KR20120117078A - Apparatus of ac driving light emitting diode and method of thereof - Google Patents

Abstract

PURPOSE: A light emitting diode driving apparatus and method are provided to prevent lifetime reduction by blocking excess current to be supplied to a light emitting diode by excessive input voltage. CONSTITUTION: A power supply unit(10) rectifies an AC power source using a bridge rectifier and changes it into ripple. A detection unit(20) comprises overvoltage detection, overvoltage interdiction, and current limit. A controller comprises a constant-voltage power supply and power control. The constant-voltage power supply changes the ripple received from the power supply unit into direct current and supplies it to the detection unit. The overvoltage detection stops the operation of output control by operating the overvoltage interdiction. [Reference numerals] (10) Power supply unit; (11) Alternating current(AC) power source input; (12) Bridge rectification; (20) Detection unit; (21) Overvoltage detection; (23) Overvoltage blocking; (24) Converting current detection; (25) Current limit; (30) Controller; (32) Constant-voltage power supply; (33) Output control; (40) Light emitting diode group

Description

Light emitting diode driving apparatus operating by AC power and driving method thereof {Apparatus of AC driving Light Emitting Diode and Method of Thereof}

The present invention relates to a driving device of a light emitting diode (LED) for lighting and a driving method thereof. More particularly, the present invention relates to a light emitting diode driving apparatus using a pulse current as a power source without converting an alternating current into a direct current, and a driving method thereof.

A light emitting diode is a semiconductor that emits light when power is supplied, and low-power, high-efficiency lighting equipment using the same is rapidly spreading.

Switched-mode power supply (SMPS) is commonly used as a converter for converting alternating current (AC) to direct current (DC) for the purpose of supplying power to such a light emitting diode.

A smooth internal electrolytic capacitor having a high breakdown voltage and a high capacity is essentially used for a component of such an SMPS, and this electrolytic capacitor has a disadvantage in that its lifetime is limited. That is, the average use time of the electrolytic capacitor is shorter than 8,000 hours compared to the use time of the light emitting diode of 50,000 hours or more. It is limited by the lifetime of the electrolytic capacitor.

In addition, since the power factor is reduced when the electrolytic capacitor is used for smoothing purposes in the rectification step of the SMPS, in order to configure a converter having excellent power factor, there is a disadvantage in that a separate means for power factor correction must be provided.

Another problem that occurs when using the SMPS is that the size of the switching transformer constituting the SMPS is limited due to the large size, and because the generation of electromagnetic waves due to switching requires an additional means to prevent this.

As a result, we are developing an AC light emitting diode that uses AC power directly, but manufactures it by dividing the operating voltage range into 10V units according to the original characteristics of the light emitting diode that is sensitive to overvoltage (overcurrent). There is a situation. In order to solve this problem, there is a problem in that an additional measure against overvoltage and another additional means must be provided in order to prevent lighting shock due to overvoltage.

The present invention eliminates the use of SMPS by directly supplying AC power to the light emitting diode, thereby extending the life of the LED lighting, minimizing the need for a switching transformer constituting the SMPS, and minimizing light emission. A diode driving device and a driving method thereof are provided.

In addition, the present invention is to prevent the over-current is supplied to the light emitting diode to shorten the lifespan, and to drive the light-emitting diode driving device so that a smooth lighting can be realized by gradually increasing the current supplied to the light emitting diode at the beginning of the drive in a simple manner To provide a method.

The present invention, in order to solve the problems of the conventional LED driving device, a power supply unit for rectifying the AC (AC) power to the bridge rectifier and converting into a pulse current; A detector including an overvoltage detection, an overvoltage blocking, a variable current detection, and a current limiting; And a control unit including a constant voltage power source and an output control, wherein the constant voltage power source converts the pulse current input from the power source unit into direct current (DC) and supplies the detected voltage to the detection unit, wherein the overvoltage detection is performed. When the pulsed voltage input from the power supply unit exceeds the reference voltage, the overvoltage cutoff is activated to stop the output control operation, and the variable current detection is supplied through the voltage change amount of the pulsed power input received from the power supply unit through the output control. Provided is a light emitting diode driving apparatus configured to form an output voltage in proportion to the voltage change amount using a load current fluctuating voltage as a control signal.

In the light emitting diode driving apparatus, the detection unit includes a detection delay, wherein the detection delay transmits the DC voltage input from the constant voltage power supply to the overvoltage detection by delaying 0.01 seconds to 1 second. Provided is a diode drive.

In the light emitting diode driving apparatus, the control unit includes an output delay, and the output delay is performed for 0.1 to 5 seconds until the pulse voltage input from the power supply unit reaches the driving power of the LED group. Provided is a light emitting diode drive device which is gradually raised and supplied to the output control.

In the light emitting diode driving apparatus, the control unit includes an output delay, and the output delay is performed for 0.1 to 5 seconds until the pulse voltage input from the power supply unit reaches the driving power of the LED group. Provided is a light emitting diode drive device which is gradually raised and supplied to the output control.

In the light emitting diode driving apparatus, the detector includes a feedback means, and the feedback means is connected between the overvoltage detection and the overvoltage cutoff to prevent flickering when the light emitting diode blinks. Provided is a diode drive.

The present invention provides a light emitting diode module including a light emitting diode group connected to the pulse current output from the power supply unit, the input power is controlled by the output control.

The present invention, the power supply unit 1 step of converting AC power into a pulse power; The constant voltage power supply converts the pulse current power into direct current power and transfers the detected power to the detection unit; The overvoltage detection may include three steps of operating an overvoltage cutoff when an overvoltage exceeding a reference voltage is detected in the pulse power supply; The overvoltage cutoff is performed by controlling output control to cut off the overvoltage; The variable current detection may be performed by transmitting the voltage change amount of the pulse current supply and the load current fluctuation voltage supplied through the output control as a control signal to the current control; The current control step of controlling the output control to form an output voltage proportional to the voltage change amount; The output control step 7 of controlling the pulsed power supplied to the LED group from the power supply; It provides a light emitting diode driving method comprising a.

In the light emitting diode driving method, before the step 3, the detection delay includes a step of delaying the DC voltage input from the constant voltage power supply to the overvoltage detection by 0.01 seconds to 1 second. To provide.

In the light emitting diode driving method, before the step 7, the output delay is gradually increased for 0.1 to 5 seconds until the pulse voltage input from the power supply unit reaches the driving power of the LED group. It provides a light emitting diode driving method comprising the step of supplying to the output control.

The present invention provides a light emitting diode driving apparatus and a method of driving the same, by directly connecting an alternating current to the light emitting diode and not using a SMPS which is a DC voltage converter.

The effect of the present invention does not use an electrolytic capacitor for the purpose of DC smoothing, there is no shortening of the life of the light emitting diode lighting according to the limited use time of the electrolytic capacitor, manufacturing cost is low, there is an effect of reducing the heat generated by operating at low power. .

Another effect of the present invention is to prevent overcurrent from being supplied to the light emitting diode due to excessive input voltage, thereby preventing shortening of the life of the LED lighting, and smooth lighting during initial driving, as well as switching which is essential for the SMPS method. The present invention provides a light emitting diode driving apparatus for miniaturization and light weight by using a transformer and a driving method thereof.

1A is a block diagram illustrating Embodiment 1 of the present invention.
1B is a block diagram illustrating Embodiment 2 of the present invention.
Fig. 1C is a block diagram illustrating Embodiment 3 of the present invention.
1D is a block diagram illustrating Embodiment 4 of the present invention.
2 is a current waveform diagram of alternating current and pulse flow
3 is a configuration circuit of a light emitting diode group
4 is a drive initial current delay graph for smooth lighting
5 is a graph showing the power change characteristics of the LED and the characteristics of the present invention.
6 is a control output waveform diagram supplied to the LED group
7A is a flowchart for explaining the operating method and features of Embodiment 1 of the present invention.
7B is a flowchart for explaining an operating method and a feature of Embodiment 2 of the present invention.
7C is a flowchart for explaining an operating method and a feature of Embodiment 3 of the present invention.
7D is a flowchart for explaining the operating method and features of Embodiment 4 of the present invention.
8 is an exemplary circuit diagram implementing Embodiment 4 of the present invention.

The LED driving apparatus for lighting of the present invention includes a power supply unit 10, a detection unit 20, and a control unit 30.

1A is a block diagram illustrating Embodiment 1 of the present invention. The power supply unit 10 includes an AC power input 11 for receiving AC (AC) phase power and a bridge rectification 12 for converting the received AC power into a pulse current, and the detection unit 20 sets an input voltage. If the voltage is higher than the input voltage received from the overvoltage detection 21 for operating the overvoltage cutoff 23, the overvoltage blocking 23 for interrupting the operation of the output control 33 by the signal of the overvoltage detection 21, and the power supply unit 10. A variable current detection 24 for detecting a voltage change and a load current change of the LED group 40 together with a current limit 25 acting on the detected signal. The control unit 30 includes a detection unit ( 20 includes a constant voltage power supply 32 for supplying a standard voltage to the 20 and an output control 33 for controlling a current supplied to the LED group 40 as an output signal of the detector 20.

A first embodiment of the present invention will be described in detail with reference to the flowchart of FIG. 7A. When AC power is input 11, it is converted into pulse current by bridge rectification 12 to form E1, and is supplied to the overvoltage detection 21, the variable current detection 24, and the output control 33 by dividing and supplying the light emitting diode group ( Drive 40). At this time, the overvoltage detection 21 turns off the output control 33 by operating the overvoltage blocking 23 when the E1 voltage is higher than the voltage set in the overvoltage detection 21. After the LED group 40 is normally driven, the change amount of E1 and the change amount of E2 of the output control 33 are detected by the variable current detection 24 to operate the current limit 25 to average the light emitting diode group 40. Ensure that a constant current can be supplied.

The AC power input 11 of the power supply unit 10 is equipped with a fuse having a rated capacity, and the AC current through the fuse is supplied in the waveform of the point of Fig. 2A, and this current is supplied by the bridge rectification 12 as shown in Fig. 2B. As it is converted into a pulse wave of the waveform, the pulse voltage varies with the AC input voltage.

The use of a stop other than the bridge rectification 12 is not impossible, but a high efficiency light emitting diode driving device having a low loss at the time of pulse flow conversion can be provided due to the above configuration.

In the overvoltage detection 21 of the detection unit 20, when the threshold voltage is set and exceeds the set voltage, the overvoltage blocking 23 is operated to output control 33 of the controller 30 in the overvoltage blocking 23 as shown in the graph of FIG. 5. ), And the variable current detection 24 outputs a signal proportional to the amount of change in the pulse current of the output of the bridge rectification 12 and the amount of current change in the output control 33 which changes according to the load condition. The current limit 25 acts on the signal to control the output control 33 to drive the LED group 40 with the control characteristics of the present invention as shown in the graph of FIG. The waveform of the control output supplied to the LED group 40 according to the present embodiment is shown in FIG.

By turning off the output control 33 when the overvoltage is detected through the overvoltage detection 21 and the overvoltage blocking 23, the overvoltage is prevented from being transmitted to the LED group 40, and the variable current detection 24 is performed. And controlling the output control 33 through the current limit 25 so that only a current having a proper capacity flows through the LED group 40, thereby preventing the lifespan of the light emitting diodes sensitive to overvoltage.

The constant voltage power supply 32 of the control unit 30 converts the pulse current into a direct current to form and supply an operating voltage and a standard voltage of the detection unit 20. Since the power supply of the detection unit 20 must be a full direct current to supply a complete direct current output from the constant voltage power supply 32 to the detection unit 20.

In the LED group 40, each LED is connected in series as shown in FIG. 3, and each LED is driven by dividing an output voltage. The power supplied to the LED group 40 is a pulse current power output from the power supply unit 10.

Fig. 1B is a block diagram illustrating Embodiment 2 of the present invention. The power supply unit 10 includes an AC power input 11 for receiving AC (AC) phase power and a bridge rectification 12 for converting the received AC power into a pulse current, and the detection unit 20 when the initial power is applied. Detection delay 22 for preventing malfunction of overvoltage detection 21, output control 33 by signals of overvoltage detection 21 and overvoltage detection 21 for activating overvoltage cut-off 23 when the input voltage is above the set voltage ), An overvoltage cutoff 23 for blocking the operation of the control panel, a fluctuation current detection 24 for detecting a change in the input voltage received from the power supply unit 10 and a change in the load current of the LED group 40, and a signal detected accordingly It includes a current limiting 25 to operate, the control unit 30 is supplied to the LED group 40 as an output signal of the constant voltage power supply 32 and the detection unit 20 for supplying a standard voltage to the detection unit 20 And an output control 33 for controlling the current to be made.

A second embodiment of the present invention will be described in detail with reference to the flowchart of FIG. 7B. When AC power is input 11, it is converted into pulse current by bridge rectification 12 to form E1, and is supplied to the overvoltage detection 21, the variable current detection 24, and the output control 33 by dividing and supplying the light emitting diode group ( Drive 40). At this time, the overvoltage detection 21 operates after 0.2 seconds has elapsed under the action of the detection delay 22, and when the E1 voltage is higher than the voltage set in the overvoltage detection 21, the overvoltage blocking 23 is activated to operate the output control 33. Turn off. After the LED group 40 is normally driven, the change amount of E1 and the change amount of E2 of the output control 33 are detected by the variable current detection 24 to operate the current limit 25 to average the light emitting diode group 40. Ensure that a constant current can be supplied.

The detection delay 22 is a means for preventing the malfunction of the overvoltage detection step 21 when the initial power is applied, so that the overvoltage detection 21 can be performed after 0.2 seconds has elapsed. The detection delay time of 0.2 seconds is an exemplary meaning, and any time can be used as long as it can prevent the malfunction of the overvoltage detection 21, and the scope of the patent is not limited thereto.

Fig. 1C is a block diagram illustrating Embodiment 3 of the present invention. The power supply unit 10 includes an AC power input 11 for receiving AC (AC) phase power and a bridge rectification 12 for converting the received AC power into a pulse current, and the detection unit 20 sets an input voltage. If the voltage is higher than the input voltage received from the overvoltage detection 21 for operating the overvoltage cutoff 23, the overvoltage blocking 23 for interrupting the operation of the output control 33 by the signal of the overvoltage detection 21, and the power supply unit 10. A variable current detection 24 for detecting a change in voltage and a load current change of the LED group 40 together with a current limit 25 acting on the detected signal, and the controller 30 is initially driven. Output delay 21 for smooth lighting during operation, constant voltage power supply 32 for supplying a standard voltage to the detection unit 20 and output control for controlling the current supplied to the LED group 40 as an output signal of the detection unit 20 (33).

A third embodiment of the present invention will be described in detail with reference to the flowchart of FIG. 7C. When AC power is input 11, it is converted into a pulse current by bridge rectification 12 to form E1, dividedly supplied to overvoltage detection 21, variable current detection 24 and output control 33, and output for 1 second. The drive current of the output control 33 is gradually raised by the delay 31 to smoothly drive the LED group 40. At this time, the overvoltage detection 21 turns off the output control 33 by operating the overvoltage blocking 23 when the E1 voltage is higher than the voltage set in the overvoltage detection 21. After the LED group 40 is normally driven, the change amount of E1 and the change amount of E2 of the output control 33 are detected by the variable current detection 24 to operate the current limit 25 to average the light emitting diode group 40. Ensure that a constant current can be supplied.

The output delay 31 controls the driving of the output control 33 as a means for smoothly turning on the initial driving, for example, by gradually increasing it for a time of, for example, 1 second until an appropriate power is reached as shown in FIG. . The output delay 31 serves to prevent the lighting shock by supplying power to the LED group 40 gradually increasing during the output delay time. The above-described output delay time of 1 second is merely an exemplary meaning and may be any time as long as it is possible to prevent the lighting shock, and the scope of the patent is not limited thereto.

Fig. 1D is a block diagram illustrating Embodiment 4 of the present invention. The power supply unit 10 includes an AC power input 11 for receiving AC (AC) phase power and a bridge rectification 12 for converting the received AC power into a pulse current, and the detection unit 20 when the initial power is applied. Detection delay 22 for preventing malfunction of overvoltage detection 21, output control 33 by signals of overvoltage detection 21 and overvoltage detection 21 for activating overvoltage cut-off 23 when the input voltage is above the set voltage ), An overvoltage cutoff 23 for blocking the operation of the control panel, a fluctuation current detection 24 for detecting a change in the input voltage received from the power supply unit 10 and a change in the load current of the LED group 40, and a signal detected accordingly It includes a current limiting 25 to operate, the control unit 30 is the output delay 21 for smooth lighting during the initial driving, the constant voltage power supply 32 for supplying a standard voltage to the detector 20 and the detector 20 Current supplied to the LED group 40 as an output signal of An output control 33 for.

A fourth embodiment of the present invention will be described in detail with reference to the flowchart of FIG. 7D. When AC power is input 11, it is converted into a pulse current by bridge rectification 12 to form E1, dividedly supplied to overvoltage detection 21, variable current detection 24 and output control 33, and output for 1 second. The drive current of the output control 33 is gradually raised by the delay 31 to smoothly drive the LED group 40. At this time, the overvoltage detection 21 operates after 0.2 seconds has elapsed under the action of the detection delay 22, and when the E1 voltage is higher than the voltage set in the overvoltage detection 21, the overvoltage blocking 23 is activated to operate the output control 33. Turn off. After the LED group 40 is normally driven, the change amount of E1 and the change amount of E2 of the output control 33 are detected by the variable current detection 24 to operate the current limit 25 to average the light emitting diode group 40. Ensure that a constant current can be supplied.

Embodiment 4 is a preferred embodiment of the present invention is equipped with both the detection delay 22 and the output delay 31 to prevent the malfunction of the over-voltage detection 21 at the initial lighting, and to shorten the life of the light emitting diode due to the lighting shock prevent.

A fourth embodiment of the present invention will be described in detail with reference to the circuit diagram of FIG. The circuit diagram of FIG. 8 is merely an example of a method of implementing the fourth embodiment, and can be modified to a configuration of circuits known to those skilled in the art, and the scope of the present invention is not limited to the configuration described in the circuit diagram of FIG. It is clear.

The AC power input 11 constituting the power supply unit 10 inputs an AC current through the fuse F1, and the AC current is converted into a pulse current by the bridge diode BD1, and the pulse current is converted into the LED group 40. ), The output delay 31, the constant voltage power supply 32, the overvoltage detection 21, the operating current of the variable current detection (24).

As a means of the output delay 31 constituting the control unit 30 is composed of R9, R10, C2, Q3 and R8 is delayed in accordance with the time constant set by R9 and C2, the current through R8 is output control By gradually increasing the bias of Q6 in (33), the LED group 40 is softly lit, and constitutes R11, ZD, R12, Q4 and C3 as a means of the constant voltage power supply 32, and the rating of the constant voltage diode ZD. The operating voltage and the standard voltage of the detector 20 are formed by the voltage, and as the means of the output control 33, Q6, Q7, and R19 are connected to the two transistors, which are connected to the multi-arlington to increase the efficiency and to change the load condition. The changing drop voltage of R19 is supplied to the input signal of the variable current detection 20 through D2.

The overvoltage detection 21 constituting the detection unit 20 is composed of R1, R2, R3, R5, R6, and OP1, and the overvoltage blocking voltage is set as the voltage setting of the negative input (-) of the OP1. In other words, the divided voltage between R1 and R2 becomes the set voltage. R3 is a feedback means for preventing flickering when OP1 flickers (ON, OFF), the detection delay 22 is composed of R7, C1 and Q1 to detect the overvoltage when the initial power is applied (21) For example, delay the action of 0.2 seconds. The time is set by the time constant of R7 and C1, and when the power is applied, the collector current of Q1 rises during the delay time, so the negative input (-) voltage of OP1 becomes positive input (+). As it gets higher, OP1 is turned off during the time defined by R7 and C1. The overvoltage cutoff 23 is composed of R4 and Q2. When the overvoltage detection 21 detects an overvoltage after the LED group 40 is normally turned on, the output of the OP1 is turned ON and the current through R4 is Q2. Is turned on to lower the bias voltage of Q6 to turn the output control 33 off. The variable current detection 24 is composed of D1, D2, R13, R14, R15, R16 and OP2, and the average power of the LED group 40 sets the negative input (-) voltage of OP2, and the positive input of OP2 ( The control signal is a pulse current voltage that determines the supply voltage change supplied through D1 and a load current change voltage supplied through D2 as a control signal, and OP2 forms an output voltage proportional to the change amount, and the current limit (25) The constituents R17, R18, and Q5 control the bias current of Q6 by controlling the collector current of Q5 according to the output of OP2, thereby supplying an average current to the LED group 40. FIG.

10: power supply
11: AC power input
12: bridge rectification
20: detector
21: overvoltage detection
22: detection delay
23: overvoltage cutoff
24: variable current detection
25: current limit
30:
31: output delay
32: constant voltage power supply
33: output control
40: light emitting diode group

Claims (10)

A power supply unit rectifying AC power into a bridge rectifier and converting the AC power into a pulse current;
A detector including an overvoltage detection, an overvoltage blocking, a variable current detection, and a current limiting; And
A light emitting diode driving apparatus comprising: a control unit including a constant voltage power supply and an output control.
The constant voltage power is supplied to the detection unit by converting the pulse current input from the power supply unit to direct current (DC),
The overvoltage detection stops the operation of the output control by activating the overvoltage cutoff when the pulsed voltage input from the power supply unit exceeds the reference voltage,
The variable current detection is a light emitting diode driving apparatus for forming an output voltage in proportion to the voltage change amount by using the voltage change amount of the pulse current power input from the power supply unit and the load current change voltage supplied through the output control as a control signal.
The method of claim 1,
The detector includes a detection delay, wherein the detection delay delays the DC voltage input from the constant voltage power supply to the overvoltage detection by 0.01 seconds to 1 second.
The method of claim 1,
The control unit includes an output delay, wherein the output delay is supplied to the output control by gradually increasing the pulse current voltage input from the power supply unit for 0.1 to 5 seconds until reaching the driving power of the LED group. A light emitting diode drive device.
The method of claim 2,
The control unit includes an output delay, wherein the output delay is supplied to the output control by gradually increasing the pulse current voltage input from the power supply unit for 0.1 to 5 seconds until reaching the driving power of the LED group. A light emitting diode drive device.
The method of claim 4, wherein
The detector includes a feedback means, wherein the feedback means is connected between the overvoltage detection and the overvoltage cutoff to prevent the LED from flickering when the LED blinks.
The method according to any one of claims 1 to 5,
And a light emitting diode group connected to the pulse power output from the power supply unit, the input power being controlled by the output control.
The power supply unit converts AC power into pulse power;
The constant voltage power supply converts the pulse current power into direct current power and transfers the detected power to the detection unit;
The overvoltage detection may include three steps of operating an overvoltage cutoff when an overvoltage exceeding a reference voltage is detected in the pulse power supply;
The overvoltage cutoff is performed by controlling output control to cut off the overvoltage;
The variable current detection may be performed by transmitting the voltage change amount of the pulse current supply and the load current fluctuation voltage supplied through the output control as a control signal to the current control;
The current control step of controlling the output control to form an output voltage proportional to the voltage change amount;
The output control step 7 of controlling the pulsed power supplied to the LED group from the power supply; LED driving method comprising a.
8. The method of claim 7,
Before the step 3, the detection delay comprises the step of transmitting the DC voltage received from the constant voltage power supply to the overvoltage detection by delaying 0.01 seconds to 1 second.
8. The method of claim 7,
Before the seventh step, the output delay includes the step of gradually increasing the pulse current voltage input from the power supply unit for 0.1 to 5 seconds until the driving power of the LED group to supply to the output control Driving method.
The method of claim 8,
Before the seventh step, the output delay includes the step of gradually increasing the pulse current voltage input from the power supply unit for 0.1 to 5 seconds until the driving power of the LED group to supply to the output control Driving method.

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