KR101879670B1 - The Converter with Reduced Initial Starting Current - Google Patents

Abstract

The present invention relates to a converter to reduce an initial starting current, most suitable for starting a light emitting diode (LED). According to the present invention, the converter to reduce an initial starting current comprises: an input end rectification diode (20) to rectify alternating current (AC) power into direct current (DC) power; a third sub diode (33) connected to positive output of the input end rectification diode (20); a first power factor improvement coupled inductor (34-1) connected to negative output of the input end rectification diode (20); a first sub diode (31) connected to one side of the first power factor improvement coupled inductor (34-1); a second power factor improvement coupled inductor (34-2) connected to the first sub diode (31); a smoothing capacitor (35) connected between the second power factor improvement coupled inductor (34-2) and a power factor improvement coupled inductor (34); a second sub diode (32) connected to a positive terminal of the smoothing capacitor (35); a main transformer (150) connected to a cathode of the second sub diode (32) and a cathode of the third sub diode (33); a main switch (37) connected between the main transformer (150) and the first power factor improvement coupled inductor (34-1); a snubber circuit to reduce surge and noise generated in switching of the main software (37); output voltage and current detection units (151, 152); constant voltage and current control units (141, 145); a cathode of a first diode (D1) connected to the constant voltage control unit (141); a cathode of a second diode (D2) connected to the constant current control unit (145); and a photocoupler transmission unit (PH1) connected to an anode of the first diode (D1) and an anode of the second diode (D2).

Description

[0001] The present invention relates to a converter having a reduced initial starting current,

The present invention relates to a power supply device with reduced initial starting current. In particular, since the power supply device has a problem in that a starting current is generated initially due to a bank capacitor, in the present invention, a converter that is most suitable for light emission of an LED (Light Emitting Diode) .

Resonant converters are the most popular power supplies. Most of all, ZVS (Zero-Voltage-Switching) is performed stably due to the resonance of the leakage inductor (Llk) and the resonant capacitor in the transformer. Therefore, various power supply devices have been actively studied and applied.

As a related prior art, Korean Patent Laid-open Publication No. 10-2018-0004655 and Laid-open Publication No. 2001-208 (hereinafter referred to as "Patent Document 1") disclose a hybrid full bridge LLC converter and a driving method thereof. The first and second full bridge LLC converters are connected in parallel to the input terminals of the first and second transformers, and the first and second full bridge LLC converters are connected in parallel. In the first and second full bridge LLC converters, 2 transformer are connected in series.

Another prior art document is disclosed in Korean Patent Registration No. 10-1223220, Publication Date 2013. 01. 10. (hereinafter referred to as Patent Document 2), which discloses a series resonant converter circuit. In the above Patent Reference 2, a resonance type converter having a half bridge circuit at the primary side of the transformer, a voltage doubler rectifying circuit at the secondary side of the transformer, a main switch for controlling the output voltage and current, The control method is disclosed.

In addition, a DC-DC converter having a wide input voltage control range is disclosed in Korean Patent Publication No. 10-1304777, Announcement 2013. 09. 05 (hereinafter referred to as Patent Document 1). Patent Document 1 discloses a technique in which an interleaved flyback converter and an LLC resonant converter are combined to transfer electric energy generated from a solar cell having a wide input range to a load, DC converter for generating a DC voltage.

However, in the above-described Patent Documents 1 to 3, the resonance type converter has been proposed, but the initial starting current can not be reduced.

[Patent Document 1] Korean Patent Laid-Open Publication No. 10-2018-0004655, Disclosure Date 2018. 01. 12. [Patent Document 2] Korean Registered Patent No. 10-1223220, Published Date 2013. 01. 10. [Patent Document 3] Korean Registered Patent No. 10-1304777, Published on March 23, 2013.

In the present invention, the initial starting current is reduced in the resonant converter to reduce stress on the electric element of the power supply device, and at the same time, a converter suitable for driving an LED (Light Emitting Diode) by introducing a constant voltage-constant current simultaneous control method is proposed do.

In the present invention, first, the initial starting current is reduced through the initial starting current reducing unit 30 in the input stage rectifier diode 20 connected to the AC power source 10. Second, the first and second power factor improvement The coupling inductors 34-1 and 34-2 are magnetically coupled 34-3 so that the starting current is further reduced. Third, the constant voltage-constant current control unit 148 is used to drive the LED (Light Emitting Diode) The constant current-constant current converter in which the initial starting current most suitable for the constant-voltage-constant current converter is reduced.

The first starting current reducing unit 30 and the first and second power factor improving coupling inductors 34-1 and 34-2 are magnetically coupled to the input stage rectifier diode 20 connected to the AC power source 10. [ The output current of the input stage filter unit 160 is reduced due to the reduction of the starting current in the power supply unit 34-3, The third embodiment is most suitable for driving an LED (Light Emitting Diode) through the constant voltage-constant current control unit 148 and has an effect of controlling the constant voltage-constant current to the load (LED, etc.) have.

1 is a schematic diagram of a conventional LED power supply
Fig. 2 is a plan view of a flyback rectification type converter (first embodiment)
3 is a flyback rectification type converter (second embodiment) in which the initial starting current is reduced,
Fig. 4 shows a forward rectification type converter (first embodiment)
Fig. 5 shows a forward rectification type converter (the second embodiment)
Fig. 6 is a 2-switch forward rectification type converter (first embodiment) in which an initial starting current is reduced. Fig.
Fig. 7 shows a two-switch forward rectification type converter (the second embodiment) in which the initial start-
8 is a half bridge forward rectification type LLC converter (first embodiment) in which an initial starting current is reduced.
9 is a half bridge forward rectification type LLC converter (second embodiment) in which the initial starting current is reduced.
10 is a circuit diagram of a constant-voltage-constant current converter
11 is a diagram showing a flyback rectification type constant voltage-constant current converter (first embodiment) in which the initial start-
12 shows a flyback rectification type constant voltage-constant current converter (second embodiment) in which the initial starting current is reduced,

The present invention will now be described in detail with reference to the accompanying drawings.

Figure 1 shows a conventional power supply for a typical LED.

And shows the conventional power supply device for general LED. The AC power source 10 is rectified through the input rectifier diode 20 and the power factor improving converter unit 100 and the DC-DC converter unit 200 generally supply power to the LED group 300 to be.

The power factor improving converter unit 100 includes a first current sensor 101 at an input terminal, a second current sensor 102 for detecting a current in the power factor improving converter unit 100, The power factor improving converter control unit 130 controls the switch of the power factor improving converter power circuit unit 110 based on the current and voltage information from the output stage first and second voltage dividing resistors 103 and 104.

The output voltage and current information of the DC-DC converter section 200 is detected from the third and fourth voltage dividing resistors 202 and 203 and the third current sensor 204 at the output terminal of the DC-DC converter section 200, And controls the switch of the DC-DC converter power circuit unit 210 through the DC-DC converter control unit 230.

2 shows a flyback rectification type converter (first embodiment) in which the initial starting current is reduced.

In the flyback rectification type converter (first embodiment) in which the initial starting current is reduced, the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10 . The output of the initial starting current reducing unit 30 is connected to a flyback transformer 36 and a main switch 37. The main switch 37 is turned on and off Power is transferred to the secondary side 36-2 of the flyback transformer while the current flow is changed to the flyback transformer primary side 36-1.

In the initial starting current reducing unit 30, a third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20, and the source terminal of the main switch 37 is connected to One terminal of the power factor improving inductor 34 is connected and the other terminal of the power factor improving inductor 34 is connected to the negative output terminal of the input stage rectifier diode 20 .

A first auxiliary diode 31 is connected to the other terminal of the power factor improving inductor 34 and a cathode terminal of the first auxiliary diode 31 and a cathode terminal of the power factor improving inductor 34 are connected to each other. A smoothing capacitor 35 is disposed on one side of the first auxiliary diode 31 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31. The second auxiliary diode 32 Is connected to a cathode terminal of the third auxiliary diode 33 and a flyback transformer primary side 36-1 of the flyback transformer.

Since the smoothing capacitor 35 is not connected to the (+) output terminal of the input stage rectification diode 20, the initial starting current reducing unit 30 has an effect of reducing the initial starting current.

It is the biggest technical feature that the LED group (Group) is emitted to the secondary side 36-2 of the flyback transformer through the flyback rectifier 40.

Fig. 3 shows a flyback rectification type converter (second embodiment) in which the initial starting current is reduced.

In the flyback rectification type converter (the second embodiment) in which the initial starting current is reduced, the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10 . The output of the initial starting current reducing unit 30 is connected to a flyback transformer 36 and a main switch 37. The main switch 37 is turned on and off Power is transferred to the secondary side 36-2 of the flyback transformer while the current flow is changed to the flyback transformer primary side 36-1.

In the initial starting current reducing unit 30, a third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20, and the source terminal of the main switch 37 is connected to One terminal of the first power factor improving coupling inductor 34-1 is connected and the other terminal of the first power factor improving coupling inductor 34-1 is connected to the input stage rectifier diode 20, (-) output terminal of the inverter.

A first auxiliary diode 31 is connected to the other terminal of the first power factor improving coupling inductor 34-1 and a cathode terminal of the first auxiliary diode 31 is connected to a first auxiliary diode 31, A smoothing capacitor 35 is disposed at one terminal of the power factor improving coupling inductor 34-1 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31 And a cathode terminal of the second auxiliary diode 32 is connected to a cathode terminal of the third auxiliary diode 33 and the flyback transformer primary side 36-1 have.

The first power factor improving coupling inductor 34-1 and the second power factor improving coupling inductor 34-2 form a magnetic coupling 34-3 and the main switch 37 is turned on, (+) Of the smoothing capacitor 35 because the second power factor improving coupling inductor 34-2 is magnetically coupled 34-3 when a current flows through the first power factor improving coupling inductor 34-1. (+) Polarity is formed in the second power factor improving coupling inductor 34-2 in the terminal direction, and electric energy is gradually stored in the smoothing capacitor 35.

When the main switch 37 is turned off, the first power factor improving coupling inductor 34-1 is cut off and the second power factor improving coupling inductor 34-2 is magnetically coupled A voltage is generated in the direction of the cathode of the first auxiliary diode 31 and the current of the first power factor improving coupling inductor 34-1 is supplied to the first auxiliary diode 31 and / A current flows through the smoothing capacitor 35 through the second power factor improving coupling inductor 34-2 so that the second power factor improving coupling inductor 34-1 is interrupted in the direction that impedes the current flow of the first power factor improving coupling inductor 34-1, There is a technical feature that an inrush current does not flow into the smoothing capacitor 35 because the inductor 34-2 has a polarity.

Therefore, the smoothening capacitor 35 is not connected to the (+) output terminal of the input stage rectifier diode 20 and the first and second power factor improving coupling inductors 34-1 and 34 -2) by reducing the inrush current to the smoothing capacitor 35, the initial starting current is greatly reduced.

It is the biggest technical feature that the LED group (Group) is emitted to the secondary side 36-2 of the flyback transformer through the flyback rectifier 40.

Fig. 4 shows a forward rectification type converter (first embodiment) in which the initial starting current is reduced.

In the forward rectification type converter (the first embodiment) in which the initial starting current is reduced, the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10. The output of the initial starting current reducing section 30 is connected to a forward transformer 39 and a main switch 37. The output of the initial starting current reducing section 30 is connected to a forward transformer 39 and a main switch 37. When the main switch 37 is turned on and off, Electric power is transmitted to the forward transformer secondary side 39-2 while the current flow is changed to the forward transformer primary side 39-1.

In the initial starting current reducing unit 30, a third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20, and the source terminal of the main switch 37 is connected to One terminal of the power factor improving inductor 34 is connected and the other terminal of the power factor improving inductor 34 is connected to the negative output terminal of the input stage rectifier diode 20 .

A first auxiliary diode 31 is connected to the other terminal of the power factor improving inductor 34 and a cathode terminal of the first auxiliary diode 31 and a cathode terminal of the power factor improving inductor 34 are connected to each other. A smoothing capacitor 35 is disposed on one side of the first auxiliary diode 31 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31. The second auxiliary diode 32 Is connected to a cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1. The cathode terminal of the third auxiliary diode 33 is connected to the cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1.

Since the smoothing capacitor 35 is not connected to the (+) output terminal of the input stage rectification diode 20, the initial starting current reducing unit 30 has an effect of reducing the initial starting current.

It is the biggest technical feature that the forward transformer secondary side 39-2 emits the LED group Group through the forward rectifying part 50. [

Fig. 5 shows a forward rectification type converter (second embodiment) in which the initial starting current is reduced.

In the forward rectification type converter (the second embodiment) in which the initial starting current is reduced, the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10. The output of the initial starting current reducing section 30 is connected to a forward transformer 39 and a main switch 37. The output of the initial starting current reducing section 30 is connected to a forward transformer 39 and a main switch 37. When the main switch 37 is turned on and off, Electric power is transmitted to the forward transformer secondary side 39-2 while the current flow is changed to the forward transformer primary side 39-1.

In the initial starting current reducing unit 30, a third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20, and the source terminal of the main switch 37 is connected to One terminal of the first power factor improving coupling inductor 34-1 is connected and the other terminal of the first power factor improving coupling inductor 34-1 is connected to the input stage rectifier diode 20, (-) output terminal of the inverter.

A first auxiliary diode 31 is connected to the other terminal of the first power factor improving coupling inductor 34-1 and a cathode terminal of the first auxiliary diode 31 is connected to a first auxiliary diode 31, A smoothing capacitor 35 is disposed at one terminal of the power factor improving coupling inductor 34-1 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31 And a cathode terminal of the second auxiliary diode 32 is connected to a cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1 .

The first power factor improving coupling inductor 34-1 and the second power factor improving coupling inductor 34-2 form a magnetic coupling 34-3 and the main switch 37 is turned on, (+) Of the smoothing capacitor 35 because the second power factor improving coupling inductor 34-2 is magnetically coupled 34-3 when a current flows through the first power factor improving coupling inductor 34-1. (+) Polarity is formed in the second power factor improving coupling inductor 34-2 in the terminal direction, and electric energy is gradually stored in the smoothing capacitor 35.

When the main switch 37 is turned off, the first power factor improving coupling inductor 34-1 is cut off and the second power factor improving coupling inductor 34-2 is magnetically coupled A voltage is generated in the direction of the cathode of the first auxiliary diode 31 and the current of the first power factor improving coupling inductor 34-1 is supplied to the first auxiliary diode 31 and / A current flows through the smoothing capacitor 35 through the second power factor improving coupling inductor 34-2 so that the second power factor improving coupling inductor 34-1 is interrupted in the direction that impedes the current flow of the first power factor improving coupling inductor 34-1, There is a technical feature that an inrush current does not flow into the smoothing capacitor 35 because the inductor 34-2 has a polarity.

Therefore, the smoothening capacitor 35 is not connected to the (+) output terminal of the input stage rectifier diode 20 and the first and second power factor improving coupling inductors 34-1 and 34 -2) by reducing the inrush current to the smoothing capacitor 35, the initial starting current is greatly reduced.

It is the biggest technical feature that the forward transformer secondary side 39-2 emits the LED group Group through the forward rectifying part 50. [

Fig. 6 shows a two-switch forward rectification type converter (first embodiment) in which the initial starting current is reduced.

In the two-switch forward rectification type converter (first embodiment) in which the initial starting current is reduced, since the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10, to be. The output of the initial starting current reducing section 30 is connected to a forward transformer 39 and a two switch forward circuit section 60 and is connected to the first and second main switches 61, 63 are turned on and off to the forward transformer primary 39-1 while the flow of current is changed to the forward transformer secondary 39-2 Power is transmitted.

The third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20 and the source of the 2-switch forward circuit unit 60 is connected to the Terminal of the power factor improving inductor 34 is connected to the negative output terminal of the input stage rectifier diode 20 and the other terminal of the power factor improving inductor 34 is connected to the .

A first auxiliary diode 31 is connected to the other terminal of the power factor improving inductor 34 and a cathode terminal of the first auxiliary diode 31 and a cathode terminal of the power factor improving inductor 34 are connected to each other. A smoothing capacitor 35 is disposed on one side of the first auxiliary diode 31 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31. The second auxiliary diode 32 Is connected to a cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1. The cathode terminal of the third auxiliary diode 33 is connected to the cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1.

Since the smoothing capacitor 35 is not connected to the (+) output terminal of the input stage rectification diode 20, the initial starting current reducing unit 30 has an effect of reducing the initial starting current.

It is the biggest technical feature that the forward transformer secondary side 39-2 emits the LED group Group through the forward rectifying part 50. [

Fig. 7 shows a two-switch forward rectification type converter (second embodiment) in which the initial starting current is reduced.

In the two-switch forward rectification type converter (the second embodiment) in which the initial starting current is reduced, the fact that the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10 is the largest technical characteristic to be. The output of the initial starting current reducing section 30 is connected to a forward transformer 39 and a two switch forward circuit section 60 and is connected to the first and second main switches 61, 63 are turned on and off to the forward transformer primary 39-1 while the flow of current is changed to the forward transformer secondary 39-2 Power is transmitted.

The third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20 and the source of the 2-switch forward circuit unit 60 is connected to the One terminal of the first power factor improving coupling inductor 34-1 is connected to the other terminal of the first power factor improving coupling inductor 34-1 and the other terminal of the first power factor improving coupling inductor 34-1 is connected to the input rectifier diode 20) to the (-) output terminal.

A first auxiliary diode 31 is connected to the other terminal of the first power factor improving coupling inductor 34-1 and a cathode terminal of the first auxiliary diode 31 is connected to a first auxiliary diode 31, A smoothing capacitor 35 is disposed at one terminal of the power factor improving coupling inductor 34-1 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31 And a cathode terminal of the second auxiliary diode 32 is connected to a cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1 .

The first power factor improving coupling inductor 34-1 and the second power factor improving coupling inductor 34-2 form a magnetic coupling 34-3 and the first and second power factor improving coupling inductors 34-1, When the switches 61 and 62 are turned on, if a current flows through the first power factor improving coupling inductor 34-1, the second power factor improving coupling inductor 34-2 is magnetically coupled 34-3 (+) Polarity is formed in the second power factor improving coupling inductor 34-2 in the direction of the (+) terminal of the smoothing capacitor 35 and electric energy is gradually stored in the smoothing capacitor 35 do.

When the first and second switches 61 and 62 are turned off in the two-switch forward circuit unit 60, the current is cut off to the first power factor improving coupling inductor 34-1, Since the improved coupling inductor 34-2 is magnetically coupled 34-3, a voltage is generated in the direction of the cathode of the first auxiliary diode 31, and the first power factor improving coupling inductor 34-1 Current flows through the smoothing capacitor 35 through the first auxiliary diode 31 and the second power factor improving coupling inductor 34-2 so that the first power factor improving coupling inductor 34-1, The inrush current does not flow into the smoothing capacitor 35 because the polarity is formed in the second power factor improving coupling inductor 34-2 in the direction that interrupts the current flow of the smoothing capacitor 35. [

Therefore, the smoothening capacitor 35 is not connected to the (+) output terminal of the input stage rectifier diode 20 and the first and second power factor improving coupling inductors 34-1 and 34 -2) by reducing the inrush current to the smoothing capacitor 35, the initial starting current is greatly reduced.

It is the biggest technical feature that the forward transformer secondary side 39-2 emits the LED group Group through the forward rectifying part 50. [

Fig. 8 shows a half bridge forward rectification type converter (first embodiment) in which the initial starting current is reduced. In the half bridge forward rectification type converter (first embodiment) in which the initial starting current is reduced, the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10, to be. The output of the initial starting current reducing section 30 is connected to half bridge first and second main switches 71 and 73. A forward transformer is connected to both ends of the half bridge second main switch 73 39 is connected to the resonance capacitor Cs 75 and the leakage inductance Llk of the forward transformer 39-3 through the LLC resonance in which the magnetization inductance Lm of the forward transformer resonates, , And zero-voltage switching (ZVS) of the two main switches 71 and 73. In addition, the flow of current is changed to the forward transformer primary side 39-1 through the half bridge first and second main switches 71 and 73 being turned on and off, Forward power is transmitted to the transformer secondary side 39-2.

The first starting current reducing unit 30 has a third auxiliary diode 33 connected to the positive output terminal of the input stage rectifier diode 20 and a source of the half bridge second main switch 73 Source terminal of the power factor correction inductor 34 is connected to one terminal of the power factor correction inductor 34 and the other terminal of the power factor correction inductor 34 is connected to the negative output terminal Respectively.

A first auxiliary diode 31 is connected to the other terminal of the power factor improving inductor 34 and a cathode terminal of the first auxiliary diode 31 and a cathode terminal of the power factor improving inductor 34 are connected to each other. A smoothing capacitor 35 is disposed on one side of the first auxiliary diode 31 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31. The second auxiliary diode 32 Is connected to a cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1. The cathode terminal of the third auxiliary diode 33 is connected to the cathode terminal of the third auxiliary diode 33 and the forward transformer primary 39-1.

Since the smoothing capacitor 35 is not connected to the (+) output terminal of the input stage rectification diode 20, the initial starting current reducing unit 30 has an effect of reducing the initial starting current.

It is the biggest technical feature that the forward transformer secondary side 39-2 emits the LED group Group through the forward rectifying part 50. [

Fig. 9 shows a half bridge forward rectification type LLC converter (second embodiment) in which the initial starting current is reduced. In the half bridge forward rectification type converter (the second embodiment) in which the initial starting current is reduced, the fact that the initial starting current reducing unit 30 is located in the input stage rectifier diode 20 connected to the AC power source 10 is the largest technical characteristic to be. The output of the initial starting current reducing section 30 is connected to half bridge first and second main switches 71 and 73. A forward transformer is connected to both ends of the half bridge second main switch 73 39 is connected to the resonance capacitor Cs 75 and the leakage inductance Llk of the forward transformer 39-3 through the LLC resonance in which the magnetization inductance Lm of the forward transformer resonates, , And zero-voltage switching (ZVS) of the two main switches 71 and 73. In addition, the flow of current is changed to the forward transformer primary side 39-1 through the half bridge first and second main switches 71 and 73 being turned on and off, Forward power is transmitted to the transformer secondary side 39-2.

The first starting current reducing unit 30 has a third auxiliary diode 33 connected to the positive output terminal of the input stage rectifier diode 20 and a source of the half bridge second main switch 73 One terminal of the first power factor improving coupling inductor 34-1 is connected to the other terminal of the first power factor improving coupling inductor 34-1 and the other terminal of the first power factor improving coupling inductor 34-1 is connected to the input terminal rectifier 34. [ And is connected to the (-) output terminal of the diode 20.

A first auxiliary diode 31 is connected to the other terminal of the first power factor improving coupling inductor 34-1 and a cathode terminal of the first auxiliary diode 31 is connected to a first auxiliary diode 31, A smoothing capacitor 35 is disposed on one terminal of the power factor improving coupling inductor 34-1 and a second power factor improving coupling inductor 34- The other side of the second power factor improving coupling inductor 34-2 is connected to a drain terminal of the first half bridge bridge 71, have.

The first power factor improving coupling inductor 34-1 and the second power factor improving coupling inductor 34-2 form a magnetic coupling 34-3 and the half bridge second main switch 73 is turned on When the current flows through the first power factor improving coupling inductor 34-1, the second power factor improving coupling inductor 34-2 is magnetically coupled 34-3, (+) Polarity is formed in the direction of the cathode terminal of each of the transistors 32, 32.

When the half bridge second main switch 73 is turned off and the half bridge first main switch 71 is turned on, the first power factor improving coupling inductor 34-1 And the second power factor improving coupling inductor 34-2 is magnetically coupled 34-3 so that a voltage is generated in the direction of the half bridge first main switch 71, The current of the power factor improving coupling inductor 34-1 flows to the smoothing capacitor 35 through the first auxiliary diode 31 so that the current flow of the first power factor improving coupling inductor 34-1 is interrupted The second power factor improving coupling inductor 34-2 has a polarity formed in the direction opposite to the direction in which the smoothing capacitor 35 is formed.

The (+) polarity generated in the second power factor improving coupling inductor 34-2 is such that the current flows from the (-) terminal of the half bridge first main switch 71 to the forward transformer 39 to the smoothing capacitor 35 There is a technical feature that an inrush current does not flow to the smoothing capacitor 35 because there is a flow.

Therefore, the smoothening capacitor 35 is not connected to the (+) output terminal of the input stage rectifier diode 20 and the first and second power factor improving coupling inductors 34-1 and 34 -2) by reducing the inrush current to the smoothing capacitor 35, the initial starting current is greatly reduced.

It is the biggest technical feature that the forward transformer secondary side 39-2 emits the LED group Group through the forward rectifying part 50. [

10 shows a constant voltage-constant current converter in which an initial starting current is reduced.

In the constant voltage-constant current converter in which the initial starting current is reduced, the initial starting current reducing unit and the switch circuit unit 80 are connected to the input stage rectifier diode 20 connected to the AC power source 10, A main transformer 150 is connected to the circuit unit 80 and a power is supplied to the LED group 300 through a flyback rectifier 40 to the secondary side of the main transformer 150 to emit light do.

The main transformer 150 includes a flyback transformer 36 for transmitting main power and a constant voltage-constant current controller 140 and an auxiliary power source transformer 91 for supplying power to the main switch control IC 81.

A main switch 37 is connected to the primary side 36-1 of the flyback transformer.

The output voltage information detected by the output voltage detector 151 at the rear stage of the flyback rectifier 40 is input to the constant voltage controller 141 of the constant voltage to constant current controller 140 to perform constant voltage control, The output current information detected through the constant current control unit 145 is inputted to the constant current control unit 145 of the constant voltage and constant current control unit 140 and the constant current control is performed, and the output of the constant current control unit 145 The main switch control IC 81 is controlled through the constant voltage-constant current control unit 148 and the main switch 37 is controlled to be turned on and off.

Fig. 11 shows a flyback rectification type constant voltage-constant current converter (first embodiment) in which the initial starting current is reduced.

In the flyback rectification type constant voltage-constant current converter (first embodiment) in which the initial starting current is reduced, the input stage filter 160 connected to the AC power source 10 and the input stage rectifier diode 20, It is the largest technical feature that the current reducing section 30 is located. The output of the initial starting current reducing unit 30 is connected to a flyback transformer 36 and a main switch 37. The main switch 37 is turned on and off Power is transferred to the secondary side 36-2 of the flyback transformer while the current flow is changed to the flyback transformer primary side 36-1.

In the initial starting current reducing unit 30, a third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20, and the source terminal of the main switch 37 is connected to One terminal of the power factor improving inductor 34 is connected and the other terminal of the power factor improving inductor 34 is connected to the negative output terminal of the input stage rectifier diode 20 .

A first auxiliary diode 31 is connected to the other terminal of the power factor improving inductor 34 and a cathode terminal of the first auxiliary diode 31 and a cathode terminal of the power factor improving inductor 34 are connected to each other. A smoothing capacitor 35 is disposed on one side of the first auxiliary diode 31 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31. The second auxiliary diode 32 Is connected to a cathode terminal of the third auxiliary diode 33 and a flyback transformer primary side 36-1 of the flyback transformer.

Since the smoothing capacitor 35 is not connected to the (+) output terminal of the input stage rectification diode 20, the initial starting current reducing unit 30 has an effect of reducing the initial starting current.

It is the biggest technical feature that the LED group (Group) is emitted to the secondary side 36-2 of the flyback transformer through the flyback rectifier 40.

The main transformer 150 includes a flyback transformer 36 for transmitting main power and a constant voltage-constant current controller 140 and an auxiliary power source transformer 91 for supplying power to the main switch control IC 81.

A main switch 37 is connected to the primary side 36-1 of the flyback transformer.

The output voltage information detected by the output voltage detector 151 at the rear stage of the flyback rectifier 40 is input to the constant voltage controller 141 of the constant voltage to constant current controller 140 to perform constant voltage control, The output current information detected through the constant current control unit 145 is inputted to the constant current control unit 145 of the constant voltage and constant current control unit 140 and the constant current control is performed, and the output of the constant current control unit 145 The main switch control IC 81 is controlled through the constant voltage-constant current control unit 148 and the main switch 37 is controlled to be turned on and off.

12 shows a flyback rectification type constant voltage-constant current converter (second embodiment) in which the initial starting current is reduced.

In the flyback rectification type constant voltage-constant current converter (the second embodiment) in which the initial starting current is reduced, the input stage filter 160 connected to the AC power source 10 and the input stage rectifier diode 20 are connected to the rear stage of the input stage rectifier diode 20, It is the largest technical feature that the current reducing section 30 is located. The output of the initial starting current reducing unit 30 is connected to a flyback transformer 36 and a main switch 37. The main switch 37 is turned on and off Power is transferred to the secondary side 36-2 of the flyback transformer while the current flow is changed to the flyback transformer primary side 36-1.

In the initial starting current reducing unit 30, a third auxiliary diode 33 is connected to the (+) output terminal of the input stage rectifier diode 20, and the source terminal of the main switch 37 is connected to One terminal of the first power factor improving coupling inductor 34-1 is connected and the other terminal of the first power factor improving coupling inductor 34-1 is connected to the input stage rectifier diode 20, (-) output terminal of the inverter.

A first auxiliary diode 31 is connected to the other terminal of the first power factor improving coupling inductor 34-1 and a cathode terminal of the first auxiliary diode 31 is connected to a first auxiliary diode 31, A smoothing capacitor 35 is disposed at one terminal of the power factor improving coupling inductor 34-1 and a second auxiliary diode 32 is connected to a cathode terminal of the first auxiliary diode 31 And a cathode terminal of the second auxiliary diode 32 is connected to a cathode terminal of the third auxiliary diode 33 and the flyback transformer primary side 36-1 have.

The first power factor improving coupling inductor 34-1 and the second power factor improving coupling inductor 34-2 form a magnetic coupling 34-3 and the main switch 37 is turned on, (+) Of the smoothing capacitor 35 because the second power factor improving coupling inductor 34-2 is magnetically coupled 34-3 when a current flows through the first power factor improving coupling inductor 34-1. (+) Polarity is formed in the second power factor improving coupling inductor 34-2 in the terminal direction, and electric energy is gradually stored in the smoothing capacitor 35.

When the main switch 37 is turned off, the first power factor improving coupling inductor 34-1 is cut off and the second power factor improving coupling inductor 34-2 is magnetically coupled A voltage is generated in the direction of the cathode of the first auxiliary diode 31 and the current of the first power factor improving coupling inductor 34-1 is supplied to the first auxiliary diode 31 and / A current flows through the smoothing capacitor 35 through the second power factor improving coupling inductor 34-2 so that the second power factor improving coupling inductor 34-1 is interrupted in the direction that impedes the current flow of the first power factor improving coupling inductor 34-1, There is a technical feature that an inrush current does not flow into the smoothing capacitor 35 because the inductor 34-2 has a polarity.

Therefore, the smoothening capacitor 35 is not connected to the (+) output terminal of the input stage rectifier diode 20 and the first and second power factor improving coupling inductors 34-1 and 34 -2) by reducing the inrush current to the smoothing capacitor 35, the initial starting current is greatly reduced.

It is the biggest technical feature that the LED group (Group) is emitted to the secondary side 36-2 of the flyback transformer through the flyback rectifier 40.

The main transformer 150 includes a flyback transformer 36 for transmitting main power and a constant voltage-constant current controller 140 and an auxiliary power source transformer 91 for supplying power to the main switch control IC 81.

A main switch 37 is connected to the primary side 36-1 of the flyback transformer.

The output voltage information detected by the output voltage detector 151 at the rear stage of the flyback rectifier 40 is input to the constant voltage controller 141 of the constant voltage to constant current controller 140 to perform constant voltage control, The output current information detected through the constant current control unit 145 is inputted to the constant current control unit 145 of the constant voltage and constant current control unit 140 and the constant current control is performed, and the output of the constant current control unit 145 The main switch control IC 81 is controlled through the constant voltage-constant current control unit 148 and the main switch 37 is controlled to be turned on and off.

The flyback rectification type constant voltage-constant current control circuit in which the initial starting current is reduced as shown in FIGS. 11 and 12 is not limited to the flyback converter alone, but may be a forward converter, a forward switch, Forward, and half-bridge converters.

In the present invention, the converter with reduced initial starting current includes an input rectifier diode (20) connected to the AC power supply (10) and rectifying the AC power to DC power; A third auxiliary diode 33 connected to the (+) output of the input rectifier diode 20; A first power factor improving coupling inductor (34-1) connected to the (-) output of the input stage rectifier diode (20); A first auxiliary diode 31 connected to one side of the first power factor improving coupling inductor 34-1; A second power factor improving coupling inductor (34-2) connected to the first auxiliary diode (31); The first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2) form a magnetic coupling (34-3); A smoothing capacitor (35) connected between the first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2); A second auxiliary diode (32) connected to the (+) terminal of the smoothing capacitor (35); A main transformer 150 connected to a cathode of the second auxiliary diode 32 and a cathode of the third auxiliary diode 33; A main switch 37 connected between the main transformer 150 and the first power factor improving coupling inductor 34-1; A load for supplying and discharging power output through the secondary side of the main transformer 150; A snubber capacitor 171, a snubber resistor 172 and a snubber diode 173 are provided on the primary side of the main transformer 150 to reduce surges and noise generated when the main switch 37 is switched. A snubber circuit; An output voltage detector 151 for detecting a voltage of the load; An output current detection unit 152 for detecting a current of the load; A constant voltage control unit 141 for controlling the output voltage detected by the output voltage detection unit 151 to a constant voltage; A constant current control unit 145 for constant current control of the output current detected by the output current detection unit 152; A cathode of a first diode (D1) connected to the constant voltage control unit (141); A cathode of a second diode D2 connected to the constant current control unit 145; And an optical coupler PH1 connected to an anode of the first diode D1 and an anode of the second diode D2; The output of the constant voltage control unit 141 and the output of the constant current control unit 145 are simultaneously controlled in the constant voltage-constant current mode.

In the present invention, the converter with reduced initial starting current includes an input rectifier diode 20 connected to the AC power source 10 to rectify the AC power to DC power; A third auxiliary diode 33 connected to the (+) output of the input rectifier diode 20; A first power factor improving coupling inductor (34-1) connected to the (-) output of the input stage rectifier diode (20); A first auxiliary diode 31 connected to one side of the first power factor improving coupling inductor 34-1; A second power factor improving coupling inductor (34-2) connected to the first auxiliary diode (31); The first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2) form a magnetic coupling (34-3); A smoothing capacitor (35) connected between the first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2); A second auxiliary diode (32) connected to the (+) terminal of the smoothing capacitor (35); A two switch forward first main switch (61) connected to a cathode of the second auxiliary diode (32); A main transformer 150 connected to the cathodes of the two-switch-forward first main switch 61 and the third auxiliary diode 33; A second switch forward second switch (63) connected between the cathode of the third auxiliary diode (33) and the first power factor improving coupling inductor (34-1); A load for supplying and discharging power output through the secondary side of the main transformer 150; An output voltage detector 151 for detecting a voltage of the load; An output current detection unit 152 for detecting a current of the load; A constant voltage control unit 141 for controlling the output voltage detected by the output voltage detection unit 151 to a constant voltage; A constant current control unit 145 for constant current control of the output current detected by the output current detection unit 152; A cathode of a first diode (D1) connected to the constant voltage control unit (141); A cathode of a second diode D2 connected to the constant current control unit 145; And an optical coupler PH1 connected to an anode of the first diode D1 and an anode of the second diode D2; The output of the constant voltage control unit 141 and the output of the constant current control unit 145 are simultaneously controlled in the constant voltage-constant current mode.

Finally, in the present invention, the converter with reduced initial starting current includes an input rectifier diode 20 connected to the AC power source 10 to rectify the AC power to DC power; A first power factor improving coupling inductor (34-1) connected to the (-) output of the input stage rectifier diode (20); A first auxiliary diode 31 connected to one side of the first power factor improving coupling inductor 34-1; A smoothing capacitor 35 connected to the first auxiliary diode 31; A second auxiliary diode (32) connected to the (+) terminal of the smoothing capacitor (35); A second power factor improving coupling inductor (34-2) connected to the second auxiliary diode (32); The first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2) form a magnetic coupling (34-3); A first half bridge first main switch 71 connected between the second power factor improving coupling inductor 34-2 and a cathode of the third auxiliary diode 33; A half bridge second main switch 73 connected between the cathode of the third auxiliary diode 33 and the other side of the first power factor improving coupling inductor 34-1; A resonant capacitor (Cs) 75 and a forward transformer 39 connected to both ends of the second main switch 73; The resonant capacitor (Cs) 75, the leakage inductance 39-3 of the forward transformer, and the magnetizing inductance Lm of the forward transformer are LLC resonant; A load (Load) for receiving and consuming power output through the secondary side of the forward transformer 39; An output voltage detector 151 for detecting a voltage of the load; An output current detection unit 152 for detecting a current of the load; A constant voltage control unit 141 for controlling the output voltage detected by the output voltage detection unit 151 to a constant voltage; A constant current control unit 145 for constant current control of the output current detected by the output current detection unit 152; A cathode of a first diode (D1) connected to the constant voltage control unit (141); A cathode of a second diode D2 connected to the constant current control unit 145; And an optical coupler PH1 connected to an anode of the first diode D1 and an anode of the second diode D2; The output of the constant voltage control unit 141 and the output of the constant current control unit 145 are simultaneously controlled in the constant voltage-constant current mode.

The present invention can be applied to a converter in which the initial starting current is reduced by a variety of modifications by a person having ordinary skill in the art, and the scope of the technology that easily transforms the technology is also recognized as belonging to the scope of the present patent will be.

10: AC power source
20: input rectifier diode
30: Initial starting current reducing section
31: First auxiliary diode
32: Second auxiliary diode
33: third auxiliary diode
34: Power factor improving inductor
34-1: first power factor improving coupling inductor
34-2: second power factor improving coupling inductor
34-3: magnetic coupling
35: smoothing capacitor
36: flyback transformer
36-1: flyback transformer primary side
36-2: Flyback transformer secondary side
37: Main switch
38: Reflux diode
39: Forward transformer
39-1: Forward transformer primary
39-2: Forward transformer secondary side
39-3: Leakage inductance of forward transformer (Llk)
40: Flyback rectifying part
41: Flyback rectifier diode
42: flyback output capacitor
50: Forward rectification part
51: forward rectification diode
52: forward reflux diode
53: Forward output inductor
54: Forward output capacitor
60: 2 switch forward circuit section
61: 2 switch forward primary switch
62: 2 switch forward first antiparallel diode
63: 2 switch forward second main switch
64: 2 switch forward second antiparallel diode
65: 2 switch forward first reflux diode
66: 2 switch forward second reflux diode
70: half bridge circuit part
71: half bridge first main switch
72: half bridge first anti-parallel diode
73: half bridge second main switch
74: half bridge second antiparallel diode
75: Resonant capacitor Cs
80: initial starting current reducing section and switch circuit section
81: Main switch control IC
91: Auxiliary power transformer
91-1: 1st auxiliary power transformer
91-2: Second auxiliary power transformer
95: Rectifier for auxiliary power supply
96: Rectifier diode for auxiliary supply
97: Output capacitor for auxiliary supply
100: Power factor improving converter section
101: first current sensor
102: second current sensor
103: First partial pressure resistance
104: Second partial pressure resistance
110: power factor improving converter power circuit part
120: Power Factor Correction Converter Gate Driver Circuit
130: Power factor improving converter control unit
131: Gate signal generator of the power factor improving converter
132: Output voltage detector of the power factor improving converter
133: first current detector
134: second current detector
140: constant voltage -
141: Constant voltage control unit
142: Constant voltage control comparison ratio
145: Constant current control unit
146: Constant current control comparator
148; Simultaneous control of constant voltage and constant current
150: main transformer
151: Output voltage detector
151-1: First output voltage divider resistor
151-2: Second output voltage dividing resistor
152: Output current detection section
160: input stage filter section
161: Varistor
162: Common Mode noise inductor
163: Differential Mode noise inductor
164: first X-capacitor (first X-Cap)
165: second X-capacitor (second X-Cap)
166: first Y-capacitor (first Y-Cap)
167: second Y-capacitor (second Y-Cap)
170: Snubber circuit
171: Snubber capacitor
172: Snubber resistance
173: Snubber diode
175: Switch bottom current detection resistor
176: Zener diode
180: Main switch control section
200: DC-DC converter unit
201: Bank capacitor
202: the third partial pressure resistance
203: the fourth partial pressure resistance
204: third current sensor
210: DC-DC converter power circuit
220: DC-DC converter gate drive circuit
230: DC-DC converter control section
231: Gate signal generator of the DC-DC converter
232: Output voltage detector of the DC-DC converter
233: a third current detector
300: LED group (Group)
301: first LED group
302: second LED group
303: Third LED group
AC1: 1st AC power
AC2: Second AC power
FG: Frame ground
C1: first capacitor
C2: second capacitor
C21: the 21st capacitor
D1: first diode
D2: second diode
D21: 21st diode
PH1: Photocoupler output
PH2: Photocoupler receiver
R1: first resistance
R2: second resistance
R3: third resistance
R4: fourth resistor
R5: fifth resistor
R11: 11th resistor
R12: resistance 12
R21: 21st resistor
R22: 22nd resistance
Rg1: first gate resistance
Rg2: second gate resistance

Claims (12)

In a converter in which an initial starting current is reduced,
An input rectifier diode 20 connected to the AC power source 10 to rectify the AC power to DC power;
A third auxiliary diode 33 connected to the (+) output of the input rectifier diode 20;
A first power factor improving coupling inductor (34-1) connected to the (-) output of the input stage rectifier diode (20);
A first auxiliary diode 31 connected to one side of the first power factor improving coupling inductor 34-1;
A second power factor improving coupling inductor (34-2) connected to the first auxiliary diode (31);
The first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2) form a magnetic coupling (34-3);
A smoothing capacitor (35) connected between the first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2);
A second auxiliary diode (32) connected to the (+) terminal of the smoothing capacitor (35);
A main transformer 150 connected to a cathode of the second auxiliary diode 32 and a cathode of the third auxiliary diode 33;
A main switch 37 connected between the main transformer 150 and the first power factor improving coupling inductor 34-1;
A load for supplying and discharging power output through the secondary side of the main transformer 150;
A snubber capacitor 171, a snubber resistor 172, and a snubber diode 173 are provided on the primary side of the main transformer 150 in order to reduce surges and noise generated when the main switch 37 is switched. A snubber circuit;
An output voltage detector 151 for detecting a voltage of the load;
An output current detection unit 152 for detecting a current of the load;
A constant voltage control unit 141 for controlling the output voltage detected by the output voltage detection unit 151 to a constant voltage;
A constant current control unit 145 for constant current control of the output current detected by the output current detection unit 152;
A cathode of a first diode (D1) connected to the constant voltage control unit (141);
A cathode of a second diode D2 connected to the constant current control unit 145;
And an optical coupler PH1 connected to an anode of the first diode D1 and an anode of the second diode D2;
Wherein an output of the constant voltage control unit (141) and an output of the constant current control unit (145) are simultaneously controlled by a constant voltage and a constant current. In a converter in which an initial starting current is reduced,
An input rectifier diode 20 connected to the AC power source 10 to rectify the AC power to DC power;
A third auxiliary diode 33 connected to the (+) output of the input rectifier diode 20;
A first power factor improving coupling inductor (34-1) connected to the (-) output of the input stage rectifier diode (20);
A first auxiliary diode 31 connected to one side of the first power factor improving coupling inductor 34-1;
A second power factor improving coupling inductor (34-2) connected to the first auxiliary diode (31);
The first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2) form a magnetic coupling (34-3);
A smoothing capacitor (35) connected between the first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2);
A second auxiliary diode (32) connected to the (+) terminal of the smoothing capacitor (35);
A two switch forward first main switch (61) connected to a cathode of the second auxiliary diode (32);
A main transformer 150 connected to the cathodes of the two-switch-forward first main switch 61 and the third auxiliary diode 33;
A second switch forward second switch (63) connected between the cathode of the third auxiliary diode (33) and the first power factor improving coupling inductor (34-1);
A load for supplying and discharging power output through the secondary side of the main transformer 150;
An output voltage detector 151 for detecting a voltage of the load;
An output current detection unit 152 for detecting a current of the load;
A constant voltage control unit 141 for controlling the output voltage detected by the output voltage detection unit 151 to a constant voltage;
A constant current control unit 145 for constant current control of the output current detected by the output current detection unit 152;
A cathode of a first diode (D1) connected to the constant voltage control unit (141);
A cathode of a second diode D2 connected to the constant current control unit 145;
And an optical coupler PH1 connected to an anode of the first diode D1 and an anode of the second diode D2;
Wherein an output of the constant voltage control unit (141) and an output of the constant current control unit (145) are simultaneously controlled by a constant voltage and a constant current. In a converter in which an initial starting current is reduced,
An input rectifier diode 20 connected to the AC power source 10 to rectify the AC power to DC power;
A third auxiliary diode 33 connected to the (+) output of the input rectifier diode 20;
A first power factor improving coupling inductor (34-1) connected to the (-) output of the input stage rectifier diode (20);
A first auxiliary diode 31 connected to one side of the first power factor improving coupling inductor 34-1;
A smoothing capacitor 35 connected to the first auxiliary diode 31;
A second auxiliary diode (32) connected to the (+) terminal of the smoothing capacitor (35);
A second power factor improving coupling inductor (34-2) connected to the second auxiliary diode (32);
The first power factor improving coupling inductor (34-1) and the second power factor improving coupling inductor (34-2) form a magnetic coupling (34-3);
A first half bridge first main switch 71 connected between the second power factor improving coupling inductor 34-2 and a cathode of the third auxiliary diode 33;
A half bridge second main switch 73 connected between the cathode of the third auxiliary diode 33 and the other side of the first power factor improving coupling inductor 34-1;
A resonant capacitor (Cs) 75 and a forward transformer 39 connected to both ends of the second main switch 73;
The resonant capacitor (Cs) 75, the leakage inductance 39-3 of the forward transformer, and the magnetizing inductance Lm of the forward transformer are LLC resonant;
A load (Load) for receiving and consuming power output through the secondary side of the forward transformer 39;
An output voltage detector 151 for detecting a voltage of the load;
An output current detection unit 152 for detecting a current of the load;
A constant voltage control unit 141 for controlling the output voltage detected by the output voltage detection unit 151 to a constant voltage;
A constant current control unit 145 for constant current control of the output current detected by the output current detection unit 152;
A cathode of a first diode (D1) connected to the constant voltage control unit (141);
A cathode of a second diode D2 connected to the constant current control unit 145;
And an optical coupler PH1 connected to an anode of the first diode D1 and an anode of the second diode D2;
Wherein an output of the constant voltage control unit (141) and an output of the constant current control unit (145) are simultaneously controlled by a constant voltage and a constant current. The method according to any one of claims 1 to 3,
And the load is an LED group (Group) 300. The converter The method according to claim 1 or 2,
Wherein the main transformer (150) comprises a flyback transformer (36) and an auxiliary power source transformer (91). The method according to claim 1 or 2,
Wherein the main transformer (150) comprises a forward transformer (39) and an auxiliary power source transformer (91). delete delete delete delete delete delete

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