KR20130048949A - Multi level control apparatus for operation led - Google Patents

Abstract

PURPOSE: An LED multi-stage driving control apparatus is provided to enable harmonic suppression, power factor improvement and flicker phenomenon minimizing by maintaining constant current control as to an input current as enabling cost reduction and simplification in circuit configuration. CONSTITUTION: An LED driving control apparatus(10b) includes an LED array(30b), a rectification part(40b), a driving control voltage generation part(50b) and a driving current control part(60b). The LED array is connected to an output axis of an input AC power supply. The rectification part is connected between an output side of the AC power supply and the input signal of the LED array. The driving control voltage generation part is connected between the LED array and the rectification part. The driving current control part is connected between the driving control voltage generation part and the LED array and the rectification part, and operates by a voltage generated in the driving control voltage generation part, and performs constant current control of a plurality of input currents inputted after passing an LED constituting the LED array.

Description

LED multi-stage drive control device {Multi level control apparatus for operation LED}

The present invention relates to an LED drive control device. More specifically, the present invention relates to an LED drive control device capable of driving a DC drive LED module or an AC drive LED module using an AC power source.

Generally, LED (Light Emitting Diode) module can be classified into DC driving LED module and AC driving LED module according to the type of power input for driving LED module.

1 is a circuit diagram of a drive device of a conventional DC drive LED module, Figure 2 is a circuit diagram of a drive device of a conventional AC drive LED module.

As shown in FIGS. 1 and 2, the driving device 1a of the conventional DC driving LED module and the driving device 1b of the AC driving LED module are a power source 2a, 2b, an LED module 3a, 3b, and a voltage. Generating sections 4a and 4b and current control sections 5a and 5b.

Referring to Figure 1 describes the operation of the conventional DC drive LED module driving device (1a) as follows.

First, when the input voltage supplied from the power supply 2a is greater than 50 percent of the forward voltage of the entire LED module 3a, an auxiliary current flows through the switch Q ₂ of the current control unit 5a. 5a) is a switch (Q ₂₎ associated with the shunt regulator (shunt regulator) after sensing the voltage of the sensing resistor (R _sen2) associated with the switch (Q ₂₎ by using (U ₂₎ by using this, it controls the secondary current Done.

Next, when the input voltage supplied from the power supply 2a is greater than the forward voltage of the entire LED module 3a, the main current flows through the switch Q _{1 of} the current control unit 5a, whereby the current control unit 5a after using a switch shunt regulator (U ₁₎ connected to the (Q ₁₎ sensing the voltage connected to the switch (Q ₁₎ sensing resistance (R _sen1) controlling the main current by using this, and at the same time sensing resistance (R _The operation of the switch Q ₂ is stopped by operating the MOSFET q ₂ connected to the switch Q ₂ using the voltage of _sen1 ).

As described above, in the case of the conventional DC driving LED module driving apparatus 1a, the shunt regulator U2 is used to control the auxiliary current, and the MOSFET q ₂ is operated to switch off the auxiliary current. A method of stopping the operation of (Q2) was used, and the devices used to control the auxiliary current and to block the auxiliary current are different from each other by the shunt regulator U ₂ and the MOSFET q _2, respectively. In the case that the price burden is increased in configuring the LED module driving apparatus due to the increase of the number and the number of LEDs constituting the LED module increases, that is, in order to make the types of the main current and the auxiliary current more than two levels, There was a problem that the configuration of the LED module drive conference is quite complicated.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is possible to simplify the circuit configuration and reduce the cost according to the circuit configuration, and at the same time, maintain constant current control for the input current to suppress harmonics, improve power factor, and flicker. An object of the present invention is to provide an LED drive control device capable of minimizing the phenomenon.

An LED drive control apparatus according to the present invention for achieving the above object is an LED drive control device using an AC power source, the input side is connected to the output side of the AC power source array; A rectifier connected between an output side of the AC power source and an input side of the LED array; A driving control voltage generator having one side connected to the LED array and the other side connected to the rectifier; And one side connected to the driving control voltage generator and the LED array, the other side connected to the rectifier, and operated by a voltage generated by the driving control voltage generator to pass through at least one LED constituting the LED array. And a driving current controller configured to control the constant current of the plurality of input currents input afterwards.

The driving control voltage generation unit may include a resistor connected to one side of the LED array and a zener diode connected to the other side of the resistor.

The driving current controller may include a first switch having one side connected to an output side of the LED array and having a first input current input from an output side of the LED array among the plurality of input currents, and one side being connected to the LED array. A second switch connected to the first switch and connected in parallel with the first switch, wherein a second input current passing through some LEDs of the LED array is input, one side of which is connected to the LED array and parallel to the second switch A third switch connected to the third input current passing through some LEDs of the LED array among the plurality of input currents, and one side of the plurality of input currents connected to the LED array and connected to the third switch in parallel; A fourth input current through which some LEDs of the LED array are input; It can include 4 switches.

The first current controller may be connected to the first switch to control the first input current and to turn off the second switch, the third switch, and the fourth switch when the first input current is input. A second current controller connected to a second switch and configured to control the second input current and to turn off the third switch and the fourth switch when the second input current is input; And a third current control unit configured to control an input current and to turn off the fourth switch when the third input current is input, and a fourth current control unit connected to the fourth switch and configured to perform constant current control of the fourth input current. can do.

The first current controller may be connected to the first switch to control the first input current and to turn off the second switch, the third switch, and the fourth switch when the first input current is input. A second current controller connected to a second switch and configured to constant current control the second input current, a third current controller connected to the third switch and configured to constant current control the third input current, and connected to the fourth switch; The electronic device may further include a fourth current controller configured to control the fourth input current by the constant current.

In addition, the first switch, the second switch, the third switch, and the fourth switch may be MOSFETs or transistors.

In addition, the first current controller may be a MOSFET, a transistor, or a shunt regulator.

In addition, the second current controller, the third current controller, and the fourth current controller may be MOSFETs or transistors.

The LED array may include a plurality of LEDs connected in series, and each of the plurality of LEDs may be a DC driving LED.

In addition, the LED array may include a plurality of LED pairs connected in parallel in a reverse direction, and each LED constituting the LED pair may be an AC driving LED.

According to the present invention, it is possible to reduce the circuit configuration cost by simplifying the circuit configuration and the circuit configuration in the LED drive control device.

In addition, even if the input voltage changes, the drive current of the LED array can be output in the form of a sine wave by the constant current control, so that it is possible to suppress harmonics, improve the power factor, and minimize flicker.

1 is a circuit diagram of a driving apparatus of a conventional DC driving LED module;
2 is a circuit diagram of a driving apparatus of a conventional AC driving LED module.
3 is a circuit diagram of an LED driving control device according to a first embodiment of the present invention;
4 to 7 are reference diagrams for the current-voltage waveforms according to the driving method of the LED driving control apparatus according to the first embodiment of the present invention;
8 is a circuit diagram of an LED drive control device according to a second embodiment of the present invention;
9 and 10 are reference diagrams for a current-voltage waveform according to a driving method of an LED driving control apparatus according to a second embodiment of the present invention;
11 is a circuit diagram of an LED drive control device according to a third embodiment of the present invention;
12 is a reference diagram for a current voltage waveform according to a driving method of an LED driving control apparatus according to a third embodiment of the present invention;
13 is a circuit diagram of an LED drive control apparatus according to a fourth embodiment of the present invention, and
14 and 15 are reference diagrams for current voltage waveforms according to a driving method of an LED driving control apparatus according to a fourth embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, preferred embodiments of the present invention will be described below, but the technical idea of the present invention may be implemented by those skilled in the art without being limited or limited thereto.

3 is a circuit diagram of the LED driving control apparatus according to the first embodiment of the present invention.

As shown in FIG. 3, the LED driving control apparatus 10a according to the first embodiment of the present invention includes an AC power supply 20a, an LED array 30a, a rectifying unit 40a, a driving control voltage generating unit 50a, and And a drive current controller 60a.

The AC power source 20a supplies power for driving the LED array 30a, and the input side of the LED array 30a is connected to the output side of the AC power source 20a.

In this case, the LED array 30a may include a plurality of LEDs connected in series, and each LED may be a DC driving LED driven by DC.

The rectifier 40a is connected between the output side of the AC power supply 20a and the input side of the LED array 30a. More specifically, the output side of the rectifier 40a is connected to the input side of the LED array 30a. The input side of the rectifier 40a is connected to the driving control voltage generator 50a and the driving current controller 60a, and rectifies the power supplied from the AC power source 20a and outputs the rectified power to the LED array 30a.

In this case, the rectifier 40a may include a plurality of diode pairs connected in the forward direction.

The driving control voltage generator 50a has one side connected to the LED array 30a and the other side connected to the rectifier 40a. The driving control voltage generator 50a inputs a current passing through some LEDs (D _{1 in} FIG. 3) of the LED array 30a. And generates a voltage for the operation of the drive current controller 60a.

In this case, the driving control voltage generator 50a may include a resistor R _B connected to one side of the LED array 30a and a zener diode Z _DB connected in series with the other side of the resistor R _B.

One side of the driving current controller 60a is connected to the driving control voltage generator 50a and the LED array 30a, and the other side of the driving current controller 60a is connected to the input side of the rectifying unit 40a and generated by the driving control voltage generator 50a. The control unit performs constant current control of a plurality of input currents inputted after passing through at least one or more LEDs constituting the LED array 30a.

In this case, one side of the driving current controller 60a is connected to the output side of the LED array 30a and the first input current i _Q1 input from the output side of the LED array 30a is input. A first current controller 62a connected to a first switch 61a and a first switch 61a to control the first input current in a constant current state, and one side thereof is connected to the LED array 30a The second input is connected to the second switch 63a and the second switch 63a through which the second input current i _Q2 passing through some of the LEDs D ₁ to D ₃ constituting the array 30a is input. A second current controller 64a for controlling the constant current, one side of which is connected to the LED array 30a and passes through some of the LEDs D ₁ and D ₂ constituting the LED array 30a among the plurality of input currents; 3rd switch 65a to which 3 input current i _Q3 is input, 3rd switch 65a ) Is associated with and connected to the third current control part (66a), one side of the LED array (30a) to the constant current control of the third input current, some LEDs constituting an LED array (30a) of the plurality of input current (D ₁ A fourth switch 67a through which the fourth input current i _Q4 is input, and a third current controller 68a connected to the fourth switch 67a to control the fourth input current in a constant current. do.

In this case, the first current controller 62a may turn off the second switch 63a, the third switch 65a, and the fourth switch 67a when the first input current is input to the first switch 61a. .

In addition, the first switch 61a, the second switch 63a, the third switch 65a, and the fourth switch 67a may be MOSFETs or transistors, and the first current controller 62a may be a MOSFET, a transistor, Or a shunt regulator, and the second current controller 64a, the third current controller 66a, and the fourth current controller 68a may be MOSFETs or transistors.

An operation process of the LED driving control apparatus 10a according to the first embodiment of the present invention will be described with reference to FIG. 3.

First, when the positive voltage supplied from the AC power source 20a is increased to be greater than 25% of the total forward voltage of the LED array 20a, the fourth input current is part of the LEDs D ₁ constituting the LED array 30a. After passing through the input signal, the driving control voltage generator 50a and the driving current controller 60a are input to the fourth switch 67a.

Then, the first switch 61a, the second switch 63a, the third switch 65a, and the fourth switch 67a are generated by the voltage generated according to the current input to the driving control voltage generator 50a. In operation, the fourth input current input to the fourth switch 67a side passes through the fourth switch 67a.

In this case, the fourth input current may play a role of an auxiliary current for improving the power factor and also drive some of the LEDs D ₁ constituting the LED array 30a to minimize flicker.

In addition, the fourth input current passing through the fourth switch 67a is converted into a voltage through the resistor R _sen4 connected to the fourth switch 67a, and the voltage is passed through the resistor R _S4 and then the fourth switch. The fourth current controller 68a connected to the 67a is operated. (In other words, the gate of the fourth current controller 68a is driven.)

In this case, the voltage for operating the fourth current controller 68a may be a divided voltage determined by the resistor RS4 and the resistor ROFF4, and the fourth switch 67a may be operated by the fourth current controller 68a. Since the magnitude of the gate voltage is adjusted, the current flowing in the fourth switch 67a can be controlled by the constant current.

Next, when the voltage supplied from the AC power source 20a is greater than 50 percent of the total forward voltage of the LED array 30a, the third input current may cause some LEDs D ₁ and D ₂ constituting the LED array 30a. After passing through, it is input to the third switch 65a side.

At this time, since the third switch 65a is in an on state by being operated by the voltage generated by the driving control voltage generation unit 50a, the third input current input to the third switch 65a is the third switch 65a. The third input current plays a role of an auxiliary current to improve power factor and simultaneously drives some of the LEDs D ₁ and D ₂ constituting the LED array 30a to minimize flicker. Can be.

In addition, the third input current is converted into a voltage by a resistor R _sen3 connected in series with the third switch 65a, and the voltage is converted into a voltage through the resistor R _S3 . 66a). (In other words, the gate of the third current controller 66a is driven.)

Here, the voltage for operating the third current controller 66a may be a divided voltage determined by the resistor R _S3 and the resistor R _off3 , and the third switch may be controlled by the operation of the third current controller 66a. Since the magnitude of the gate voltage of 66a is adjusted, the current flowing through the third switch 66a can be controlled constantly.

When the voltage supplied from the AC power source 20a is greater than 75 percent of the total forward voltage of the LED array 30a, the second input current passes through some of the LEDs D ₁ to D ₃ constituting the LED array 30a. After that, it is input to the second switch 63a side.

At this time, since the second switch 63a is in an on state by being operated by the voltage generated by the driving control voltage generator 50a, the second input current input to the second switch 63a is the second switch 63a. The second input current serves to minimize the flicker by driving some of the LEDs D ₁ to D ₃ constituting the LED array 30a at the same time as the auxiliary current for improving the power factor. Can be.

In addition, the second input current is changed into a voltage by a resistor R _sen2 connected in series with the second switch 63a, and the voltage is converted into a voltage by the second current control unit connected with the second switch 63a through the resistor R _S2 . 64a). In other words, the gate of the second current control unit 64a is driven.

Here, the voltage for operating the second current controller 64a may be a divided voltage determined by the resistor R _s2 and the resistor R _off2 , and the second switch is operated by the operation of the second current controller 64a. Since the magnitude of the gate voltage of 63a is adjusted, the current flowing through the second switch 63a can be controlled constantly.

When the voltage supplied from the AC power supply 20a is greater than the total forward voltage of the LED module 30a, the first input current passes through the rectifying portion 40a and the output side of the LED module 30a (that is, the LED through the LEDs (D ₁₎ to the LED (D ₄₎ constituting the module (30a)) is input toward the first switch (61a).

At this time, since the first switch 61a is in an on state by being operated by the voltage generated by the driving control voltage generator 50a, the first input current input to the first switch 61a is the first switch 61a. Will pass through.

In this case, the first input current may serve as a main current for driving the LED array 30a.

In addition, the first input current is changed into a voltage by a resistor _Rsen1 connected in series with the first switch 61a, and the voltage is converted into a voltage by the first current controller 62a connected with the first switch 61a through the resistor R _s1 . ).

Here, the voltage for operating the first current controller 64a may be a divided voltage determined by the resistor R _s1 and the resistor R _GS1 , and may be a first switch by the operation of the first current controller 62a. Since the magnitude of the gate voltage of 61a is adjusted, the current flowing through the first switch 61a can be controlled constantly.

When the first current controller 62a is operated, the voltage of the resistor R _sen1 connected in series with the first switch 61a is transferred through the resistors R _off2 , R _off3 , and R _off4 to the second current controller 64a. The third current controller 66a and the fourth current controller 68a (that is, the second current controller 64a, the third current controller 66a, and the fourth current controller 68a) are turned on. (on) the second switch 63a, the third switch 65a, and the fourth switch 67a to be turned off so that the second input current, the third input current, and the fourth input current do not flow. can do.

In other words, the second current controller 64a, the third current controller 66a, and the fourth current controller 68a may be in an active area before the first input current is input to the first switch 61a. Operate to perform constant current control on the second input current, the third input current, and the fourth input current, and when the first input current is input to the first switch 61a, the on state is Thus, the second switch 63a, the third switch 65a, and the fourth switch 67a may serve as a dual role.

Therefore, according to the LED driving control apparatus 10a according to the first embodiment of the present invention, the driving control voltage generation unit 50a for generating a voltage for the operation of the driving current control unit 60a may include a resistor 52a and a zener diode. And a constant current control and formulation 2 switch 63a, a third switch 65a, and a fourth switch 67a for the second input current, the third input current, and the fourth input current. Since the second current control unit 64a, the third current control unit 66a, and the fourth current control unit 68a perform the off operation with respect to FIG. 2, the circuit configuration can be simplified and the circuit configuration cost can be reduced.

4 to 7 are reference diagrams for current-voltage waveforms according to a driving method of the LED driving control apparatus according to the first embodiment of the present invention.

As shown in FIGS. 4A and 5 to 7, when the magnitude of the positive voltage supplied from the AC power source 20a is greater than 25 percent of the total forward voltage of the LED array 20a, the fourth switch ( 67a) and the fourth input current i _Q4 which is constant current controlled by the operation of the fourth current controller 68a may be supplied to the LED array 20a, and the magnitude of the positive voltage may be the LED array 20a. If greater than 50 percent of the total forward voltage magnitude of the third input current (i _Q3 ) constant current controlled by the operation of the third switch 65a and the third current controller 66a can be supplied to the LED array 20a. And the second input current constant current controlled by the operation of the second switch 63a and the second current controller 64a when the magnitude of the positive voltage is greater than 75 percent of the total forward voltage of the LED array 20a. (i _Q2 ) can be supplied to the LED array 20a. When the magnitude of the positive voltage is greater than the total forward voltage of the LED array 20a, the first input current i _Q1 constant controlled by the operation of the first switch 61a and the first current controller 62a. ) May be supplied to the LED array 20a.

In addition, as described above, the magnitude of the positive voltage supplied from the AC power supply 20a, which is presented on the condition that the second input current, the third input current, and the fourth input current are supplied to the LED array 20a, respectively. The ratio (ie, 25 percent, 50 percent, 75 percent of the magnitude of the total forward voltage of the LED array 30a) is determined by the first input current, the second input current, the third input current, and the fourth input current. It is just one of the embodiments for having a four-level structure by vertical and horizontal summation of the above, and the ratio is not limited thereto, but it can be adjusted as needed (for example, 20%, 45%, 70 percent, etc.)

In addition, when the constant current controlled first input current i _Q1 is supplied to the LED array 20a, the second switch 63a, the third switch 65a, and the operation of the first current controller 62a. The fourth switch 67a may be turned off, and it may be confirmed that the driving region of each switch is wide in order of the fourth switch 67a, the third switch 65a, and the second switch 67a.

Accordingly, the input current Iac for driving the LED array 30a after being supplied from the AC power source 20a is the first input current, the second input current, the third input current, and the fourth input current. Because of the vertical and horizontal summation of the four-level structure (ie, four-stage structure), as shown in (b) of FIG. It is possible to have a sinusoidal shape possible.

8 is a circuit diagram of the LED driving control apparatus according to the second embodiment of the present invention.

As shown in FIG. 8, the LED driving control apparatus 10b according to the second exemplary embodiment of the present invention includes an AC power supply 20b, an LED array 30b, a rectifier 40b, a driving control voltage generator 50b, And a drive current controller 60b.

The AC power supply 20b supplies power for driving the LED array 30b, and the input side of the LED array 30b is connected to the output side of the AC power supply 20b.

In this case, the LED array 30b includes a plurality of LEDs connected in series, and each LED may be a DC driving LED driven by DC.

The rectifier 40b is connected between the output side of the AC power supply 20b and the input side of the LED array 30b. More specifically, the output side of the rectifier 40b is connected to the input side of the LED array 30b. The input side of the rectifier 40b is connected to the driving control voltage generator 50b and the driving current controller 60b, and rectifies the power supplied from the AC power source 20b and outputs the rectified power to the LED array 30b.

In this case, the rectifier 40b may include a plurality of diode pairs connected in the forward direction.

The driving control voltage generator 50b has one side connected to the LED array 30b and the other side connected to the rectifier 40b, and inputs a current passing through some LEDs (D _{1 in} FIG. 5) of the LED array 30b. And generates a voltage for the operation of the drive current controller 60b.

In this case, the driving control voltage generator 50b may include a resistor R _B connected to one side of the LED array 30b and a zener diode Z _DB connected in series with the other side of the resistor R _B.

One side of the driving current controller 60b is connected to the driving control voltage generator 50b and the LED array 30b, and the other side of the driving current controller 60b is connected to the input side of the rectifier 40b and is generated by the driving control voltage generator 50b. The control unit performs constant current control of a plurality of input currents inputted after passing through at least one or more LEDs constituting the LED array 30b.

In this case, one side of the driving current controller 60b is connected to the output side of the LED array 30b and the first input current i _Q1 input from the output side of the LED array 30b is input. A first current controller 62b connected to a first switch 61b and a first switch 61b to control the first input current in a constant current, and one side thereof is connected to an LED array 30b and includes an LED among the plurality of input currents. The second input is connected to the second switch 63b and the second switch 63b through which the second input current i _Q2 passing through some of the LEDs D ₁ to D ₃ constituting the array 30b is input. A second current controller 64b configured to control the constant current, one side of which is connected to the LED array 30b and passes through some LEDs D ₁ and D ₂ constituting the LED array 30b among the plurality of input currents; 3rd switch 65b to which 3 input current i _Q3 is input, 3rd switch 65b ) Is associated with and connected to the third current control section (66b), one side of the LED array (30b) to the constant current control of the third input current, some LEDs constituting the LED array (30b) of the plurality of input current (D ₁ A fourth switch 67b through which the fourth input current i _Q4 is input, and a fourth current controller 68b connected to the fourth switch 67b to control the fourth input current in a constant current. do.

At this time, the first current controller 62b operates when the first input current is input to the first switch 61b to turn off the second switch 63b, the third switch 65b, and the fourth switch 67b. The second current controller 64b may operate when the second input current is input to the second switch 63b to turn off the third switch 65b and the fourth switch 67b, and the third current. The controller 66b may operate when the third input current is input to the third switch 65b to turn off the fourth switch 67b.

In addition, the first switch 61b, the second switch 63b, the third switch 65b, and the fourth switch 67b may be MOSFETs or transistors, and the first current controller 62b may be a MOSFET, a transistor, Or a shunt regulator, and the second current controller 64b, the third current controller 66b, and the fourth current controller 68b may be MOSFETs or transistors.

Referring to FIG. 8, an operation process of the LED driving control apparatus 10b according to the second embodiment of the present invention will be described.

First, when the positive voltage supplied from the AC power source 20b increases to be greater than 25 percent of the total forward voltage of the LED array 20b, the fourth input current is part of the LEDs D ₁ constituting the LED array 30b. After passing through the input signal, the driving control voltage generator 50b and the driving current controller 60b are input to the fourth switch 67b.

Then, the first switch 61b, the second switch 63b, the third switch 65b, and the fourth switch 67b are formed by the voltage generated according to the current input to the driving control voltage generation unit 50b. In operation, the fourth input current input to the fourth switch 67b side passes through the fourth switch 67b.

In this case, the fourth input current may play a role of an auxiliary current for improving the power factor and drive some of the LEDs D ₁ constituting the LED array 30b to minimize flicker.

In addition, the fourth input current passing through the fourth switch 67b is converted into a voltage through a resistor R _sen4 connected to the fourth switch 67b, and the voltage is passed through the resistor R _S4 and then the fourth switch. The fourth current controller 68b connected to the 67b is operated. (In other words, the gate of the fourth current controller 68b is driven.)

In this case, the voltage for operating the fourth current controller 68b may be a divided voltage determined by the resistor R _S4 and the resistor R _OFF40 , and by the operation of the fourth current controller 68b, the fourth switch ( Since the magnitude of the gate voltage of the 67b) is adjusted, the current flowing through the fourth switch 67b can be controlled by the constant current.

Next, when the voltage supplied from the AC power source 20b is greater than 50 percent of the total forward voltage of the LED array 30b, the third input current may cause some of the LEDs D ₁ and D ₂ constituting the LED array 30b. After passing through, it is input to the third switch 65b side.

At this time, since the third switch 65b is in an on state by being operated by the voltage generated by the driving control voltage generator 50b, the third input current input to the third switch 65b is the third switch 65b. The third input current plays a role of an auxiliary current for improving power factor and at the same time, drives some of the LEDs D ₁ and D ₂ constituting the LED array 30b to minimize flicker. Can be.

In addition, the third input current is converted into a voltage by a resistor R _sen3 connected in series with the third switch 65b, and the voltage is converted into a voltage through the resistor R _S3 . 66b). (In other words, the gate of the third current controller 66b is driven.)

Here, the voltage for operating the third current controller 66b may be a divided voltage determined by the resistor R _S3 and the resistor R _off30 , and may be a third switch by the operation of the third current controller 66b. Since the magnitude of the gate voltage of 66b is adjusted, the current flowing through the third switch 66b can be controlled constantly.

Further, by the voltage across the resistance (R _sen3) operating a fourth current control unit (68b) via a diode (D ₃₎ and a resistor (R _off41) is associated with the resistance (R _sen3) (that is, a fourth current control ( Since the fourth switch 67b is turned off by turning on 68b), the fourth input current does not flow.

When the voltage supplied from the AC power supply 20b is greater than 75 percent of the total forward voltage of the LED array 30b, the second input current passes through some arrays D ₁ to D ₃ constituting the LED module 30b. After that, it is input to the second switch 63b side.

At this time, since the second switch 63b is in an on state by being operated by the voltage generated by the driving control voltage generator 50b, the second input current input to the second switch 63a is the second switch 63b. The second input current serves to minimize the flicker by driving some of the LEDs D ₁ to D ₃ constituting the LED array 30b at the same time as the auxiliary current for improving the power factor. Can be.

In addition, the second input current is converted into a voltage by a resistor R _sen2 connected in series with the second switch 63b, and the voltage is converted into a voltage by the second current controller connected with the second switch 63b through the resistor R _s2 . 64b). In other words, the gate of the second current controller 64b is driven.

Here, the voltage for operating the second current controller 64b may be a divided voltage determined by the resistor R _s2 and the resistor R _off20 , and the second switch may be controlled by the operation of the second current controller 64b. Since the magnitude of the gate voltage of 63b is adjusted, the current flowing through the second switch 63b can be controlled constantly.

Further, by the voltage across the resistance (R _sen2) operating a third current control section (66b) through the resistor (R _sen2) and connected diode (D ₁₎ and a resistor (R _off31) (that is, the third current control ( 66b), the through-on (on) to) the third switch (65b) so that it does not to ensure that off flow through the third input current, associated with the resistance (R _sen2) diode (D ₂₎ and a resistor (R _off42) a The fourth current control unit 68b may be operated (that is, the fourth current control unit 68b is turned on) to turn off the fourth switch 67b so that the fourth input current does not flow.

When the voltage supplied from the AC power supply 20b is greater than the total forward voltage of the LED module 30b, the first input current passes through the rectifying unit 40b and then the output side of the LED module 30b (that is, the LED It passes through the LEDs (D ₁ ) to (D ₄ ) constituting the module 30b and is input to the first switch 61b side.

At this time, since the first switch 61b is in an on state by being operated by the voltage generated by the driving control voltage generator 50b, the first input current input to the first switch 61b is the first switch 61b. Will pass through.

In this case, the first input current may serve as a main current driving the LED array 30b.

In addition, the first input current is converted into a voltage by a resistor R _sen1 connected in series with the first switch 61b, and the voltage is converted into a voltage by the first current control unit connected to the first switch 61b through the resistor R _s1 . 62b). In other words, the gate of the first current control unit 62b is driven.

Here, the voltage for operating the first current controller 62b may be a divided voltage determined by the resistor R _s1 and the resistor R _GS1 , and may be a first switch by the operation of the first current controller 62b. Since the magnitude of the gate voltage of 61b is adjusted, the current flowing through the first switch 61b can be controlled constantly.

When the first current controller 62b is operated, the voltage of the resistor R _sen1 connected in series with the first switch 61b is _changed through the resistors R _off20 , R _off30 , and R _off40 through the second current controller 64b. The third current controller 66b and the fourth current controller 68b (that is, the second current controller 64b, the third current controller 66b, and the fourth current controller 68b) are turned on. (on) the second switch 63b, the third switch 65b, and the fourth switch 67b to be turned off so that the second input current, the third input current, and the fourth input current do not flow. can do.

In other words, before the third input current is input to the third switch 65b, the fourth current controller 68b operates in an active region to perform the constant current control on the fourth input current. When the third input current is input to the third switch 67b, the third input current is turned on to play a dual role of turning off the fourth switch 67b, and the third current controller 66b performs the second input current. Before is input to the second switch 63b side, it operates in the active area to perform constant current control on the third input current, and when the second input current is input to the second switch 63b side, the second state control unit 64b is in an on state and performs an dual role of turning off the third switch 67b, and the second current controller 64b is an active region before the second input current is input to the second switch 63b. Operate at the first input Performing a constant current control to the current and, if the first input current to the input side of the first switch (63b) on (on) is the state can perform a dual role of turning off the second switch (63b).

Accordingly, according to the LED driving control device 10b according to the second embodiment of the present invention, the driving control voltage generation unit 50b for generating a voltage for the operation of the driving current control unit 60b may include a resistor 52b and a zener diode. 54b, the constant current control and the second switch 63b, the third switch 65b, and the fourth switch 67b for the second input current, the third input current, and the fourth input current. Since the second current controller 64b, the third current controller 66b, and the fourth current controller 68b perform the off operation with respect to FIG. 2, the circuit configuration can be simplified and the circuit configuration cost can be reduced.

9 and 10 are reference diagrams for current-voltage waveforms according to a driving method of the LED driving control apparatus according to the second embodiment of the present invention.

As shown in FIGS. 9A and 10, when the magnitude of the positive voltage supplied from the AC power source 20b is greater than 25 percent of the total forward voltage of the LED array 20b, the fourth switch 67a and The fourth input current i _Q4 , which is constant current controlled by the operation of the fourth current controller 68b, may be supplied to the LED array 20b, and the magnitude of the positive voltage is forward in the entire forward direction of the LED array 20b. When greater than 50 percent of the voltage magnitude, the third input current i _Q3 which is constant current controlled by the operation of the third switch 65b and the third current controller 66b may be supplied to the LED array 20b. When the magnitude of the positive voltage is greater than 75 percent of the total forward voltage of the LED array 20b, the second input current i _Q2 which is constant current controlled by the operation of the second switch 63b and the second current controller 64b. ) May be supplied to the LED array 20a, The positive voltage of the larger than the total forward voltage of the LED array (20b) of the first switch (61b) and a first operation on said first input current (i _Q1) of the constant current control by the current control section (62b) LED It can be supplied to the array 20b.

In addition, when the third input current i _Q3 is supplied to the LED array 20b through the third switch 65b, the fourth switch 68b is turned off by the operation of the third current controller 66b. When the second input current i _Q2 is supplied to the LED array 20b through the second switch 63b, the third switch 66b and the third switch may be operated by the operation of the second current controller 64b. The fourth switch 68b may be turned off, and when the first input current i _Q1 is supplied to the LED array 20b through the first switch 61b, the operation of the first current controller 62b may not be performed. The second switch 63b, the third switch 65b, and the fourth switch 67b may be turned off, and the first switch 61b, the second switch 63b, and the third switch 65b may be turned off. It can be seen that the fourth switch 67b partially operates only at a specific voltage.

Accordingly, the input current I _ac for driving the LED array 30b after being supplied from the AC power source 20b is the first input current, the second input current, the third input current, and the fourth input. Since the vertical summation of currents results in a four-level structure (ie, a four-stage structure), as shown in FIG. It is possible to have a sinusoidal shape.

FIG. 11 is a circuit diagram of the LED driving control apparatus according to the third embodiment of the present invention, and FIG. 12 is a reference diagram of a current voltage waveform according to the driving method of the LED driving control apparatus according to the third embodiment of the present invention.

As shown in FIG. 11, the LED driving control apparatus 100a according to the third exemplary embodiment of the present invention includes an AC power supply 110a, an LED array 120a, a rectifying unit 130a, a driving control voltage generating unit 140a, and The driving current controller 150a is included.

Here, in the LED driving control apparatus 100a according to the third embodiment of the present invention, a plurality of input currents passing through at least one or more LEDs constituting the LED array 120a may include a first input current and a second input current. And a third input current and have a three-level structure (that is, a three-stage structure) by horizontal and vertical summation of the first input current, the second input current, and the third input current. The driving current controller 150a may include a first switch 151a, a first current controller 152a, a second switch 153a, a second current controller 154a, a third switch 155a, and a third current controller ( 156a, the detailed configuration and operation method of the LED drive control device 100a according to the third embodiment of the present invention are the same as the LED drive control device 10a according to the first embodiment of the present invention. Detailed description thereof will be omitted.

As shown in FIG. 12, when the magnitude of the positive voltage input from the AC power source 110a is greater than 1/3 of the magnitude of the overall forward voltage of the LED array 120a, the third input current i _Q3 is the LED. When the positive voltage is greater than 2/3 of the magnitude of the total forward voltage of the LED array 120a, the second input current i _Q2 is supplied to the LED array 110a. When the positive voltage is greater than the total forward voltage of the LED array 120a, since the first input current i _Q1 is supplied to the LED array 110a, the LED array is supplied from the AC power source 110a. Since the input current I _ac driving 120a has a three-level structure by vertical and horizontal summation of the first input current, the second input current, and the third input current (that is, 3 (B) has a structure As shown in Fig. 2), it is possible to have a sinusoidal shape that maintains a constant current even when the input voltage fluctuates, and can suppress harmonics and improve the power factor.

FIG. 13 is a circuit diagram of the LED driving control apparatus according to the fourth embodiment of the present invention, and FIGS. 14 and 15 are reference diagrams for current voltage waveforms according to the driving method of the LED driving control apparatus according to the fourth embodiment of the present invention. to be.

As shown in FIG. 13, the LED driving control apparatus 110b according to the fourth exemplary embodiment of the present invention includes an AC power supply 110b, an LED array 120b, a rectifier 130b, a driving control voltage generator 140b, and And a driving current controller 150b.

Here, in the LED driving control apparatus 100b according to the fourth embodiment of the present invention, a plurality of input currents passing through at least one or more LEDs constituting the LED array 120b may include a first input current and a second input current. And a driving current so as to have a three-level structure (that is, a three-stage structure) by vertical summation of the first input current, the second input current, and the third input current. The control unit 150b includes the first switch 151b, the first current controller 152b, the second switch 153b, the second current controller 154b, the third switch 155b, and the third current controller 156b. In this configuration, the detailed configuration and operation method of the LED drive control device 110b according to the fourth embodiment of the present invention is the same as the LED drive control device 10b according to the second embodiment of the present invention Detailed description will be omitted.

14 and 15, when the magnitude of the positive voltage input from the AC power source 110b is greater than 1/3 of the magnitude of the overall forward voltage of the LED array 120b, the third input current i _Q3. ) Is supplied to the LED array 110b and the second input current i _Q2 is directed to the LED array 110b when the positive voltage is greater than 2/3 of the magnitude of the overall forward voltage of the LED array 120b. When the positive voltage is greater than the size of the entire forward voltage of the LED array 120b, since the first input current i _Q1 is supplied to the LED array 110b, the positive voltage is supplied from the AC power source 110a. Since the input current I _ac for driving the LED array 120a has a three-level structure by vertical summation of the first input current, the second input current, and the third input current (that is, Will have a three-stage structure) (B) it maintains a constant current to the input voltage fluctuation, as shown in, and it is possible to have a possible sinusoidal harmonic suppression and a power factor improvement.

In addition, although not shown in the drawings, the LED module 3b of FIG. 2 is configured to include a plurality of LED pairs in which the LED arrays are connected in parallel in a reverse direction by using an AC driving LED. In such a manner as to configure the LED drive control device according to the embodiment, it is possible to implement the LED drive control device according to the first to fourth embodiments of the present invention using the AC drive LED.

The above description is merely illustrative of the technical idea of the present invention, and various modifications, changes, and substitutions may be made by those skilled in the art without departing from the essential characteristics of the present invention. It will be possible. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

(10a, 10b, 100a, 100b): LED drive control device
(20a, 20b, 110a, 110b): AC power supply (30a, 30b, 120a, 120b): LED array
(40a, 40b, 130a, 130b): rectifier
(50a, 50b, 140a, 140b): drive control voltage generator
(60a, 60b, 150a, 150b): drive current controller

Claims (10)

In the LED drive control device using an AC power source,
An LED array having an input side connected to an output side of the AC power supply;
A rectifier connected between an output side of the AC power source and an input side of the LED array;
A driving control voltage generator having one side connected to the LED array and the other side connected to the rectifier; And
One side is connected to the drive control voltage generator and the LED array, and the other side is connected to the rectifier and operated by the voltage generated by the drive control voltage generator to pass through at least one LED constituting the LED array. And a drive current control unit configured to control the constant current of the plurality of input currents. The method of claim 1,
The driving control voltage generation unit LED driving control apparatus, characterized in that the one side comprises a resistor connected to the LED array and a Zener diode connected to the other side of the resistance. The method of claim 1,
The driving current controller may include a first switch having one side connected to an output side of the LED array and a first input current input from an output side of the LED array among the plurality of input currents, and one side connected to the LED array. A second switch connected in parallel with the first switch and receiving a second input current passing through some LEDs of the plurality of input currents, one side of which is connected to the LED array and connected to the second switch in parallel; A third switch to which a third input current passing through some LEDs of the LED array is input, and one side of the plurality of input currents is connected to the LED array and connected in parallel with the third switch, wherein the third switch includes: A fourth switch to which a fourth input current passing through some LEDs of the LED array is input; LED drive control device comprising a. The method of claim 3, wherein
A first current controller connected to the first switch and configured to control the first input current and to turn off the second switch, the third switch, and the fourth switch when the first input current is input; A second current controller connected to a switch and configured to control the second input current and to turn off the third switch and the fourth switch when the second input current is input, the third switch connected to the third switch and the third input current A third current controller configured to control the constant current and turn off the fourth switch when the third input current is input, and a fourth current controller connected to the fourth switch and configured to perform a constant current control of the fourth input current. LED drive control device characterized in that. The method of claim 3, wherein
A first current controller connected to the first switch and configured to control the first input current and to turn off the second switch, the third switch, and the fourth switch when the first input current is input; A second current controller connected to a switch and configured to constant current control the second input current, a third current controller connected to the third switch and configured to constant current control the third input current, and a fourth switch connected to the fourth switch. And a fourth current controller configured to control the constant current of the input current. The method of claim 3, wherein
And the first switch, the second switch, the third switch, and the fourth switch are MOSFETs or transistors. The method according to claim 4 or 5,
And the first current controller is a MOSFET, a transistor, or a shunt regulator. The method according to claim 4 or 5,
And the second current controller, the third current controller, and the fourth current controller are MOSFETs or transistors. The method of claim 1,
And the LED array includes a plurality of LEDs connected in series, and each of the plurality of LEDs is a DC driving LED. The method of claim 1,
And the LED array includes a plurality of LED pairs connected in parallel in a reverse direction, and each LED constituting the LED pair is an AC driving LED.

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