KR20170057035A - Direct LED Driving Circuit for Improving Flicker - Google Patents

Abstract

The present invention relates to a direct LED driving device and, more specifically, to a direct LED driving device for improving flicker. The direct LED driving device for improving flicker comprises: a first LED group whose input side is connected to an output side of an alternating current power source to supply power; a first constant current circuit whose input side is connected to an output side of the first LED group; a first charging/discharging unit whose input side is connected to the output side of the alternating current power source to supply power; a first driving current control unit whose input side is connected to the output side of the alternating current power source to supply power; a second charging/discharging unit connected to the first charging/discharging unit in series; a second LED group connected to the second charging/discharging unit in parallel; a second constant current circuit whose input side is connected to an output side of the second LED group; a second driving current control unit connected to the second LED group in parallel; and a third constant current circuit to supply a constant current to the second LED group, the second driving current control unit, and the second charging/discharging unit. The first and the second driving current control unit are turned on if an input voltage is larger than a voltage of the first or the second charging/discharging unit to provide a current path.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a direct-current LED driving circuit for improving flicker,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an LED direct drive apparatus, and more particularly, to an LED direct drive apparatus improved in flicker.

Generally, in a conventional LED driving circuit, an AC power supply voltage is applied to two input terminals of a bridge diode, and a current rectified by a bridge diode is controlled to drive LEDs provided in the LED module to emit light. Korean Patent Application Nos. 10-2010-0056623, 10-2010-0056683, and the like can be referred to as related arts.

In addition, Korean Patent Application No. 10-2011-0113891 (LED multi-stage drive control device) discloses a circuit for driving the LED module as shown in FIG.

1, in order to stop the flow of the auxiliary currents (i _Q2 , i _Q3 , i _Q4 ) when the main current i _Q1 flows according to the change of the input power source V _ac , R _off20 , R _off30 , R _off40 were used and D ₁ , R _off31 , and D ₂ , R _off42 were used to stop the flow of the remaining auxiliary currents (i _Q3 , i _Q4 ) when the auxiliary current i _Q2 flowed, and the auxiliary current i _Q3 D ₃ , R off ₄₁ was used to stop the flow of the remaining auxiliary current i _Q4 when flowing. In addition, the sensing resistors R _sen1 , R _sen2 , R _sen3 , and R _sen4 are used to sense the main current and the auxiliary current. The detailed operation procedure can be referred to the patent document.

However, in such a conventional LED driving circuit, although the number of current levels of four stages is illustrated in FIG. 1, in order to increase the number of current levels to improve the light efficiency and the harmonic characteristic, There is a problem that the number of parts such as diodes and resistors for cutting off the flow of auxiliary current exponentially increases.

Also, as shown in FIG. 1, in the conventional direct drive method, when the input voltage is higher than the voltage, the main current and the auxiliary current can flow only in the current waveform. Therefore, when the input voltage is low, There was a problem.

In order to solve this problem, Korean Patent Application No. 2013-73436 has been developed. In the referenced patent documents, the above-mentioned problems are solved. An LED (Light Emitting Diode) is directly driven by an AC (alternating current) And dimming can be performed. A simple circuit can be used without a large increase in the number of components, so that it is possible to drive even a low AC input. Also, the current is kept constant even when the input AC voltage fluctuates, so that the flicker characteristic is excellent And an LED driving circuit capable of driving the LED driving circuit.

However, the improvement of the above-described conventional technique can improve the flicker rate and the flicker of the LED group 1, but the current of the LED group 2 has a problem that the current does not flow when the input voltage is low, .

Korean Patent Application No. 10-2010-0056623 Korea Patent Application No. 10-2010-0056683 Korean Patent Application No. 10-2011-0113891 Korean Patent Application No. 10-2012-0120901

According to an aspect of the present invention, there is provided an LED driving device for driving a LED with energy charged in a capacitor when an input voltage is low using at least a capacitor, thereby improving the flicker by making a current flow in all the sections I have to.

In addition, the present invention provides an LED direct drive device capable of reducing the power factor and the crest factor by completely controlling the current as well as the current by applying the current control method of the conventional driving method to the charge / discharge current flow of the capacitor.

According to an aspect of the present invention, there is provided an electronic apparatus comprising: a first LED group connected to an output side of an AC power source for supplying power to an input side; A first constant current circuit whose input side is connected to the output side of the first LED group; A first charging unit connected to an output side of an AC power source for supplying power to the input side; A first driving current control unit connected to an output side of an AC power source for supplying power to the input side; A second charging unit connected in series with the first charging unit; A second LED group connected in parallel to the second charging unit; A second constant current circuit whose input side is connected to the output side of the second LED group; A second driving current controller connected in parallel to the second LED group; And a third constant current circuit for providing a constant current to the second LED group, the second driving current control unit, and the second driving current unit, wherein the first driving current control unit and the second driving current control unit generate And is turned on when the voltage of the first charging or discharging portion is higher than the voltage of the first charging discharging portion or the second charging discharging portion.

According to another aspect of the present invention, there is provided a light emitting device comprising: a first LED group connected to an output side of an AC power source for supplying power to an input side; A first constant current circuit whose input side is connected to the output side of the first LED group; A first charging unit connected to an output side of an AC power source for supplying power to the input side; A first driving current control unit connected to an output side of an AC power source for supplying power to the input side; A second charging unit connected in series with the first charging unit; A second LED group connected in parallel to the second charging unit; A second constant current circuit whose input side is connected to the output side of the second LED group; A second driving current controller connected in parallel to the second LED group; A first divided constant current circuit connected to the output side of the second charging and discharging circuit and the output side of the second constant current circuit for providing a constant current; And a second divided constant current circuit connected to the output side of the second driving current control unit for providing a constant current, wherein the first driving current control unit and the second driving current control unit are configured such that the input voltage is lower than the first driving current control unit If it is larger than the voltage of the second charging unit, it is turned on to provide a current path.

According to another aspect of the present invention, there is provided a liquid crystal display comprising: a first LED group connected to an output side of an AC power source for supplying power to an input side; A first constant current circuit whose input side is connected to the output side of the first LED group; A first charging unit connected to an output side of an AC power source for supplying power to the input side; A first driving current control unit connected to an output side of an AC power source for supplying power to the input side; A second charging unit connected in series with the first charging unit; A second LED group connected in parallel to the second charging unit; A second constant current circuit whose input side is connected to the output side of the second LED group; A third charging unit connected in series to the second charging unit; A third LED group connected in parallel to the third emitter; A third constant current circuit connected to the output side of the third LED group; A second driving current controller connected in parallel to the third LED group; And a third constant current circuit for providing a constant current to the third LED group, the second driving current control unit, and the third charging unit, wherein the first driving current control unit controls the first driving current control unit such that the input voltage is higher than the voltage of the third charging unit The second driving current control unit is turned on if the input voltage is greater than the sum of the voltages of the first and second charging units, and the second driving current control unit is turned on when the input voltage is higher than the sum of the voltages of the first and second charging units. And is larger than the sum of the voltages of the second and third charging units, the current path is turned off.

Wherein the first driving current control unit is turned on when the input voltage is greater than the voltage of the third charging unit and the second driving current control unit is turned on when the input voltage is greater than the sum of the voltages of the first charging unit and the second charging unit, Provide a path.

According to another aspect of the present invention, there is provided a liquid crystal display comprising: a first LED group connected to an output side of an AC power source for supplying power to an input side; A first constant current circuit whose input side is connected to the output side of the first LED group; A first charging unit connected to an output side of an AC power source for supplying power to the input side; A first driving current control unit connected to an output side of an AC power source for supplying power to the input side; A second charging unit connected in series with the first charging unit; A second LED group connected in parallel to the second charging unit; A second constant current circuit whose input side is connected to the output side of the second LED group; A third charging unit connected in series to the second charging unit; A third LED group connected in parallel to the third emitter; A third constant current circuit connected to the output side of the third LED group; A second driving current controller connected in parallel to the first LED group and the second LED group; A fourth charging unit connected in series to the third charging unit; A fourth constant current circuit connected in series to the fourth charging unit; A third driving current controller connected in parallel to the third charging unit and the fourth charging unit; A fourth driving current controller connected in parallel to the first charging unit; And a fifth constant current circuit for providing a constant current to the fourth LED group, the third driving current control unit, and the fourth driving current control unit, wherein the first driving current control unit has an input voltage higher than the voltage of the fourth charging unit And the second driving current control unit is turned on when the input voltage is greater than the sum of the voltages of the third and fourth charging units and the third driving current control unit is turned on when the input voltage is higher than the sum of the first charging unit and the second charging unit. And the fourth driving current control unit is turned on if the input voltage is greater than the sum of the voltages of the second charging unit, the third charging unit and the fourth charging unit.

According to the present invention, when the input voltage is low using a minimum of capacitors, the LED is driven by the energy charged in the capacitor, thereby improving the flicker by making the current flow in all the sections.

In addition, the present invention can also reduce the power factor and the crest factor by completely controlling the current as well as the current by applying the current control method of the conventional driving method to the charge / discharge current flow of the capacitor.

1 is a view for explaining a conventional LED driving circuit.
2 is a diagram for explaining an LED driving circuit in which a conventional flicker is improved.
FIG. 3A is a configuration diagram of an LED direct drive device in which a flicker is improved according to an embodiment of the present invention, and FIG. 3B is a diagram showing a current of a third constant current circuit.
FIG. 4A is a view for explaining the operation of the LED direct drive apparatus shown in FIG. 3A, and FIG. 4B is a current voltage waveform diagram corresponding thereto.
FIG. 5A is a diagram for explaining the operation of the LED direct drive apparatus shown in FIG. 3A, and FIG. 5B is a current voltage waveform diagram corresponding thereto.
FIG. 6A is a diagram for explaining the operation of the LED direct drive apparatus shown in FIG. 3A, and FIG. 6B is a current voltage waveform diagram corresponding thereto.
FIG. 7A is a view for explaining the operation of the LED direct drive apparatus shown in FIG. 3A, and FIG. 7B is a current voltage waveform diagram corresponding thereto.
8 is a configuration diagram of an LED direct drive apparatus in which flicker is improved according to another embodiment of the present invention.
FIG. 9A is a configuration diagram of a flicker-improved LED direct drive apparatus according to another embodiment of the present invention, and FIG. 9B is a view showing an input voltage and an input current at this time.
FIG. 10A is a configuration diagram of a flicker-improved LED direct drive apparatus according to another embodiment of the present invention, and FIG. 10B is a view showing an input voltage and an input current at this time.
Fig. 11 is an embodiment of the LED direct drive apparatus of Fig. 3a.
12 shows the capacitor voltage, the DC link voltage, the LED current, and the input current waveform.
13 shows an LED driving state according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments will be described in detail below with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terms first, second, etc. may be used to describe various components, but the components are not limited by the terms, and the terms are used only for the purpose of distinguishing one component from another Is used.

FIG. 3A is a configuration diagram of a flicker-improved LED direct drive apparatus according to an embodiment of the present invention.

Referring to FIG. 3A, the flicker-improved LED direct drive apparatus includes an AC power source 20, a rectifying unit 30, a first LED group 41, a second LED group 42, The first driving current control unit 51, the second driving current control unit 52, the first charging unit 61, the second charging unit 62, the first constant current circuit 71, the second constant current circuit 72, A third constant current circuit 73 and a first diode D _f1 .

The AC power supply 20 supplies power for driving the first LED group 41 and the second LED group 42. The output side of the first LED group 41 is connected to the input side of the first LED group 41, And the output side is connected to the input side of the group 42 via the first drive current control part 51. [

The rectifying unit 30 is connected between the output side of the AC power source 20 and the input side of the first LED group 41 and more specifically the output side of the rectifying unit 30 after the output side) of the diode (BD ₁₎ is connected to the first LED group 41, a first drive current control section 51 and the first chungbang parts (61) rectifies the power supplied from the AC power supply (20) To the first LED group 41, the first driving current controller 51 and the first charging / discharging unit 61, respectively.

In this case, the first LED group 41 and the second LED group 42 may be configured such that a plurality of LED arrays including a plurality of LEDs connected in series are connected in parallel in the forward direction.

The first driving current control unit 51 is connected in parallel to the first LED group 41 and is connected in series with the second LED group 42. In other words, the first driving current control unit 51 is connected in parallel to the first LED group 41 and the output side is connected to the input side of the second LED group 42. [

One end of the first driving current control part 51 is connected to the contact between the first LED group 41 and the first charging part 61 and the AC power source 20 is connected to the capacitor The first input current i _Q1 supplied from the AC power source 20 is input and switched when the voltage V _C is larger than V _C = V _C2 = V _C1 . Here, the first driving current control unit 51 may be implemented by a MOSFET or a transistor.

Next, the second driving current control unit 52 is connected in parallel with the second LED group 42. [

One end of the second driving current control unit 52 is connected to the second charging unit 62 and the AC power supply 20 charges the capacitor voltage V _C = V _C2 = V _C1 ), The second input current i _Q2 supplied from the AC power source 20 is input and the second input current i _Q2 is switched. Here, the second driving current controller 52 may be implemented by a MOSFET or a transistor.

The first charging unit 61 has one side connected to the output side of the rectifying unit 20 and the input side of the first LED group 41 and is connected to the first LED group 41 or charges the power supplied from the AC power supply 20 for supplying the voltage.

On the other hand, the second charging unit 62 is connected to the output side of the first charging unit 61 and the input side of the second LED group 42 on one side, and to the input side of the second charging unit 42 according to the magnitude of the voltage supplied from the AC power source 20 And supplies the voltage for the operation of the second LED group 42 or the power supplied from the AC power supply 20 for supplying the voltage.

Next, one side of the first constant current circuit 71 is connected to the output side of the first LED group 41 to provide a constant first current I ₁ to the first LED group 71.

The second constant current circuit 72 has one side connected to the output side of the second LED group 42 to provide a constant second current I ₂ from the output side of the second LED group 42 to the second LED group 42 do.

One side of the third constant current circuit 73 is connected to the second drive current control part 52 and the output side contacts of the second charge and discharge circuit 62 and the second constant current circuit 72 to provide the third current I ₃ .

On the other hand, the first diode Df1 is positioned between the first charging part 61 and the second charging part 62 to suppress the voltage flowing backward from the second charging part 62. [

In this configuration, the first constant current circuit 71 and the second constant current circuit 72 always drive the first LED group 41 and the second LED group 42 with a constant current and the third constant current circuit 73 3B is controlled to a small current value L ₂ when the input voltage is low and to a large current value L ₁ when the input voltage is high.

4A is a view for explaining the operation of the LED direct drive apparatus shown in FIG. 3A.

4A, when the input voltage is lower than the voltage of the first charging / discharging unit 61 or the second charging / discharging unit 62 (in this case, this means t ₀ to t ₁ in FIG. 4B) The first charging unit 61 supplies a current to the first LED group 41 regardless of whether the current control unit 51 and the second driving current control unit 52 are turned on and the second charging / Thereby providing current to the second LED group 42,.

FIG. 5A is a view for explaining the operation of the LED direct drive apparatus shown in FIG. 3A.

5A, when the input voltage is higher than the voltage of the first charging / discharging unit 61 or the second charging / discharging unit 62 and lower than the sum of the first charging charging unit 61 and the second charging charging unit 62 When it is small (in this case, t ₁ to t ₂ The first driving current control unit 51 and the second driving current control unit 52 are turned on.

As a result, the input voltage and the voltage of the first charging unit 61 cooperate to provide a current to the first LED group 41. When the input voltage and the voltage of the second charging unit 62 cooperate with each other, (42).

As described above, the first and second charging parts 61 and 62 gradually decrease as the current is supplied in cooperation with the input voltage.

At this time, the input voltage is lower than the sum of the first and second charging units 61 and 62, and the third driving current control unit 73 operates with a low current L ₂ .

6A is a diagram for explaining the operation of the LED direct drive apparatus shown in FIG. 3A.

6A, when the input voltage is greater than the sum of the first and second charging parts 61 and 62 (in this case, it means t ₂ to t ₃ in FIG. 6B) The driving current control section 51 and the second driving current control section 52 are turned off.

As a result, the input voltage provides current to the first LED group 41, and the input voltage continues to provide current to the second LED group 42. [

Then, the input voltage charges the first charging and discharging unit 61 and the second charging and discharging unit 62.

At this time, since the input voltage is larger than the sum of the first charging part 61 and the second charging part 62, the third constant current circuit 73 operates with a high current L ₁ .

FIG. 7A is a diagram for explaining the operation of the LED direct drive apparatus shown in FIG. 3A.

7A, when the input voltage is higher than the voltage of the first charging / discharging unit 61 or the second charging / discharging unit 62 and lower than the sum of the first charging charging unit 61 and the second charging charging unit 62 When it becomes smaller again (in this case, t ₃ to t ₄ The first driving current control unit 51 and the second driving current control unit 52 are turned on again.

As a result, the input voltage and the voltage of the first charging unit 61 cooperate to provide a current to the first LED group 41. When the input voltage and the voltage of the second charging unit 62 cooperate with each other, (42).

As described above, the first and second charging parts 61 and 62 gradually decrease as the current is supplied in cooperation with the input voltage.

At this time, since the input voltage is lower than the sum of the first and second charging units 61 and 62, the third constant current circuit 73 operates again with a low current L ₂ .

8 is a configuration diagram of a flicker-improved LED direct drive apparatus according to another embodiment of the present invention.

Referring to FIG. 8, a flicker LED driving apparatus according to another embodiment of the present invention includes an AC power source 20, a rectifying unit 30, a first LED group 41, a second LED group 42, 1 driving current control unit 51, a second driving current control unit 52, a first charging unit 61, a second charging unit 62, a first constant current circuit 71, a second constant current circuit 72, 1 division and a constant current circuit (73-1), the second split current circuit (73-2) and a first diode (D _f1).

3A, the first divided constant-current circuit 73-1 is connected only to the outputs of the second charging unit 62 and the second constant-current circuit 72, and the second divided constant-current circuit 73 -2) is connected to the output side of the second drive current control part 52.

This configuration is similar to the configuration of FIG. 3 except that the first divided constant current circuit 73-1 and the second divided constant current circuit 73-2 provide the same current to the components connected to each other. A detailed description thereof will be omitted. In such a direct drive method, the second divided constant current circuit 73-2 is added to the first divided constant current circuit 73-1 so that the loss is dispersed.

That is, the third constant current circuit 73 of FIG. 3A is divided into the first divided constant current circuit and the second divided constant current circuit to disperse the loss.

9A is a block diagram of a flicker-improved LED direct drive apparatus according to another embodiment of the present invention.

9A, a flicker LED driving apparatus according to another embodiment of the present invention includes an AC power source 120, a rectifier 130, a first LED group 141, a second LED group 142, The first driving current control unit 151, the second driving current control unit 152, the first charging unit 161, the second charging unit 162, the third charging unit 163, A first constant current circuit 171, a second constant current circuit 172, a third constant current circuit 173, a fourth constant current circuit 174, a first diode D _f1 and a second diode D _f2 have.

This configuration increases the number of LED groups from two to three as compared with the structure shown in FIG. 3A, and thus the number of constant current circuits increases from three to four, but the number of the driving current controllers is the same.

The AC power source 120 supplies power for driving the first LED group 141, the second LED group 142 and the third LED group 143, and the first LED group 141, And is connected to the input side of the second LED group 142 via the first LED group 141 and is connected to the third LED group 143 via the first driving current control unit 151. [ ).

The rectifying unit 130 is connected between the output side of the AC power source 120 and the input side of the first LED group 141 and more specifically the output side of the rectifying unit 130 after the output side) of the diode (BD ₁₎ is connected to the first LED group 141, the first driving current control portion 151 and the first chungbang all 161 rectifies the power supplied from the AC power supply 120, To the first LED group 141, the first driving current control unit 151, and the first charging unit 161, respectively.

In this case, the first LED group 141, the second LED group 142, and the third LED group 143 may be configured such that a plurality of LED arrays including a plurality of LEDs connected in series are connected in parallel in the forward direction .

In this configuration, the second LED group 142 is connected to the first LED group 151 in series. In addition, a third LED group 143 is connected in series to the second LED group 142.

The first driving current control unit 151 is connected in parallel to the first and second LED groups 141 and 142 and is connected in series with the third LED group 143. [ In other words, the first driving current control unit 151 is connected in parallel with the first LED group 141 and the second LED group 142, and the output side is connected to the input side of the third LED group 143.

One end of the first driving current control unit 151 is connected to the contact between the first LED group 141 and the first charging unit 161 and the AC power source 20 is connected to the capacitor If it is greater than the voltage V _C3 , it receives the first input current i _Q1 supplied from the AC power source 120 and switches it. Here, the first driving current controller 151 may be implemented as a MOSFET or a transistor.

The second driving current controller 152 is connected in parallel with the third LED group 143.

The second driving current controller 152 is connected to the output side of the second charging and discharging unit 162 and the input side of the third charging and discharging unit 163 and the AC power source 20 ) Is greater than the summed voltage of the capacitor voltages V _C1 and V _C2 , And receives the second input current i _Q2 supplied from the AC power source 120 and switches it. Here, the second driving current controller 152 may be implemented by a MOSFET or a transistor.

The first charging unit 161 has one side connected to the output side of the rectifying unit 120 and the input side of the first LED group 141 and is connected to the first LED group 141 or charges the power supplied from the AC power source 120 for supplying the voltage.

One side of the second charging part 162 is connected to the output side of the first charging part 161 and the input side of the second LED group 142 and is connected to the second charging part 142 according to the magnitude of the voltage supplied from the AC power source 120 And supplies the voltage for the operation of the second LED group 142 or the power supplied from the AC power supply 120 for supplying the voltage.

The third charging unit 163 has one side connected to the output side of the second charging unit 162 and the input side of the third LED group 143, Supplies the voltage for the operation of the third LED group 143 or charges the power supplied from the AC power source 120 for supplying the voltage.

Next, one side of the first constant current circuit 171 is connected to the output side of the first LED group 141 to provide a constant first current I ₁ to the first LED group 171.

The second constant current circuit 172 is connected to the output side of the second LED group 142 to provide a constant second current I ₂ from the output side of the second LED group 142 to the second LED group 142 do.

One end of the third constant current circuit 173 is connected to the output side of the third LED group 143 to provide a constant third current I ₃ from the output side of the third LED group 143 to the third LED group 143 do.

One end of the fourth constant current circuit 174 is connected to the second drive current control part 152 and the output side contacts of the third charge and discharge part 163 and the third constant current circuit 173 to provide the fourth current I ₄ .

The first diode D _f1 is located between the first charging portion 161 and the second charging portion 162 to suppress the voltage flowing backward from the second charging portion 162.

The second diode D _f2 is located between the second charging unit 162 and the third charging unit 163 to suppress the voltage flowing backward from the third charging unit 163.

9B, when the input voltage is smaller than the third charging unit 163, the first charging unit 161, the second charging unit 162, or the third charging unit 163, And drives the first LED group 141, the second LED group 142, or the third LED group 143 with the energy of the first LED group 141, the second LED group 142, and the third LED group 143, respectively.

Alternatively, when the input voltage is greater than the voltage of the third charging unit 163 and less than the sum of the first charging unit 161 and the second charging unit 162, the first charging unit 161 and the second charging unit 162, The first LED group 141 and the second LED group 142 are driven by the energy of the front portion 162 and the first driving current control portion 151 is turned on and the third LED group 143 is driven . At this time, the input current begins to flow and the fourth constant current circuit 174 drives with the lowest current (L ₃ ).

On the other hand, if the input voltage is greater than the sum of the voltages of the first charging and discharging unit 161 and the second charging and discharging unit 162 and smaller than the sum of the first charging charging unit 161 to the third charging charging unit 163, The current control unit 151 is turned off and the second driving current control unit 152 is turned on so that the first LED group 141 and the second LED group 142 are driven by the input voltage, And is driven by the third charging unit 163. At this time, the current of the fourth constant current circuit 174 is driven to the intermediate value L ₂ . That is, the input current is driven to an intermediate value.

Next, if the input voltage is greater than the sum of the first to third charging units 161 to 163, the input voltage drives the first to third LED groups 141 to 143, The first to third charging units 161 to 163 are charged. At this time, the fourth constant current circuit 174 is driven with the highest current L ₁ . That is, the input current has the highest current.

10A is a configuration diagram of a flicker-improved LED direct drive apparatus according to another embodiment of the present invention.

Referring to FIG. 10A, a flicker-improved LED direct drive apparatus according to another embodiment of the present invention includes an AC power source 220, a rectifier 230, a first LED group 241, a second LED group 242, The third LED group 243, the fourth LED group 243, the first driving current control unit 251, the second driving current control unit 252, the third driving current control unit 253, the fourth driving current control unit The second charging unit 262, the third charging unit 263, the fourth charging unit 264, the first constant current circuit 271, the second constant current circuit 272, A third constant current circuit 273, a fourth constant current circuit 274, a fifth constant current circuit 275, a first diode D _f1 , a second diode D _f2 and a third diode D _f3 .

This configuration increases the number of LED groups from two to four as compared with the structure disclosed in FIG. 3A, and thus the number of constant current circuits increases from three to five. Then, the number of driving current control sections increased from two to four.

The AC power source 220 supplies power for driving the first LED group 241, the second LED group 242, the third LED group 243 and the fourth LED group 244 The output side of which is connected to the input side of the first LED group 241 and is connected to the input side of the second LED group 242 via the first LED group 241 and the second drive current control unit 252 And is connected to the fourth LED group 244 via the first driving current control unit 251. The fourth LED group 244 is connected to the third LED group 243 via the first driving current control unit 251. [

The rectifying unit 230 is connected between the output side of the AC power source 220 and the input side of the first LED group 241 and more specifically the output side of the rectifying unit 230 The first drive current control unit 251, the second drive current control unit 252, the fourth drive current control unit 254 and the first charge current control unit 252 (the output side of the diode BD ₁ ) The first driving current control unit 251, the second driving current control unit 252, the fourth driving current control unit 251, and the second driving current control unit 252. The first driving current control unit 251, the second driving current control unit 252, 254 and the first charging and discharging unit 261, respectively.

At this time, the first LED group 241, the second LED group 242, the third LED group 243, and the fourth LED group 244 are connected to each other in such a manner that a plurality of LED arrays, each including a plurality of LEDs connected in series, And may be configured in a parallel connection manner.

In this configuration, the first LED group 241 to the fourth LED group 244 are connected in series.

The first driving current controller 251 is connected in parallel with the first LED group 241 to the third LED group 243 and is connected in series with the fourth LED group 244. In other words, the first driving current control unit 251 is connected in parallel with the first LED group 241 to the third LED group 243, and the output side is connected to the input side of the fourth LED group 244.

One end of the first driving current control unit 251 is connected to the contact between the first LED group 241 and the first charging unit 261 and the AC power source 20 is connected to the capacitor If it is larger than the voltage V _C4 , the first input current i _Q1 supplied from the AC power source 220 is received and switched. Here, the first driving current controller 251 may be implemented as a MOSFET or a transistor.

The second driving current control unit 252 is connected in parallel with the first LED group 241 and the second LED group 242.

One end of the second driving current control unit 252 is connected to the third charging unit 263 and the AC power supply 20 is connected to the sum of the capacitor voltages V _C3 and V _C4 according to the voltage level of the AC power supply 220. [ The second input current i _Q2 supplied from the AC power source 220 is input and the second input current i _Q2 is switched. Here, the second driving current controller 252 may be implemented by a MOSFET or a transistor.

The third driving current control unit 253 is connected in parallel with the third LED group 243 and the fourth LED group 244. [

One end of the third driving current control unit 253 is connected to the third charging unit 263 and the AC power supply 20 is connected to the sum of the capacitor voltages V _C1 and V _C2 according to the voltage level of the AC power supply 220. The third input current i _Q3 supplied from the AC power source 220 is input and the third input current i _Q3 is switched. Here, the third driving current controller 253 may be implemented as a MOSFET or a transistor.

One end of the fourth driving current control unit 254 is connected to a contact between the first LED group 241 and the first charging unit 261 and the AC power supply 20 is connected to the capacitor If it is greater than the sum of voltages V _C1 , V _C2 and V _C3 , And receives the fourth input current i _Q4 supplied from the AC power source 220 and switches it. Here, the fourth driving current control unit 254 may be implemented as a MOSFET or a transistor.

The first charging unit 261 has one side connected to the output side of the rectifying unit 220 and the input side of the first LED group 241, Supplies the voltage for the operation of the LED group 241 or the power supplied from the AC power supply 220 for supplying the voltage.

One side of the second charging and discharging unit 262 is connected to the output side of the first charging unit 261 and the input side of the second LED group 242. Depending on the magnitude of the voltage supplied from the AC power source 220 And supplies the voltage for the operation of the second LED group 242 or the power supplied from the AC power supply 220 for supplying the voltage.

On the other hand, the third charging unit 263 has one side connected to the output side of the second charging unit 262 and the input side of the third LED group 243, and is connected to the third charging unit 243 according to the magnitude of the voltage supplied from the AC power source 220 And supplies the voltage for the operation of the third LED group 243 or the power supplied from the AC power supply 220 for supplying the voltage.

The fourth charging unit 264 has one side connected to the output side of the third charging unit 263 and the input side of the fourth LED group 244, Supplies the voltage for the operation of the LED group 244 or the power supplied from the AC power supply 220 for supplying the voltage.

Next, one side of the first constant current circuit 271 is connected to the output side of the first LED group 241 to provide a constant first current I ₁ to the first LED group 271.

The second constant current circuit 272 has one side connected to the output side of the second LED group 242 to provide a constant second current I ₂ from the output side of the second LED group 242 to the second LED group 242 do.

One end of the third constant current circuit 273 is connected to the output side of the third LED group 243 to provide a constant third current I ₃ from the output side of the third LED group 243 to the third LED group 243 do.

The fourth constant current circuit 274 is connected to the output side of the fourth LED group 244 to provide a constant fourth current I ₄ from the output side of the fourth LED group 244 to the fourth LED group 244. [ do.

One end of the fifth constant current circuit 275 is connected to the third drive current control unit 253 and the output side contacts of the fourth charge and discharge unit 264 and the fourth constant current circuit 274 to provide a fifth current I ₅ .

On the other hand, the first diode D _f1 is positioned between the first charging part 261 and the second charging part 262 to suppress the voltage flowing backward from the second charging part 262.

The second diode D _f2 is positioned between the second charging unit 262 and the third charging unit 263 to suppress the voltage flowing backward from the third charging unit 263.

The third diode D _f3 is located between the third charging unit 263 and the fourth charging unit 264 and suppresses the voltage flowing backward from the fourth charging unit 264.

 10B, when the input voltage is lower than the fourth charging unit 264, the first charging unit 261, the second charging unit 262, the third charging unit 263, The second LED group 242, the third LED group 243 or the fourth LED group 244 with the energy of the first charging unit 264 or the energy of the fourth charging unit 264, respectively.

Alternatively, when the input voltage is greater than the voltage of the fourth charging unit 264 and less than the sum of the third charging unit 263 and the fourth charging unit 264 (the voltage of the third charging unit and the charging voltage of the fourth charging unit 264 The sum of the voltages of the first and second charging units is equal to the sum of the voltages of the first and second charging units), the first driving current control unit 251 is turned on so that the input voltage drives the fourth LED driving unit 244, The first LED group 241, the second LED group 242 and the third LED group 243 are driven by the energy of the front portion 261, the second charging portion 262 and the third charging portion 263 . At this time, the fifth constant current circuit is driven with the lowest current (L ₄ ).

Alternatively, when the input voltage is greater than the sum of the third charging and discharging unit 263 and the fourth charging and discharging unit 264 and less than the sum of the second charging and discharging unit 262 to the fourth charging and discharging unit 264, The second drive current control unit 262 and the third drive current control unit 263 are turned on so that the input voltage is applied to the first and second LED groups 241 and 243, (243) and the fourth LED group (244) in parallel. At this time, the fifth constant current circuit 275 is driven with the second lowest current L ₃ .

On the other hand, if the input voltage is greater than the sum of the voltages of the second to fourth charging units 262 to 264 and smaller than the sum of the first charging charging unit 261 to the fourth charging charging unit 264, The current control unit 252 and the third driving current control unit 253 are turned off and the fourth driving current control unit 254 is turned on so that the second LED group 242 to the fourth LED group 244 are driven by the input voltage , The first LED group 241 is driven by the first charging unit 261. At this time, the fifth constant current circuit is driven to the _second largest value (L ₂ ).

Next, when the input voltage is greater than the sum of the first to fourth charging units 261 to 264, the input voltage drives the first to fourth LED groups 241 to 244, The first to fourth charging units 261 to 264 are charged by the voltage. At this time, the fifth constant current circuit is driven with the highest current (L ₁ ).

11 is an exemplary view illustrating the LED direct drive apparatus shown in FIG. 3A.

11, the LED direct drive apparatus according to the present embodiment includes an AC power supply 20, a rectifying unit 30, a first LED group 41, a second LED group 42, The second constant current circuit 71, the second constant current circuit 72, the third constant current circuit 71, the second drive current control unit 52, the first charge and discharge unit 61, the second charge and discharge unit 62, A first diode _Df1 , a second diode _Df2 , an input voltage sensing unit 80, a first operation control unit 91, and a second operation control unit 92, as shown in FIG.

The first driving current control unit 51 includes a first P-channel MOSFET Q ₁ having a source terminal connected to a power source, a first Zener diode Z _D1 connected between a source and a gate of the first MOSFET, the first consists of the first switch voltage division resistance (R _gs1), a first switch voltage division resistors second switch voltage division resistance (R _gn1) connected in series to a connected between the source and the gate of the MOSFET.

The operation of the P-channel first MOSFET is such that a current flows from the source to the drain when the gate of the P-channel first MOSFET falls to a certain negative voltage. To this end, the first MOSFET is when the second MOSFET 6 (q ₆₎ of the first operation control unit 91 operates the gate of the first MOSFET source drops to negative contrast.

At this time, the falling ratio is reduced by the partial voltage ratio of the first switch voltage distribution resistor and the second switch voltage distribution resistor, and in such a situation, the first Zener diode limits the voltage falling above a specific voltage.

Next, the second driving current control section 52 includes a P-channel second MOSFET Q ₂ having a source terminal connected to the output side of the first LED group 41 and a second MOSFET Q ₂ connected between the source and the gate of the second MOSFET a zener diode (Z _D2) and, the second is connected between the source and the gate of 2 MOSFET 3 switches the voltage division resistance (R _gs2) and the third and the fourth switch the voltage division resistance (R _gn2) connected in series to the switch voltage division resistor consist of.

The operation of the second P-channel MOSFET is such that the current flows from the source to the drain when the gate of the second MOSFET falls to a certain negative voltage. To this end, the second MOSFET to the second when the first MOSFET 7 (q ₇₎ of the operation control section 92 to operate the gate of the second MOSFET drops to sound source preparation.

At this time, the falling ratio is lowered by the partial voltage ratio of the third switch voltage dividing resistor and the fourth switch voltage dividing resistor, and the second zener diode limits the falling to a specific voltage or higher in such a situation.

On the other hand, the first constant current circuit 71 includes a first LED group 41, a drain connected to the output-side N-channel Claim 3 MOSFET (Q _11), a first constant-voltage distribution resistor connected to the output of the power supply (20) (R _B1 of A second constant voltage distribution resistor R _B11 connected between the first constant voltage distribution resistor and the gate of the third MOSFET and a second shunt regulator R _B11 connected between the gate of the third MOSFET and the input side of the second drive current control section 52. [ (u ₁₎ and the third first sensing distribution resistor connected between the source and the second drive current control first sensing resistor connected between the (R _S1) and the first shunt regulator and the first sensed resistance of the MOSFET (R _gs2) and connected to the first constant voltage distribution resistor and the input side of the second constant voltage distribution resistor contact and a second drive current control unit of claim 3 includes a zener diode (Z _D3).

In this configuration, to drive the gate of the third MOSFET, a driving voltage is generated using the first constant voltage distribution resistor and the third zener diode from the both end voltages of the first charging unit and the gate is driven through the third constant voltage distribution resistor, Allows current to flow through the MOSFET.

Once the current flows, the voltage is changed to the voltage through the first sensing resistor and the cathode voltage of the first shunt regulator falls when the voltage becomes the reference voltage (2.5V or 1.25V) of the first shunt regulator. That is, the third MOSFET enters the active region in the saturation region, becomes the variable resistance of the third MOSFET, flows the current flowing through the third MOSFET to the (reference voltage) / (the first sensing resistance value) do.

Next, the second constant current circuit 72, the second LED group 42, a third constant voltage distribution and a drain connected to the output-side N-channel Claim 4 MOSFET (Q _12), connected to the output side of the first LED group 41 of the resistance claim connected to the input side of the (R _B2) and a third constant-voltage distribution resistor and a fourth fourth constant-voltage distribution resistor (R _B21) and a fourth MOSFET gate and the third constant current circuit 73 of the connected between the gate of the MOSFET second shunt regulator (u ₂₎ and the fourth second sensing resistor (R _S2) and a second second sensing distribution and shunt regulator coupled between the second sense resistor resistance source and the coupled between the third constant current circuit of the MOSFET (R _gs3 ), and a fourth zener diode (Z _D4 ) connected to a contact of the third constant voltage distribution resistor and the fourth constant voltage distribution resistor and an input side of the third constant current circuit.

The operation of the second constant current circuit 72 is similar to that of the first constant current circuit 72, and a detailed description thereof will be omitted.

Next, a third constant current circuit 73, the second drain to the output side N-channel fifth MOSFET (Q ₁₃₎ connected to the constant current circuit 72 and a second fifth voltage distribution connected to the input side of chungbang parts (61) the coupled between the resistance (R _B3) and, connected to the output side of the input voltage sensing unit 80, the sixth constant-voltage distribution resistor (R _B4) and a fifth constant-voltage gate of a distributed resistance and the sixth voltage distribution resistor and a fifth MOSFET 7, the constant-voltage distribution resistor (R _B31) and the third shunt regulator coupled between the gate and the power supply 20 of the 5 MOSFET (u ₃₎ and the third sensing resistor connected between the source and the power supply of claim 5 MOSFET (R _S3 A third sensing distribution resistor R _gs4 connected between the third shunt regulator and the third sensing resistor, and a fifth sensing resistor R _gs2 connected between the fifth constant voltage distribution resistor and the sixth constant voltage distribution resistor and a fifth zener diode Z _D5 ).

The operation of the third constant current circuit 73 is similar to that of the first constant current circuit 72, and a detailed description thereof will be omitted. In this configuration, a gate voltage is generated by using the fifth constant voltage distribution resistor and the fifth zener diode from the voltage between both ends of the second charge and discharge unit for driving the gate of the fifth MOSFET, and the gate is driven through the seventh constant voltage distribution resistor A current is made to flow through the fifth MOSFET or a drive voltage is generated from the output voltage of the input voltage sensing unit 80 by using the sixth constant voltage distribution resistor and the fifth Zener diode and the gate is driven through the seventh constant voltage distribution resistor, Because the current flows through the MOSFET, it can provide two kinds of constant currents.

Next, the input voltage sensing unit 80 includes a first input voltage distribution resistor R ₁₁ , a second input voltage distribution resistor R ₁₂ , and a third input voltage distribution resistor R ₁₂ connected in series between the input side and the output side of the power source 20. An input voltage distribution resistor R ₁₃ and a fourth input voltage distribution resistor R ₁₄ .

The input voltage sensing unit 80 includes a fourth shunt regulator u ₄ connected to the contacts of the second input voltage distribution resistor and the third input voltage distribution resistor and to the output side of the power source.

The input voltage sensing unit 80 divides the first input voltage dividing resistor to the fourth input voltage dividing resistor and provides the divided voltage. The fourth shunt regulator reflects the voltage, and when the voltage exceeds the predetermined voltage, the reference voltage to provide.

On the other hand, the first operation control section (91) of claim 1 and comprises a first 6 MOSFET (q ₆₎ connected to the driving current control and the output side of the power source the second operation control unit 92 has an output side of the second drive current control and power a seventh MOSFET includes (q ₇₎ connected to.

The first operation control section 91 and the second operation control section 92 may be configured such that the input voltage is greater than the voltage of the first charge / discharge section or the second charge / discharge section and smaller than the sum of the first charge / discharge section and the second charge / discharge section The first driving current control unit and the second driving current control unit are turned on. In order to realize this, the first operation control unit 91 and the second operation control unit 92 are turned off only when the voltage is higher than the sum of the first charge / discharge unit and the second charge / discharge unit. The first operation control unit 91 and the second operation control unit 92 are operated when the input voltage is lower than the voltage of the first or second charge / discharge unit.

I.e. the input voltage is increased two first chungbang all the second chungbang the sum becomes larger than the voltage input voltage sensing portion of all four shunt regulator and is a (low) This of claim ₈ MOSFET (q 8) has a drain It becomes high.

Claim 8 MOSFET that is a ninth MOSFET (q ₉₎ operates as a high, the ninth voltage is applied to the third shunt regulator as the MOSFET is operated the third sensing distribution resistor (R _gs4) and a fourth sensing distribution Is decreased due to the voltage-dividing resistance of the resistor R _d9 , so that the current level controlled by the third constant current circuit is increased.

Also, as the drain of the eighth MOSFET becomes high, the tenth MOSFET (q10) is turned on and the sixth MOSFET and the seventh MOSFET are turned off, so that the first MOSFET and the second MOSFET also stop operating.

12 shows the capacitor voltage, the DC link voltage, the LED current, and the input current waveform, and FIG. 13 shows the LED driving state according to the present invention.

As shown in FIG. 12, according to the present invention, the current flowing through the LED is constant, thereby providing an improved LED having no flicker as shown in FIG.

20, 120, 220: Power
30, 130, and 230:
41, 42, 141, 142, 143, 241, 242, 243, 244:
51, 52, 151, 152, 251, 252, 253:
61, 62, 161, 162, 163, 261, 262, 263, 264:
71, 72, 73, 171, 172, 173, 174, 271, 272, 273, 284:
80: Input voltage sensing section 91, 92: Operation control section

Claims (16)

A first LED group connected to an output side of an AC power source for supplying power to the input side;
A first constant current circuit whose input side is connected to the output side of the first LED group;
A first charging unit connected to an output side of an AC power source for supplying power to the input side;
A first driving current control unit connected to an output side of an AC power source for supplying power to the input side;
A second charging unit connected in series with the first charging unit;
A second LED group connected in parallel to the second charging unit;
A second constant current circuit whose input side is connected to the output side of the second LED group;
A second driving current controller connected in parallel to the second LED group; And
And a third constant current circuit for providing a constant current to the second LED group, the second driving current control unit, and the second charging unit,
Wherein the first driving current control unit and the second driving current control unit are turned on when the input voltage is higher than the voltage of the first charging unit or the second charging unit, thereby providing a current path. The method according to claim 1,
Further comprising a first diode positioned between the first and second charging units to block a current flowing back in the second charging unit. The method according to claim 1,
The third constant current circuit
A first divided constant current circuit connected to the output side of the second charging and discharging circuit and the output side of the second constant current circuit for providing a constant current; And
And a second divided constant current circuit connected to the output side of the second drive current control unit for providing a constant current. The method according to claim 1,
Wherein the first driving current control unit and the second driving current control unit are turned off when the sum of the voltages of the first and second charging and discharging units is greater than the input voltage. The method of claim 1, wherein
Wherein the third constant current circuit provides a first constant current if the input voltage is greater than the voltage of the first charging or discharging part and if the input voltage is greater than the sum of the voltages of the first charging and discharging part, 2 < / RTI > constant current, and the second constant current is greater than the first constant current. A first LED group connected to an output side of an AC power source for supplying power to the input side;
A first constant current circuit whose input side is connected to the output side of the first LED group;
A first charging unit connected to an output side of an AC power source for supplying power to the input side;
A first driving current control unit connected to an output side of an AC power source for supplying power to the input side;
A second charging unit connected in series with the first charging unit;
A second LED group connected in parallel to the second charging unit;
A second constant current circuit whose input side is connected to the output side of the second LED group;
A second driving current controller connected in parallel to the second LED group;
A first divided constant current circuit connected to the output side of the second charging and discharging circuit and the output side of the second constant current circuit for providing a constant current; And
And a second divided constant current circuit connected to the output side of the second driving current control part for providing a constant current,
Wherein the first driving current control unit and the second driving current control unit are turned on when the input voltage is higher than the voltage of the first charging unit or the second charging unit, thereby providing a current path. A first LED group connected to an output side of an AC power source for supplying power to the input side;
A first constant current circuit whose input side is connected to the output side of the first LED group;
A first charging unit connected to an output side of an AC power source for supplying power to the input side;
A first driving current control unit connected to an output side of an AC power source for supplying power to the input side;
A second charging unit connected in series with the first charging unit;
A second LED group connected in parallel to the second charging unit;
A second constant current circuit whose input side is connected to the output side of the second LED group;
A third charging unit connected in series to the second charging unit;
A third LED group connected in parallel to the third emitter;
A third constant current circuit connected to the output side of the third LED group;
A second driving current controller connected in parallel to the third LED group; And
And a third constant current circuit for providing a constant current to the third LED group, the second driving current control unit, and the third charging unit,
Wherein the first driving current control unit is turned on when the input voltage is greater than the voltage of the third charging unit and off when the input voltage is greater than the sum of the voltages of the first charging unit and the second charging unit, The first and second charging units are turned on when the sum of the voltages of the first charging unit and the second charging unit is greater than the sum of the voltages of the first charging unit and the second charging unit. The method of claim 7,
A first diode positioned between the first charging unit and the second charging unit to block a current flowing backward from the second charging unit; And
Further comprising a second diode positioned between the second and third charging units to block current flowing back in the third charging unit. The method of claim 7,
Wherein the first driving current control unit is turned on when the input voltage is greater than the voltage of the third charging unit and off when the sum of the first charging unit and the second charging unit is greater than the sum of the first charging unit and the second charging unit,
Wherein the second driving current control unit is turned on when the input voltage is greater than the sum of the voltages of the first and second charging units and is turned off when the sum of the first and second charging units is greater than the sum of the first and second charging units, The improved LED straightening device. The method of claim 9,
Wherein the first and second LED groups are turned on when the first and second drive current control units are turned off. The method of claim 7,
Wherein the fourth constant current circuit provides a first constant current when the input voltage is greater than the voltage of the first charging unit and provides a second constant current when the input voltage is greater than the sum of the first charging unit and the second charging unit, The second constant current is larger than the first constant current, and the third constant current is larger than the second constant current, the flicker is improved. A first LED group connected to an output side of an AC power source for supplying power to the input side;
A first constant current circuit whose input side is connected to the output side of the first LED group;
A first charging unit connected to an output side of an AC power source for supplying power to the input side;
A first driving current control unit connected to an output side of an AC power source for supplying power to the input side;
A second charging unit connected in series with the first charging unit;
A second LED group connected in parallel to the second charging unit;
A second constant current circuit whose input side is connected to the output side of the second LED group;
A third charging unit connected in series to the second charging unit;
A third LED group connected in parallel to the third emitter;
A third constant current circuit connected to the output side of the third LED group;
A second driving current controller connected in parallel to the first LED group and the second LED group;
A fourth charging unit connected in series to the third charging unit;
A fourth constant current circuit connected in series to the fourth charging unit;
A third driving current controller connected in parallel to the third charging unit and the fourth charging unit;
A fourth driving current controller connected in parallel to the first charging unit; And
And a fifth constant current circuit for providing a constant current to the fourth LED group, the third driving current control unit and the fourth charging unit,
Wherein the first driving current control unit is on when the input voltage is greater than the voltage of the fourth charging unit and the second driving current control unit is on when the input voltage is greater than the sum of the voltages of the third charging unit and the fourth charging unit, The third drive current control unit may be turned on when the input voltage is greater than the sum of the voltages of the first and second charge and discharge units and the fourth drive current control unit is turned on when the input voltage is higher than the second charge, And the flicker is turned on if the sum of the voltages of the fourth and fifth charging units is greater than the sum of the voltages of the fourth and fifth charging units. The method of claim 12,
A first diode positioned between the first charging unit and the second charging unit to block a current flowing backward from the second charging unit;
A second diode positioned between the second charging unit and the third charging unit to block current flowing backward from the third charging unit; And
And a third diode positioned between the third and fourth charging and discharging blocks to shut off the current flowing in the fourth charging and discharging part. The method of claim 12,
Wherein the fifth constant current circuit provides a first constant current when the input voltage is greater than the voltage of the fourth charging unit and provides a second constant current when the input voltage is greater than the sum of the voltages of the third charging unit and the fourth charging unit, If the input voltage is greater than the sum of the voltages of the second and third charging and discharging units and the fourth charging and discharging unit and provides the third constant current when the input voltage is greater than the sum of the voltages of the first charging to fourth charging, Wherein the second constant current is larger than the first constant current, the third constant current is larger than the second constant current, and the fourth constant current is larger than the third constant current. In the flicker-improved LED direct drive apparatus,
The first LED group is connected to the output side of the AC power supply for supplying power to the input side, the output side is connected to the first constant current circuit, the parallel connection is connected to the first charging unit,
The first driving current control unit is connected in parallel to the first LED group,
The second LED group is connected in parallel to the second charging unit connected in series to the first charging unit,
The second driving current control unit is connected in parallel to the second LED group,
The first constant current circuit supplies a constant current to the first LED group, the second constant current circuit provides a constant current to the second LED group, and the third constant current circuit supplies the constant current to the second LED group, An improved flicker-free LED direct drive device that provides a constant current to the charge. A first LED group connected to an output side of an AC power source for supplying power to the input side;
A first constant current circuit whose input side is connected to the output side of the first LED group;
A first charging unit connected to an output side of an AC power source for supplying power to the input side;
A first driving current control unit connected to an output side of an AC power source for supplying power to the input side;
A second charging unit connected in series with the first charging unit;
A second LED group connected in parallel to the second charging unit;
A second constant current circuit whose input side is connected to the output side of the second LED group;
A second driving current controller connected in parallel to the second LED group;
A third constant current circuit for providing a constant current to the second LED group, the second driving current control unit, and the second charging unit;
An input voltage sensing unit connected to an input side and an output side of the AC power source to sense an input voltage;
A first operation control unit connected to the input voltage sensing unit and the second charge / discharge unit to turn on the first drive current control unit when an input voltage becomes higher than a voltage of the second charge / discharge unit; And
And a second operation control unit connected to the input voltage sensing unit and the second charge and discharge unit to turn on the second drive current control unit when an input voltage becomes higher than a voltage of the second charge and discharge unit.

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