KR20130108034A - Driving circuit for led lamp - Google Patents

Abstract

PURPOSE: A light emitting diode (LED) driving circuit is provided not to separate a substrate of a high-voltage field effect transistor through an additional layer, thereby minimizing the size of the high-voltage field effect transistor. CONSTITUTION: A power unit (110) includes a power input terminal and a rectifier circuit of AC power inputted through the power input terminal. An LED lamp unit (120) is formed with a plurality of LEDs. A switching circuit unit (130) is connected to an output end of each LED. A reference voltage supply unit (140) applies a reference voltage for each switching circuit unit. Each reference voltage unit of the reference voltage supply unit is commonly grounded to a negative end of the rectifier circuit. A system ground unit is commonly grounded to each switching circuit unit. A bleeding switching circuit (180) forms a supply channel of a bleeding current. [Reference numerals] (110) AC power; (180) Circuit total earthing point& FET source point; (AA) Rectifier negative point

Description

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

The present invention relates to an LED driver circuit, and more particularly to an LED driver circuit which minimizes the size of a high-voltage field-effect transistor without separating a substrate of the high-voltage field-effect transistor through an additional layer, The function of the illumination device is related to the LED light driving circuit which can be implemented in the same manner as that of the existing AC direct type LED lighting device.

LED (Light Emitting Diode) is a current driving device, and can be operated normally if a constant current is supplied stably. In particular, LEDs requiring high power have a large driving current (typically, 350 mA or more), so that the LED itself generates a lot of heat, and therefore, the deterioration rate of brightness is larger than that of LEDs at low power. This is directly linked to the lifetime of the LED and is very important in the lighting market.

For the above reasons, the LED at high power is usually driven by a constant current, and PWM (Pulse Width Modulation) is used to more efficiently use the power of the SMPS used as a constant current power source.

However, due to the characteristics of the LEDs driven by the constant current, this method requires additional circuits and various electronic components constituting the corresponding circuit, leading to an increase in the manufacturing cost of the lighting device including the LED.

For this reason, a method of rectifying the AC power source and applying the rectified AC power to the LED module connected in series is used. The LED lighting device using this method is called an AC direct type LED lighting device.

FIG. 1 is a diagram showing an example of a conventional AC direct type LED lighting apparatus. The driving principle of the AC direct type LED lighting apparatus will be described as follows.

The power supply unit 10 composed of an AC power source and a rectifier converts the AC power source signal into a rectified and rectified signal and transmits it to the LED driver 20.

As the power supply voltage increases, current paths are formed in the order of IBL1, ILED1, ILED2, and ILED3, where the reference voltages V1, V2, V3, and V4 of each circuit forming the current path are defined as V1 &lt; V2 &lt; V3 &lt; When set in relation to V4, each current path operates to turn off the previous current path during its operation. On the contrary, if the voltage decreases from the maximum value, all the current paths can be operated, but only the last current path among the current paths that can be operated due to the setting of V1 <V2 <V3 <V4, A current path is formed in the order of ILED2, ILED1, and IBL1.

That is, in one cycle of the AC direct LED lighting device, LED driving currents are converted in the order of IBL1 → ILED1 → ILED2 → ILED3 → ILED2 → ILED1 → IBL1. At this time, IBL1 = V1 / RISEN, ILED1 = V2 / RISEN, ILED2 = V3 / RISEN, ILED3 = V4 / RISEN.

FIG. 2 is a more detailed view of the circuit of FIG. 1, wherein FIG. 2 illustrates a state in which a substrate of a high voltage FET is connected to the ground of the entire circuit.

In other words, in a general circuit configuration, the ground circuit is formed at the point of the lowest voltage potential value of the whole circuit system, and thus, in this circuit system, the negative terminal, which is a valuable current path of the full- As shown in FIG.

This results in a voltage difference between the source points of the internal high voltage FET connected to the resistor RISEN and the substrate point of the internal high voltage FET do. Here, the voltage applied between the source point of the high voltage FET and the substrate is the voltage value V _RISEN between the resistor RISEN and the ground.

Here, the voltage applied to the source of the resistor RISEN, that is, the high voltage FET, can be from a few tens of volts to a maximum of several volts, while the substrate always has a minimum voltage So that an operation known as a body effect of a field effect transistor (FET) usually occurs. The body effect increases the threshold voltage of the field effect transistor (FET) by the voltage value applied between the substrate and the source terminal of the field effect transistor (FET), thereby causing the current drive of the field effect transistor Capacity and so on.

Therefore, unless the maximum voltage value applied to the resistor RISEN is designed to be sufficiently low, the maximum possible current value of the entire LED driving system is reduced, or a high voltage FET ) Need to be designed more than necessary.

Korean Patent No. 10-01132194 &quot; Light emitting device and LED driving method using the same &quot; Korean Patent No. 10-01110380 &quot; AC drive LED illumination device &quot;

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to minimize the size of a high voltage field effect transistor without taking a method of separating a substrate of a high voltage field effect transistor through an additional layer, The LED lighting device according to the present invention can be realized in the same manner as the function of the existing direct current type LED lighting device.

In addition, since the present invention does not adopt a method of separating the substrate of the high voltage field effect transistor through an additional layer, it is possible to reduce the size of the high voltage field effect transistor, And to provide a driving circuit.

According to an aspect of the present invention, there is provided an LED driving circuit comprising: a power supply unit including a power input terminal to which an external AC power is applied and a rectification circuit of an AC power input through the power input terminal; And an n-th LED located at a longest distance from a power supply unit, the first LED being connected to the power supply unit and each LED being connected in series, A plurality of switching circuit units individually connected to output terminals of the LEDs forming the illumination unit to form current supply channels for the LEDs; a reference voltage supply unit for applying a reference voltage to each of the switching circuit units; A reference voltage grounding portion in which a voltage portion is commonly grounded to a negative end of the rectifying circuit, The robu each is configured to include the grounding system common ground.

The power supply unit may further include a dimmer connected to the power input terminal to receive an AC voltage and to apply an output voltage to the rectifying circuit.

The apparatus may further include a first resistor connected between the reference voltage ground and the system ground.

The switching circuit includes a switching element connected to an output terminal of the LED and connected to the system grounding part and a comparator for comparing a reference voltage of the reference voltage part and a voltage input from the ground terminal of the system grounding part .

The apparatus may further include a bleeding switching circuit connected in parallel to a connection line between the power source and a power input terminal of the first LED to form a bleeding current supply channel, And the bleeding reference voltage portion is also commonly grounded to the negative terminal of the rectifying circuit.

The bleeding switching circuit may include a switching element connected to the output terminal of the rectifying circuit and connected to the system grounding part and a comparator for comparing a reference voltage of the bleeding reference voltage part and a voltage input from the ground terminal of the system grounding part .

The switching elements of the switching circuit section and the switching elements of the bleeding switching circuit may be respectively connected to the output terminal of the rectifying circuit or the output terminal of the LED and to the source of the system grounding section, And is an effect transistor (MOS FET).

In addition, either or both of the switching circuit section and the bleeding switching circuit are characterized in that the comparator and the field effect transistor (MOS FET) form a negative feedback circuit.

The voltage of the negative terminal of the rectifying circuit and the voltage of the reference voltage ground have the same voltage value. The voltage of the system ground, the substrate voltage of the field effect transistor, and the source output voltage Are characterized by having the same voltage value.

The system grounding part may include a common grounding resistor to which the switching circuitry is commonly grounded, and the reference voltage grounding part may include a second resistor for grounding the bleeding reference voltage of the bleeding switching circuit. .

The switching element of the switching circuit part may be switched to either the first current path connected to the LED and the second current path connected to the common ground resistance in accordance with the comparator output of the switching circuit part, And the common voltage is varied.

According to another aspect of the present invention, there is provided an LED driving circuit comprising: a power supply unit including a power input terminal to which an external AC power is applied and a rectifying circuit of an AC power input through the power input terminal; An LED lighting unit including an n-th LED located at a longest distance from a power supply unit starting from a first LED, the first LED being connected to the power supply unit and each LED being connected in series; A first switching circuit part including a bleeding switching circuit connected in parallel to the input line connection line to form a bleeding current supply channel and a first LED switching circuit connected to an output terminal of the first LED to form a current supply channel, A second LED switching circuit to an n-th LED switching circuit which are individually connected to the output terminal of the n-th LED from the output terminal of the second LED, A second switching circuit part for each LED switching circuit forming an individual current supply channel for the corresponding LED; and a control circuit for applying a reference voltage to each of the bleeding switching circuit and the first LED switching circuit, A first reference voltage supply unit commonly grounded to a negative terminal of the rectifying circuit and a second reference voltage supply unit for applying a reference voltage to the second LED switching circuit and the nth LED switching circuit, A system grounding part in which each of the LED switching circuits of the second switching circuit part is commonly grounded; and a second grounding part that is connected in parallel to the negative terminal of the rectifying circuit, And a first common grounding resistor for making the common ground of the first LED switching circuit and the second common switching circuit And a second common ground resistor for providing a common ground of the LED switching circuit.

Further, the apparatus may further include a current operation control unit for controlling the on / off operation of the bleeding switching circuit and the LED switching circuit of the first switching circuit unit according to the on / off operation state of the LED switching circuit included in the second switching circuit unit .

According to the present invention, the size of a high-voltage field-effect transistor is minimized while a substrate of a high-voltage field-effect transistor is isolated through an additional layer, and the function of the LED lighting device including the high- And can be implemented in the same manner as the direct LED lighting device.

In addition, since the method of separating the substrate of the high voltage field effect transistor through the additional layer is not adopted, the reduction of the size of the high voltage field effect transistor is realized and thus the factor of the increase of the total circuit system is not caused.

1 is a view showing an example of a conventional direct current type LED lighting apparatus;
FIG. 2 is a detailed view of the conventional AC direct type LED lighting apparatus of FIG. 1
3 is a view showing an LED light driving circuit according to an embodiment of the present invention;
4 is a view showing an example of an embodiment of an LED light driving circuit according to FIG.
5 is a view showing an LED light driving circuit according to another embodiment of the present invention.
6 is a view showing an example of an embodiment of an LED lighting driver circuit according to Fig. 5
7 is a view showing an LED light driving circuit according to another embodiment of the present invention;
8 is a diagram showing an example of an embodiment of an LED lighting driver circuit according to Fig. 7

Hereinafter, an LED driver circuit according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a view illustrating an LED lighting circuit according to an exemplary embodiment of the present invention.

The LED lighting circuit 100 according to an exemplary embodiment of the present invention includes a power supply unit 110, an LED illumination unit 120, a switching circuit unit 130, a reference voltage supply unit 140, a reference voltage grounding unit 150, and a system ground unit 160. The LED driving circuit according to an exemplary embodiment of the present invention may further include a first resistor 170 and a bleeding switching circuit 180.

The power source unit 110 includes a power source input terminal (not shown) to which an external AC power source (AC power source, hereinafter referred to as an AC power source) is applied, and a rectifier circuit 111 of an AC power source input through the power source input terminal . The power supply unit 110 may further include a dimmer connected to the power input terminal to receive an AC voltage and to apply an output voltage to the rectifying circuit 111. Here, the dimmer can be selected from any one of the conventional dimmers, and therefore, a detailed description thereof will be omitted in the present embodiment.

 The LED illumination unit 120 includes a plurality of LEDs 121 to 123, that is, a first LED 121 located at a shortest distance from a connection point with the power source unit 110 and a first LED 121 And an n-th LED 123 located at a longest distance from the power supply unit 110. The first LED 121 is electrically connected to the power supply unit 110 and all the LEDs 121 to 123 included in the first and second illumination units 120 and 120 are connected to each other in series.

The switching circuit unit 130 is individually connected to the output terminals of the LEDs 121 to 123 forming the LED illumination unit 120. Each of the switching circuit units 130 forms a current supply channel for the LEDs 121 to 123 do.

The switching circuit unit 130 may include a switching device 131 and a comparator 132.

The switching elements 131 are individually connected to the output terminals of the LEDs 121 to 123 forming the LED illumination unit 120 and are commonly connected to the system grounding unit 160. In this embodiment, it is assumed that the switching element 131 is a field effect transistor (MOS FET), particularly a high voltage field effect transistor (MOS FET). In this field effect transistor, the drain is connected to one of the LEDs 121 to 123, The source is connected to the system ground, and the gate is connected to the comparator 132. In the example of FIG.

The comparator 132 compares the reference voltage of the reference voltage section and the voltage input from the ground terminal of the system ground section 160.

In addition, the switching circuit portion may be one in which the comparator and the field effect transistor (MOS FET) form an additional feedback circuit.

The reference voltage supply unit 140 applies a reference voltage to each of the switching circuit units 130.

The reference voltage ground unit 150 has a configuration in which the reference voltage units 141 to 143 of the reference voltage supply unit 140 are commonly grounded to the negative ends of the rectifier circuit 111.

The system grounding unit 160 is commonly grounded with each of the switching circuit units 130.

The first resistor 170 is connected between the reference voltage ground unit 150 and the system ground unit 160.

The bleeding switching circuit 180 is connected in parallel to the connection line between the power source 110 and the power input terminal of the first LED 121. The bleeding switching circuit 180 forms a supply channel for the bleeding current. The bleeding switching circuit 180 is connected to the system ground 160 together with the plurality of switching circuits 130 and the bleeding reference voltage 154 for applying the reference voltage to the bleeding switching circuit 180 is also connected to the rectifying circuit 111 are commonly grounded.

Such a bleeding switching circuit 180 may include a switching element 181 and a comparator 182. The switching element 181 is connected to the output terminal of the rectifying circuit 111 and is connected to the system grounding part 160. The comparator 182 compares the reference voltage of the bleeding reference voltage section 144 and the voltage input from the ground terminal of the system ground section 160.

Here, the switching element 181 of the bleeding switching circuit 180 has a drain connected to the output terminal of the rectifying circuit 111, a source connected to the system grounding part 160, and a gate connected to the comparator 182, Transistor (MOS FET). In particular, as in the case of the switching element 131 of the switching circuit part 130, a high-voltage field effect transistor (MOS FET) is used.

In the bleeding switching circuit 180, the comparator 181 and the field effect transistor (MOS FET) may form a negative feedback circuit.

The LED lighting driver circuit 100 according to the present embodiment can control the voltage value of the system ground 160 as the ground point of the entire circuit and the ground voltage of the substrate of the field effect transistors 131 and 181 The values are the same. Since the negative terminal of the rectifying circuit 111 is used as the common ground of the reference voltage portions 141 to 143 and the bleeding reference voltage portion 144 of the reference voltage supplying portion 140, The voltage of the negative stage and the voltage of the reference voltage grounding unit 150 indicate the same voltage value. The voltage value of the negative stage or the voltage value of the reference voltage grounding unit 150 may be the ground voltage of the substrate of the system grounding unit 160 or the field effect transistors 131 and 181 or the ground voltage of the field effect transistors 131 and 181 ) And the voltage value thereof are different from each other.

According to such a grounding structure, the LED lighting driver circuit 100 has a bias such that the substrate and the source of the field effect transistors 131 and 181 are directly connected to each other, and the body effect disappears. Further, the field effect transistors 131 and 181 for driving the same current can be formed with a minimum area, and a further layer for electrically separating the field effect transistors 131 and 181 is required in the LED light driving circuit 100 .

4 and furthermore, FIG. 4 is a diagram showing an embodiment of an EL illumination driving circuit according to FIG.

The power supply of the reference voltage supplier 140 for generating the reference voltages V1, V2, V3 and V4 of all the channels formed by the bleeding switching circuit 180 and the switching circuit 130 is the internal power supply VDD, The ground point is connected to the negative terminal of the rectifier circuit 111 while the power source of the entire circuit system is shared. The grounding of the comparators 132 and 182 constituting each channel is separated from the system grounding part 160 and not connected to the substrate of the field effect transistors 132 and 182, The same effect as that of the conventional AC direct type LED lighting apparatus described above with reference to Figs. 1 and 2 can be achieved.

Next, an LED light driving circuit according to another embodiment of the present invention will be described with reference to FIG. The LED driver circuit 200 according to the present embodiment has the same structure as the LED driver circuit 100 shown in FIG. 3 and the power source unit 110, the LED driver 120, and the switching circuit unit 130 And a detailed description thereof will be omitted, and the same reference numerals will be used, and it will be explained that the remaining components are mainly described with reference to FIG.

The system grounding unit 260 includes a common grounding resistor 261 to which the switching circuit unit 130 is commonly grounded and a reference voltage grounding unit 250 that is connected to the grounding terminal of the bleeding switching circuit 280 And a second resistor 251 for grounding the bleeding reference voltage portion 244.

The switching element 131 of the switching circuit unit 130, that is, the field effect transistor 131 is connected to the first current path connected to the LEDs 121 to 123 according to the output of the comparator 132 of the switching circuit unit 130, And the second current path connected to the grounding resistance 261 to change the common voltage of the common ground resistance 261. [

The LED driving circuit 200 of the present embodiment having the above-described structure is grounded so as to remove the body effect of the field effect transistor 281 located at the shortest distance from the power source 110. That is, the voltage V1 of the bleeding reference voltage portion 244 and the reference voltage portions 241 to 243 of the reference voltage supply portion 240 do not share the same common ground. The respective channels operate as IBL1 = V1 / RISEN2, ILED1 = V2 / RISEN1, ILED2 = V3 / RISEN1 and ILED3 = V3 / RISEN1, Can be minimized.

6 and FIG. 6, FIG. 6 is a diagram showing an embodiment of an EL illumination driving circuit according to FIG.

4, the internal power supply VDD is shared by the entire circuit system, while the grounding point of the voltage V1 of the bleeding reference voltage portion 244 of the bleeding switching circuit 280 and the grounding point of the switching circuit portion 130 The grounding points of the voltages V2, V3, and V4 of the reference voltage portions 241 to 243 are separated. Thus, the size of the field effect transistor of the bleeding switching circuit driving IBL1 can be minimized.

Next, an LED light driving circuit according to another embodiment of the present invention will be described with reference to FIG.

The LED lighting circuit 300 according to the present embodiment includes a power supply unit 310, an LED illumination unit 320, a first switching circuit unit 340, a second switching circuit unit 350, A second common voltage supply unit 370, a system ground unit 380, a first common ground resistance 391, and a second common ground resistance 392. The LED driver circuit 300 according to the present embodiment may further include a current operation controller 330.

The power source unit 310 includes a power source input terminal (not shown) to which an external AC power source (AC power source, hereinafter referred to as "AC power source") is applied and a rectifier circuit 311 of an AC power source input through the power source input terminal . The power supply unit 310 may further include a dimmer connected to the power input terminal to receive an AC voltage and to apply an output voltage to the rectifying circuit 311. Here, the dimmer can be selected from any one of the conventional dimmers, and therefore, a detailed description thereof will be omitted in the present embodiment.

 The LED illumination unit 320 includes a plurality of LEDs 321 to 323, that is, a first LED 321 located at a shortest distance from a connection point with the power supply unit 310 and a first LED 321 And an n-th LED 323 located at the longest distance from the power supply unit 310. [ The first LED 321 is electrically connected to the power supply unit 310 and all the LEDs 321 to 323 included in the first LED 321 and the illumination unit 320 are connected to each other in series.

The first switching circuit part 340 includes a bleeding switching circuit 341 and a first LED switching circuit 342. The bleeding switching circuit 341 is connected between the power input part of the power source part 310 and the first LED 321 And connected in parallel to the connection line to form a bleeding current supply channel. The first LED switching circuit 342 is connected to the output terminal of the first LED 321 to form a current supply channel.

The second switching circuit unit 350 includes a second LED switching circuit 351 to an nth LED switching circuit (a third switching circuit 353 in this embodiment) which are individually connected to the output terminal of the n-th LED from the output terminal of the second LED 322 And the second LED switching circuit 351 to the third LED switching circuit 352 included in the second switching circuit portion 350 form separate current supply channels for the LEDs 322 and 323.

The first reference voltage supply unit 360 applies a reference voltage to the bleeding switching circuit 341 and the first LED switching circuit 342 while each of the reference voltage units 361 and 362 applies a negative voltage to the rectifying circuit 311, And is commonly grounded.

The second reference voltage supply unit 370 applies the reference voltage to the second LED switching circuit 351 and the third LED switching circuit 352 and the reference voltage portions 371 and 372 are connected to the negative terminals Respectively.

The system grounding unit 380 is commonly grounded by the LED switching circuits 351 and 352 of the second switching circuit unit 350.

The first common grounding resistor 391 and the second common grounding resistor 392 are connected in parallel to the negative terminal of the rectifying circuit 311. The first common grounding resistor 391 is connected to a bleeding switching circuit 341 The common grounding of the first LED switching circuit 342 is performed and the common grounding of the second LED switching circuit 351 to the third LED switching circuit 352 is performed on the second common ground resistance 392.

The current operation control unit 330 controls the bleeding switching circuit 341 of the first switching circuit unit 340 and the first LED switching circuit 341 of the first switching circuit unit 340 according to the on / off operation states of the LED switching circuits 351 and 352 included in the second switching circuit unit 350, And controls the on / off operation of the circuit 342.

The LED lighting driver circuit 300 of the present embodiment configured as described above has a grounding structure for preventing the body effect from being generated in the field effect transistor of the second switching circuit unit 350 located at a relatively long distance from the power supply unit 310.

The first common grounding resistor 391 and the second common grounding resistor 392 are connected in parallel to the negative terminal of the rectifying circuit 311 so that the first switching circuit portion 340 and the second switching circuit portion 350 function as fully isolated circuits and set the ground to the source of the LED switching circuits 351, 352 included in the second switching circuit portion 350, that is, the second switching circuit portion 350. At this time, although the internal ground of the circuit is a specific point in the second switching circuit part 350, the ground point of the reference voltages V1 to V4 should be formed at the negative end of the rectifying circuit 311. [

Since the first switching circuit unit 340 and the second switching circuit unit 350 correspond to circuits completely separated from each other, the first switching circuit unit 340 and the second switching circuit unit 350 operate in accordance with the ON / OFF state of the second switching circuit unit 350 The operation state must be changed, and the current operation controller 330 takes charge of the operation.

The channel of the second switching circuit unit 250 is connected to the second common grounding resistor 392 and the channel of the first switching circuit unit 340 is connected to the first common grounding resistor 391 by the first common grounding resistor 391, It is decided. Since the entire system ground, that is, the system ground unit 380, is formed in the first switching circuit 340, the size of the field effect transistors included in the second switching circuit 350 can be minimized.

Fig. 8 is a diagram showing an embodiment of an EL illumination driving circuit according to Fig. 7; Fig.

As can be seen from FIGS. 3 to 8, the LED driving circuit according to the present invention does not take a method of separating the substrate of the high voltage field effect transistor through an additional layer, and the size of the high voltage field effect transistor The function of the LED lighting device including the high voltage field effect transistor is realized in the same manner as the function of the existing direct current type LED lighting device.

In addition, since the method of separating the substrate of the high voltage field effect transistor through the additional layer is not adopted, the reduction of the size of the high voltage field effect transistor does not cause the increase in the cost of the entire circuit system.

It is to be understood that the present invention is not limited to the above-described embodiment, and that various modifications and changes may be made without departing from the scope of the present invention as defined in the appended claims. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100, 200, 300: LED lighting driving circuit
110: power supply unit 111: rectifier circuit
120: LED lighting unit 121: first LED
122: second LED 123: third LED
130: switching circuit unit 131: switching element
132: comparator 140,240: reference voltage supply
141 to 143, 241 to 243: Reference voltage section 144: Bleeding reference voltage section
150, 250: Reference voltage ground 160, 260: System ground
170: first resistor 180: bleeding switching circuit
181: switching element 182: comparator
251: second resistor 261: common ground resistance
281: switching element 282: comparator
310: power supply unit 311: rectifier circuit
320: LED lighting unit 321: first LED
322: second LED 323: third LED
330: current operation control unit 340: first switching circuit
341: Bleeding switching circuit 342: First LED switching circuit
350: second switching circuit section 351: second LED switching circuit
352: third LED switching circuit 360: first reference voltage supply section
361,362: reference voltage section 370: second reference voltage supply section
371, 372: reference voltage section 380: system ground section
391: first common ground resistance 392: second common ground resistance

Claims (13)

A power supply unit including a power input terminal to which an external AC power is applied and a rectification circuit for an AC power input through the power input terminal;
An LED lighting unit including an n-th LED located at a longest distance from a power source, the first LED being located at a shortest distance from a connection point with the power source unit, the first LED being connected to the power source unit and each LED being connected in series;
A plurality of switching circuit units individually connected to output terminals of the LEDs forming the LED illumination unit to form current supply channels for the LEDs;
A reference voltage supply unit for applying a reference voltage to each of the switching circuit units;
A reference voltage grounding part in which each reference voltage part of the reference voltage supplying part is commonly grounded to a negative end of the rectifying circuit;
LED lighting driving circuit including a system grounding unit each of the switching circuit unit is a common ground. The method of claim 1,
Wherein the power supply further comprises a dimmer connected to the power input terminal to receive an AC voltage and to apply an output voltage to the rectifying circuit. 3. The method according to claim 1 or 2,
Further comprising a first resistor connected between the reference voltage ground and the system ground. 3. The method according to claim 1 or 2,
The switching circuit unit
LED lighting driving circuit comprising: a switching element connected to the output terminal of the LED and connected to the system ground unit; and a comparator for comparing a reference voltage of the reference voltage unit and a voltage input from the ground terminal of the system ground unit. in. 5. The method of claim 4,
And a bleeding switching circuit connected in parallel to a connection line between the power supply unit and the power input terminal of the first LED to form a bleeding current supply channel, wherein the bleeding switching circuit includes the plurality of switching circuits in the system ground. And grounded together with the bleeding reference voltage unit, which is commonly grounded to the negative terminal of the rectifier circuit. The method of claim 5, wherein
The bleeding switching circuit includes a switching element connected to an output terminal of the rectifying circuit and simultaneously connected to the system ground unit, and a comparator for comparing a reference voltage of the bleeding reference voltage unit and a voltage input from the ground terminal of the system ground unit. LED lighting driving circuit, characterized in that. The method according to claim 6,
Wherein a switching element of the switching circuit section and a switching element of the bleeding switching circuit are respectively connected to an output terminal of the rectifying circuit or an output terminal of the LED and a source is connected to the system ground section and a gate is connected to the comparator, (MOS FET). &Lt; / RTI &gt; The method of claim 7, wherein
Wherein either one or both of the switching circuit section and the bleeding switching circuit forms a negative feedback circuit between the comparator and the MOS FET. The method of claim 7, wherein
The voltage of the negative terminal of the rectifying circuit and the voltage of the reference voltage ground have the same voltage value and the voltage of the system ground and the substrate voltage of the field effect transistor and the source output voltage of the field effect transistor are the same And a voltage value. The method of claim 5, wherein
Wherein the system ground is formed by including a common grounding resistor to which the switching circuitry is commonly grounded and the reference voltage grounding portion comprises a second resistor for grounding the bleeding reference voltage of the bleeding switching circuit, LED lighting driving circuit. 11. The method of claim 10,
Wherein the switching element of the switching circuit part performs switching operation to either the first current path connected to the LED and the second current path connected to the common ground resistance in accordance with the comparator output of the switching circuit part, And an output terminal of the LED driving circuit. A power supply unit including a power input terminal to which an external AC power is applied and a rectification circuit for an AC power input through the power input terminal;
An LED lighting unit including an n-th LED located at a longest distance from a power source, the first LED being located at a shortest distance from a connection point with the power source unit, the first LED being connected to the power source unit and each LED being connected in series;
A bleeding switching circuit connected in parallel to a connection line between the power source and a power input terminal of the first LED to form a bleeding current supply channel and a first LED switching circuit connected to an output terminal of the first LED to form a current supply channel, A first switching circuit part including a circuit;
A second switching in which each LED switching circuit forms a separate current supply channel for the corresponding LED, including second to nth LED switching circuits individually connected to an output end of the nth LED from an output end of the second LED; Circuit section;
A first reference voltage supply unit to which a reference voltage is applied to each of the bleeding switching circuit and the first LED switching circuit and each reference voltage portion is commonly grounded to a negative end of the rectifying circuit;
A second reference voltage supply unit to which a reference voltage is applied to the second LED switching circuit and an nth LED switching circuit, respectively, and each reference voltage portion is commonly grounded to the negative terminal of the rectifying circuit;
A system grounding section in which each LED switching circuit of the second switching circuit section is commonly grounded;
The common ground of the first common ground resistor and the second LED switching circuit to the nth LED switching circuit in which the common ground of the bleeding switching circuit and the first LED switching circuit are formed in a state of being connected in parallel with the negative terminal of the rectifier circuit. LED lighting driving circuit comprising a second common ground resistance is grounded. 13. The method of claim 12,
And a current operation control unit controlling an on / off operation of the bleeding switching circuit and the LED switching circuit of the first switching circuit unit according to an on / off operation state of the LED switching circuit included in the second switching circuit unit. LED lighting driving circuit.

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