KR101145899B1 - A universal constant current led traffic lights for temperature compensation - Google Patents

Abstract

PURPOSE: A general-purpose temperature compensation type constant current LED traffic signal lamp is provided to add an ambient temperature compensation circuit selection switch according to an LED color, thereby changing voltage-current and temperature properties according to the LED color. CONSTITUTION: A rectifier(200) converts an AC power source into a DC power source. A power conversion part(300) converts the DC power source into the AC power source. The power conversion part includes a pulse width modulation circuit. An output part(400) comprises a voltage controller(420). The voltage controller controls output voltage according to a switched LED module. A feedback circuit part(500) adjusts the duty ratio of a pulse. The feedback circuit part comprises a temperature compensation circuit(520). The temperature compensation circuit varies reference voltage according to an ambient temperature.

Description

A universal constant current led traffic lights for temperature compensation

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching mode power supply, and more particularly, a general-purpose temperature compensation incorporating a power supply for supplying a constant current by compensating for a change in light output characteristics of an LED according to a change in ambient temperature. Type constant current LED traffic light.

In general, traffic lights for vehicles and pedestrians are installed around the road to smooth traffic flow. Conventional traffic lights use a filament incandescent lamp, such an incandescent lamp has a disadvantage in that a lot of power consumption and short lifespan often need to be replaced, resulting in high maintenance costs.

In order to solve the shortcomings of such incandescent lamps, a traffic light using an LED (Light Emitting Diode) is widely used in recent years. The LED traffic light has an energy saving effect of about 80% to 90% at the same brightness with a power consumption level of 1/10 compared to an incandescent signal.

The conventional LED traffic light improves the stability of the power supply by adopting a power supply method called a switching mode power supply (hereinafter referred to as SMPS) applied to an AC voltage applied from a traffic signal controller. The SMPS controls the on / off of the switch connected to the primary side of the transformer to adjust the amount of current transmitted from the primary side to the secondary side of the transformer to adjust the output voltage output thereby. It is a power supply.

Since the SMPS fluctuates in the load due to the temperature characteristic of the LED, the load, the SMPS changes the output voltage of the SMPS according to the change in the ambient temperature.

Typically, when the ambient temperature increases while driving the LED, the current flowing through the LED decreases, and when the temperature decreases, the current flowing through the LED increases, causing a wavelength shift. Therefore, the LED has a problem in that the light output characteristics (brightness (current) and color, etc.) of the LED changes according to the change in ambient temperature. In addition, as the temperature of the LED increases, its life is shortened.

In addition, since the voltage and current characteristics are different according to the color of the LED elements, SMPS differs according to the voltage and current characteristics of the LEDs for each color in order to realize a traffic light with three-color LEDs such as red, green, and yellow. It is inconvenient to install a specially designed SMPS in consideration of this and use it in replacement. In addition, since the temperature characteristics according to the change of the ambient temperature for each color is also different, even if used in the same place, there is an inconvenience to have a separate SMPS if the color is different.

The present invention is to solve the problems of the prior art, the load capacity, such as the number of LED of the LED module for each color constituting the traffic light is generally similar but there is a slight difference in the characteristics of the voltage and current according to the color and also the ambient temperature dependence If there is, there is no need to have separate power supply for maintenance and new installation, etc. for each characteristic, and the output current adjustment switch according to the color of traffic light and ambient temperature are reflected on the output of one power supply. By adding the ambient temperature sensor and resistance switch to select the ambient temperature compensation circuit according to the LED color to switch the resistance, it is possible to change the voltage and current characteristics suitable for each color by simple switch operation from one power supply. To provide an adaptable universal temperature compensated constant current LED traffic light will be.

In addition, another object of the present invention is to change the output voltage and current of the power supply device by changing the reference voltage in accordance with the change in the ambient temperature, thereby maintaining a constant light output of the LED signal lamp, extending the life of the LED, brightness and change rate It is intended to provide a general purpose temperature compensated constant current LED traffic light that minimizes.

According to the present invention for achieving the above object, a general-purpose temperature-compensated constant current LED signal lamp includes a rectifier for rectifying an applied AC power source to a DC power source, and a pulse width modulation circuit, and includes a pulse width modulation circuit. Accordingly, the power converter converts and outputs the DC power output from the rectifier into an AC voltage having a predetermined voltage level, and rectifies and outputs the AC voltage output from the power converter into a DC voltage and turns on the LED module 600. And an output unit including a voltage adjusting unit for adjusting the output voltage according to the output voltage, and comparing the output voltage and the reference voltage outputted through the output unit, and transferring the comparison result to the power conversion unit through a photocoupler to transmit the duty ratio of the pulse. And a feedback circuit unit including a temperature compensation circuit for changing the reference voltage according to the ambient temperature. The voltage adjusting unit includes two resistors connected in series to an output terminal of the output unit, a second selection switch and a resistor connected in series to the output terminal and connected in parallel to the two resistors, the contacts of the two resistors, and the second resistor. And a first selection switch positioned between the selection switch and the contact of the resistor, wherein the temperature compensation circuit includes first and second resistors connected in series, and a second connection connected in parallel to the first and second resistors, respectively. And a first thermistor, a first switch disposed between the contacts of the two resistors and the first thermistor, and a second thermistor disposed between the contacts of the two resistors and the second thermistor.

Universal temperature compensation constant current LED traffic light according to the present invention is an output current control switch according to the color of the traffic light at the output terminal of one power supply and the ambient temperature sensor to reflect the ambient temperature and the resistor to select the LED color to switch With the addition of the ambient temperature compensation circuit selector switch, it is possible to adapt the voltage current characteristic and the temperature characteristic appropriate to each color universally by simple switch operation in one power supply.

In addition, the general-purpose temperature-compensated constant current LED traffic light according to the present invention changes the reference voltage according to the change of ambient temperature to change the output voltage of the power supply to maintain the optical characteristics (light output) of the LED signal light constantly, It can prevent the breakdown of LED signal lamp and maintain long life.

1 is an overall circuit diagram of a general-purpose temperature compensated constant current LED traffic light according to an embodiment of the present invention.
2 is a circuit diagram showing the configuration of a temperature compensation circuit when the load is an amber LED.
3 is a circuit diagram showing a configuration of a temperature compensation circuit when the load is a red LED.
4 is a circuit diagram showing the configuration of a temperature compensation circuit when the load is a green LED.

Although the present invention may be variously modified and may have various embodiments, specific embodiments are illustrated in the drawings and described in detail, but the present invention is not intended to be limited to the specific embodiments, and It is to be understood that all changes, equivalents, and substitutes included in the spirit and scope are included.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Expressions such as the first and the second are merely a means for expressing the invention in more detail, and the invention is not limited to the above expression, and the singular encompasses the plural expression unless the context clearly indicates otherwise.

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

1 is an overall circuit diagram of a general-purpose temperature compensation constant current LED (Light Emitting Diode) signal lamp according to an embodiment of the present invention.

As shown in FIG. 1, the general-purpose temperature-compensated constant current LED signal lamp according to the embodiment of the present invention includes a power input unit 100, a rectifier 200, a power converter 300, an output unit 400, and a feedback circuit unit 500. It consists of a power supply and LED module 600, including. In the present invention, the operation of the power supply unit and the LED module 600, including the power input unit 100, rectifier 200, power converter 300, output unit 400, feedback circuit unit 500, etc. It is similar to the operation process as known in the Korean Utility Model No. 389959 (2005.07.07), which is known in the art related to the invention, and the detailed description thereof is briefly described and the voltage adjusting unit of the output unit 400 which is a feature of the present invention. A connection relationship according to the switch operation of the temperature compensation circuit 520 of the 420 and the feedback circuit unit 500 will be described in detail.

The power input unit 100 is composed of a fuse (F1), varistor (VA1), inductor (L3), capacitors (C11, C7) to report the power supply from the overvoltage and overcurrent and to reduce the noise terminal voltage It includes a line filter and supplies commercial power to the power supply.

The rectifier 200 rectifies the AC power input through the power input unit 100 into DC power. The rectifier 100 includes a bridge rectifier and a smoothing circuit.

The bridge rectifier is composed of four diodes (D4, D5, D6, D7), and outputs an AC power applied between the contacts of diodes (D4, D5) and the contacts of diodes (D6, D7) with the same pulsating current. do.

The smoothing circuit is a low pass filter composed of capacitors C3 and C4 and an inductor L2, and smoothes the pulsating current and outputs it as a DC current.

The power converter 300 may vary the DC power rectified by the rectifier 200 to a predetermined DC voltage in a pulse width modulation (PWM) manner. The power converter 300 includes a transformer 310, a PWM generator 320, a switching device Q1, and the like.

The transformer 310 receives a DC power output from the rectifier 200 and converts the input voltage into an output voltage having a predetermined voltage level.

The PWM generator 320 adjusts the duty ratio of the switching element Q1 according to an electrical signal input through the photodiode of the photocoupler 530 which will be described later. The PWM generator 320 generates a pulse according to the adjusted duty ratio and outputs the pulse to the gate of the switching element Q1. That is, the PWM generator 320 changes the output voltage of the power converter 300 by adjusting the duty ratio of the switching element Q1.

The switching element Q1 repeats an on / off operation according to a pulse output from the PWM generator 320.

The power conversion unit 300 controls the amount of current flowing into the primary winding of the transformer 310 by the DC current stabilized by the rectifier 200 through the on / off operation of the switching element (Q1) power The output voltage of the converter 300 is changed.

In other words, while the switching element Q1 is on, the rectified DC current flows into the primary winding of the transformer 310 and is charged in the primary winding. Meanwhile, while the switching element Q1 is off, the rectified DC current does not flow into the primary winding of the transformer 310, and transfers the current stored in the primary winding to the secondary winding of the transformer 310. do.

The output unit 400 includes a secondary rectifier 410 connected to the secondary winding of the transformer 310 and a voltage adjusting unit 420 for adjusting the output voltage of the output unit 400.

The secondary rectifier 410 rectifies, smoothes, and outputs the output of the transformer 310. The secondary rectifier 410 removes noise from the rectifier diode D1 for rectifying the alternating current output from the secondary winding of the transformer 310 with a positive current and the current output from the rectifier diode D1. Noise filters, and the like. Here, the noise filter is composed of capacitors C2 and C5 and inductor L1.

The voltage adjusting unit 420 adjusts the output voltage Vout of the output unit 400 according to the color of the LED to be turned on, and selects a fixed output voltage by adjusting a selection switch according to the LED type (color).

The voltage adjusting unit 420 includes a first selection switch TP1, a second selection switch TP2, and resistors R15, R20, and R32. The resistors R15 and R20 are connected in series to the output terminal of the secondary rectifier 410, and one end of the first selection switch TP1 is connected to the contacts of the two resistors R15 and R20. The other end of the first selection switch TP1 is connected to a contact of the second selection switch TP2 and the resistor R32. The second selection switch TP2 and the resistor R32 are connected to the two resistors R15 and R20 in parallel, respectively.

The voltage adjusting unit 420 adjusts on / off of the first and second selection switches TP1 and TP2 according to the load as shown in [Table 1]. The voltage adjusting unit 420 adjusts the minimum voltage and the maximum voltage range of the required voltage for each LED module (red, yellow, green) in the range of 20 to 80%. [Table 1] is a setting shown as an example to help understanding of the present invention is not limited to this, the on / off conditions of each switch can be changed according to the resistance value of the circuit connected to each switch and the characteristics of the LED, the load element. In it will be self-evident.

TP1 TP2 Load ON ON Red ON OFF - OFF ON - OFF OFF Green / Yellow

In addition, the output unit 400 includes a current detecting resistor R11 to detect a current supplied to the load.

The feedback circuit unit 500 includes a feedback controller 510, a temperature compensation circuit 520, a photo coupler 530, and the like.

The feedback control unit 510 amplifies a difference between the output voltage adjusted by the voltage adjusting unit 420 and the measured voltage and the reference voltage measured through the current detecting resistor R11 to input the photocoupler 530. Generate voltage.

The temperature compensation circuit 520 measures a change in the ambient temperature to maintain a constant light output that changes with the temperature change of the LED, and serves to compensate for the light output variation of the LED according to the measured ambient temperature change. .

The temperature compensation circuit 520 may have a resistance variable according to a change in ambient temperature, and transmit a voltage applied to the variable resistance to the feedback controller 510 as a reference voltage.

The temperature compensation circuit 520 includes a first resistor R28 and a second resistor R38 connected in series between a reference voltage terminal Vref of the feedback controller 510 and a predetermined input terminal, and the first resistor ( A second thermistor RT2 connected in parallel to R28, a first thermistor RT1 connected in parallel to the second resistor R38, and a contact between the first resistor R28 and the second resistor R38; The first switch SW1 connected between the second thermistor RT2, the second switch located between the contact of the first resistor R28 and the second resistor R38 and the first thermistor RT1. (SW2) is included.

Here, the first and second thermistors (RT1, RT2) is composed of NTC (Negative Temperature Coefficient Thermistor) element that the resistance value decreases as the temperature rises. In the present invention, the first and second thermistors are described with an NTC element as an example, but the design can be changed to a PTC (Positive Temperature Coefficient Thermistor) element whose resistance value increases with increasing temperature.

The temperature compensation circuit 520 adjusts the first and second switches SW1 and SW2 according to the color or temperature characteristics of the LED as shown in [Table 2].

SW1 SW2 LED color ON ON Yellow ON OFF Red OFF ON - OFF OFF Green

In addition, the feedback circuit unit 500 includes a photo coupler 530 connected to the PWM generator 320 and connected to an output terminal of the temperature compensation circuit 520. The photo coupler 530 includes a light emitting unit emitting light energy by varying light intensity according to the voltage output from the feedback control unit 510 and a light receiving unit converting light energy output from the light emitting unit into electrical energy. Since the technology of the photocoupler is a technique known in Korean Utility Model No. 389959 (2005.07.07), the detailed description thereof will be omitted.

That is, when the current supplied to the LED module 600 changes due to a change in the ambient temperature, the photocoupler 530 changes the brightness of the light emitting part according to the change in the ambient temperature and is output from the PWM generator 320. Determine the duty ratio of the pulses.

The LED module 600 is composed of a red LED module, a yellow LED module, a green LED module, and is driven by a DC current output from the output unit 400. The LED module 600 drives one of a red LED module, a yellow LED module, and a green LED module according to a control signal of a traffic light controller (not shown).

Hereinafter, the configuration of the temperature compensation circuit for each load will be described with reference to FIGS. 2 to 4.

Figure 2 is a circuit diagram showing the configuration of the temperature compensation circuit, when the load is a yellow LED, Figure 3 is a circuit diagram showing the configuration of the temperature compensation circuit, when the load is a red LED, Figure 4 is a green LED In this case, it is a circuit diagram showing the configuration of the temperature compensation circuit.

When the load is a yellow LED module, the first switch SW1 and the second switch SW2 are turned on, and as shown in FIG. 2, the temperature compensating circuit 520 has a reference voltage Vref and the feedback. The first resistor R28 and the second resistor R38 connected in series between one input terminal (+) of the controller 510 and the first resistor R28 and the second resistor R38 in parallel, respectively. The second thermistor RT2 and the first thermistor RT1 are connected.

The first and second thermistors RT1 and RT2 change the reference voltage by changing the resistance value according to the change of the ambient temperature.

For example, when the ambient temperature increases, the resistances of the first and second thermistors RT1 and RT2 decrease and the resistances of the first and second thermistors RT1 and RT2 decrease. The reference resistance is also reduced by reducing the overall resistances of R28 and R38 and the first and second thermistors RT1 and RT2.

As the reference voltage decreases, the adjusted output voltage of the output unit 400 and the difference voltage between the measured output voltage and the reference voltage increase, so that the brightness of the light emitting portion of the photocoupler 530 increases. That is, since the voltage value transferred to the PWM generator 320 through the light receiver of the photocoupler 530 increases, the PWM generator 320 increases the duty ratio to increase the output voltage of the power converter 300. . Therefore, the current supplied to the LED module 600 is increased.

On the other hand, when the ambient temperature decreases, the resistance values of the first and second thermistors RT1 and RT2 increase, and thus, the first and second resistors R28 and R38 and the first and second thermistors RT1 and RT2. The total resistance of increases and the reference voltage also increases. Therefore, when the reference voltage is increased, the difference between the measured output voltage and the output voltage adjusted by the voltage adjusting unit 420 and the reference voltage is reduced, so that the PWM generator 320 through the photocoupler 530. The voltage delivered to the circuit decreases. Therefore, the duty ratio of the pulse generated from the PWM generator 320 is reduced to reduce the output voltage of the power converter 300, and the current supplied to the LED module 600 is reduced.

When the load is a red LED module, as shown in [Table 2], since the first switch SW1 is turned on and the second switch SW2 is turned off, as shown in FIG. The two resistors R38 are connected in series, the second thermistor RT2 is connected in parallel with the first resistor R28, and one end thereof is connected to the contacts of the first resistor R28 and the second resistor R38. The other end is connected to the first resistor (R28).

Since the resistance of the second thermistor RT2 decreases as the ambient temperature increases, the overall resistance of the first resistor R28, the second resistor R38, and the second thermistor RT2 decreases and the reference voltage also decreases. do.

On the other hand, when the ambient temperature decreases, the resistance of the second thermistor RT2 increases, so that the overall resistance of the first resistor R28, the second resistor R38, and the second thermistor RT2 increases and the reference voltage is also increased. Increases.

When the load is a green LED, as shown in FIG. 4, a reference voltage based on a series resistance value of the first resistor R28 and the second resistor R38 is used without using a thermistor.

Referring to the operation of the LED traffic light having the above configuration as follows.

The LED traffic light turns on any one of the red, yellow, and green LED modules 600 under the control of a traffic light controller (not shown). That is, the on / off conditions of the first and second selection switches TP1 and TP2 of the voltage adjusting unit 420 are changed and set according to the LED module to be turned on, and the first and second switches of the temperature compensation circuit 520 ( The on / off conditions of SW1 and SW2 are also changed.

When AC power is applied through the power supply unit 100, the rectifier 200 rectifies the AC power and transfers the AC power to the power converter 300. The power converter 300 converts the output voltage rectified by the rectifier 200 into an output voltage having a predetermined magnitude in a pulse width modulation method. The output unit 400 rectifies the output voltage converted by the power converter 300 through the secondary rectifier 410 and converts the output voltage into DC power, and adjusts the voltage adjusting unit 420 according to the load. The converted DC power is adjusted to the output voltage for each load and output to the LED module 600.

The feedback circuit unit 500 compares the measured (measured) voltage output from the output unit 400 and the output voltage adjusted by the voltage adjusting unit 420 with a reference voltage, and converts the output voltage according to the comparison result into a photocoupler ( 530). The output voltage of the output unit 400 may not obtain a desired output value because the voltage of the LED varies depending on the ambient temperature.

In this case, the temperature compensation circuit 520 of the feedback circuit unit 500 decreases the resistance of the NCT element when the ambient temperature rises, and thus the reference voltage decreases. In addition, when the ambient temperature decreases, the resistance value of the NCT element increases, thereby increasing the reference voltage.

The reference voltage Verf changed according to the ambient temperature is input to the feedback control unit 510 of the feedback circuit unit 500, and the feedback control unit 510 is an actual measurement (voltage) voltage output from the output unit 400. And compare the output voltage adjusted by the voltage adjusting unit 420 with the reference voltage, and generate an output voltage according to the comparison result. The feedback controller 510 applies the output voltage generated according to the comparison result to the photo coupler 530.

The port coupler 530 accumulates electric charges in the capacitor C17 when the comparison output voltage reaches a predetermined value or more. The voltage accumulated in the capacitor C17 adjusts the duty ratio of the pulse signal generated by the PWM generator 320.

The PWM generator 320 controls the duty ratio of the pulse signal to vary the output voltage of the voltage supply device.

As described above, in the detailed description of the present invention has been described with respect to preferred embodiments of the present invention, various modifications can be made without departing from the scope of the present invention if one of ordinary skill in the art to which the present invention pertains. Of course.

Therefore, the scope of the present invention should not be limited to the embodiments described, but should be defined by the claims below and equivalents thereof.

100: power input unit
200: rectifier
300: power conversion unit
400: output unit
500: feedback circuit

Claims (10)

Rectifying unit 200 for rectifying the applied AC power to DC power,
A power conversion unit including a pulse width modulation circuit and converting a DC power output from the rectifying unit 200 into an AC voltage having a predetermined voltage level according to a pulse generated by the pulse width modulation circuit; 300),
The output unit 400 rectifies and outputs the AC voltage output from the power converter 300 into a DC voltage, and includes a voltage adjusting unit 420 for adjusting the output voltage according to the LED module 600 that is turned on. ,
Compare the output voltage and the reference voltage output through the output unit 400 and transfer the comparison result to the power converter 300 through the photocoupler 530 to adjust the duty ratio of the pulse, the ambient temperature A feedback circuit unit 500 including a temperature compensation circuit 520 for changing the reference voltage according to
The voltage adjusting unit 420 includes two resistors R15 and R20 connected in series to the output terminal of the output unit 400, a second selection switch TP2 connected in series to the output terminal and connected in parallel to the two resistors. A resistor R32, a first selection switch TP1 positioned between the contacts of the two resistors R15 and R20 and the contacts of the second selection switch TP2 and the resistor R32,
The temperature compensation circuit 520 may include first and second resistors R28 and R38 connected in series, and second and first thermistors RT2 and RT1 connected in parallel to the first and second resistors, respectively. And a first switch SW1 disposed between the contacts of the two resistors and the first thermistor, and a second switch SW2 disposed between the contacts of the two resistors and the second thermistor. Compensated constant current LED traffic light.
The method of claim 1, wherein the voltage adjusting unit,
If the LED module 600 is a red LED module, a general temperature compensation type constant current LED traffic light, characterized in that to turn on the first selection switch and the second selection switch.
The method of claim 1, wherein the voltage adjusting unit,
If the LED module 600 is a yellow or green LED module, the general temperature compensation type constant current LED traffic light, characterized in that the first selection switch and the second selection switch off.
The method of claim 1, wherein the temperature compensation circuit,
When the LED module 600 is a yellow LED module, the first switch and the second switch are turned on to connect the first resistor and the second resistor in series, and the second resistor is connected in parallel with the first resistor. A general-purpose temperature compensated constant current LED signal lamp comprising: connecting the first thermistor to a second resistor in parallel.
The method of claim 1, wherein the temperature compensation circuit,
If the LED module 600 is a red LED module, the first switch is turned on and the second switch is turned off to connect the first resistor and the second resistor in series, and the second thermistor is parallel to the first resistor. Universal temperature compensation constant current LED traffic light characterized in that the connection.
The method of claim 1, wherein the temperature compensation circuit,
If the LED module 600 is a green LED module, the first temperature and the second switch, the general temperature compensation type constant current LED signal lamp, characterized in that for connecting the first resistor and the second resistor in series.
The method of claim 1, wherein the first and second thermistor,
A general-purpose temperature-compensated constant current LED traffic light, characterized in that implemented by the NCT element resistance decreases with increasing ambient temperature.
The method of claim 1, wherein the temperature compensation circuit,
A general-purpose temperature-compensated constant current LED traffic light, characterized in that as the ambient temperature increases, the overall resistance decreases to decrease the reference voltage.
The method of claim 1, wherein the temperature compensation circuit,
A general-purpose temperature compensated constant current LED traffic light, characterized in that when the ambient temperature decreases, the overall resistance increases to increase the reference voltage.
The method of claim 8 or 9, wherein the power conversion unit,
When the reference voltage is reduced, the output voltage is increased, and if the reference voltage is increased, the general-purpose temperature compensation type constant current LED traffic light.

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