KR101875404B1 - Smart LED streetlight system CAPABLE OF variable illumination color temperature - Google Patents

Abstract

A smart LED streetlight system with variable color temperature has an integrated control server that predicts visibility distance based on outdoor climate information; And an LED streetlight receiving the visual distance information predicted by the integrated control server and adjusting a wavelength of light emission based on the predicted visual distance information.

Description

[0001] The present invention relates to a smart LED streetlight system,

The present invention relates to a smart LED streetlight system, and more particularly to a color temperature variable smart LED streetlight system.

Recently, global warming due to energy shortage and CO ₂ emission has become an international issue, and the spread of LED lighting, which is a green light, is actively promoted all over the world.

In recent years, LED streetlights have been widely used to reduce power consumption. As information and communication technologies have developed, technologies for more efficiently controlling LED streetlights have been used.

In the existing smart road lighting system, a rain sensor and an illuminance sensor are arranged in the vicinity of the LED streetlight, and the turn-on and turn-off of the LED streetlight are controlled based on the detection result of the sensor, Thereby adjusting the brightness.

However, since the durability of the rain sensor and the illuminance sensor exposed to the external environment is weakened, it is difficult to secure the reliability of the detection result of the sensor.

In addition, in consideration of the Yeongjong Bridge collision accident caused by the collision of 106 cars due to a short distance due to fog, the conventional system that controls the LED streetlight using only the detection results of the rain sensor and the illuminance sensor improves the visibility of the driver It does not provide a function to prevent traffic accidents.

KR 10-0932917 B

SUMMARY OF THE INVENTION The present invention provides a color temperature variable smart LED streetlight system that adjusts a wavelength of light emitted using predicted visual distance information based on climate information.

According to an embodiment of the present invention, an integrated control server for predicting a visibility distance based on outdoor climate information; And a LED streetlight receiving the predicted visibility information transmitted from the integrated control server and adjusting a wavelength of light emitted based on the predicted visibility information.

The integrated control server further receives temperature information and humidity information from a temperature and humidity sensor built in the LED streetlight and predicts the visible distance of the surrounding area of the LED streetlight.

In addition, the LED streetlight emits light having a longer wavelength as the visible distance is shortened in adjusting the wavelength of light emitted based on the visible range information.

The color temperature-variable smart LED streetlight system according to the embodiment of the present invention can prevent traffic accidents by improving the visibility of the driver by adjusting the wavelength of light emitted using the predicted visibility information based on the climate information.

1 is a conceptual diagram of a smart LED streetlight system according to an embodiment of the present invention.
2 is a block diagram of a smart LED streetlight system according to an embodiment of the present invention.
3 is a flowchart showing an embodiment of a process of predicting visible range information
4 is a flowchart showing an embodiment of a process of changing the color temperature of a street lamp
5 is an exemplary diagram of a plurality of LED streetlights connected to a network

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention.

FIG. 1 is a conceptual diagram of a smart LED streetlight system according to an embodiment of the present invention, and FIG. 2 is a configuration diagram of a smart LED streetlight system according to an embodiment of the present invention.

The smart LED streetlight system according to the present embodiment includes only a simple structure for clearly explaining the technical ideas to be proposed.

Referring to FIG. 1, the smart LED streetlight system includes an integrated control server 100 and an LED streetlight 200. The smart LED streetlight system includes a color temperature variable smart LED streetlight 200 having a variable color temperature to emit light according to predicted visible distance information PRE_CLIMATE_INFO System. ≪ / RTI >

The detailed configuration and main operation of the smart LED streetlight system configured as above will be described below.

The integrated control server 100 predicts the visibility distance based on the external climate information CLIMATE_INFO.

Climate information (CLIMATE_INFO) is connected to the weather station's server and provides information on atmospheric pressure, hourly forecast, hourly forecast, daily forecast, weekly forecast, monthly forecast, climate information for the last three years, shortest forecast, Weather information provided by the weather station such as weather information.

Climate information (CLIMATE_INFO) includes all information related to weather observed at each individual station as well as the servers of the meteorological agency.

The LED streetlight 200 receives the visual distance information PRE_CLIMATE_INFO predicted by the integrated control server 100 and adjusts the wavelength of emitted light based on the predicted visual distance information PRE_CLIMATE_INFO.

A temperature and humidity sensor is built in the LED streetlight 200, and the temperature and humidity sensor is configured to detect temperature information and humidity information around the LED streetlight 200. At this time, the temperature and humidity sensor is preferably arranged so as not to be directly exposed to the external environment (snow, rain) by the structure of the LED streetlight 200.

The LED streetlight 200 controls the wavelength of light emitted based on the visible range information (PRE_CLIMATE_INFO), and operates to emit light of an increasingly longer wavelength as the viewing distance becomes shorter.

Here, the shortening of the viewing distance means that the distance seen by the human vision, such as heavy rain / heavy snow fall, hail fall, fogging, yellow dust, smoke, .

For example, when the LED streetlight 200 is provided with the first LED element group for emitting the color temperature of 2800K to 3000K and the second LED element group for emitting the color temperature of 4800K to 5000K,

When the second LED element group emitting light of color temperatures of 4800K to 5000K is emitted at a normal time and when the visible range is shortened due to the gaseous phase fermentation, the first LED element group emitting light of color temperatures of 2800K to 3000K is emitted.

The numerical value of the color temperature and the kind of the color temperature exemplified in this embodiment are merely one example, and the LED streetlight 200 is configured such that light near a wavelength of about 560 to 780 nm region that emits red light as the viewing distance becomes shorter .

That is, since the light of a longer wavelength is farther than the light of a short wavelength, it is preferable that the light is controlled to emit light with a relatively longer wavelength as the visible distance is shortened.

Meanwhile, the integrated control server 100 may further receive temperature information and humidity information from the temperature and humidity sensor built in the LED streetlight 200, and can predict the visible distance of the surrounding area of the LED streetlight 200.

Basically, the integrated control server 100 is configured to predict visible range information (PRE_CLIMATE_INFO) of an area where the LED streetlight 200 is installed based on outdoor climate information (CLIMATE_INFO).

However, since the climate information CLIMATE_INFO may not reflect the information of the field where the LED streetlight 200 is installed in real time, the integrated control server 100 receives temperature information and humidity from the temperature and humidity sensor built in the LED streetlight 200, Information can be received, and the visibility information (PRE_CLIMATE_INFO) can be re-calculated considering both the temperature information, the humidity information, and the climate information (CLIMATE_INFO).

For reference, there are two types of fog caused by evaporation: steam steam and wire steam, and fog generated by cooling is called radiant steam and steam steam.

Steam is a fog that occurs when cold air is blowing on a surface much warmer than it is, and only when the temperature difference is very large.

When the warm air on the warming wire ascends on the slope of the cold air, the heat is generated by the adiabatic cooling and it rains. It is a mist that is generated by the evaporation of the raindrop falling into the cold air.

It is also called a room office by a mist which is generated by the radiating cooling of the floor and the cooling of the air near the floor. Radiant mite is good when there is no wind on a clear day and the relative humidity is high. If there is wind, the thickness of the base layer that is cooled by turbulence is increased and the degree of cooling becomes smaller, so that no fog occurs.

Adult breeze is a fog that occurs when the air spreads horizontally. The cooling of the moving air is related to the temperature difference between the air and the underlying cool surface, and also to the rate at which the air crosses the isotherm of the underlying surface.

Therefore, the integrated control server 100 basically calculates whether or not the steam radiated, the radiated, radiated radiated, and the radiated radiated are generated based on the climatic information (CLIMATE_INFO)

When the temperature information and the humidity information of the area where the LED streetlight 200 is installed are delivered in real time, the integrated control server 100 considers the temperature information, the humidity information, and the climate information (CLIMATE_INFO) The wavelength at which the LED streetlight 200 emits light can be adjusted according to the calculation result.

For reference, the LED streetlight 200 may include a first camera for photographing a visible light region, a second infrared camera for photographing an infrared region, and a third camera for photographing an ultraviolet region.

The LED streetlight 200 may transmit at least one of the photographed images of the first to third cameras to the integrated control server 100. The integrated control server 100 controls the temperature and humidity information and the climate information CLIMATE_INFO, And visual range information (PRE_CLIMATE_INFO) can be calculated in consideration of both photographed images.

At this time, since the photographed image photographed by the camera of the LED streetlight 200 is the most reliable data, the integrated control server 100 transmits the visible distance information (PRE_CLIMATE_INFO) calculated by the temperature information, the humidity information, and the climate information (CLIMATE_INFO) (PRE_CLIMATE_INFO) with priority given to the visible range information (PRE_CLIMATE_INFO) calculated by the photographed image.

When the camera is incorporated in the LED streetlight 200, the visible range information PRE_CLIMATE_INFO is basically calculated by the photographed image in the visible light region. That is, the camera captures a plurality of reference targets arranged at regular intervals, and can visually recognize whether the reference target is identified or not.

Also, the integrated control server 100 can calculate the visible range information (PRE_CLIMATE_INFO) by combining at least one of the photographed image in the visible light region, the photographed image in the infrared region, and the photographed image in the ultraviolet region.

Meanwhile, the camera built in the LED streetlight 200 has a built-in rider sensor. The rider sensor outputs the laser to the moving vehicle, and receives the reflected light to measure the distance to the vehicle.

The distance information with the vehicle measured by the rider sensor can be provided to the integrated control server 100. The integrated control server 100 calculates the distance information of the vehicle, the measured time information, It is possible to calculate the field distance information (PRE_CLIMATE_INFO) of a more reliable field by combining all the camera images.

The integrated control server 100 can display the visual distance information PRE_CLIMATE_INFO calculated by the temperature information, the humidity information and the climate information CLIMATE_INFO, and the visual distance information PRE_CLIMATE_INFO calculated by the photographed image, And stores it as a database. For reference, it is preferable that the correction value of the error is stored only when a change in the visual distance occurs due to a natural phenomenon. For example, when an error occurs due to an artificial phenomenon such as a fire in the vicinity, the correction value is not stored in the database.

When the visual information (PRE_CLIMATE_INFO) is calculated on the basis of the temperature information, the humidity information, and the climate information in a state in which no image is provided, the integrated control server 100 reflects the correction value stored in the database, (PRE_CLIMATE_INFO).

Meanwhile, when the integrated control server 100 provides the photographed image, the integrated control server 100 may provide the brightness information of the area where the LED streetlight 200 is installed, Can be adjusted. That is, as the brightness of the surroundings of the LED streetlight 200 becomes darker, it is possible to control to emit brighter light.

In addition, the integrated control server 100 can only control the LED streetlight 200 on the basis of the climate information CLIMATE_INFO if the adjustment-viewing distance is good so as to emit light having different color temperatures in every season. That is, it is possible to emit light of a short wavelength of the blue series in the summer when the temperature is high and to emit light of the long wavelength of the red series in the winter when the temperature is low.

3 is a flowchart showing an embodiment of a process of predicting visible range information.

The process of predicting the visible range information described above with reference to FIG. 3 will now be described in brief.

First, step S11 of collecting climate information CLIMATE_INFO of the weather station is performed.

Next, a step S12 for judging whether the weather information related to the visual distance has been effected is proceeded.

Next, when the weather special is fermented, the step (S13) of storing the weather data before and after the weather special is performed.

Finally, the calculation process is performed based on the fog forecast model. That is, the step S14 in which the visible range information PRE_CLIMATE_INFO is calculated (predicted) based on the climate information CLIMATE_INFO.

At this time, the visual distance information PRE_CLIMATE_INFO may be calculated by adding a step S15 in which temperature information and humidity information built in the LED streetlight 200 are further provided.

4 is a flowchart showing an embodiment of a process of changing the color temperature of the streetlight.

The color temperature changing process described above with reference to FIG. 4 will be summarized as follows.

First, a step S21 of collecting climate information CLIMATE_INFO of the weather station is performed.

Next, the process of determining whether fog occurs is performed based on the foggy forecast model. That is, step S22 where the visual distance information PRE_CLIMATE_INFO is calculated (predicted) based on the occurrence of fog on the basis of the climate information CLIMATE_INFO.

Next, when it is calculated that a fog occurs, a step S24 is performed in which the color temperature (wavelength) of the LED streetlight 200 is adjusted according to the visible range information PRE_CLIMATE_INFO according to the occurrence of fog.

In this case, even if the fog is not generated, the color temperature (wavelength) of the LED streetlight 200 is changed according to the weather information, when the goggles are fermented through the step S23 of judging whether the goggles are fermented The adjusting step S24 proceeds.

5 is an illustration of a plurality of LED streetlights connected to a network.

Referring to FIG. 5, a plurality of LED streetlights are arranged at regular intervals along the roadway.

As described above, each LED streetlight 200 is configured to control the wavelength of light emitted under the control of the integrated control server 100,

When a plurality of LED streetlights are provided, the LED streetlights are connected to a network to exchange data. In other words, a smart LED streetlight system linked to the Internet of things is constructed.

The plurality of LED streetlights adjust the wavelength of light emitted by receiving the visual distance information predicted by the integrated control server 100.

At this time, at least one LED streetlight exchanges data with the integrated control server 100 in a broadband wireless communication manner, and each LED streetlight is configured to exchange data with neighboring LED streetlights through a local wireless communication method.

Here, the broadband wireless communication scheme is defined as any one of communication schemes such as 2G, 3G, 4G, and LTE, and the local wireless communication scheme may be defined as any one of communication schemes such as Bluetooth, ZigBee, and wireless LAN (WIFI).

For reference, each LED streetlight is basically configured to exchange data with neighboring LED streetlights in a local wireless communication system. However, in consideration of the distanced distance, LED streetlights, which exchange data with the integrated control server 100, Lt; RTI ID = 0.0 > and / or < / RTI >

In addition, each of the LED streetlights connected by the local wireless communication method can automatically reconfigure the network connection configuration to exchange data with neighboring LED streetlights when the communication connection state with neighboring LED streetlights is poor.

Therefore, even if the communication of one LED streetlight for exchanging data in the local wireless communication system is poor, the network connection configuration is automatically reconfigured so that the data exchange can proceed between the remaining LED streetlights after excluding the LED streetlight where the failure occurs.

In addition, since at least one LED streetlight capable of exchanging data with the integrated control server 100 in a broadband wireless communication system is provided, when the communication failure occurs, the LED streetlight in which the failure has not occurred and the integrated control server 100 The network connection configuration is automatically reconfigured so that data can be exchanged. At this time, as the LED streetlight for exchanging data with the integrated control server 100 through the broadband wireless communication method is changed, the local network network is automatically reconfigured.

On the other hand, the integrated control server 100 further receives temperature information and humidity information from a temperature and humidity sensor built in a plurality of LED streetlights, and predicts a visible distance of a peripheral area of a plurality of LED streetlights.

The plurality of LED street lamps can be classified into at least one streetlight group based on their respective positions. The integrated control server 100 predicts the visible distances for each streetlight group, and then determines the wavelength of light emitted for each streetlight group Can be adjusted.

An operation when a plurality of LED streetlights are classified into at least one streetlight group will be described as follows.

For example, it is assumed that the first streetlight group, the second streetlight group, and the third streetlight group are sequentially arranged.

The cameras of the pair of LED street lamps facing each other with the road in the first streetlight group set each other as a reference target and shoot each other. The camera recognizes whether the reference target is identified, .

In this case, when there are a plurality of LED streetlights facing each other in the first streetlight group, the visual distance information (PRE_CLIMATE_INFO) of the first streetlight group is calculated by averaging each value, and the wavelength of light emitted according to the visible distance information (PRE_CLIMATE_INFO) .

At this time, each LED streetlight of the second streetlight group and the third streetlight group independently calculates the visible range information (PRE_CLIMATE_INFO) of each streetlight group through the above-described operation.

Therefore, the wavelengths of light emitted by the respective streetlight groups are different from each other, and the integrated control server 100 uses the visible range information (PRE_CLIMATE_INFO) calculated from the above-mentioned field information as the top priority information.

For reference, in consideration of a communication failure with the integrated control server 100, after recognizing whether or not the reference target is identified by using a camera of an LED streetlight facing each other, a subject identifying the on- . That is, even if communication failure occurs with the integrated control server 100, the streetlight group itself can adjust the wavelength of emitted light after calculating the visible range information (PRE_CLIMATE_INFO).

The integrated control server 100 can exchange data with a plurality of LED streetlights in real time, thereby monitoring the operation status of each LED streetlight. That is, the integrated control server 100 displays the normal / bad operation state of each LED streetlight, the wavelength of the light currently emitting light, and the like so that the administrator can check the state of the plurality of LED streetlights and manually control them Provide information.

In addition, the integrated control server 100 maps and displays the positions of a plurality of LED streetlights, so that the operator can transmit the position of the corresponding LED streetlights when a malfunction occurs. Each LED streetlight is equipped with a module (GPS module) capable of transmitting satellite position information, so that the operator can utilize the satellite position information displayed on the map.

The smart LED streetlight system according to the embodiment of the present invention can prevent a traffic accident by improving the visibility of the driver by adjusting the wavelength of light emitted using the predicted visibility information based on the climate information.

Further, since the plurality of LED streetlights are connected to the adjacent LED streetlights through the network, it is possible to efficiently exchange data and easily identify the LED streetlights in which a failure occurs through the network.

Thus, those skilled in the art will appreciate that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Integrated control server
200: LED streetlight

Claims (3)

An integrated control server for predicting the visibility distance based on outdoor climate information; And
And a plurality of LED street lamps receiving the visual distance information predicted by the integrated control server and adjusting a wavelength of light emitted based on the predicted visual distance information,
Wherein the plurality of LED streetlights include a first camera for photographing a visible light region, a second camera for photographing an infrared region, and a third camera for photographing an ultraviolet region, To the integrated control server,
The integrated control server combines at least one of the photographed image of the visible light region, the photographed image of the infrared region, and the photographed image of the ultraviolet region to reflect the calculation of the visible range information,
Wherein the first camera of the plurality of LED streetlights includes a rider sensor for measuring a distance to the vehicle, distance information of the vehicle measured by the rider sensor is provided to the integrated control server, The measured time information, and the camera photographed image of the vehicle are reflected on the calculation of the visible range information,
When the visual distance information calculated by the temperature information, the humidity information, and the climate information and the visual distance information calculated by the photographed image occur, the integrated control server calculates a correction value corresponding to the error, The visual distance information is finally calculated by reflecting the correction value stored in the database when the visual distance information is calculated on the basis of the temperature information, the humidity information, and the climate information,
The plurality of LED streetlights are classified into at least one streetlight group based on their respective positions to adjust the wavelength of light emitted by each streetlight group,
At least one LED streetlight facing each other across the road in the same streetlight group,
If the number of LED streetlights facing each other is more than two, the identified values are averaged. Then,
And controlling the wavelengths of light emission based on the visible distance information by using the visibility distances of the self-identified spot in each streetlight group when a communication failure occurs between the integrated control server and the plurality of LED streetlights, As the viewing distance becomes shorter, the light of longer wavelength is emitted,
The integrated control server monitors the operation status of each LED streetlight by exchanging data with the plurality of LED streetlights in real time, displays the normal / bad operation state of each LED streetlight, the wavelength of light currently emitting light, and the like ,
Wherein the integrated control server maps and displays the positions of the plurality of LED streetlights, thereby transmitting satellite position information of the corresponding LED streetlights from a worker when a malfunction occurs.
The method according to claim 1,
The integrated control server,
And further receives temperature information and humidity information from a temperature and humidity sensor built in the plurality of LED streetlights, and predicts a visible distance of a peripheral area of the plurality of LED streetlights. delete

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