KR101150655B1 - Diamond-shaped multi-directional fixed tracking methods solar cells system streetlight and the manufacturing method - Google Patents

Abstract

The present invention relates to a diamond-shaped multi-directional fixed-tracking solar cell system street lamp and a method of manufacturing the same, wherein each individual solar cell located in the upper portion is composed of six solar cells, and the individual solar cell located in the lower portion is composed of nine solar cells. The individual solar cells located in the upper part consist of three circular eight-sided photovoltaic modules composed of eight directions, and the six individual solar cells located in the lower part consist of eight directions each composed of lower circular-faced solar modules. And a flange located at the bottom included in the upper circular facet photovoltaic module and a flange located at the top included in the lower circular facet photovoltaic module and configured as a circular faceted photovoltaic module, and included in the circular faceted photovoltaic module. Is coupled to the flange and the angle frame located at the bottom, is coupled to the lower plate included in the angle frame and the body A circuit box is provided on the upper surface of the base plate, a battery enclosure including a thermal insulation foam inside the rim, and a thermal insulation styrofoam insulation is inserted therein, and the side plate and the fixing pipe are attached to the lower plate, and the top and the round of the fixed pipe are attached. It is attached to each side of the solar module is attached to the bottom of the flange located at the top, and the bolt is coupled to the side of the fixing pipe to tighten the bolt on the upper side of the street lamp to fix the circular face solar module, the top of the street lamp The luminaire is coupled to, and a check hole is formed at the bottom of the street lamp is configured to check the power generation status and abnormality.
In addition, the power generated in each of the eight individual photovoltaic modules included in the circular facet photovoltaic module is input to the energy harvesting circuit, each of the eight input power is collected as a single power in the harvesting circuit and sent to the controller, in the controller During the day, electric power is stored in the battery, and at night, the light of the luminaire is illuminated by the electric power stored in the battery.

Description

Diamond-shaped multi-directional fixed tracking methods solar cells system streetlight and the manufacturing method

The present invention relates to a diamond-shaped multi-directional fixed-tracking solar cell system street lamp and a method of manufacturing the same, and as a result of monitoring the generation of solar cells by computer for 365 days a year, in more detail, the conventional flat panel solar cell The present invention relates to a diamond-shaped multi-directional fixed-tracking solar cell system street lamp that provides power generation efficiency of up to about 40% higher than street lamps, and a method of manufacturing the same.

Recently, you can see a lot of solar street light with solar cells. The solar street light is to generate electricity by generating solar power, and does not require any electric work and has the advantage that it can be used semi-permanently without constant power supply.

However, a solar cell used in a conventional solar street light is a flat plate, and as described below with reference to FIG. 1B attached below, shadow shadows caused by tropospheric clouds are cast on the surface of the solar cell during or around the day of solar light. If shadow shading 602 is formed by trees, mountains, buildings, etc., the mining opportunity is lost and power generation is not performed or power generation efficiency drops sharply. When shadow shading 602 is formed for a long time, hot spot phenomenon occurs in the solar cell 601. It eventually causes solar cell failure.

In addition, since a fixed flat panel solar cell is generally used in one direction, it cannot be expected to generate power when clouds are generated in a time zone that can collect the most sunlight. In order to compensate for the shortcomings of such fixed solar cells, a solar tracking model in which solar cells are axially rotated to track the moving sun is also produced, but the solar tracking type is also a flat panel solar cell and a rotational joint is applied to rotate the solar tracking model. Due to the radius of the joint, a wide space, constant power consumption, and various failures occur in each mechanical part and tracking controller.

FIG. 1A is a perspective view of a solar street lamp to which a conventional fixed flat panel solar cell is applied, and FIG. 1B is an exemplary view of a shadow partially generated on the surface of the solar cell.

The present invention has been made to solve the above-mentioned problems of the prior art, even if shadow shading is formed on the whole or part of the solar cell by the cloud in the troposphere, maximize the power generation efficiency by scattering radiation and reflection solar radiation and the sun in any direction It aims to provide light generation efficiency, especially in cloudy rainy seasons or short winter seasons, providing a higher generation efficiency of more than about 40% in total for up to one year than flat type.

In order to achieve the above object, the present invention, the electric power generated by the circular circular facet photovoltaic module composed of the upper circular facet photovoltaic module formed of the solar cell of 24 sides and the lower circular facet photovoltaic module formed of the 48 facet to the energy harvesting circuit It is characterized by consisting of a structure that is charged and discharged through the charging unit to collect as a storage battery.

The present invention has an advantage of reducing the installation area, and also reducing the installation area limitation and having a high power generation efficiency of up to about 40% or more due to a long lighting condition structure, non-directional scattering radiation, and reflection solar radiation than a flat panel solar cell.

Hereinafter, with reference to the accompanying Figure 1c as follows.

Circular angular photovoltaic module 10 is configured in eight directions with a 360 ° around the flange 110 located on the top, it is possible to light even if sunlight shines in any direction. In other words, it is possible to mine during the daytime according to the movement of the sun without a tracking device from sunrise to sunset.

In addition, if the shadow shadow 602 by the outside is draped over the circular angular photovoltaic module 10, the corresponding individual photovoltaic modules of the eight will be reduced power generation becomes a low efficiency power generation 604, but the shadow shade 602 is cast The remaining individual photovoltaic modules are not capable of normal power generation (603).

Figure 1c is an illustration of the shadow partially generated on the surface of the circular solar module.

Figure 1a is a perspective view of a solar street lamp applying a conventional fixed flat panel solar cell.
Figure 1b is an illustration of the shadow partially generated on the surface of a conventional solar cell.
Figure 1c is an illustration of the shadow partially generated on the surface of the circular angular solar module.
Figure 2 is a diamond perspective multi-directional fixed tracking solar cell system street lamp full perspective view.
Figure 2a is a side cross-sectional view of a circular angular photovoltaic module.
Figure 2b is a planar cross-sectional view of a circular angular photovoltaic module.
Figure 3 is a cross-sectional perspective view of a circular angular solar module.
Figure 3a is a perspective view of the partial separation of the upper circular angular solar module.
Figure 3b is a perspective view of the lower circular angular solar module partially separated.
Figure 3c is a side cross-sectional view of an individual solar cell coupling.
Figure 3d is a cross-sectional plan view of an individual solar cell combined.
Figure 3e is an upper circular angular photovoltaic module junction box partial assembly configuration.
Figure 3f is a lower circular angular solar module junction box partial assembly configuration.
Figure 4a is a top-up junction box structure diagram.
Figure 4b is a top-bottom junction box structure diagram.
4c is a bottom-up junction box structure diagram.
Figure 4d is a bottom-bottom junction box structure diagram.
5 is a view of the flange and the body and the angle frame coupling.
6 is a battery enclosure structure diagram.
7 is a schematic diagram of a diamond-shaped multi-directional fixed-tracking solar cell system street lamp circuit.
Figure 8a is a simplified layout of the circular angular solar module.
8B is an individual solar module wiring diagram.
8c is an individual solar cell configuration diagram.

The present invention is a circular faceted surface including an upper circular angular photovoltaic module 100 composed of 24 upper solar panels 12 and a lower circular angular photovoltaic module 200 composed of 48 lower solar panels 13. Photovoltaic power generation by the photovoltaic module 10, the power is collected through the harvesting circuit 71 and stored in the storage battery by the control of the controller 72, and at night is a system for illuminating the light using the lamp 20.
Hereinafter, a diamond-type multi-directional fixed-tracking solar cell street light according to the present invention will be described in detail with reference to the accompanying drawings.
In the configuration of the present invention, as shown in Figure 2, the check hole 31 is formed at the bottom and the lamppost 30 is coupled to the luminaire 20 at the top, and the circular faceted solar module 10 at the top of the lamppost It is configured to be combined.
As shown in FIG. 3, the circular angular solar module 10 includes an upper circular angular solar module 100, a lower circular angular solar module 200, and a body 400, and an upper circular angular surface. The coupling hole 122 formed in the flange 120 coupled to the lower portion of the solar module 100 and the coupling hole 212 formed in the flange 210 coupled to the upper portion of the lower circular angular solar module 200 coincide with each other. The upper circular angular solar module 100 and the lower circular angular solar module 200 are coupled to the bolt 50 and the nut 51.
In addition, the battery box 60 is provided with a circuit box 70 is coupled to the front body 400.
The upper circular angular solar module 100 is configured as shown in Figure 3a, the removable groove 152 and the glass fixture 130, 140 and the flange that can be coupled to the solar panel in the longitudinal direction on each side, respectively Coupling grooves 153 capable of engaging the 110 and 121 are formed and are arranged at regular intervals in a circular shape and a plurality of upper frames 150 configured to be inclined at a predetermined angle toward the center side, and the arranged upper part A rectangular upper solar panel 12 is disposed between the frames 150 so that both ends thereof are coupled to the detachable groove 152, and are disposed at the upper end of the arranged upper frame 150 to provide a plurality of coupling holes 131. A plurality of glass fixtures 130 are formed to match the coupling groove 153 and are fixed downward so that the upper end of the upper solar panel 12 is not separated from the front. A plurality of coupling holes 11 in close contact with the upper end of the fixture 130 1) is formed to match the coupling hole 131, a plurality of air holes 112 are formed in the center and the glass fixture 130, the upper frame 150 and the upper solar panel 12 as a single object A flange 110 having a circular shape and having a circular shape is disposed at a lower end of the upper frame 150 and is formed to coincide with a plurality of coupling holes 141 and a coupling groove 154 and protrudes upward in the front. A plurality of glass fixing bodies 140 are formed to fix the lower ends of the upper solar panels 12 so that the lower ends of the upper solar panels 12 do not move forward, and the plurality of coupling holes 121 are in close contact with the lower ends of the glass fixing bodies 140. ) Is formed to coincide with the coupling hole 141 and a plurality of coupling holes 122 are formed at regular intervals inwardly so that the flange 120 has a circular shape, and the respective coupling holes 111 and 121 are formed. (131) 141 and the position of the coupling groove 152 is matched in the same line fastening means 170 (1) The glass fixtures 130 and 140 and the flanges 110 and 120 are coupled to the upper and lower ends of the upper frame 150 by 80.
As shown in Figure 3b, the lower circular angular photovoltaic module 200 has a detachable groove 252 and glass fixtures 230 and 240 and flanges capable of coupling the solar panels in the longitudinal direction on both sides thereof. Coupling grooves 253 capable of engaging the 210 and 221 are formed and are arranged at regular intervals in a circular shape and a plurality of lower frames 250 configured to be inclined at a predetermined angle toward the center side, and the arranged lower A rectangular lower solar panel 13 is disposed between the frames 250 so that both ends thereof are coupled to the detachable groove 252, and a plurality of coupling holes 231 are disposed at the top of the arranged lower frame 250. A plurality of glass fixtures 230 are formed to coincide with the coupling grooves 253 and fixed downwards in front of the lower solar panel 13 so that the upper ends of the lower solar panels 13 are not separated from the front. A plurality of coupling holes 21 in close contact with the upper end of the fixture 230 1) is formed to coincide with the coupling hole 231 and serves to bind the glass fixture 230, the lower frame 250 and the lower solar panel 13 into a single object and a plurality of at regular intervals inwardly. Coupling hole 212 is formed to form a flange 210 having a circular shape and the lower frame 250, the plurality of coupling holes 241 and the coupling groove 254 is formed to match the front A plurality of glass holders 240 are formed upwardly to fix the lower end of the lower solar panel 13 so that the lower end of the solar panel 13 is not separated from the front, and the plurality of glass holders 240 are in close contact with each other. The hole 221 is formed to coincide with the coupling hole 241 and the plurality of protrusions 222 having the coupling hole 223 formed on the outer circumference thereof are formed vertically to form the lower circular angular solar module 200 with the body and the angle. It can be attached to the frame and has a circular shape The flange 220 and the positions of the respective coupling holes 211, 221, 231, 241 and the coupling groove 252 coincide in the same line, so that the lower frame ( The glass fixtures 230 and 240 and the flanges 210 and 220 are coupled to the top and bottom of the 250.
3C to 3D, the silicon packing 290 is provided at the corners of the upper solar panel 12 and the lower solar panel 13 coupled between the upper frame 150 and the lower frame 250. It acts as a buffer so that the solar panel is not damaged by wind pressure or vibration.
Looking at the bar shown in Figures 3e to 4d,
The junction box 310 coupled to the upper circular angular photovoltaic module 100 has a coupling hole 314 formed at four sides and a coupling hole 315 formed at the center of the side, and can be coupled to the upper frame 150 at the rear. Detachable groove 352 is formed to the rear of the upper circular angular photovoltaic module 100 coupled to the junction box 310 to the coupling hole 154 formed in the upper frame 150 to the upper portion of the upper frame 150 The hole 314 is coupled by the fastening means 312, the protrusion 354 is formed on the top to prevent the flow into the junction box 310, the box cover 311 is coupled to the junction box 310 A plurality of coupling holes 316 are formed, and protrusions 353 are formed at both ends thereof to seal the inside and are coupled to the junction box 310 by the fastening means 313.
In addition, the junction box 320 has a coupling hole 324 formed at the center of the side end and a coupling hole 325 formed at four corners, and a detachable groove 362 that can be coupled to the upper frame 150 to the rear is formed in an upper circular shape. Coupling means 322 of the coupling hole 324 of the junction box 320 in the coupling hole 154 formed in the upper frame 150 to the rear of the solar module 100 in the lower portion of the upper frame 150 Is coupled by, the protrusion 364 is formed on the top to prevent the inflow into the junction box 320, the box cover 321 coupled to the junction box 320 is formed with a plurality of coupling holes 326 Protruding portions 363 are formed at both ends to seal the inside and are coupled to the junction box 320 by the fastening means 323.
In addition, the junction box 330 coupled to the lower circular angular solar module 200 has a coupling hole 334 and four corners at the center of the side end, and a coupling hole 335 is formed to be coupled to the lower frame 250 to the rear. Removable groove 372 is formed is located in the upper portion of the lower frame 250 to the rear of the lower circular angular solar module 200 in the junction box 330 in the coupling hole 254 formed in the lower frame 250 The coupling hole 334 is coupled by the fastening means 332, the protrusion 374 is formed on the upper to prevent the inflow into the junction box 330, the box cover coupled to the junction box 330 ( 331 is formed with a plurality of coupling holes 336 and the protrusions 373 are formed at both ends to seal the inside and is coupled to the junction box 330 by the fastening means 333.
In addition, the junction box 340 has a coupling hole 344 and four corners at the center of the coupling hole 345 is formed in the bottom and the removable groove 382 that can be coupled to the lower frame 250 is formed in the lower circular The coupling hole 344 of the junction box 340 is fastened to the coupling hole 254 formed in the lower frame 250 at the lower portion of the lower frame 250 to the rear of each solar module 200. Is coupled by, the protrusion 384 is formed on the top to prevent the inflow into the junction box 340, the box cover 341 is coupled to the junction box 340 is formed with a plurality of coupling holes 346 Protruding portions 383 are formed at both ends to seal the inside, and are coupled to the junction box 340 by fastening means 343.
Looking at the bar shown in Figure 5, the body 400 is formed with a plurality of holes 406 in the upper and lower, the fixing pipe 401 is coupled to the fixing means 404 in the hole 406 is configured vertically The bottom plate 403 having a fan shape having a plurality of holes 406 formed on the lower portion of the fixed pipe 401 is welded to both sides of the fixed pipe 401, and the lower plate 403 of the lower plate 403. An angle frame 500 in which a triangular side plate 402 is vertically attached to the side and a side of the fixed pipe 401 by welding, and a plurality of holes 501 are formed on the upper surface and the side circumference under the lower plate 403. It is configured to be coupled by the fastening means 505, the fixing means 404 coupled to the fixing pipe 401 is configured to be fixed to the circular polygonal solar module 10 when coupled to the top of the street lamp (30).
Looking at the bar shown in Figure 6, the lower styrofoam insulation 65 is formed with a battery storage space 66 for storing one or two or more storage batteries, the storage battery 75 is accommodated, and other equipment in addition to the storage battery can be stored separately. Receiving space 67 is formed. The lower battery enclosure 62 may accommodate the lower styrofoam insulating material 65, and the insulating urethane foam 63 is filled therein to serve to keep warm and insulate. In addition, the upper styrofoam insulating material (64) having the same configuration as the lower styrofoam insulating material (65) above the lower styrofoam insulating material (65) is configured to be symmetrically coupled to the lower styrofoam insulating material (65), the battery lower enclosure (62) An upper battery enclosure 61 having the same configuration as that of the battery lower enclosure 62 is combined. A plurality of lock devices 68 are coupled to the outer surfaces of the combined battery upper outer box 61 and the battery lower outer box 62 so as to prevent the upper and lower parts from being opened.
Looking at the bar shown in Figures 7 to 8c, a plurality of solar cells 42 are arranged at regular intervals connected to the ribbon line 44, the EVA sheet 41 and the upper low iron tempered glass 160 or forward The lower low iron tempered glass 260 is configured, and the EVA sheet 41 and the back sheet 43 are configured at the rear, and the upper solar panel 12 and the lower solar panel 13 are formed by vacuum compression.
The individual photovoltaic module 11 is composed of a desired power generation voltage and a current generation by connecting a predetermined upper solar panel 12 and a lower solar panel 13 to a power line 45. ) And a plurality of generated power is transmitted to the harvesting circuit 71, and each of the transmitted power is collected in the harvesting circuit 71 to be stored in the storage battery 75 under the control of the controller 72 or the luminaire 20 It is used as the output to illuminate the light.

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

10: circular angular solar module 11: individual solar module
12: upper solar panel 13: lower solar panel
20: lamp 30: street lamp 31: check hole
41: EVA sheet 42: Cell 43: back sheet 44: ribbon line
45 power line
50: bolt 51: nut
60: battery enclosure 61: battery upper enclosure 62: battery lower enclosure
63: insulation urethane foam 64: upper styrofoam insulation
65: lower styrofoam insulation 66: battery storage space 67: storage space
68: lock device
70: circuit box 71: harvesting circuit 72: controller 75: storage battery
90: street light basis 91: the sun
100: upper circular angular solar module 200: lower circular angular solar module
110, 120: flange 111, 121, 131, 141: coupling hole 112: air hole
122, 212: coupling hole
130, 140: glass fixture
132, 142: protrusion
150: upper frame 152: removable groove 153: coupling groove 154: coupling hole
160: upper low iron tempered glass
170, 180: fastening means
210, 220: flange
211, 221, 231, 241: coupling holes
222, 232, 242: protrusion
223: coupling hole
230, 240: glass fixture
250: lower frame 252: removable grooves 253, 254: coupling holes
260: lower low iron tempered glass
270, 280: fastening means
290: Silicone Packing
310, 320, 330, 340: junction box 311, 321, 331, 341: box cover
312, 322, 332, 342: fastening means 313, 323, 333, 343: fastening means
314, 316, 324, 326: coupling holes 334, 336, 344, 346: coupling holes
315, 325, 335, 345: coupling hole
350, 360, 370, 380: Ribbon line entrance 352, 362, 372, 382: Detachable groove
353, 363, 373, 383: protrusions 354, 364, 374, 384: protrusions
355, 365, 375, 385: terminal block
400: body 401: fixed pipe 402: side plate 403: bottom plate 404: fixing means
406, 407: hall
500: angle frame 501,502: holes 503, 505: fastening means
600: flat panel solar module 601: solar cell 602: shadow
603: normal power display 604: low efficiency power display

Claims (14)

A plurality of solar cells 42 arranged in a row with a trapezoidal upper low iron tempered glass 160 having a transparent color and an EVA sheet 41 and a back sheet 43 and ribbon lines connected to the solar cells 42 ( A plurality of upper frames in which the upper solar panel 12 including a 44, and the removable groove 152 and the coupling groove 153 in the longitudinal direction are formed on both sides and are disposed at regular intervals in a circular shape and inclined at a predetermined angle. 150 and the upper solar panel 12 is disposed between the arranged upper frames 150 so that both ends are coupled to the detachable groove 152, and are disposed on an upper end of the arranged upper frame 150. The plurality of coupling holes 131 are formed to coincide with the coupling groove 153 and the plurality of glass fixing body 130 is formed in the front downward projection 132, and on the upper end of the glass fixing body 130 In close contact with each other, a plurality of coupling holes 111 are formed to coincide with the coupling holes 131. The air hole 112 is formed in the flange 110 having a circular shape, and is disposed at the lower end of the upper frame 150 is formed to match the plurality of coupling holes 141 and the coupling groove 154 and the front A plurality of glass fixing body 140, the protrusion 142 is formed upward in contact with the lower end of the glass fixing body 140 is formed so that the plurality of coupling holes 121 coincide with the coupling hole 141. And a plurality of coupling holes 122 are formed at regular intervals inwardly to form a flange 120 having a circular shape, and each of the coupling holes 111, 121, 131, 141 and the coupling groove 152. The upper circular shape consisting of the glass fixture 130, 140 and the flange 110, 120 is coupled to the upper and lower ends of the upper frame 150 by the fastening means 170, 180 is matched Each solar module module 100;
Located at the rear of the upper circular angular photovoltaic module 100 and in the middle of the ribbon line inlet 350, 360 and the terminal block 355, 365 and the protrusions 354, 364 formed on the middle and both sides A plurality of junction boxes 310 and 320 including formed coupling holes 314 and 324 and a plurality of coupling holes 315 and 325 formed at four corners, and the plurality of junction boxes 310 and 320. ) Is attached to each of the junction boxes 310, 320 between the removable grooves 352, 362 is formed, the removable grooves 352, 362 are attached to the upper and lower portions of the upper frame 150 and A plurality of coupling holes 154 are formed in the upper and lower portions of the rear surface of the frame 150, and the coupling holes 314 and 324 coincide with each coupling hole 154 so as to be junctioned by the fastening means 312 and 322. Boxes 310 and 320 are fixed to the upper frame 150, and the fixed junction boxes 310 and 320 are formed with protrusions 353 and 363 at both ends, and a plurality of coupling holes 316 ( 326 formed box cover 311 321 is coupled to the coupling holes 315 and 325 formed in the junction boxes 310 and 320 by the fastening means 313 and 323;
Located at the bottom of the upper circular angular solar module 100, a plurality of solar cells arranged in a line with the trapezoidal lower low iron tempered glass 260 and the EVA sheet 41 and the back sheet 43 having a transparent color A lower solar panel 13 including a 42 and a ribbon line 44 connected to the solar cell 42, and a detachable groove 252 and a coupling groove 253 are formed in both sides in a longitudinal direction, and thus are formed in a circular shape. A plurality of lower frames 250 disposed at intervals and inclined at a predetermined angle, and the lower solar panel 13 is disposed between the disposed lower frames 250 so that both ends thereof are detachable from the groove 252. Coupled, a plurality of glass fixtures are arranged on the top of the arranged lower frame 250 is formed so that the plurality of coupling holes 231 and the coupling groove 253 and the projection 232 is formed downward in front 230 is in close contact with the upper end of the glass fixture 230, a plurality of coupling holes 211 A plurality of coupling holes 212 are formed to coincide with the coupling holes 231 and are formed at a predetermined interval inwardly so that the flange 210 has a circular shape and is disposed at a lower end of the lower frame 250. Coupling hole 241 and the coupling groove 254 is formed to match the plurality of glass fixing body 240 and the protrusion 242 is formed upward in front of the glass fixing body 240 is in close contact with the plurality of Flange 120 having a circular shape by forming two coupling holes 221 to be aligned with the coupling holes 241 and having a plurality of protrusions 222 having a coupling hole 223 formed on the outer circumference thereof; The positions of the respective coupling holes 211, 221, 231, 241 and the coupling grooves 252 are matched to each other so that the upper and lower surfaces of the lower frame 250 are fastened by the fastening means 270 and 280. A lower circular angular solar module 200 configured to be coupled to the stagnation 230 and 240 and the flanges 210 and 220;
Located at the rear of the lower circular angular solar module 200 and in the middle of the ribbon line inlet 370, 380 and the terminal block 375 (385) formed in the middle and the protrusions 374 (384) formed in the upper and both sides A plurality of junction boxes 330 and 340 including coupling holes 334 and 344 formed in the four corners and a plurality of coupling holes 335 and 345 formed in the four corners, and the plurality of junction boxes 330 and 340. ) Is attached to each of the junction boxes 330, 340 between the removable grooves 372, 382 is formed and the removable grooves 372, 382 are attached to the upper and lower portions of the lower frame 250 and A plurality of coupling holes 254 are formed in the upper and lower portions of the rear surface of the frame 250, and the coupling holes 334 and 344 coincide with each of the coupling holes 254 to be junctioned by the fastening means 332 and 342. The boxes 330 and 340 are fixed to the lower frame 250, and the fixed junction boxes 330 and 340 are provided with protrusions 373 and 383 at both ends, and a plurality of coupling holes 336 ( 346 formed box cover (331) ) 341 is coupled to the coupling holes 335 and 345 formed in the junction boxes 330 and 340 by the fastening means 333 and 343;
The upper circular angular photovoltaic module 100 and the lower circular angular photovoltaic module 200 are respectively coupled to the coupling holes 122 and 212 formed by the bolts 50 and the nuts 51.
A plurality of holes 406 are formed in upper and lower portions in the inner center of the combined upper circular angular solar module 100 and lower circular angular solar module 200 and fixing means 404 in the hole 406. The combined fixed pipe 401 is located vertically in the center, and the bottom plate 403 of the fan shape having a plurality of holes 407 formed on the outer side at the bottom of both sides of the fixed pipe 401 is attached by welding. A body 400 including a plurality of side plates 402 attached by welding to both ends of the lower plate 403 and to the side surfaces of the fixed pipe 401;
A circular angle frame 500 having a plurality of holes 501 and 502 formed on upper and side surfaces thereof is formed at a lower portion of the body 400 in holes 407 and angle frames 500 formed in the lower plate 403. The holes 502 coincide and are joined by the fastening means 505;
The flange 220 coupled to the lower circular angular solar module 200 is in close contact with the top of the lower plate 403 and the angle frame 500 and the coupling hole 223 and the angle frame 500 formed in the flange 220. Holes 501 formed in the match are coupled by the fastening means 503,
An upper surface of the lower plate 403 of the body 400 may house a lower styrofoam insulating material 65 having a plurality of battery storage spaces 66 and a receiving space 67 and the lower styrofoam insulating material 65. An upper styrofoam insulating material having a symmetrical form in which the lower battery foam enclosure 62 and the lower styrofoam insulating material 65 and the lower battery enclosure 62 are filled above the battery lower enclosure 62. 64 and the upper battery case 61 is coupled to the lower styrofoam insulating material 65 and the lower battery case 62, one or two or more batteries 75 are stored in the battery storage space 66, the storage battery A battery enclosure 60 including a plurality of lock devices 68 coupled to an outer side of the upper enclosure 61 and the lower battery enclosure 62;
A circular faceted solar module 10 including a circuit box 70 in which a harvesting circuit 71 and a controller 72 are mounted on an outer surface of the battery box 60;
An inspection hole 31 is formed at a lower portion of the fixed pipe 401 included in the circular-angle solar module 10, and an upper end of the street lamp column 30 to which the luminaire 20 is coupled is inserted and coupled to the upper portion.
Diamond-shaped multi-directional fixed-tracking solar cell system street light comprising the fixing of the circular angular solar module 10 by the fixing means (404) to the combined street lamp column (30).
The method of claim 1,
Diamond-shaped multi-directional fixed-tracking solar cell system street lamp further comprises a silicon packing (290) is wrapped around the slopes of the plurality of upper and lower solar panels (12).
The method of claim 1,
The circuit configuration is connected to the harvesting circuit 71 by grouping a predetermined upper solar panel 12 and the lower solar panel 13, the harvesting circuit 71 and the controller 72 is connected, the controller 72 And a storage battery (75) are connected, and the diamond-shaped multi-directional fixed-tracking solar cell system street light, characterized in that output from the controller (72) and the storage battery (75).
delete delete delete delete delete delete delete delete delete delete delete

Images