JPH0513185A - Discharge lamp lighting device - Google Patents

Abstract

PURPOSE:To secure starting and re-starting of a discharge lamp and miniaturize a pulse transformer constituting a starter in a discharge lamp lighting device where a resonance circuit is used. CONSTITUTION:A power source 11 having a high frequency inverter is applied to a resonance circuit comprising capacitors 12, 13 and a choke coil 14. A high voltage pulse from a high voltage pulse generating device 16 is superposed on a voltage generated in the capacitor 13, to be applied to a discharge lamp 15. A detector 17 detects a state of the discharge lamp 15, and controls frequency of the high frequency inverter in accordance with the output. Application of the high voltage pulse by the high voltage pulse generating device 16 is controlled according to a period determined with a voltage charged to a charging circuit 23 and a discharge voltage of a discharging gap 24. Consequently, it is possible to decrease pulse energy required for the high voltage pulse, reduce an output of the resonance circuit, and miniaturize a lighting device.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a discharge lamp lighting device for starting a discharge lamp and controlling lighting.

[0002]

2. Description of the Related Art In recent years, discharge lamps have come to be used for various purposes, and discharge lamp lighting devices that can be lit by various power sources and that are small in size and operate stably have become widespread. In order to reduce or substantially eliminate harmful electrophoretic and acoustic resonance effects that generally occur during the lighting operation of a discharge lamp such as a metal halide lamp, a device that operates more stably is being developed. It has been proposed to supply a high voltage due to LC resonance between a pair of electrodes of a discharge lamp. This excites the excitable components enclosed in the discharge lamp at high voltage, and then maintains this excitation,
A method in which a high frequency current having a size within a predetermined range and having a predetermined repetition rate is supplied to an electrode from a high frequency inverter, and the direction in which the high frequency current is supplied to the electrode is periodically and alternately changed. It is known from Japanese Patent Application Laid-Open No. 61-273183 that the contents shown in FIG. 18 have already been described.

In this type of discharge lamp lighting device, in order to start and light the discharge lamp R as shown in FIG. 18, a high voltage generated by series resonance of an LC circuit generally composed of a capacitor C ₂ and a choke coil L. (Resonance voltage) is supplied to the discharge lamp R. In this case, since the resonance voltage maintains a substantially sinusoidal wave, it is possible to supply a larger starting energy to the discharge lamp than when a high voltage pulse is applied, and therefore, a method in which a high voltage pulse is applied Generally, startability is improved.

[0004]

[Problems to be Solved by the Invention]
In order to start (restart) the discharge lamp of
A breakdown voltage of several k to several tens of kV is required, and L
In order to secure this high voltage by series resonance of the C circuit
Is a capacitor C₂and
It is necessary to feed the choke coil L. Therefore, Cho
Of the choke coil to prevent saturation of the
Caused by increasing core size and resonance
To ensure insulation against high voltage,
Indexer C ₂And the choke coil L becomes large,
There is a problem that the miniaturization of the lighting device is hindered. The present invention
Pay attention to the above issues, and keep the discharge lamp small and stable.
To provide a discharge lamp lighting device capable of
Is.

[0005]

In order to solve the above problems, a discharge lamp lighting device of the present invention includes a DC power source, a high frequency inverter driven by the DC power source and oscillating, and an output terminal of the high frequency inverter. A resonance circuit consisting of a series circuit of a connected choke coil and a capacitor, a discharge lamp connected to the connection point between the choke coil and the capacitor that make up this resonance circuit, and a high-voltage pulse applied in series or in parallel to this discharge lamp. High-voltage pulse generator connected so as to detect the characteristics of the discharge lamp lamp characteristics, and the output signal of the detector, the oscillation frequency of the high-frequency inverter or duty ratio variable or DC power output A lighting control device for controlling the lighting of the discharge lamp by limiting the current is provided.

[0006]

In the discharge lamp lighting device of the present invention having the above-described structure, the oscillation frequency of the lighting device is controlled when the discharge lamp is started, and the resonant voltage of the photovoltage of about several hundred to several kV is generated by the LC series resonance of the resonant circuit. The generated high voltage is applied to the discharge lamp, and the high voltage pulse generator has a small energy but superimposes a high voltage pulse having a voltage value capable of breaking down between the main electrodes of the discharge lamp. It is applied to the discharge lamp. As a result, the startability of the discharge lamp can be improved and the lighting device can be downsized.

[0007]

【Example】

(Embodiment 1) An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a configuration diagram showing a first embodiment of a discharge lamp lighting device of the present invention. As shown in FIG. 1, as components, 11 is a power supply device, 12 and 13 are capacitors, 14 is a choke coil, 15 is a discharge lamp, 16 is a high voltage pulse generator, 17 is a detection device, and 18 is a lighting control device. Yes, the power supply device 11 is a capacitor 12, a choke coil 1
4. The discharge lamp 15 is connected via the high voltage pulse generator 16 and the detector 17 so as to start and light the discharge lamp 15. The power supply device 11 is composed of a DC power supply 19, a high-frequency inverter 20 that drives the discharge lamp 15 via the capacitors 12, 13 and the choke coil 14, and an oscillation circuit 21. The oscillating circuit 21 is controlled by the lighting control device 18, so that the oscillating frequency of the high-frequency inverter 20 causes the capacitor 12, which constitutes the LC series resonant circuit,
13 has a capacitance and a choke coil 1
When controlled to have a resonance frequency determined by the inductance of 4, the high voltage is generated across the capacitor 13 arranged in parallel in the series circuit of the discharge lamp 15 and the high voltage pulse generator 16. At this time, the high voltage pulse generator 16 is also installed between the main electrodes of the discharge lamp 15 at the same time.
From which a high voltage pulse is supplied. That is, the high voltage pulse generator 16 includes a pulse transformer 22 and a charging circuit 23.
, A discharge gap 24, and a capacitor 25. The high frequency output from the charging circuit 23 is charged into the capacitor 25, and the pulse transformer 22 is charged through the discharge gap 24.
Input to the primary winding of the pulse transformer 22, the energy is small, but sufficient pulse voltage to break down between the main electrodes of the discharge lamp 15 is output from the secondary winding of the pulse transformer 22 to the discharge lamp 15. Apply. In the present embodiment, the high voltage pulse generator 16 is connected to the discharge lamp 15 so as to apply the high voltage pulse in series, but it may be connected so as to be applied in parallel. Pulse transformer 22
The output voltage from the secondary winding is applied to the discharge lamp 15 via the capacitor 13 to cause breakdown between the main electrodes of the discharge lamp 15. The detection device 17 detects the state at this time and sends a detection signal to the lighting control device 18. Note that the detection device 17 has a small impedance, and is required for the resonance condition of the series resonance circuit composed of the capacitors 12, 13 and the choke coil 14, the attenuation and absorption of the generated high voltage pulse, and the limitation of the lamp current. It shall not be affected.

The operation of the discharge lamp lighting device having such a configuration will be described. When the output voltage of the DC power supply 19 is supplied to the middle point of the primary winding of the transformer 27 via the resistor 26, the transistors 28 and 29 are alternately switched by the signal from the oscillation circuit 21, and the resistor 26 and the transformer are switched. Current flows through the primary winding of the transformer 27 and one of the transistor 28 and the transistor 29, and FETs 30 and 31 that are switching elements are provided in the secondary windings of the transformer 27.
In order to operate the drive circuits 32 and 33 that drive the LED, an alternating voltage alternating with the oscillation frequency set by the lighting control device 18 is output. At this time, the FETs 30 and 31
Alternately conducts (hereinafter abbreviated as ON) and cuts off (hereinafter abbreviated as OFF) with a pause period set by the lighting control device 18. The inductance components of the choke coil 14 and the secondary winding of the pulse transformer 22 are
When the discharge lamp 15 is turned on, it becomes an inductance that limits the lamp current. Further, the capacitor 12 is F
A charge is charged during a period when the ET 30 is on and the FET 31 is off, and conversely, a charge is discharged during a period when the FET 30 is off and the FET 31 is on, thereby having a function of maintaining lighting of the discharge lamp 15 and generating a resonance voltage. Sometimes it acts as one of the capacitance components. Choke coil 14
Has a lamp current limiting function and acts as an inductance component when a resonance voltage is generated.

In this embodiment, when the DC power supply 19 is turned on, the high frequency inverter 20 first oscillates at a low frequency of about 2 kHz, and the low frequency AC voltage is generated by the capacitors 12, 13 and the choke coil 14. Supply to the configured series resonant circuit. When the high frequency resonance voltage generated by the resonance circuit is superimposed on the low frequency voltage generated at this time, the detection device 17 detects the resonance voltage.
The lighting control device 18 changes the oscillation frequency of the high frequency inverter 20 to a high frequency of, for example, about 100 kHz by this detection voltage. If this high frequency is set near the resonance frequency of the series resonance circuit, the capacitor 1
A resonance voltage of about several hundred to several kV is generated at both ends of 3. Here, the charging circuit 23 constituting the high voltage pulse generator 16
Is connected in parallel with the capacitor 13, and as the voltage across the capacitor 13 rises due to resonance,
The input voltage of the charging circuit 23 rises, and the capacitor 25 connected to the output end of the charging circuit 23 is charged. When this voltage reaches the breakdown voltage of the discharge gap 24, the discharge gap 24 breaks down and the discharge gap 24
The high frequency output is input to the primary winding of the pulse transformer 22 via. As a result, the boosted high voltage pulse is generated in the secondary winding of the pulse transformer 22 and applied to the discharge lamp 15 via the capacitor 13. At this time, the discharge lamp 15 is supplied with a resonance voltage which is generated at both ends of the capacitor 13 due to resonance and is equivalent to several hundred to several kV. As a result, the high voltage pulse superposed on the voltage across the capacitor 13 causes breakdown between the main electrodes of the discharge lamp 15 and starts the initial discharge. Therefore,
In this method, most of the starting energy required from the start of the initial discharge of the discharge lamp 15 to the transition to arc discharge can be covered by the resonance voltage supplied at this time. Therefore, the high-voltage pulse applied from the high-voltage pulse generator 16 to the discharge lamp 15 has an extremely narrow pulse width necessary for breaking down between the main electrodes of the discharge lamp 15 and initiating the initial discharge. A pulse voltage with small energy is sufficient. The applied high voltage pulse is applied to the capacitor 13 by the power supply device 11.
It also has the function of preventing the return to the side. Through these series of operations, the discharge lamp 15 can be easily started without extinguishing during the transition from glow discharge to arc discharge,
It becomes possible to light.

When the discharge lamp 15 is turned on, the impedance of the discharge lamp 15 is lowered, and a large amount of current flows through the discharge lamp 15, causing the series resonance circuit composed of the capacitors 12, 13 and the choke coil 14 to resonate. Can't be maintained. At this time, the detection device 17 detects that the discharge lamp 15 has started by detecting that the current flowing through the series resonance circuit has changed abruptly. Next, the lighting control device 18 controls the detection signal of the detection device 17 so that the oscillation frequency of the high frequency inverter 20 becomes a frequency of, for example, about 10 kHz. After that, when the lamp voltage is low, the high frequency inverter 2
When the lamp voltage is high, the oscillation frequency of the high frequency inverter 20 is increased to increase the current flowing through the choke coil 14 to increase the oscillation frequency of the discharge lamp 1.
The current flowing through the discharge lamp 15 is reduced and the discharge lamp 15 is controlled to be rated. In the present embodiment, when the discharge lamp 15 is activated and a lamp current flows to lower the impedance of the discharge lamp 15, the capacitors 12, 13,
The series resonance circuit constituted by the choke coil 14 and the choke coil 14 cannot maintain the resonance structure, and the voltage supplied to both ends of the capacitor 13, and thus the high-voltage pulse generator 1
The input voltage of the charging circuit 23 constituting 6 decreases, and the generation of the high voltage pulse automatically stops. Also, the charging circuit 2
It is assumed that the input impedance of 3 is sufficiently larger than that of the capacitor 13 and does not affect the resonance condition of the series resonance circuit configured by the capacitors 12 and 13 and the choke coil 14.

As described above, most of the energy required for transition from glow discharge to arc discharge of the discharge lamp 15 is supplied by the resonance voltage. However, unlike the conventional example, the energy required for breakdown of the discharge lamp 15 is supplied. Can utilize the energy of the high-voltage pulse generated by the high-voltage pulse generator 16 to efficiently start the vehicle. Therefore, since the starting energy required to be generated by resonance is superposed with a high voltage pulse that is a high voltage even in a small amount compared to the conventional example, it is expected that a considerable effect can be obtained. Discharge lamp 15 as an example
The peak value of the resonance voltage by the series resonance circuit required for the breakdown can be reduced to about several hundreds to several kV (about 10% of the conventional example in this embodiment). Therefore, when the resonance frequencies are equal, the inductance value of the choke coil 14, which is necessary to generate the same resonance voltage, can be reduced to about 10%, and the withstand voltage also becomes low. The volume of is greatly reduced. At the same time, the withstand voltage required for the capacitors 12 and 13 also decreases, so that the capacitors 12 and 1
3 can also be significantly downsized. As a result, the number of components required for starting and lighting the discharge lamp 15 is increased as compared with the conventional example, but it is expected that the lighting device as a whole will be significantly downsized. Further, by utilizing resonance, the output voltage of the DC power supply 19 can be significantly reduced.

In the present embodiment, as a means for detecting the activation / lighting of the discharge lamp 15, a change in the resonance current due to a change in the impedance of the discharge lamp 15 is detected. , Light output, etc.
Others may be used as long as they are related to the lamp characteristics that can confirm the start and lighting of the lamp.

Further, in this embodiment, the discharge gap is used as the means for generating the high voltage pulse, but other means,
For example, a semiconductor switch element such as a transistor may be used.

Further, in the present embodiment, the high frequency inverter 20 of the power supply device 11 is composed of a series inverter circuit. However, the output voltage has alternating polarities, and a similar effect can be obtained, such as a bridge inverter circuit. It doesn't matter. Further, in the present embodiment, the lamp current during lighting is limited by the capacitor 12 and the choke coil 14. However, a current source may be limited by the direct current power source in the preceding stage of the high frequency inverter, which is used in the high frequency inverter. It may be a chopper operation of a semiconductor element. Further, the high frequency inverter performs an inverter operation in which the polarity of the output voltage is alternated during the resonance operation, but it may be configured to output a low frequency AC output or a DC output during lighting.

(Second Embodiment) FIG. 2 shows a second embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 2, 11 is a power supply device, 12 and 13 are capacitors, 14 is a choke coil, 15 is a discharge lamp, 34 is a high voltage pulse generator, 17 is a detection device, and 35 is a lighting control device. is there. Charging circuit 3 of high voltage pulse generator 34
Reference numeral 6 has an output end of the power supply device 11, that is, an input end thereof connected between the drain and the source of the FET 31, and a lighting control device 35 which operates based on a signal from the detection device 17.
The charging circuit 36 has a function of stopping the charging and stopping the generation of the high voltage pulse. When electric power is supplied to the discharge lamp lighting device, the high voltage pulse generator 34 causes the discharge lamp 15 to generate a resonance voltage.
The basic operation until a high voltage pulse is applied to the discharge lamp 15 and the discharge lamp 15 is started and lit is the same as in the first embodiment.

By the way, in the first embodiment, the stop of the application of the high voltage pulse causes the resonance of the series resonance circuit constituted by the capacitors 12, 13 and the choke coil 14 when the discharge lamp 15 is started and turned on. The condition is broken and the resonance voltage is lowered, that is, the voltage generated across the capacitor 13 is lowered, so that the high voltage pulse generator 16 is insufficiently charged.
However, in such a method, the discharge lamp 15 starts
Even after lighting, there is residual charge associated with the time constant of the charging circuit 23 that constitutes the high-voltage pulse generator 16, which causes an unnecessary pulse voltage and causes flickering after the discharge lamp 15 is lit. In addition, there may be a problem that the discharge lamp 15 may vibrate at high frequency even after the arc discharge.

In this embodiment, the detection device 17 detects that the discharge lamp 15 has started and turned on, and the lighting control device 3
5, when the lighting control device 35 controls the oscillation frequency of the high frequency inverter 20, it also sends a signal to the high voltage pulse generation device 34 at the same time to stop the charging of the charging circuit 36 to generate a high voltage pulse. The generation has stopped. With this, it is possible to surely stop the application of the high voltage pulse to the discharge lamp 15 immediately after the discharge lamp 15 is started and turned on, and it is possible to solve the above-mentioned problems and realize a quick transition to arc discharge. You can

Further, in this embodiment, the charging circuit 36 of the high voltage pulse generator 34 has its input end connected to the output end of the power supply device 11, that is, between the drain and source of the FET 31, and therefore its input impedance. Is the size of capacitors 12, 13 and choke coil 14.
It does not affect the resonance condition of the series resonance circuit composed of. Therefore, the input impedance of the high voltage pulse generator 34 can be made extremely small. As a result, the charging time constant of the charging circuit 36 constituting the high voltage pulse generator 34 can be set short, and the generation cycle of the high voltage pulse, that is, the pulse interval can be narrowed. As a result, even if the energy of the high voltage pulse per shot is reduced, the discharge lamp 1
The number of high-voltage pulses applied to No. 5 is increased, and the startability equal to or higher than that of the first embodiment can be expected. Also, since the energy that each high voltage pulse has can be reduced,
It is expected that the charging circuit 36 and the high voltage pulse generator 34 as a whole can be made smaller than in the case of the first embodiment.

Although the high voltage pulse generator 34 is installed on the ground side of the discharge lamp 15 in this embodiment, it may be installed on the high voltage side. Further, the generation phase of the high voltage pulse may be synchronized with the switching of the power supply device 11. In this case, the generation phase of the high voltage pulse is 30 ° to 90 °.
If the angle is set to 0 ° or 210 ° to 270 °, it is easy to keep the discharge lamp 15 lit.

(Embodiment 3) FIG. 3 shows a third embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 3, 11 are a power supply device, 12 and 13 are capacitors, 14 is a choke coil, 15 is a discharge lamp, 37 is a high voltage pulse generator, 38 is a detector, and 39 is a high voltage pulse control. The device, 40 is a lighting control device. The power supply device 11 has the same configuration and function as in the first embodiment, and the discharge lamp 15 is started and turned on via the capacitor 12, the choke coil 14, the high voltage pulse generator 37, and the detector 38. It is connected.

The present embodiment is different from the first embodiment in that the detecting device 38 is the detecting device 38.
5 has a function of detecting activation and lighting, and a function of detecting a resonance current generated by a series resonance circuit composed of the capacitors 12 and 13 and the choke coil 14 and detecting a peak value thereof. Further, in this embodiment, the thyristor 41, which is a switch element with a control terminal, is used in place of the discharge gap 24 in the first embodiment, and the detection device 38 is placed at a place where a resonance current can be detected as shown in FIG. The high voltage pulse controller 39, which is arranged and detects its peak value, inputs the detection signal to the high voltage pulse controller 39 connected to control the gate terminal of the thyristor 41 of the high voltage pulse generator 37. That is, in this embodiment, even if the capacitor 25 connected to the output terminal of the charging circuit 36 constituting the high-voltage pulse generator 37 completes charging, it continues to receive a signal from the high-voltage pulse controller 39. 41 does not conduct, and the electric charge charged in the capacitor 25 is maintained. Then, when the detection device 38 detects the resonance current and detects the peak value of the resonance current and issues a signal to the high voltage pulse control device 39, a high voltage pulse is generated from the high voltage pulse generation device 37, and the peak of the resonance voltage. It is controlled so as to be superimposed on the value and applied to the discharge lamp 15. In the first embodiment, it was difficult to reliably generate the high voltage pulse near the peak value of the resonance voltage, whereas in the present embodiment, the high voltage pulse is reliably generated in the peak value of the resonance voltage. Then, the discharge voltage is applied to the discharge lamp 15, the effect of superimposing the high voltage pulse on the resonance voltage is enhanced, and the lamp can be more reliably started.

In this embodiment, the resonance current is detected, but the resonance voltage may be detected. Further, in the present embodiment, the peak value of the resonance is detected, but if it is a certain value or more effective for improving the startability of the discharge lamp 15, a value other than the peak value is detected and the high voltage pulse generator 37 is detected. Can be operated.

(Embodiment 4) FIG. 4 shows a fourth embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 4, 11 is a power supply device, 12 and 13 are capacitors, 14 is a choke coil, 15 is a discharge lamp, 37 is a high voltage pulse generator, 38 is a detector, and 42 is a high voltage pulse control. Device, 43 is a lighting control device, 44 is an oscillation control device, and the power supply device 11 is a capacitor 12, a choke coil 14, a high voltage pulse generation device 37, and a detection device 3.
The discharge lamp 15 is connected via 8 to start and light.

In the present embodiment, the oscillation control device 44 is arranged between the lighting control device 43 and the oscillation circuit 21 of the power supply device 11, and drives the high frequency inverter 20 of the power supply device 11 at a constant cycle. Control intermittently. at the same time,
While the oscillation circuit 21 is operating, a signal is sent from the oscillation control device 44 to the high voltage pulse control device 42 via the lighting control device 43 and the detection device 38 to operate the high voltage pulse generation device 37. A high voltage pulse is applied to the discharge lamp 15 to start and light it. Therefore, also in the case of the present embodiment, as in the case of the third embodiment, even if the capacitor 25 connected to the output end of the charging circuit 36 constituting the high voltage pulse generator 37 has completed charging, Until receiving the signal from the voltage pulse control device 42, the thyristor 4
1 does not conduct, and the electric charge charged in the capacitor 25 is maintained. Then, in synchronization with the generation period of the resonance voltage determined by the signal of the oscillation control device 44, the high voltage pulse generator 37 operates to apply the high voltage pulse to the discharge lamp 15 to start the discharge lamp 15. It lights up. As a result, even though the resonance voltage is reliably supplied to the discharge lamp 15 when a high-voltage pulse is generated, the discharge lamp 15 is intermittently controlled, so that an equivalent equivalent per unit time that flows to the capacitors 12 and 13 and the choke coil 14 at the time of resonance. Since the resonance current value can be reduced and the saturation current density required for the choke coil 14 can be lowered, the choke coil 1
4 can be miniaturized. At the same time, the capacitor 1
Since the equivalent electric power to be supplied to the power supply devices 2 and 13 and the choke coil 14 is also reduced, the maximum output power of the power supply device 11 is reduced and the power supply device 11 can be expected to be downsized.

(Embodiment 5) A fifth embodiment of the discharge lamp lighting device according to the present invention is shown in FIG. As shown in FIG. 5, 11 is a power supply device, 12 and 13 are capacitors, 45 is a choke coil, 15 is a discharge lamp, 16 is a high voltage pulse generator, 17 is a detection device, and 46 is a lighting control device. The power supply device 11 is connected via the capacitor 12, the choke coil 45, the high-voltage pulse generation device 16, and the detection device 17 so as to activate and light the discharge lamp 15.

In the present embodiment, the lighting control device 46 has a saturation current characteristic control function, and the choke coil 45 does not saturate when the resonance voltage is generated, that is, when the resonance current flows through the choke coil 45, but the discharge lamp is not. Immediately after turning on 15,
That is, the saturation current characteristic of the choke coil 45 is controlled so that the choke coil 45 is saturated during a period when a large starting current flows and the inductance component is lost. When power is supplied to the discharge lamp lighting device having such a configuration, the high voltage pulse generator 1 is generated together with the generation of the resonance voltage.
A high voltage pulse is applied to the discharge lamp 15 from 6 and the basic operation until the discharge lamp 15 is activated and lit is the same as that of the first embodiment. In this embodiment, the discharge lamp 1
Control is performed so that the choke coil 45 is saturated and the inductance component is lost during a period in which a large starting current is supplied to the discharge lamp 15 in order to quickly increase the luminous flux after the start of the No. 5 circuit. That is, when the detection device 17 detects that the discharge lamp 15 has started up, a signal is sent to the lighting control device 46, and the lighting control device 46 saturates the choke coil 45 and loses the inductance component. The oscillating frequency of the oscillating circuit 21 is controlled so that the inductance component that limits the lamp current of is a very small value. In the present embodiment, only the inductance component of the secondary winding of the pulse transformer 22 that constitutes the high voltage pulse generator 16 is present, and it is about 10% of that during stable lighting. Therefore, after the discharge lamp 15 is activated,
During the starting current supply period required for quickly raising the luminous flux, the discharge lamp 1 produces an extremely large starting current.
5 can be supplied, and the time required from the start of the discharge lamp 15 to the stable lighting can be shortened.

When the starting current is supplied to the discharge lamp 15 and the lamp voltage of the discharge lamp 15 rises, the gas pressure in the arc tube of the discharge lamp 15 rises accordingly.
The impedance of the discharge lamp 15 also increases. As a result, the lamp current is limited more than immediately after the discharge lamp 15 is started, and eventually the lamp current drops to a current value at which the choke coil 45 is not saturated. As a result, the choke coil 45 promptly recovers the inductance component and acts as a current limiting element having the inductance component necessary for stable lighting of the discharge lamp 15.

In this embodiment, the lamp current is limited due to the increase in impedance of the discharge lamp 15 after the starting current is supplied, and the inductance component of the choke coil 45 is automatically restored. The choke coil 4 by detecting an increase in the lamp voltage.
Control may be performed to recover the inductance component of No. 5.

(Sixth Embodiment) FIG. 6 shows a sixth embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 6, 11 is a power supply device, 12 and 13 are capacitors,
45 is a choke coil, 15 is a discharge lamp, 72 is a high-voltage pulse generator, 48 is a detector, 49 is a lighting controller, and the power supply device 11 is a capacitor 12, a choke coil 45, a high-voltage pulse generator 72, Detector 48
The discharge lamp 15 is connected so as to be activated and turned on via the. In the present embodiment, the high voltage pulse generator 72 is the capacitor 1 that constitutes the LC series resonance circuit.
3 includes a charging circuit 47, a discharging gap 24, and a pulse transformer 22. The charging circuit 47 includes capacitors 13, 50 and 25, resistors 51, diodes 52 and 53.
A double voltage rectifier circuit is configured by.

This embodiment is characterized in that the input terminal of the double voltage rectifying circuit which is a charging circuit is connected to both ends of the capacitor 13 which constitutes the LC series resonance circuit together with the choke coil 45. That is, the resonance voltage generated at both ends of the capacitor 13 is double-voltage rectified to generate the discharge gap 24.
The voltage required to break down the capacitor 2
Charge to 5. When the voltage charged in the capacitor 25 reaches the voltage required for the discharge gap 24 to break down, the discharge gap 24 breaks down and the generated pulse voltage is boosted by the pulse transformer 22 and applied to the discharge lamp 15. As a result, breakdown occurs between the main electrodes of the discharge lamp 15. The discharge lamp 15 is started and lit by a series of these operations.

If breakdown occurs between the main electrodes of the discharge lamp 15, the impedance of the discharge lamp 15 decreases,
LC composed of choke coil 45 and capacitor 13
The resonance condition of the series resonance circuit is broken. As a result, the voltage charged to both ends of the capacitor 25 becomes insufficient, and the generation of the high voltage pulse is quickly stopped. However, the discharge lamp 15
If the discharge lamp 15 does not transfer to the arc discharge due to lack of starting energy, etc. even if the main electrodes of the discharge lamp break down and the glow discharge is started, the discharge lamp 1
The impedance of 5 increases again, the resonance condition of the LC series resonance circuit composed of the choke coil 45 and the capacitor 13 is restored, and the high voltage is charged in the capacitor 25, whereby the high voltage pulse generator 72 operates. Then, a high voltage pulse is generated and applied to the discharge lamp 15.
By repeating these operations, the discharge lamp 15 will be completely transformed into arc discharge and will reach stable lighting. The basic operation of the power supply device 11 including the high frequency inverter 20 at this time is similar to that of the first embodiment.

The present invention is characterized in that the high frequency high voltage generated by resonance is rectified to charge the capacitor of the high voltage pulse generator, whereby the high voltage required to break down the discharge gap. Can be easily obtained with a simple configuration. That is, a sufficiently high voltage can be obtained even with a relatively low-order booster circuit. It is possible to significantly reduce the size of the charging circuit. In addition, in the double voltage rectification circuit configuration which is the charging circuit of the present embodiment, the resistor 51 is a limiting resistor for preventing the continuous discharge of the discharge gap 24, and in addition to this, the continuous discharge of the discharge gap 24 is performed. It may be omitted if measures are taken to prevent it. Further, the arrangement of the resistor 51 may be other than that of the present embodiment as long as it does not impair the effects of the present invention, such as connecting in series with the diode 52. Further, in the present embodiment, the double voltage rectifier circuit is used as the rectifier circuit, but other than this, for example, a triple voltage quadruplet or quadruple voltage rectifier circuit may be used, and conversely, the resonance voltage generated across the capacitor 13 A rectifier circuit that does not have a boosting function may be used as long as it has a sufficient voltage to break down the discharge gap 24. Further, in the present embodiment, the resonance voltage generated at both ends of the capacitor 13 by the LC series resonance circuit including the choke coil 45 and the capacitor 13 is used, but the resonance voltage generated at both ends of the choke coil 45 is also used. I do not care.

(Embodiment 7) FIG. 7 shows a seventh embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 7, 11 are a power supply device, 12 and 13 are capacitors, and
54 is a transformer whose primary winding constitutes an LC series resonance circuit together with the capacitor 13, 15 is a discharge lamp, 73
Is a high voltage pulse generator including the transformer 54, 57 is a detection device, 58 is a lighting control device, and the power supply device 11 is
The discharge lamp 15 is connected via the capacitor 12, the high-voltage pulse generator 73, and the detector 57 so as to start and light the discharge lamp 15. The high-voltage pulse generator 73 has a secondary winding of the transformer 54 as its input terminal, and uses a rectifier circuit including the capacitor 25, the resistor 55, the diode 56, the discharge gap 24, and the pulse transformer 22 as a charging circuit. There is.

In this embodiment, the input terminal of the high-voltage pulse generator 73 has its primary winding LC-connected together with the capacitor 13.
It is characterized in that it is connected to the secondary winding of a transformer 54 that constitutes a series resonance circuit. That is, by the LC series resonance circuit composed of the primary winding of the transformer 54 and the capacitor 13, the resonance voltage generated at both ends of the primary winding of the transformer 54 is transmitted to the secondary winding of the transformer 54 to boost the voltage. By rectifying, the capacitor 25 is charged with a voltage required to break down the discharge gap 24. When the voltage charged in the capacitor 25 reaches the voltage required for the discharge gap 24 to break down, the discharge gap 24 breaks down and the generated pulse voltage is boosted by the pulse transformer 22 and applied to the discharge lamp 15. To be done. This causes breakdown between the main electrodes of the discharge lamp 15. The process of starting and lighting the discharge lamp 15 by the series of operations is the same as that of the sixth embodiment. The basic operation of the power supply device 11 including the high frequency inverter 20 at this time is the same as that of the first embodiment.

A feature of the present invention is that the resonance voltage generated by the LC series resonance is boosted by using a transformer, so that the voltage required to break down the discharge gap even if the rectifier circuit does not have a boosting function. Is to be able to charge the capacitor. That is, the resonance voltage generated across the primary winding of the transformer 54 can be easily boosted to an arbitrary voltage value by operating the number of turns of the secondary winding. Therefore, since the step of boosting the rectifier circuit can be omitted, the rectifier circuit can be reduced in size and weight. Note that, also in this embodiment, as in the case of the sixth embodiment, the resistor 51, which constitutes the rectifying circuit, has the discharge gap 2
4 is a limiting resistance for preventing the continuous discharge of No. 4 and may be omitted if other means for preventing the continuous discharge of the discharge gap 24 is taken. Also, the arrangement of the resistor 51 is
Other than the case of the present embodiment, other devices such as a diode 56 connected in series may be used as long as they do not impair the effects of the present invention.

(Embodiment 8) FIG. 8 shows an eighth embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 8, 11 is a power supply device, 12 and 13 are capacitors,
14 is a choke coil, 15 is a discharge lamp, 37 is a high voltage pulse generator, 59 is a detector, 39 is a high voltage pulse controller, and 60 is a lighting controller. Power supply 11
The configuration and function of the discharge lamp 15 are the same as those of the first embodiment, and the discharge lamp 15 is connected via the capacitor 12, the choke coil 14, the high voltage pulse generator 37, and the detector 59.
Is connected to start up and light up.

The present embodiment is different from the first embodiment in the detection device 59. The detection device 59 is the discharge lamp 1.
5 has the function of detecting the start-up and lighting, and by detecting the resonance current generated by the series resonance circuit composed of the capacitors 12 and 13 and the choke coil 14, the peak value of the resonance voltage with the phase shifted by 90 degrees. Is to have a function of detecting. Further, in the present embodiment, the thyristor 41, which is a switch element with a control terminal, is used in place of the discharge gap 24 in the first embodiment, and the detection device 59 is located at a place where the resonance current can be detected as shown in FIG. A high voltage pulse control device 39 which is arranged so as to detect the peak value of the resonance voltage whose phase is shifted by 90 degrees and to connect the detection signal to control the gate terminal of the thyristor 41 of the high voltage pulse generation device 37. To enter. That is, in this embodiment, the capacitor 25 connected to the output terminal of the charging circuit 36 that constitutes the high voltage pulse generator 37.
Even when the charging is completed, the thyristor 41 does not conduct until the signal from the high voltage pulse control device 39 is received, and the charge charged in the capacitor 25 is maintained. Then, when the detection device 59 detects the resonance current to detect the peak value of the resonance voltage and issues a signal to the high voltage pulse control device 39, a high voltage pulse is generated from the high voltage pulse generation device 37, as shown in FIG. As described above, it is controlled so as to be applied to the discharge lamp 15 so as to be superimposed on the peak value of the resonance voltage. That is, the gate signal is controlled so that the thyristor 41 becomes conductive near the peak value of the phase of the resonance voltage generated across the capacitor 13. In the first and third embodiments, it was difficult to reliably generate the high voltage pulse near the peak value of the resonance voltage, whereas in the present embodiment, the high voltage pulse is reliably resonated. Since the voltage is applied to the discharge lamp 15 at the peak value, the effect of superimposing the high voltage pulse on the resonance voltage is enhanced, and the lamp can be started more reliably than in the first and third embodiments. Becomes

In this embodiment, the resonance current is detected, but the resonance voltage may be detected. Further, in the present embodiment, the peak value of the resonance current is detected, but if the peak value of the resonance current is equal to or higher than a certain value effective in improving the startability of the discharge lamp 15, the high voltage pulse generator 37 is detected by detecting a value other than the peak value. Can be operated.

(Embodiment 9) FIG. 10 shows a ninth embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 10, as components, 11 is a power supply device, 12 and 13 are capacitors, 14 is a choke coil, 15 is a discharge lamp, 37 is a high voltage pulse generator, 61 is a detection device, and 39 is a high voltage pulse control device. 62 are lighting control devices. The power supply device 11 has the same configuration and function as those in the first embodiment, and the discharge lamp 15 is activated and lit via the capacitor 12, the choke coil 14, the high voltage pulse generator 37, and the detector 61. It is connected.

The present embodiment is different from the first embodiment in the detection device 61. The detection device 61 is the discharge lamp 1
5 has the function of detecting the start-up and lighting, and the function of detecting the peak value of the resonance current by detecting the resonance current generated by the series resonance circuit composed of the capacitors 12 and 13 and the choke coil 14. That is. Further, in this embodiment, the thyristor 41, which is a switch element with a control terminal, is used in place of the discharge gap 24 in the first embodiment, and the detection device 61 is
As shown in FIG. 10, it is arranged at a place where the resonance current can be detected, the peak value of the resonance current is detected, and the detection signal is connected to control the gate terminal of the thyristor 41 of the high-voltage pulse generator 37. Input to the voltage pulse controller 39.

That is, in this embodiment, even if the capacitor 25 connected to the output terminal of the charging circuit 36 constituting the high voltage pulse generator 37 has completed charging, it receives a signal from the high voltage pulse controller 39. Until then, the thyristor 41 does not conduct, and the electric charge charged in the capacitor 25 is maintained. Then, when the detection device 61 detects the resonance current to detect the peak value of the resonance voltage and issues a signal to the high voltage pulse control device 39, a high voltage pulse is generated from the high voltage pulse generation device 37, as shown in FIG. In this way, it is controlled so as to be applied to the discharge lamp 15 so as to be superimposed on the peak value of the resonance current. That is, the gate signal is controlled so that the thyristor 41 becomes conductive in the vicinity of the peak value of the resonance current generated at both ends of the capacitor 13. In the first and third embodiments, it was difficult to reliably generate the high voltage pulse near the peak value of the resonance current, whereas in the present embodiment, the high voltage pulse is reliably resonated. The current is applied to the discharge lamp 15 at the peak value. As a result, after the discharge lamp 15 is activated, it is possible to easily supply a large starting current, which is the energy required for the transition from the glow discharge to the arc discharge. Conventionally, these starting energies largely depend on the energy of the high voltage pulse applied to the discharge lamp, and only the starting energy of the high voltage pulse is necessary for the discharge lamp to change from glow discharge to arc discharge. There was a problem that the discharge lamp was apt to go out immediately after breakdown due to lack of energy. According to the present invention, it becomes possible to reliably supply the starting energy even if the energy possessed by the high voltage pulse is reduced.
Even if the size is reduced, the lamp can be activated more reliably than in the first and third embodiments.

In this embodiment, the resonance current is detected, but the resonance voltage may be detected. Further, in the present embodiment, the peak value of the resonance current is detected, but if the peak value of the resonance current is equal to or higher than a certain value effective in improving the startability of the discharge lamp 15, the high voltage pulse generator 37 is detected by detecting a value other than the peak value. Can be operated.

(Embodiment 10) FIG. 12 shows a tenth embodiment of the discharge lamp lighting device according to the present invention. As shown in FIG. 12, 11 are a power supply device, 12 and 13 are capacitors, 14 is a choke coil, 15 is a discharge lamp, and 6 are components.
3 is a high voltage pulse generator, 17 is a detector, and 18 is a lighting controller. The power supply device 11 has the same configuration and function as in the first embodiment, and after the discharge lamp 15 is started by the high voltage pulse generator 63, the discharge is performed via the capacitor 12, the choke coil 14, and the detection device 17. The lamp 15 is connected to light.

This embodiment is different from the first embodiment in a high voltage pulse generator 63, which is connected in parallel with a capacitor 13 which constitutes an LC series resonance circuit. The circuit 23, the capacitor 25 connected to the output end of the charging circuit, the discharge gap 24, and the pulse transformer 22, one end of which is connected to the output end of the secondary winding of the pulse transformer 22 and inside or outside the arc tube of the discharge lamp The auxiliary electrode 64 for starting is provided on the.

When the power supply device 11 is driven, the capacitor 1
A resonance voltage is generated at both ends of the capacitor 3, and the capacitor 25 is charged with the high frequency output from the charging circuit 23 connected in parallel with the capacitor 13. When the voltage charged in the capacitor 25 reaches the breakdown voltage of the discharge gap 24, the discharge gap 24 breaks down and pulse energy is input to the primary winding of the pulse transformer 22 via the discharge gap 24. The output voltage of the pulse transformer 22 is applied to the discharge lamp 15 via the auxiliary starting electrode 64,
The breakdown between the main electrodes of the discharge lamp 15 is made.

After the breakdown between the main electrodes of the discharge lamp 15, the control operation of the lighting control device 18 until stable lighting and the basic operation of the power supply device 11 including the high frequency inverter 20 are the same as in the present invention. Similar to the first embodiment, the starting auxiliary electrode 64 does not affect the characteristics of the lamp during lighting.

According to the present invention, the high voltage pulse generated in the secondary winding of the pulse transformer 22 is supplied to the auxiliary auxiliary electrode 64 for starting provided in the discharge tube of the discharge lamp 15 or in the vicinity thereof.
It is characterized in that it is applied to the discharge lamp 15 via the. In this case, the auxiliary auxiliary electrode 64 is used for the discharge lamp 15
It acts as a proximity conductor provided in the arc tube or in the vicinity thereof and has the effect of reducing the distance between the main electrodes of the discharge lamp 15 and lowering the starting voltage of the discharge lamp 15. Therefore, the discharge lamp can be restarted with a low pulse voltage as compared with the case where the high voltage pulse generated in the secondary winding of the pulse transformer is directly applied to the discharge lamp as in the first embodiment of the present invention. Will be possible.

As a result, the voltage generated by the high-voltage pulse generator can be set lower than that in the first embodiment of the present invention, so that the output voltage of the charging circuit and the pulse transformer constituting the high-voltage pulse generator are set. It is possible to reduce the high voltage pulse generator, and as a result, it is possible to downsize the high voltage pulse generator as compared with the case of the first embodiment of the present invention. Although the auxiliary electrode for starting is provided near the outside of the arc tube of the discharge lamp in FIG. 12 for explaining the present embodiment, it may be installed inside the arc tube of the discharge lamp.

(Embodiment 11) FIG. 13 shows an eleventh embodiment of the discharge lamp lighting device according to the present invention. In addition, in FIG.
The structure of the discharge lamp 15 of the eleventh embodiment of the discharge lamp lighting device of the present invention and the starting auxiliary electrode 65 provided in the vicinity thereof is shown.
The configurations and functions of the other elements are the same as those in the tenth embodiment.

This embodiment differs from the tenth embodiment in that
It is the structure of the auxiliary electrode 65 for starting, and in this embodiment, it is shown in FIG.
As shown in FIG. 3, at least the surface of the starting auxiliary electrode 65 facing the arc tube of the discharge lamp 15 is covered with an insulator 66.

Generally, as a means for facilitating the starting of a discharge lamp, when a starting auxiliary electrode is provided near the outside of the arc tube of the discharge lamp, a decrease in luminous flux due to devitrification of the arc tube becomes a major problem. This is because the auxiliary starting electrode is negatively charged during the lighting of the discharge lamp. That is,
When light is emitted to the starting auxiliary electrode by the light emission of the discharge lamp, photoelectrons are emitted from the starting auxiliary electrode made of metal. As a result, the starting auxiliary electrode is negatively charged while the discharge lamp is lit. The metal encapsulated as iodide in the arc tube of the discharge lamp is ionized during lighting and exists as ions in the arc tube. Of these, sodium ions have a positive charge and their ionic radius is particularly small. Therefore, when the auxiliary starting electrode attached near the outer wall of the arc tube is negatively charged, it is attracted to the auxiliary auxiliary electrode and passes between the quartz crystals constituting the arc tube to the outside of the arc tube. leak. As a result, the arc tube is devitrified, and the life of the lamp is shortened such that the luminous flux is reduced.

The present embodiment is characterized in that at least the surface of the auxiliary starting electrode 65 facing the arc tube of the discharge lamp 15 is covered with an insulator 66. As a result, the main electrode tube distance of the discharge lamp 15 is shortened by the presence of the auxiliary starting electrode 65, and the starting auxiliary electrode is irradiated from the lit discharge lamp 15 without impairing the effect that the voltage required for starting can be reduced. The light that is emitted can be blocked.
Therefore, photoelectrons are not emitted from the auxiliary starting electrode 65 during the lighting of the discharge lamp 15, and the auxiliary auxiliary electrode 65 is not negatively charged, so that devitrification of the arc tube due to the outflow of sodium ions can be prevented. As a result, it is possible to provide a discharge lamp lighting device in which the starting voltage of the discharge lamp 15 is lowered and the lamp life is prevented from being shortened due to a decrease in luminous flux.

The insulator 66 used in this embodiment is non-conductive, such as ceramic or glass, does not deteriorate even under high temperature conditions near the arc tube, and does not affect the lamp characteristics during lighting. Is. Further, in the present embodiment, the discharge lamp 1 is provided on the surface of the auxiliary auxiliary electrode 65.
Although only the surface of No. 5 facing the arc tube is covered with the insulator 66, as shown in FIG.
The structure may be such that the sheath is completely covered with the sheath-shaped insulator 67.

(Embodiment 12) A twelfth embodiment of the discharge lamp lighting device according to the present invention is shown in FIG. In addition, in FIG.
The structure of the discharge lamp 68 of the 12th Example of the discharge lamp lighting device in this invention is shown. In the present embodiment, when the discharge lamp 68 is started, a high voltage pulse is applied to the discharge lamp 68 from the high voltage pulse generator 69 via the auxiliary auxiliary electrode 70 for starting the breakdown between the main electrodes of the discharge lamp 68. The lighting operation until the stable lighting is started is basically the same as that of the tenth embodiment. This embodiment is the tenth embodiment of the discharge lamp lighting device according to the present invention.
The present embodiment is different from the above embodiment in the arrangement of the high voltage pulse generator 69, and in this embodiment, the high voltage pulse generator 69 is incorporated in the discharge lamp 68.

In this embodiment, when the discharge lamp 68 is started, the high voltage pulse generator 69 superimposes the resonance voltage supplied from the outside of the discharge lamp 68 on the auxiliary auxiliary electrode 7 for starting.
A high voltage pulse is generated via 0 and applied to the discharge lamp 68. In this case, since the high-voltage pulse for starting the discharge lamp 68 can be generated inside the lamp, the attenuation due to long-distance transmission of the pulse is minimized and the pulse existing outside the discharge lamp is minimized. It is possible to prevent radiation noise from the transformer and the pulse transmission line. Further, since the pulse attenuation is small, the peak value of the high voltage pulse generated by the high voltage pulse generator 69 can be lowered, and the high voltage pulse generator 69 can be downsized.

The high voltage pulse generator 69 does not block the light output from the discharge lamp 68 during lighting, and does not affect the lighting characteristics of the other discharge lamp 68.
Further, in this embodiment, the discharge lamp 68 has a single-ended mold structure, but a double-ended mold structure may also be used.

(Thirteenth Embodiment) A thirteenth embodiment of the discharge lamp lighting device according to the present invention will be described. FIG. 16 is a configuration diagram showing this embodiment, and the basic configuration of this embodiment is the same as that of the first embodiment of the discharge lamp lighting device of the present invention. In the present embodiment, the impedance of the resonance circuit, that is, the value of the inductance of the choke coil 14 and the capacitance of the capacitor 13, which form the LC series resonance circuit, is shown in FIG.
The output is set to resonate with the third harmonic (shown in FIG. 17B). Then, the oscillation frequency of the high-frequency inverter 20 is changed according to the state of the discharge lamp 15, and the control function is provided so that the oscillation frequency of the high frequency inverter 20 can be set to the basic resonance frequency (shown in FIG. 17C) determined by the impedance of the resonance circuit. Characterize. In addition, in FIG. 17, VL
Is the output voltage of the high frequency inverter 20, IL1 and IL2
Shows the waveform of the current flowing through the choke coil 14.

With the discharge lamp lighting device according to the present embodiment, the discharge lamp 15 is in a cold state, that is, after the lamp is turned off, a sufficient time has elapsed, and the gas pressure, temperature, etc. in the arc tube are being turned on or immediately after the lamp is turned off. The circuit operation when the discharge lamp 15 is started when the discharge voltage is sufficiently lower than the above will be described. When the DC power supply 19 is turned on, the high-frequency inverter 20 first oscillates at a low frequency of about 2 kHz, and chokes this low-frequency voltage, as in the case of the first embodiment of the discharge lamp lighting device according to the present invention. Coil 14,
And a series resonance circuit composed of the capacitor 13. When the high frequency resonance voltage generated by the resonance circuit is superimposed on the low frequency voltage generated at this time, the detection device 1
7 detects this resonance voltage.

The lighting control device 71 uses the detected voltage to
The oscillation frequency of the high frequency inverter 20 is, for example, 33 kHz.
Change to a frequency around z. This frequency is set near the third harmonic of the fundamental resonance frequency determined by the impedance of the LC series resonance circuit, and the capacitor 13
A resonance voltage of about several kV is generated at both ends of the discharge lamp 1
5 is supplied. A high-voltage pulse generator 16 generates a high-voltage pulse by superimposing it on the resonance voltage and applies it to the discharge lamp 15. As a result, the breakdown between the main electrodes of the discharge lamp 15 starts, and the initial discharge is started. The operation of the high-frequency inverter 20 after breakdown between the main electrodes of the discharge lamp 15 and until stable lighting is the same as in the first embodiment of the present invention. That is, when the main electrodes of the discharge lamp 15 break down and the initial discharge is started, the starting current generated by resonance flows into the discharge lamp 15 via the choke coil 14. Through these series of operations, the discharge lamp 15 can be started and turned on without being extinguished during the transition from the glow discharge to the arc discharge.

Next, the discharge lamp 15 is discharged in a hot state, that is, in a state where the gas pressure, temperature, etc. in the arc tube are higher than those in the cold state, not sufficiently after the lamp is turned off. The operation of starting (restarting) the lamp 15 will be described. Also in this case, after the DC power supply 19 is turned on,
The circuit operation until the detection device 17 detects the resonance voltage is
This is the same as the case of the first embodiment of the present invention. In the present embodiment, the detection device 17 simultaneously detects the lamp temperature, which is one of the characteristics relating to the state of the lamp, such as the surface temperature of the arc tube of the discharge lamp 15 and the temperature of the outside air near the discharge lamp 15. The discharge lamp 15 has a function of detecting the lamp state and determining whether the discharge lamp 15 is in a cold state or a hot state. If the discharge lamp 15 is in a hot state, the lighting control device 71 changes the oscillation frequency of the high frequency inverter 20 to a frequency of, for example, about 100 kHz, which is higher than that at the time of cold start, according to the detection signal from the detection device 17. This frequency is set in the vicinity of the fundamental resonance frequency determined by the impedance of the LC series resonance circuit, and a resonance voltage higher than that in the case of resonance using the third harmonic is generated at both ends of the capacitor 13 to cause a discharge lamp. 15 are supplied.

A high voltage pulse is generated from the high voltage pulse generator 16 by superimposing on the resonance voltage, and the discharge lamp 15
Apply to. As a result, the breakdown between the main electrodes of the discharge lamp 15 starts, and the initial discharge is started. Discharge lamp 15
After starting the initial discharge, the starting current generated by resonance flows into the discharge lamp 15 through the choke coil 14, the discharge lamp 15 transitions to the arc discharge through the glow discharge, and the operation up to lighting, And, the method of adjusting the oscillation frequency of the high frequency inverter 20 and starting the discharge lamp 15 at the rated lighting after the discharge lamp 15 is started is as follows.
This is the same as when the discharge lamp 15 is in the cold state.

Generally, during cold starting of the discharge lamp 15,
Since the electrode temperature is lowered, even if the breakdown occurs between the main electrodes, the starting energy is often insufficient and the lamp disappears during the transition from glow discharge to arc discharge.
The energy required at this time does not require a high voltage, but it is essential that it has a large resonance current sufficient to raise the temperature of the electrodes. Therefore, when the energy for transferring the glow discharge to the arc discharge is supplied by the resonance circuit of the power supply device as in the present invention,
The resonance frequency is preferably a low frequency.

According to this embodiment, when the discharge lamp 15 is cold started, the high frequency inverter is operated at about 33 kHz even though the basic resonance frequency is about 100 kHz. Therefore, although the resonance voltage that can be supplied is low due to resonance at a frequency lower than the basic resonance frequency, sufficient energy due to a large resonance current can be supplied to the discharge lamp 15, and the startability of the discharge lamp 15 during cold starting can be improved. Can be improved.

Further, in this embodiment, since the third harmonic of the oscillation frequency of the high frequency inverter is used as the resonance frequency, the choke coil 14 constituting the LC series resonance circuit is prevented from becoming large in size when determining the resonance condition. Therefore, when the value of the inductance is constant, the capacity of the capacitor 13 required to resonate at a low frequency of 1/3 of the basic resonance frequency needs to be three times as large as when resonating at the basic resonance frequency. Absent. Therefore, it is possible to prevent the capacitor 13 for generating a large resonance current required for supplying the starting energy to the discharge lamp 15 from increasing in size, and to increase the capacity of the capacitor 13 connected in parallel to the discharge lamp 15. As a result of the increase in the discharge current, the lamp current has a rest period, which makes it difficult to start the discharge lamp 15, or flicker occurs or disappears for a certain period after the start of the discharge lamp 15. It is possible to improve the startability of the discharge lamp 15 during cold starting.

On the other hand, when the discharge lamp 15 is hot-restarted, the electrode temperature is sufficiently increased. Therefore, the energy supplied to the discharge lamp 15 for converting the glow discharge to the arc discharge is higher than that at the cold start. It can be a small one. However, the temperature and pressure inside the arc tube are both rising, and a higher voltage is required in order to break down between the main electrodes as compared with the cold start. Therefore, in this case, the high frequency inverter is operated at the basic resonance frequency, and a resonance voltage higher than that at the cold start is supplied to the discharge lamp 15 to facilitate the breakdown between the main electrodes. As a result, it is possible to provide a discharge lamp lighting device that has good startability regardless of the state of the discharge lamp 15 and that can be downsized.

[0066]

As is apparent from the above description, the discharge lamp lighting device of the present invention is provided with a high voltage pulse generator for generating a high voltage pulse, and the LC series resonance which constitutes the lighting device when the discharge lamp is started. The resonant voltage generated by the circuit
By superimposing a high-voltage pulse on the discharge lamp and applying it to the discharge lamp, it is possible to provide a discharge lamp lighting device capable of improving the startability of the discharge lamp and realizing a drastic downsizing of the lighting device. 4. Brief description of the drawings

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a discharge lamp lighting device according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a discharge lamp lighting device according to a second embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a discharge lamp lighting device according to a third embodiment of the present invention.

FIG. 4 is a block diagram showing a configuration of a discharge lamp lighting device according to a fourth embodiment of the present invention.

FIG. 5 is a block diagram showing the configuration of a discharge lamp lighting device according to a fifth embodiment of the present invention.

FIG. 6 is a block diagram showing a configuration of a discharge lamp lighting device according to a sixth embodiment of the present invention.

FIG. 7 is a block diagram showing the configuration of a discharge lamp lighting device according to a seventh embodiment of the present invention.

FIG. 8 is a block diagram showing the configuration of a discharge lamp lighting device according to an eighth embodiment of the present invention.

FIG. 9 is a waveform diagram for explaining the operation of the discharge lamp lighting device of the same embodiment.

FIG. 10 is a block diagram showing the configuration of a discharge lamp lighting device according to a ninth embodiment of the present invention.

FIG. 11 is a waveform diagram for explaining the operation of the discharge lamp lighting device of the same embodiment.

FIG. 12 is a block diagram showing a configuration of a discharge lamp lighting device according to a tenth embodiment of the present invention.

FIG. 13 is a side view showing the structure of a discharge lamp used in the discharge lamp lighting device of the eleventh embodiment of the present invention.

FIG. 14 is a side view showing another structure of the discharge lamp used in the discharge lamp lighting device of the embodiment.

FIG. 15 is a side view showing the structure of a discharge lamp used in the discharge lamp lighting device according to the twelfth embodiment of the present invention.

FIG. 16 is a block diagram showing the configuration of a discharge lamp lighting device according to a thirteenth embodiment of the present invention.

FIG. 17 is a waveform diagram of a resonance voltage and a resonance current for explaining the operation of the discharge lamp lighting device of the embodiment.

FIG. 18 is a block diagram showing a configuration of a conventional discharge lamp lighting device.

[Explanation of symbols]

11 power supply 12, 13 capacitors 14 choke coil 15 discharge lamp 16 High voltage pulse generator 17 Detector 18 Lighting control device 19 DC power supply 20 high frequency inverter 22 pulse transformer 23 Charging circuit

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Takuyuki Kamiya             1006 Kadoma, Kadoma-shi, Osaka Matsushita Electric             Sangyo Co., Ltd. (72) Inventor Shigeru Horii             1006 Kadoma, Kadoma-shi, Osaka Matsushita Electric             Sangyo Co., Ltd.

Claims (14)

[Claims] 1. A DC power supply, a high-frequency inverter that is driven by the DC power supply to oscillate, a resonance circuit including a series circuit of a choke coil and a capacitor connected to an output terminal of the high-frequency inverter, the choke coil and a capacitor. A discharge lamp connected to the connection point of the discharge lamp, a high-voltage pulse generator connected to the discharge lamp so as to apply a high-voltage pulse in series or in parallel, and a detection device for detecting characteristics relating to the lamp characteristics of the discharge lamp. And a lighting control device that controls lighting of the discharge lamp by varying the oscillation frequency or duty ratio of the high frequency inverter or limiting the output current of the DC power supply according to the output signal of the detection device. 2. The detection device is configured to detect the start / lighting of the discharge lamp, and the lighting control device to stop the output of the high voltage pulse generation device according to the output signal of the detection device. The discharge lamp lighting device according to 1. 3. A trigger signal for detecting a resonance voltage or a resonance current increased by a resonance circuit to at least a certain value and a trigger signal for operating a high voltage pulse generator upon receiving a signal from the detection device. A switching element having a control terminal for generating a high voltage pulse control device, wherein the high voltage pulse generation device receives a trigger signal from the high voltage pulse control device and operates to apply a high voltage pulse to a discharge lamp. The discharge lamp lighting device according to claim 1 or 2, further comprising: 4. A trigger for operating a high-voltage pulse generator in synchronization with the generation of a resonance voltage in response to a signal from the oscillation control device, the oscillation control device controlling the high-frequency inverter to intermittently oscillate. The discharge lamp lighting device according to claim 1, further comprising a high-voltage pulse control device that generates a signal. 5. The discharge lamp lighting device according to claim 1, wherein the lighting control device has a saturation current characteristic control function such that the choke coil is saturated when the detection device detects activation of the discharge lamp. . 6. The discharge circuit according to claim 1, wherein the high-voltage pulse generator comprises, as a charging circuit, a rectifier circuit connected to a resonance circuit composed of a series circuit of a choke coil and a capacitor connected to the output terminal of the high-frequency inverter. Electric lighting device. 7. The discharge lamp lighting according to claim 1, wherein the choke coil is composed of a primary winding of the transformer, and the high-voltage pulse generator comprises a rectifying circuit connected to the secondary winding of the transformer as a charging circuit. apparatus. 8. The discharge device according to claim 3, wherein the detection device has a function of detecting at least the phase of the resonance voltage or the resonance current, and the high voltage pulse generation device operates in synchronization with the vicinity of the peak value of the resonance voltage. Electric lighting device. 9. The discharge device according to claim 3, wherein the detection device has a function of detecting at least the phase of the resonance voltage or the resonance current, and the high voltage pulse generation device operates in synchronization with the vicinity of the peak value of the resonance current. Electric lighting device. 10. The discharge lamp has a starting auxiliary electrode provided in the arc tube or in the vicinity thereof, and a high voltage pulse generator supplies a high voltage pulse to the discharge lamp via the starting auxiliary electrode. The discharge lamp lighting device according to claim 1, which is applied. 11. The auxiliary starting electrode has at least a surface facing the arc tube of the discharge lamp covered with an insulating material.
The discharge lamp lighting device described. 12. The discharge lamp lighting device according to claim 10, wherein the high voltage pulse generator is built in the discharge lamp. 13. The discharge control device according to claim 1, wherein the lighting control device varies the frequency of the output of the high-frequency inverter so as to resonate with the fundamental resonance frequency of the resonance circuit or a harmonic thereof according to the output signal of the detection device. Electric lighting device. 14. The discharge lamp lighting device according to claim 13, wherein the lighting control device changes the oscillation frequency of the high frequency inverter at least when the discharge lamp is restarted.