KR200389289Y1 - Streetlight lighting producing system for using solar cell and GPS - Google Patents

Abstract

The present invention relates to a lighting production system of a street lamp using a solar cell and a GPS, and in particular, a street lamp having a pedestal at a bottom, a rotating shaft protruding from an upper end thereof, and a street lamp pole having a space in which a storage battery is stored therein. Wow; Rotating pontoon formed so that it can be rotated 360 degrees in the rotation axis of the street lamp pontoon; A screen panel formed in a polygonal or disc shape, and having a light collecting plate and a GPS antenna for charging the battery on an upper surface thereof, a reflecting surface formed on a bottom surface thereof, and fixed to be inclined by a support from a side of the rotating iron rod; A lighting directing device formed in a square or a cylindrical shape having both ends opened to radiate light to the screen panel and a distance through a plurality of super-brightness LEDs so as to rotate left and right by a bracket at an upper end of the street lamp pole; And a control module provided inside the lighting device to control charging and output of the storage battery and controlling the lighting device.

According to the present invention as described above, it synchronizes with its own timer time using GPS standard time information of GPS, and is a color (red, green, blue, White) Simultaneous display is possible, and lighting is produced by time control group unit (for example, group of A group, B group, C group D group by 5-100 units sequentially lighting and blinking) Light intensity can be controlled by strong and weak light, and can also be used semi-permanently by adopting high power LED and using light as a power source using solar power which is infinite power.

Description

Street lighting lighting system using solar cell and GPS

The present invention relates to a lighting directing system of a street lamp using a solar cell and a GPS, and more specifically, by using standard time information received from a GPS satellite, the lighting is produced by lighting, blinking and intensity of light by color at sunset. The present invention relates to a lighting production system of a street lamp using a solar cell and a GPS.

Generally, AC 220V, which is a commercial power source, is used when using other conventional lighting, and is lit and blinked by a timer device of a controller at sunrise and sunset.

As a result, when installing a large number of lights, a lot of extra electric work, construction schedule, and construction costs are required, and there may be an electric leakage phenomenon, and the light bulb capacity is high, so the electricity consumption is high.

Therefore, in controlling and installing a large number of existing lamps, the light bulb capacity used for the lamps is still generally used as 50W or more, which causes a shortening of the lifespan and extra maintenance costs by the light bulbs.

In addition, the street lamp or the landscape lighting lamp has been proposed to perform the operation of turning on and off using a separate timer, but due to the characteristics of the lamp, it is difficult to accurately match the lighting and flashing time in units of 1/100 second, and the lighting of each lamp Due to the impossibility of synchronizing time, it is difficult to control many lights and the intensity and weakness of light. When color is produced, color filter is attached to the front of the bulb, so the change is made by motor control.

Accordingly, the lamps and the like have a problem that the installation cost is increased due to the redundant installation, the electrical leakage accident and the separate maintenance and repair is different.

In order to solve this problem, Utility Model Registration No. 20-0297845 (LED street light using solar energy) was developed.

LED street light using the solar energy as shown in Figure 1 is installed on the top of the street lamp pole (2), the solar cell (6) as a heat collecting plate, and directly below the advertising panel 7 is installed, the advertising panel ( 7) Fixing bracket 8 is installed on the upper surface, and a plurality of support bars 9, 9a, 9b are connected to the fixing bracket 8, and ends of the support bars 9, 9a, 9b. An illumination lamp 10, 10a, 10b having an LED as a light source is installed in the lamp, and the lamp lamp 5 of the street lamp 1 also includes a plurality of LEDs (about 8-12).

However, such a conventional LED street light using solar energy simply turns on the lamp and lighting lamp using solar energy, so it is impossible to produce lighting according to the sum of hue, and the lighting and blinking cycles are simply controlled at the time of its own timer. There is a problem that can not be correctly lit, flashing according to the sunrise, sunset time that varies by date.

The present invention is to solve the above problems, using the satellite standard time information of the GPS to synchronize with its own timer time, by the Meteorological Agency sunrise, sunset time program, a number of ultra-high brightness LED lights at sunrise, sunset ( Simultaneous red, green, blue, and white production is possible, and lighting is sequentially turned on and off for each time control group unit (for example, 5 to 100 units in A group, B group, and C group D group unit). Its purpose is to provide a lighting production system of street lamps using solar cells and GPS that can produce visual time lighting and control light intensity with strong and weak light.

It is also an object of the present invention to provide a lighting production system of a street lamp using a solar cell and a GPS that can be used as a power source by using a solar cell that is infinitely power, and can be used semi-permanently by adopting an ultra-bright LED.

Features of the present invention for achieving the above object,

In the street light,

A street lamp pole having a pedestal at a bottom thereof, a rotating shaft protruding from an upper end thereof, and having a space for accommodating a battery therein; Rotating pontoon formed so that it can be rotated 360 degrees in the rotation axis of the street lamp pontoon; A screen panel formed in a polygonal or disc shape, and having a light collecting plate and a GPS antenna for charging the battery on an upper surface thereof, a reflecting surface formed on a bottom surface thereof, and fixed to be inclined by a support from a side of the rotating iron rod; A lighting directing device formed in a square or a cylindrical shape having both ends opened to radiate light to the screen panel and a distance through a plurality of super-brightness LEDs so as to rotate left and right by a bracket at an upper end of the street lamp pole; And a control module provided inside the lighting device to control charging and output of the storage battery and controlling the lighting device.

Here, the lighting display device is formed in a rectangular or cylindrical with both ends open, the fixing hole is fixed to the bracket is formed at both ends of the central portion, the control module is provided therein; A plurality of red, green, and blue ultra-high brightness LEDs mounted thereon, and an advertisement lighting panel provided inside the upper end of the body; And a plurality of white ultra high brightness LEDs mounted thereon, the street lighting panel provided inside the lower end of the body.

Here, the red, green, and blue super high brightness LED of the advertising lighting panel is the red, green, blue super high brightness LED is electrically connected to a group, so that each of the lights overlap to produce the desired light color. The red, green, and blue ultra high-brightness LEDs are sequentially formed to be adjacent to each other and mounted in a grid arrangement, a date arrangement, and a triangular arrangement.

The control module may further include a charging module configured to charge the voltage output from the light collecting plate to the storage battery and to output the voltage charged to the storage battery; An overcharge protection circuit installed on a line of the light collecting plate and the storage battery to block a voltage charged from the light collecting plate to the storage battery under external control, and to prevent the charging voltage charged in the storage battery from flowing back to the light collecting plate; An over-discharge protection circuit installed on a line of the charging module and the lighting directing device to detect an overload of the lighting directing device; A GPS module for receiving a GPS signal received from the GPS antenna and outputting standard time information; A user setting circuit for allowing a user to set a flashing cycle and a light intensity of the red, green, and blue ultra high brightness LEDs; Synchronize the system by using the standard time information output from the GPS module, red, green of the lighting device according to the preset or user setting at sunset according to the weather station sunrise, sunset time program and color rendering program stored inside Outputs a control signal for controlling the blinking of the blue and white ultra-high brightness LEDs, and operates the overcharge protection circuit when the overcharge detection signal is output from the charging module to block charging of the battery, and to overload the over discharge protection circuit. A microcomputer to block the output of the control signal when is detected; A pulse width modulation circuit for controlling light intensity by converting each control signal output from the microcomputer to the red, green, blue, and white ultra high brightness LEDs of the lighting apparatus into a PWM signal; An amplifier circuit for amplifying the PWM signal output from the pulse width modulation circuit; And a switching circuit switched according to a PWM signal output from the amplifying circuit to control a voltage supplied from the storage battery to the red, green, blue, and white super high brightness LEDs.

The charging module may include: a comparator measuring the intensity of the charging voltage by comparing the level of the charging voltage of the battery with a reference voltage; An overcharge indicator configured to display whether overcharged during overcharge according to the intensity of the voltage output from the comparator; And a constant voltage output unit configured to output the charging voltage of the storage battery to a constant constant voltage.

The GPS module may further include: a power supply circuit which receives a constant voltage output from the constant voltage output unit and supplies power to each component; A first amplifier for amplifying a GPS signal received from the GPS antenna; A central processing unit for extracting and outputting standard time information from the GPS signals received through the first amplifier; And a second amplifier for amplifying the standard time information extracted from the central processing unit.

Here, the user setting circuit includes a plurality of dip switches and a test switch, and adjusts the lighting time and the light intensity of each of the red, green, blue, and white super high brightness LEDs according to the operation of the dip switch. Then, all the red, green, blue, white ultra-high brightness LED is turned on according to the operation of the test switch.

Here, the pulse width modulation circuit receives a control signal output from the microcomputer to vary the width of the PWM signal to sequentially control the brightness when the red, green, blue, white ultra-high brightness LED is lit, An auxiliary microcomputer for outputting a retransmission request signal when an abnormality of the control signal outputted from the auxiliary microcomputer; A plurality of PWM modules for generating a PWM signal in accordance with a control signal output from the microcomputer; And a communication port for outputting a retransmission request signal output from the auxiliary microcomputer to the microcomputer.

Here, the switching circuit is a collector connected to the output terminal of the constant voltage output, the base is connected to the output terminal of the PWM module, the emitter is connected to the red, green, blue ultra-bright LED side and output from the PWM module The switching speed is controlled by the PWM signal is a switching transistor for controlling the brightness of the red, green, blue ultra-bright LED.

Hereinafter, with reference to the accompanying drawings, the configuration of the lighting directing system of a street lamp using a solar cell and GPS according to the present invention will be described in detail.

Figure 2 is a block diagram showing the configuration of the lighting production system of the solar cell and the GPS street lamp according to the present invention, Figure 3 is a perspective view showing the configuration of the lighting production system of the street lamp using the solar cell and GPS according to the present invention 4 is a side cross-sectional view of FIG. 3, and FIGS. 5A to 5C are plan views illustrating the configuration of an advertisement lighting panel of a lighting directing system using a solar cell and a GPS according to the present invention.

2 to 5c, the lighting directing system 100 of the street lamp using the solar cell and the GPS according to the present invention includes a street lamp pontoon 110, a rotating pontoon 120, a screen panel 130, It is composed of a lighting rendering device 140, and a control module 200.

First, the street lamp pole 110 is formed in a circular, polygonal shape, has a pedestal 111 at the bottom, a circular rotating shaft 113 protrudes formed on the top, the space portion in which the storage battery 150 is stored 115 is provided.

In addition, the rotating pontoon 120 is formed to be rotatable 360 degrees on the rotating shaft 113 of the street lamp pontoon 110.

In addition, the screen panel 130 is formed in a polygonal or disc shape, and a light collecting plate 160 and a GPS antenna 170 for charging the storage battery 150 are attached to an upper surface thereof, and a reflective surface 131 is formed on a lower surface thereof, and rotates. It is fixed to be inclined by the support 133 on the side of the pontoon (120). Here, the reflective surface 131 is provided so that the advertisement is visually exposed.

In addition, the lighting directing device 140 is formed in a square or cylindrical with both ends opened to the screen panel 130 and the distance to the light through a plurality of super-brightness LED bracket 117 at the top of the street lamp pole 110 It is installed to be able to rotate left and right by.

Here, the lighting directing device 140 is formed in a square or cylindrical with both ends open, the fixing hole 142 is fixed to the bracket 117 is formed at both ends of the central portion, the control module 200 is provided therein The body 141, a plurality of red, green, and blue ultra high brightness LEDs 144 are mounted, an advertisement lighting panel 143 provided inside the upper end of the body 141, and a plurality of white super high brightness LEDs 146. Is mounted, and consists of a street lighting panel 145 is provided inside the lower end of the body 141.

Here, the red, green, and blue super high brightness LEDs 144 of the advertising lighting panel 143 are red, green, and blue super high brightness LEDs 144 are electrically connected to one group, and each light is overlapped. In order to produce a desired color of light, the red, green, and blue super high-brightness LEDs 144 are sequentially formed to be adjacent to each other and mounted in a grid arrangement, a date arrangement, and a triangular arrangement as shown in FIGS. 5A to 5C.

Here, the red, green, blue, and white super high brightness LEDs 144 and 146 may be electrically connected in series, parallel, and parallel / parallel mixing, and each of the red, green, blue and white super high brightness LEDs may be used. 144 and 146 may be turned on and blink independently.

The control module 200 includes a charging module 210, an overcharge protection circuit 220, an overdischarge protection circuit 230, a GPS module 240, a user setting circuit 250, and a microcomputer ( 260, a pulse width modulation circuit 270, an amplifier circuit 280, and a switching circuit 290.

The charging module 210 compares the level of the charging voltage of the battery 201 with a reference voltage to measure the intensity of the charging voltage and the overcharge according to the intensity of the voltage output from the comparator 211. An overcharge indicator 212 for displaying whether or not overcharge, and a constant voltage output unit 213 for outputting the charging voltage of the storage battery 150 to a constant constant voltage.

The overcharge protection circuit 220 is installed on the line between the light collecting plate and the storage battery and is switched according to a switching signal outputted by detecting the overcharge from the microcomputer 260 through the comparator 211 to block the charging of the storage battery. The charging voltage charged in the 150 is blocked from flowing back to the light collecting plate 160.

The over-discharge protection circuit 230 is installed on the line of the constant voltage output unit 213 of the charging module 210 and the lighting directing device 140 to detect the overload of the lighting directing device 140 to overdischarge the storage battery 150. To block. Here, the over-discharge protection circuit 230 may be implemented using a sensing resistor or the like.

The GPS module 240 may receive a constant voltage output from the constant voltage output unit 213 and supply power to each component, and a first amplifier for amplifying the GPS signal received from the GPS antenna 170. 242, a central processing unit 243 for extracting and outputting standard time information from GPS signals received through the first amplifier 242, and a second amplifier for amplifying standard time information extracted from the central processing unit 243. And 244.

The user setting circuit 250 includes a plurality of dip switches 251 and a test switch 252, and according to the operation of the dip switch 251, the red, green, blue, and white ultra high-brightness LEDs 144 and 146 are provided. The sequential blinking time and the light intensity are adjusted, and all of the red, green, blue, and white super high brightness LEDs 144 and 146 are turned on according to the operation of the test switch 252.

The microcomputer 260 controls the system as a whole, and in particular, synchronizes the system using standard time information output from the GPS module 240, and at sunset according to the weather station sunrise, sunset time program and color rendering program stored therein. Outputs a control signal for controlling the lighting of the red, green, blue, and white ultra high brightness LEDs 144 and 146 of the lighting directing device according to a preset setting or a user's setting, and outputs an overcharge detection signal from the overcharge protection circuit 220. When the overcharge protection circuit 220 is operated to block the charging of the battery 150, and when an overload is detected from the overdischarge protection circuit 230, the output of the control signal is blocked.

The pulse width modulation circuit 270 receives a control signal output from the microcomputer 260 to sequentially control brightness when the red, green, blue, and white super high brightness LEDs 144 and 146 are turned on. And a plurality of generating PWM signals in accordance with the control signal output from the auxiliary microcomputer 271 and the auxiliary microcomputer 271 for outputting a retransmission request signal when the control signal output from the microcomputer 260 is abnormal. The PWM module 272 and a communication port 273 for outputting the retransmission request signal output from the auxiliary microcomputer 271 to the microcomputer 260.

The amplifier circuit 280 amplifies the PWM signal output from the pulse width modulation circuit 270.

The switching circuit 290 has a collector connected to the output terminal of the constant voltage output unit 213, a base connected to the output terminal of the PWM module 272, and an emitter connected to the red, green, and blue ultra-bright LEDs 144. The switching speed is controlled by the PWM signal output from the module 272 to control the brightness of the red, green, and blue super high brightness LEDs 144.

Hereinafter, the operation of the lighting directing system of a street lamp using a solar cell and a GPS according to the present invention will be described in detail with reference to FIGS. 2 to 5C.

First, referring to the operation of the charging module 210, by rotating the rotating pontoon 120 in the rotating shaft 113 of the street lamp pole 110 in the state where the street lamp is installed, the light collecting plate 160 of the screen panel 130 is optimally sun Fix the light to a location where it can focus.

In this state, when the solar light is collected from the light collecting plate 160, the DC power, which is a charging voltage, is generated in the light collecting plate 160, which is charged by the storage battery 150.

In this case, when the level of the charging voltage of the storage battery 150 is compared with the reference voltage by the comparator 211, the intensity of the charging voltage is measured and output, and the overcharge indicator 212 displays the overcharge during overcharging, and the comparator 211 When the microcomputer 260 receives the measured value at the input voltage and the charging voltage exceeds a predetermined level, the overcharge protection circuit 220 is operated to cut off the charging voltage supplied from the light collecting plate 160 to the storage battery 150.

On the other hand, when overload is detected in the advertisement lighting panel 143 and the street lighting panel 145 which are the load sides in the over-discharge protection circuit 220, the microcomputer 260 stops output of the control signal and the advertisement lighting panel 143 and the distance. The operation of the lighting panel 145 is stopped to prevent the battery 150 from being over discharged. Thus, it is possible to prevent the overcharging and overdischarging of the storage battery 150 to shorten the life of the storage battery 150.

In addition, the light collecting plate 160 generates a charging voltage during the day to store the voltage in the storage battery 150, but at the night, the light collecting plate 160 also acts as a load, so that the light collecting plate 160 passes through the overcharge protection circuit 220. To prevent the charging voltage from flowing back.

When the charging voltage is charged in the storage battery 150 as described above, it is applied to each component through the constant voltage output unit 213 of the charging module 210.

Thus, the power supply circuit 241 of the GPS module 240 transmits the voltage output from the constant voltage output unit 213 of the charging module 210 from the storage battery 150 to each component of the GPS module 240.

Then, when the GPS signal is received from the GPS satellites in the GPS antenna 170, the first amplifier 242 amplifies it and outputs it to the central processing unit 243, the central processing unit 243 is received and the standard time of the GPS signal After extracting the information, the information is amplified by the second amplifier 244 and output to the microcomputer 260.

After receiving the standard time information from the central processing unit 243 of the GPS module 240, the microcomputer 260 synchronizes the timer with the standard time information by using an internal program, and then directs the lighting according to the sunrise and sunset time programs of the Meteorological Agency. It outputs a control signal that turns on the red, green, blue, and white ultra high brightness LEDs 144 and 146 of the device 140. At this time, the microcomputer 260 is a control signal according to the lighting time and the light intensity or a predetermined value of the red, green, blue, and white ultra-high brightness LEDs 144 and 146 set by the user through the user setting circuit 250. Outputs On the other hand, the user can control the individual lighting time of the red, green, blue, white ultra-high brightness LEDs (144, 146) through the user setting circuit 250, the lighting time can be controlled for each group unit, the lighting speed Control of light intensity, etc. is also possible.

On the other hand, when the control signal is output from the microcomputer 260, the auxiliary microcomputer 271 of the pulse width modulation circuit 270 controls the PWM module 272 to generate a PWM signal according to the control signal. At this time, the pulse width modulation circuit 270 generates a PWM signal to minimize heat generated initially when the red, green, blue, and white super high brightness LEDs 144 and 146 are turned on, and to stabilize the brightness of the light. In the beginning, the width of the signal is made wider, and after that, the width of the signal is made narrower. In addition, the auxiliary microcomputer 271 controls the brightness of the red, green, and blue super high-brightness LEDs 144 by varying the PWM signal when the color is displayed according to the control signal of the microcomputer 260, thereby freely producing the lighting color. To be done.

When the PWM signal is output from the PWM module 272 of the pulse width modulation circuit 270, the PWM signal is amplified through the amplifier circuit 280 and input to the switching transistors Q1 to Q4. Switched by the PWM signal to supply / cut off the constant voltage output from the constant voltage output unit 213 of the charging module (210).

Then, the red, green, and blue ultra-bright LEDs 144 connected to the switching transistors Q1 to Q4 are turned on by the constant voltage applied from the constant voltage output unit 213, depending on the switching speed of the switching transistors Q1 to Q4. Its brightness is controlled.

Therefore, by using ultra-bright LEDs in the PWM method at sunset using accurate voltage information from the voltage and GPS satellites charged with sunlight to produce lighting and advertisement lighting, the overheat emission and brightness, which are disadvantages of the super bright LEDs, are reduced. Since it is relatively small compared to the existing ones, there is little change in brightness and heat emission, so it is possible to secure lifetime and reliability of light products and stability of light quantity.

In addition, the user can control the color sum, brightness and lighting time of the super high brightness LED as well as the individual and group of the super high brightness LED. Since the lighting can be produced to maximize the advertising effect, it can produce a fantastic lighting.

Meanwhile, in the present invention, the street lamp is described as an embodiment, but all lamps using high-brightness LED lamps as well as street lamps, security lamps, clairvoyant lamps, underwater lamps, fountain lamps, underground lights, aviation lights, bus stop lamps, park toilets, etc. It can be applied to lighting and landscape lighting.

According to the inventors of the present invention, which is configured as described above, the street lighting lighting system using the solar cell and the GPS, the satellite standard time information of the GPS is synchronized with its own timer time, and the sunrise, sunset by the Meteorological Agency sunrise, sunset time program It is possible to produce colors (red, green, blue, white), which are a number of ultra-high brightness LED lights, and the lighting is produced by the time control group unit (for example, group A, group B, and group C in groups of 5 to 100 units). Group D Group units can be sequentially lit and blinking to produce visual time lighting and light intensity strong or weak.

In addition, it can be used semi-permanently by using the solar cell which is infinite power as a power source and adopting ultra-high brightness LED lighting.

While the present invention has been shown and described with respect to specific embodiments, it should be understood that the present invention may be variously modified and changed without departing from the spirit or the scope of the present invention provided by the following utility model registration claims. It will be clear that those skilled in the art can easily know.

1 is a perspective view showing the configuration of an LED street light using a conventional solar energy,

Figure 2 is a block diagram showing the configuration of the lighting directing system of the street lamp using the solar cell and GPS according to the present invention,

Figure 3 is a perspective view showing the configuration of the lighting directing system of the street lamp using the solar cell and GPS according to the present invention,

4 is a side cross-sectional view of FIG.

5a to 5c is a plan view showing the configuration of the advertising lighting panel of the lighting production system of the street lamp using the solar cell and GPS according to the present invention.

<Explanation of symbols on main parts of the drawings>

110: street lamp pontoon 120: rotating pontoon

130: screen panel 140: lighting directing device

144: red, green, blue super high brightness LED

146: white super high brightness LED 200: control module

210: charging module 220: overcharge protection circuit

230: over-discharge protection circuit 240: GPS module

260: microcomputer 270: pulse width modulation circuit

Claims (9)

In the street light, A street lamp pole having a pedestal at a bottom thereof, a rotating shaft protruding from an upper end thereof, and having a space for accommodating a battery therein; Rotating pontoon formed so that it can be rotated 360 degrees in the rotation axis of the street lamp pontoon; A screen panel formed in a polygonal or disc shape, and having a light collecting plate and a GPS antenna for charging the battery on an upper surface thereof, a reflecting surface formed on a bottom surface thereof, and fixed to be inclined by a support from a side of the rotating iron rod; A lighting directing device formed in a square or a cylindrical shape having both ends opened to radiate light to the screen panel and a distance through a plurality of super-brightness LEDs so as to rotate left and right by a bracket at an upper end of the street lamp pole; And The lighting directing system of the solar cell and the street lamp using GPS, characterized in that it comprises a control module provided inside the lighting directing device to control the charging and output of the storage battery, and to control the lighting directing device. The method of claim 1, The lighting directing device, A body formed in a rectangular or cylindrical shape having both ends opened, fixing holes fixed to the bracket at both ends of a central portion, and having the control module provided therein; A plurality of red, green, and blue ultra-high brightness LEDs mounted thereon, and an advertisement lighting panel provided inside the upper end of the body; And A plurality of white ultra high-brightness LED is mounted, the street lighting panel using a solar cell and GPS, characterized in that consisting of a street lighting panel provided inside the lower end of the body. The method of claim 2, The red, green, blue ultra high brightness LED of the advertising lighting panel, The red, green, and blue super high brightness LEDs are electrically connected to one group, and the red, green, and blue super high brightness LEDs are sequentially formed to neighbor each other so that each light overlaps to produce a desired light color. A street lighting system using a solar cell and GPS, which is mounted in an array, a date array, and a triangular array. The method of claim 2, The control module, A charging module configured to charge the voltage output from the light collecting plate to the storage battery and output a voltage charged in the storage battery; An overcharge protection circuit installed on a line of the light collecting plate and the storage battery to block a voltage charged from the light collecting plate to the storage battery under external control, and to prevent the charging voltage charged in the storage battery from flowing back to the light collecting plate; An over-discharge protection circuit installed on a line of the filling module and the lighting directing device to detect an overload of the lighting directing device; A GPS module for receiving a GPS signal received from the GPS antenna and outputting standard time information; A user setting circuit for allowing a user to set a flashing cycle and a light intensity of the red, green, and blue ultra high brightness LEDs; Synchronize the system by using the standard time information output from the GPS module, red, green of the lighting device according to the preset or user setting at sunset according to the weather station sunrise, sunset time program and color rendering program stored inside Outputs a control signal for controlling the blinking of the blue and white ultra-high brightness LEDs, and operates the overcharge protection circuit when the overcharge detection signal is output from the charging module to block charging of the battery, and to overload the over discharge protection circuit. A microcomputer to block the output of the control signal when is detected; A pulse width modulation circuit for controlling light intensity by converting each control signal output from the microcomputer to the red, green, blue, and white ultra high brightness LEDs of the lighting apparatus into a PWM signal; An amplifier circuit for amplifying the PWM signal output from the pulse width modulation circuit; And And a switching circuit configured to switch according to a PWM signal output from the amplifying circuit to control a voltage supplied from the storage battery to the red, green, blue, and white super high brightness LEDs. Lighting production system. The method of claim 4, wherein The charging module, A comparator for measuring the intensity of the charging voltage by comparing the level of the charging voltage of the battery with a reference voltage; An overcharge indicator configured to display whether overcharged during overcharge according to the intensity of the voltage output from the comparator; And Lighting system of the street lamp using the GPS and the solar cell, characterized in that consisting of a constant voltage outputter for outputting the charging voltage of the battery with a constant constant voltage. The method according to claim 4 or 5, The GPS module, A power supply circuit which receives the constant voltage output from the constant voltage output unit and supplies power to each component; A first amplifier for amplifying a GPS signal received from the GPS antenna; A central processing unit for extracting and outputting standard time information from the GPS signals received through the first amplifier; And And a second amplifier configured to amplify the standard time information extracted from the central processing unit. The method of claim 4, wherein The user setting circuit, A plurality of dip switches and a test switch, The lighting time and light intensity of each of the red, green, blue, and white super high brightness LEDs are adjusted according to an operation of the dip switch, and the red, green, blue, and white super high brightness LEDs are controlled according to an operation of the test switch. Lighting production system of street lamp using solar cell and GPS which all light up. The method according to claim 4 or 5, The pulse width modulation circuit, In response to the control signal output from the microcomputer, the width of the PWM signal is varied so that the brightness is sequentially controlled when the red, green, blue, and white ultra high brightness LEDs are turned on, and the abnormality of the control signal output from the microcomputer. An auxiliary microcomputer for outputting a time retransmission request signal; A plurality of PWM modules for generating a PWM signal in accordance with a control signal output from the auxiliary microcomputer; And And a communication port configured to output a retransmission request signal output from the auxiliary microcomputer to the microcomputer. The method of claim 8, The switching circuit, A collector is connected to an output terminal of the constant voltage output unit, a base is connected to an output terminal of the PWM module, and an emitter is connected to the red, green, and blue ultra high brightness LEDs, and the switching speed is increased by a PWM signal output from the PWM module. The lighting system of the street lamp using the solar cell and GPS, characterized in that the switching transistor for controlling the brightness of the red, green, blue ultra-high brightness LED is adjusted.