JP2005340064A - High pressure discharge lamp lighting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To restrain flicker of a high pressure discharge lamp. <P>SOLUTION: The high pressure discharge lamp 6 is lighted by converting direct current into alternating current by a DC/AC inverter circuit 4 after boosting the direct current voltage impressed on an input side by a DC/DC converter circuit 1, and by supplying the alternating current to the high pressure discharge lamp 6. When a polarity of a current I<SB>L</SB>of the high pressure discharge lamp 6 lighted by a square wave is inverted, output voltage DC/DC of the DC/DC converter circuit 1 is increased to not less than 1.5 times the voltage V<SB>L</SB>of the high pressure discharge lamp 6 at lighting. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a lighting device for a high pressure discharge lamp used for lighting a vehicle headlamp.

In a conventional high pressure discharge lamp lighting device, the input side of a voltage supply source that generates a direct current is connected to a power source for supplying the voltage, and the output side of the voltage supply source converts the direct current into an alternating current. A commutator is connected, and a high-pressure discharge lamp connected to the output side thereof is lit by an alternating lamp current. The voltage supply source is connected to means for generating a current pulse in each half cycle of the lamp current. (For example, Patent Document 1)
Japanese translation of PCT publication No. 10-501919 (pages 7-11, FIGS. 1, 2, 4)

  In a conventional lighting device that lights a high-pressure discharge lamp with an alternating lamp current, the polarity of the lamp current is reversed, so that it is difficult to balance the temperature of the electrodes, and the stability of the discharge is poor. As a result, the base point of the arc discharge moves on the electrode surface, causing a flicker phenomenon called flicker. This flicker phenomenon is particularly noticeable in high-pressure discharge lamps used for automobile headlamps. This is due to a special lighting method in which the power immediately after lighting is about twice as much as that during stable lighting.

  With respect to this problem, in the lighting device for a high pressure discharge lamp disclosed in Patent Document 1, a current having the same polarity as the polarity of the lamp current is generated in the latter half of the lamp current by means of generating a current pulse connected to the voltage supply source. By superimposing the pulse on the lamp current, the stability of the discharge is increased and the occurrence of flicker is suppressed.

  However, in the lighting method of Patent Document 1, if it is assumed that the lamp is lit at a constant power, the lamp current must be reduced and lighted in other time zones by the amount of addition of the pulsed current. Disappear. As a result, it was found that the discharge is less stable and flickering occurs.

  In addition, when lighting a high-pressure discharge lamp that does not enclose mercury, the power-on time at the beginning of lighting is longer than that of a high-pressure discharge lamp enclosing mercury, and during that time, a large current flows, so the electrode does not deform or melt during that time. Designed so thick. Therefore, in the lighting of a high-pressure discharge lamp that does not enclose mercury, it can be said that the method of superimposing the lamp current is a means that discharges other than the time when the lamp current is superimposed are more difficult to stabilize and flickering is likely to occur.

  An object of the present invention is to provide a lighting device for a high pressure discharge lamp that suppresses the occurrence of flicker.

  After the DC voltage applied to the input side is stepped down or boosted by a DC / DC converter circuit, the DC power is converted into AC power by a DC / AC inverter circuit, and the AC power is supplied to a high pressure discharge lamp. In a high pressure discharge lamp lighting device for lighting a discharge lamp, when the polarity of the current of the high pressure discharge lamp that is lit with a substantially rectangular wave is reversed, the output voltage of the DC / DC converter circuit is changed to the high pressure discharge lamp. It is characterized by being set to 1.5 times or more with respect to the voltage at the time of stable lighting.

  According to the present invention, occurrence of flicker can be suppressed.

(First embodiment)
Hereinafter, a lighting device for a high pressure discharge lamp according to an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a circuit diagram illustrating a lighting device for a high-pressure discharge lamp according to a first embodiment of the present invention.

  The lighting device for the high pressure discharge lamp includes a DC power source V1, a switch S1, a DC / DC converter circuit 1, an output voltage detection circuit 2, an output current detection circuit 3, a DC / AC inverter circuit 4, an igniter 5, a high pressure discharge lamp 6, and It consists of a control circuit that controls these.

  The DC / DC converter circuit 1 includes a capacitor C1, a switching element Q1, a power MOS drive circuit 11, a PWM comparator 12, a sawtooth wave generation circuit 13, and a transformer T1, which constitutes the primary side of the transformer T. The transformer T2 and the diode D1 The secondary side of the transformer T connected to the DC / AC inverter circuit 4 by the capacitor C2 constitutes the secondary side of the transformer T connected to the igniter 5 by the transformer T3, the diode D2, and the capacitor C3.

  The connection relationship on the primary side of the transformer T will be described. For example, the switching element Q1, which is a MOSFET, is connected in series to the DC power source V1, the switch S1, and the transformer T1, and the power MOS drive circuit 11 is connected to the gate thereof. Is connected. A PWM comparator 13 is connected to the power MOS drive circuit 11, and a sawtooth wave generation circuit 13 is connected to its non-inverting input terminal. The capacitor C1 is connected in parallel to the DC power supply V1 through the switch S1.

  The connection relationship on the secondary side of the transformer T connected to the DC / AC inverter circuit 4 will be described. The transformer T2 is connected in series to the diode D1, and the capacitor C2 is connected in parallel to the transformer T2 via the diode D1. ing.

  The connection relationship on the secondary side of the transformer T connected to the igniter 5 will be described. The transformer T3 is connected in series with the middle point of the transformer T2 and the diode D1 and the diode D2, and constitutes an output to the igniter 5. The capacitor C3 is connected in parallel to the transformer T3 via the diode D2.

  The output voltage detection circuit 2 includes resistors R1 to R3 connected in series, and is connected to the output side of the capacitor C2 and in parallel to the capacitor C2.

  The output current detection circuit 3 includes a resistor R4, and is connected between the output voltage detection circuit 2 and the DC / AC inverter circuit 4 and on the low voltage side.

  The DC / AC inverter circuit 4 includes, for example, switching elements Q2 to 5 made of MOSFETs, drive circuits 14 to 17, a rectangular low frequency generation circuit 18, a buffer BUF, and an inverter INV. The connection relationship is a so-called full-bridge circuit configuration in which switching elements Q2 and Q3 and switching elements Q4 and Q5 are connected in series, and are connected in parallel to the output terminal of the DC / DC converter circuit 2. It has become. An output terminal of the DC / AC inverter circuit 4 is provided from a connection point between the switching elements Q2 and Q3 and the switching elements Q4 and Q5. Driving circuits 14 to 17 are connected to the gates of the switching elements Q2 to Q5, respectively, the driving circuits 15 and 16 are connected to the buffer BUF, the driving circuits 14 and 17 are connected to the inverter INV, and are further connected to SW2, which will be described later. Are connected to the rectangular low-frequency oscillation circuit 16.

  The igniter 5 includes capacitors C4 and C5, a pulse transformer L, and a gas arrester GA. The capacitor C4 is connected in parallel to both ends of the output end of the DC / AC inverter circuit 4. The capacitor C5 is connected in series via the output terminal of the transformer T3 and the resistor R5. The pulse transformer L is connected in series to one of the outputs of the DC / AC inverter circuit 4. The pulse transformer L is connected to a gas arrester GA connected in parallel to the capacitor C5.

  The high-pressure discharge lamp 6 is a lamp that does not contain mercury in the discharge space, and instead emits light by evaporating metal halide and rare gas, and the pulse transformer L of the igniter 5 is connected to the output terminal of the DC / AC inverter circuit 4. Connected through.

  The control circuit for controlling the switching element Q1 of the DC / DC converter circuit 1 includes a differential amplifier circuit 7, a reference voltage V2, a resistor R8, a lighting detection circuit 21, a lighting time timer 22, and a target power value. A setting circuit 23, a dividing circuit 24, a turn-off time timer 25, a switch SW2, a differential amplifier circuit 8, a delay circuit 26, a logic circuit 27, a switch SW3, a switching element Q6, and resistors R9 to R12 are used.

  The differential amplifier circuit 7 includes an OP amplifier 19, a diode D3, a resistor R6, and a capacitor C6. A voltage detection point between the resistor R1 and the resistors R2 and R3 of the input voltage detection circuit 2 is connected to the non-inverting input terminal of the input of the OP amplifier 19, and a reference voltage V2 is connected to the inverting input terminal, respectively. A diode D3 is connected in series to the end. A resistor R6 and a capacitor C6 are connected in parallel to the series connection of the OP amplifier 19 and the diode D3. The output terminal of the differential amplifier circuit 7 is connected to the input of the inverting input terminal of the PWM comparator 12 via the resistor R8.

  The differential amplifier circuit 8 includes an OP amplifier 20, a diode D4, a resistor R7, and a capacitor C7. The connection relationship is the same as that of the differential amplifier circuit 7. A voltage detection point between the resistor R4 of the input current detection circuit 3 and the DC / AC inverter circuit 4 is connected to the non-inverting input terminal of the input of the OP amplifier 20, and a division circuit 24 is connected to the inverting input terminal. . The division circuit 24 includes a voltage detection point between the resistors R1, R2 and the resistor R3 of the input voltage detection circuit 2, a voltage detection point between the resistors R1, R2 and the resistor R3, a lighting detection circuit 21, and a lighting time. A target power value setting circuit 23 is connected via a timer 22. Further, a lighting detection circuit 21 is connected to the lighting time timer 22 via a light-out timer 23. The lighting time timer 22 and the target power value setting circuit 23 are connected to switches SW2 and SW3 that are switched or opened / closed after a predetermined time when an input is input, respectively. The output terminal of the differential amplifier circuit 8 is connected to the inverting input terminal of the PWM comparator 12 via the resistor R8.

  Further, the inverting input terminal of the PWM comparator 12 is connected to the collector between the resistors R9 and R10 and to the transistor TR1 arranged in parallel with the resistor R10. Connected to the base of the transistor TR1 are a logic circuit 27 that outputs a combination of output waveforms of the rectangular low frequency generation circuit 18 and the delay circuit 26, a switch SW3, and a resistor R11.

  Next, the circuit operation of the present embodiment will be described.

  When the switch S1 is closed, for example, a voltage is generated in the capacitor C1 by the DC power source V1, which is a battery for automobiles of tens to tens of volts. This capacitor C1 functions to suppress minute voltage fluctuations due to changes in the output current of the DC power supply. When a voltage is generated in the capacitor C1, the voltage is supplied to the OP amplifier 19 (not shown). At this time, the voltage of the non-inverting input terminal is zero, and since the reference voltage V2 is connected to the inverting input terminal, the OP amplifier 19 outputs a low level. This voltage is input to the inverting input terminal of the PWM comparator 12 via the diode D3 and is compared with the sawtooth wave of the sawtooth wave generating circuit 13 to generate a PWM wave. The operational voltage of the PWM comparator 13 is input to the power MOS drive circuit 11 to switch the switching element Q1.

  On the secondary side of the transformer T, a boosted voltage is generated by the switching operation of the switching element Q1 on the primary side. The current due to the voltage generated in the transformer T2 charges the capacitor C2 via the diode D1. The voltage across the capacitor C2 is detected by the resistors R1, R2 and R3 of the output voltage detection circuit 2, and the detection result is input to the non-inverting input terminal of the OP amplifier 19 of the differential amplifier circuit 7. Yes. At this time, the reference voltage V2 is connected to the input of the inverting input terminal of the OP amplifier 19, and when the input voltage value is lower than the reference voltage V2, there is no input to the inverting input terminal of the PWM comparator 12. The voltage on the secondary side of the transformer T is increased to increase the voltage of the capacitor C2. Here, the resistor R6 connected in parallel to the OP amplifier 19 is inserted to adjust the gain of the OP amplifier 19, and the capacitor C6 delays the phase of the output to stabilize the operation of the entire lighting device. It is used to make it.

  The current due to the voltage generated in the transformer T3 charges the capacitor C5 of the igniter 5 through the diode D2 and the resistor R5. Here, the capacitor C3 is mainly used as a smoothing capacitor for smoothing the voltage from the transformer T3. When the voltage of the capacitor C5 becomes sufficiently high to a voltage at which the gas arrester GA breaks down, the gas arrester GA becomes electrically conductive and a current starts to flow through the pulse transformer L. Thereby, a high-pressure pulse is applied to the high-pressure discharge lamp 6, and the high-pressure discharge lamp 6 undergoes dielectric breakdown, causing glow discharge. Here, the capacitor C4 functions as a filter for preventing the high-pressure pulse from flowing back to the DC / AC inverter circuit 4 in the high-pressure discharge lamp 6. After the high-pressure pulse is applied to the high-pressure discharge lamp 6, the voltage of the capacitor C5 is lowered, so that the gas arrester GA is again in an insulated state, and the igniter 5 is substantially inoperative. Here, up to this point, the switch S2 is in a state where the connection between the drive circuits 14 to 17 and the rectangular low-frequency generation circuit 18 is cut off as shown in the figure.

  When the high-pressure discharge lamp 6 breaks down and glow discharge occurs, the charge charged in the capacitor C2 flows rapidly to the high-pressure discharge lamp 6 as a lamp current through the DC / AC inverter circuit 4. Due to this current, the high pressure discharge lamp 6 shifts from glow discharge to arc discharge and starts to light. The lighting immediately after this maintains a lighting state called DC lighting that maintains the same polarity for a relatively long time.

  Here, in the output voltage detection circuit 2, the voltage is detected by the divided voltage of the resistor R 1 and the resistors R 2 and R 3 and is input to the lighting detection circuit 21. In the lighting detection circuit 21, the charge of the capacitor C2 is supplied to the high pressure discharge lamp 6 to detect that the voltage has dropped. By this detection, the lighting time counting timer 22 starts counting, and the switch S2 is switched after a predetermined time has elapsed from the start of timing. As a result, the drive circuits 14 to 17 and the rectangular low frequency generation circuit 18 are connected.

  When the switch S2 is switched, the rectangular low frequency is input to the drive circuits 14 to 17 through the buffer BUF and the inverter INV, and the switching elements Q2 to Q5 are on / off controlled. In this control, when the switching elements Q2 and Q5 are on, the switching elements Q3 and Q4 are off, and when the switching elements Q2 and Q5 are off, the switching elements Q3 and Q4 are on, that is, the switching element Q2 ˜Q5 repeats polarity inversion. As a result, substantially rectangular wave AC power is generated on the output side of the DC / AC inverter circuit 4, and the high-pressure discharge lamp 6 shifts to lighting when stable. Here, the “substantially rectangular wave” refers to a case where the waveform has a waveform close to a flat characteristic, such as an instantaneous rise, fall, or the like that a rectangular wave has. That is, it includes a case where it takes about several microseconds for rising and falling, or a case in which a certain portion protrudes or is depressed while basically having a flat characteristic.

  The constant power control of the high pressure discharge lamp 6 will be described. The constant power control is performed based on the measurement results of the output voltage detection circuit 2 and the output current detection circuit 3. The voltage detection result of the output voltage detection circuit 2 is input to the division circuit 24. Further, the division circuit 24 has a target power value setting circuit 23 that operates in accordance with the output from the lighting time measuring circuit 22, and in that state, a high voltage. The power to be supplied to the discharge lamp 6 is also input. Therefore, a signal for obtaining an ideal current value is output from the divider circuit 24 and input to the inverting input terminal of the OP amplifier 20 of the differential amplifier circuit 8. Then, the current detection result of the current detection circuit 3 is input to the non-inverting input terminal of the OP amplifier 20, and a signal resulting from the comparison is input to the inverting input terminal of the PWM comparator 12. Therefore, the duty ratio of the switching element Q1 changes, and the high-pressure discharge lamp 6 is controlled at a constant power.

  The inverting input terminal of the PWM comparator 12 is connected with a circuit for sending a signal for increasing the voltage to the switching element Q1 at the start of polarity inversion and for sending a signal for stopping the voltage increase signal at the time of polarity inversion. Yes. The operation of this circuit will be described with reference to a time chart for explaining the operation of increasing the voltage of the DC / DC converter circuit during polarity inversion in FIG.

  The rectangular wave emitted from the rectangular low frequency generation circuit 18 has the same waveform as that of the rectangular low frequency generation circuit 18 and is pulsed by a logical circuit 27 that is an exclusive OR with the rectangular wave emitted from the delay circuit 26 delayed by a predetermined time. Output waveform. When a pulse-like output waveform is input to the base of the transistor TR1, it is turned on when the input is at a high level and turned off when it is at a low level. Then, the input signal to the inverting input terminal of the PWM comparator 12 is reduced while the transistor TR1 is on. When the transistor TR1 is off, the original state is restored after a predetermined time.

  As a result, when the input signal at the inverting input terminal of the PWM comparator 12 is reduced, the signal becomes a signal for extending the on-time of the switching element Q1 by the reduced time, so that the output voltage of the DC / DC converter circuit 1 is higher than usual. It has been. As a result, the high-pressure discharge lamp 6 has a substantially rectangular lighting waveform with no time during which no current causing the discharge delay flows.

In this embodiment, the high level time of the output waveform of the logic circuit 27, since the polarity of the switching element Q2~Q5 of the DC / AC inverter circuit 4 is switched, the lamp current I _L flowing through the high-pressure discharge lamp 6 The time to zero cross is set. The desired high level time can be set by measuring in advance through experiments. Here, “zero cross” means a state in which the waveform intersects the time axis.

The set time for rising of the high level may be immediately before or after the time when the polarity of the switching elements Q2 to Q5 of the DC / AC inverter circuit 4 is switched. Even in this case, the output voltage of the DC / DC converter circuit 1 in a predetermined period can be boosted. However, if it is immediately after the increase of the voltage is lowered, if it is just before, since the lamp current I _L is increased, when the polarity of the switching element Q2~Q5 of the DC / AC inverter circuit 4 is switched Is most desirable.

The reason for setting the high level falling time is to prevent the lamp current _IL from increasing too much. This is because, in the constant power control, if the lamp current _IL is excessively increased, the excessive current must be reduced in other portions, thereby preventing the occurrence of unstable discharge caused by this. .

FIG. 3 is an explanatory diagram for explaining the vicinity of the polarity inversion of the output waveform when the signal of FIG. 2 is input. Here, V _{DC / DC} is the voltage across the capacitor C2, that is, the output voltage of the DC / DC converter circuit 1, and V _L and I _L are the lamp voltage and lamp current of the high-pressure discharge lamp 6, respectively. The direction shown in FIG. Further, t1 is the timing at which the polarity of the switching element Q2~Q5 of the DC / AC inverter circuit 4 is inverted, t2 indicates the timing at which the lamp current _{I L} crosses zero.

In the figure, until t1, only the switching elements Q3 and Q4 of the DC / AC inverter 2 are in an on state, and stable power is supplied from the DC / DC converter circuit 1. Output voltage _{V DC / DC} constant voltage of about 45V of the DC / DC converter circuit 1 in this case, about 45V lamp voltage _{V L} is the voltage at the time of stabilization, the lamp current _{I L} negative constant of about 0.77A Voltage and constant current are flowing.

At t1, when only the switching elements Q3 and Q4 of the DC / AC inverter 2 are switched on and only the switching elements Q2 and Q5 are switched on, the lamp voltage V _L and the lamp current _IL gradually approach zero. . This is because the energy accumulated in the pulse transformer L is released, and this emission time is proportional to the energy accumulation amount of the pulse transformer L. When all the energy of the pulse transformer L is released, the lamp current _IL becomes zero. During the time when the energy of the pulse transformer L is released, the output voltage V _{DC / DC} of the DC / DC converter circuit 1 continues to rise because the capacitor C2 is charged. In the present invention, at this time, the output voltage V _{DC / DC} of the DC / DC converter circuit 1 is further increased, so the voltage is higher than usual.

Then, the next moment the lamp current I _L becomes zero, the lamp voltage V _L and inverted lamp current I _L flows. According to the present invention, the output voltage V _{DC / DC} of the DC / DC converter circuit 1 is boosted to 1.5 times or more of the voltage at the time of stable lighting when the polarity of the current flowing through the high pressure discharge lamp 6 is reversed. It was because it was done. As described above, it was confirmed that by keeping the current flowing in the lamp current _IL at all times, no discharge delay or the like occurred and no flickering occurred. Incidentally, in the figure, since the output voltage V _{DC / DC} of the DC / DC converter circuit 1 at that time is 75V and the stable ramp voltage _VL is 45V, the voltage is boosted by about 1.7 times. In the high pressure discharge lamp lighting device that does not use the present invention, the output voltage V _{DC / DC} of the DC / DC converter circuit 1 is about 1.3 times the lamp voltage _VL at the time of stability. In this case, after the lamp current _IL became zero, the waveform did not flow for a short time, and it was confirmed that the high-pressure discharge lamp 6 flickers.

After that, the lamp voltage V _L and the lamp current I _L gradually increase and decrease and gradually approach the values at the time of stable lighting.

In this embodiment, the switching element Q2~Q5 of the DC / AC inverter circuit 4 is polarity reversed, until the lamp current I _L flowing through the high-pressure discharge lamp 6 crosses zero, the on-time of the duty ratio of the switching element Q1 by widening, it is possible to boost the output voltage of the DC / DC converter circuit 1 when the lamp current I _L is zero-crossing. Then, the output voltage V _{DC / DC} of the DC / DC converter circuit 1 is increased by 1.5 times or more with respect to the lamp voltage _VL when the high-pressure discharge lamp 6 is stably lit, thereby causing flicker in the high-pressure discharge lamp. Can be prevented.

  Further, in this embodiment, since the lighting method increases the voltage value as compared with the prior art, it is not necessary to increase the withstand capability of the element. That is, it is possible to prevent occurrence of flickering in the high-pressure discharge lamp without increasing the cost and size of the lighting device.

(Second Embodiment)
FIG. 4 is a circuit diagram illustrating a lighting device for a high pressure discharge lamp according to a second embodiment of the present invention. About each part of this 2nd Embodiment, the same part as each part of the lighting device of the high pressure discharge lamp of 1st Embodiment of FIG. 1 is shown with the same code | symbol, and the description is abbreviate | omitted.

  This second embodiment is different from the first embodiment in that it is not a method of adjusting the duty ratio of the switching element Q1 to increase the output voltage of the DC / DC converter circuit 1, and therefore the PWM comparator. Only the signal from the differential amplifier circuit 7 or the differential amplifier circuit 8 affects the inverting input terminal 12. Further, instead of the buffer BUF, the inverter INV, and the switch SW2, a control circuit 28 including the function of the switch SW2 is connected. By this control circuit 28, the rectangular wave of the rectangular low frequency generation circuit 25 is converted into signals input to the switching elements Q2 to Q5, respectively, as shown in a time chart illustrating the rectangular wave by the control circuit of FIG. Here, (a) to (d) in the figure indicate the time in each switching state.

  FIG. 6 is an equivalent circuit diagram for explaining the operation of the DC / AC inverter circuit by the control circuit shown in FIG. Here, S2 to S5 in FIG. 5 are simplified diagrams of the switching operation of the switching elements Q2 to 5, and D2 to D5 are parasitic diodes of the switching elements Q2 to Q5 that are MOSFETs, respectively. Further, (a) to (d) in the figure correspond to (a) to (d) in FIG.

  6 is input to the switching elements Q2 to Q5 by the control circuit 28, and the DC / AC inverter circuit 4 operates. In the first control (a), only the switching elements Q3 and Q4 are on, and the switch S4, the high pressure discharge lamp 6, the pulse transformer L, and the switch S3 are turned on. Therefore, current flows from the DC / DC converter circuit 1 and the capacitor C2.

  In the third control (b), only the two switching elements Q3 and Q5 located on the low voltage side of the DC / AC inverter circuit 4 are on, and the switch S3, the high pressure discharge lamp 6, the pulse transformer L, and the switch S5. Are conducted to form a closed circuit. Therefore, since the current due to the energy accumulated in the pulse transformer L flows in the closed circuit, the time until the energy of the pulse transformer L is completely released can be lengthened without being released all at once. Further, the current from the DC / DC converter circuit 1 flows in the direction of charging the capacitor C2 without flowing into the DC / AC inverter circuit 4.

In the second control (c), only the switching elements Q2 and Q3 are on, and the switch S2, the high-pressure discharge lamp 6, the pulse transformer L, and the switch S5 are turned on. Therefore, the current from the DC / DC converter circuit 1 and the capacitor C2 flows through the high-pressure discharge lamp 6 in the opposite direction to that in (a), and the lamp voltage V _L and the lamp current V _I are in _relation to (a). The opposite polarity.

  In the third control (d), the circuit state is the same as in (b), but the closed circuit by the switch S3, the high-pressure discharge lamp 6, the pulse transformer L, and the switch S5 is generated by the energy accumulated in the pulse transformer L. The direction of the current is opposite to (b).

  Thereafter, lighting with a rectangular wave at the time of stability repeats (a) to (d).

  FIG. 7 is an explanatory diagram for explaining the vicinity of the polarity inversion of the output waveform in the operation of the circuit shown in FIG. Here, (a) to (c) in the figure correspond to (a) to (c) in FIGS.

Referring to the figure, since the stable power is supplied from the DC / DC converter circuit 1 in the latter half of (a), the output voltage V _{DC / DC} of the DC / DC converter circuit 1 is a constant voltage of about 45V, the ramp The voltage V _L is a stable voltage of about 45 V, and the lamp current I _L is a negative voltage and current of about 0.77 A.

When the state shown in FIG. 6A is switched to FIG. 6B, the lamp voltage V _L and the lamp current _IL gradually approach the voltage and current. This is because the energy accumulated in the pulse transformer L is released as described in the first embodiment. Here, in the present embodiment, since the circuit state (b) is obtained, the energy accumulated in the pulse transformer L is not easily lost, and the time when it is completely zero is increased. During this time, the capacitor C2 continues to be charged and the voltage continues to rise.

At the same time the current of the lamp current I _L is 0, switched to the circuit state of FIG. 6 (c). Then, immediately, the polarity of the lamp voltage _{V L} and the lamp current _{I L} is reversed, immediately thereafter, the lamp voltage _{V L} rises to temporarily voltage close to the output voltage _{V DC / DC} of the DC / DC converter circuit 1 . Then, the voltage value gradually approaches a stable voltage value after going down and rising. Also, since the lamp current I _L is also the current is zero, rises, through a descending, gradually approaches the current value during stable.

Output voltage V _{DC / DC} of the DC / DC converter circuit 1 when the polarity of the lamp current I _L is reversed, the lamp voltage of the high-pressure discharge lamp 6 is boosted between about 1.7 times.

Here, as compared with the waveform around the polarity inversion in the first embodiment of FIG. 3, the time until the lamp current _IL becomes 0 is extended, and the output voltage V of the DC / DC converter circuit 1 is extended during that time. _It can be seen that _{DC / DC} is high.

In this embodiment, by extending the time required for releasing the energy of the pulse transformer L, the charging time of the capacitor C2 is lengthened, and the output voltage V _{DC / DC} of the DC / DC converter circuit 1 is increased to a predetermined voltage. be able to.

  Note that the present embodiment is not limited to the above-described embodiment, and may be modified as follows, for example.

  When switching elements having parasitic diodes such as MOSFETs are used as the switching elements Q2 to Q5, only the switch S3 is turned on in the state of FIG. 6B, and only the switch S5 is turned on in the state of FIG. 6D. You may control to turn on.

  Further, in the circuit states of FIGS. 6B and 6D, the low voltage side of the switching elements Q2 to Q5 is turned on, but the high voltage side may be turned on. Moreover, you may switch a high voltage | pressure side and a low voltage | pressure side by (b) and (d).

Further, as shown in the explanatory diagram of other output waveforms in FIG. 8, the polarity of the switching element of the DC / AC inverter circuit 4 may be switched after the lamp current _IL becomes 0 and a little time elapses. Also in this case, it was confirmed that the occurrence of flicker can be suppressed. However, the time that current does not flow through the high-pressure discharge lamp 6 is 20μs or less, and the lamp current _{I L} to the polarity reversal during the relative stability when the lamp voltage _{V L,} the output voltage _{V DC} of the DC / DC converter circuit 1 _Only when _{/ DC} is sufficiently increased.

  The present invention is not limited to the above-described embodiment, and may be modified as follows, for example.

When the polarity of the current of the present invention is reversed, the relationship V _{DC / DC} / V _L between the output voltage V _{DC / DC} of the DC / DC converter circuit 1 and the voltage V _L at the time of stable lighting of the high-pressure discharge lamp 6 is Preferably, it is 1.7 times or more, and in this case, a particularly great effect on flickering is obtained. Moreover, although the upper limit of V _{DC / DC} / V _L is not set, the effect of the present invention can be obtained even when the numerical value is as large as possible.

Immediately before the polarity of the lamp current applied to the high-pressure discharge lamp 6 according to the present invention is reversed, the output voltage of the DC / DC converter circuit 1 is 1.5 times the lighting voltage when the high-pressure discharge lamp 6 is stable. As another means described above, there is a method of sufficiently increasing the inductor L of the igniter 5. This is because, even in the conventional operation of the DC / AC inverter circuit 4, the increase in the energy of the inductor L causes the lamp voltage _VL of the high-pressure discharge lamp 6 to reverse its polarity as in the second embodiment. You can lengthen the time. Thereby, the charging time of the capacitor C2 can be lengthened, and the output voltage V _{DC / DC} of the DC / DC converter circuit 1 can be increased.

  Alternatively, the output voltage of the DC / DC converter circuit 1 may be increased before the energy of the inductor L is lost by reducing the capacitance of the capacitor C2 and increasing the voltage increase rate. However, in this method, it is conceivable that the ripple of the output current increases due to the insufficient capacity of the capacitor C2, and the circuit operation becomes unstable. Therefore, the operating frequency of the DC / DC converter circuit 1 is increased to reduce the ripple. It is desirable to reduce.

  Further, immediately before the polarity inversion of the switching elements Q2 to Q5 of the DC / AC inverter circuit 4, the discharge does not become unstable in other portions, for example, the time width is 5% or less of a half cycle of the lamp current waveform, the current value If a pulsed current of about 1.5 times the stable current value is superimposed, a further effect against flickering can be obtained.

The circuit diagram explaining the lighting device of the high pressure discharge lamp of the 1st Embodiment of this invention. The time chart figure explaining the operation | movement which raises the voltage of the DC / DC converter circuit during the polarity reversal of the lighting device of the high pressure discharge lamp shown in FIG. FIG. 3 is an explanatory diagram for explaining the vicinity of the polarity inversion of the output waveform when the signal of FIG. 2 is input. The circuit diagram explaining the lighting device of the high pressure discharge lamp of the 2nd Embodiment of this invention. The time chart explaining the rectangular wave by a control circuit. FIG. 6 is an equivalent circuit diagram for explaining the operation of the DC / AC inverter circuit by the control circuit shown in FIG. 5. FIG. 7 is an explanatory diagram for explaining the vicinity of the polarity inversion of the output waveform in the operation of the circuit shown in FIG. 6. Explanatory drawing of the other output waveform in operation | movement of the circuit shown in FIG.

Explanation of symbols

V1 DC power supply 1 DC / DC converter circuit Q1 switching element T transformer 2 output voltage detection circuit 3 output current detection circuit 4 DC / AC inverter circuit Q2 to Q5 switching element 5 igniter L pulse transformer 6 high pressure discharge lamp 7, 8 differential amplification Circuit 12 PWM comparator

Claims (3)

The DC voltage applied to the input side is stepped down or boosted by a DC / DC converter circuit, then DC power is converted to AC power by a DC / AC inverter circuit, the AC power is supplied to a high pressure discharge lamp, and the high voltage In the lighting device of the high pressure discharge lamp for lighting the discharge lamp,
When the polarity of the current of the high-pressure discharge lamp that is lit with substantially rectangular wave AC power is reversed, the output voltage of the DC / DC converter circuit is set to the voltage during stable lighting of the high-pressure discharge lamp. A lighting device for a high-pressure discharge lamp characterized by being set to 1.5 times or more. The DC voltage applied to the input side is stepped down or boosted by turning on / off switching elements included in the DC / DC converter circuit, and then the DC power is converted into AC power by a plurality of switching elements of the DC / AC inverter circuit. In the lighting device of the high pressure discharge lamp for supplying the AC power to the high pressure discharge lamp and lighting the high pressure discharge lamp,
A signal for increasing the output voltage is sent to the DC / DC converter circuit immediately before or immediately after the polarity inversion of the switching element of the DC / AC inverter circuit, and the DC / DC converter at the time of zero crossing of the current of the high-pressure discharge lamp. A lighting device for a high-pressure discharge lamp, wherein a signal for stopping an increase in output voltage is sent to a circuit. DC power supply,
A DC / DC converter circuit for stepping down or boosting a DC voltage input by the DC power source by turning on and off a switching element; and
A capacitor for smoothing the stepped down or boosted output voltage;
A DC / AC inverter circuit that converts DC power from the capacitor into AC power by turning on and off a plurality of switching elements;
An igniter including a pulse transformer connected to the output side of the DC / AC inverter circuit and generating a high voltage pulse from which an output voltage of the DC / DC converter circuit is guided;
The igniter comprises a high pressure discharge lamp that is lit by AC power after a high pressure pulse is applied,
A first control for controlling the switching element of the DC / AC inverter circuit so that a current of a first polarity flows when the high-pressure discharge lamp is lit with a substantially rectangular wave; and the switching of the DC / AC inverter circuit A second control for controlling the element so that a current of a second polarity flows; and controlling the switching element of the DC / AC inverter circuit so that the high voltage side or the low voltage side of the DC / AC inverter circuit is conductive. A lighting device for a high-pressure discharge lamp having a third control.

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