KR20160075487A - LED driving circuit supporting different kind of power supply - Google Patents

Abstract

Provided is a lighting device which can be connected to AC power sources having various voltages. The lighting device includes a first light emitting unit; a backflow preventing unit connected to a lower end of the first light emitting device in series; a resistor connected to a lower end of the backflow preventing unit in series; a second light emitting unit connected to a lower end of the resistor in series; and a transistor including a first terminal connected to an upper end of the first light emitting device, a second terminal connected to an upper end of the resistor, and a third terminal connected to a bias voltage connected to the lower end of the resistor, wherein the transistor turns on/off a current passage between the first and second terminals according to a peak value of a power input from a power source unit.

Description

[0001] The present invention relates to a LED driving circuit,

The present invention relates to an LED lighting circuit capable of being directly connected to an AC power supply of various voltages.

A light emitting diode (LED) is a kind of semiconductor device that can emit light of various colors by forming a light emitting source through the formation of a PN diode of a compound semiconductor. Such a light emitting device has a long lifetime, can be reduced in size and weight, and can be driven at a low voltage. In addition, these LEDs are resistant to shock and vibration, do not require preheating time and complicated driving, can be packaged after being mounted on a substrate or lead frame in various forms, so that they can be modularized for various purposes and used as a backlight unit A lighting device, and the like.

A plurality of light emitting diodes may be used to provide one independent illumination, wherein the light emitting diodes may be connected in series or in parallel. At this time, the commercial power may be converted into the direct current power and applied to the light emitting diodes so that all of the light emitting diodes are always turned on. In this case, a device for converting alternating current to direct current is further required.

When the direct current power supply is used as described above, a separate direct current rectifying unit is required. The configuration of the direct current rectifying unit can be removed and the alternating current power can be directly applied to the light emitting diodes. At this time, the light emitting diodes may be connected to each other in series, and the ON / OFF states of the light emitting diodes may be changed according to the magnitude of the varying input voltage. The flicker phenomenon occurs as the ON / OFF state is repeated, and the usage rate of each LED is lowered, thereby decreasing the light output efficiency.

(1) the flicker phenomenon can be eliminated or mitigated, and (2) the power factor can be prevented from being lowered due to the operation of the AC power source, even if the lighting device composed of the light emitting diodes is driven by the AC power source, It may be advantageous to use an AC power source.

On the other hand, the peak voltage of the commercial AC power source may vary from region to region. In this case, when one illumination device using LEDs is applied to an AC power source of different sizes, the brightness of the illumination device may be changed and the power efficiency may be changed. Therefore, even if AC power of different size is applied, LED lighting for AC power source that can exhibit uniform light output and efficiency is needed.

In order to solve the above-described problems, the present invention provides an LED driving apparatus capable of supporting a heterogeneous power supply.

According to an aspect of the present invention, there is provided an illumination device comprising: a first light emitting portion; A second light emitting portion; And a control voltage output unit adapted to output a control voltage according to a peak value of the input power supplied. The first light emitting unit and the second light emitting unit are switched between a serial connection state and a parallel connection state according to the value of the control voltage.

Here, the control voltage output unit may include a peak detecting unit configured to hold a peak value of the input power source and output a peak voltage Vpeak; And a voltage comparator adapted to output the control voltage having a first logic value if the peak voltage is greater than a predetermined value and a second logic value otherwise.

Here, the first logic value may be a logic high and the second logic value may be a logic low, or the first logic value may be a logic low and the second logic value may be a logic high. In addition, the peak detecting unit may include a diode and a capacitor.

The illumination device may further include: a switch unit connecting between a first upstream end of the first light emitting unit and a second upstream end of the second light emitting unit; And a backflow prevention unit connecting between the first downstream end of the first light emitting unit and the second upstream end.

At this time, the switch unit is configured to form a current path between the first upstream end and the second upstream end when the control voltage has the first logic value, and to block the current path when the control voltage has the second logic value .

The illumination device may further include: a first driver; And a second driver, wherein the first driver is configured to control a value of a current flowing through the first LED when the input power has a first value, wherein the input power is greater than the first value And may not control the value of the current flowing through the first LED unit when the second LED has a large second value.

Here, the second driver may control a value of a current flowing through the second LED unit when the input power source has the first value, and when the input power source has the second value, And a current value flowing through the second LED unit.

The internal circuit of the second driver may have a first configuration when the input power has the first value and a second configuration when the input power has the second value . And the illumination device may be configured to have the same light output when the input power source has the first value and when the input power source has the second value.

Also, the first LED unit may include a plurality of LED groups, and the plurality of LED groups may be sequentially turned on from the upstream end to the downstream end of the plurality of LED groups when the voltage value of the input power source rises have.

The second LED unit may include a plurality of LED groups, and the plurality of LED groups may be sequentially turned on from the upstream end to the downstream end of the plurality of LED groups when the voltage value of the input power source rises .

In addition, the first LED unit includes a plurality of LED groups, and when the voltage value of the input power source rises, the plurality of LED groups are switched from the parallel connection to the serial connection state .

The second LED unit includes a plurality of LED groups, and when the voltage value of the input power source rises, the plurality of LED groups are switched from the parallel connection to the serial connection state .

According to the present invention, it is possible to provide an LED driving apparatus capable of switching the serial-parallel connection state according to the peak value of the AC power supply voltage in the LED driving system, It is possible to provide an LED driver capable of adjusting the output to be the same.

FIG. 1 shows an LED driving apparatus 100 according to a first embodiment of the present invention.
2A shows the operation of the LED driving apparatus 100 and the connection of circuit configurations when operated by a commercial power source having a first voltage (ex: 120V).
FIG. 2B shows the operation of the LED driving apparatus 100 and the connection of the circuit configuration when operated by a commercial power source having a second voltage (ex: 277V).
The first LED unit 30 and the first driving unit 31 of FIG. 3A further illustrate one embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. 1, respectively.
The second LED portion 32 and the second drive portion 33 of FIG. 3B further illustrate other embodiments of the internal structure of the second LED portion 12 and the second drive portion 17 of FIG. 1, respectively.
FIG. 3 (a) shows an example of the waveform of the output voltage Vi of the power supply unit 10 of FIG. 3a on the time axis.
(B), (c), (d) and (e) in FIG. 3c are graphs showing the relationship between the output voltage Vi of each of the light emitting groups CH1 to CH4 An example of the current waveforms (ID1 to ID4) is shown on the time axis.
The first LED unit 40 and the first driving unit 41 of FIG. 4A respectively show still another embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. 1, respectively.
The second LED portion 42 and the second driving portion 43 of FIG. 4B further illustrate another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG. 1, respectively.
Fig. 4C shows the circuit shown in Fig. 4A in which only one channel portion is separated.
4D shows the waveform of the input current Ik flowing through the backflow prevention diode D and FIG. 4B shows the waveform of the light emission current ILED flowing through the light emitting group CH And FIG. 4 (d) shows the waveform of the capacitor current (IC) flowing through the capacitor C. In FIG.
The first LED unit 50 and the first driving unit 51 of FIG. 5A each have another embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. 1 It is detailed.
The second LED portion 52 and the second drive portion 53 of FIG. 5B further have another embodiment of the internal structure of the second LED portion 12 and the second drive portion 17 of FIG. It is detailed.
FIG. 5C shows the voltage and current characteristics of each node and element of the LED lighting circuit 5 shown in FIGS. 5A and 5B with respect to time.
The first LED unit 60 and the first drive unit 61 of FIG. 6A respectively show another embodiment of the internal structure of the first LED unit 11 and the first drive unit 16 of FIG. 1 in more detail.
The second LED portion 62 and the second driving portion 63 of FIG. 6B further illustrate another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG. 1, respectively.
7 shows on / off states of the switches included in the LED lighting circuit of FIG. 6 according to input voltages.
8A to 8E show equivalent circuit structures of the first LED unit 80 and the first driver 81 in the time domain (P1 to P5), respectively.
Figs. 8F to 8J show equivalent circuit structures of the second LED portion 82 and the second driver 83 in the time periods P1 to P5, respectively.
The first LED 101 and the first driving unit 102 of FIGS. 9A through 9J respectively show another embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. And the second LED portion 103 and the second driving portion 104 respectively show another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG.
10A is a view for explaining a structure of a light emitting device according to a seventh embodiment of the present invention.
10B shows a power supply unit 10, a light emitting group 220, a first bypass unit 230, a second bypass unit 240, and a light emitting device 901 shown in FIG. 10A.
11 is a view for explaining the structure of the LED lighting device 300 according to the eighth embodiment of the present invention
12 is a view for explaining a structure of an LED lighting apparatus 400 according to a ninth embodiment of the present invention.
FIG. 13 is a view for explaining the structure of an LED lighting apparatus 500 according to a tenth embodiment of the present invention.
14 is a view for explaining an embodiment of a light emitting unit constituting an LED driving apparatus according to an eleventh embodiment of the present invention.
The first LED unit 150 and the first driving unit 151 of FIG. 15A further illustrate another embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. 1, respectively.
The second LED portion 152 and the second driving portion 153 of FIG. 15B further illustrate another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG. 1, respectively.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein, but may be implemented in various other forms. The terminology used herein is for the purpose of understanding the embodiments and is not intended to limit the scope of the present invention. Also, the singular forms as used below include plural forms unless the phrases expressly have the opposite meaning.

≪ Embodiment 1 >

FIG. 1 shows an LED driving apparatus 100 according to a first embodiment of the present invention. 1, the LED driving apparatus 100 includes a power supply unit 10, LED units 11 and 12, a control voltage output unit 13, drivers 16 and 17, a switch unit 18, And the backflow prevention portion 19.

The power supply unit 10 refers to a power supply unit that outputs a waveform repeatedly increasing or decreasing with time, and can output a ripple having a period of, for example, 100 Hz / 120 Hz. The peak voltage at this time may have a value of, for example, 120V * 1.414 or 277V * 1.414. The LEDs 11 and 12 may include one or more LED groups 20. At this time, the LED groups 20 included in the LED units 11 and 12 may be referred to as individual LED channels or light emitting groups. For example, if there are N LED groups in one LED unit, it can be seen that there are N LED channels. It is assumed that the LED driving apparatus 100 includes the first LED unit 11 and the second LED unit 12 in the first embodiment of the present invention. The LED unit may be referred to as a light emitting unit.

The control voltage output unit 13 may include a peak detection unit 14 and a voltage comparison unit 15. The peak detector 14 holds and outputs the peak value Vpeak of the output voltage of the power source 10. The voltage ratio control unit 15 compares the peak value Vpeak with a preset value and outputs a control voltage Vcon. The control voltage Vcon has a logical high value if the peak value Vpeak is greater than the preset value, and otherwise has a logical low value. At this time, the control voltage Vcon may have a logical low value if the peak value Vpeak is greater than the predetermined value, and may otherwise have a logical high value. The predetermined value may be provided to the voltage ratio distributor 15 using a voltage divider R1 / R2.

Driving units 16 and 17 may be connected to the LED units 11 and 12. The first LED unit 11 may be connected to the first driving unit 16 and the second LED unit 12 may be connected to the second driving unit 17. [

The first driver 16 is characterized in that the on / off state or the enable / disable state is switched according to the logic value of the control voltage Vcon.

However, the second driver 17 maintains the on-state at all times without being switched between the on / off states according to the logic value of the control voltage Vcon. However, the internal configuration of the second driver 17 may vary according to the logic value of the control voltage Vcon.

The current flowing in the first LED unit 11 can be controlled by the first driving unit 16 when the LED driving apparatus 100 is operated by a commercial power source having the first voltage ex .

However, when the LED driving apparatus 100 is operated by a commercial power source having a second voltage (ex: 277V) higher than the first voltage, the first driving unit 16 is disabled, The current flowing in the unit 11 can be controlled by the second driving unit 17 without being controlled by the first driving unit 16. [

On the other hand, when the LED driving apparatus 100 is operated by the commercial power source having the first voltage (ex: 120V), the current flowing in the second LED unit 12 is controlled by the second driving unit 17 .

When the LED driving apparatus 100 is operated by a commercial power source having a second voltage (ex: 277V) higher than the first voltage, the first driving unit 16 is disabled, The current flowing in the first LED unit 12 and the second LED unit 12 can be controlled by the second driver 17. At this time, the total light output from the first LED unit 11 and the second LED unit 12 is determined only by the second driver 17.

The switch unit 18 may be connected between the first upstream end of the first LED unit 11 and the second upstream end of the second LED unit 12 and the first downstream end of the first LED unit 11 and the second upstream end of the second LED unit 12 may be connected. The backflow prevention part 19 can be connected between the second upstream end of the two LED parts 12. The switch unit 18 is adapted to switch the on / off state according to the logic value of the control voltage Vcon. The current output from the power supply unit 10 is divided into the first LED unit 11 and the second LED unit 12 when the switch unit 18 is turned on. That is, the first LED unit 11 and the second LED unit 12 are connected to each other in parallel. On the other hand, when the switch unit 18 is in the off state, the first LED unit 11 and the second LED unit 12 are connected in series, and no current flows through the switch unit 18.

2A shows the operation of the LED driving apparatus 100 and the connection of circuit configurations when operated by a commercial power source having a first voltage (ex: 120V). 2A, the peak detector 14 outputs a voltage peak value of 120 * 1.414 (= 2) when the voltage of the power source 10 is the first voltage (ex: 120V) (Vcon = Low) to output the logic low value to the control voltage Vcon. The low value of the voltage comparator 15 is input to the first driving unit 16, the second driving unit 17, and the switch unit 18. Accordingly, the first driving unit 16 maintains the ON state and the internal circuit of the second driving unit 17 has the first configuration. The switch unit 18 is also kept in the ON state. That is, when the control voltage Vcon has a low value, a current path passing through the switch unit 18 is formed between the first upstream end and the second upstream end. The downstream end of the first LED unit 11 and the upstream end of the second LED unit 12 are short-circuited to each other so that the first driving unit 16, And the second driving unit 17 are connected to each other in parallel.

The first driver 16 is configured to control the value of the current flowing through the first LED 11 in the case of operating with a commercial power source having a first voltage ex (120 V). For example, the first driving unit 16 can control the first LED unit 11 to have an output of 10W. The second driving unit 17 is configured to control the value of the current flowing through the second LED unit 12. For example, the second driving unit 17 can control the second LED unit 12 to have an output of 10W. To this end, the second driving unit 17 must operate according to the first configuration described above. The first driving unit 16 and the second driving unit 17 together can control the first LED unit 11 and the second LED unit 12 to have a total output of 20W.

FIG. 2B shows the operation of the LED driving apparatus 100 and the connection of the circuit configuration when operated by a commercial power source having a second voltage (ex: 277V). 2B, when the voltage of the power source 10 is the second voltage (ex: 277V), the peak detector 14 outputs a voltage peak value of 277 * 1.414 (2), and the voltage comparator 15 And outputs a logic high value (Vcon = High). The high value of the voltage comparator 15 is input to the first driving unit 16, the second driving unit 17, and the switch unit 18. Accordingly, the first driving unit 16 is turned off, the second driving unit 17 is maintained in the ON state, and the internal circuit of the second driving unit 17 has the second configuration . The switch unit 18 is maintained in the OFF state. That is, when the control voltage Vcon has a high value, the current path between the first upstream end and the second upstream end is cut off. Accordingly, the first LED unit 11 and the second LED unit 12 are connected in series with each other.

At this time, the second driving unit 17 is configured to control a current value flowing through the first LED unit 11 and the second LED unit 12. That is, the second driving unit 17 can control the first LED unit 11 and the second LED unit 12 to have a total output of 20W. To this end, the second driving unit 17 must operate in the second configuration described above.

The first and second configurations described above may mean a configuration in which the equivalent resistance by the sensing resistor Rs2 and the sensing resistor Rs3 described later has a first value and a configuration in which a second value is set.

Hereinafter, the power supply unit, the LED unit, and the driving unit included in the LED driving apparatus 100 may be collectively referred to as an 'LED lighting circuit' and an 'LED lighting apparatus'. According to the second to twelfth embodiments of the present invention, the LED lighting apparatus may be configured in various ways according to the serial and parallel states of the LED units 11 and 12. [

≪ Embodiment 2 >

The first LED unit 30 and the first drive unit 31 of FIG. 3A respectively show one embodiment of the internal structure of the first LED unit 11 and the first drive unit 16 of FIG. 1, The second LED portion 32 and the second drive portion 33 of the first LED portion 3b and the second LED portion 12 of FIG. 1 respectively show another embodiment of the internal structure of the second LED portion 12 and the second drive portion 17 in detail.

3A shows a circuit in which the light emitting groups belonging to the first LED unit 30 are sequentially turned on from the upstream end to the downstream end in accordance with the voltage rise of the voltage unit 10 according to the second embodiment of the present invention will be. 3B shows a circuit in which the light emitting groups belonging to the second LED portion 32 are sequentially turned on from the upstream end to the downstream end in accordance with the voltage rise of the voltage portion 10 according to the second embodiment of the present invention will be.

3A and 3B, three LEDs are included in each of the four light emitting groups CH1 to CH4. When the control voltage Vcon having a low value is input to the first driving unit 31, the first driving unit 31 is in the ON state do. At this time, the switch unit (not shown) may connect between the first upstream end of the first LED unit 30 and the second upstream end of the second LED unit 32. The switch unit receives a control voltage Vcon having a low value and forms a current path between the first upstream end and the second upstream end. Thus, the first LED unit 30 and the second LED unit 32 are connected in parallel . As the voltage of the voltage unit 10 rises, the light emitting groups CH1 of the same number are simultaneously turned on in the light emitting groups of the first LED unit 30 and the second LED unit 32, CH2 to CH4) will be turned on. That is, the light emitting group CH1 of the first LED unit 30 and the light emitting group CH1 of the second LED unit 32 are simultaneously turned on, and then the light emitting group CH2 of the first LED unit 30 The light emitting group CH2 of the second LED portion 32 is simultaneously turned on. The light emitting groups CH3 and CH4 of the first LED unit 30 and the second LED unit 32 may be turned on in the same manner.

(Vcon) having a high value is input to the first driving unit 31, the first driving unit 31 is in the OFF state when it is operated by the commercial power supply having the second voltage (ex: 277V) do. At this time, the switch unit (not shown) may connect between the first upstream end of the first LED unit 30 and the second upstream end of the second LED unit 32. The switch unit receives the control voltage Vcon having a high value and cuts off the current path between the first upstream end and the second upstream end. The first LED unit 30 and the second LED unit 32 are connected in series . As the voltage of the voltage unit 10 rises, the light emitting groups CH1 to CH4 of the first LED unit 30 are sequentially turned on and the light emitting groups CH1 to CH4 of the second LED unit 32 are sequentially It turns on.

3B, a value of a second current flowing through the second LED unit 32 is controlled by the second driving unit 33. Specifically, the value of the second current flowing through the second LED unit 32 is controlled by the second driving unit 33, Is controlled by the sensing resistance value. Here, the sensing resistance may mean, for example, an equivalent resistance consisting of Rs2 and Rs3 shown in the second driver. At this time, the value of the equivalent resistance can be determined in the following manner. Vcon has a first logic value (ex: Low) when the input voltage has a first value (ex: 120V) and a second logic value ex when the input voltage has a second value (ex: 277V) : High). When Vcon has the first logic value (Low), since the sensing resistor Rs3 existing in the second driver does not appear to exist, the equivalent resistance formed by the two sensing resistors Rs2 and Rs3 becomes the first value = Rs2). When Vcon has the second logic value (High), the sensing resistor Rs2 and the sensing resistor Rs3 are connected in parallel to each other, so that the equivalent resistance has a second value (= Rs2 // Rs3).

If the input voltage is greater than the first value (ex: 120V) by properly selecting the values of the sensing resistor Rs1 of the first driver 31 and the sensing resistor Rs2 and sensing resistor Rs3 of the second driver 33, And the second total light output value of the LED driving apparatus 100 when the input voltage has a second value (ex: 277V) can be adjusted have. Preferably, the first total light output and the second total light output are the same.

FIG. 3C shows an example of one cycle of the waveform of the output voltage Vi of the power supply unit 10 of FIG. 3A on the time axis. (B), (c), (d) and (e) in FIG. 3c are graphs showing the relationship between the output voltage Vi of each of the light emitting groups CH1 to CH4 An example of the current waveforms (ID1 to ID4) is shown on the time axis. Referring to FIG. 3C, it can be seen that there is a time period in which no current flows in each of the light emitting groups CH1 to CH4, and a time period in which no current flows is longer for a light emitting group located downstream from the AC power source, It can be seen that the shape of the current according to the square wave becomes closer to the square wave. 3C, the variation of the brightness of each of the light emitting groups CH1 to CH4 may have a frequency value twice the frequency of the output voltage Vi of the power supply unit 10. [ This phenomenon is generally seen in the AC power direct LED driving device shown in Fig. 3A, and is 100% in terms of the percentage flicker.

≪ Third Embodiment >

The first LED unit 40 and the first drive unit 41 of FIG. 4A respectively show still another embodiment of the internal structure of the first LED unit 11 and the first drive unit 16 of FIG. 1, The second LED portion 42 and the second driving portion 43 of FIG. 4B further illustrate another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG. 1, respectively.

FIG. 4A is a diagram illustrating a first LED unit 40 and a second LED unit 40 of the LED lighting apparatus provided for smoothing the current applied to the LED of the AC power direct LED driving apparatus 100 according to the third embodiment of the present invention. 41). FIG. 4B is a diagram illustrating a second LED unit 42 and a second LED unit 42 provided in order to smooth the current applied to the LED of the AC power direct LED driving apparatus 100 according to the third embodiment of the present invention. 43).

Referring to FIGS. 4A and 4B, the backflow prevention diodes D and D1 to D3 are connected in series between the light emitting groups CH1 to CH4. Capacitors C1 to C4 are connected in parallel to the light emitting groups CH1 to CH4, respectively.

When the control voltage Vcon having a low value is input to the first drive unit 41, the first drive unit 51 is in the ON state do. At this time, the switch unit (not shown) may connect between the first upstream end of the first LED unit 40 and the second upstream end of the second LED unit 42. Since the switch unit receives the control voltage Vcon having the Low value and forms a current path between the first upstream end and the second upstream end, the first LED unit 40 and the second LED unit 42 are connected in parallel .

(Vcon) having a high value is input to the first driving unit 41, the first driving unit 41 is in the OFF state do. At this time, the switch unit (not shown) may connect between the first upstream end of the first LED unit 40 and the second upstream end of the second LED unit 42. The switch unit receives the control voltage Vcon having a high value to cut off the current path between the first upstream end and the second upstream end and the first LED unit 40 and the second LED unit 42 are connected in series .

Fig. 4C shows the circuit shown in Fig. 4A in which only one channel portion is separated. FIG. 4C shows a case where a capacitor C is connected in parallel to a light emitting group CH corresponding to any one of the channels. The backflow prevention diode D is connected in series to the light emitting group CH and the capacitor C. The light emitting group CH may be composed of one or more LEDs.

4D shows a waveform of the input current I _k flowing through the backflow prevention diode D and FIG. 4D shows a waveform of the light emission current I _LED flowing through the light emitting group CH. (C) of FIG. 4D shows the waveform of the capacitor current I _C flowing through the condenser _C , and FIG.

When the input current I _k is input, the input current I _k is divided into the capacitor C and the light emitting group CH while the voltage of the capacitor C increases, The current (I _LED ) also increases.

When the input current I _k is not inputted, the capacitor C is discharged and a current due to the discharge flows into the light emitting group CH.

The larger the capacity of the condenser C, the longer the discharge time can be. The current flowing through the light emitting group CH does not become 0 and the value of the current is maintained at a certain level or more when the discharging time is sufficiently larger than the half cycle of the input power source (e.g., 1/120 second in the case of 60 hz power supply). Therefore, the light emitting group CH can be darkened with time, but is not turned off. As the capacitance of the capacitor C becomes larger, the current flowing through the light-emitting group CH becomes smoother and the flicker is reduced.

In the LED lighting device according to the third embodiment of the present invention shown in Figs. 4A and 4B, among the arbitrary first light emitting group and the second light emitting group, the first light emitting group is connected to the input power source The length of the first time at which the input power directly supplies power to the first light emitting group is longer than the length of the second time at which the input power supplies the direct light to the second light emitting group Can be confirmed through FIG. 3C.

In the LED lighting apparatus according to the fourth to tenth embodiments of the present invention, the length of the first time may be substantially equal to the length of the second time.

<Fourth Embodiment>

The first LED unit 50 and the first driving unit 51 of FIG. 5A each have another embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. 1 The second LED portion 52 and the second drive portion 53 of FIG. 5B correspond to another structure of the internal structure of the second LED portion 12 and the second drive portion 17 of FIG. The embodiment is shown in more detail.

5A and 5B show an example of an LED lighting device 5 including a light emitting group CH1 to CH2 which can be converted into a serial-parallel connection state according to a fourth embodiment of the present invention.

The first drive unit 51 is in the ON state since the control voltage Vcon having the Low value is input to the first drive unit 51 when the first drive unit 51 is operated by the commercial power source having the first voltage ex do. At this time, the switch unit (not shown) may connect between the first upstream end n1 of the first LED unit 50 and the second upstream end n1 of the second LED unit 52. Since the switch unit receives the control voltage Vcon having the Low value and forms a current path between the first upstream end and the second upstream end, the first LED unit 50 and the second LED unit 52 are connected in parallel .

When the control voltage Vcon having the high value is input to the first driving unit 51, the first driving unit 51 is in the OFF state do. At this time, the switch unit (not shown) may connect between the first upstream end n1 of the first LED unit 50 and the second upstream end n1 of the second LED unit 52. The switch unit receives the control voltage Vcon having a high value and cuts off the current path between the first upstream end n1 and the second upstream end n1, And the unit 52 has a configuration that is connected in series.

5A and 5B, the light emitting groups CH1 to CH2 can be converted into a serial connection state and a parallel connection state. The reconfiguration of the connection state is performed by turning on / off states of the distribution switch CS1 and the bypass switch BS1 . &Lt; / RTI &gt; The ON / OFF state of the distribution switch CS1 and the bypass switch BS1 can be automatically adjusted according to the magnitude of the input voltage Vi.

5A and 5B, the bypass switch BS1 and the power distribution switch CS1 may be transistors. Examples of the transistor include, but are not limited to, a bipolar transistor (BT), a field effect transistor (FET), and an insulated gate bipolar transistor (IGBT).

When the bypass switch BS1 operates in the non-saturation region, the magnitude of the current Ip1 flowing through the bypass switch BS1 can be determined by the ratio of the bias voltage Vp1 to the value of the resistor R1. That is, one current source can be provided by the bypass switch BS1, the current Ip1, and the bias voltage Vp1. Alternatively, when the bypass switch BS1 operates in the saturation region, the bypass switch BS1 may exhibit a resistance-like property.

Further, when the power distribution switch CS1 operates in the non-saturation region, the magnitude of the current I1 flowing through the power distribution switch CS1 can be determined by the ratio of the values of the bias voltage V1 and the resistance RS have. That is, one current source can be provided by the distribution switch CS1, the current I1, and the bias voltage V1. Alternatively, when the power distribution switch CS1 operates in the saturation region, the power distribution switch CS1 may exhibit a resistance-like property.

FIG. 5C shows the voltage and current characteristics of each node and element of the LED lighting circuit 5 shown in FIGS. 5A and 5B with respect to time.

For convenience of explanation, it is assumed that the forward voltages of the light emitting groups CH1 to CH2 are all Vf. It is assumed that the maximum current values designed to flow through the bypass switch BS1, the distribution switch CS1 and the distribution switch CS2 are designed as I _BS1 , I _CS1 and I _CS2 , respectively. When the input voltage Vn1 is between 0 Vf, no current flows through the circuit. When the input voltage Vn1 is between Vf and 2 Vf, the bypass switch BS1 and the power distribution switch CS1 operate in the non-saturation region and operate as the current source, and the power distribution switch CS2 operates in the saturation region . At this time, a current of the magnitude of I _BS1 can flow through the bypass switch BS1 and the power distribution switch CS2. At this time, the magnitude of the current flowing through the power distribution switch _CS1 may be a value obtained by subtracting I _BS1, which is the value of the current flowing through the power distribution switch CS2 from I _CS1 . The current ID1 flowing through the light emitting group CH1 is equal to the current value I _CS1- I _BS1 flowing through the distribution switch CS1 and the current ID2 flowing through the light emitting group CH2 is distributed Is equal to the value of the current I _BS1 flowing through the switch CS2. At this time, since the input voltage is not sufficiently high, no current flows through the diode D1.

When the input voltage Vn1 is 2 Vf or more, a current can flow through the diode D1. At this time, an additional current flows through the diode D1 to the resistor R1, and the bypass switch BS1 is turned off. Then, the power distribution switch CS2 is operated in the non-saturation region, and the power distribution switch CS1 can be turned off. At this time, ICS2-sized current can flow through the distribution switch CS2. And the current ID1 flowing through the light emitting group CH1 light emitting group CH2 is equal to the current value I _CS2 flowing through the power distribution switch CS2.

That is, when the power source is operated by a commercial power source having the first voltage (ex: 120V) and the input voltage at this time is between Vf and 2Vf, the light emitting groups CH1 and CH2 of the first LED unit 50, The light emitting groups CH1 and CH2 of the LED unit 52 are all in a parallel state, so that the four light emitting groups are simultaneously turned on. The light emitting groups CH1 and CH2 of the first LED unit 50 and the light emission of the second LED unit 52 of the second LED unit 52 are operated by a commercial power source having a second voltage ex (277V) The groups (CH1, CH2) are all in series.

<Fifth Embodiment>

The first LED unit 60 and the first drive unit 61 of FIG. 6A respectively show another embodiment of the internal structure of the first LED unit 11 and the first drive unit 16 of FIG. 1 in detail, The second LED portion 62 and the second driving portion 63 of FIG. 6B further illustrate another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG. 1, respectively.

6A shows an example of the first LED unit 60 and the first driving unit 61 of the LED lighting apparatus 5 according to the fifth embodiment of the present invention. 6B shows an example of the second LED portion 62 and the second driving portion 63 of the LED lighting device 5 according to the fifth embodiment of the present invention.

The LED units 60 and 62 and the driving units 61 and 63 shown in FIG. 6 are modified by extending the LED unit and the driving unit shown in FIGS. 5A and 5B.

A plurality of light emitting groups CH1 to CH5 are connected to the LED units 60 and 62 according to FIG. The light emitting groups CH1 to CH5 can be switched between the series and parallel states. This reconfiguration of the connection state can be achieved by adjusting the on / off states of the distribution switches CS1 to CS4 and the bypass switches BS1 to BS4. The ON / OFF states of the distribution switches CS1 to CS4 and the bypass switches BS1 to BS4 can be automatically adjusted according to the magnitude of the input voltage Vi.

7 shows on / off states of the switches included in the LED lighting circuit of FIG. 6 according to input voltages.

The graph 70 of FIG. 7 (a) shows the magnitude of the input voltage Vi over time. The input voltage may be in the form of a triangular wave as shown in FIG. 7 (a) or may be given in various forms such as a square wave and a saw tooth wave.

The magnitude of the input voltage Vi may be divided into a plurality of voltage periods LI0 to LI5. Each of the voltage periods LI0 to LI5 may correspond to a plurality of time periods P0 to P5. The length and position of the plurality of time points P0 to P5 on the time axis t may be determined by specific values of the forward voltages of the light emitting groups CH1 to CH5 shown in FIG.

In the time periods P0 to P5 shown in FIG. 7A, the LED circuit according to the fifth embodiment can operate in a steady state. However, it can operate in a transient state in which the state of the LED circuit is switched between the time periods P0 to P5. For convenience of explanation, the steady state will be mainly described in this specification.

Each row in FIG. 7 (b) represents time points P0 to P5, and each column corresponds to a time interval P0 (P0) of each of the switches BS1 to BS4 and CS1 to CS5 shown in FIG. To P5 in FIG. This change in the on / off state can be automatically performed by the LED lighting circuit 5 shown in Fig.

Hereinafter, the operation principle of the LED illumination circuit 5 according to Fig. 5 will be described with reference to Figs. 7, 8, and 9. Fig.

The first LED unit 80 and the first drive unit 81 of FIGS. 8A to 8J respectively show another embodiment of the internal structure of the first LED unit 11 and the first drive unit 16 of FIG. 1 in more detail And the second LED portion 82 and the second driving portion 83 respectively show another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG.

The first LED 101 and the first driving unit 102 of FIGS. 9A through 9J respectively show another embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. And the second LED portion 103 and the second driving portion 104 respectively show another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG.

8A to 8E show equivalent circuit structures of the first LED unit 80 and the first driver 81 in the time domain (P1 to P5), respectively. Figs. 8F to 8J show equivalent circuit structures of the second LED portion 82 and the second driver 83 in the time periods P1 to P5, respectively. At this time, the pair of the first LED unit 80 and the first driving unit 81 are paired with the pair of the second LED unit 82 and the second driving unit 83 to form one LED lighting circuit.

8A and 8F show the configuration of the LED illumination circuit 5 at the time point P0 as well as the time interval P1.

In the time period P0, since the magnitude of the input voltage Vi is not sufficiently large, none of the light emitting groups CH1 to CH5 may be turned on.

Since the bypass switches BS1 to BS4 and the power distribution switches CS1 to CS5 are all turned on in the time zone P1, the circuits shown in Figs. 6A and 6B have the circuit structures shown in Figs. 8A and 8F, respectively do. At this time, the turn-off switch BS1 and the power distribution switch CS1 in the turned-on switch operate in the non-saturation region and can serve as a current source. And the remaining switches of the turned on switch may operate in the saturation region. At this time, since the voltages of the anodes of the backflow prevention diodes D1, D2, D3 and D4 are higher than the voltages of the cathodes, both ends of these diodes can be regarded as open. Therefore, the circuits shown in Figs. 8A and 8F can be represented by equivalent circuits as shown in Figs. 9A and 9F, respectively.

In the time zone P2, since both of the bypass switches BS2 to BS4 and the distribution switches CS2 to CS5 are turned on and the bypass switch BS1 and the distribution switch CS1 are all turned off, The circuit has the structure of the circuit as shown in Figs. 8B and 8G, respectively. At this time, the turn-off switch BS2 and the power distribution switch CS2 among the turned-on switches operate in the non-saturation region and can serve as a current source. And the remaining switches of the turned on switch may operate in the saturation region. At this time, since the voltages of the anodes of the backflow prevention diodes D2, D3 and D4 are higher than the voltages of the cathodes, both ends of these diodes can be regarded as open. Therefore, the circuits shown in Figs. 8B and 8G can be represented by the equivalent circuits shown in Figs. 9B and 9G, respectively.

In the time zone P3, since the bypass switches BS3 to BS4 and the power distribution switches CS3 to CS5 are all turned on and the bypass switches BS1 to BS2 and the power distribution switches CS1 to CS2 are all turned off, The circuit shown in Fig. 6B has the structure of the circuit as shown in Figs. 8C and 8H, respectively. At this time, the turn-off switch BS3 and the power distribution switch CS3 among the turned-on switches operate in the non-saturation region and can serve as a current source. And the remaining switches of the turned on switch may operate in the saturation region. At this time, both ends of these diodes can be regarded as open because the voltage of the anode of the reverse current prevention diodes D3 and D4 is higher than the voltage of the cathode. Therefore, the circuits shown in Figs. 8C and 8H can be represented by the equivalent circuits shown in Figs. 9C and 9H, respectively.

In the time zone P4, since the bypass switch BS4 and the power distribution switches CS4 to CS5 are all turned on and the bypass switches BS1 to BS3 and the power distribution switches CS1 to CS3 are all turned off, The circuits shown in Figs. 8A and 8B have the structures of the circuits shown in Figs. 8D and 8I, respectively. At this time, the turn-off switch BS4 and the power distribution switch CS4 among the turned-on switches operate in the non-saturation region and can serve as a current source. And the remaining switches of the turned on switch may operate in the saturation region. At this time, since the voltage of the anode of the reverse current prevention diode D4 is higher than the voltage of the cathode, both ends of these diodes can be regarded as open. Therefore, the circuits shown in Figs. 8D and 8I can be represented by the equivalent circuits shown in Figs. 9D and 9I, respectively.

Since the power distribution switch CS5 is turned on and the bypass switches BS1 to BS4 and the power distribution switches CS1 to CS4 are all turned off in the time zone P5, the circuits shown in Figs. 6A and 6B are shown in Figs. 8j. &Lt; / RTI &gt; At this time, the distribution switch CS5 operates in the non-saturation region and can serve as a current source. The circuits shown in Figs. 8E and 8J can be represented by the equivalent circuits shown in Figs. 9E and 9J, respectively.

As described above, Figures 9A-9J can be understood to represent approximated equivalent circuits of the circuit according to Figures 8A-8J, respectively.

9, it can be understood that the circuit structure of the LED lighting circuit 5 shown in Fig. 6 is changed in accordance with the magnitude of the input voltage Vi.

In FIGS. 9A and 9F showing the configuration in the time domain P1, the light emitting groups CH1 to CH5 are connected in parallel to each other.

Light emitting groups CH2 to CH5 are connected in parallel to each other in Fig. 9B and Fig. 9G, which represent the time period P2, and the light emitting group CH1 is connected in series with the light emitting groups CH2 to CH5.

The light emitting groups CH3 to CH5 are connected in parallel to each other in FIGS. 9C and 9H, and the light emitting groups CH1 to CH2 are connected in series with the light emitting groups CH3 to CH5.

The light emitting groups CH4 to CH5 are connected in parallel to each other in Fig. 9D and Fig. 9I, which represent the time period P4, and the light emitting groups CH1 to CH3 are connected in series with the light emitting groups CH4 to CH5.

The light emitting groups CH1 to CH5 are connected in series to each other in Fig. 9E and Fig. 9J in the time domain P5.

It is confirmed that both the first LED unit and the light emitting groups CH1 to CH5 of the second LED unit are turned on when a voltage Vi is applied to the light emitting group CH1 in each time period.

At this time, in the case of operating with the commercial power source having the first voltage (ex: 120V), since the control voltage Vcon having the Low value is input to the first driving unit 81, the first driving unit is turned on , And a switch unit (not shown) forms a current path between a first upstream end of the first LED unit 80 and a second upstream end of the second LED unit 82, so that the first LED unit and the second LED unit are connected in parallel And have a connected configuration.

The first driving unit is turned off because the control voltage Vcon having the high value is input to the first driving unit 81. In the case where the first driving unit 81 is operated by the commercial power source having the second voltage ex, (Not shown) cuts off the current path between the first upstream end n1 of the first LED unit 80 and the second upstream end n1 of the second LED unit 82 and the first LED unit 50 and the second LED unit 52 are connected in series.

Therefore, when a voltage Vi is applied to the extent that the light emitting group CH1 is turned on, the light emitting groups of the first LED unit and the second LED unit are operated simultaneously when the first voltage ex (120V) And the light emitting group of the first LED unit and the light emitting group of the second LED unit are operated in the order of the voltage (ex: 277V).

In the circuit of Fig. 9, the sum of currents input and output to the LED illumination circuit in the time periods P1 to P5 can be defined as Itt1, Itt2, Itt3, Itt4, Itt5, respectively. At this time, it can be designed to satisfy the relationship of Itt5> Itt4> Itt3> Itt2> Itt1. In this design, the power factor of the LED lighting circuit can be improved because the total current supplied also increases as the input voltage Vi increases.

<Sixth Embodiment>

Hereinafter, a sixth embodiment of the present invention, which is designed to satisfy the relationship of Itt5> Itt4> Itt3> Itt2> Itt1, will be described below with reference to FIG.

Figure 9a and the distribution switch (CS1) in Fig. 9f is operative in a non-saturation region, I1 + I2 + I3 + the value of I4 + I5 distribution switch (CS1) is the maximum current that can be passed through same and I _CS 1 The value of I1 is adjusted. At this time, the ratio between the sum of I1 and I2 + I3 + I4 + I5 can be determined by the maximum current value I _BS1 provided when the bypass switch BS1 operates as a current source. Therefore, Itt1 = I _CS1 is established.

9B and 9G, the power distribution switch CS2 operates in the non-saturation region, and the value of I2 + I3 + I4 + I5 is equal to the maximum current value I _CS2 that the power distribution switch CS2 can pass through , The value of I2 is adjusted. At this time, the ratio between the sum of I2 and I3 + I4 + I5 may be determined by the maximum current value I _BS2 provided when the bypass switch BS2 operates as a current source. Therefore, Itt2 = I _CS2 is established.

9C and 9H, the power distribution switch CS3 is operated in the non-saturation region, and the value of I3 + I4 + I5 is equal to I _CS3 , which is the maximum current value that the power distribution switch CS3 can pass, Is adjusted. At this time, the ratio between the sum of I3 and I4 + I5 can be determined by the maximum current value I _BS3 provided when the bypass switch BS3 operates as a current source. Therefore, Itt3 = I _CS3 is established.

9D and 9I, the power distribution switch CS4 operates in the non-saturation region, and the value of I4 + I5 is set to a value equal to I _CS4 , which is the maximum current value that the power distribution switch CS4 can pass, . At this time, the ratio between I4 and I5 can be determined by the maximum current value I _BS4 provided when the bypass switch BS4 operates as a current source. Therefore, Itt4 = I _CS4 is established.

In Figs. 9E and 9J, the distribution switch CS5 operates in the non-saturation region. Therefore, Itt5 = I _CS5 is established.

In order to maximize the relative brightness among the light emitting groups CH1 to CH5 at a specific moment, the maximum value of the current that can be provided when the switches CS1 to CS5 and BS1 to BS4 operate as a current source is designed to be optimized .

<Seventh Embodiment>

10A is a view for explaining a structure of a light emitting device according to a seventh embodiment of the present invention.

10B shows a power supply unit 10, a light emitting group 220, a first bypass unit 230, a second bypass unit 240, and a light emitting device 901 shown in FIG. 10A. In addition, specific embodiments of the light emitting group 220, the first bypass unit 230, and the second bypass unit 240 are shown together.

The first LED portion 121 and the first driving portion 122 of the light emitting device 200 according to the embodiment of FIG. 10A are similar to the first LED portion 11 and the first driving portion 16 of FIG. 1, Other embodiments are shown in more detail.

The light emitting device 200 may include a power supply unit 10 for supplying a power source capable of varying the potential and a plurality of light emitting groups 220.

Each of the light emitting groups 220 includes at least one light emitting device 901 and is electrically connected to each other in order from upstream to downstream in order to receive power from the power supply unit 10. Here, the 'upstream direction' means closer to the current output terminal of the power supply unit 10, and the 'downstream direction' means that it is disposed further from the current output terminal of the power supply unit 10.

The light emitting device 200 includes a first light emitting group 220 and a second light emitting group 222 which are disposed at an upstream end of the first light emitting group 220 and the second light emitting group 220, And a first bypass unit 230 for electrically connecting the upstream end of the first bypass unit 230 to the first bypass unit 230 so as to be intermittently interrupted. The term "upstream end" refers to a terminal closer to the power supply unit 10 (i.e., a current input terminal) among the terminals provided in the light emitting group, and the term "downstream end" refers to a terminal May refer to a remote terminal (i.e., a current outlet terminal). Here, 'intermittently enabled' means that a current flow channel can be formed or blocked between the both terminals provided by the first bypass unit 230.

The light emitting device 200 may include a plurality of light emitting units 220 and 222 and a plurality of second light emitting groups 220 and 222. The light emitting unit 200 may include a plurality of light emitting units 220 and 222, And a second bypass unit 240 for electrically connecting the downstream ends of the third light emitting groups 220 and 223 to enable intermittent control. Here, 'intermittently enabled' means that a current flow channel can be formed or blocked between both terminals provided by the second bypass unit 240.

These implementations can be applied to the LED illumination circuit of Fig. At this time, the circuits between the terminals T1 and T2 provided by the first bypass unit 230 can be interrupted by the bypass switch 903 (BS). A third terminal T3 may be selectively provided to the first bypass unit 230 according to the embodiment. The circuit between the both terminals T1 and T2 provided by the second bypass unit 240 can be interrupted by the power distribution switch 902 (CS).

In various embodiments herein, the power supply 10 may be referred to as a &quot; rectifier &quot; or a &quot; power supply &quot;.

And the light emitting group 220 may be referred to as a 'light emitting channel' or a 'LED light emitting group'.

The first bypass unit 230 may be referred to as a 'jump circuit unit', a 'bypass circuit', or a 'first circuit unit'.

The second bypass unit 240 may be referred to as a 'distribution circuit unit' or a 'second circuit unit'.

The light emitting device 901 may be referred to as an 'LED cell', an 'LED device', or an 'emitter'.

And the bypass switch 903 may be referred to as a &quot; jump switch. &Quot;

&Lt; Eighth Embodiment >

11 is a view for explaining a structure of an LED lighting apparatus 300 according to an eighth embodiment of the present invention. The first LED unit 131 and the first driving unit 132 of the LED lighting apparatus 300 according to the embodiment of FIG. 11 are similar to those of the first LED unit 11 and the first driving unit 16 of FIG. 1, Another embodiment is shown in more detail.

The LED lighting apparatus 300 can receive operating power from the AC power source 301. [

The LED lighting device 300 includes at least one LED cell 901 and may include N light-emitting channels 220 connected in a linear fashion (where N is a natural number of 2 or more).

The LED lighting device 300 may include a rectifying unit 10 that is electrically connected to the start end of the light emitting channels 220 and rectifies the AC power source 301 to supply power to the last end of the light emitting channels 220 have. Here, the starting end means the light emitting channel closest to the current output terminal of the rectifying unit 10 among the light emitting channels 220, and the last end means the light emitting channel arranged farthest.

The LED lighting apparatus 300 includes a plurality of distribution circuit units (not shown) including a distribution switch 902 branched from each connection between the light-emitting channels 220 and connected to the ground, 240).

The LED lighting device 300 is connected to the input terminals of the (M + 1) -th light emitting channels 220 and 212, branched from the input terminals of the Mth light emitting channels 220 and 211 among the light emitting channels 220, (Where M is a natural number equal to or larger than 1 and equal to or smaller than N-1) including a jump switch 903 for interrupting a current flowing on the switch circuit 903.

The LED illumination device 300 is disposed between the connection part between the Mth light emitting channel 220 and the Mth light emitting channel 220 and the Mth light emitting channel 220, And a reverse current blocking unit 904 disposed on the circuit to prevent a current flowing to the input terminal of the (M + 1) -th light emitting channel 220 or 212 through the jump circuit unit 230 from flowing toward the rectifying unit 10 can do.

11 shows an embodiment of the backflow prevention portion 904. The backflow prevention portion 904 may be implemented by a diode D or a transistor. An example of the transistor is as described above. This embodiment is applied to the LED portions 60 and 62 shown in Fig. The backflow prevention unit 904 may be implemented by a transistor other than the diode D, and in this case, the on / off state of the transistor can be controlled according to the time periods P0 to P5 shown in FIG.

The jump circuit unit 230, the light emitting channel 220, and the power distribution circuit unit 240 shown in FIG. 11 are implemented with the same structure as that of the first bypass unit, the light emitting group, and the second bypass unit shown in FIG. 10A It is possible.

&Lt; Example 9 &

12 is a view for explaining a structure of an LED lighting apparatus 400 according to a ninth embodiment of the present invention. The first LED portion 133 and the first driving portion 134 of the LED lighting device 400 according to the embodiment of FIG. 12 are similar to those of the first LED portion 11 and the first driving portion 16 of FIG. 1, Another embodiment is shown in more detail.

The LED lighting apparatus 400 may have a structure in which a plurality of LED light emitting groups 220 having at least one LED element 901 are sequentially connected.

The LED lighting device 400 may include a power supply 10 for applying AC power to the LED light emitting groups 220 and 203 on one end of the LED light emitting group 220. [

The LED lighting device 400 may include a detour line 230 connecting an input terminal and an output terminal of the first LED light emitting groups 220 and 204, which are at least any one of the LED light emitting groups 220.

The LED illumination device 400 is disposed on the detour line 230 so that the potential of the power source supplied by the power supply 10 is lower than the potential of the next LED emission groups 220 and 205 of the first LED emission groups 220 and 204 Off switch 903 that closes the bypass line 230 when the potential of the bypass line 230 is not greater than the potential capable of turning on.

The bypass circuit 230, the LED light emitting group 220, and the power distribution circuit portion 240 shown in FIG. 12 are implemented with the same structure as that of the first bypass portion, the light emitting group, and the second bypass portion shown in FIG. . The backflow prevention portion 904 is disposed between the current output terminal of the detour line 230 and the current output terminal of the first LED light emitting group 220 and 204, May be prevented from flowing into the first LED light emitting groups 220 and 204. [

<Tenth Embodiment>

13 is a view for explaining a structure of an LED lighting apparatus 500 according to a tenth embodiment of the present invention. The first LED portion 135 and the first driving portion 136 of the LED lighting apparatus 500 according to the embodiment of FIG. 13 are similar to those of the first LED portion 11 and the first driving portion 16 of FIG. 1, Another embodiment is shown in more detail.

The LED lighting apparatus 500 can receive driving power from the AC power source 10.

The LED lighting device 500 may include a plurality of light emitting groups 220. At this time, each of the light emitting groups 220 includes at least one LED element 901, and may be electrically connected in a linear manner so as to have an order from the most upstream to the most downstream. Here, 'most upstream' indicates the position closest to the current output terminal of the power supply unit 10, and 'most downstream' indicates the farthest position.

The LED lighting apparatus 500 may include a first circuit unit 230 for bypassing a connection point between the light emitting groups 220.

The LED lighting apparatus 500 may be configured such that the AC power is first applied to the light emitting group on the downstream side of the light emitting group on the relatively upstream side among the light emitting groups 220 while the potential of the supplied AC power supply 10 rises And a second circuit unit 240 connecting the connection point and the ground.

At this time, between the current output terminal of any of the light emitting groups 220 and the current output terminal of the first circuit unit 230 which is configured to bypass the current that can flow in the arbitrary light emitting group 220, May be deployed. At this time, the current output from the current output terminal of the first circuit unit 230 can not pass through the backflow prevention unit.

&Lt; Eleventh Embodiment >

14 is a view for explaining an embodiment of a light emitting unit constituting an LED driving apparatus according to an eleventh embodiment of the present invention.

14 (a) is a block diagram of a light emitting unit 2 according to an eleventh embodiment of the present invention. The light emitting unit 2 may have three input / output terminals: a current input terminal TI, a current output terminal TO1, and a current bypass output terminal TO2.

The light emitting unit 2 may include a first bypass unit 230, a light emitting group 220, and a second bypass unit 240. The light emitting unit 2 may selectively include the backflow prevention portion 904. [

Both terminals of the second bypass unit 240 are connected when the switch in the first bypass unit 230 is on, that is, when a current flows between the terminals T1 and T2 (that is, 2 current flows through the bypass portion). That is, when the first bypass unit 230 is in the on-state, a current flows through the bypass path provided by the first bypass unit 230, and a current also flows through the second bypass unit 240.

When the switch in the first bypass unit 230 is off, that is, when no current flows between the terminal T1 and the terminal T2, both terminals of the second bypass unit 240 are also opened (That is, no current flows through the second bypass section). That is, when the first bypass unit 230 is in an off state, not only current does not flow through the bypass path provided by the first bypass unit 230 but also current flows through the second bypass unit 240 No current flows.

Accordingly, when the switch in the first bypass unit 230 is in the ON state, a part of the current input through the current input terminal TI is input to the light emitting group 220, and the other part is input to the first bypass unit 230 May be bypassed to the bypass path provided by the bypass path. At least a part or all of the current output from the output terminal of the light emitting group 220 is bypassed through the second bypass unit 240 without being output to the current output terminal TO1, ). &Lt; / RTI &gt; The current passing through the bypass path provided by the switch in the first bypass unit 230 may be output to the current output terminal TO1.

In contrast, when the switch in the first bypass unit 230 is in the off state, all the current input through the current input terminal TI is input to the light emitting group 220. And all of the current output from the output terminal of the light emitting group 220 can be output to the current output terminal TO1.

A resistor may be connected to the current bypass output terminal TO2. The resistor may be, for example, the resistance Rs1 of Fig. 6A or the equivalent resistance of the resistor Rs2 and the resistor Rs3 of Fig. 6B. The value of the current flowing through the power distribution switch CS can be determined by the value of the resistance and the value of the voltage V input to the power distribution switch CS in Fig. 9B.

14 (b) shows an embodiment of the light-emitting unit 2 shown in Fig. 14 (a). An embodiment of the light emitting unit 2 according to Fig. 14 (b) can be applied to the LED lighting circuit 5 of Fig. On / off of the switch element (bypass switch) BS in FIG. 14 (b) is determined by the bias voltage Vp, the sensing resistance R, the current It flowing through the sensing resistor R, (N4) based on the relative potential Vth of the node n4. That is, the bias voltage Vp is on / off of the switch element BS depending on whether the bias voltage Vp is smaller or larger than a value obtained by adding the relative potential Vth to a value obtained by multiplying the current It by the resistance R, Off can be determined. In other words, the on / off state of the switching element BS can be controlled by interlocking with the voltage of the current output terminal TO1.

FIG. 14C shows an LED illumination circuit 600 according to an eleventh embodiment of the present invention, which is completed by connecting the light-emitting units 2 shown in FIG. 14A.

The LED lighting circuit 600 includes one or more light emitting units 2 including a light emitting group 220, a current input terminal TI, a current output terminal TO1, and a current bypass output terminal TO2 can do.

At this time, the current output terminal TO1 can selectively output all the currents or some currents of the currents input through the current input terminal TI. The current bypass output terminal TO2 outputs the remaining current except for the part of the currents when the current output terminal TO1 outputs only the part of the current. At this time, the remaining current may be a current flowing through the light emitting group.

A different light emitting group 220 may be connected to the current output terminal TO1 of the light emitting unit 2. At this time, the other light emitting group 220 may or may not be included in another light emitting unit.

The current bypass output terminal TO2 of the light emitting unit 2 may be connected to the current output terminal of the other light emitting group 220. [ At this time, the other light emitting group 220 may or may not be included in another light emitting unit.

<Twelfth Embodiment>

The first LED unit 150 and the first driving unit 151 of FIG. 15A respectively show still another embodiment of the internal structure of the first LED unit 11 and the first driving unit 16 of FIG. 1, The second LED portion 152 and the second driving portion 153 of FIG. 15B further illustrate another embodiment of the internal structure of the second LED portion 12 and the second driving portion 17 of FIG. 1, respectively.

Figs. 15A and 15B are circuits modified from the fifth embodiment according to Figs. 6A and 6B. In FIGS. 6A and 6B, five light emitting groups CH1 to CH5 are connected to one LED unit. In FIGS. 15A and 15B, four light emitting groups CH1 to CH4 are connected to one LED unit . Although capacitors are not connected in parallel to the respective light emitting groups CH1 to CH5 in FIGS. 6A and 6B, the capacitors C1 to C4 are connected in parallel to the light emitting groups CH1 to CH4 in FIGS. 15A and 15B It is different in that it is connected.

According to the same principle as described in the third embodiment, in a time period in which AC power can not be directly transmitted to each of the light emitting groups CH1 to CH4 in Figs. 15A and 15B, each of the capacitors C1 to C4 is self- The currents larger than 0 may always flow in each of the light emitting groups CH1 to CH4 if the capacitors C1 to C4 have a sufficient capacity because the energy stored in the light emitting groups CH1 to CH4 is supplied to the respective light emitting groups CH1 to CH4 Points can be easily understood.

The capacitors may be connected in parallel to both terminals T1 and T2 of the light emitting group 220 shown in Fig. 14A in the same manner as in the twelfth embodiment described above. A capacitor may be connected in parallel between the current input terminal and the current output terminal of the light emitting group CH shown in FIG. 14 (b).

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 essential characteristics thereof. The contents of each claim in the claims may be combined with other claims without departing from the scope of the claims.

Claims (4)

A first light emitting portion;
A backflow preventing part connected in series to a downstream end of the first light emitting part;
A resistor connected in series to a downstream end of the backflow prevention portion;
A second light emitting portion connected in series to a downstream end of the resistor; And
A first terminal connected to an upstream end of the first light emitting portion, a second terminal connected to an upper end of the resistor, and a third terminal connected to a bias voltage connected to a downstream end of the resistor, And a transistor for turning on / off a current path between the first terminal and the second terminal in accordance with a peak value.
Lighting device.
The method according to claim 1,
When the peak value of the input power source has a first peak value,
In the backflow prevention portion,
Current does not flow,
In the resistor,
A current is prevented from flowing from the backflow prevention portion,
Lighting device.
The method according to claim 1,
When the peak value of the input power source has a second peak value,
In the backflow prevention portion,
Current flows,
In the resistor,
And an electric potential difference is generated between the second terminal and the third terminal,
Lighting device.
The method according to claim 1,
The transistor comprising:
The first terminal and the second terminal are turned off by a potential difference generated at both ends of the resistor to turn off a current path between the first terminal and the second terminal or to be turned on by a potential difference that is lost at both ends of the resistor, Terminal, and the second terminal,
Lighting device.

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