KR20160021961A - Apparatus for constant current driving with improving power factor - Google Patents

Abstract

The present invention relates to an apparatus and method for driving a constant current from an input of commercial alternating current power and, more specifically, to a constant current apparatus and method for effectively driving an LED. The apparatus for driving an LED according to the present invention comprises: first to third LED groups connected to an alternating current power source; a rectifier part; an input voltage sensing part; a charge and discharge part; first to third driving current control parts; and first and second flicker improving parts, wherein a voltage charged in the charge and discharge part is provided to at least one of the first to third LED groups when the sensed input voltage reaches a predefined critical value or less.

Description

TECHNICAL FIELD [0001] The present invention relates to a fixed current driving device having a power factor improving effect,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for inputting commercial AC power and driving a fixed current, and more particularly, to a fixed current apparatus and method effective for driving an LED.

Generally, AC LED can be operated without a separate power supply such as SMPS (Switching-Mode Power Supply), but has a low power factor due to a large amount of harmonics, There is inevitably a section where the input current is 0 (zero), which causes a flicker phenomenon.

In order to solve such a problem, Korean Patent No. 10-1198408 has proposed a method of suppressing the occurrence of flicker by using a valley fill circuit to continuously flow some currents flowing through the LED. However, in the conventional technology, only the current flowing in some LEDs can be continuously controlled, and the input current is not controlled by the capacitor charging current of the valley fill circuit, which causes an overcurrent, which causes a rise in the crest factor There was a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the conventional art, and it is an object of the present invention to provide a flicker- And a second flicker improvement unit connected in series with the third LED group, so that the LED current is continuously supplied. When the input voltage is low using the input voltage sensing unit, the LED is driven by the energy charged in the capacitor The present invention relates to a device for directly driving an LED in an alternating current.

Another object of the present invention is to provide a method and an apparatus for continuously flowing an LED current by using a flicker improvement unit connected in parallel with a first LED group and connected in series with a second LED group, To an apparatus for directly driving an LED for driving an LED with charged energy.

However, the objects of the present invention are not limited to those mentioned above, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an apparatus for driving an LED, including: a first LED group connected to an output side of an AC power source for supplying power to an input side; A second LED group whose input side is connected to the output side of the first LED group; A third LED group whose input side is connected to the output side of the second LED group; A rectifying part connected between the output side of the ac power source and the first LED group input side; An input voltage sensing unit connected to an output side of the rectifying unit and an input side of the first LED group to sense an input voltage; A charging unit having one side connected to an output side of the rectifying unit and an input side of the first LED group; A first driving current control unit connected to an output side of the first LED group and switching a first input current input from an output side of the first LED group; A second driving current control unit connected to the second LED group output side and switching a second input current input from the output side of the second LED group; A third driving current control unit connected to the third LED group output side to switch a third input current input from the output side of the third LED group; A first flicker improving unit connected in parallel with the first LED group and having an output connected to an input side of the second LED group; A second flicker improving unit connected in parallel with the second LED group and having an output connected to an input side of the third LED group; Wherein when the sensed input voltage is less than a predetermined threshold value, a voltage charged in the charging unit is provided to at least one of the first LED group, the second LED group, and the third LED group. do.

A first diode coupled between the first LED group output side and the second LED group input side; And a second diode coupled between the output side of the second LED group and the input side of the third LED array group.

If the input voltage sensed by the input voltage sensing unit is smaller than the sum of the forward voltage of the first LED group and the forward voltage of the second LED group, the first flicker improving unit, And the first to third diode groups may be supplied with the current charged in the charging unit via the third driving current control unit or a large voltage of the input voltage.

The input voltage sensed by the input voltage sensing unit is greater than the sum of the forward voltage of the first LED group and the forward voltage of the second LED group and the sum of the forward voltage of the first LED group and the forward voltage of the third LED group The current is supplied to the first and second diode groups by the input voltage via the second driving current control unit and the current is supplied to the charging and discharging unit via the second flicker improving unit and the third driving current control unit, The current can be supplied to the third diode group by the voltage charged in the third diode group.

When the input voltage sensed by the input voltage sensing unit is greater than the sum of the forward voltages of the first to third LED groups, A current can be provided to the third diode group.

Here, when the input voltage sensed by the input voltage sensing unit is larger than the sum of the forward voltages of the first to third LED groups, the input voltage is higher than the sum of the forward voltages of the first to third LED groups It is possible to control the current supplied via the three drive current control part to be larger than the case where the current is small.

According to another aspect of the present invention, there is provided an apparatus for driving an LED, including: a first LED group connected to an output side of an AC power source for supplying power to an input side; A second LED group whose input side is connected to the output side of the first LED group; A rectifying part connected between the output side of the ac power source and the first LED group input side; An input voltage sensing unit connected to an output side of the rectifying unit and an input side of the first LED group to sense an input voltage; A charging unit having one side connected to an output side of the rectifying unit and an input side of the first LED group; A drive control voltage generating unit having one side connected to the charging unit and the input side of the first LED group; One end of the first LED group is connected to the drive control voltage generator and the output side of the first LED group, and the other end of the first LED group is operated by a voltage generated by the drive control voltage generator, A first driving current control unit for controlling the constant current; One of which is connected to the drive control voltage generator and the second LED group output side and is operated by a voltage generated by the drive control voltage generator to generate a second input current input from the output side of the second LED group, A third driving current control unit for controlling the second driving current; A flicker improvement unit connected in parallel with the first LED group and having an output connected to an input side of the second LED group; And supplies a voltage charged in the capacitor constituting the charge / discharge unit to at least one of the first LED group and the second LED group when the sensed input voltage becomes a predetermined threshold value or less .

Wherein the input voltage sensing unit includes: a first Zener diode having one side connected to a contact point of the rectifying unit and the first LED group; A resistor serially connected to the other side of the first Zener diode; And a second Zener diode connected in series with the other side of the resistor.

The first Zener diode may be set to have a value equal to or greater than a sum of a voltage of the first LED group and a forward voltage of the second LED group.

The apparatus may further include an operation controller connected to an input side of the flicker improvement unit, one side of which controls an operation of the flicker improvement unit according to a voltage magnitude of the AC power source.

Here, the operation control unit may turn off the flicker improvement unit when the input voltage supplied from the AC power source is greater than a predetermined threshold value and current flows in series to the first and second LED groups.

On the other hand, the apparatus comprises: a first diode connected between the output side of the flicker improvement section and the input side of the second LED group; And a second diode coupled between the output side of the first LED group and the input side of the second LED array group.

Wherein the first diode allows a second input current passing through the flicker improving unit to be supplied to the third driving current control unit through the second LED group according to the magnitude of the voltage supplied from the AC power source, The second input current passed through the first LED group may be supplied to the third driving current control unit through the second LED group according to the magnitude of the voltage supplied from the AC power source.

The third driving current control unit may include a second switch having one side connected to the output side of the second LED group and receiving the second input current; And a second current controller connected to the second switch and configured to control the second input current by a constant current.

The third driving current control unit may further include a MOSFET that is turned on when a current flows in the first LED group and the second LED group in order to further flow the current.

The apparatus further includes a fourth driving current control unit connected to the output side of the charging unit and operated by a voltage supplied from the charging unit and performing a constant current control on a fourth input current supplied from the charging unit It is possible.

Here, the fourth driving current control unit may be connected to the operation control unit.

The third driving current control unit may further include a switch connected to the operation control unit.

According to an aspect of the present invention, there is provided an apparatus for driving an LED, including: a first LED group connected to an output side of an AC power source for supplying power to an input side; A second LED group whose input side is connected to the output side of the first LED group; A rectifying part connected between the output side of the ac power source and the first LED group input side; A charging unit having one side connected to an output side of the rectifying unit and an input side of the first LED group; A drive control voltage generating unit having one side connected to the charging unit and the input side of the first LED group; One end of the first LED group is connected to the drive control voltage generator and the output side of the first LED group, and the other end of the first LED group is operated by a voltage generated by the drive control voltage generator, A first driving current control unit for controlling the constant current; One of which is connected to the drive control voltage generator and the second LED group output side and is operated by a voltage generated by the drive control voltage generator to generate a second input current input from the output side of the second LED group, A third driving current control unit for controlling the second driving current; A fourth driving current control unit connected between the charging and discharging unit and operated by a voltage supplied from the charging unit and performing a constant current control on a fourth input current supplied from the charging unit; A flicker improving unit connected in parallel with the first LED group and having an output connected to an input side of the second LED group; And an operation control unit connected to the input side of the flicker improvement unit and having one side connected to the input side of the flicker improvement unit and controlling an operation of the flicker improvement unit according to a voltage level of the AC power source, And the charging current of the battery is sensed.

The first flicker enhancement unit includes a first flicker improvement unit connected in parallel with the first LED group and a second flicker improvement unit connected in parallel with the second LED group, and a second flicker improvement unit connected in parallel with the third LED group. In the case where the input voltage is low by using the input voltage sensing unit, the LED is driven by the energy charged in the capacitor, thereby making the flow of the LED current in all the sections to make the flicker generation rate considerably lower There is an effect that can be.

Also, since the present invention is applied to charging or discharging current flow of a capacitor, not only an LED current but also an input current can be controlled to greatly reduce the crest factor.

1 is a first diagram showing an apparatus for driving an LED according to an embodiment of the present invention.
2 is a first diagram for explaining the operation of the LED driving apparatus shown in FIG.
3 is a second diagram for explaining the operation of the LED driving apparatus shown in FIG.
4 is a third diagram for explaining the operation of the LED driving apparatus shown in FIG.
FIG. 5 is an exemplary view illustrating an apparatus for driving the LED shown in FIG. 1. FIG.
6 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.
7 is a first diagram for explaining the operation of the LED driving apparatus shown in Fig.
8 is a second diagram for explaining the operation of the LED driving apparatus shown in FIG.
FIG. 9 is a third diagram for explaining the operation of the LED driving apparatus shown in FIG.
10 is a fourth diagram for explaining the operation of the LED driving apparatus shown in FIG.
11 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.
12 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.
13 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.
14 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.
15 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.
16A and 16B show the current-voltage waveform of the LED driving apparatus according to the embodiment of the present invention and the flicker picture compared with the prior art.
17A to 17B show the current-voltage waveform of the LED driving apparatus according to the embodiment of the present invention and the flicker picture compared with the prior art.

Hereinafter, an apparatus for driving an LED according to an embodiment of the present invention will be described with reference to the accompanying drawings. The present invention will be described in detail with reference to the portions necessary for understanding the operation and operation according to the present invention.

In describing the constituent elements of the present invention, the same reference numerals may be given to constituent elements having the same name, and the same reference numerals may be given thereto even though they are different from each other. However, even in such a case, it does not mean that the corresponding component has different functions according to the embodiment, or does not mean that it has the same function in different embodiments, and the function of each component is different from that of the corresponding embodiment Based on the description of each component in FIG.

Particularly, in the present invention, a first flicker improving unit connected in parallel with the first LED group and serially connected with the second LED group, and a second flicker improving unit connected in parallel with the second LED group and serially connected with the third LED group In this way, a constant current of the LED current is made to flow, and the input voltage sensing unit is used to drive the LED with the energy charged in the capacitor when the input voltage is low.

1 is a first diagram showing an apparatus for driving an LED according to an embodiment of the present invention.

As shown in FIG. 1, an apparatus for driving an LED according to this embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b1, a third LED group 30b2, The first driving current control unit 70, the second driving current control unit 75, the third driving current control unit 80, the first flicker improvement unit 70, the second driving current control unit 70, A second flicker improvement unit 90b, a first diode 130a, and a second diode 130b.

The AC power source 20 supplies power for driving the first LED group 30a, the second LED group 30b1 and the third LED group 30b2. The first LED group 30a is connected to an AC power source The input side of the second LED group 30b1 is connected to the output side of the first LED group 30a and the input side of the third LED group 30b2 is connected to the output side of the second LED group 30b1 ).

In this case, the first LED group 30a, the second LED group 30b1, and the third LED group 30b2 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 rectifying unit 40 is connected between the output side of the AC power source 20 and the input side of the first LED group 30a and more specifically the output side of the rectifying unit 40 the output of the diode (BD ₁₎ side) the first and then are connected to the first LED group (30a), chungbang part (50), a first flicker improvement part (90a) rectifies the power supplied from the AC power source 20, a first To the LED group 30a, the charging unit 50, and the first flicker improving unit 90a.

The input voltage sensing unit 42 is connected between the output side of the rectifying unit 40 and the input side of the first LED group 30a and the ground GND to sense the input voltage.

The charging unit 50 has one side connected to the output side of the rectifying unit 40 and the input side of the first LED group 30a and is connected to the first LED group 30a according to the magnitude of the voltage supplied from the AC power source 20. [ The second LED group 30b1, and / or the third LED group 30b2, or charges the power supplied from the AC power supply 20 for supplying the voltage.

The first driving current control unit 70 switches the first input current i _Q2 inputted after one side is connected to the output side of the first LED group 30a and passes through the first LED group 30a.

At this time, the first driving current controller 70 may be implemented by a MOSFET or a transistor.

The second driving current control part 75 is connected to the output side of the second LED group 30b1 on one side to switch the second input current i _Q5 inputted from the output side of the second LED group 30b1.

At this time, the second driving current control unit 75 may be implemented by a MOSFET or a transistor.

A third drive current control section 80 switches the third input current i _Q1 which one side is connected to the output side of the third LED group (30b2) input from the output side of the third LED group (30b2).

At this time, the third driving current control unit 80 may be implemented as a MOSFET or a transistor.

The first flicker improving unit 90a is connected in parallel with the first LED group 30a and connected in series with the second LED group 30b1. In other words, the flicker improvement unit 90 is connected in parallel with the first LED group 30a and the output side is connected to the input side of the second LED group 30b1.

One side of the first flicker improving unit 90a is connected to the contact point of the first LED group 30a and the charging unit 50 and is connected to the charging unit 50 or the AC power source 20 and receives the fourth input current i _Q4 and switches it. Here, the first flicker improvement section 90a may be implemented by a MOSFET or a transistor.

The second flicker improving unit 90b is connected in parallel with the second LED group 30b1 and connected in series with the third LED group 30b2. In other words, the second flicker improving unit 90b is connected in parallel with the second LED group 30b1, and the output side is connected to the input side of the third LED group 30b2.

The second flicker improving unit 90b is connected to the charging unit 50 and has a fifth input current i supplied from the charging unit 50 or the AC power source 20 according to the voltage magnitude of the AC power source 20. [ _Q6 and switches it. Here, the second flicker improvement section 90b may be implemented by a MOSFET or a transistor.

2 is a first diagram for explaining the operation of the LED driving apparatus shown in FIG.

Hereinafter, it is assumed that the forward voltage of the first LED group is 2V _F and the forward voltages of the second and third LED groups are both V _F.

First, as shown in Figure 2, when the input voltage is less than 3V _F [i.e., the first LED group, the forward voltage (2V _F) and the time is less than the voltage obtained by adding the forward voltage (V _F) of the second LED group ], Switch parts Q ₁ , Q ₂ and Q ₄ are turned on and switch parts Q ₅ and Q ₆ are turned off. A first current passing through the LED group (30a) flows through the switching unit Q _2, the second current of the LED groups (30b1) and the third LED group (30b2) through the switching unit Q ₄ and Q _1, a diode D ₇ Flows. That is, when the input voltage sensed by the input voltage sensing unit is smaller than the sum of the forward voltage of the first LED group and the forward voltage of the second LED group, the first diode group is driven by the first driving current control unit 70 And the second and third diode groups are supplied with currents through the first to third diode groups 30a, 30b1, and 30b2 to pass through the first flicker improvement unit 90a and the third driving current control unit 80, respectively.

At this time, when the input voltage is lower than the voltage of the parallel capacitors C ₁ and C ₂ , the voltage of the parallel capacitors C ₁ and C ₂ causes the current of the LED groups to flow through the diode D _f1 and the diode D _f3 , ₁ , and C ₂ , the input power source causes the currents of the LED groups to flow.

3 is a second diagram for explaining the operation of the LED driving apparatus shown in FIG.

3, when the input voltage is greater than 3V _F and less than 4V _F (that is, when the input voltage is greater than the sum forward voltage (3V _F ) of the first LED group and the second LED group and the first, is less than the sum voltage (4V _F) of the three LED groups], the switching unit Q _1, Q _5, Q ₆ is turned on and the switch unit Q _2, Q ₄ is turned off. Current of the first LED group (30a) and a second current in the LED groups (30b1) flows through the switching unit Q ₅ and the diode D _2, the third LED group (30b2) flows through the switching unit Q ₆ and Q ₁ . That is, when the input voltage sensed by the input voltage sensing unit is greater than the sum of the forward voltage of the first LED group and the forward voltage of the second LED group and less than the sum of the forward voltages of the first LED group and the third LED group Current is supplied to the first and second diode groups 30a and 30b1 via the second driving current control unit 75 and the second flicker improvement unit 90b and the third driving current control unit 80 A current is provided to the third diode group.

At this time, the current of the first LED group 30a and the second LED group 30b1 (summing forward voltage is 3V _F ) flows the input power and the current of the third LED group 30b2 (forward voltage is V _F ) The voltage of the capacitor C ₁ , which is much smaller than the input voltage, flows. Therefore, each of the LED groups can be driven while minimizing the loss.

4 is a third diagram for explaining the operation of the LED driving apparatus shown in FIG.

As shown in FIG. 4, when the input voltage is greater than 4V _F (that is, when the sum voltage of the first, second and third LED groups is larger than 4V _F ), the switch portions Q ₂ , Q ₄ , Q ₅ , Q ₆ is turned off and only switch portion Q ₁ is turned on. The currents of the first, second and third LED groups flow through the switching unit Q ₁ and the diodes D ₂ and D ₇ . That is, when the input voltage sensed by the input voltage sensing unit is larger than the sum of forward voltages of the first through third LED groups, the first through third diode groups 30a , 30b1, 30b2 are supplied with current.

At this time, the current of the first, second, and third LED groups (the sum forward voltage of their 4V _F ) flows the input power. At this time, the power factor may be improved by controlling the level of the current flowing to be larger than that when the input voltage is less than 4V _F. That is, when the input voltage is larger than the sum of the forward voltages of the first to third LED groups, The power factor can be improved by controlling the current level so that the current provided through the power source is increased.

As described above, in the driving method proposed in the present invention, the currents flowing through the first, second, and third LED groups are always kept constant, but the voltage sources for causing the currents to flow are different from each other, And can be driven without flicker problems.

FIG. 5 is an exemplary view illustrating an apparatus for driving the LED shown in FIG. 1. FIG.

5, the apparatus for driving the LED according to the present embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b1, a third LED group 30b2, The first drive current control unit 70, the second drive current control unit 75, the third drive current control unit 70, the third drive current control unit 70, the second drive current control unit 70, The first flicker improving unit 90b, the first operation controlling unit 100a, the second operation controlling unit 100b, the fourth driving current controlling unit 110, the first flicker improving unit 90b, the first flicker improving unit 90b, A diode 130a, and a second diode 130b. The configuration and specific driving method of each circuit component shown in Fig. 5 will be described in detail below with respect to other embodiments.

6 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.

6, the apparatus for driving the LED according to the present embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b, a rectifying unit 40, A first drive current control unit 70, a third drive current control unit 80, a flicker improvement unit 90, an operation control unit 100, A fourth driving current control unit 110, a first diode 120, and a second diode 130. [

The second embodiment includes a second driving current control unit 75 and a second flicker improvement unit 90b including Q ₅ and Q ₆ serving as switches in the configuration of FIG. 1, and a diode D ₇ , The forward voltage V _F of the third LED group 30b1 and the forward voltage V _F of the third LED group 30b2 are integrated into the forward voltage 2V _F of the second LED group 30b as one LED group. In order to improve the CF by controlling the current flowing through the valley filled circuit, a switch portion Q ₃ is included and a fourth drive current control portion 110 having a circuit configuration as shown in FIG.

The diodes D ₁ and D ₂ , the MOSFET Q ₄ , the resistors R _B4 and R _B5 and the zener diodes ZD _B2 are added to improve the flicker of the second LED group 30b, When the current flows in the first LED group 30a and the second LED group 30b in series, the operation of the flicker improvement circuit is stopped to increase the efficiency. In order to increase the efficiency, the MOSFET q ₁ and the MOSFETs R _off6 and R _off7 ) Has been added. The input voltage sensing unit 42 outputs a high signal when the input voltage is higher than 4 V _{F, which} is the forward voltage of the sum of the first and second LED groups. The input voltage sensing unit 42 includes two zener diodes ZD _B3 and ZD _B4 , (R _sen4 ).

The AC power source 20 supplies power for driving the first LED group 30a and the second LED group 30b and the first LED group 30a is connected to the output side of the AC power source 20 And the input side of the second LED group 30b is connected to the output side of the first LED group 30a.

In this case, the first LED group 30a and the second LED group 30b 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 rectifying unit 40 is connected between the output side of the AC power source 20 and the input side of the first LED group 30a and more specifically the output side of the rectifying unit 40 The output side of the diode BD1 is connected to the first LED group 30a, the charging unit 50, the driving control voltage generating unit 60 and the flicker improving unit 90 and supplied from the AC power source 20 The power source can be rectified and then supplied to the first LED group 30a, the charging unit 50, the driving control voltage generating unit 60, and the flicker improving unit 90.

The input voltage sensing unit 42 is connected between the output side of the rectifying unit 40 and the input side of the first LED group 30a and the ground GND to sense the input voltage. This input voltage the other side of the sensing unit 42 is a Zener diode (ZD _B3), the Zener diode (ZD _B3) which one side is connected to the contact of the holding portion 40 and the first LED group (30a) for sensing the input voltage and A resistor R _sen4 connected in series, and a zener diode ZD _B4 serially connected to the other side of the resistor R _sen4 .

At this time, the value of the Zener diode ZD _{B3 in the} input voltage sensing unit 42 may be set to have a value equal to or greater than a sum of the forward voltage of the first LED group 30a and the forward voltage of the second LED group 30b .

The charging unit 50 has one side connected to the output side of the rectifying unit 40 and the input side of the first LED group 30a and is connected to the first LED group 30a according to the magnitude of the voltage supplied from the AC power source 20. [ And the second LED group 30b or charges the power supplied from the AC power supply 20 for supplying the voltage.

One end of the drive control voltage generating unit 60 is connected to the contact point between the charge and discharge unit 50 and the first LED group 30a and the AC power source 20 or the light- And generates a voltage for operation of the first driving current control unit 70 and the third driving current control unit 80 based on the current supplied from the front unit 50.

At this time, the driving control voltage generator 60 has a Zener diode that is one side of the other end in series with the chungbang part (50) and the first resistor being connected to the contacts of the LED group (30a) (R _B) and a resistor (R _B) connected (ZD _B1 ).

One side of the first driving current control unit 70 is connected to the output side of the driving control voltage generating unit 60 and the first LED group 30a and is operated by the voltage generated by the driving control voltage generating unit 60, 1 LED group 30a and then controls the first input current i _Q2 to be constant current.

The first driving current controller 70 is connected to the output side of the first LED group 30a at one side and the first input current input terminal at the output side of the first LED group 30a, The first switch 72 and the first current control unit 74 are connected to the first switch 72 and the first switch 72 and the first current control unit 74 controls the first input current to be constant current. Transistor.

One side of the third driving current control unit 80 is connected to the output side of the driving control voltage generating unit 60 and the second LED group 30b and is operated by the voltage generated by the driving control voltage generating unit 60, The second input current i _Q1 input from the output side of the second LED group 30b is subjected to constant current control.

At this time, the third driving current control unit 80 is connected to the output side of the second LED group 30b, one side of which is connected to the second input current through the output side of the second LED group 30b, And a second current control unit 84 connected to the second switch 82 and the second switch 82 for constant current control of the second input current and the second switch 82 may be a MOSFET or a transistor, (84) may be a shunt regulator.

The flicker improvement unit 90 is connected in parallel with the first LED group 30a and in series with the second LED group 30b. In other words, the flicker improvement section 90 is connected in parallel with the first LED group 30a and the output side is connected to the input side of the second LED group 30b.

The flicker improvement unit 90 has one side connected to the contact point of the first LED group 30a and the charging unit 50 and is connected to the charging unit 50 or the AC power source 20 according to the voltage of the AC power source 20. [ A third switch 92 and a third switch 92 to which a third input current i _Q4 supplied from the third switch 92 is input and generates a voltage for driving the third switch 92 to pass the third input current , And the third switch 92 may be a MOSFET or a transistor.

One end of the operation control unit 100 is connected to the input side of the flicker improving unit 90 and controls the operation of the flicker improving unit 90 according to the voltage level of the AC power source 20 Off ") of the operation control switch 102. At this time, the operation control switch 102 may be a MOSFET or a transistor.

At this time, the operation control unit 100 turns off the flicker improving unit 90 when the input voltage is sufficiently high and current flows in the first LED group 30a and the second LED group 30b in series.

The fourth driving current control unit 110 is connected between the charging unit 50 and the ground and operates according to the voltage supplied from the charging unit 50 to supply the fourth input current i _Q3 supplied from the charging unit 50 to the constant current control do.

The fourth driving current control unit 110 is connected to the fourth switch 112 and the fourth switch 114 to which the fourth input current supplied from the charge and discharge unit 50 is inputted and outputs the fourth input current to the constant current The fourth switch 112 and the fourth current control 114 may be a MOSFET or a transistor.

The first diode 120 is connected between the output side of the flicker improvement unit 90 and the input side of the second LED group 30b and is connected to the flicker improving unit 90 according to the magnitude of the voltage supplied from the AC power source 20. [ The second input current passed through the second LED group 30b is supplied to the third driving current control unit 80 while the second diode 130 is connected to the output side of the first LED group 30a The second input current passed through the first LED group 30a is supplied to the second LED group 30b according to the magnitude of the voltage supplied from the AC power source 20, And supplied to the third driving current control unit 80. [ Also, the second diode 130 prevents current from flowing back when the first switch 72 and the third switch 92 are turned on at the same time.

7 is a first diagram for explaining the operation of the LED driving apparatus shown in Fig.

As shown in FIG. 7, in the case of the period t0 to t1 (see FIG. 16A, which will be described later with respect to the application of the input voltage in this specification including this period), the input voltage supplied from the alternating- The voltages of the first and second LED groups 30a and 30b are set to be lower than the voltages of the capacitors C1 and C2 constituting the front part 50. In this case, 2 LED groups 30b are driven in parallel (in this drawing and the following drawings, the current path is indicated by a dotted line).

In other words, the first input current passed through the first LED group 30a is supplied to the first drive current control unit 70, which is operated by the voltage supplied from the drive control voltage generation unit 50, The first input current flows through the first switch 72 and the first input current is converted into a voltage through the sensing resistor R _sen2 included in the first driving current controller 70 and then through the resistor R _off2 , (In other words, drives the gate of the first current control section 74). At this time, the voltage applied to the first current control part 74 is determined by the distribution resistances of the resistances R _off2 and R _gs2 , and this voltage drives the one current control part 74 in the active area to perform the constant current control.

The second input current that has passed through the flicker improving section 90 and the second LED group 30b is supplied to the third drive circuit 60 that is operated by the voltage supplied from the drive control voltage generating section 50, flows through the second switch 82 of the current control unit 80, this current is the voltage over the then resistance R _S1 changes to a voltage via a sense resistor (R _sen1) of the third drive current control unit 80 regulator of u ₁ ref. At this time, the voltage applied to the ref of the voltage regulator u ₁ is determined as the divided voltage of the resistors R _S1 and R _gs1 , and this voltage drives the voltage regulator to control the constant current.

_{According to} the design of the resistances R _sen2 , R _off2 and R _gs2 and the resistances R _sen1 , R _S1 and R _gs1 , the _currents of the first and second LED groups 30a and 30b are equal to each other in the period t0 to t1 The currents of the first and second LED groups 30a and 30b flow constantly and the input current does not flow as in the period from t0 to t1 of FIG. 16A.

8 is a second diagram for explaining the operation of the LED driving apparatus shown in FIG.

8, when the input voltage supplied from the AC power supply 20 is larger than the voltages of the capacitors C1 and C2 constituting the charging unit 50 and the voltage of the first LED group 30a is higher than the voltage of the capacitors C1 and C2 constituting the charging unit 50, The first LED group 30a and the second LED group 30b are connected in parallel to the input voltage V _ac supplied from the power source 20 in a period shorter than the sum forward voltage of the first LED group 30a and the second LED group 30b. .

In other words, the first input current passed through the first LED group 30a, as in the above-described period t0 to t1, is in the on state due to the voltage supplied from the drive control voltage generator 50 _Flows through the first switch 72 of the first driving current control unit 70 and the first input current is converted into a voltage through the sensing resistor R _sen2 included in the first driving current control unit 70 And drives the first current control unit 74 (that is, drives the gate of the first current control unit 74) through the resistor R _off2 . At this time, the voltage applied to the first current control part 74 is determined by the distribution resistances of the resistances R _off2 and R _gs2 , and this voltage drives the one current control part 74 in the active area to perform the constant current control.

The second input current that has passed through the flicker improving section 90 and the second LED group 30b is supplied to the third drive circuit 60 that is operated by the voltage supplied from the drive control voltage generating section 50, Flows through the second switch 82 of the current control unit 80 and is switched to the voltage through the sensing resistor R _sen1 of the third driving current control unit 80 and then drives the ref of the voltage regulator u ₁ through the resistor R _S1 do. At this time, the voltage applied to the ref of the voltage regulator u ₁ is determined as the divided voltage of the resistors R _S1 and R _gs1 , and this voltage drives the voltage regulator to control the constant current.

 Referring to the current flowing at this time, the currents of the first and second LED groups 30a and 30b constantly flow as in the period between t0 and t1 as in the period between t1 and t2 of FIG. 16A, The sum current of the first LED group 30a and the second LED group 30b flows.

FIG. 9 is a third diagram for explaining the operation of the LED driving apparatus shown in FIG.

9, when the input voltage supplied from the AC power source 20 is higher than the combined forward voltage of the first LED group 30a and the second LED group 30b in the period from t2 to t3, The first LED group 30a and the second LED group 30b are supplied with the input voltage Vac supplied from the power source 20 in this period, And is driven in series.

In other words, the second input current that has passed through the first LED group 30a and the second LED group 30b flows through the second switch 82 of the third driving current control unit 80, (R _sen1 ) of the voltage regulator 80 and drives the ref of the voltage regulator u ₁ through the resistor R _S1 . At this time, the voltage applied to the ref of the voltage regulator u ₁ is determined as the divided voltage of the resistors R _S1 and R _gs1 , and this voltage drives the voltage regulator to control the constant current.

At this time, whether the input voltage is higher than the sum voltage of the first LED group 30a and the second LED group 30b is possible through the Zener diode ZD _B3 . It is possible to design the voltage of the Zener diode ZD _B3 to the sum voltage of the first LED array group 30a and the second LED group 30b.

When the input voltage is greater than the voltage of the Zener diode ZD _B3, the voltage is applied to the operation control switch 102 of the operation control unit and the first current control unit 74 of the first drive current control unit 70 through the resistors R _off5 and R _off6 Turn on and operate in the saturation region. When the operation control switch q1 of the operation control unit is turned on, the gate voltage of the third switch 92 of the flicker improving unit 90 is made "0" to turn off the third switch 92, When the control section 74 is turned on, the gate voltage of the first switch 72 of the first drive current control section 70 is made " 0 ", and the first switch 72 is turned off. The currents of the first and second LED groups 30a and 30b have the same values as in the period t0 to t2 and flow constantly and are equal to the input current as in the period from t2 to t3 in FIG. 16A.

10 is a fourth diagram for explaining the operation of the LED driving apparatus shown in FIG.

10, when the input voltage supplied from the AC power supply 20 exceeds the summing forward voltage of the first LED group 30a and the second LED group 30b and the total forward voltage of the charging and discharging unit 50 in the period from t3 to t4, The first LED group 30a and the second LED group 30b are supplied with the input voltage V _ac supplied from the power source 20 in a period longer than the sum of the voltages of the capacitors C1 and C2 constituting the first LED group 30a. The capacitors C1 and C2 constituting the charging and discharging unit 50 are charged.

At this time, the current flow and control method of the current flowing through the first LED group 30a and the second LED group 30b are the same as the periods t2 to t3, and the current flows in parallel with the current flow to charge the capacitors C1 and C2 . At this time, the current to charge the capacitors C1 and C2 is controlled to lower the maximum input current to lower the crest factor. The current charging the capacitors C1 and C2 is changed to a voltage through the sensing resistor R _sen3 and this voltage drives the gate of the fourth current control section 114 of the fourth driving current control section 110 through the resistor R _off2 . At this time, this voltage drives the fourth current control unit 114 in the active region to perform the constant current control.

The currents of the first LED group 30a and the second LED group 30b flow with the same values as the periods t0 through t3 as in the period from t3 to t4 in FIG. 16A, and the input current flows through the first LED group 30a and the second LED group 30b and the currents for charging the capacitors C1 and C2 flow together, so that a larger amount of current flows than in the period between t2 and t3.

In addition, as the input voltage decreases, the current path and the control method during the period t4 to t5, t5 to t6, and t6 to t7 are divided into the periods t2 to t3, t1 to t2, (t0 to t1). The currents flowing through the first LED group 30a and the second LED group 30b are constant over the entire period t0 to t7.

11 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.

11, an apparatus for driving an LED according to the present embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b, a rectifying unit 40, A first drive current control unit 70, a third drive current control unit 80, a flicker improvement unit 90, an operation control unit 100, A fourth driving current control unit 110, a first diode 120, and a second diode 130. [

The apparatus for driving the LED according to the present embodiment is a form in which the input voltage sensing unit 42 is removed in the embodiment described above with reference to FIG. In this embodiment, instead of the input voltage sensing unit 42, the voltage of R _sen3 sensing the valley filled charge current is used.

12 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.

12, an apparatus for driving an LED according to the present embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b, a rectifying unit 40, A first drive current control unit 70, a third drive current control unit 80, a flicker improvement unit 90, an operation control unit 100, A first diode 120, and a second diode 130.

That is, the apparatus for driving the LED according to the present embodiment has a configuration in which the fourth driving current controller 110 is removed in the apparatus for driving the AC LED of FIG.

Since the current flowing through the first LED group 30a and the second LED group 30b is always constant though the shape of the input current is increased by increasing the amount of current charged in the valley filled circuit in this manner, 6 as shown in Fig.

13 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.

13, an apparatus for driving an LED according to the present embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b, a rectifying unit 40, The first drive current control unit 70, the third drive current control unit 80, the flicker improvement unit 90, the operation control unit 100, the fourth drive current control unit 110 ), A first diode (120), and a second diode (130).

That is, the apparatus for driving the LED according to the present embodiment has a configuration in which the input voltage sensing unit 42 and the fourth driving current control unit 110 are removed in the apparatus for driving the LED of FIG.

Since the current flowing through the first LED group 30a and the second LED group 30b is always constant, the flicker improving characteristics are not uniform. It is maintained as it is in the configuration of Fig.

14 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.

As shown in FIG. 14, an apparatus for driving an LED according to the present embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b, a rectifying unit 40, A first drive current control unit 70, a third drive current control unit 80, a flicker improvement unit 90, an operation control unit 100, A fourth driving current control unit 110, a first diode 120, and a second diode 130. [

That is, the apparatus for driving the LED according to the present embodiment is a modification of the third driving current control unit 80 in the structure for driving the LED of FIG. For example, the configuration may be such that the MOSFET q ₄ and the resistor R _{gs1 _ on} for improving the power factor and the harmonic characteristic are added to the third driving current control unit 80 shown in FIG.

In this manner, the current flowing through the first LED group 30a and the second LED group 30b can be controlled to improve the power factor and the harmonic characteristic while satisfying the flicker characteristic of the% flicker of 20%. In addition, it is possible to increase the input voltage a first LED group (30a) and a second LED group (30b) is connected in series to improve the power factor by passing a current larger by turning on the MOSFET q ₄ when an electric current flows. .

15 is a diagram illustrating an apparatus for driving an LED according to another embodiment of the present invention.

15, an apparatus for driving an LED according to the present embodiment includes an AC power source 20, a first LED group 30a, a second LED group 30b, a rectifying unit 40, A first drive current control unit 70, a third drive current control unit 80, a flicker improvement unit 90, an operation control unit 100, A first diode 120, and a second diode 130.

That is, the apparatus for driving the LED according to the present embodiment is a modification of the third driving current control unit 80 in the configuration for driving the LED of FIG. For example, the configuration may be such that the MOSFET q ₄ and the resistor R _{gs1 _ on} are added to the third driving current control unit 80 shown in FIG. 6 to improve the power factor and the harmonic characteristic.

In this manner, the current flowing through the first and second LED groups 30a and 30b can be controlled to improve the power factor and the harmonic characteristics while satisfying the flicker characteristics. Also the input voltage to the first LED group (30a) and a second LED group (30b) connected in series increases to improve the power factor by passing a current larger by turning on the MOSFET q ₄ when an electric current flows.

16A and 16B show the current-voltage waveform of the LED driving apparatus according to the embodiment of the present invention and the flicker picture compared with the prior art.

FIG. 16A shows the input voltage, the current, the first LED group, and the current flowing in the second LED group according to the embodiment shown in FIG. 6, which are 220V, 60Hz input voltage, 10W LED, and the case where the power factor is 0.94.

As described above, it has been confirmed that the LED driving apparatus according to the present embodiment can solve the flicker problem as compared with the conventional art, as shown in FIG. 16B, by continuously generating currents flowing in the first and second LED groups.

17A to 17B show the current-voltage waveform of the LED driving apparatus according to the embodiment of the present invention and the flicker picture compared with the prior art.

17A shows the input voltage, the current, the current flowing in the first LED group, and the like of the LED driving apparatus according to the embodiment shown in FIG. 14. The waveforms include 220V, 60Hz input voltage, 9.8W LED, And the power factor,% flicker (% FL) is 20%. As described above, the LED driving apparatus according to the present invention is able to increase the power factor by improving the input current while satisfying the% flicker as shown in FIG. 17B while continuously generating the current flowing through the LED.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as falling within the scope of the present invention.

20: AC power source
30a: the first LED group
30b: the second LED group
40: rectification part
42: input voltage sensing unit
50:
60: drive control voltage generator
70: first drive current control section
80: third drive current control section
90: flicker improvement section
100:
110: fourth drive current control section
120: first diode
130: second diode

Claims (19)

A first LED group connected to an output side of an AC power source for supplying power to the input side;
A second LED group whose input side is connected to the output side of the first LED group;
A third LED group whose input side is connected to the output side of the second LED group;
A rectifying part connected between the output side of the ac power source and the first LED group input side;
An input voltage sensing unit connected to an output side of the rectifying unit and an input side of the first LED group to sense an input voltage;
A charging unit having one side connected to an output side of the rectifying unit and an input side of the first LED group;
A first driving current control unit connected to an output side of the first LED group and switching a first input current input from an output side of the first LED group;
A second driving current control unit connected to the second LED group output side and switching a second input current input from the output side of the second LED group;
A third driving current control unit connected to the third LED group output side to switch a third input current input from the output side of the third LED group; And
A first flicker improving unit connected in parallel with the first LED group and having an output connected to the input side of the second LED group; And
A second flicker improving unit connected in parallel with the second LED group and having an output connected to the input side of the third LED group;
Wherein when the sensed input voltage is less than a predetermined threshold value, a voltage charged in the charging unit is provided to at least one of the first LED group, the second LED group, and the third LED group. A device for driving an LED. The method according to claim 1,
A first diode coupled between the first LED group output side and the second LED group input side; And
A second diode coupled between the output side of the second LED group and the input side of the third LED array group;
Further comprising: a light source for driving the LED. The method according to claim 1,
When the input voltage sensed by the input voltage sensing unit is smaller than the sum of the forward voltage of the first LED group and the forward voltage of the second LED group,
The first flicker improving unit, the first driving current control unit, and the third driving current control unit, or a large voltage of the input voltage, the current is supplied to the first to third diode groups Wherein the light emitting device is provided with a light emitting diode. The method according to claim 1,
Wherein the input voltage sensed by the input voltage sensing unit is greater than the sum of the forward voltage of the first LED group and the forward voltage of the second LED group and less than the sum of the forward voltage of the first LED group and the forward voltage of the third LED group Occation,
Wherein the current is supplied to the first and second diode groups by the input voltage via the second driving current control unit and the current is supplied to the charging and discharging unit via the second flicker improving unit and the third driving current control unit And a current is provided to the third diode group by a voltage. The method according to claim 1,
When the input voltage sensed by the input voltage sensing unit is greater than the sum of forward voltages of the first to third LED groups, the first to third Wherein a current is provided to the diode group. 5. The method of claim 4,
When the input voltage sensed by the input voltage sensing unit is larger than the sum of the forward voltages of the first to third LED groups, the input voltage is smaller than the sum of the forward voltages of the first to third LED groups The current supplied through the three driving current control part is larger than the current supplied to the driving current control part. A first LED group connected to an output side of an AC power source for supplying power to the input side;
A second LED group whose input side is connected to the output side of the first LED group;
A rectifying part connected between the output side of the ac power source and the first LED group input side;
An input voltage sensing unit connected to an output side of the rectifying unit and an input side of the first LED group to sense an input voltage;
A charging unit having one side connected to an output side of the rectifying unit and an input side of the first LED group;
A drive control voltage generating unit having one side connected to the charging unit and the input side of the first LED group;
One end of the first LED group is connected to the drive control voltage generator and the output side of the first LED group, and the other end of the first LED group is operated by a voltage generated by the drive control voltage generator, A first driving current control unit for controlling the constant current;
One of which is connected to the drive control voltage generator and the second LED group output side and is operated by a voltage generated by the drive control voltage generator to generate a second input current input from the output side of the second LED group, A third driving current control unit for controlling the second driving current; And
A flicker improving unit connected in parallel with the first LED group and having an output connected to an input side of the second LED group;
Wherein when the sensed input voltage is less than a predetermined threshold value, a voltage charged in a capacitor constituting the charging / discharging unit is supplied to at least one of the first and second LED groups. Device for driving an LED. 8. The method of claim 7,
Wherein the input voltage sensing unit comprises:
A first Zener diode having one side connected to the rectifying part and a contact point of the first LED group;
A resistor serially connected to the other side of the first Zener diode; And
A second zener diode connected in series with the other side of the resistor;
And a driving circuit for driving the LED. 9. The method of claim 8,
Wherein the first zener diode comprises:
And the second LED group is set to have a value equal to or greater than a sum of a voltage of the first LED group and a forward voltage of the second LED group. 8. The method of claim 7,
An operation controller connected to the input side of the flicker improvement part and controlling an operation of the flicker improvement part according to a voltage magnitude of the AC power source;
Further comprising: a light source for driving the LED. 11. The method of claim 10,
The operation control unit,
And turns off the flicker improvement unit when an input voltage supplied from the AC power source is greater than a preset threshold value and a current flows in series to the first LED group and the second LED group. 8. The method of claim 7,
A first diode coupled between the output side of the flicker improvement portion and the input side of the second LED group; And
A second diode coupled between the output side of the first LED group and the input side of the second LED array group;
Further comprising: a light source for driving the LED. 13. The method of claim 12,
Wherein the first diode passes a second input current passing through the flicker improvement unit according to a magnitude of a voltage supplied from the AC power supply to the third driving current control unit through the second LED group,
And the second diode is configured such that a second input current passing through the first LED group is supplied to the third driving current control unit through the second LED group according to the magnitude of the voltage supplied from the AC power source A device for driving an LED. 8. The method of claim 7,
Wherein the third driving current control unit comprises:
A second switch having one side connected to the output side of the second LED group and receiving the second input current; And
A second current controller coupled to the second switch and configured to control the second input current by a constant current;
And a driving circuit for driving the LED. 15. The method of claim 14,
Wherein the third driving current control unit comprises:
A MOSFET that is turned on when a current flows in series to the first LED group and the second LED group to further flow the current;
Further comprising: a light source for driving the LED. 8. The method of claim 7,
A fourth driving current control unit connected between the charging and discharging unit and operated by a voltage supplied from the charging unit and performing a constant current control on a fourth input current supplied from the charging unit;
Further comprising: a light source for driving the LED. 17. The method of claim 16,
Wherein the fourth driving current control unit comprises:
And an operation control unit for controlling the operation of the LED. 11. The method of claim 10,
Wherein the third driving current control unit comprises:
And a switch connected to the operation control unit. A first LED group connected to an output side of an AC power source for supplying power to the input side;
A second LED group whose input side is connected to the output side of the first LED group;
A rectifying part connected between the output side of the ac power source and the first LED group input side;
A charging unit having one side connected to an output side of the rectifying unit and an input side of the first LED group;
A drive control voltage generating unit having one side connected to the charging unit and the input side of the first LED group;
One end of the first LED group is connected to the drive control voltage generator and the output side of the first LED group, and the other end of the first LED group is operated by a voltage generated by the drive control voltage generator, A first driving current control unit for controlling the constant current;
One of which is connected to the drive control voltage generator and the second LED group output side and is operated by a voltage generated by the drive control voltage generator to generate a second input current input from the output side of the second LED group, A third driving current control unit for controlling the second driving current;
A fourth driving current control unit connected between the charging and discharging unit and operated by a voltage supplied from the charging unit and performing a constant current control on a fourth input current supplied from the charging unit;
A flicker improving unit connected in parallel with the first LED group and having an output connected to an input side of the second LED group; And
And an operation control unit connected to the input side of the flicker improvement unit and controlling the operation of the flicker improvement unit according to a voltage magnitude of the AC power source,
Wherein the charging current sensing unit senses a charging current of the charging unit using a resistor included in the fourth driving current control unit.

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