KR101504279B1 - Drive circuit of Light-Emitting Diode - Google Patents

Abstract

A light emitting diode driving circuit according to an embodiment of the present invention includes an input unit for receiving an AC voltage from the outside, a rectifying unit for rectifying the AC voltage supplied from the input unit, a smoothing unit for smoothing the AC voltage rectified by the rectifying unit, A first lamp disposed in series and operating in a turn-on or turn-off state by being supplied with an AC voltage, a second lamp arranged in parallel with the smoothing portion and provided with a smoothed AC voltage from the smoothing portion, A discharging part arranged in parallel with the smoothing part to form a discharging path capable of discharging the alternating voltage charged in the smoothing part when the second lamp part is turned off, When the current flowing in the first ramp portion or the second ramp portion is detected and an abnormality of the set specific current is detected, the first ramp portion or the second ramp portion A driving circuit for adjusting the current flowing.

Description

[0001] The present invention relates to a drive circuit of a light-

The present invention relates to a light emitting diode driving circuit, and more particularly, to a light emitting diode driving circuit capable of improving light efficiency, power factor, and harmonic characteristics while maintaining high efficiency while solving flicker phenomenon when an LED is driven by an AC voltage .

The conventional technology for driving LEDs with a constant current is a linear regulator and an AC direct type method in which an AC voltage is directly applied by constituting SMPS and LED in multi-stages for better power efficiency. However, each driving method has the following problems.

Linear regulators have caused heat generation due to power efficiency degradation, resulting in increased heat sink size and reduced light efficiency.

Switching mode power supply (SMPS) has increased components due to noise, harmonic problems caused by high-speed switching, and increased circuit complexity.

In the case of the low-cost type, noise, power factor, and harmonic characteristics were problematic.

AC direct type has a problem that light deviation occurs due to flicker problem (% Flicker 100%), deviation occurs due to current deviation of LED stage, brightness deviation occurs due to instantaneous voltage drop, and light efficiency is lowered at the same power efficiency.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for improving the efficiency and power factor while reducing the number of parts while solving the Flicker problem, In addition, it is aimed to provide a light emitting diode driver circuit free from EMI and EMC problems.

A light emitting diode driving circuit according to an embodiment of the present invention includes an input unit for receiving an AC voltage from the outside, a rectifying unit for rectifying the AC voltage supplied from the input unit, a smoothing unit for smoothing the AC voltage rectified by the rectifying unit, A first ramp portion arranged in series and provided with an AC voltage and operated while being turned on or off, a smoothing portion arranged in parallel with the smoothing portion and supplied with a smoothed AC voltage from the input AC voltage and smoothing portion, A discharging unit arranged in parallel with the smoothing unit to form a discharging path capable of discharging the alternating voltage charged in the smoothing unit when the second lamp unit is turned off; When a set specific voltage is detected or a current flowing in the first lamp unit or the second lamp unit is detected and an abnormality of the set specific current is detected, And a driving circuit unit for adjusting a current flowing through the first or second lamp unit.

The driving circuit unit may include a current adjusting switching unit electrically connected to the first lamp unit or the second lamp unit to control or cut off the current flowing through the first and second lamp units while being turned on or off, A current detection drive control unit for adjusting a current flowing in the current adjustment switching unit or turning off the current adjustment switching unit when a predetermined current or more is detected and detecting an electric current flowing through the current adjustment switching unit, And a voltage detection power supply unit for supplying a control signal to the current detection drive control unit, which can control the current control switching unit when a specified voltage is detected by detecting the input AC voltage.

The backlight unit may further include a reverse voltage prevention unit disposed between the first and second lamp units to prevent a charged AC voltage from flowing to the first lamp unit.

Further, the smoothing part may be formed of a capacitor, or the discharging part may be formed of a resistor.

Also, the current detection drive control unit controls the first lamp unit and the second lamp unit to operate in accordance with the magnitude and sequence of the specific current by receiving the AC voltage and the smoothed voltage, and the second lamp unit arranged in parallel with the smoothing unit controls the AC voltage And smoothing the AC voltage supplied from the smoothing part to operate.

Also, the discharge unit may be formed of any one of MOSFET, IGBT, and BJT, and the reverse voltage prevention unit may be formed of any one of a diode, a bridge diode, a MOSFET, an IGBT, and a BJT.

The first ramp portion and the second ramp portion disposed in parallel with the smoothing portion are disposed in parallel with each other. The first ramp portion and the second ramp portion are arranged in series or in parallel to each other .

The voltage detecting power supply unit for detecting the AC voltage input to the input unit may include electrically connected after passing through the first lamp unit or the second lamp unit.

The LED driving circuit according to the embodiment of the present invention has the following effects.

First, there is an effect of improving power factor and harmonic characteristics while solving and mitigating the flicker phenomenon in AC driving.

Second, it maintains a high efficiency ratio and has an effect of improving the light efficiency as compared with the AC drive of the same efficiency.

Third, it has fewer parts to be applied than SMPS drive, and it has no EMI and EMC problem.

Fourth, there is an effect of solving the light brightness deviation problem caused by the light brightness deviation problem of some LEDs due to the current deviation and the instantaneous input voltage drop.

Fifth, it has an effect of improving the withstand voltage characteristic against a high voltage.

1 is a circuit diagram of a light emitting diode driving circuit according to a first embodiment of the present invention.
2 is a circuit diagram of a light emitting diode driving circuit according to a second embodiment of the present invention.
3 is a circuit diagram of a light emitting diode driving circuit according to a third embodiment of the present invention.
4 is a circuit diagram of a light emitting diode driving circuit according to a fourth embodiment of the present invention.
5 is a circuit diagram of a light emitting diode driving circuit according to a fifth embodiment of the present invention.
6 illustrates an LED light output waveform for an AC input voltage during application of a LED driving circuit according to various embodiments of the present invention.
FIG. 7 is an actual view illustrating an actual light output by applying a light emitting diode driving circuit according to various embodiments of the present invention.

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

1 is a circuit diagram of a light emitting diode driving circuit according to a first embodiment of the present invention.

1, the LED driving circuit according to the first embodiment of the present invention includes an input unit 110, a rectifying unit 120, a smoothing unit 150, a first lamp unit 130a, a second lamp unit 130b, A discharging unit 160, and a driving circuit unit 170. [

The input unit 110 receives an AC voltage from the outside. The input unit 110 is electrically connected to the rectifying unit 120, receives the commercial AC voltage from the outside, and provides the rectified voltage to the rectifying unit 120.

The rectifying unit 120 receives the AC voltage from the input unit 110 and rectifies it. The rectifying unit 120 may be formed of at least one diode and rectified by receiving an input AC voltage. Accordingly, the rectifying unit 120 may provide rectified AC voltage after rectifying through the at least one diode by receiving the AC voltage.

The smoothing unit 150 receives and rectifies the rectified AC voltage from the rectifying unit 120. The smoothing part 150 may be formed of a capacitor while being electrically connected to the rectifying part 120. That is, the smoothing unit 150 may smooth the AC voltage rectified from the rectifying unit 120 by using a capacitor. At this time, the smoothed AC voltage can be a voltage substantially close to DC.

The first ramp portion 130a is disposed in series with the smoothing portion 150 and operates by turning on or turning off by receiving an AC voltage. The first lamp unit 130a may be formed by electrically connecting at least one or more LEDs. In this case, the first lamp unit 130a may be represented by an eleventh ramp unit 130a ₁ and a twelfth lamp unit 130a ₂ .

The second lamp unit 130b is supplied with the AC voltage and the smoothed AC voltage from the smoothing unit 150 and operates while turning on or off. The second lamp unit 130b is formed by electrically connecting at least one or more LEDs to each other. Here, the second ramp portion 130b may be represented by the 21st and 22nd ramp portions, though not shown.

The first lamp unit 130a and the second lamp unit 130b may be disposed in parallel with the smoothing unit 150 and may be connected or connected in series, have.

The discharge unit 160 is disposed in parallel with the smoothing unit 150 to form a discharge path capable of discharging the AC voltage charged in the smoothing unit 150 when the second ramp unit 130b is turned off do. The discharge unit 160 is formed of a resistor, and is disposed in parallel with the smoothing unit 150. When the second lamp unit 130b is turned off, the discharge unit 160 may quickly discharge the alternating voltage charged in the capacitor so that the afterglow remaining in the LED may disappear. That is, the discharge unit 160 may form a discharge path by disposing a resistor in parallel with the capacitor in order to quickly remove the afterglow generated when the second lamp unit 130b is turned off. That is, the discharge unit 160 is formed of a resistor and the smoothing unit 150 is formed of a capacitor, so that the discharge time can be shortened by the RC time constant.

In this case, the discharge unit 160 is not limited to a resistor, and may be formed of various electrical elements such as a MOSFET, an IGBT, and a BJT. If the discharge unit 160 is formed of a MOSFET, an IGBT, a BJT, or the like, the second lamp unit 130b can operate in reverse. That is, when the second lamp unit 130b is turned off, the discharge unit 160 turns on to form a discharge path for quickly removing afterglow. In other words, when the second lamp unit 130b is turned off, the current detection drive control unit 171 detects the current and drives the discharge unit 160 to provide a detection signal to turn on the discharge unit 160 can do. Accordingly, the discharging path can be formed while the discharge unit 160 is turned on.

The driving circuit unit 170 detects an input voltage inputted to the input unit 110 and detects a set specific voltage or a current flowing in the first lamp unit 130a or the second lamp unit 130b, And adjusts the current flowing in the first ramp portion 130a or the second ramp portion 130b. The driving circuit unit 170 may include a current adjustment switching unit 173, a current detection drive control unit 171, and a voltage detection power supply unit 172.

The current adjustment switching unit 173 is electrically connected to the first or second lamp unit 130a or 130b and turns on or off so that the first lamp unit 130a and the second lamp unit 130b are turned on or off, And controls or cuts off the current flowing through the second lamp unit 130b. The current adjustment switching unit 173 is controlled by the current detection drive control unit 171 and operates by receiving the converted AC voltage from the voltage detection power supply unit 172. [ As shown in FIG. 1, the current adjustment switching unit 173 may be formed of at least one current adjustment switching unit 173C ₁ , 173C ₂ ,..., 173C _n .

The current detection drive control unit 171 detects a current flowing in the current adjustment switching unit 173 and adjusts the current flowing to the current adjustment switching unit 173 or switches the current adjustment switching unit 173 Turn off. The current detection drive control unit 171 detects a current flowing through the current adjustment switching unit 173 electrically connected to the first lamp unit 130a or the second lamp unit 130b, And controls the adjustment switching unit 173 to adjust the current flowing in the first lamp unit 130a or the second lamp unit 130b. At this time, the current detection drive control unit 171 can detect the current flowing in the current adjustment switching unit 173 in real time and compare it with a predetermined specific current. When the detected current is detected to be lower than the set specific current by comparing the detected current based on the set specific current, the current regulating switching is performed such that a high current flows through the first lamp unit 130a or the second lamp unit 130b The control unit 173 controls the current adjustment switching unit 173 so that a low current flows through the first lamp unit 130a or the second lamp unit 130b when the detected current is detected to be higher than the set specific current The current can be controlled so that light can be emitted constantly.

The current detection drive control unit 171 controls the first ramp unit 130a disposed in series with the smoothing unit 150 to operate by receiving an AC voltage from a voltage detection power supply unit 172 to be described later, The second ramp portion 130b arranged in parallel with the rectifying portion 150 may be controlled to receive the smoothed AC voltage from the smoothing portion 150 to operate.

The current detection drive control unit 171 detects the current flowing through the current adjustment switching unit 173 electrically connected to the second lamp unit 130b and outputs a current to the second lamp unit 130b Controls the current adjustment switching unit 173 so as to limit the flowing current or controls the current adjustment switching unit 173 which is electrically connected to the previous first lamp unit 130a disposed in series with the second lamp unit 130b The current flowing through the second ramp portion 130b can be adjusted.

The voltage detection power supply unit 172 converts the AC voltage input through the input unit 110 and supplies the AC voltage to the current adjustment switching unit 173 and the current detection drive control unit 171. The voltage detection power supply unit 172 detects the input AC voltage, The control signal for controlling the current adjustment switching unit 173 is provided to the current detection drive control unit 171.

The reverse voltage prevention unit 140 is disposed between the first lamp unit 130a and the second lamp unit 130b to prevent the charged AC voltage from flowing to the first lamp unit 130a. The reverse voltage prevention unit 140 may be formed of a diode so as to prevent the charged voltage from flowing to the first lamp unit 130a. That is, when the AC voltage charged in the smoothing unit 150 is greater than the AC voltage to which the AC voltage charged in the smoothing unit 150 is inputted, the reverse voltage prevention unit 140 prevents the reverse voltage flowing backward toward the previously disposed first lamp unit 130a can do.

At this time, the reverse voltage prevention unit 140 may be formed of various electrical elements such as a diode, a bridge diode, a MOSFET, an IGBT, and a BJT. When the reverse voltage prevention unit 140 is formed of various electrical elements such as a diode, a bridge diode, a MOSFET, an IGBT, and a BJT, the current detection drive control unit 171 controls the smoothing unit 150 and the AC The smoothed AC voltage detected by the smoothing unit 150 is detected by the first lamp unit 130a disposed in series with the second lamp unit 130b and before the second lamp unit 130b It can be controlled to turn on only when it is lower than the AC voltage.

Also, in the case of the reverse voltage prevention unit 140, the role of the reverse voltage prevention unit 140 may be replaced with a bridge diode when the rectifying unit 120 is disposed at the initial stage.

The operation of the LED driving circuit according to the first embodiment of the present invention described above is as follows. In order to facilitate the description of the drawings, the first lamp unit 130a is divided into an eleventh lamp unit 130a ₁ and a twelfth lamp unit 130a ₂ when a plurality of first lamp units are provided. The eleventh ramp portion 130a ₁ and the twelfth ramp portion 130a ₂ may have substantially the same configuration and function. The second lamp unit 130b is divided into a 21st lamp unit and a 22nd lamp unit, although not shown in the case of a plurality of second lamp units 130b. The twenty-first lamp unit and the twenty-second lamp unit may have substantially the same configuration and function.

1, the LED driving circuit according to the first embodiment of the present invention is formed in the smoothing unit 150 through an AC input input from the input unit 110 and a diode formed in the rectifying unit 120 A second ramp portion 130b driven by the rectifying portion 120 with a smoothed AC voltage by the capacitor, an eleventh ramp portion 130a ₁ and a twelfth ramp portion 130a ₂ driven by a constant current with an AC voltage .

First, when the AC voltage is supplied from the input unit 110, the eleventh lamp unit 130a ₁ is turned on by the AC voltage rectified by the rectifier unit 120. [

After the eleventh ramp portion 130a ₁ is turned on, the rectified AC voltage is increased to a set specific current or the second ramp portion 130b arranged next to the eleventh ramp portion 130a ₁ When the current flowing through the current adjusting switching unit 173 which is electrically connected to the current control switching unit 173 flows more than a predetermined specific current, the current detecting and driving control unit 171 controls the eleventh lamp unit 130a ₁ to turn off It is possible to control the current adjustment switching unit 173 which is electrically connected to the lamp unit 130a ₁ .

The AC voltage rectified in the smoothing unit 150 is then charged and the AC voltage is supplied to turn on the second lamp unit 130b. As such, after the second lamp unit 130b is turned on, the alternating voltage is increased to set the predetermined current or to the twelfth lamp unit 130a ₂ disposed next to the second lamp unit 130b, The current detection drive control unit 171 controls the second lamp unit 130b such that the second lamp unit 130b is turned off when the current flowing in the current adjustment switching unit 173 connected to the second lamp unit 130b The current control switching unit 173 can be controlled by the current control unit 173. This operation can be repeatedly performed.

At this time, the current detected by the current regulating switching unit 173, which is the alternating voltage that is lower than the set alternating voltage provided by the input unit 110 and is electrically connected to the second lamp unit 130b, It is possible to control the current regulating switching unit 173 which is electrically connected to the eleventh lamp unit 130a ₁ so that the eleventh lamp unit 130a ₁ turns on when the current flows below the _first lamp unit 130a ₁ .

In the case of the second ramp portion 130b disposed in parallel with the smoothing portion 150, when the input AC voltage is lower than the smoothed AC voltage charged in the smoothing portion 150, the eleventh ramp portion 130a ₁ and The reverse voltage preventing unit 140 disposed between the second lamp units 130b blocks the reverse voltage that is the alternating voltage charged from the second lamp unit 130b to the eleventh lamp unit 130a ₁ , A smoothed AC voltage is applied to the second ramp portion 130b connected to the first portion 150 and the current can flow.

By operating in this manner, the current input to the second ramp portion 130b disposed in parallel with the smoothing portion 150 uses the instantaneous alternating current, but the optical output can produce a nearly DC-like waveform in which the flicker is resolved have.

At this time, the voltage detection power supply unit 172, which is electrically connected to the input unit 110 and detects the AC voltage or converts and supplies the AC voltage, may be connected after passing through the eleventh lamp unit 130a ₁ (N LEDs). Here, the voltage detection power supply unit 172 receives a high voltage from the input voltage, converts the voltage into a low voltage, and supplies the low voltage to the current adjustment drive control unit 171 or the current adjustment switch 173 electrically connected to the eleventh ramp unit 130a ₁ . As described above, since the voltage detection power supply unit 172 is connected after passing through the eleventh ramp unit 130a ₁ , the withstand voltage characteristic can be secured by Vf.

In other words, when a high voltage (for example, 300 V) is applied through the input unit 110, a high voltage (300 V) is directly applied to the conventional voltage detection power supply unit. However, when the eleventh lamp unit 130 a ₁ is connected, A voltage 220V which is separated by Vf (for example, 80V) of the lamp unit 130a ₁ (N LEDs) may be applied. Thereby, the withstanding voltage characteristic (the characteristic which does not break even at a high voltage) can be improved.

In addition, the eleventh and twelfth ramp portions 130a ₁ and 130a ₂ driven by the direct AC voltage can improve the power factor and the harmonic power efficiency have.

Also, since the number of the eleventh to ninth lamps 130a ₁ , 12a and 130b ₂ and the number of the second lamps 130b can be switched at the inputted AC frequency, .

2 is a circuit diagram of a light emitting diode driving circuit according to a second embodiment of the present invention.

2, the LED driving circuit according to the second embodiment of the present invention includes an input unit 210, a rectifying unit 220, a smoothing unit 250, a first lamp unit 230a, a second lamp unit 230b, A discharging unit 260, and a driving circuit unit 270. [

The function of each element corresponding to the LED driving circuit according to the second embodiment of the present invention and the organic relation between the elements are the same as those of the respective elements corresponding to the LED driving circuit according to the first embodiment And the organic relations among them are substantially the same as each other. Therefore, each of the detailed descriptions thereof will be omitted below.

As shown in FIG. 2, the second ramp portion 230b and the first ramp portion 230a, which are arranged in parallel with the smoothing portion 250, are arranged in series.

When the AC voltage is provided from the input unit 210, the AC voltage rectified by the rectification unit 220 is supplied to the AC voltage rectified to the smoothing unit 250 and the AC voltage is applied to the second lamp unit 230b Turned on.

As described above, when the second ramp portion 230b is turned on, the alternating voltage is increased to set the predetermined alternating voltage or the first ramp portion 230a disposed next to the second ramp portion 230b, (Not shown) disposed in the driving circuit unit 270 when the current flowing through the current adjusting switching unit 273 connected to the second lamp unit 230b flows through the second lamp unit 230b is turned off off control of the current regulating switching unit 273, which is electrically connected to the second lamp unit 230b.

In the case of the second ramp portion 230b disposed in parallel with the smoothing portion 250, when the input AC voltage is lower than the smoothed AC voltage charged in the smoothing portion 250, the rectification portion 220 and the second ramp portion 230b, The second lamp unit 230b connected to the smoothing unit 250 prevents the reverse voltage from flowing from the second lamp unit 230b to the rectification unit 220 by the reverse voltage prevention unit 240 disposed between the first lamp unit 230b and the second lamp unit 230b, So that a smoothed AC voltage is applied and a current can flow.

Thereafter, when the rectified AC voltage increases, the first ramp portion 230a is turned on. This operation can be repeatedly performed.

3 is a circuit diagram of a light emitting diode driving circuit according to a third embodiment of the present invention.

3, the LED driving circuit according to the third embodiment of the present invention includes an input unit 310, a rectifying unit 320, a smoothing unit 350, an eleventh lamp unit 330a ₁ , a twelfth lamp unit 330a ₂ , a second lamp unit 330b, a discharge unit 360, and a driving circuit unit 370.

The function of each element corresponding to the LED driving circuit according to the third embodiment of the present invention and the organic relation between them are the same as those of the respective elements corresponding to the LED driving circuit according to the first embodiment And the organic relations among them are substantially the same as each other. Therefore, each of the detailed descriptions thereof will be omitted below.

3, the eleventh ramp portion 330a ₁ and the twelfth ramp portion 330a ₂ are arranged in series, and the second ramp portion 330b arranged in parallel with the smoothing portion 350 is disposed in the top The last configuration is located.

First, when the AC voltage is provided from the input unit 310, the eleventh ramp unit 330a ₁ is turned on by the AC voltage rectified by the rectification unit 320.

After the eleventh ramp portion 330a ₁ is turned on, the rectified alternating voltage is increased to a predetermined alternating voltage or a twelfth ramp portion (not shown) disposed next to the eleventh ramp portion 330a ₁ 330a ₂₎ and when the electric flow is above a predetermined current, the current flowing to the current control switching unit 373 is set to be connected to when the current detection drive control section (not shown disposed in the driver circuit portion 370) is the 11th ramp portion (330a ₁ Can be controlled to be turned off.

When the rectified AC voltage is increased, the twelfth lamp part 330a ₂ is turned on.

After the twelfth lamp part 330a ₂ is turned on, the rectified AC voltage is increased to set the predetermined alternating voltage or the _second ramp part 330b disposed next to the twelfth ramp part 330a ₂ . The current detection drive control unit (not shown) may turn off the twelfth lamp unit 330a ₂ when a current flowing in the current adjustment switching unit 373 electrically connected to the first lamp unit 330a The current adjustment switching unit 373 can be controlled.

When the AC voltage input to the smoothing unit 350 is increased, the second lamp unit 330b is turned on. This operation can be repeatedly performed.

In the case of the second ramp portion 330b disposed in parallel with the smoothing portion 350, if the input AC voltage is lower than the smoothed AC voltage charged in the smoothing portion 350, the twelfth ramp portion 330a ₂ and A reverse voltage is prevented from flowing from the second lamp unit 330b to the twelfth lamp unit 330a ₂ by the reverse voltage prevention unit 340 disposed between the second lamp units 330b, A smoothed AC voltage may be applied to the second ramp portion 330b to allow current to flow.

By operating in this manner, the eleventh ramp portion 330a ₁ , the twelfth ramp portion 330a ₂ , and the second ramp portion 330b, in which the current of the second ramp portion 330b disposed at the end flows less, The light deviation problem of the formed LED can be alleviated.

4 is a circuit diagram of a light emitting diode driving circuit according to a fourth embodiment of the present invention.

4, the LED driving circuit according to the fourth exemplary embodiment of the present invention includes an input unit 410, a rectifying unit 420, smoothing units 450a and 450b, an eleventh lamp unit 430a ₁ , The first lamp unit 430a ₂ , the 21st lamp unit 430b ₁ , the 22nd lamp unit 430b ₂ , the discharge units 460a and 460b, and the driving circuit unit.

The function of each element corresponding to the LED driving circuit according to the fourth embodiment of the present invention and the organic relation between them are the same as those of the LED driving circuit according to the first and second embodiments The function to the elements and the organic relation between them are substantially the same, so that the respective further explanations thereof will be omitted below.

4, a twenty- _first lamp unit 430b ₁ , an eleventh lamp unit 430a ₁ , and a twelfth lamp unit 430a ₂ arranged in parallel with the smoothing unit 450a are arranged in series, And a twenty- _second ramp portion 430b2 disposed in parallel with the smoothing portion 450b.

First, when an alternating voltage is provided from the input unit 410, an alternating voltage rectified by the rectifying unit 420 is provided, and when the alternating voltage input to the smoothing unit 450a is increased, the 21st lamp unit 430b ₁ Is turned on.

After the twenty- _first ramp portion 430b ₁ is turned on, the smoothed alternating-current voltage is increased to a predetermined alternating-current voltage or an eleventh ramp portion (not shown) disposed after the twenty- _first ramp portion 430b ₁ 430a ₁₎ to the case flow is above a predetermined current the current is set to flow the electric current control switching part 473 are connected to when the current detection drive control section (not shown disposed in the driver circuit portion 470) are 21 ramp portion (430b ₁ Can be controlled to be turned off.

In the case of the twenty- _first ramp portion 430b1 arranged in parallel with the smoothing portion 450a, when the input AC voltage becomes lower than the smoothed alternating voltage charged in the smoothing portion 450, the rectifying portion 420 and the twenty- portion (430b _1), reverse voltage protection unit portion 21 lamp by (440a) disposed between (430b ₁₎ blocks a passage of the reverse voltage rectifying section 420 in the and portion 21 lamps connected to the smoothing unit (450a) A smoothed AC voltage is applied to the gate electrode 430b ₁ so that a current can flow.

When the rectified AC voltage is increased, the eleventh ramp portion 430a ₁ is turned on.

After the eleventh ramp portion 430a ₁ is turned on, the rectified AC voltage is increased to a predetermined alternating voltage or a twelfth ramp portion (not shown) disposed next to the eleventh ramp portion 430a ₁ The current detection drive control unit (not shown) may turn off the eleventh ramp unit 430a ₁ when the current flowing through the current adjustment switching unit 473 electrically connected to the _first lamp unit 430a ₁ and the _second current unit 430a ₂ flows through the predetermined current or more. .

When the AC voltage is increased, the twelfth lamp unit 430a ₂ is turned on.

After the twelfth lamp unit 430a ₂ is turned on, the alternating voltage is increased to set the predetermined alternating voltage or the twenty- _second lamp unit 430b ₂ arranged next to the twelfth lamp unit 430a ₂ . _The current detection drive control unit (not shown) controls the 12 th lamp unit 430a ₂ to be turned off when the current flowing in the current adjustment switching unit 473 electrically connected to the _second lamp unit 430a can do.

When the AC voltage input to the smoothing unit 450b is increased, the 22nd lamp unit 430b ₂ is turned on. This operation can be repeatedly performed.

Further, the smoothing unit (450b) in the case of the twenty-second ramp portion (430b ₂₎ arranged in parallel to the input AC voltage is part becomes lower than the smoothed AC voltage twelfth lamp to be charged in the smoothing unit (450b) that is (430a ₂₎ and a 22 lamp unit (430b ₂₎ reverse voltage protection unit (440b) block of claim 22, ramp portion (430b ₂₎ of claim 12, the lamp unit (430a ₂₎ by flowing a reverse voltage on by being disposed between, and smooth portions ( A smoothed AC voltage is applied to the twenty- _second lamp unit 430b2 connected to the _second lamp unit 450b.

5 is a circuit diagram of a light emitting diode driving circuit according to a fifth embodiment of the present invention.

5, the LED driving circuit according to the fifth embodiment of the present invention includes an input unit 510, a rectifying unit 520, smoothing units 550a and 550b, an eleventh ramp unit 530a ₁ , The first lamp unit 530a ₂ , the 21st lamp unit 530b ₁ , the 22nd lamp unit 530b ₂ , the discharge units 560a and 560b, and the driving circuit unit.

The function of each component corresponding to the LED driving circuit according to the fifth embodiment of the present invention and the organic relation between them are the same as those of the respective components corresponding to the LED driving circuits according to the first and fourth embodiments The function to the elements and the organic relation between them are substantially the same, so that the respective further explanations thereof will be omitted below.

5, a twenty- _first lamp unit 530b ₁ and an eleventh lamp unit 530a ₁ arranged in parallel with the smoothing unit 550a are arranged in series, and the twenty- _first lamp unit 530b ₁ , the lamp of claim 12, part (530a ₂₎ and a smoothing unit (550b) and the lamp unit 22 (530b ₂₎ arranged in parallel is configured to be arranged in parallel.

First, when an AC voltage is provided from the input unit 510, an AC voltage rectified by the rectification unit 520 is provided so that the AC voltage rectified to the smoothing unit 550a is charged and the 21st lamp unit 530b ₁ is turned on turn on.

When the AC voltage input after the 21st lamp part 530b ₁ is turned on is increased, the predetermined alternating-current voltage is set or the eleventh ramp part (530b ₁ ) disposed after the 21st lamp part 530b ₁ 530a ₁₎ to the case flow is above a predetermined current the current is set to flow the electric current control switching part 573 are connected to when the current detection drive control section (not shown disposed in the driver circuit portion 570) are 21 ramp portion (530b ₁ Can be controlled to be turned off.

In this case, in the case of the twenty- _first ramp portion 530b ₁ arranged in parallel with the smoothing portion 550a, when the input AC voltage becomes lower than the smoothed AC voltage charged in the smoothing portion 550a, the rectifying portion 520 and the twenty- portion (530b ₁₎ of claim 21, the lamp unit by a reverse voltage prevention portion (540a) is disposed between (530b ₁₎ blocks a passage of the reverse voltage rectifying section 520 in the and portion 21 lamps connected to the smoothing unit (550a) A smoothed AC voltage is applied to the gate electrode 530b ₁ and a current can flow.

When the AC voltage is increased, the eleventh ramp portion 530a ₁ is turned on.

When the alternating voltage rectified in the twelfth lamp unit 530a ₂ arranged in parallel to the twenty _first lamp unit 530b ₁ increases, the twelfth lamp unit 530a ₂ turns on, ramp portion (530b ₁₎ and the alternating-current voltage rectified by the 22 lamp unit (530b ₂₎ arranged in parallel and charged in the smoothing unit (550b) at the same time the 22 lamp unit (530b ₂₎ is turned on is (turn on) .

In the case of the twenty- _second ramp portion 530b2 arranged in parallel with the smoothing portion 550b, when the input AC voltage becomes lower than the smoothed alternating voltage charged in the smoothing portion 550b, the rectifying portion 520 and the twenty- (530b ₂₎ a reverse voltage prevention portion (540b) of claim 22, the lamp unit (530b _2), the rectification part 520, a 21 lamp unit (530b ₁₎ and 12 of the lamp unit (530a _2), in by being disposed between the station A smoothed AC voltage is applied to the twenty- _second ramp portion 530b ₂ connected to the smoothing portion 550 to block the flow of the voltage and the current can flow.

6 illustrates an LED light output waveform for an AC input voltage during application of a LED driving circuit according to various embodiments of the present invention.

6, when the commercial AC voltage is received and the first ramp portion or the second ramp portion is driven through rectification of the rectification portion according to the embodiment of the present invention, Due to the characteristics, dead zone where LED does not turn on can cause flicker phenomenon. At this time, the smoothing part is arranged in parallel with the lamp part so that the AC voltage is smoothly charged and supplied, so that the light output of the LED can be made constant with respect to the time axis.

As a result, the dead zone can be easily removed and the flicker phenomenon can be solved or mitigated.

Therefore, as shown in FIG. 6, the light output can be substantially constant with time according to the conventional AC driving.

FIG. 7 is an actual view illustrating an actual light output by applying a light emitting diode driving circuit according to various embodiments of the present invention.

As shown in FIG. 7, results of applying the LED driving circuit according to various embodiments of the present invention.

That is, when driving the LED drive by using the conventional AC power source directly, assuming that 100% is based on the percent flicker, which is one of the flicker criteria, it is confirmed that the various embodiments proposed in the present invention are improved to 12.5% .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

On the contrary, those skilled in the art will appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims.

Accordingly, all such appropriate modifications and changes, and equivalents thereof, should be regarded as within the scope of the present invention.

110: Input unit 120:
130a: first ramp part 130b: second ramp part
140: reverse voltage prevention part 150: smooth part
160: discharging part 170: driving circuit part
171: current detection drive control unit 172: voltage detection power supply unit

Claims (8)

An input unit for receiving an AC voltage from the outside;
A rectifying unit for receiving and rectifying an AC voltage from an input unit;
A smoothing unit for smoothing the AC voltage rectified by the rectifying unit;
A first lamp part arranged in series with the smoothing part and operating with turning on or turning off by receiving an AC voltage;
A second ramp portion disposed in parallel with the smoothing portion and operating with an input AC voltage and a smooth AC voltage supplied from the smoothing portion and turning on or off;
A discharging portion disposed in parallel with the smoothing portion to form a discharge path capable of discharging the AC voltage charged in the smoothing portion when the second ramp portion is turned off;
The input voltage is detected to detect the set specific voltage, or the current flowing in the first or second lamp unit is detected to detect a current exceeding the specified current, the current flowing in the first lamp unit or the second lamp unit And a driving circuit for adjusting the driving current.
The method according to claim 1,
The driving circuit section
A current regulating switching unit that is electrically connected to the first lamp unit or the second lamp unit and controls or cuts off the current flowing through the first and second lamp units while being turned on or off;
A current detection drive control unit for detecting a current flowing in the current adjustment switching unit and adjusting a current flowing in the current adjustment switching unit or turning off the current adjustment switching unit when a predetermined specific current or more is detected; And
A current control unit for converting the AC voltage input through the input unit and supplying the AC voltage to the current adjustment switching unit and the current detection drive control unit and detecting the input AC voltage, And a voltage detection power supply unit for providing the control voltage to the control unit.
The method of claim 2,
And a reverse voltage preventing unit disposed between the first lamp unit and the second lamp unit to prevent the charged AC voltage from flowing to the first lamp unit.
The method of claim 3,
Wherein the smoothing part is formed of a capacitor or the discharging part is formed of a resistor.
The method of claim 2,
The current detection drive control unit controls the first lamp unit and the second lamp unit to operate in accordance with the magnitude and order of the specific current by receiving the AC voltage and the smoothed voltage and controls the second lamp unit arranged in parallel with the smoothing unit And supplies the smoothed AC voltage to the light emitting diode driving circuit.
The method of claim 3,
Wherein the discharge unit is formed of any one of MOSFET, IGBT, and BJT, and the reverse voltage prevention unit is formed of any one of a diode, a bridge diode, a MOSFET, an IGBT, and a BJT.
The method according to claim 1,
A first ramp portion arranged in series with the smoothing portion and a second ramp portion arranged in parallel with the smoothing portion, wherein at least one of the first ramp portion and the second ramp portion is arranged in series or in parallel and mixed, Circuit.
The method of claim 2,
A voltage detection power supply unit for detecting an AC voltage input to an input unit is electrically connected after passing through a first lamp unit or a second lamp unit.

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