 313 attached to the rear of the frame 312 having a quadrangular shape. A lower surface solar module 300 having a plurality of circular arrangements;
The center coupling portion 410 located in the center, the upper circular ring frame 420 and the upper and lower circular ring frame 430 and the middle and lower circular ring frame 440 consisting of a circular shape from the top to the bottom around the central coupling portion 410 ) And the lower and lower polygonal ring frame 450 and the lower polygonal ring frame 460 composed of polygons are arranged at predetermined intervals, and the upper horizontal frame 421 and the middle upper part of the wheel-shape shape in the central coupling part 410 are arranged. The lower frame 431, the lower middle horizontal frame 441, and the lower horizontal frame 461 each have an upper circular ring frame 420, a middle upper circular ring frame 430, a middle lower circular ring frame 440, and a middle lower polygon ring frame. The vertical frame 470 coupled to the lower polygonal ring frame 460 and coupled to the upper and lower horizontal frame 431 and the lower and lower horizontal frame 441 and the lower horizontal frame 461. Module frame 400 and configured to include;
Lower circular fixing plate 702 including an upper circular fixing plate 701 which is located at the top and includes a coupling hole 703 formed in the center and a plurality of holes 704, and a coupling hole 703 located at the bottom and being formed in the center. ), A housing 705 coupled to a position of the hole 704 of the upper circular fixing plate 701, a generator 706 coupled to the inside of the housing 705, and perpendicular to a lower end of the generator 706. A rotation shaft 707 coupled to the rotation shaft, a plurality of horizontal disks 711 inserted into the rotation shaft 707 and formed in a circular shape and positioned at predetermined intervals between upper and lower portions, and between the horizontal disks 711. A wind generator 700 having a curved shape and including a plurality of wings 712 arranged in a circle about a rotation axis 707;
The upper and lower circular fixing plate 701 and the lower circular fixing plate 702 of the wind turbine 700 are coupled to and fixed to the middle and lower part horizontal frame 441 and the lower horizontal frame 461 included in the module frame 400. The upper end of the upper polyhedral solar module 100 is coupled to the circular annular frame 420, the lower end of the upper polyhedral solar module 100 and the upper end of the central polyhedral solar module 100 to the middle upper circular annular frame 430. It is coupled, the bottom of the central polyangular solar module 200 is coupled to the lower and lower circular ring frame 440, the rotating body 500 is coupled to each side of the middle and lower polygonal ring frame 450, the rotating body 500 A top of a plurality of lower photovoltaic modules 310 included in the lower multi-faceted photovoltaic module 300 is coupled to each rotating body 500 at one side of the side;
The coupling body 610 is coupled to the frame 312 and the vertical frame 470 included in the module frame 400 and the lower side photovoltaic module 310, one side is coupled to the outside of the vertical frame 470 The housing 601 is coupled to the servo motor 603, and one end is inserted into the housing 601 and the other end includes a shaft 602 is coupled to the coupling 610 coupled to the frame 312 A cylinder 600 configured;
The servo motor 603 of the cylinder 600 is operated so that the shaft 602 is drawn out or drawn in so that the lower surface solar module 300 is rotated about the pivot 500 to move up and down;
The solar wind multi-directional tracking fusion generator 10 including the lower surface solar module 300 is configured to operate the cylinder 600 by the control of the PLC control program to move up and down, one or more poles (31) Is installed in series and parallel to the power converter 20, and is configured to be connected to the grid connection line 23 through the power meter 21 and the transformer 22 in the power converter 20 KEPCO's network power grid that does not require a power generation site due to the implementation of the obligation to supply renewable energy
The method of claim 1,
The solar wind multi-directional tracking fusion generator 10 is a power grid pole of the Korea Electric Power Corporation network power grid that does not require a power generation site in accordance with the implementation of the new renewable energy supply mandatory system, including being installed in one or more traffic light poles (32) Supply of next generation decentralized smart energy using PV solar wind multi-faceted convergence power generation system for mass system

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