KR20230030092A - Complex electricity supply system of roadway lighting equipment comprising outdoor illumination intensity knowing sensor - Google Patents

Abstract

According to the present invention, a road lighting facility complex power supply system using an external illuminance recognition sensor comprises an external illuminance recognition sensor, an independent installation frame, a solar power generation panel, a power distribution panel, and a lighting control member to efficiently supply electricity supplied from a power plant and electricity supplied from the solar power generation panel in association with external illuminance as power of a road lighting facility and has an advantage in that the solar power generation panel for solar power generation can be installed in a tunnel formed through a mountain.

Description

Complex electricity supply system of roadway lighting equipment comprising outdoor illumination intensity knowing sensor}

The present invention relates to a complex power supply system for road lighting equipment using an external illuminance recognition sensor.

The road lighting equipment refers to lighting installed on the ceiling of a tunnel, roadside, etc., and supplying electricity to such road lighting equipment is a power supply system of the road lighting equipment.

Most of the power supply systems of these road lighting facilities use electricity transmitted from power plants, but there is a tendency to additionally use solar light for eco-friendliness.

It is that of the patent document presented below that can supply electricity by generating electricity using such sunlight.

However, according to the power supply system of the conventional road lighting facility that generates electricity using solar light, regardless of external illumination such as whether it is cloudy, clear, sunset, or sunrise, supplied from the power plant Since electricity is always supplied as a power source for lighting, there is a problem in that power use efficiency is lowered.

In addition, according to the conventional power supply system of road lighting equipment that generates electricity using sunlight and supplies electricity, since the solar power generation panel for photovoltaic power generation is installed in a form disposed on the outer surface of the ceiling covering the road However, there was a problem that it could not be installed in the tunnel formed through the mountain.

Registered Patent No. 10-1008518, Registration Date: 2011.01.10., Title of Invention: Photovoltaic Power Generation Device for Road

The present invention provides a road lighting facility complex power supply system using an external illuminance recognition sensor that allows electricity supplied from a power plant and electricity supplied from a photovoltaic panel to be efficiently supplied to the road lighting facility in conjunction with the external illuminance. to do for the purpose of

Another object of the present invention is to provide a road lighting equipment complex power supply system using an external illuminance recognition sensor so that a photovoltaic power generation panel for photovoltaic power generation can be installed in a tunnel formed through a mountain.

A road lighting facility complex power supply system using an external illuminance recognition sensor according to an aspect of the present invention can supply electricity to road lighting facilities,

an external illuminance recognition sensor for recognizing the external illuminance of the road lighting equipment; An independent installation frame erected in a location independent of the road lighting equipment; a photovoltaic panel disposed on the independent installation frame and capable of generating photovoltaic power; A power switchboard disposed on an inner space of the independent installation frame and capable of supplying at least one of electricity supplied from a power plant and electricity generated from the photovoltaic panel to the road lighting facility to be supplied to the road lighting facility; and in conjunction with the external illuminance value of the road lighting facility recognized by the external illumination sensor, the power switchboard converts any one of the electricity supplied from the power plant and the electricity generated from the photovoltaic panel to the road lighting facility. It includes; lighting control member for controlling to supply to.

According to the road lighting facility complex power supply system using an external illuminance recognition sensor according to an aspect of the present invention, the road lighting facility complex power supply system using the external illuminance recognition sensor includes an external illuminance recognition sensor, an independent installation frame and , As it includes a photovoltaic panel, a power switchboard, and a lighting control member, electricity supplied from the power plant and electricity supplied from the photovoltaic panel are efficiently supplied to road lighting facilities in conjunction with external illumination. It can be done, and there is an effect that the photovoltaic power generation panel for photovoltaic power generation can be installed in a tunnel formed through a mountain.

1 is a view showing a road lighting facility complex power supply system using an external illuminance recognition sensor according to an embodiment of the present invention applied to a tunnel;
2 is a block diagram of components constituting a road lighting facility complex power supply system using an external illuminance recognition sensor according to an embodiment of the present invention.
3 is a partially enlarged cross-sectional view of a combined power supply system for road lighting facilities using an external illuminance recognition sensor according to another embodiment of the present invention.
4 is a cross-sectional view of a cleaning member using discharged air from a tunnel constituting a complex power supply system for road lighting facilities using an external illuminance recognition sensor according to another embodiment of the present invention.
5 is an enlarged view of part A shown in FIG. 4;
6 is an enlarged view of part B shown in FIG. 4;

Hereinafter, a combined power supply system for road lighting facilities using an external illuminance recognition sensor according to embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a view showing a complex power supply system for road lighting facilities using an external illuminance recognition sensor according to an embodiment of the present invention applied to a tunnel, and FIG. 2 is an external illuminance recognition sensor according to an embodiment of the present invention. It is a block diagram of the components constituting the complex power supply system for road lighting facilities using

Referring to FIGS. 1 and 2 together, the road lighting equipment complex power supply system 100 using the external illumination intensity recognition sensor according to the present embodiment can supply electricity to the road lighting equipment 20, and external illumination A recognition sensor 145, an independent installation frame 115, a photovoltaic panel 130, a power switchboard 120, and a lighting control member 140 are included.

The external illuminance recognition sensor 145 is installed outside the open area where the road lighting equipment 20 is installed, and recognizes the external illuminance of the road lighting equipment 20 .

In this embodiment, the road lighting equipment 20 is a light emitting lamp installed on the ceiling of the tunnel 10 or the like.

The independent installation frame 115 is erected at a location independent of the road lighting equipment 20.

In this embodiment, the independent installation frame 115 is installed on an outer space spaced a predetermined distance from the entrance of the tunnel 10 .

The photovoltaic panel 130 is inclined at a predetermined angle on the independent installation frame 115 and can generate photovoltaic power.

The power switchboard 120 is disposed on the inner space of the independent installation frame 115, and the electricity supplied from the power plant 105 and the photovoltaic panel 130 are supplied to the road lighting equipment 20. At least one of the electricity generated in can be supplied to the road lighting equipment 20.

Here, the power plant 105 becomes a transmission power source, and the photovoltaic power generation using the photovoltaic power generation panel 130 becomes a distributed power source that is independent of the transmission power source.

Reference numeral 110 is a concrete base cast at a predetermined height on the installation surface on which the independent installation frame 115 is installed. The power switchboard 120 is installed on the concrete base 110, and the independent installation frame 115 is built on the concrete base 110 in a form surrounding the power switchboard 120, and the solar The power generation panel 130 is installed on the upper part of the independent installation frame 115 to perform solar power generation and to perform a function of a ceiling panel that protects the power switchboard 120 from rain.

The lighting control member 140 interlocks with the external illuminance value of the road lighting facility 20 recognized by the external illuminance sensor 145, so that the power switchboard 120 is supplied from the power plant 105. It is to control to supply any one of the electricity generated by the photovoltaic power generation panel 130 to the road lighting facility 20.

For example, in an emergency such as a power outage, the power switchboard 120 supplies electricity supplied from the power plant 105 to the road lighting equipment 20 at all times for 24 hours, before and after sunrise and sunset. When the external illuminance value of the road lighting facility 20 recognized by the external illuminance recognition sensor 145 is between 3,000 and 10,000 lx, when it is cloudy and recognized by the external illuminance recognition sensor 145 When the external illuminance value of the road lighting facility 20 is 30,000 to 50,000 lx, the power switchboard 120 provides electricity supplied from the power plant 105 and the photovoltaic panel 130 It can be controlled to supply the electricity generated in the road lighting equipment 20 together.

Hereinafter, the operation of the road lighting facility complex power supply system 100 using the external illuminance recognition sensor according to the present embodiment will be described with reference to the drawings.

When the external illuminance value of the road lighting facility 20 recognized by the external illuminance recognition sensor 145 is less than a preset illuminance value, the lighting control member 140 determines that the power switchboard 120 is the power plant 105 ) is controlled to supply electricity supplied from the road lighting facility 20, and the external illumination value of the road lighting facility 20 recognized by the external illumination intensity recognition sensor 145 is greater than or equal to the preset illumination intensity value. , The lighting control member 140 may control electricity generated by the photovoltaic panel 130 to be supplied to the road lighting equipment 20 .

Alternatively, the power switchboard 120 supplies electricity generated by the photovoltaic power generation panel 130, which is a distributed power source, to some of the plurality of circuits constituting the road lighting facility 20, and the road lighting facility 20 ), electricity supplied from the power plant 105, which is a transmission power source, may be supplied to the rest of the plurality of circuits constituting the circuit. In this case, when the external illuminance value of the road lighting facility 20 recognized by the external illuminance recognition sensor 145 is less than the preset illuminance value, the lighting control member 140 determines that the power switchboard 120 Only the electricity supplied from the power plant 105 is controlled so that it is constantly supplied to the rest of the plurality of circuits constituting the road lighting facility 20, and the road lighting facility 20 recognized by the external illuminance recognition sensor 145 When the external illuminance value is equal to or greater than the preset illuminance value, the lighting control member 140 transmits electricity supplied from the photovoltaic panel 130 to the power switchboard 120 to the road lighting facility 20. In addition to being supplied to some of the plurality of circuits constituting the circuit, electricity supplied from the power plant 105 is controlled so that it is always supplied to the rest of the plurality of circuits constituting the road lighting equipment 20 .

As described above, the road lighting facility complex power supply system 100 using the external illuminance recognition sensor includes the external illuminance recognition sensor 145, the independent installation frame 115, and the photovoltaic power generation panel 130 And, as the power switchboard 120 and the lighting control member 140 are included, the electricity supplied from the power plant 105 and the electricity supplied from the photovoltaic panel 130 interlock with the external illumination It can be efficiently supplied as power for the road lighting facility 20, and the photovoltaic power generation panel 130 for photovoltaic power generation can also be installed in the tunnel 10 formed by penetrating a mountain.

Hereinafter, a combined power supply system for road lighting facilities using an external illuminance recognition sensor according to another embodiment of the present invention will be described with reference to the drawings. In performing this description, descriptions overlapping with those already described in the above-described embodiment of the present invention are replaced therewith, and will be omitted here.

3 is an enlarged cross-sectional view of a portion of a complex power supply system for road lighting facilities using an external illuminance recognition sensor according to another embodiment of the present invention, and FIG. 4 utilizes an external illuminance recognition sensor according to another embodiment of the present invention. A cross-sectional view of a cleaning member using air discharged from a tunnel constituting a complex power supply system for one road lighting facility, FIG. 5 is an enlarged view of part A shown in FIG. 4, and FIG. 6 is a view of part B shown in FIG. is an enlargement

3 to 6 together, in this embodiment, the road lighting equipment 20 is a light emitting lamp installed on the ceiling inside the tunnel 10, and the road lighting using the external illuminance recognition sensor according to the present embodiment The facility complex power supply system further includes a cleaning member 250 utilizing tunnel discharge air.

The tunnel discharge air utilization cleaning member 250 generates sunlight by using air discharged from the tunnel 10 through the entrance 11 of the tunnel 10 due to wind pressure when a vehicle enters the tunnel 10 . The upper surface of the power generation panel 230 can be cleaned.

In detail, the tunnel discharge air utilization cleaning member 250 includes an air collector 251, an air flow pipe 252, an air discharge nozzle 253, an air generator rotor 261, an air generator 260, , a direction changing motor 265, a direction changing blade 266, and a pipe cleaning member 270.

The air collector 251 is configured to collect air discharged from the tunnel 10 through the entrance 11 of the tunnel 10 by wind pressure when a vehicle enters the tunnel 10 . It is formed in a relatively extended form toward the tunnel (10) from the upper part of the inlet (11) of (10).

The air flow pipe 252 is connected to the photovoltaic panel 230 from the air collector 251 so that the air collected by the air collector 251 flows toward the upper surface of the photovoltaic panel 230. It extends to a predetermined length toward the upper surface of the.

The air discharge nozzle 253 is to eject the air flowing through the air flow pipe 252 to the upper surface of the photovoltaic panel 230 .

The air collection body 251 is formed in a shape that is relatively widened toward the upper part of the entrance 11 of the tunnel 10 compared to the portion connected to the air flow pipe 252, and the air flow pipe 252 ), the air flow pipe 252 is gradually narrowed from a portion connected to the air collector 251 to a portion connected to the air discharge nozzle 253, and the air discharge nozzle 253 is It forms an open form toward the upper surface of the photovoltaic panel 230 . Then, when a vehicle enters the tunnel 10, the air discharged from the tunnel 10 through the entrance 11 of the tunnel 10 by wind pressure is collected through the air collector 251 and then the After being flowed through the air flow pipe 252, it is sprayed through the air discharge nozzle 253, so that foreign substances such as dust and leaves on the upper surface of the photovoltaic panel 230 are blown out and cleaned.

The air generating rotor 261 is disposed inside the air collecting body 251 and is rotated by air introduced through the air collecting body 251, and is formed in a shape having a plurality of blades.

The air generator 260 includes a power generation rotation shaft connected to the air power generation rotor 261, and generates power while the power generation rotation shaft rotates according to the rotation of the air power generation rotor 261.

The direction change motor 265 is disposed inside the air discharge nozzle 253 and is operated by electricity generated by the air generator 260, and a step motor or the like may be suggested as an example.

The direction changing blade 266 is connected to the motor rotational shaft of the direction changing motor 265 and is disposed inside the air discharge nozzle 253 according to the operation of the direction change motor 265. Through 253, the direction of the air sprayed toward the upper surface of the photovoltaic panel 230 is changed.

While the air from the tunnel 10 flows through the air collector 251, the air power generation rotor 261 is rotated, and power is generated in the air generator 260, and the air generator 260 The direction conversion motor 265 is operated using electricity formed in ), so that the direction conversion blade 266 is rotated in the up and down direction within a predetermined angle range, and accordingly, the air is discharged through the discharge nozzle 253 Air can reach the entire upper surface of the photovoltaic panel 230 uniformly.

The pipe cleaning member 270 receives a portion of the air flowing through the air flow pipe 252 and sprays it toward the inside of the air flow pipe 252 to clean the inside of the air flow pipe 252. It may include a pipe cleaning support 271, a pipe cleaning air inflatable body 272, a pipe cleaning flow pipe 273, and a delayed open valve 274.

The pipe cleaning support 271 is built on the outer wall of the air flow pipe 252 at a predetermined height.

The air expanding body 272 for pipe cleaning is disposed above the pipe cleaning support 271, is formed in a spherical shape made of an elastic material such as rubber, and is part of the air flowing through the air flow pipe 252. It can be expanded while accommodating .

The air inflatable body 272 for pipe cleaning is made transparent so that sunlight can pass therethrough.

The pipe cleaning flow pipe 273 connects the inside of the air flow pipe 252 and the air expanding body 272 for pipe cleaning, so that some of the air flowing through the air flow pipe 252 is used for pipe cleaning. This is to flow into the inflatable air body 272, and to inject the air that has flowed into and accommodated into the inflatable air body 272 for cleaning the pipe into the inside of the air flow pipe 252 for cleaning.

The pipe cleaning flow pipe 273 communicates with the upper portion of the air flow pipe 252 and is inclined at a predetermined angle toward a portion connected to the air collector 251 in the air flow pipe 252. The upper part of the air flow pipe 252 and the pipe cleaning flow pipe 273 are formed in an inclined shape such that a portion toward the air discharge nozzle 253 is an acute angle. Then, some of the air flowing through the air flow pipe 252 can flow in the flow direction and then smoothly flow into the flow pipe 273 for pipe cleaning.

The delay open valve 274 covers the flow pipe 273 for pipe cleaning from the inside of the inflatable air body 272 for pipe cleaning, so that the internal pressure of the inflatable air body 272 for pipe cleaning is a preset pressure. This is to prevent the air inside the inflatable air flow pipe 272 for pipe cleaning from being injected into the air flow pipe 252 through the flow pipe 273 for pipe cleaning until an abnormality occurs.

The delayed open valve 274 is made of an elastic material such as rubber, and one side of the delayed open valve 274 is fixed to one side of an inner surface of the air inflatable body 272 for cleaning the pipe. The body of the valve 274 is formed to cover and block the entrance connected to the flow pipe 273 for pipe cleaning in the inside of the air inflatable body 272 for pipe cleaning, and the other side of the delay open valve 274 is It is caught on the other side of the inner surface of the air inflatable body 272 for cleaning the pipe.

When air flows into the inside of the air expanding body 272 for pipe washing from the flow pipe 273 for pipe washing, the delay open valve 274 controls the pressure of the air flowing in from the flow pipe 273 for pipe washing. While being elastically deformed to the inside of the inflatable air body 272 for pipe cleaning, the inlet connected to the flow pipe 273 for pipe cleaning is opened in the inflatable air body 272 for pipe cleaning.

On the other hand, when air does not flow into the inside of the inflatable air body 272 for pipe cleaning from the flow pipe 273 for pipe cleaning, the internal pressure of the inflatable air body 272 for pipe cleaning is equal to or higher than the preset pressure. The other side of the delayed open valve 274 remains caught on the other side of the inner surface of the air expanding body 272 for pipe cleaning until The inlet connected to the flow pipe 273 for pipe cleaning is closed by the inflatable body 272 .

When configured as described above, when a vehicle enters the tunnel 10, the air discharged from the tunnel 10 is collected by the air collector 251, flows through the air flow pipe 252, and then the air It is sprayed onto the top surface of the photovoltaic panel 230 through the discharge nozzle 253 to clean the photovoltaic panel 230 .

During this process, as the air power generation rotor 261 is rotated by the air collected by the air collector 251, the air power generation rotor 261 generates power, and the electricity generated by the air power generation rotor 261 As the direction changing motor 265 is operated, the direction changing blade 266 rotates, and the direction of the air injected through the air discharge nozzle 253 covers multiple points on the upper surface of the photovoltaic panel 230. Accordingly, the air injected through the air discharge nozzle 253 is uniformly discharged to the entire upper surface of the photovoltaic panel 230, so that the photovoltaic panel 230 The top surface can be cleaned as a whole.

Meanwhile, during the flow of air through the air flow pipe 252, a portion of the air flowing through the air flow pipe 252 passes through the pipe cleaning flow pipe 273 to the air expanding body 272 for pipe cleaning. It is introduced into the inside and the air expander 272 for cleaning the pipe is primarily expanded.

As the air accommodated inside the inflatable air body 272 for pipe cleaning is heated by the solar heat of sunlight passing through the inflatable air body 272 for pipe cleaning, the internal pressure of the inflatable air body 272 for pipe cleaning increases. As a result, the air expanding body 272 for cleaning the pipe is secondarily expanded.

During the process of increasing the internal pressure of the inflatable air body 272 for pipe cleaning, the delay open valve 274 is operated until the internal pressure of the inflatable air body 272 for pipe cleaning becomes equal to or greater than the preset pressure. After being closed, when the internal pressure of the inflatable air body 272 for pipe cleaning reaches the preset pressure, the other side of the delay open valve 274 is connected to the inner surface of the inflatable air body 272 for pipe cleaning. When the state caught on the side is released, the other side of the delayed open valve 274 is lowered into the inside of the flow pipe 273 for pipe cleaning, and the delayed open valve 274 is opened to open the air expanding body 272 for pipe cleaning. ) is discharged through the flow pipe 273 for cleaning the pipe, and accordingly, the inside of the air flow pipe 252 is automatically cleaned.

As described above, as the road lighting facility complex power supply system using the external illuminance recognition sensor further includes the tunnel discharge air utilization cleaning member 250, when the vehicle enters the tunnel 10, the wind pressure The air discharged from the tunnel 10 through the inlet 11 of the tunnel 10 is collected through the air collector 251 and then flows through the air flow pipe 252, and then the air discharge nozzle 253 ), foreign substances such as dust and fallen leaves on the upper surface of the photovoltaic power generation panel 230 are blown out and cleaned, and accordingly, the upper surface of the photovoltaic power generation panel 230 is maintained in a clean state to generate electricity Efficiency can be improved.

Although the present invention has been shown and described in relation to specific embodiments above, those skilled in the art may modify the present invention in various ways without departing from the spirit and scope of the present invention described in the claims below. And it will be appreciated that it can be changed. However, it should be clearly stated that all of these modifications and variations are included within the scope of the present invention.

According to the combined power supply system for road lighting facilities using an external illuminance recognition sensor according to an aspect of the present invention, the electricity supplied from the power plant and the electricity supplied from the photovoltaic power generation panel in conjunction with the external illuminance are efficiently used for road lighting facilities. Since it can be supplied as power and a solar power generation panel for photovoltaic power generation can be installed in a tunnel formed through a mountain, its industrial applicability is high.

100: Road lighting facility complex power supply system using an external illumination sensor
115: independent installation frame
120: power switchboard
130: solar power panel
140: lighting control member
145: external illumination sensor

Claims (3)

As it can supply electricity to road lighting equipment,
an external illuminance recognition sensor for recognizing the external illuminance of the road lighting equipment;
An independent installation frame erected in a location independent of the road lighting equipment;
a photovoltaic panel disposed on the independent installation frame and capable of generating photovoltaic power;
A power switchboard disposed on an inner space of the independent installation frame and capable of supplying at least one of electricity supplied from a power plant and electricity generated from the photovoltaic panel to the road lighting facility to be supplied to the road lighting facility; and
In conjunction with the external illuminance value of the road lighting facility recognized by the external illumination sensor, the power switchboard converts any one of electricity supplied from the power plant and electricity generated from the photovoltaic power generation panel to the road lighting facility. A road lighting facility complex power supply system using an external illuminance recognition sensor comprising: a lighting control member for controlling supply. According to claim 1,
The road lighting equipment is installed inside the tunnel,
The road lighting facility complex power supply system using the external illuminance recognition sensor
When a vehicle enters the tunnel, the air discharged from the tunnel is used to clean the upper surface of the photovoltaic panel; a cleaning member utilizing discharged air from the tunnel; Road lighting equipment complex power supply system. According to claim 2,
The cleaning member utilizing the tunnel discharge air
an air collector formed in a shape relatively extended toward the tunnel so that air discharged from the tunnel can be collected when a vehicle enters the tunnel;
an air flow pipe extending a predetermined length from the air collector toward the upper surface of the photovoltaic panel so that the air collected by the air collector flows toward the upper surface of the photovoltaic panel;
An air discharge nozzle for ejecting the air flowing through the air flow pipe to the upper surface of the photovoltaic panel;
An air generating rotor disposed inside the air collector and rotated by air introduced through the air collector;
An air generator including a power generation rotation shaft connected to the air power generation rotor and generating power while the power generation rotation shaft rotates according to the rotation of the air power generation rotor;
A direction changing motor operated by electricity generated by the air generator;
a direction changing blade connected to a motor rotation shaft of the direction changing motor and disposed inside the air discharge nozzle to change the direction of the air ejected through the air discharge nozzle according to the operation of the direction change motor;
A pipe cleaning member capable of cleaning the inside of the air flow pipe by receiving some of the air flowing through the air flow pipe and spraying it toward the inside of the air flow pipe,
The pipe cleaning member is
A pipe cleaning support built on an outer wall of the air flow pipe;
an air inflatable body for pipe cleaning, which is disposed above the pipe cleaning support, is formed in a spherical shape made of an elastic material, and is expandable while accommodating a part of the air flowing through the air flow pipe;
The inside of the air flow pipe is connected to the inflatable air body for cleaning the pipe, so that some of the air flowing through the air flow pipe flows into the inflatable body for cleaning the pipe, and the air flowing into the inflatable air body for cleaning the pipe is allowed to flow into the inflatable body. A pipe cleaning flow pipe for spraying into the air flow pipe;
The air inside the inflatable pipe-cleaning body covers the flow pipe for pipe-cleaning inside the inflatable air-cleaning body for pipe-cleaning until the internal pressure of the inflatable air-cleaning body reaches a preset pressure or higher. A delay open valve prevents the air from being injected into the air flow pipe through the pipe cleaning flow pipe;
When air flows into the inside of the inflatable air body for cleaning the pipe from the flow pipe for cleaning the pipe, the delay open valve is elastically deformed into the inflatable body for cleaning the air, and the inflatable body for cleaning the pipe cleans the pipe. The inlet connected to the flow pipe is opened,
When air does not flow from the pipe-cleaning flow pipe to the inside of the pipe-cleaning air inflatable body, the delay open valve operates until the internal pressure of the pipe-cleaning air inflatable body reaches the preset pressure or higher. The air inflatable body closes the inlet connected to the flow pipe for cleaning the pipe,
When a vehicle enters the tunnel, the air discharged from the tunnel is collected by the air collector, flows through the air flow pipe, and is then sprayed to the upper surface of the photovoltaic panel through the air discharge nozzle to generate solar power. clean the panel
As the air power generation rotor is rotated by the air collected by the air collector, the air power generation rotor is generated, and as the direction change motor is operated by the electricity generated by the air power generation rotor, the direction change blade is rotated. The direction of the air injected through the air discharge nozzle may be switched toward a plurality of points on the upper surface of the photovoltaic panel,
A part of the air flowing through the air flow pipe is introduced into the inside of the air inflatable body for pipe cleaning through the flow pipe for pipe cleaning, and the air inflatable body for pipe cleaning is primarily expanded;
As the air accommodated inside the inflatable pipe-cleaning body is heated by solar heat, the internal pressure of the inflatable pipe-cleaning body is increased, and the inflatable body for pipe-cleaning is secondarily expanded,
The delayed open valve is closed until the internal pressure of the inflatable air body for pipe cleaning is equal to or greater than the preset pressure, and the delayed open valve is closed when the internal pressure of the inflatable air body for pipe cleaning reaches the preset pressure. Road lighting equipment using an external illumination intensity recognition sensor, characterized in that when the valve is opened, the air accommodated inside the air inflating body for pipe cleaning is discharged through the pipe cleaning flow pipe to clean the inside of the air flow pipe. Complex power supply system.

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