KR101030282B1 - Controller of load pilot lamp having a function of alteration color - Google Patents

Abstract

PURPOSE: A controller of a load pilot lamp having a function that alternates seven colors is provided to increase the durability and completeness of a system by distinguishing day/night without a separate optical sensor. CONSTITUTION: A voltage detecting unit(209) detects the voltage of electrical energy. An object sensing module(213) senses the existence of vehicles. A humidity sensor module(215) detects surrounding humidity. A switching unit(211) turns on/off an eye guidance lamp(217). A controller(201) controls the switching unit.

Description

Eye-guided light control device with color changing function {CONTROLLER OF LOAD PILOT LAMP HAVING A FUNCTION OF ALTERATION COLOR}

The present invention relates to a road safety light, and more particularly, based on a power supply and a control of a flashlight using a solar cell, a color change function that induces a night vision on the road while changing and controlling the emission color according to the detection of a driving vehicle. It relates to a gaze induction light control device having a.

In general, the gaze guidance lamp is already provided in various forms, and is equipped with a reflector and a light emitting body that emit light to perform a role and a function of inducing the driver's safe operation. As described above, in the case of the induction lamp equipped with the reflector, the headlights of the vehicle are reflected through the reflector, and the driver recognizes the light and distinguishes the lanes. By charging and generating light using the charged energy at night, the driver distinguishes the lane through the light.

1 is a perspective view showing a conventional solar LED eye-guided light. As shown, the solar LED gaze induction lamp (1), which is installed at a predetermined interval on the road road surface, LED light emitting unit 31 having a plurality of ultra-high brightness LED (31b) largely as a light emitting device, An upper housing 10 including a light emitting display panel 30 provided with a solar cell 34 for supplying power to the LED light emitting unit 31, and the upper housing 10 is hermetically coupled to an upper opening thereof. And the PCB circuit board 40 and the storage battery 50 for the operation control of the eye induction lamp (1) is provided in the inner space is composed of a lower housing 20 embedded on the road road surface.

In addition, the upper surface of the upper housing 10 is integrally formed with a transparent cover 11 through which the sunlight can be transmitted by a transparent material, the solar energy transmitted through the transparent cover 11, the solar cell 34 ) Converts into electrical energy and charges the battery 50 during the day to make the operation of the eye induction lamp 1 even on cloudy days such as at night, in rainy weather, and in heavy fog. In addition, since the internal space of the lower housing 20 provided with the battery 50 is sufficient, the battery 50 is classified for use at night and rainy days or on a cloudy day such as heavy fog, so that the LED is stable during the day and night. It has a luminous efficiency.

The upper housing 10 configured as described above has the same upper surface as the transparent cover 11 and is coupled to the lower housing 20, and when the lower housing 20 is buried on the road surface, the upper surface is external. The light emitted from the LED of the LED light emitting part 31 passes through the transparent cover 11 and diffuses to the outside. Therefore, the conventional gaze guidance lamp minimizes the portion exposed on the road surface to reduce the impact caused by the driving vehicle and prevent the LED's inability to emit light, and the watertight packing is provided at the portion to be coupled to the transparent cover, the upper housing, and the upper housing. The lower housing is completely sealed to prevent water from penetrating into the inner space. In addition, by using the prism as a lens unit of the LED light emitting unit to induce the light emitted from the LED to expand and diverge along the vehicle lane, it is easy to distinguish the effect even at night or daytime rain, dense fog.

However, the above-described conventional eye guidance light has a number of effects, but in the end, it has a passive structure that only increases durability, and performs only simple lighting control in day / night and lighting control in cloudy weather by fog. Functionality for planning the safety of a traveling vehicle is deteriorated. That is, a safety accident on the road is caused by a rigid environment around the road, and as in the prior art, it will be said that it is insufficient to prevent the safety accident based on only the control of turning on and off of induction lamps.

The present invention was created to solve the above problems, and an object of the present invention is to identify the day / night without a separate optical sensor to control the line of sight light having a seven-color color change function to increase the durability and completeness of the system In providing a device.

Another object of the present invention is to monitor the driving state of the vehicle, and by changing the color of the gaze guidance lamp according to the result, it is possible to induce a change in the surrounding environment of the driver to ensure the safety of the vehicle driving color change It is to provide a gaze guidance light control device having.

It is still another object of the present invention to provide a gaze induction light control device having a seven-color color changing function that can increase the functionality of the system by performing a control of turning on and off the gaze induction lamp according to the fog and humidity conditions.

In order to achieve the above object, the apparatus for controlling a gaze induction light having a color changing function of the present invention converts solar energy into electrical energy from the solar cell 205 and charges it with the battery 207, and then uses charging energy. An apparatus for turning on / off the gaze induction lamp 217, the apparatus comprising: a voltage detector 209 for detecting a voltage of electrical energy provided from the solar cell 205 and converting the voltage into a digital signal; An object detecting sensor module 213 for detecting whether a vehicle is detected by detecting a signal reflected according to a vehicle driving state; Humidity sensor module for detecting the humidity of the surroundings (215); A switching unit 211 for turning off the eye induction lamp 217; And a controller 201 for controlling the switching unit 211 by using values input by the voltage detector 209, the object sensor module 213, and the humidity sensor module 215.
The control unit 201,
When the voltage value detected by the voltage detector 209 is greater than or equal to a preset reference value, it is determined as daytime, and when it is less than the preset reference value, it is determined as nighttime,
When it is determined to be daytime, when the detected humidity value is less than the reference value by detecting the ambient humidity state from the humidity sensor module 215, the switching unit 211 is switched off to turn off the eye induction lamp 217,
Even if it is determined as daytime, when the humidity value is equal to or higher than the reference value or at night, the switching unit 211 is turned on to light the eye induction lamp 217,
When the vehicle is detected by the object detecting sensor module 213 in the state where the eye induction lamp 217 is turned on, the color of the eye induction lamp 217 is changed.

The gaze guidance lamp control device having a seven-color color change function proposed in the present invention performs a charging function of electric energy using the solar cell, recognizes the state of development of the solar cell, and discriminates day / night, the object detecting sensor By detecting the vehicle driving state by changing the color of the eye guidance light from the result, it is possible to increase the completeness of the system and to induce safe driving.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, Figure 2 is a block diagram showing a control device of the eye guidance lamp according to the present invention. As shown, a solar cell 205 that converts solar energy into electrical energy, a battery 207 that accumulates electrical energy provided from the solar cell 205, and an electrical energy provided from the solar cell 205. Voltage detecting unit 209 for detecting a voltage and converting it into a digital signal, an object detecting sensor module 213 for detecting a signal reflected according to a vehicle driving state, a humidity sensor module 215 for detecting ambient humidity, many Day / night based on the output signal of the line-flowing light lamp 217 composed of the LED (LED) element of the LED, the switching unit 211 for controlling the light-inducing light lamp 217 on and off, and the voltage detection unit 209 After determining the ambient humidity state from the humidity sensor module 215, and if it is determined that the humidity is less than the reference value and daytime, and supplies the energy generated from the solar cell 205 to the battery 207, Humidity When it is determined that the threshold value is higher than or equal to night, the eye induction lamp 217 is controlled to be turned on through the switching unit 211 and based on the detection signal of the object detecting sensor module 213, The control unit 201 instructs a change in lighting.

Here, the solar energy may be solar energy or solar energy, or may include both sunlight and solar energy. Accordingly, the solar cell 205 may be assumed to be a solar power generator that converts solar energy into electrical energy. In the embodiment of the present invention, the solar cell 205 will be described as a power generator that converts solar energy into electrical energy.

Meanwhile, the gaze induction lamp 217 of the present invention has a structure in which the color of the lamp may be changed according to the instruction of the controller 201, and provides at least seven colors. The seven colors may be implemented in colors that can detect visually significant differences. However, two single colors, such as green, red or blue, red or blue, green or yellow or red, can be provided depending on the location of installation and use.

The object detecting sensor module 213 is for detecting a vehicle driving state on a road, and is installed at a predetermined distance away from a gaze induction light control device according to the present invention. Therefore, the eye induction and the like has a predetermined shape and is buried in the road surface, but the object detecting sensor module 213 may be installed at a distance, for example, about 50M, to transmit the detection signal of the sensor without noise. As described above, the object detecting sensor module 213 is a device for detecting a driving state of a vehicle, and is installed in a toll gate of a highway, in particular, a high-pass lane, thereby changing the color of the eye guidance light lamp when the vehicle enters the rear vehicle. Make sure your car is safe.

Hereinafter, the operation of the present invention will be described in detail with reference to the accompanying drawings. First, FIG. 3 is table information for describing a control pattern according to the present invention. Here, the color of the gaze induction lamp shown in the table information is arbitrarily described, but this is for ease of description, and the color may be changed to any one of seven colors according to the installation place or use of the gaze induction lamp. Of course.

The solar cell 205 receives solar energy and converts the solar energy into electrical energy, and the voltage of the converted electrical energy is converted into a digital signal through the voltage detector 209. The controller 201 recognizes the voltage value of the electric energy and determines whether the preset reference value is reached. If the controller 201 determines that the voltage detected from the solar cell 205 is greater than or equal to the reference value, that is, the controller 201 determines that it is daytime, the controller 201 uses a humidity sensor module (see FIG. 3). 215), the output value is received.

The humidity sensor module 215 determines whether current humidity, for example, fog, is generated. The output value of the humidity sensor module 215 is amplified and output as an electric signal of a predetermined level via the interface unit 203. The controller 201 recognizes this. In this case, when the signal detected by the humidity sensor module 215 is less than the reference value, that is, the amount of fog generated is less than the reference value, the control unit 201 turns off the switching unit 211 to turn off the gaze induction lamp 217. Let's do it.

Here, as the gaze induction lamp 217 is turned off, the output value of the object detecting sensor module 213 is not important and is set to Don't Care in the diagram. On the other hand, when the detection voltage of the solar cell 205 is greater than or equal to the reference value, and the output value of the humidity sensor module 215 is also greater than or equal to the reference value, the amount of generation of fog exceeds the reference value, and the control unit 201 is a gaze induction lamp. 217 is controlled to light up. The lighting color of the eye induction lamp 217 may be preferably “YELLOW”.

On the other hand, when the gaze induction lamp according to the present invention is installed on a highway, for example, a toll gate, the controller 201 may change the color of the gaze induction lamp 217 according to the vehicle driving environment, which is illustrated in FIG. 4A. As usual, the color of the gaze induction lamp may be turned on as 'YELLOW', and when the vehicle passes through an arbitrary position, the color of the gaze induction lamp may be changed to 'BLUE'. That is, when the vehicle enters or passes through an arbitrary position as shown in FIG. 4B, the gaze induction lamp 217 turns on 'BLUE'.

This causes an effect of notifying the driver of the lane or at least stably guiding the driver's gaze by changing the color of the gaze induction lamp 217 when the vehicle approaches the toll gate. Of course, the gaze induction and the like presented in the present invention can induce the same effect even if installed in a curved road, steep slope area, etc. in addition to the toll gate.

FIG. 5 is a diagram illustrating an example of a main circuit diagram of the apparatus for controlling the eye-guided light according to the present invention. The object sensor module 213, the voltage detector 209, the switching unit 211, and the eye-guided lamp 217 may be illustrated. Doing.

As illustrated, the generated energy of the solar cell 205 is connected to the battery 207 via the diode D1, and the voltage detector 209 is positioned between the diode D1 and the solar cell 205. The voltage detector 209 depressurizes the voltage supplied from the solar cell 205, and then amplifies and outputs the voltage as a signal of a predetermined level to use it as a switching signal. In addition, the object detecting sensor module 213 receives the output voltage of the solar cell 205, regulates it to a rated voltage, and generates and supplies an outgoing signal of a predetermined period to the outgoing circuit.

Therefore, when a signal emitted from the transmitting circuit of the object detecting sensor module, for example, ultrasonic waves or infrared rays is reflected from the vehicle, it is detected by the receiving circuit of the object detecting sensor module. The receiving circuit converts the received ultrasonic or infrared signal into an electrical signal and amplifies it to a rated voltage. Subsequently, the gaze induction lamp 217 is turned on or off by the output signal of the switching unit 211 and the output signal of the voltage detection unit 209. Here, the eye-guided lamp 217 has YELLOW or BLUE color, as shown on the circuit, is automatically selected to be turned on.

Here, although the attached circuit diagram excludes the programmed microcomputer shown in FIG. 2, that is, the controller 201, the switching operation of the lamp without the controller may be implemented by combining the output value of the object detecting sensor and the output voltage value of the solar cell. It can be illustrated.

On the other hand, when the power generation voltage of the solar cell 205 detected by the voltage detector 209 is less than the reference value, that is, at night, the eye induction lamp 217 should be turned on, regardless of the detection result of the humidity sensor. According to the output value of the object detection sensor module 213, the color of the eye-guiding lamp lamp 217 is changed.

For example, when the output of the object detecting sensor module 213 is OFF, that is, when the vehicle is not detected, the controller 201 operates the switching unit 211 to set the color of the gaze induction lamp 217 to 'YELLOW'. To keep. If the control unit 201 is not implemented separately in FIG. 5, the 'HIGH' signal is applied to the switching unit 211 as the output value of the object detection sensor module 213, that is, the vehicle is not detected, is applied to the gaze induction lamp lamp ( Only the lamp corresponding to 'YELLOW' in 217) is turned on. The output value of the 'HIGH' level of the object detection sensor module 213 is applied to the base terminal of the transistor Q2 to turn off the lamp corresponding to 'BLUE' of the eye induction lamp 217. In the circuit diagram shown, the difference between on and off will be determined by the number of inverters.

On the other hand, when the vehicle is detected from the object detection sensor module 213, that is, when the output signal of the object detection sensor module 213 is at a 'LOW' level, the inverted switching is performed with the above-described circuit operation, and thus the eye-guiding lamp 217 turns off the 'YELLOW' lamp and turns on the 'BLUE' lamp. In addition, although the eye-guided lamp 217 is implemented in a single color in the accompanying circuit diagram, it will be obvious that full color can be used as described above.

As described above, the gaze guidance light control device having a seven-color color changing function according to the present invention, performs the charging function of the electric energy using the solar cell, and recognizes the state of development of the solar cell to determine the day / night, The object detection sensor provides the ability to detect the driving condition of the vehicle and change the seven colors of the eye guidance light from the result, thereby expanding the field of application of the eye guidance light, increasing the functionality of the system, and reducing the traffic accident rate. It is judged that the industrial use value is high enough.

1 is a perspective view showing a conventional eye-guided light.

Figure 2 is a block diagram showing a device for controlling the gaze induction light according to the present invention.

FIG. 3 is a diagram for describing the control pattern of FIG. 2.

Figure 4a, 4b is a view showing an installation state of the eye guidance lamp according to the invention.

5 is a circuit diagram of an apparatus for controlling the line of sight light according to another embodiment of the present invention.

<Explanation of symbols for main drawings>

201: control unit 203: interface unit

205: Solar Cell 207: Battery

209: voltage detector 211: switching unit

213: object detection sensor module 215: humidity sensor module

217: eye-guided lamp

Claims (7)

In the apparatus for converting the solar energy from the solar cell 205 to electrical energy, charged with the battery 207, and then turning on the gaze induction lamp 217 using the charging energy, A voltage detector 209 for detecting a voltage of electrical energy provided from the solar cell 205 and converting the voltage into a digital signal; An object detecting sensor module 213 for detecting whether a vehicle is detected by detecting a signal reflected according to a vehicle driving state; Humidity sensor module for detecting the humidity of the surroundings (215); A switching unit 211 for turning off the eye induction lamp 217; And It includes a control unit 201 for controlling the switching unit 211 by using the values input by the voltage detector 209, the object detection sensor module 213 and the humidity sensor module 215, The control unit 201, When the voltage value detected by the voltage detector 209 is greater than or equal to a preset reference value, it is determined as daytime, and when it is less than the preset reference value, it is determined as nighttime, When it is determined to be daytime, when the detected humidity value is less than the reference value by detecting the ambient humidity state from the humidity sensor module 215, the switching unit 211 is switched off to turn off the eye induction lamp 217, Even if it is determined to be daytime, when the humidity value is higher than the reference value or at night, the switching unit 211 is turned on to turn on the gaze induction lamp 217 in yellow. When the vehicle is detected by the object detecting sensor module 213 in the state that the eye induction lamp 217 is turned on, the color of the eye induction lamp 217 is changed from yellow to blue. The object detecting sensor module (213) is a gaze induction light control device having a color change function, characterized in that installed in front of the distance from the eye induction lamp (217) by a distance that can transmit the detection signal of the sensor without noise. delete delete delete delete delete delete

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