KR101701699B1 - Electronic ballast for fluorescent light, and lighting control method thereof - Google Patents

Abstract

The present invention relates to an electronic ballast for a fluorescent lamp and a lighting control method thereof, comprising: a first resonant circuit unit consisting of a first inductor having one end connected to any one output end of an inverter which supplies a power for lighting a first fluorescent lamp and the other end connected to an input end of any one filament of the first florescent, and a first capacitor having one end connected to an output end of the any one filament and the other end connected to an input end of the other one filament, and passing an alternating current power supply of a frequency band which is desired to be supplied to the first fluorescent lamp by using characteristics of an inductive reactance of the first inductor, which is changed according to a frequency component supplied from the inverter, and a capacitive reactance of the first capacitor while attenuating an alternating current power supply of a frequency band which is reluctant to be supplied to the first fluorescent lamp; and a filament preheating unit switched on for a predetermined time when an initial first fluorescent lamp is lighted in a state of being connected to the first capacitor in parallel so as to disconnect the output end of the any one filament and the input end of the other one filament and to preheat a filament, and switched off after the predetermined time to light the first fluorescent lamp. The filament in the first fluorescent lamp is preheated for a predetermined time by turning on a switch of the filament preheating unit when the initial first fluorescent lamp is lighted, thereby preventing the filament from being damaged when the initial first fluorescent lamp is lighted. Also, an induced voltage that is higher than a firing voltage of the first fluorescent lamp is generated during a predetermined time from a first inductor included in the first resonant circuit unit when the switch of the filament preheating unit is turned off after the predetermined time so as to light the first fluorescent lamp.

Description

ELECTRONIC BALLAST FOR FLUORESCENT LIGHT, AND LIGHTING CONTROL METHOD THEREOF FIELD OF THE INVENTION [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ballast for an electronic fluorescent lamp and a lighting control method thereof and more particularly to a ballast for an electronic fluorescent lamp which preheats a filament provided in a fluorescent lamp for a predetermined period of time before lighting the fluorescent lamp, And a control method.

Generally, a ballast for a fluorescent lamp is applied several hundreds of volts, and more than 1,000 volts, depending on the power consumption of the fluorescent lamp (including sterilizing fluorescent lamps and industrial fluorescent lamps) in the filament provided in the fluorescent lamp when the fluorescent lamp is first turned on.

At this time, if an excessive voltage is applied to the filament of the fluorescent lamp, the filament is damaged, the constituent material detached from the filament is stuck to both sides of the fluorescent lamp, and the lifetime of the fluorescent lamp is also shortened.

In addition, if the filament is damaged by the transient voltage, the filament becomes thinner and the resistance of the filament becomes higher. As the resistance of the filament increases, the amount of current passing through the filament decreases, and the light of the fluorescent lamp gradually becomes darker.

On the other hand, "Prior Art No. 10-2006-0024415", "Discharge lamp lighting device" is filed and disclosed in the prior art of the present invention. The discharge lamp lighting device controls the switch element on and off so as to convert the DC power supply voltage into a high- And a discharge lamp which is supplied with a high frequency voltage from the inverter circuit and which is turned on with an inductor, a capacitor and a predetermined lighting frequency, wherein a deflection angle with respect to the lighting frequency at an impedance when the discharge lamp is rated is -20 A resonance load circuit set between 0 and 40 degrees, a pulse voltage for turning on and off the switching element at a period shorter than the lighting period of the discharge lamp, and generating a high signal width of the pulse voltage in correspondence to the lighting period A pulse width modulation is performed in accordance with a waveform change of a sinusoidal voltage, and a sinusoidal current And a control circuit for controlling the supply of the voltage.

However, the above-mentioned discharge lamp lighting device also has a problem that the function of preheating the filament provided in the fluorescent lamp before the fluorescent lamp is turned on is insufficient or is not sufficiently equipped, so that the life of the fluorescent lamp can not be maintained for a long time.

Korean Patent Publication No. 10-2004-0045339 (June 1, 2004) Korean Patent Publication No. 10-2006-0024415 (Mar. 16, 2006)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a fluorescent lamp which is capable of preventing excessive voltage from being applied to a filament of a fluorescent lamp, The object of the present invention is to provide a ballast for an electronic fluorescent lamp and its lighting control method which can prevent blackening of a fluorescent lamp due to the contaminants generated from filaments sticking to the inner wall of both sides of the fluorescent lamp and prolong the life of the fluorescent lamp.

According to an aspect of the present invention, there is provided an electronic fluorescent lamp ballast according to the present invention, wherein the ballast is connected to one output end of an inverter that supplies power for lighting the first fluorescent lamp, and the other end is connected to one filament input end of the first fluorescent lamp. An inductive reactance of a first inductor which is composed of a first inductor and a first capacitor whose one end is connected to the output terminal of one filament and the other end is connected to the input terminal of another filament and which changes in accordance with a frequency component supplied from the inverter, A first resonance circuit part for passing an AC power source of a frequency band desired to be supplied to the first fluorescent lamp and attenuating an AC power source of a frequency band which is not desired to be supplied to the first fluorescent lamp by using the characteristic of the capacitive reactance of the first capacitor; When the initial first fluorescent lamp is turned on in a state of being connected in parallel with the first capacitor, the filament is preheated by shorting the output terminal of one filament and the other filament input terminal for a predetermined time, And the filament preheating section is switched off to turn on the first fluorescent lamp. When the initial first fluorescent lamp is turned on, the switch of the filament preheating section is turned on, and the filament in the first fluorescent lamp is preheated for a predetermined time, The filament is prevented from being damaged when the fluorescent lamp is lit, and when the switch of the filament preheating unit is turned off after a predetermined time, the voltage is higher than the discharge start voltage of the first fluorescent lamp for a predetermined time from the first inductor provided in the first resonance circuit unit An induced voltage is generated and the first fluorescent lamp is turned on.

The electronic ballast for a fluorescent lamp and its lighting control method according to the present invention having such a structure preheats a filament provided in a fluorescent lamp for several hundreds of milliseconds to several hundreds of milliseconds using a voltage lower than a discharge start voltage when the first fluorescent lamp is turned on.

Thereafter, the present invention supplies a fluorescent lamp with a fluorescent lamp at a voltage higher than the discharge start voltage instantaneously or for a short time such as several tens of milliseconds to light the fluorescent lamp.

It is possible to prevent an excessive voltage from being applied to the filament of the fluorescent lamp when the initial fluorescent lamp is turned on so that the pollutant generated from the filament due to the transient voltage sticks to the inner wall of both sides of the fluorescent lamp to prevent the fluorescent lamp from blackening have.

In addition, when the present invention is used, the lifetime of a fluorescent lamp can be prolonged for a long time. For example, in a test in which a fluorescent lamp is turned on and off at intervals of 30 seconds, It was difficult to pass more than 6,000 times, but the fluorescent lamp did not die in the On and Off tests of 50,000 to 60,000 times or more.

For this reason, consumers can reduce the cost of replacing a fluorescent lamp and significantly reduce the number of fluorescent lamps to be discarded.

In addition, the present invention can save a material cost by adding a filament preheating part to a conventional inverter, while the lifetime of a fluorescent lamp can be increased by at least 5 to 10 times.

1 is a control block diagram of a ballast for an electronic fluorescent lamp,
2 is a control circuit diagram of a ballast for an electronic fluorescent lamp,

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the ballast for an electronic fluorescent lamp according to the present invention has one end connected to one output terminal of an inverter 13 for supplying electric power for lighting the first fluorescent lamp 11, A first inductor 15 connected to the input terminal of one filament 12a of the first fluorescent lamp 11 and a second inductor 15 connected to the output terminal of one filament 12a and the other terminal of the other filament 12b The inductance of the first inductor 15 and the capacitive reactance of the first capacitor 17, which are constituted by the first capacitor 17 connected to the first inductor 15 and varying in accordance with the frequency component supplied from the inverter 13, The first inductor 15 constituting the first resonance circuit portion 19 that attenuates the alternating current power supply of the frequency band in which the alternating current power supply of the frequency band desired to be supplied to the first fluorescent lamp 11 is allowed to pass, ) And the first L seater 17 and; When the initial first fluorescent lamp 11 is turned on in a state of being connected in parallel with the first capacitor 17, the first filament 12b is switched on for a predetermined time, so that one filament 12b, which is different from the output terminal of one filament 12a, The input terminal is short-circuited or the impedance between the output terminal of one filament 12a and the input terminal of one filament 12b is lowered to preheat the filaments 12a and 12b. After a predetermined time has elapsed, And a filament preheating section 21 for lighting the fluorescent lamp 11.

The filament preheating section 21 is switched on when the initial first fluorescent lamp 11 is turned on and the filaments 12a and 12b in the first fluorescent lamp 11 are preheated for a predetermined period of time, The first inductor 15 provided in the first resonance circuit unit 19 is turned off for a predetermined time after the predetermined time has elapsed after the switch of the filament preheating unit 21 is turned off, An induced voltage higher than the discharge start voltage of the fluorescent lamp 11 is generated and the first fluorescent lamp 11 is turned on.

1, the present invention includes an EMI (Electromagnetic Interface) filter unit 1 for removing a noise component input from an AC power source, an AC power supply unit 3 for supplying an AC power output from the EMI filter unit 1 to a DC power source A Valley fill Power Factor Correction (PFC) 5 for reducing power loss by increasing a power factor when the alternating current power is changed to DC power in the rectifying circuit portion 3, And a boost circuit for boosting a DC voltage output from the valley-fill PFC (5).

The inverter 13 includes an inverter driving circuit 9 for converting the DC power boosted by the boost circuit 7 to an AC power having an oscillation frequency of several tens Khz and supplies the converted AC power to the first fluorescent lamp 11, To the filaments (12a, 12b) of the first fluorescent lamp (11).

The inverter 13 may be provided with a dimming unit for adjusting the brightness of the first fluorescent lamp 11 by adjusting the pulse width output from the inverter 13 to the first fluorescent lamp 11.

The filament preheating unit 21 preheats the filaments 12a and 12b of the first fluorescent lamp 11 within several seconds to several seconds.

The time for preheating the first fluorescent lamp 11 may vary depending on the characteristics of the fluorescent lamp, that is, the consumed electric power of the fluorescent lamp, or the first, second, or third straight fluorescent lamps or the U-shaped fluorescent lamps. , 200ms to 2 seconds or less is usually sufficient.

As a result of the experiment, it was possible to maximize the life of the first fluorescent lamp 11 when the filaments 12a and 12b equipped in the first fluorescent lamp 11 were preheated for 500 ms to 1.5 seconds.

As shown in FIGS. 1 and 2, the filament preheating section 21 is a charge / discharge circuit composed of a resistor and a capacitor. The filament preheating section 21 includes a filament preheating section 21 for correcting the output voltage to 0.63% of the input voltage And a second filament 12b connected to the first capacitor 17 in parallel with the output terminal of the first filament 12a when the initial first fluorescent lamp 11 is turned on, The switching unit 25 transmits the control signal to the switching unit 25 to which the input terminal is connected or not connected so that the output terminal of one filament 12a is connected to the input terminal of the other filament 12b, And 12b. When the timing setting unit 23 reaches a voltage set to a predetermined value by the time constant, the switching unit 25 transmits a control signal to the switching unit 25, ramen A switch on / off control unit 27 for turning on the first fluorescent lamp 11 by not connecting the output terminal of the first filament 12a and the input terminal of another filament 12b to the control signal of the switch on / off control unit 27, And a switching unit 25 connecting or disconnecting the output terminal of one filament 12a and the input terminal of another filament 12b.

The switching unit 25 includes a relay that is switched on or off according to a control signal of the switch on / off control unit 27, a field effect transistor, a transistor A silicon-controlled rectifier, a triac, a phototransistor, a photocoupler, and the like.

A resistor or a capacitor or an inductor is connected in series between the output terminal of the one filament 12a and the input terminal of the switching unit 25 or between the input terminal of the other filament 12b and the output terminal of the switching unit 25, .

The first resonant circuit portion 19 and the first fluorescent lamp 11 are constituted by two or more elements and the one filament preheating portion 21 is connected to each of the two or more first resonant circuit portions 19 1 capacitor 17 in parallel.

Two or more first resonant circuit portions 19 (19) are provided on both ends of the respective first capacitors 17 provided in the two or more first resonant circuit portions 19 connected to both ends of the one filament preheating portion 21, And the first filament preheating section 21 is switched on, at least two first fluorescent lamps 11 are preheated, and the one filament preheating section 21 is preheated when the one filament preheating section 21 is switched on, When the first fluorescent lamp 21 is switched off, at least two first fluorescent lamps 11 are turned on.

A second inductor 31 connected to one input end of the filament 30a of the second fluorescent lamp 29 having one end connected to one output end of the inverter 13 and the other end connected thereto, A second capacitor 33 connected to the output terminal of one filament 30a provided in the second fluorescent lamp 29 and the other end connected to the input terminal of another filament 30b provided in the second fluorescent lamp 29, And is supplied to the second fluorescent lamp 29 by using the characteristics of the inductive reactance of the second inductor 31 and the capacitive reactance of the second capacitor 33 that vary according to the frequency component supplied from the inverter 13 And a second resonant circuit portion (35) for attenuating the alternating current power source in the frequency band where the alternating current power source of the desired frequency band is passed and the second fluorescent lamp (29) is not desired to be supplied.

The filament preheating unit 21 is switched on for a predetermined time when the initial second fluorescent lamp 29 is turned on in parallel with the second capacitor 33 and is connected to the second fluorescent lamp 29 The filament 30a and the filament 30b are connected to each other by shorting the output terminal of one filament 30a and the input terminal of another filament 30b or lowering the impedance between the output terminal of one filament 30a and the input terminal of another filament 30b, And after a predetermined time has elapsed, the second fluorescent lamp 29 is turned on by being switched off.

An anode terminal is connected between the output terminal of one filament 12a of the first fluorescent lamp 11 and an input terminal of the switching unit 25 and an anode terminal is connected to the output terminal of any one filament 12a, An anode is connected between the output terminal of the switching unit 25 and the input terminal of the other filament 12b of the first fluorescent lamp 11. The first diode 37 is connected to the input terminal of the switching unit 25, And a second diode 39 connected to the output terminal of the switching unit 25 and connected to the input terminal of the other filament 12b of the first fluorescent lamp 11 at the cathode end.

The first and second diodes 37 and 39 are connected in parallel to the first and second diodes 37 and 39 such that the first and second diodes 37 and 39 operate in the negative voltage cycle of alternating current. Diodes 45 and 47 may be connected in the reverse direction.

An anode terminal is connected to a filament output terminal 30a provided in the second fluorescent lamp 29 between the output terminal of one filament 30a of the second fluorescent lamp 29 and the input terminal of the switching unit 25, And a third diode 41 connected to the input terminal of the switching unit 25 is connected to the cathode terminal of the second fluorescent lamp 29. The output terminal of the switching unit 25 and the other terminal of the second fluorescent lamp 29 A fourth diode 43 is connected between an input terminal of the second fluorescent lamp 29 and an anode terminal connected to the output terminal of the switching unit 25 and a cathode terminal connected to the input terminal of another filament 30b of the second fluorescent lamp 29, Respectively.

The third and fourth diodes 41 and 43 are connected in parallel to the third and fourth diodes 41 and 43 so that the second fluorescent lamp 29 can operate even in a negative voltage cycle of alternating current. The diodes 49 and 51 may be connected in the reverse direction.

The first, second, and fourth diodes 37, 39, 41, and 43 are provided to separate the first resonant circuit portion 19 and the second resonant circuit portion 35 from each other.

In the lighting control method of the electronic ballast for a fluorescent lamp of the present invention, when the initial fluorescent lamp 11 is turned on, one filament 12b different from the output terminal of one filament 12a of the first fluorescent lamp 11 The switch of the filament preheating section 21 in which the switch is opened and closed in the state of being connected to the input end of the first filament 12a and the other end of the filament 12b different from the output terminal of the one filament 12a is short- (12a, 12b) for a predetermined period of time; and a step of preheating the filaments (12a, 12b) for a predetermined time, The induction voltage is generated from the first inductor 15 of the first resonance circuit 19 and the fluorescent lamp is turned on so that the first fluorescent lamp 11 is turned on for a predetermined time before the first fluorescent lamp 11 is turned on, The filaments 12a and 12b 12b of the first fluorescent lamp 11 and the blackening of both sides of the first fluorescent lamp 11 are changed to black so that the life of the first fluorescent lamp 11 is prolonged.

The filament preheating unit 21 closes the switch within several seconds to several seconds to preheat the filaments 12a and 12b of the first fluorescent lamp 11.

A filament preheating unit (not shown) in which a switch is opened and closed in a state where the output terminal of one filament 12a of the first fluorescent lamp 11 is connected to the input terminal of another filament 12b when the initial first fluorescent lamp 11 is turned on The step of preheating the filaments 12a and 12b equipped in the first fluorescent lamp 11 for a predetermined time by shorting the output terminal of one filament 12a and the input terminal of another filament 12b by closing the switch of the first filament 12a The filament preheating section 21 reaches a voltage set to a predetermined value by the time constant at which the output voltage of the timing setting section 23 composed of the charge / discharge circuit composed of the resistor and the capacitor reaches 0.63% of the input voltage If the timing setting unit 23 has reached a voltage set to a predetermined value, the filament preheating unit 21 outputs the output signal of any one filament 12a of the first fluorescent lamp 11, And one other The switch of the switching unit 25 which is closed by using the switch on / off control unit 27 for transmitting the switch open / close signal to the switching unit 25 for opening / closing the switch in the state of being connected to the input terminal of the filament 12b of the first Further comprising a step of preheating the filaments (12a, 12b) provided in the fluorescent lamp (11) by a predetermined time determined by the time constant set in the timing setting section (23).

The electronic ballast for a fluorescent lamp and its lighting control method according to the present invention having such a structure preheats a filament provided in a fluorescent lamp for several hundreds of milliseconds to several hundreds of milliseconds using a voltage lower than a discharge start voltage when the first fluorescent lamp is turned on.

Thereafter, the present invention supplies a fluorescent lamp with a fluorescent lamp at a voltage higher than the discharge start voltage for a short period of time, such as a moment or several tens of milliseconds, to illuminate the fluorescent lamp.

The present invention prevents an excessive voltage from being applied to a filament of a fluorescent lamp at a very low level when the first fluorescent lamp is lit, that is, with almost no preparatory operation, so that contaminants generated from the filament by the transient voltage stick to the inner walls of both sides of the fluorescent lamp, The blackening can be prevented.

In addition, when the present invention is used, the lifetime of a fluorescent lamp can be prolonged for a long time. For example, in a test in which a fluorescent lamp is turned on and off at intervals of 30 seconds, It was difficult to pass more than 6,000 times, but the fluorescent lamp did not die in the On and Off tests of 50,000 to 60,000 times or more.

For this reason, consumers can reduce the cost of replacing a fluorescent lamp and significantly reduce the number of fluorescent lamps to be discarded.

In addition, the filament preheating unit 21 may be additionally provided in the inverter 13 of the present invention, so that the material cost can be saved, while the lifetime of the fluorescent lamp can be increased by at least 5 to 10 times.

1. EMI filter 3. Rectifier circuit
5. Valley fill PFC 7. Boost circuit
9. Inverter drive circuit 11. First fluorescent lamp
13. Inverter 15. First inductor
17. First capacitor 19. First resonator circuit
21. Filament preheating section 23. Timing setting section
25. Switching unit 27. Switch on / off control unit
29. Second fluorescent lamp 31. Second inductor
33. Second capacitor 35. Second resonance circuit
37. First diode 39. Second diode
41. Third diode 43. Fourth diode

Claims (7)

The other end of the first fluorescent lamp 11 is connected to one output end of the inverter 13 which supplies electric power for lighting the first fluorescent lamp 11 which is once applied to illumination, sterilization or industry, and the other end is connected to any one filament 12a And a first capacitor 17 having one end connected to the output terminal of one filament 12a and the other end connected to the input terminal of the other filament 12b, 13 by using the characteristics of the inductive reactance of the first inductor 15 and the capacitive reactance of the first capacitor 17 that change in accordance with the frequency component supplied from the first fluorescent lamp 11, A first resonance circuit unit 19 for attenuating an alternating current power source of a frequency band which is passed through the alternating current power source and is not to be supplied to the first fluorescent lamp 11,
When the initial first fluorescent lamp 11 is turned on in a state of being connected in parallel with the first capacitor 17, the first filament 12b is switched on for a predetermined time, so that one filament 12b, which is different from the output terminal of one filament 12a, And a filament preheating section 21 for shorting the input terminal to preheat the filaments 12a and 12b and turning off the first fluorescent lamp 11 after a predetermined time has elapsed,
The filament preheating section 21 is turned on when the initial first fluorescent lamp 11 is turned on and the filaments 12a and 12b are preheated by heating the filaments 12a and 12b in the first fluorescent lamp 11 for a predetermined time, To prevent damage,
When the switch of the filament preheating section 21 is turned off after a predetermined time, the voltage is lower than the discharge start voltage of the first fluorescent lamp 11 for a predetermined time from the first inductor 15 provided in the first resonance circuit section 19 A high induced voltage is generated and the first fluorescent lamp 11 is turned on,
The filament preheating unit 21 preheats the filaments 12a and 12b of the first fluorescent lamp 11 for several hundreds ms to several seconds,
The filament preheating section 21 is a charge / discharge circuit composed of a resistor and a capacitor. The filament preheating section 21 has a timing setting section 23 for changing the time constant at which the output voltage reaches 0.63% of the input voltage depending on the size of the resistor and the capacity of the capacitor.
A switching unit which connects or disconnects one filament input terminal 12b and one filament input terminal 12b in parallel with the first capacitor 17 when the initial first fluorescent lamp 11 is turned on, 25 to cause the switching unit 25 to connect one of the output ends of the filament 12a and the other input end of the filament 12b to preheat the filaments 12a,
When the timing setting unit 23 reaches a predetermined time by the time constant, it transmits a control signal to the switching unit 25 so that the switching unit 25 outputs one filament 12a output terminal and one filament A switch on / off control unit 27 for turning on the first fluorescent lamp 11 by not connecting an input terminal of the first fluorescent lamp 12b;
And a switching unit 25 for connecting or disconnecting the output terminal of one filament 12a and the input terminal of another filament 12b according to a control signal of the switch on / off control unit 27,
The first resonant circuit part (19) and the first fluorescent lamp (11) are composed of two or more,
The one filament preheating section 21 is connected in parallel to each first capacitor 17 provided in the two or more first resonant circuit sections 19,
Two or more first resonance circuit portions 19 are provided on both ends of the first capacitors 17 provided in the two or more first resonance circuit portions 19 connected to both ends of the one filament preheating portion 21 Electrical or electronic devices are connected to separate,
When the one filament preheating section 21 is switched on, two or more first fluorescent lamps 11 are preheated,
Two or more first fluorescent lamps 11 are turned on when the one filament preheating unit 21 is switched off,
A second inductor 31 having one end connected to one of the output terminals of the inverter 13 and the other end connected to the input terminal of one filament 30a of the second fluorescent lamp 29, And a second capacitor 33 connected to the output terminal of one filament 30a provided in the second fluorescent lamp 29 and the other end connected to the input terminal of another filament 30b provided in the second fluorescent lamp 29, The inductance of the second inductor 31 and the capacitive reactance of the second capacitor 33 are changed in accordance with the frequency component supplied from the first fluorescent lamp 29 and the second fluorescent lamp 29, Further comprising a second resonant circuit portion (35) for attenuating an alternating current power source of a frequency band which is passed through the power source and is not intended to be supplied to the second fluorescent lamp (29)
An anode terminal is connected to the output terminal of any one filament 12a and a cathode terminal is connected to the output terminal of one filament 12a of the first fluorescent lamp 11 and the input terminal of the switching unit 25, And an anode terminal is connected between the output terminal of the switching unit 25 and the input terminal of the other filament 12b of the first fluorescent lamp 11. The first diode 37 is connected to the input terminal of the first fluorescent lamp 11, A second diode 39 connected to an output terminal of the switching unit 25 and having a cathode terminal connected to the input terminal of the other filament 12b of the first fluorescent lamp 11 is connected,
An anode terminal is connected to one filament output terminal 30a provided in the second fluorescent lamp 29 between the output terminal of one filament 30a of the second fluorescent lamp 29 and the input terminal of the switching unit 25, And a third diode 41 connected to the input terminal of the switching unit 25 is connected to the cathode of the second fluorescent lamp 29. The output terminal of the switching unit 25 and the other one filament 30b of the second fluorescent lamp 29 are connected, A fourth diode 43 connected to an output terminal of the switching unit 25 and an cathode terminal connected to the input terminal of another filament 30b of the second fluorescent lamp 29 is connected between the input terminals Wherein the ballast is a ballast for an electronic fluorescent lamp.
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