KR101561067B1 - Power supply for LED lighting unit - Google Patents

Abstract

The present invention relates to a power supply device for extending the lifetime of an LED lighting lamp, and more particularly, to a power supply device that substantially shortens the lifetime of the LED lighting lamp by an LED converter having a relatively short lifetime in comparison with the lifetime of the LED lighting lamp LED which can solve the problem that the maintenance cost is increased due to short life span when the tunnel is installed in a tunnel or ceiling where it is difficult to repair, And more particularly to a power supply for extending the life of an illumination lamp.
A power supply device for extending the service life of the LED lighting lamp according to the present invention includes a plurality of LED converters for supplying lighting power to the LED lighting lamp; An external power source to be supplied to one of the plurality of LED converters; And a control unit for controlling the transfer unit.

Description

Technical Field [0001] The present invention relates to a power supply for an LED lighting unit,

The present invention relates to a power supply device for extending the lifetime of an LED lighting lamp, and more particularly, to a power supply device that substantially shortens the lifetime of the LED lighting lamp by an LED converter having a relatively short lifetime in comparison with the lifetime of the LED lighting lamp LED which can solve the problem that the maintenance cost is increased due to short life span when the tunnel is installed in a tunnel or ceiling where it is difficult to repair, And more particularly to a power supply for extending the life of an illumination lamp.

LED has various advantages such as low illuminance, low power consumption, semi-permanent lifetime, and environment-friendly and emotional lighting. Recently, it has become a light source for lighting fixtures, LED lighting is widely used in places.

LEDs are known to have a semi-permanent lifetime, but the ambient environment is under ideal conditions, and in fact, they do not have a semi-permanent lifetime due to heat dissipation problems or overload problems.

Although the lifespan is limited due to factors caused by the surrounding environment, it is considerably long.

When the life span of the LED lighting lamp is about 5 to 6 years, the lifetime of the LED converter that supplies the lighting power to light up the LED lighting lamp is not enough.

Therefore, there is a problem that the LED lighting lamp does not light up, that is, the life is short, because the lifetime of the LED converter that supplies normal or lighting power is short (that is, a failure occurs).

Also, due to the shortened life span, it is difficult to repair the fault due to installation of the tunnel or ceiling on the spot, which increases repair cost.

However, since the lifespan of the LED converter is not yet developed to be equal to or longer than the lifetime of the LED lamp at the current level of technology, the lifetime of the LED lamp is shortened due to the life of the LED converter, There is a pressing need for means to resolve.

[0003] The prior art relating to a power supply device including an LED converter for supplying lighting power to an LED lighting lamp is disclosed in Korean Patent No. 0727354 entitled " Light Emitting Diode Constant Current Pulse Width Modulation Drive Circuit ", Registered Patent No. 0982167 " And a method of operating the LED light source ". The power supply for the LED lighting lamp according to the prior art including the above-mentioned two patents has a long lifetime, but the lifetime of the LED lighting lamp by the power supply (that is, the LED converter) I am not interested in this shortening issue. In other words, there is no way to prolong the life span of LED lights.

The present invention is contrived to solve the problem that the lifetime of the LED lighting lamp is substantially shortened even though the lifespan of the LED converter is short as described above and has a long lifetime. The present invention has a plurality of LED converters capable of lighting one LED lighting lamp , When the LED converter fails, the other LED converter supplies the power to the LED lighting by the changeover unit and the control unit, thereby extending the practical lifetime of the LED lighting lamp and extending the life span of the LED lighting fixture And to provide a power supply device for extending the lifetime of the LED lighting lamp, which can reduce defective maintenance costs for the power supply device.

Another object of the present invention is to provide a power supply for extending the lifetime of a LED lighting lamp with high reliability by maximizing energy efficiency by minimizing power consumption.

According to an aspect of the present invention, there is provided a power supply apparatus for extending the life of an LED lighting lamp,

A plurality of LED converters for supplying lighting power to the LED lighting lamps;

An external power source to be supplied to one of the plurality of LED converters;

And a control unit for controlling the transfer unit.

The control unit

A sensing unit for sensing an external power source supplied to the LED converter connected to the external power source through the transfer unit,

And a driving unit that receives the signal of the sensing unit and drives the transfer unit.

The control unit may further include a delay unit for delaying the signal of the sensing unit to the driving unit,

Wherein the switching unit uses a relay of a magnet switch which is operated by a driving coil and an electromagnetic force generated in the driving coil,

The sensing unit

A current transformer for sensing a current of an external power source supplied to the LED converter,

A comparator for comparing a sensing voltage according to a current sensed by the current transformer with a reference voltage;

And an inverter for inverting the comparison signal of the comparator,

Wherein the driving unit includes a transistor for turning on / off the inverted signal of the inverting to supply or cut off driving power to the driving coil,

The delay unit includes a capacitor charged with the inverting signal of the inverting and turning on and off the transistor with a charged voltage.

The power supply device for extending the service life of the LED lighting lamp according to the present invention has a plurality of LED converters capable of lighting one LED lighting lamp, The other LED converters that are in normal operation can supply the lighting power so that the practical life of the LED lighting lamp is extended and accordingly the maintenance cost of the LED lighting lamp and the power supply is extended to reduce the maintenance cost.

The LED converter is provided separately from the power factor improving unit for improving the energy efficiency and the PWM unit for controlling the switching of the transformer for the rated power source. The LED converter is not driven separately. The power factor improving PWM unit improves the power factor, So that the energy efficiency is maximized and the driving power of the feedback part is supplied from the secondary winding separately wound to the transformer secondary side so that the driving power of the driving power , It protects the converter safely by detecting the overcurrent due to the short circuit and immediately feedbacks it. In addition, the varistor is formed at the input side of the commercial power supply to cut off the surge power, the EMI filter is configured to minimize the conduction noise, Designed to have sufficient structure and minimize radiation noise High reliability.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a power supply for extending the life of an LED lighting lamp according to the present invention; FIG.
FIG. 2 is a circuit diagram of a control unit and a switching unit for sensing and switching the current of the LED converter in FIG. 1;
3 is a schematic configuration diagram of an LED converter according to the present invention.
4 is a specific circuit diagram of Fig.

Hereinafter, a power supply apparatus for extending the life of the LED lighting lamp according to the present invention will be described in more detail with reference to the drawings.

Before describing the present invention in more detail,

While the present invention has been described in connection with certain embodiments, it is obvious that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the numerals of the tens and the digits of the digits, the digits of the tens, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

In the drawings, the components are expressed by exaggeratingly larger (or thicker) or smaller (or thinner) in size or thickness in consideration of the convenience of understanding, etc. However, It should not be.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

As shown in FIG. 1, the power supply device for extending the service life of the LED lighting lamp according to the present invention includes a plurality of LED converters 2A and 2B, transfer parts RE1-A and RE1-B, .

The LED converters 2A and 2B convert an external power supply (usually a commercial power supply of AC 220 V) into a lighting power supply (that is, a rated power supply) suitable for lighting the LED lighting lamp 1,

The changeover units RE1-A and RE1-B are switched so that the external power source is supplied to the LED converter which operates normally among the plurality of LED converters 2A and 2B,

The control unit 4 senses a current supplied to the LED converters 2A and 2B to determine whether the LED converter is faulty. When it is determined that the LED converter is faulty, the control unit 4 determines that the transfer units RE1-A and RE1- Control to supply external power to the other LED converters that are operating.

FIG. 2 shows a circuit diagram for the transfer parts RE1-A and RE1-B and the control part 4 in FIG.

The switches RE1-A and RE1-B are controlled by the control unit so that external power is supplied to any one of the plurality of LED converters 2A and 2B. That is, when a failure occurs in the LED converter to which the external power is supplied by the change-over units RE1-A and RE1-B, the changeover units RE1-A and RE1- So that the external power is supplied to the other LED converter so that the LED light 1 can be continuously lighted.

Relays are used as the change-over units RE1-A and RE1-B. That is, a relay comprising a drive coil RE1-B for generating an electromagnetic force when a power source is inputted and a magnet switch RE1-A for switching operation by an electromagnetic force generated in the drive coil RE1-B is used.

In addition to the relays, the switches RE1-A and RE1-B may be electronic devices such as transistors, triacs, and thyristors having an on-off (switching) function, but these electronic devices have an on- The relay is more stable in the switching operation because the on / off function is physically weak.

The control unit 4 includes a direct current unit 5, a sensing unit 6, a delay unit 8, and a driving unit 9.

The direct current unit 5 converts the AC commercial power source, which is an external power source, into direct current, and supplies the power required for driving the transfer units RE1-A and RE1-B and the control unit 4. [

The direct current unit 5 includes a capacitor C7 and a resistor R7 for controlling the current of the input commercial AC power source, bridge diodes D1 to D4 for full-wave rectifying the external power source, smoothing the full- And a zener diode (ZD1) for making the DC voltage become a constant voltage, that is, a constant voltage.

The sensing unit 6 senses an external power supplied to the LED converter connected to the external power source by the transfer units RE1-A and RE1-B and determines whether the LED converter is faulty.

The sensing unit 6

Current converters L1-A and L1-B for sensing the current of the external power source supplied to the LED converter 2A,

A sense current induced at the secondary side (L1-A) of the current transformers (L1-A and L1-B) is input to the non-inverting terminal and a reference current obtained by dividing the voltage of the direct current portion through the two resistors A comparator U3-A for receiving and comparing the voltage to the inverting terminal,

And an inverter (U3-B) for inverting a comparison signal, which is an output signal of the comparator (U3-A).

The drive unit 9 receives the signal from the sensing unit 6 and drives the transfer units RE1-A and RE1-B so that the external power is supplied to the normally operated LED converter.

The driving unit 9 is turned on and off by an inversion signal which is an output signal of the inverter U3-B so that the driving power of the direct current unit 5 is supplied to or cut off from the driving coil RE1-B of the switching unit And a display LED (LED1) which is turned on and informed when the LED converter has a failure and is switched to another LED converter.

The delay unit 8 receives the signal of the sensing unit 6 from the driving unit 9 with a predetermined time delay so that the LED converter 2A recognizes the failure of the LED converter 2A when the external power source is initially turned on, So that the changeover units RE1-A and RE1-B do not malfunction.

In other words, when the external power source is initially turned on, it takes about 0.6 seconds until the LED illumination light 1 is turned on, that is, until the LED converter is normally operated. The converter can be judged as a failure so that the delay unit 8 transmits the signal of the sensing unit 6 to the driving unit 9 after this time.

The delay unit 8 includes a capacitor C3 which is charged with an inverted signal of the inverting unit U3-B and turns on and off the transistor Q2 of the driving unit with a charged voltage, And a resistor R4 for transferring the inverted signal of the inverter U3-B and determining the charging / discharging speed of the capacitor C3.

The capacitor C3 of the delay unit 8 is supplied with the voltage of the transistor Q2 even when the voltage (i.e., the inverted signal) sufficient to turn on (or turn off) the transistor Q2 in the inverter U3- And turns on the transistor Q2 until the voltage that can turn on the transistor Q2 is charged.

Hereinafter, the operations of the switching unit and the control unit will be schematically described on the assumption that two LED converters are provided as shown in FIG.

First, before the external power source is turned on, the magnet switch RE1-A of the relay as the transfer unit is connected to the primary LED converter 2A.

The current transformers L1-A and L1-B sense the current flowing in the primary LED converter 2A, and the comparator U3-A detects the current flowing in the primary LED converter 2A if the primary LED converter 2A is normal when the external power source is turned on. (U3-B) outputs a low signal as an inverted signal, so that the transistor (Q2) maintains the turn-off state and the drive coil The driving power source is not applied to the display elements RE1-B, and the display LED (LED1) is also not turned on.

At this time, the comparator U3-A outputs a low signal because the intensity of the current sensed by the current converters L1-A and L1-B is low at the initial stage of the external power supply, and the inverter U3- The external power supplied within the delay time is stabilized by delaying the transfer of the high signal (that is, the signal capable of turning on the transistor Q2) to the transistor Q2 for a predetermined time even if the signal is outputted In other words, when the LED converter is normal, the transistor Q2 is maintained in the turned-off state, and the drive power is applied to the drive coils RE1-B of the relay as the change- .

If the primary LED converter 2A is abnormal when the external power source is turned on, that is, if the primary LED converter 2A is faulty, it is applied to the primary LED converter sensed by the current converters L1-A and L1- The comparator U3-A outputs a low signal as a comparison signal, the inverter U3-B outputs a high signal as an inverted signal, and the comparator U3- When the delay time of the unit 8 elapses, a high signal turns on the transistor Q2, and when the transistor Q2 is turned on, the driving power of the direct current unit 5 turns on the relay driving coil RE1 -B) and the magnet switch RE1-A is switched to the secondary LED converter 2B so that the external power is supplied to the secondary LED converter 2B and at the same time the driving power is supplied to the LED LED1 And is turned on in red.

Hereinafter, the LED converters 2A and 2B according to the present invention will be described in more detail with reference to FIGS. 3 to 5. FIG.

For reference, some of the symbols (reference numerals) of the electronic components used in the circuit diagram of the LED converter may be the same as the symbols (reference numerals) of the electronic components used in Figs. 1 and 2, The preferences of the electronic devices to be used are unrelated to the preferences of the electronic devices of FIGS. 1 and 2.

3 and 4, the LED converter includes an EMI filter 10, a rectifier 20, a power factor improving PWM unit 30, a transformer T1, a direct current unit 40, a feedback unit 50, , A driving power supply unit (60), and the like.

Referring to FIG. 4, a fuse F1 for protecting the converter by interrupting the overcurrent when the overcurrent is inputted to the commercial power supply is connected to the input side to which the commercial power is input, and a fuse F1 for clamping the instantaneous overvoltage And a varistor (MOV1) for protecting the converter is connected.

The EMI filter 10 is connected to the output side of the fuse F1 and the varistor MOV1 to remove a conductive noise included in a commercial power source.

The EMI filter 10 includes two line filters LF1 and LF2 on both sides and capacitors C3 and C10 provided on output sides of the two line filters LF1 and LF2 and two line filters LF1 and LF2, And the intermediate point between the two capacitors C1 and C2 connected in series is grounded to flow the conductive noise included in the commercial power supply to the ground.

The rectifier 20 performs full-wave rectification of the commercial power output from the EMI filter 10 and converts it into a pulsed power supply.

The rectifying unit 20 includes bridge diodes D1 to D4.

The transformer (T1) transforms the pulsating current output from the rectifying unit (20) and outputs a rated power having improved power factor.

The power factor improving PWM unit 30 controls the switching of the transformer so as to improve the power factor and output the rated power.

The power factor improving PWM unit 30

A switching device (Q1) for turning on and off the transformer (T1)

A control unit U1 for controlling the switching of the switching device Q1,

Start resistors R2 and R24 and a capacitor C9 for providing a start voltage for initial operation of the control unit U1,

R2, R3, and C6 that sense the voltage waveform of the output pulsating current of the rectifying unit 20 and provide the detected voltage waveform to the control unit U1,

An auxiliary coil t1 wound on the primary side of the transformer T1 and magnetically coupled thereto,

Driving power units R28, C21, ZD1 and D6 for converting a voltage induced in the auxiliary coil t1 to a driving power source and providing the voltage to the control unit U1,

 A current sensing unit R13 for sensing a current induced by the switching of the transformer T1 from the auxiliary coil t1 and sensing a zero point where the current intensity is zero and providing the zero point to the control unit U1;

Snares (D9, R12, C11) for limiting and protecting the intensity of counter electromotive force induced on the primary side of the transformer (T1)

(R5, 7, 8, 9, 10, 11, 14, C8, etc.) connected to drive the control unit (U1).

The control unit U1 controls the switching of the switching device Q1 so that the waveform of the current induced in the transformer T1 matches the waveform of the voltage output from the rectifier 20, And the current is in phase to improve the power factor.

More specifically, the control unit U1 controls the voltage of the output pulsating current source of the rectifier unit 20 sensed by the voltage sensing units R1, R23, R3, and C6, The switching element Q1 is switched on and off at a low frequency and the switching element Q1 is switched on and off at a relatively high frequency at the point of time when the voltage is weak, The voltage waveform and the period are the same and the shapes are matched to improve the power factor.

Referring back to FIG. 5,

When the waveform of the one period voltage PV output from the rectifying unit 20 and detected by the voltage sensing units R1, R23, R3, and C6 is the same as shown in the drawing,

At the time when the voltage waveform PV starts, the control unit U1 shortly turns off the switching element Q1 after turning on the switching element Q1,

The control unit U1 is turned on at a time point at which the intensity of the current induced by the transformer T1 is detected by the current sensing unit R13, Turns on the switching element Q1 and then turns off. At this time, since the voltage intensity of the voltage waveform is increased earlier than that before, the turn-off period is slightly longer, that is, Lt; / RTI >

Thus, the turn-on / turn-off period (i.e., the period) is turned on at each time point when the zero point is sensed by the current sensing unit R13 and is proportional to the voltage intensity at that time, When the turn-off period is long (i.e., switched to low frequency) and the turn-off period is gradually shortened (i.e., switched to high frequency) while going to both sides, the current Pi ), The waveform of the triangular waveform is the same as that of the triangular waveform, and the total current (PI) waveform of the average value connecting the current Pi waveforms has the same period and the same waveform as the voltage PV waveform, And the current (PI) are in phase and the power factor is improved.

The power factor of the pulsating power source improved by the present invention reaches 95%, and the power factor can be improved close to perfection.

The direct current unit 40 directs the output power induced on the secondary side of the transformer T1 to direct current and supplies the direct current to the load LED (L).

The direct current unit 40 includes diodes D7 and D8 for rectifying the output power of the transformer T1 and capacitors C5 and C12 and C17 for smoothing and directing the output power of the transformer T1 and a transformer T1 at the turn- And includes a resistor R26 and a capacitor C18 as a snubber that protects and protects the secondary from overvoltage.

And a line filter (LF3) for removing noise from a rated power supplied as an LED load is provided on the output side of the direct current part (40).

The feedback unit 50 senses the voltage and current output from the direct current unit 40, that is, the LED (L) load, and transmits the sensed voltage and current to the control unit U1 of the power factor improving PWM unit 30, The control unit U1 controls the switching of the switching element Q1 so that the constant and stable rated power (constant voltage and / or constant current) can be supplied to the LED load.

The feedback unit 50

A photocoupler P1 for feedback-transmitting a voltage and a current signal sensed by turning on and off to the control unit U1,

An overvoltage sensing Zener diode ZD2 for turning on the photocoupler P1 when the output voltage of the DC part 40 exceeds the reference voltage, that is, sensing the output voltage of the DC part 40,

An overcurrent sensing resistor R22 for sensing the output current of the direct current unit 40,

A comparator U2-A for turning on the photocoupler P1 when the current sensed by the overcurrent sensing resistor R22 exceeds a reference current,

A variable resistor VR1 for setting a reference current of the comparator U2-A, and peripheral elements U3, C16, R18, and the like.

The driving power supply unit 60 supplies driving power to the comparator U2-A of the feedback unit 50. [

The driving power supply unit 60 includes an auxiliary winding t2 magnetically coupled to a secondary side of the transformer T2, a diode D10 rectifying a voltage induced in the auxiliary winding t2, And a capacitor C19 and a resistor R27 for supplying the driving power to the U2-A.

Finally, in order to increase the illumination efficiency, it is preferable that the LED uses a high-brightness chip LED and a reflective coating is applied to the surface of the PCB on which the high-brightness chip LED is mounted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Should be construed as falling within the scope of protection of the present invention.

10: EMI filter 20: rectification part
30: Power factor improving PWM unit 40: DC part
50: feedback section 60: driving power supply section
T1: Trance

Claims (4)

A plurality of LED converters for supplying lighting power to the LED lighting lamps;
An external power source to be supplied to one of the plurality of LED converters;
And a control unit for controlling the switching unit. The power supply unit extends the lifetime of the LED lighting lamp,

A sensing unit for sensing an external power source supplied to the LED converter connected to the external power source through the transfer unit,
A driving unit for receiving the signal of the sensing unit and driving the transfer unit;
And a delay unit for delaying and transmitting a signal of the sensing unit to the driving unit,

Wherein the switching unit uses a relay of a magnet switch which is operated by a driving coil and an electromagnetic force generated in the driving coil,

The sensing unit
A current transformer for sensing a current of an external power source supplied to the LED converter,
A comparator for comparing a sensing voltage according to a current sensed by the current transformer with a reference voltage;
And an inverter for inverting the comparison signal of the comparator,

Wherein the driving unit includes a transistor for turning on / off the inverted signal of the inverting to supply or cut off driving power to the driving coil,

Wherein the delay unit includes a capacitor charged with the inverting signal of the inverting and turning on and off the transistor with a voltage to be charged. The method according to claim 1,
The transformer T1 includes a transformer T1 transforming the pulsating current power output from the rectifying section,
A power factor improving PWM unit 30 for controlling the switching of the transformer so as to improve the power factor and output the rated power,
A direct current section 40 for converting an output power source induced on the secondary side of the transformer T1 into a direct current and supplying the direct current to the LED L as a load,
A feedback unit 50 for sensing the voltage and current output from the direct current unit 40 and transmitting the detected voltage and current to the control unit U1 of the power factor improving PWM unit 30,
Further comprising a driving power supply unit (60) for supplying driving power to the comparator (U2-A) of the feedback unit (50)

The power factor improving PWM unit 30
A switching device (Q1) for turning on and off the transformer (T1)
A control unit U1 for controlling the switching of the switching device Q1,
Start resistors R2 and R24 and a capacitor C9 for providing a start voltage for initial operation of the control unit U1,
R2, R3, and C6 for sensing the voltage waveform of the output pulsating current source of the rectifying unit and providing the voltage waveform to the control unit U1;
An auxiliary coil t1 wound on the primary side of the transformer T1 and magnetically coupled thereto,
Driving power units R28, C21, ZD1 and D6 for converting a voltage induced in the auxiliary coil t1 to a driving power source and providing the voltage to the control unit U1,
A current sensing unit R13 for sensing a current induced by the switching of the transformer T1 from the auxiliary coil t1 and sensing a zero point where the current intensity is zero and providing the zero point to the control unit U1;
Snares (D9, R12, C11) for limiting and protecting the intensity of counter electromotive force induced on the primary side of the transformer (T1)
(R5, 7, 8, 9, 10, 11, 14, C8, etc.) connected to drive the control unit (U1)

The direct current part (40)
Diodes D7 and D8 for rectifying the output power of the transformer T1, capacitors C5, C12 and C17 for smoothing and direct current,
A resistor R26 and a capacitor C18 as a snubber for limiting and protecting the overvoltage from being induced in the secondary side of the transformer T1 at the time of turning on and turning off,
And a line filter (LF3) for removing noise from the rated power supplied to the LED load,

The feedback unit 50
A photocoupler P1 for feedback-transmitting a voltage and a current signal sensed by turning on and off to the control unit U1,
A zener diode ZD2 for turning on the photocoupler P1 when the output voltage of the direct current unit 40 exceeds a reference voltage,
An overcurrent sensing resistor R22 for sensing the output current of the direct current unit 40,
A comparator U2-A for turning on the photocoupler P1 when the current sensed by the overcurrent sensing resistor R22 exceeds a reference current,
A variable resistor VR1 for setting a reference current of the comparator U2-A and peripheral elements U3, C16, R18, etc.,

The driving power supply unit 60
A diode D10 for rectifying a voltage induced in the auxiliary winding t2 and a diode D10 for smoothing the voltage to be supplied to the comparator U2-A as a driving power source And a capacitor (C19) and a resistor (R27) for supplying power to the LED lamp. delete delete

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