KR101380610B1 - Led lamp control circuit compatible type fluorescent lamp - Google Patents

Abstract

The present invention relates to a fluorescent lamp compatible type LED control circuit and, more specifically, to a fluorescent lamp compatible type LED lamp control circuit, which is capable of replacing a fluorescent lamp with an LED lamp without replacing lighting fixtures and ballast stabilizers. The fluorescent lamp compatible type LED lamp control circuit includes: a plurality of LED modules where a plurality of LEDs are connected to each other in series, in parallel, or in series and parallel; a first electrode and a second electrode having two terminals, respectively, to receive AC power; a rectifying unit consisting of two bridge diodes to rectify and output AC power inputted through the first and second electrodes; a transcoil for outputting (+)power outputted through the rectifying unit to a control unit and the LED modules through a first coil; and the control unit for receiving (+)power through the first coil, receiving (-)power through the rectifying unit, outputting voltage required to drive the LED modules, and adjusting a second coil of the transcoil to control the voltage and current of the first coil. [Reference numerals] (32) Voltage and current control unit; (34) Driving and cooperating unit; (36) Constant voltage and constant current sensing unit; (40) LED module

Description

Fluorescent lamp compatible LED lamp control circuit {LED lamp control circuit compatible type fluorescent lamp}

The present invention relates to a fluorescent lamp compatible LED control circuit, and more particularly, to a fluorescent lamp compatible LED lamp control circuit that can be used by replacing the fluorescent lamp with an LED lamp without replacing the luminaire and ballast.

In general, a fluorescent lamp is a device that generates an electric discharge due to a high voltage inside the lamp and the ultraviolet rays generated according to the reaction react with the fluorescent material applied to the inner surface of the lamp to emit visible light.

The fluorescent lamps are classified into FL-, FLR- and FHF-types of which filament electrodes are formed on both sides of the fluorescent lamp, and F-types of FPL, FDL and FML types, which form filament electrodes on one side thereof.

The fluorescent lamp is essentially provided with a ballast in order to apply a high voltage to the fluorescent lamp to generate an electrical discharge, and to maintain a constant current having a negative resistance characteristic after the electrical discharge.

The ballast is largely divided into magnetic type and electronic type. The ballast for magnetic fluorescent lamp is composed of iron core and choke coil, and commercial power passes through the ballast, resulting in phase difference between current and voltage. The electronic ballast for the ballast is used to convert the commercial frequency into a high frequency of several tens of kHz using an internal electronic circuit to turn on the lamp.

1A to 1D are diagrams illustrating a wiring connection relationship between a fluorescent lamp and a ballast.

First, FIG. 1A shows the wiring connection relationship between the fluorescent lamp FL1 and the ballast for magnetic fluorescent lamp MB. The filament electrodes are formed on both sides of the fluorescent lamp FL1 so that the AC power source is magnetic. The closed circuit is connected to the filament electrode on the other side of the magnetic fluorescent lamp FL1 through the filament electrode on the other side of the fluorescent lamp (MB), the fluorescent lamp FL1 and the starter (S), and the operation of the starter (S). | Fluorescent lamp FL1 lights up.

1B illustrates a wiring connection relationship between the U-shaped fluorescent lamp FL2 and the magnetic fluorescent ballast MB, and the filament electrodes are formed on one side of the U-shaped fluorescent lamp FL2, respectively, so that the AC power source is a magnetic fluorescent lamp. And a closed circuit connected to the filament electrode on one side of the U-shaped fluorescent lamp FL2 through the ballast MB, the filament electrode on one side of the U-shaped fluorescent lamp FL2, and the starter S. By operation, the U-shaped fluorescent lamp FL2 is turned on.

Fig. 1C shows the wiring connection relationship between the fluorescent lamp FL1 and the ballast for electronic fluorescent lamps. The filament electrodes are formed on both sides of the fluorescent lamp FL1, so that the AC power supply is used for the electronic fluorescent lamp ballast. It is supplied to the | -shaped fluorescent lamp FL1 through both filament electrodes of the | -shaped fluorescent lamp FL1 via EB), and is lighted.

FIG. 1D illustrates the wiring connection relationship between the U-shaped fluorescent lamp FL2 and the electronic fluorescent ballast (EB), wherein filament electrodes are formed on one side of the U-shaped fluorescent lamp FL2, respectively, so that AC power is supplied to the electronic fluorescent ballast. The light is supplied to the U-shaped fluorescent lamp FL2 through the filament electrodes on one side of the U-shaped fluorescent lamp FL2 via EB.

By the way, the above-described fluorescent lamps (FL1, FL2) has a problem in that the life is short, regardless of the shape of the fluorescent lamps (FL1, FL2) need to be replaced frequently, and the power consumption is high.

On the other hand, LED lamps that emit light when a current is applied have a lower light brightness change rate than other lamps due to low power consumption, high light efficiency, long life, low UV emission and temperature change (temperature change according to season). As it is known, existing fluorescent lamps are being replaced with LED lamps.

At this time, if the accessories of fluorescent lamps including fixtures and ballasts installed are removed and replaced with new LED lamps, the raw materials and installation cost will exceed the profits from replacing LED lamps.

Therefore, only fluorescent lamps should be replaced with LED lamps without replacing the existing luminaires and ballasts.

However, LED lamps are operated by a fairly low DC power supply, whereas the ballast of fluorescent lamps converts commercial AC power into high frequency of several tens of GHz to supply fluorescent lamps to light the fluorescent lamps. LED lamp cannot be turned on.

When the LED lamp is connected to the fluorescent lamp ballast, the LED lamp does not properly handle high frequency or voltage such as the ballast, and causes problems such as the LED lamp not working or being destroyed.

In order to solve this problem, a circuit for stable use by replacing the fluorescent lamp with an LED lamp between the ballast and the LED lamp has been provided. In the related art, a simple bridge rectifier circuit has been solved.

When the above problem is solved by a simple bridge rectifier circuit method, a difference in power consumption of LED lamps according to manufacturers and products of magnetic fluorescent ballasts or electronic fluorescent ballasts has occurred.

In other words, the conventional simple bridge rectifier circuit method does not actively control the fluorescent lamp in response to various output changes of the ballast, so the difference in power consumption is too large for a ballast of any manufacturer, even the power consumption of the conventional fluorescent lamp or the power consumption is too low. As a result, the characteristics of the LED lamp did not meet the slight change in the power consumption.

In addition, the life of the ballast is much shorter than the LED, so when the life of the ballast ends, AC power cannot be used as it is.

In addition, when the other electrode is in contact with the hand while the one electrode is connected to the AC power when the LED lamp is installed and replaced, there is a problem that an electric shock accident occurs because a closed circuit is formed.

On the other hand, Korean Patent Publication No. 10-0949087 discloses an LED lighting device, this prior patent does not reflect the current value output from the LED lamp of the high frequency input only through the ballast of the fluorescent lamp Since the LED lamp is turned on by treating AC power, it does not satisfy the certification criteria of power consumption described above, and there is a problem in that an accident due to electric shock cannot be prevented.

Patent Registration No. 10-0949087 (Notice date March 22, 2010)

The present invention has been made to solve the above-mentioned problems, the ballast is rectified by the high frequency AC power or commercial AC power input through the ballast of the fluorescent lamp and control the LED lamp by reflecting the current value output from the LED lamp Fluorescent lamp compatible LED lamp control circuit that can make the difference in power consumption uniform regardless of the manufacturer or type, and can control the LED lamp by inputting commercial AC power without replacing the ballast when the ballast life is over. The purpose is to provide.

In addition, an object of the present invention is to provide a FET that is connected to the gate through a resistor at the rear end of the rectifier circuit, even if the hand electrode is in contact with the other electrode while the one electrode is connected to the AC power supply, the gate drive voltage is weak, the FET is conducting The present invention provides a fluorescent lamp compatible LED lamp control circuit that can prevent an accident due to electric shock.

Fluorescent lamp compatible LED lamp control circuit according to an embodiment of the present invention for achieving the above object is a plurality of LED modules connected in series, parallel or serially parallel;

First and second electrodes each having two terminals and receiving AC power or commercial AC power output from the fluorescent ballast;

A rectifying unit composed of two bridge diodes to rectify and output AC power input through the first electrode and the second electrode;

A transcoil for outputting (+) power output through the rectifier to a controller and an LED module through a primary coil; And

Receiving (+) power through the primary coil and (-) power through the rectifier, outputting the voltage required to drive the LED module and adjusting the secondary coil of the transcoil to adjust the voltage of the primary coil And a control unit for controlling the current;

.

According to another embodiment of the present invention, a fluorescent lamp compatible LED lamp control circuit includes: an LED module in which a plurality of LEDs are connected in series, in parallel or in parallel;

First and second electrodes each having two terminals and receiving AC power or commercial AC power output from the fluorescent ballast;

A rectifying unit composed of two bridge diodes to rectify and output AC power input through the first electrode and the second electrode;

A transcoil for outputting (+) power output through the rectifier to a controller and an LED module through a primary coil; And

A control unit which receives (+) power through the primary coil and (−) power through the rectifier, outputs a voltage required to drive the LED module and controls the voltage and current of the primary coil;

In addition, a capacitor is connected in series to each of the two terminals of any one of the first electrode and the second electrode is characterized in that the AC power is input to the rectifier through each capacitor.

In addition, the first and second FETs whose gates are connected to the drain and the source through the resistors are respectively provided on the lines for outputting the (+) power and the (-) power at the rear end of the rectifier to form an electric shock prevention part.

The controller may include a constant voltage and constant current sensing unit configured to measure an output voltage and a current of the LED module.

The voltage and current of the primary coil are controlled by adjusting the inductance value of the secondary coil based on the voltage and current measured by the constant voltage and constant current detector connected to the transcoil, or the voltage measured by the constant voltage and constant current detector. And a voltage and current controller which directly controls the voltage and current of the primary coil based on the current value.

Interposed between the constant voltage and constant current detection unit and the voltage and current control unit interlocks the voltage and current control unit and the constant voltage and constant current detection unit, and receives the DC power of (+) and (-) to output the voltage required to drive the LED module. It is characterized by consisting of a drive and an interlock.

According to the above-mentioned means for solving the problem, since the rectified high frequency AC power or commercial AC power input through the ballast of the fluorescent lamp and the LED lamp is controlled by reflecting the current value output from the LED lamp, Regardless of power consumption, LED lamp can be controlled by inputting commercial AC power without replacing ballast.

In addition, a FET is connected to the gate through a resistor at the rear of the rectifier circuit. Even if a hand contacts the other electrode while the one electrode is connected to an AC power source, the gate driving voltage is weak so that the FET is not conducting. It can prevent.

1A to 1D are diagrams illustrating a wiring connection relationship between a general fluorescent lamp and a ballast.
2A and 2B are views illustrating an LED lamp control circuit according to an embodiment of the present invention.
3a to 3f are views showing an embodiment in which the fluorescent lamp is replaced with the LED lamp according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

It is to be noted that the same components of the drawings are denoted by the same reference numerals and symbols as possible even if they are shown in different drawings.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Also, when a part is referred to as "including " an element, it does not exclude other elements unless specifically stated otherwise.

2A is a view showing an LED lamp control circuit according to an embodiment of the present invention.

As shown in the drawing, the electrodes J1 and J2 are configured to include the rectifier 10, the electric shock prevention unit 20, the transcoil TQ, the controller 30, and the LED module 40.

The electrodes J1 and J2 are filament electrodes provided on both sides or one side of the LED lamp, and the first electrode J1 includes a first terminal ① and a second terminal ②, and a second electrode (2). J2) consists of a third terminal ③ and a fourth terminal ④.

The first terminal ① and the second terminal ② of the first electrode J1, the third terminal ③ and the fourth terminal ④ of the second electrode J2 are ballasts for magnetic fluorescent lamps ( MB) is connected to the output side of the electronic fluorescent ballast (EB), or AC power is input through the first electrode (J1) and the second electrode (J2) in connection with a general commercial AC power.

The first terminal ① of the first electrode J1 is connected between the first diode D1 and the third diode D3 connected in series through the first capacitor C1, and the second terminal ② is formed of the first terminal ②. It is connected between the second diode (D2) and the fourth diode (D3) connected in series through the two capacitor (C2), the first diode (D1) and the second diode (D2), the third diode (D3) and the fourth Diodes D4 are interconnected.

The combination of the diodes D1 to D4 constitutes the first bridge rectifier circuit 12a.

In addition, the third terminal ③ of the second electrode J2 is connected between the fifth diode D5 and the seventh diode D7 connected in series, and the fourth terminal ④ is the sixth diode D6 connected in series. And an eighth diode D8, a fifth diode D5, a sixth diode D6, a seventh diode D7, and an eighth diode D8.

The combination of the diodes D5 to D8 constitutes the second bridge rectifier circuit 12b.

In addition, an output side first line L1 of the first diode D1 and the second diode D2 connected between the first bridge rectifying circuit 12a and the second bridge rectifying circuit 12b may be connected to the fifth diode ( The third diode D3 and the fourth diode D4, which are connected to the D5 and the sixth diodes D6, and are connected to each other, are connected to the second line (the output side of the seventh diode D7 and the eighth diode D8). It is connected to L2) to form a double bridge rectifier circuit.

That is, in the present invention, the rectifier 10 includes a double bridge rectifier circuit.

At this time, the connection directions of the diodes D1 to D4 of the first bridge rectifying circuit 12a and the diodes D5 to D8 of the second bridge rectifying circuit 12b are respectively the first electrode J1 and the second electrode J2. Is the same for.

The AC power input to the rectifying unit 10 is rectified through a double bridge rectifying circuit, so that the positive power is output through the first line L1, and the negative power is output through the second line L2.

The first line L1 is connected to the first FET Q1 constituting the electric shock prevention unit 20, and the gate of the first FET Q1 is connected to the first resistor R1 and the second resistor R2. It is connected to the drain and the source.

Similarly, the second line L2 is connected to the second FET Q2 constituting the electric shock prevention unit 20, and the gate of the second FET is drained and sourced through the fourth resistor R4 and the third resistor R3. Is connected to.

Subsequently, the first line L1 of the positive power source is connected to the controller 30 and the LED module 40 through the primary coil TQ1 of the transcoil TQ.

In addition, the second line L2 of the (−) power source is connected to the LED module 40 via the control unit 30.

The control unit 30 is composed of a voltage and current control unit 32, the driving and interlocking unit 34, the constant voltage and constant current detection unit 36, the voltage and current control unit 32 of the transcoil (TQ) The inductance value of the primary coil TQ1 is changed by changing the inductance value of the secondary coil TQ2 connected to the secondary coil TQ2, and the voltage and current flowing through the primary coil TQ1 through the first line L1. Adjust

The driving and interlocking unit 34 is interposed between the voltage and current control unit 32 and the constant voltage and constant current detecting unit 36 to interlock the voltage and current control unit 32 and the constant voltage and constant current detecting unit 36. The LED module 40 is turned on by outputting the rated voltage and current for the LED module 40 from the DC power supply of the first line L1 and the second line L2.

The driving and linking unit 34 may operate the LED lamp 40 by a pulse width modulation (PWM) method, for example, by changing the duty cycle of a clock pulse having a fixed frequency to maintain a constant output voltage. Lights up.

The constant voltage and constant current detection unit 36 measures the voltage and current values output from the LED module 40 and provides the voltage and current control unit 32 through the driving and interlocking unit 34. 32 changes the inductance value of the secondary coil TQ2 of the transcoil TQ based on the voltage and current values provided by the voltage and current control unit 32 to eventually control feedback of the LED module 40.

The LED module 40 is made of a plurality of LEDs are connected in series, parallel or series.

Referring to the operation of the control circuit described above, the AC power source is connected to both or one of the first terminal ① and the second terminal ② of the first electrode J1, and the third terminal of the second electrode J2. When applied to both or either of (③) and the fourth terminal (4), the first bridge rectifier circuit 12a is connected to the first bridge rectifying circuit 12a through both or one of the first capacitor C1 and the second capacitor C2. AC power is supplied to the second bridge rectifier circuit 12b through both or one of the third terminal ③ and the fourth terminal ④.

At this time, AC of several tens of kHz (electronic fluorescent ballast) output through the ballast is generated by the action of continuously charging and discharging the capacitors C1 and C2 connected in series with the first terminal ① and the second terminal ②. In addition to the power supply, 60Hz commercial AC power can be used as input.

The AC power input to the first bridge rectifier circuit 12a and the second bridge circuit 12b is rectified so that the positive power source is supplied through the first line L1, and the negative source power source is supplied to the second line L2. It is input to the first FET Q1 and the second FET Q2 of the electric shock prevention unit 20 through the second FET Q2.

At this time, the driving voltage is applied through the first resistor R1 and the fourth resistor R4 connected to the gates of the first FET Q1 and the second FET Q2 to conduct the first FET Q1 and the second FET Q2. Accordingly, (+) power is supplied to the controller 30 and the LED module 40 through the primary coil TQ1 of the transcoil TG, while (-) power is supplied to the LED module ( 40 is supplied to the LED module 40 is turned on.

At this time, when the AC power having a high frequency of the electronic fluorescent ballast EB having a large change rate of power consumption by company or product is input to the first electrode J1 and the second electrode J2, the flow of the pulse is controlled. Through the constant voltage and constant current sensing unit 36 of the circuit 30 and the driving and interlocking unit 34, the LED is controlled according to the adjustment of the transcoil TQ secondary coil TQ2 of the voltage and current control unit 32. 40) to supply a uniform voltage and current.

For example, when the output current of the LED module 40 measured by the constant voltage and constant current detector 36 is large, the voltage and current controller 32 increases the inductance value of the secondary coil TQ2 of the transcoil TQ. The current flowing in the primary side coil TQ1 is reduced.

On the other hand, when a low frequency magnetic fluorescent ballast or commercial AC power is input to the first electrode J1 and the second electrode J2, the rectified waveform of the low frequency flows, so that the primary coil of the transcoil TQ (TQ1) The current flow is not greatly affected by the control of the secondary coil TQ2 of the transcoil TQ.

Therefore, the voltage and current controller 32 supplies uniform voltage and current to the LED module 40 by controlling the current of the constant voltage and constant current detector 36 and the driving and supply unit 34.

Meanwhile, when the AC power is input through the first electrode J1 and the second electrode J2, the first FET Q1 and the second FET Q2 of the electric shock prevention unit 20 are each connected to a first resistor ( The driving voltage is applied through R1) and the fourth resistor R4.

However, when one of the first electrode (J1) and the second electrode (J2) is plugged in (connected to an AC power supply) and the other electrode is held by hand while installing the LED lamp, the first FET Q1 and the second FET Q2 are connected. A weaker driving voltage than the normal operation is applied to the gate of) so that the first FET Q1 and the second FET Q2 do not conduct, and thus electric shock current does not flow.

Figure 2b is a view showing the LED lamp control circuit according to another embodiment of the present invention.

The difference from the LED lamp control circuit shown in FIG. 2A is that the transcoil TQ is formed of the primary coil TQ1, and directly from the voltage and current controller 32 of the controller 30 to the primary coil TQ1. To control the voltage and current flowing.

That is, the voltage and current controller 32 is connected to the primary coil TQ1 and directly controls the voltage and current flowing through the primary coil TQ1 based on the voltage and current values measured by the constant voltage and constant current detector 36. do.

The remaining configuration or operation is the same as in FIG.

3a to 3f are views showing an embodiment in which the fluorescent lamp is replaced with the LED lamp according to the present invention.

The following LED lamps LL1 and LL2 incorporate the parallel and parallel LED module and LED control circuit shown in Figs. 2A and 2B.

First, FIG. 3A shows the wiring connection relationship between the | shaped LED lamp LL1 and the magnetic fluorescent lamp ballast MB. The filament electrodes (the first electrode of FIG. 2 and the first electrode of FIG. 2 electrodes) are formed respectively, and one terminal of one filament electrode is directly inputted with AC power, and one terminal of the other filament electrode is inputted through a magnetic fluorescent ballast (MB), which was used for a conventional LED lamp. (LL1) lights up.

At this time, even though the other terminal of one filament electrode and the other terminal of the other filament electrode are not connected to each other, the | -shaped LED lamp LL1 is turned on by the control circuit of FIGS. 2A and 2B.

3B illustrates a wiring connection relationship between the U-shaped LED lamp LL2 and the ballast for magnetic fluorescent lamps MB. The filament electrodes are formed on one side of the U-shaped LED lamp LL2, respectively, to form one of the upper filament electrodes. AC power is directly input to the terminal, and one terminal of the lower filament electrode is input through the magnetic fluorescent ballast (MB) used in the conventional LED lamp to light up the U-shaped LED lamp (LL2).

At this time, the U-shaped LED lamp LL2 is turned on by the control circuits of FIGS. 2A and 2B described above even if the other terminal of the one upper filament electrode and the other terminal of the one lower filament electrode are not connected to each other.

Fig. 3c shows the wiring connection relationship between the | shaped LED lamp LL1 and the electronic fluorescent ballast [EB]. Filament electrodes are formed on both sides of the shaped LED lamp LL1, and AC power is used for the existing LED lamp. It is supplied to the | -shaped LED lamp LL1 through both filament electrodes via the electronic fluorescent ballast EB, and is turned on.

FIG. 3D shows the wiring connection relationship between the U-shaped LED lamp LL2 and the electronic fluorescent ballast (EB). Filament electrodes are formed on one side of the U-shaped fluorescent lamp LL2, respectively, and AC power is applied to the existing LED lamp. It is supplied to the U-shaped LED lamp LL2 through one of the upper and lower filament electrodes through an electronic fluorescent ballast (EB) used, and is turned on.

Fig. 3E shows the wiring connection relationship between the | shaped LED lamp LL1 and the commercial AC power supply. The filament electrodes are formed on both sides of the | shaped LED lamp LL1, so that the commercial AC power source is connected to either of the two terminals of the It is supplied to the | LED lamp LL1 through one terminal and turned on.

FIG. 3F shows the wiring connection relationship between the U-shaped LED lamp LL2 and the commercial AC power source. Filament electrodes are formed on the upper and lower sides of the U-shaped fluorescent lamp LL2 so that the commercial AC power source is connected to the two terminals of the filament electrode on one side. It is supplied to the U-shaped LED lamp LL2 through any one of the terminals and turned on.

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, but, on the contrary, And it goes without saying that the invention belongs to the scope of the invention.

10: rectifier (double bridge rectifier circuit) 12a, 12b: bridge rectifier circuit
20: electric shock prevention unit 30: control unit
32: voltage and current controller 34: drive and interlock
36: constant voltage and constant current detection unit 40: LED module
J1, J2: Electrode Q1, Q2: FET
TQ: transcoil

Claims (5)

An LED module in which a plurality of LEDs are connected in series, in parallel or in parallel;
First and second electrodes each having two terminals and receiving AC power or commercial AC power output from the fluorescent ballast;
A rectifying unit composed of two bridge diodes to rectify and output AC power input through the first electrode and the second electrode;
A transcoil for outputting (+) power output through the rectifier to the controller and the LED module through the primary coil to directly drive the LED module by the primary coil; And
Receiving (+) power through the primary coil and (-) power through the rectifier, outputting the voltage required to drive the LED module and adjusting the secondary coil of the transcoil to adjust the voltage of the primary coil And a control unit for controlling the current; Lt; / RTI >
The control unit includes a constant voltage and constant current detection unit for measuring the output voltage and current between the (-) and the ground of the LED module;
A voltage and current control unit connected to the transcoil to adjust the inductance value of the secondary coil based on the voltage and current values measured by the constant voltage and constant current detector to control the voltage and current of the primary coil;
Interposed between the constant voltage and constant current detection unit and the voltage and current control unit interlocks the voltage and current control unit and the constant voltage and constant current detection unit, and receives the DC power of (+) and (-) to output the voltage required to drive the LED module. Fluorescent lamp compatible LED lamp control circuit, characterized in that consisting of a drive and an interlock. An LED module in which a plurality of LEDs are connected in series, in parallel or in parallel;
First and second electrodes each having two terminals and receiving AC power or commercial AC power output from the fluorescent ballast;
A rectifying unit composed of two bridge diodes to rectify and output AC power input through the first electrode and the second electrode;
A transcoil for outputting (+) power output through the rectifier to the controller and the LED module through the primary coil to directly drive the LED module by the primary coil; And
A control unit which receives (+) power through the primary coil and (−) power through the rectifier, outputs a voltage required to drive the LED module and controls the voltage and current of the primary coil; Lt; / RTI >
The control unit includes a constant voltage and constant current detection unit for measuring the output voltage and current between the (-) and the ground of the LED module;
A voltage and current controller connected to the transcoil to directly control the voltage and current of the primary coil based on the voltage and current values measured by the constant voltage and constant current detectors;
Interposed between the constant voltage and constant current detection unit and the voltage and current control unit interlocks the voltage and current control unit and the constant voltage and constant current detection unit, and receives the DC power of (+) and (-) to output the voltage required to drive the LED module. Fluorescent lamp compatible LED lamp control circuit, characterized in that consisting of a drive and an interlock. 3. The method according to claim 1 or 2,
A capacitor is connected in series to each of the two terminals of any one of the first electrode and the second electrode fluorescent lamp compatible LED lamp control circuit, characterized in that the AC power is input to the rectifier through each capacitor. 3. The method according to claim 1 or 2,
The first and second FETs, whose gates are connected to the drain and the source through the resistors, are respectively provided on the lines for outputting the positive power and the negative power at the rear end of the rectifier to form an electric shock prevention part. Type LED lamp control circuit. delete

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