KR100372013B1 - Electronic ballast - Google Patents

Abstract

The present invention includes a feedback circuit (310; 310 ') for controlling the power supply of the chip 350 for controlling the oscillator in order to efficiently protect the ballast in the event of overvoltage or lamp failure, and the upper terminal of the DC voltage supply unit The control terminal of the switching element Q1, which is inserted between the power supply terminals of the chip, is connected to one terminal of the lamp. When the lamp is incapable of controlling the switching element, the DC voltage is not applied to the chip so that the chip operates. The control terminal Vdet of the chip is connected to the upper potential terminal of the DC voltage through the resistor R7 and the output control line of the protection circuit unit 500; 500 'is connected to the control terminal so that the output of the lamp unit is In the case of an abnormal voltage, the lamp driver is shut down and the input overvoltage detector 320 includes a switch terminal of the voltage divider resistors R13 and R14 inserted between the upper potential terminal and the ground terminal and a switch of the protection circuit portion. Including the constant voltage element ZD3 inserted in the reverse direction between the elements (Q2) and configured to shut down the chip by switching the switching element (Q2) when the supply voltage is an overvoltage, the potential of the control terminal at the overvoltage below the reference value Dropping, and when the lamp is disabled by the feedback circuit unit 310 detects this and cuts off the voltage supply of the IC enables efficient protection of the ballast circuit.

Description

Electronic ballast {ELECTRONIC BALLAST}

TECHNICAL FIELD The present invention relates to the improvement of an electronic ballast, and more particularly, to an electronic ballast for protecting the ballast efficiently in the event of an overvoltage or a lamp failure.

Electronic ballasts contain a starting semiconductor element in the ballast, which preheats the electrode with its switching action or electrode heating winding and starts the lamp by the semiconductor switching action, while the lamp is heated by the lamp current and the electrode heating winding during lighting. As the ballast used in the circuit method, there are self-excited equations oscillated by its own LC resonant circuit, and the equations relating to the present invention using a separate oscillator.

Electronic ballasts have a number of advantages over conventional ballasts, but have weaknesses in voltage fluctuations and surge voltages, and therefore must have built-in protection circuits.

An example of a strike-type electronic ballast employing an oscillating IC chip will be described with reference to FIG.

The conventional electronic ballast as shown in FIG. 1 includes a voltage stabilizer 100 including a fuse, a capacitor C1-C4, and a transformer LF1-LF3 to stabilize the voltage of an AC power source. . The AC voltage stabilized in the voltage stabilizer is full-wave rectified by the rectifier 200 formed of the bridge diodes D1-D4, and is applied to the lamp driver 300.

The lamp driving unit includes a smoothing circuit composed of resistors R1 and R2 and a capacitor C7, and the DC voltage smoothed by the smoothing circuits R1, R2 and C7 is applied to the VCC terminal (No. 8 terminal) of the IC 350. ) To supply the operating power to the IC. For example, the IC may use a KA7541 chip.

Since the IC has eight chip terminals, the DC voltage is applied to the control terminal Ldet, which is the fourth terminal, through the resistor R7. The soft start capacitor connection terminal (terminal 1) and the soft start resistor connection terminal (terminal 3) are connected to the ground terminal through a capacitor C9 and a resistor R8, respectively. Will determine the initial frequency and phase for a soft start. The timing capacitor connection terminal, which is terminal 2, is connected to ground through another capacitor C8, and the capacitor C8 is periodically charged and discharged to generate a sawtooth waveform that determines the oscillation frequency. Terminal 5 is the ground terminal, and terminals 7 and 8 are the output terminals. The output terminal is connected to the input side of the oscillator OSC, and the first output side of the oscillator is connected to the gate terminal of the first switching element MOSFET Q3 and the connection terminal of the first and second switching elements through a resistor R9. The second output side is connected to the gate terminal and the ground terminal of the MOSFET Q4 which is the second switching element through the resistor R10. Thus, the oscillator oscillates at a constant frequency to periodically switch the switching elements. One terminal of the first switching element Q3 is connected to the output side of the rectifying unit, and one terminal of the second switching element is grounded. The other terminals of the first and second switching elements are connected to each other, and the connection terminal is connected to one side of the lamp LAMP in the lamp unit 400 again through one winding of the transformer PT1. The other side of the lamp LAMP is connected to the output terminal and the ground terminal of the rectifier 200 through the capacitors C5 and C6, respectively, and both ends of the lamp are connected through the capacitor C13 for impedance and resonance adjustment. One side of the capacitor C13 is connected to the connection terminals of the current control resistors R1 and R2 and the smoothing capacitor C7 through the resistor R3.

On the other hand, the secondary winding of the transformer PT1 is also connected to the connection terminals of the current control resistors R1 and R2 and the smoothing capacitor C7 through the diode D5 and the resistor R6, and the diode D6. And a protection circuit unit 500 through a resistor R12. The other side of the resistor R12 is connected to the base side of the switching transistor Q2 through the constant voltage diode ZD2 connected in the reverse direction, and in parallel thereto, the RC parallel circuits R11 and C12 are connected to the ground. . The switching transistor Q2 is of emitter ground type, and the base side and the collector side are grounded through the capacitors C11 and C10, respectively, and the collector side is connected to the Vcc terminal of the IC chip 350.

Therefore, when the output voltage to the lamp is greater than or equal to a predetermined value, the constant voltage diode ZD2 breaks down to turn on the switching transistor Q2, and eventually the Vcc terminal of the IC chip 350 is grounded to drive the circuit. By stopping the operation, the driving circuit is protected from the overvoltage on the output side.

However, the conventional ballast has the following various problems.

First, for example, the lamp driving unit is operated even when the lamp is disabled, such as when there is no lamp, and has a problem of power loss due to the standby power operating constantly and the socket melted by heating the socket around the filament. In addition, since the protection circuit unit 500 is connected to the Vcc terminal of the IC chip for control, it is necessary to control the high voltage (9-30 V) of the Vcc terminal. The elements C10 and C11 must have a large parameter value, which is not preferable in view of the efficiency of power consumption of the entire ballast. In addition, there is a problem that it is difficult to effectively shut down the circuit operation when the input voltage is high.

The present invention is intended to solve the above problems, and a first object of the present invention is to stop the operation of the ballast when the lamp is disabled.

Further, a second object of the present invention is to easily shut down the lamp driving circuit at the time of lamp output overvoltage.

In addition, a third object of the present invention is to easily shut down the lamp driving circuit during an input voltage overvoltage.

Further objects and effects of the present invention will become more apparent from the following detailed description of the invention described with reference to the accompanying drawings.

1 is a circuit diagram of a conventional electronic ballast.

2 is a circuit diagram of an electronic ballast according to a first embodiment of the present invention.

3 is a circuit diagram of an electronic ballast according to a second embodiment of the present invention.

4 is a circuit diagram of an electronic ballast according to a third embodiment of the present invention.

5 is a circuit diagram of an electronic ballast according to a fourth embodiment of the present invention.

6 is a circuit diagram of an electronic ballast according to a fifth embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: voltage stabilizer 200: rectifier

300, 300 ': lamp driving part 310, 310': feedback circuit part

320: input overvoltage detection unit 400, 400 ': lamp unit

500: protection circuit

An electronic ballast which is an aspect of the present invention for achieving the above object includes a DC voltage supply unit (100, 200; 100 ', 200'), a lamp unit (400; 400 '), and a power supply of the DC voltage supply unit. And a lamp driver 300 (300 ') for driving the lamp (LAMP) of the lamp unit and a protection circuit unit (500; 500') for controlling the operation of the lamp driver when the output of the lamp unit is an abnormal voltage. An electronic ballast comprising: an oscillator (OSC) for supplying a high frequency operating current to the lamp; A chip (350) connected to a power supply (Vcc) terminal to an upper potential terminal of the supplied DC voltage to control the oscillator; And a feedback circuit unit 310 (310 ') for controlling the supply power of the chip. Includes, wherein the feedback circuit unit, the switching element Q1 is inserted between the upper terminal of the DC voltage supply unit and the power supply terminal of the chip, the control terminal of the switching element is one terminal of the lamp And the lamp controls the switching element when the lamp is disabled so that the DC voltage is not applied to the chip so that the chip stops operating.

An electronic ballast, which is another aspect of the present invention, is oscillated by the power of the DC voltage supply unit 100, 200; 100 ', 200', the lamp unit 400; 400 ', and the DC voltage supply unit, and the lamp of the lamp unit is controlled. In the electronic ballast comprising a lamp driver (300; 300 ') for driving (LAMP) and a protection circuit unit (500; 500') for controlling the operation of the lamp driver when the output of the lamp unit is an abnormal voltage, An oscillator (OSC) for supplying a high frequency operating current to the lamp; And a chip 350 connected to a power supply (Vcc) terminal to an upper potential terminal of the supplied DC voltage to control the oscillator. The control terminal Vdet of the chip is connected to the upper potential terminal of the DC voltage through a coupling resistor R7, and the output control line of the protection circuit unit 500; It is connected to a control terminal, characterized in that the lamp driving unit is shut down when the output of the lamp unit is an abnormal voltage.

An electronic ballast, which is another aspect of the present invention, is a lamp driving unit which oscillates by the power of the DC voltage supply units 100 and 200, the lamp unit 400, and the DC voltage supply unit to drive the lamp LAMP. An electronic ballast including a protection circuit unit 500 for controlling the operation of the lamp driver when the output of the lamp unit is an abnormal voltage; an oscillator for supplying a high frequency operating current to the lamp; A chip (350) connected to a power supply (Vcc) terminal to an upper potential terminal of the supplied DC voltage to control the oscillator; And an input overvoltage detector 320 for detecting whether the supplied DC voltage is overvoltage; The input overvoltage detector 320 may include voltage divider resistors R13 and R14 inserted between the upper potential terminal and the ground terminal, a connection terminal of the voltage divider resistor, and a switching element of the protection circuit unit 500. And a constant voltage element ZD3 inserted in a reverse direction between Q2), and switching the switching element Q2 to shut down the chip when the supply voltage of the upper terminal of the DC voltage is overvoltage.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. For the sake of simplicity of description, elements having the same functions as in the conventional ballast circuits in the drawings are given the same reference numerals and symbols, and detailed descriptions are omitted.

First, the electronic ballast according to the first embodiment of the present invention will be described with reference to FIG.

As shown in FIG. 2, the electronic ballast according to the first embodiment of the present invention is also the voltage stabilizer 100, the rectifier 200, the lamp unit 400 and the protection circuit unit in the same manner as the conventional electronic ballast of FIG. It has a 500, in addition to the transformer (PT1) for connecting to one terminal of the lamp (LAMP) of the lamp unit for detecting the output voltage and the capacitors (C5, C6) connected to the other terminal of the lamp.

However, in the ballast of FIG. 2, the lamp driver 300 alternately turns on / off according to the smoothing circuits R1, R2, and C7, the oscillator OSC for supplying a high frequency operating current to the lamp, and the operation of the oscillator. In addition to the MOSFETs Q3 and Q4 as repetitive off-reverse switching elements and the chip 350 for controlling the oscillator, a power supply (Vcc) terminal is connected to the upper potential terminal of the supplied DC voltage to supply the power supply of the chip. It further has a feedback circuit unit 310 for controlling.

That is, the feedback circuit portion 310 is inserted between the resistors R1 and R2 as the current control element and the capacitor C7. The feedback circuit section includes a transistor Q1 as a switching element between the resistors R1 and R2 corresponding to the terminal for supplying the DC voltage and the terminal of the smoothing capacitor C7, which is also the power supply (Vcc) terminal of the chip. Is made by inserting. The base side of the transistor Q1 corresponding to the control terminal of the switching element is connected to one terminal of the lamp (for example, the connection terminals of the capacitors C5 and C6) via the resistor R4. At the same time, it is preferable that the constant voltage diode ZD1 is connected to the ground in the reverse direction to the base of the transistor. The remaining part is the same as the conventional ballast circuit of FIG.

Therefore, in the normal operation of the lamp, since the 'high' signal is applied to the base terminal of the transistor Q1 and is in the 'on' state, the driving voltage is supplied to the chip like a conventional ballast, but the lamp is not connected to the socket. When the lamp is disabled, the base terminal of the transistor Q1 becomes 'low' and 'turns off' to a 'off' state. Thus, the DC voltage of the smoothing circuit part is not applied to the chip and the chip stops operating. Done. Therefore, it is possible to solve the problems of the prior art that the lamp driving unit is operated even when the lamp is not available to heat and melt the socket around the filament and reduce the loss power caused by standby power.

Next, the electronic ballast according to the second embodiment of the present invention will be described with reference to FIG.

As shown in FIG. 3, the electronic ballast according to the second embodiment of the present invention also has the same voltage stabilizer 100, rectifier 200, lamp unit 400, and protection circuit unit as in the conventional electronic ballast of FIG. It has a 500, in addition to the transformer (PT1) for connecting to one terminal of the lamp (LAMP) of the lamp unit for detecting the output voltage and the capacitors (C5, C6) connected to the other terminal of the lamp. In addition, the lamp driver 300 also alternates with the current control and smoothing circuit (R1, R2, C7), the oscillator (OSC) for supplying a high frequency operating current to the lamp, and the operation of the oscillator, similar to the conventional ballast. MOSFET (Q3, Q4) as a switching element to repeat the on / off reversely, and a power supply (Vcc) terminal is connected to the upper potential terminal of the supplied DC voltage to control the oscillator (350).

However, in the ballast of Fig. 3, the collector side signal of the transistor Q2, which is an output control signal of the switching element of the protection circuit portion, is not connected to the Vcc terminal of the chip but to the control terminal (Ldet terminal) of the chip.

That is, in the lamp driver 300, the connection terminals of the resistors R1 and R2 of the oscillator power supply circuits R1, R2 and C7 and the capacitor C7 are connected to the control terminal of the chip 350 through the resistor R7. Ldet terminal). The remaining part is the same as the conventional ballast circuit of FIG.

Therefore, when the operating voltage of the lamp detected by the transformer PT1 is normal, the transistor is connected in the opposite direction to the constant voltage diode ZD2 at the base end of the transistor Q2, which is a switching element of the protection circuit 500, so that no current flows. Q2) is in an 'off' state, and therefore, a voltage higher than a predetermined voltage (for example, 2V) is applied to the control terminal of the chip, so that the chip operates normally. However, when the operating voltage of the lamp detected by the transformer PT1 is greater than or equal to a predetermined voltage, the constant voltage diode ZD2 causes a breakdown and causes a current to flow through the base end of the transistor Q2 which is a switching element of the protection circuit 500. The transistor Q2 is turned on, so that the chip's control terminal is applied with a voltage less than 2V (ie 0.7V) to shut down the chip.

Conventionally, since the output control signal of the protection circuit is connected to the Vcc terminal of the chip, it is difficult to stop the operation of the chip easily because, for example, a voltage of 9V or more must be controlled. Further, accordingly, since the elements having a large parameter value should be used as elements of the capacitor of the protection circuit or the protection circuit of the resistors, there is a problem that the power consumption of the ballast itself is large. However, in the ballast of Fig. 3, it is sufficient to control a voltage of a lower voltage (exactly 2V, for example), so that overvoltage control can be performed more easily than in the prior art of Fig. 1.

Next, the electronic ballast according to the third embodiment of the present invention will be described with reference to FIG.

As shown in FIG. 4, the electronic ballast according to the third embodiment of the present invention also has the same voltage stabilizer 100, rectifier 200, lamp unit 400, and protection circuit unit as in the conventional electronic ballast of FIG. It has a 500, in addition to the transformer (PT1) for connecting to one terminal of the lamp (LAMP) of the lamp unit for detecting the output voltage and the capacitors (C5, C6) connected to the other terminal of the lamp.

However, in the ballast of FIG. 4, the lamp driver 300 alternately turns on / off according to the smoothing circuits R1, R2, and C7, an oscillator OSC for supplying a high frequency operating current to the lamp, and an operation of the oscillator. In addition to the MOSFETs Q3 and Q4 as repeating off-reversely, and a power supply (Vcc) terminal connected to the upper potential terminal of the supplied DC voltage, the output terminal of the rectifier is connected to the chip 350 for controlling the oscillator. The electronic device further includes an input overvoltage detector 320 for detecting whether an input voltage between the ground terminals is overvoltage.

That is, in the input overvoltage detector 320, a series circuit of voltage divider resistors R13 and R14 is inserted between the upper potential terminal (one terminal of the resistors R1 and R2 of the smoothing circuit) and the ground terminal of the rectifier. A constant voltage element (for example, constant voltage diode ZD3) is inserted in the reverse direction between the connection terminal and the base terminal of the transistor Q2 of the protection circuit part 500. At this time, the detection voltage of the connection point of the divided resistors R13 and R14 of the input overvoltage detector 320 is set to about 36V when the input voltage determines that the voltage is about 300V or more. The remaining part is the same as the conventional ballast circuit of FIG.

Therefore, when the input voltage is normal, the divided voltages of the divided resistors R13 and R14 are connected to the base terminal of the transistor Q2, which is the switching element of the protection circuit 500, in the opposite direction to the constant voltage diode ZD3, so that no current flows. Q2) is in an 'off' state, and therefore, a voltage higher than a predetermined voltage (for example, 2V) is applied to the control terminal of the chip, so that the chip operates normally. However, when the input voltage is greater than or equal to the predetermined voltage, the constant voltage diode ZD3 causes a breakdown and a current flows through the base terminal of the transistor Q2, which is a switching element of the protection circuit 500, so that the transistor Q2 is turned on. In this state, the control terminal of the chip is applied with a voltage less than 2V (that is, 0.7V) to shut down the chip.

That is, when the overvoltage input is cut off by using a conventional varistor, the varistor may be destroyed when the overvoltage input is over 380 V. When the input voltage returns to the normal voltage again, the switchboard switch is turned off and then on. However, according to the electronic rectifier according to the third embodiment of the present invention, it has a reset function automatically, and since the existing protection circuit is used, the overvoltage of the input voltage is added by adding a simple configuration to the existing circuit. Efficient ballast circuit protection against

The electronic ballast of the form combining the first to third embodiments of the present invention is also possible. First, the electronic ballast of the form combining the features of the first and second embodiments is effective in the case of an abnormality in the output portion. It is possible to configure the driving unit to stop the operation. That is, when the lamp is disabled, the feedback circuit unit 310 detects this and cuts off the supply of the driving voltage of the IC to protect the lamp. When the output voltage is higher than the allowable value, the protection circuit unit 500 operates to operate the IC. Since the IC is shut down even with a small voltage of 350, efficient handling can be performed in the event of an abnormality in the output unit.

In addition, according to the electronic ballast of the form in which the second and third embodiments of the present invention are combined, it is possible to effectively protect the ballast when the input voltage or the output voltage is an overvoltage. That is, if the input voltage is an overvoltage, the input overvoltage detector 320 detects this, and if the output voltage is an overvoltage, the protection circuit detects it and turns on the switching element Q2 to low voltage the control terminal of the IC chip. Since it is possible to control at a low voltage, there is an advantage that the components of the protection circuit 500 itself can also be composed of elements having a small parameter value.

In addition, according to the electronic ballast of the type combining the third and first embodiments of the present invention, it is possible to protect the circuit by cutting off the driving (Vcc) voltage of the IC when the input / output voltage is an abnormal voltage. That is, the input voltage is overvoltage by the input overvoltage detector 320, the output voltage is overvoltage by the existing protection circuit 500, and the output circuit is disabled by the feedback circuit unit 310 In this case, it is possible to protect the ballast by cutting off the supply of voltage to the Vcc terminal of the IC chip. In particular, according to the electronic ballast of the fourth embodiment in which the first to third embodiments of the present invention are combined, as shown in FIG. 5, the control terminal of the IC when the input voltage is overvoltage and the output voltage is overvoltage When the potential of (Ldet) falls below the reference value and there is an abnormality in the output part (when the lamp is impossible), the feedback circuit unit 310 detects this and cuts off the voltage supply to the Vcc terminal of the IC to effectively protect the ballast circuit. Becomes possible.

6 shows an electronic ballast according to a fifth embodiment of the present invention, which shows a method in which the electronic ballast according to the present invention is applied to a two-lamp system.

As shown in Fig. 6, the voltage stabilization circuit section 100 'of this embodiment is composed of a fuse FUSE, a varistor VA, transformers LF1, LF2, and capacitors C1-C3. The rectifier 200 'and the protection circuit part 500' constituted of the bridge diodes D1-D4 are the same as the rectifier part 200 and the protection circuit part 500 (refer to FIG. 5) of the fifth embodiment.

The lamp unit 400 ′ is composed of two first and second lamps LAMP1 and LAMP2 and two capacitors C13 and C23. The first lamp is connected to one terminal of the first MOSFET Q3 through the primary side of the transformer PT1, and the second lamp is connected to one terminal of the second MOSFET Q4 through the primary side of the other transformer PT2. . The source and drain sides of the first MOSFET Q14 are bridged through the capacitor C14. The secondary sides of the transformers PT1 and PT2 are connected to the coupling resistor R6 to the Vcc terminal of the chip through diodes D5 and D9, respectively, and at the same time, the input control side R12 of the protection circuit portion through diodes D6 and D10. ) Is connected.

Bootstrap circuits BT and C16 are connected to the input terminal of the ramp control unit 300 ', and one end of the bootstrap circuit is connected to one end of the first MOSFET Q3 through the forward diodes D11 and D12. It is grounded through the capacitor C15. Both ends of the bridge diode are also bridged through the capacitor C7, and the lower potential terminal of the bridge diode is also reversely coupled to ground through the diodes D7 and D8. The remaining circuit is the same as the circuit of the fourth embodiment except that the input overvoltage detector 320 does not exist in the fifth embodiment.

Therefore, according to the electronic ballast according to the fifth embodiment of the present invention, it becomes possible to protect the ballast circuit from abnormal state of input / output while further suppressing the flickering phenomenon by lamps having two phases different from each other.

Although the present invention has been described above with reference to one embodiment shown in the accompanying drawings, the present invention is not limited thereto, and various modifications may be made within a range easily understood by those skilled in the art. Therefore, the limitation of the present invention should be limited only by the following claims.

As described above, the problem of the prior art in that the lamp driving unit is operated to heat and melt the socket around the filament even when the lamp is disabled, and a solution to reduce the loss power caused by standby power is possible. Since elements having a large parameter value must be used as elements of a protection circuit of resistors, there is a problem in that power consumption of the ballast itself is large, but according to the present invention, since it is sufficient to control a lower voltage, it is easier than in the prior art. It is possible to perform the overvoltage control, and according to the electronic rectifier according to the present invention automatically has a reset function, and furthermore, because the existing protection circuit is used, by adding a simple configuration to the existing circuit to the overvoltage of the input voltage Efficient ballast circuit protection A.

Claims (8)

Lamp driving unit 300 which oscillates by the power of the DC voltage supply unit 100, 200; 100 ', 200', the lamp unit 400; 400 ', and the DC voltage supply unit to drive the lamp LAMP of the lamp unit. 300 ') and a protection circuit unit 500 (500') for controlling the operation of the lamp driver when the output of the lamp unit is an abnormal voltage, An oscillator (OSC) for supplying a high frequency operating current to the lamp; A chip (350) connected to a power supply (Vcc) terminal to an upper potential terminal of the supplied DC voltage to control the oscillator; And A feedback circuit unit 310 (310 ') for controlling the power supply of the chip; Including but not limited to: The feedback circuit unit includes a switching element Q1 inserted between the upper terminal of the DC voltage supply unit and the power supply terminal of the chip, and the control terminal of the switching element is connected to one terminal of the lamp. And the lamp controls the switching element when the lamp is disabled so that the DC voltage is not applied to the chip so that the chip stops operating. The method of claim 1, The control terminal Vdet of the chip is connected to the upper potential terminal of the DC voltage through a coupling resistor R7, and the output control line of the protection circuit unit 500; 500 'is connected to the control terminal of the chip. And the lamp driver shuts down when the output of the lamp part is an abnormal voltage. Lamp driving unit 300 which oscillates by the power of the DC voltage supply unit 100, 200; 100 ', 200', the lamp unit 400; 400 ', and the DC voltage supply unit to drive the lamp LAMP of the lamp unit. 300 ') and a protection circuit unit 500 (500') for controlling the operation of the lamp driver when the output of the lamp unit is an abnormal voltage, An oscillator (OSC) for supplying a high frequency operating current to the lamp; And A chip (350) connected to a power supply (Vcc) terminal to an upper potential terminal of the supplied DC voltage to control the oscillator; Including, The control terminal Vdet of the chip is connected to the upper potential terminal of the DC voltage through a coupling resistor R7, and the output control line of the protection circuit unit 500; 500 'is connected to the control terminal of the chip. And the lamp driver shuts down when the output of the lamp part is an abnormal voltage. The method of claim 3, wherein Further comprising an input overvoltage detector 320 for detecting whether the supplied DC voltage is overvoltage, The input overvoltage detector 320 is provided between the divided resistors R13 and R14 inserted between the upper potential terminal and the ground terminal, between the connection terminal of the divided resistor and the switching element Q2 of the protection circuit unit 500. And a constant voltage element (ZD3) inserted in a reverse direction, and switching the switching element (Q2) to shut down the chip when the supply voltage of the upper terminal of the DC voltage is an overvoltage. The method according to any one of claims 1 to 3, The lamp unit 400 'includes first and second lamps LAMP1 and LAMP2 connected to the lamp driver 300', and the phases of the output voltages for lighting the first and second lamps are opposite to each other. Electronic ballast characterized by the above-mentioned. The output of the lamp unit 300 and the lamp driver 300 that oscillates by the power of the DC voltage supply unit 100 and 200, the lamp unit 400, the DC voltage supply unit to drive the lamp LAMP of the lamp unit, and the output of the lamp unit is abnormal. In the electronic ballast comprising a protection circuit unit 500 for controlling the operation of the lamp driver when the voltage, An oscillator (OSC) for supplying a high frequency operating current to the lamp; A chip (350) connected to a power supply (Vcc) terminal to an upper potential terminal of the supplied DC voltage to control the oscillator; And An input overvoltage detector 320 for detecting whether the supplied DC voltage is overvoltage; Including but not limited to: The input overvoltage detector 320 is provided between the divided resistors R13 and R14 inserted between the upper potential terminal and the ground terminal, between the connection terminal of the divided resistor and the switching element Q2 of the protection circuit unit 500. And a constant voltage element (ZD3) inserted in a reverse direction, and switching the switching element (Q2) to shut down the chip when the supply voltage of the upper terminal of the DC voltage is an overvoltage. The method of claim 6, Further comprising a feedback circuit unit 310 for controlling the power supply of the chip, The feedback circuit unit includes a switching element Q1 inserted between the upper terminal of the DC voltage supply unit and the power supply terminal of the chip, and the control terminal of the switching element is connected to one terminal of the lamp. And the lamp controls the switching element when the lamp is disabled so that the DC voltage is not applied to the chip so that the chip stops operating. The method of claim 7, wherein The control terminal Vdet of the chip is connected to the upper potential terminal of the DC voltage through a coupling resistor R7, and the output control line of the protection circuit 500 is connected to the control terminal of the chip. And the lamp driver shuts down when the output of the lamp portion is an abnormal voltage.