KR100775066B1 - Guidance light controller - Google Patents

Abstract

A guiding light controller is provided to detect a minute current by using one chip semiconductor device as a device for detecting a current provided to drive a light emitting diode lamp. A guiding light controller includes a power regulator(110), a constant voltage supply unit(120), a current detection unit(130), first and second voltage detection units(140,150), a controller(160), an LED(Light Emitting Diode) driver(170), and a constant rectifier(180). The power regulator adjusts an input voltage to drive the light emitting diode lamp to a wanted power. The constant voltage supply unit converts and supplies the power adjusted by the power regulator into a constant voltage. The current detection unit detects a current of the voltage inputted to the power regulator as a virtual effective value, amplifies the detected virtual effective value to a predetermined level and converts the amplified value into a DC value. The first and second voltage detectors detect a level of positive and negative constant voltages supplied by the constant voltage supply unit. The controller controls a driving of the LED lamp by the detection voltage of the first and second voltage detectors, and generates a brightness adjustment control signal which automatically adjusts the brightness of the LED based on the current level detected by the current detection unit. The LED driver drives the LED in response to the brightness adjustment control signal generated from the controller. The constant rectifier supplies the constant current to the LED lamp by adjusting the current provided to the LED lamp in case of driving the LED lamp by the LED driver.

Description

Induction light controller {Guidance light controller}

The present invention implements an induction lamp installed in order to inform the position of the induction path to the aircraft traveling on the ground with a light emitting diode (LED) and a device for detecting a current when lighting by using a separate one chip (chip) semiconductor element The present invention relates to an induction lamp control device that enables detection of a current and controls a light emitting diode step by step according to the detected current level.

In general, a variety of runway lights (guide lights) are installed for the safe operation of the aircraft, first, the exposed guide lights, buried guide lights and buried centerline guide lights installed on the airport runway to guide the aircraft on a certain route on the airport runway at night, The aviation law prevents collisions of aircraft at night, such as high buildings such as buildings, steel towers, transmission towers, and structures in the mountains, and prevents collisions of aircrafts operating at night, and remotely controls lights to ensure safety of aircraft as well as safety of high structures. maintain

To do it.

As such, there are many lights on the runway, and there are international standards that are predetermined according to the installation location and use, and the specs and structure of the lights are basically determined according to the standard. Since the installed lighting should be displayed to distinguish the runway at night as well as in bad weather or heavy fog, the brightness of the lighting is very bright, about 5,000 to 30,000cd, and the power consumption is about 100 to 200W.

These lamps are fully exposed to direct sunlight and geothermal heat in summer and rise to very high temperatures, and in winter they have very low temperatures due to outside air, so they must withstand various environments and maintain high brightness. Although the bulbs are mainly used, these neon bulbs do not last as long as about 200 hours due to the high brightness and the external environment.Therefore, there are problems such as checking the lamps regularly and replacing the broken lamps immediately.

Many light emitting diodes were used as lamps.

A power supply device such as a lighting device using a light emitting diode may step down an AC input voltage to a desired voltage through a transformer, and pass a desired amount of voltage through a diode or a bridge circuit, and then, through a capacitor or stabilization device, a target DC voltage may be applied. It is difficult to control the brightness of LED bulbs by outputting them, but it is difficult to control the brightness of LED bulbs.

The present invention has been proposed in response to the above requirements,

SUMMARY OF THE INVENTION An object of the present invention is to provide an induction lamp control device capable of detecting a fine current by using a separate 1Chip semiconductor element as a device for detecting a current supplied for driving a light emitting diode lamp.

Another object of the present invention is to provide an induction light control device for automatically controlling a light emitting diode step by step according to a detected current level.

"Induction light control device" according to the present invention for achieving the above object,

A power regulator for regulating the input voltage to drive the light emitting diode lamp;

A constant voltage generator for supplying power regulated by the power regulator to a constant voltage;

A current detector for detecting a current of a voltage input to the power regulator as an RMS value, amplifying the detected effective value to a predetermined level, and converting the current to a DC;

First and second voltage detectors for detecting levels of positive and negative constant voltages produced by the constant voltage regulator, respectively;

A controller which is a main control unit (MCU) for controlling the driving of the light emitting diode lamp by the detected voltages of the first and second voltage detectors, and automatically adjusting the brightness adjusting step of the light emitting diode according to the current level detected by the current detector. Wow;

A light emitting diode (LED) driver for driving the light emitting diode in response to the step-by-step brightness control signal output from the controller;

When driving the light emitting diode lamp by the light emitting diode driver is characterized in that it comprises a constant current to supply to the light emitting diode lamp by controlling the current supplied to the light emitting diode lamp to a constant current.

In addition, the current detection unit,

A current detecting element for detecting a current of a voltage input to the power regulator as an RMS value;

An effective value amplifier which amplifies the effective value detected by the current detecting element to a predetermined level;

A voltage converter converting the voltage amplified by the effective value amplifier into a DC voltage corresponding thereto;

And a DC amplifier for amplifying the DC voltage converted by the voltage converter to a set level and providing the controller with a detected current value.

The voltage converter includes an effective value-direct current converter for converting an effective value amplified by the effective value amplifier into a DC voltage corresponding thereto, wherein the current detection unit comprises an effective value amplifier unit, a voltage converter, and a DC amplifier to detect a fine current. The module is implemented by modularizing the chip, and the controller controls the light emitting diode lamp to any one of five levels of brightness levels which are preset according to the detected current value.

According to the present invention, by detecting a device for detecting a current supplied to drive a light emitting diode lamp by using a separate 1Chip semiconductor element, there is an advantage that a fine current can also be detected.

In addition, since the microcurrent can be detected, there is an advantage that the precise brightness can be adjusted when the brightness of the light emitting diode is adjusted.

In addition, there is an advantage that the LED can be automatically controlled step by step according to the detected current level.

Hereinafter, described in detail with reference to the accompanying drawings a preferred embodiment of the present invention. If it is determined that the detailed description of the known function or configuration related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a block diagram of an induction light control apparatus according to the present invention, Figure 2 is a detailed circuit diagram showing an embodiment of FIG.

As shown in the drawing, the induction lamp control apparatus according to the present invention includes a power regulator 110, a constant voltage regulator 120, a current detector 130, first and second voltage detectors 140, 150, and a controller ( MCU) 160, a light emitting diode driver 170, a constant current device 180, a reset unit 190, and an LED lamp unit 200.

The power regulator 110 is to adjust the input voltage to drive the light emitting diode (LED) lamp to the required power, the reactor (RV1), resistor (R25), capacitor (C28 ~ C30), Zener diode for power adjustment (ZD2, ZD3) and a triac Q2 connected to one end of the zener diode ZD3 to adjust the input voltage to the required power.

The constant voltage regulator 120 supplies the power regulated by the power regulator 110 to a constant voltage, and supplies diodes D5, D6, D3, and D4, and capacitors C3, C18, C9, C23, C24, C11, and C20. , C8, C16, C17, C19, C27, C21, C12, C10), and DC-DC converters 121, 122.

The current detector 130 detects a current of the voltage input to the power regulator 110 as an RMS value, amplifies the effective value to a predetermined level, and converts the current into a DC, which is input to the power regulator. A current detection element 131 for detecting a current of a voltage as an RMS value, an effective value amplifier 132 for amplifying the effective value detected by the current detection element 131 to a predetermined level, and the effective value amplifier 132 A voltage converter 133 for converting the voltage amplified by the DC voltage to a corresponding DC voltage, and amplifying the DC voltage converted by the voltage converter 133 to a set level to provide the detected current value to the controller 160. DC amplifier 134 is included.

The first voltage detector 140 detects the level of the positive electrostatic voltage (+6.2 V) generated by the constant voltage regulator 120, and includes a capacitor C6, a resistor R10, and a voltage. Distribution resistors R13 and R14.

The second voltage detector 150 detects the level of the negative constant voltage (-6.2 V) made by the constant voltage regulator 120. The second voltage detector 150 includes the capacitor C7, the resistor R15, and the voltage distribution. And the resistors R12 and R11.

The controller 160 controls the driving of the light emitting diode lamps by the detected voltages of the first and second voltage detectors 140 and 150, and adjusts the brightness of the light emitting diodes according to the current level detected by the current detector 130. As a main control unit (MCU) for automatically adjusting the steps, it is preferable that a memory for storing a program and control values for brightness adjustment is provided therein.

The LED driver 170 drives the LED in response to the step-by-step brightness control signal output from the controller 160. An amplifier (U3) for amplifying the brightness control signal generated by the controller 160, Field effect transistor (FET) Q1 which performs switching operation to adjust brightness according to the output signal of amplifier U3, and several separated resistors of low capacitance to solve the heat problem caused by the use of high capacitance. (R1 _ R5).

When the constant current device 180 drives the light emitting diode lamp coupled to the LED lamp unit 200 by the light emitting diode driver 170, the constant current controller 180 adjusts the current supplied to the light emitting diode lamp to provide a constant current to the light emitting diode lamp. It performs the function.

The reset unit 190 is for automatically resetting the device when the driving voltage of the controller 160 is lower than the set value. The reset unit 190 includes a reset circuit U2, a resistor R6, and a capacitor C2.

In the induction lamp control apparatus according to the present invention configured as described above, the voltage supplied to the light emitting diode driving power through the secondary coil (L1, L2) of the transformer at the front end (CCR) is the reactor (RV1) of the power regulator 110, After the resistor R25 and the capacitors C28, C29 and C30, the triac Q2 is controlled by the adjustment of the zener diodes ZD2 and ZD3 so that the input voltage is adjusted to the power required and the voltage regulator 120 is the rear stage. Is supplied.

The constant voltage generator 120 receives a positive constant voltage (+6.2) from a plurality of diodes D5, D6, D3, and D4 and capacitors C3, C18, C9, C23, C24, C11, C20, C8, and C16. It is made of V) and supplied, and it is made of negative constant voltage (-6.2V). The DC-DC converter 121 lowers the positive constant voltage (+ 6.2V) again to produce a predetermined DC voltage (+ 2.5V), and outputs the DC-DC converter 122 to the negative constant voltage (−). 6.2V) is again dropped to output a predetermined DC voltage (-2.5V).

The reset unit 190 compares a predetermined DC voltage (+ 2.5V) generated by the DC-DC converter 121 in the reset circuit U2 with a preset voltage, and when the DC voltage becomes lower than the preset voltage. A reset signal for resetting the device is generated and communicated to the controller 160.

When the reset signal is transmitted by the reset unit 190 while the device is in operation, the controller 160 unconditionally initializes the device. This is to prevent malfunctions that may occur due to lack of voltage in advance.

Meanwhile, the first voltage detector 140 receives a positive constant voltage (+ 6.2V) generated by the constant voltage regulator 120 through the capacitor C6 and the resistor R10 and receives the voltage division resistors R13 and R14. The positive voltage detection value is distributed to the controller 160 as a positive constant voltage detection value, and the second voltage detector 150 is also connected to the negative voltage generated by the voltage regulator 120 through the capacitor C7 and the resistor R15. -6.2V) is input, distributed to the voltage divider resistors R12 and R11, and transferred to the controller 160 as a negative constant voltage detection value.

The controller 160 compares the positive constant voltage and the negative constant voltage detected by the first and second voltage detectors 140 and 150 with the positive constant voltage reference value and the negative constant voltage reference value previously stored in the internal memory, respectively. In case of abnormality of positive and negative constant voltages, the induction light control device is immediately stopped. This is also to prevent the malfunction of the device or the damage of the circuit which may be caused by abnormal constant voltage.

As is well known, when the driving voltage is supplied to the power regulator 110, the current detector 130 detects a current of the voltage supplied from the current detecting element 131. The detection current is an effective value RMS. In other words, assuming that the input voltage is a sine wave between, the RMS values represent effective values varying between + and-as one aggregate value. In general, sinusoidal sinusoids oscillate with the same period in the + region and-region. Speaking of the energy concept, we need to find the area of sinusoids. So the concept introduced is RMS. If you take the square of the sine wave, the values in the-region are also changed to the + region, and the root is taken and averaged. In conclusion, if only the peak value of the vibration is measured, only the force of the peak part is measured, and thus there is a limit in measuring the actual complex vibration. Therefore, the detection of the fine current is impossible in the present invention. It becomes possible.

The effective value of the detected current is amplified to the predetermined level by the effective value amplifier U9 of the effective value amplifier 132 and input to the voltage converter 133. This is to prevent signal loss occurring during signal processing at the later stage.

The RMS-to-DC converter U8 of the voltage converter 133 converts the input RMS value into a DC voltage corresponding thereto and transmits the converted RMS value to the DC amplifier 134 (U7). Here, the effective value is an AC component, so it is converted to DC.

The DC amplifier 134 (U7) amplifies the DC voltage input according to the time constant set by the resistor R17 and the capacitors C13 and C14 to a predetermined level and provides it to the controller 160 as a current detection value.

Here, the effective value amplifier 131, the voltage converter 133, and the DC amplifier 134 of the current detector 130 are implemented as one semiconductor chip, and are separated from other circuits.

The current detection unit 130 is implemented as a single chip, by detecting the current to the power supply in the process of the effective value detection method, amplifying it, and converting the amplified effective value into a DC voltage and amplifying it back to a predetermined level. It is possible to detect a fine current.

The controller 160 compares the current detection value with a reference brightness control level for brightness adjustment in steps stored in the internal memory in advance, and determines a current level, that is, a light emitting diode brightness adjustment level. In this case, the brightness control level can be implemented in various stages, but it is preferable to set the level to 5 levels as a result of combining the realization, the implementation, and the controllability.

Existing devices applying the light emitting diode to the induction lamp have a disadvantage in that it is impossible to detect a microcurrent (low current), so that the accuracy of brightness control of the light emitting diode is deteriorated. ) Can be accurately detected, and thus accuracy of brightness control of the light emitting diode can be obtained.

In other words, the light emitting diode is affected by the brightness of its current characteristics, and if the supply current is not accurately detected, it becomes difficult to adjust the level in stages. Therefore, in the present invention, even the minute current is accurately detected, thereby achieving optimum accuracy in controlling the brightness of the light emitting diodes.

When the light emitting diode brightness level for the detection current is determined, the controller 160 extracts a control value for brightness adjustment from the memory and generates a brightness control signal.

The brightness control signal thus generated is amplified to a predetermined level by the amplifier U3 of the light emitting diode driver 1170, and the amplified signal is input to the control terminal of the field effect transistor Q1 to be applied to the field effect transistor Q1. To control the switching.

The level for brightness adjustment is set according to the switching of the field effect transistor Q1, and the constant current generator 180 adjusts the current of the LED driving voltage supplied to the LED lamp unit 200 according to the set brightness adjustment level. The brightness of the light emitting diode lamp is controlled by adjusting the current.

Another feature of the present invention is to control the lamp of the light emitting diode by the constant current method. The light emitting diode is usually controlled by a constant voltage method. In the present invention, by using the constant current control method, it is possible to optimize the brightness adjustment step by step. In addition, since the internal implementation circuit for the constant current control may be applied to a known constant current control circuit known in the art as it is, a detailed description thereof will be omitted.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a block diagram showing the configuration of an induction light control apparatus according to the present invention.

Figure 2 is a circuit diagram showing the configuration of the induction light control apparatus according to the present invention.

<Explanation of symbols for the main parts of the drawings>

110... Power regulator

120... Constant voltage

130... Current detector

131... Current detection element

132... Effective value amplifier

133... Voltage converter

134... DC amplifier

160... Controller

170... LED Driver

180... Constant current

Claims (5)

An apparatus for controlling an induction lamp to which a light emitting diode lamp is applied, A power regulator (110) for adjusting a voltage input to drive the light emitting diode lamp to a required power; A constant voltage regulator 120 for supplying the power adjusted by the power regulator 110 to a constant voltage; A current detector (130) for detecting a current of the voltage input to the power regulator (110) as an RMS value, amplifying the detected effective value to a predetermined level, and converting the current to a DC; First and second voltage detectors (140) (150) for detecting the levels of positive and negative constant voltages produced by the constant voltage generator (120), respectively; Controlling the driving of the light emitting diode lamps by the detected voltages of the first and second voltage detectors 140 and 150, and automatically adjusting the brightness of the light emitting diodes according to the current level detected by the current detector 130. A controller 160 which is a main control unit (MCU) for generating a brightness control signal; A light emitting diode (LED) driver 170 for driving the light emitting diode in response to a stepwise brightness control signal generated by the controller 160; When the light emitting diode lamp is driven by the light emitting diode driver 170, an induction lamp comprising a constant current device 180 for supplying the light emitting diode lamp by adjusting the current supplied to the light emitting diode lamp to a constant current. controller. The method of claim 1, wherein the current detection unit, A current detection element (131) for detecting a current of a voltage input to the power regulator (110) as an RMS value; An effective value amplifier 132 for amplifying the effective value detected by the current detection element 131 to a predetermined level; A voltage converter 133 for converting the voltage amplified by the effective value amplifier 132 into a DC voltage corresponding thereto; And a direct current amplifier (134) for amplifying the DC voltage converted by the voltage converter (133) to a set level and providing the detected current value to the controller (160). The inductive lamp control apparatus according to claim 2, wherein the voltage converter 133 includes an effective value-DC converter U8 for converting the effective value amplified by the effective value amplifier 132 into a DC voltage corresponding thereto. . The method of claim 1 or 2, wherein the current detection unit is characterized in that the effective amplifier unit 132, the voltage converter 133 and the DC amplifier 134 is modularized into a single chip to enable the detection of fine current. Induction Light Controls. The apparatus of claim 1, wherein the controller (160) controls the light emitting diode lamp to any one of five levels of brightness levels preset in accordance with the detected current value.

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