JPH0634396B2 - Lamp abnormality detection circuit - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a discharge lamp lighting device for lighting a plurality of discharge lamps such as fluorescent lamps in parallel, and detects abnormalities such as exhaustion of a filament emitter and filament breakage at the end of the life of the discharge lamp. The present invention relates to a lamp abnormality detection circuit for detecting.

[Background technology]

In an inverter type discharge lamp lighting device for lighting a discharge lamp such as a fluorescent lamp at a high frequency, an inverter that supplies high frequency power to the discharge lamp, for example, when an abnormality such as exhaustion of a filament emitter or filament breakage occurs at the end of the life of the discharge lamp. Excessive stress may be applied to the switching elements of the circuit, and the switching elements may be destroyed.

In order to prevent such a problem, a lamp abnormality detection circuit is provided to detect an increase in the lamp voltage due to the occurrence of abnormality such as exhaustion of the filament emitter or filament breakage at the end of the life of the discharge lamp. An abnormal signal is given to a control circuit for controlling the on / off of the switching element to forcibly shut off the switching element to protect the switching element.

A conventional discharge lamp lighting device of this type is disclosed in Japanese Patent Laid-Open No. 56-5.
There is a discharge lamp lighting device disclosed in Japanese Patent No. 4792. This discharge lamp lighting device is a device in which a plurality of discharge lamps are connected via a balancer, and detects an abnormal voltage when a half-wave discharge state is reached via a detection winding magnetically coupled to the balancer. Is.

However, this discharge lamp lighting device detects an AC component, and cannot detect a DC component. Therefore, the detection accuracy was low. Further, an abnormality could not be detected unless the lighting circuit had a balancer.

The discharge lamp lighting device shown in FIG. 9 and FIG. 10 has been proposed as a device capable of solving the problem of the discharge lamp lighting device.

First, in the discharge lamp lighting device of FIG. 9, a high frequency voltage from an inverter circuit (not shown) is applied between the X point and the Y point, and the high frequency voltage is discharged through the balancer L ₁ to the discharge lamps LP ₁ , LP. ₂ and discharge lamps LP ₁ and LP ₂
Are lit in parallel. Then, the lamp abnormality detecting circuit rectifies the lamp voltage of the discharge lamp LP ₁ , that is, the voltage V _A1 at the point A _{1 by the} smoothing voltage detecting unit IV including the diode D ₁ , the resistors R ₁ and R ₂ and the capacitor C ₇ . The voltage of the discharge lamp LP ₂ is smoothed and divided, and the voltage V _A2 at the point A ₂ is rectified, smoothed, and rectified by a smooth voltage detecting unit V including a diode D ₂ , resistors R ₃ , R ₄ and a capacitor C _8. Voltage-dividing and smoothing type voltage detector I
The voltage V _B1 obtained from the B ₁ point of V is added to the comparator (comprising an operational amplifier) OP ₃ of the voltage comparison unit VI and compared with the reference voltage (zener voltage) generated across the zener diode ZD ₃ and smoothed. The voltage V _B2 obtained from the point B ₂ of the mold voltage detector V is added to the comparator (comprising an operational amplifier) OP ₄ and compared with the reference voltage (zener voltage) generated across the Zener diode ZD ₄ , and the comparator OP ₃ , OP ₄ is ORed by the OR circuit OR ₁ and the high level output of this OR circuit OR ₁ is output from the Z point as a lamp abnormality signal.

In this case, the discharge lamp LP ₁ Consumable filament emitter end of life, when the voltage V _A1 abnormality occurs A ₁ point of broken filaments, etc. is increased, the voltage V _B1 of the _point B also rises, B ₁ point When the voltage of V exceeds the reference voltage created by the Zener diode ZD ₃ , the output of the comparator OP ₃ becomes high level, and a high level abnormality detection signal is output from the OR circuit OR ₁ and is given to the switching element of the inverter circuit, for example. Stop the base current to protect the switching element. When an abnormality occurs in the discharge lamp LP ₂ , the voltage V _{A2 of} A ₂ rises and the voltage V _{2 of the} point B ₂ increases.
_B2 rises, and the OR circuit OR ₁ outputs a high-level abnormal signal. Incidentally, C ₁ and C ₂ are capacitors for LC series resonance.

In the circuit of FIG. 9, the discharge lamps LP ₁ , LP
_Since the lamp voltage of the discharge lamps LP ₁ and LP ₂ was only compared with a constant reference voltage to detect the abnormality of _{No. 2} , when the ambient temperature or the power supply voltage changed or when dimming was performed. It was necessary to take measures to prevent malfunction due to fluctuations in the lamp voltage.

The discharge lamp lighting device of FIG. 10 can solve the problem of the circuit of FIG. The lamp abnormality detection circuit in this discharge lamp lighting device uses a voltage comparison unit VII instead of the voltage comparison unit VI in FIG. This voltage comparator VII
Is a comparator OP ₁ , OP ₂ , a Zener diode Z
D _1, consists ZD ₂ and the OR circuit OR _2, the absolute value of the difference voltage of the voltage V _B1, V _B2 which is output smoothing type voltage detection unit IV, from V exceeds a Zener diode ZD _1, ZD ₂ zener voltage When this happens, a high level abnormal signal is output from the OR circuit OR ₂ .

With this configuration, the two discharge lamps LP ₁ and LP
Fluctuations in the lamp voltage (not a lamp abnormality) that occur simultaneously in ₂ are canceled, and malfunctions such as when the ambient temperature or the power supply voltage changes or when dimming is performed can be prevented.

However, the voltages V _B1 and V _{B2 obtained} by smoothing the lamp voltages V _A1 and V _A2 of the discharge lamps LP ₁ and LP ₂ rarely show a significant difference between the normal state and the abnormal state. It was not easy to detect abnormalities reliably.

As another conventional example, it is conceivable to use a photosensor to compare the luminous flux between two discharge lamps and send out a detection signal when the luminous flux drops when the emitter is consumed, but the problem of the mounting position of the photosensor remains. .

It is also possible to detect the filament current difference between two discharge lamps by utilizing the fact that an excessive current flows through the filament during half-wave discharge, but a choke coil for detection is required, and the circuit configuration Becomes complicated.

[Object of the Invention]

An object of the present invention is to provide a lamp abnormality detection circuit that can easily and reliably detect an abnormality in a discharge lamp.

[Disclosure of Invention]

According to the present invention, when two discharge lamps are lit in parallel, when any one of the discharge lamps has an abnormality at the end of its life such as exhaustion of filament emitter or disconnection of filamentation, instantaneous lamp voltage and instantaneous lamp An abnormality of the discharge lamp is detected by utilizing the fact that the phase of the current deviates from the phase of the instantaneous lamp voltage and the instantaneous lamp current of the normal discharge lamp. The present invention is based on the premise that when one discharge lamp is normal and the other discharge lamp is in an abnormal state such as one side emitter exhaustion state, the instantaneous lamp voltage or the instantaneous lamp current of both is out of phase. It is possible to detect when one discharge lamp is normal and the other discharge lamp is in an abnormal state such as one side emitter exhaustion state, and both discharge lamps are in the same emitter exhaustion state. When it becomes, it is impossible to detect that it is abnormal.

Therefore, in the lamp abnormality detecting circuit of the present invention, the first and second non-smooth type detecting sections detect the instantaneous lamp voltage or the instantaneous lamp current of the first and second discharge lamps, respectively, and the comparing section detects the instantaneous lamp voltage or current. The absolute value of the difference between the first and second instantaneous lamp voltages or the instantaneous lamp currents detected by the first and second non-smooth detectors is compared with a reference value set to a predetermined level, and the absolute value of the difference is An abnormal signal is generated from the comparison unit when the reference value is exceeded.

According to the configuration of the present invention, the non-smooth type detection unit detects the instantaneous lamp voltage or the instantaneous lamp current of the first and second discharge lamps, and detects the detected first and second instantaneous lamp voltage or instantaneous lamp current. The absolute value of the difference is compared with a reference value set to a predetermined level, and an abnormal signal is generated from the comparison unit when the absolute value of the difference exceeds the reference value. Therefore, the first and second discharges are performed. When one of the lamps is normal and the other is abnormal, there is a difference in phase between the instantaneous lamp voltage or the instantaneous lamp current of the first and second discharge lamps, even if there is no difference in amplitude. Therefore, a large difference appears between the first and second instantaneous lamp voltage or instantaneous lamp current, and the absolute value of the difference between the first and second instantaneous lamp voltage or instantaneous lamp current is compared with the reference value. Yo Can one of the first and second discharge lamps is to easily and reliably detect that normal, the other is abnormal.

Embodiment A first embodiment of the present invention will be described with reference to FIGS. 1 to 3. That is, as shown in FIG. 1, this lamp abnormality detection circuit includes instantaneous lamp voltages of the first and second discharge lamps LP ₁ and LP ₂ in the non-smooth type detection units I and II of FIGS. Are detected respectively. That is, A
The voltages V _A1 and _A2 at ₁ point and A ₂ point are rectified and divided.

Further, this lamp abnormality detection circuit detects the voltage by the comparison unit III by the first and second non-smooth type detection units I and II, and rectifies and divides the voltage V from the points a ₁ and a ₂ to output the voltage V. The absolute value of the difference between _a1 and V _a2 is compared with the reference value, and when the absolute value of the difference exceeds the reference value, an abnormal signal is generated from the comparison unit III.

The configuration and operation of the discharge lamp lighting circuit including the lamp abnormality detection circuit will be described in detail below.

In this discharge lamp lighting device, as shown in FIG. 1, the voltage of the AC power source E is full-wave rectified by a diode bridge DB and further smoothed by a smoothing capacitor C ₆ to obtain a DC power source. Inverter circuit INV
Is feeding.

The inverter circuit INV is connected to the oscillator OSC and the DC power supply in series, and switching elements Tr ₃ and Tr that are turned on and off alternately by the output of the oscillator OSC.
₄ and a resistor R ₈ that determines the oscillation frequency of the oscillator OSC,
R ₉ and a capacitor C ₅ and a switch S ₁ for switching the oscillation frequency, and outputs a high frequency output of a predetermined frequency from both ends of the switching element Tr _{4 to} a choke coil L _{2, a} capacitor C ₄ having a large capacity for power supply, and a balancer L _1. the two discharge lamp LP _1, is applied to the LP ₂ through adapted starting to light the discharge lamp LP _1, LP _2. In this case, the discharge lamp LP _1, a capacitor C ₁ connected in parallel to the LP _2, C ₂ is a choke coil L
₂ constitutes a resonance circuit, and the oscillation circuit OSC oscillates at a frequency near the resonance frequency of the oscillation circuit, and by changing the oscillation frequency, the voltage across the capacitors C ₁ , C ₂ , that is, the discharge lamp LP ₁ , LP ₂ can be adjusted.

Further, the lamp abnormality detecting circuit is composed of the non-smooth type detecting sections I and II and the comparing section III, as described above.

The non-smooth detector I includes a diode D ₁ and resistors R ₁ and R ₂
And detects the instantaneous lamp voltage of the discharge lamp LP ₁ . Specifically, the voltage V _A1 at the point A ₁ is rectified and divided, and the voltage V _a1 is output from the point a ₁ .

Further, the non-smooth type detection unit II includes a diode D ₂ and resistors R ₃ and R ₄ , and detects the instantaneous lamp voltage of the discharge lamp LP ₂ . Specifically, the voltage V _A2 at the point A ₂ is rectified and divided, and the voltage V _a2 is output from the point a ₂ .

The comparison unit III includes comparators OP ₁ and OP ₂ , Zener diodes ZD ₁ and ZD ₂ , and diodes D ₃ and D ₄ ,
The absolute value | V _a1 −V _a2 | of the difference voltage between the voltage V _{a1 at the} point a ₁ and the voltage V _{a2 at the} point a _{2 is} set to the zener diodes ZD ₁ and ZD _2.
Zener voltage V _ZD of

When | V _a1 −V _a2 |> V _ZD (1) holds, the output of either _one of the comparators OP ₁ and OP ₂ becomes high level, and the diodes D ₃ and ₄ forming the OR circuit. A high-level abnormal signal is output to the cathode side of, and when | V _a1 −V _a2 | ≦ V _ZD (2), both outputs of the comparators OP ₁ and OP ₂ are low. The level becomes high, and the cathode side of the diodes D ₃ and ₄ forming the OR circuit becomes a high impedance state.

The resistors R ₁₀ and R ₇ and the capacitor C _{3 form} a charge / discharge circuit. When the cathode side of the diodes D ₃ and ₄ is at a high level, the capacitor C ₃ is charged, and the cathode sides of the diodes D ₃ and D ₄ are connected. The capacitor C ₃ is discharged in the high impedance state. On / off of the switch S ₁ for switching the oscillation frequency is switched according to the voltage of the capacitor C ₃ of the charge / discharge circuit. Diode D ₃ ,
When a high level abnormal signal is output to the cathode side of D ₄ , the switching frequency of the oscillator OSC changes in the direction away from the resonant frequency of the resonant circuit by switching the switch S ₁ , and the discharge lamp LP ₁ , The voltage applied to LP ₂ will decrease.

When both the discharge lamps LP ₁ and LP ₂ are normal,
Discharge lamp LP _1, the voltage of the lamp voltage or A ₁ point and A ₂ of the LP ₂ V _A1, rectifies the _A2 and divided voltage V
_{a1, a2} is the Yo shown by the broken line H _1, H ₂ in the second views, respectively, become substantially in phase of the waveform, the potential difference in the voltage V _a1, V _a2 of ₁ point and a _2-point a is little. Therefore, the output terminal of the comparison unit III is in a high impedance state, the capacitor C ₃ is not charged and only discharged, and normally becomes zero.

However, when one of the discharge lamps LP ₁ and LP ₂ , for example, the discharge lamp LP ₁ becomes abnormal such as exhaustion of the filament emitter or filament breakage, the voltage V _{a1 at the} point a ₁ is broken in FIG. 3 (a). As indicated by J ₁ , the voltage V _{a2 at the} point a ₂ becomes as indicated by the broken line J ₂ in FIG. 3 (a), and when the two are compared, they are out of phase (in the case of this figure, the amplitude Although the two are different, there is no problem even if the amplitude is the same).

As a result, the difference voltage between the voltage V _{a1 at the} point a ₁ and the voltage V _{a2 at the} point a ₂ is due to the existence of the phase difference between the voltage V _a1 and the voltage _a2 .
It partially exceeds the Zener voltage V _ZD of the Zener diodes ZD ₁ and ZD ₂ . In this case, the periods T ₁ , T
_3, at T _5, as the output is high level of the comparison unit III are satisfied (1) condition, the capacitor C ₃ is charged through the resistor R _10, the voltage across V _C3, the third view (b ) In solid line J ₃
As shown in, the condition of the equation (2) is satisfied during the periods T ₂ and T ₄ , the output end of the comparison unit III becomes a high impedance state, and the capacitor C ₃ is discharged through the resistor R ₇ .
The voltage V _C3 across the capacitor C ₃ will drop.
At this time, the voltage V _C3 across the capacitor C ₃ is not zero on average and has a certain value. The switch S ₃ is controlled by this voltage V _C3 , and the oscillation frequency of the oscillation circuit OSC is the resonance of the resonance circuit. The frequency shifts from the frequency of the inverter circuit INV to the discharge lamps LP ₁ and LP ₂
The power supplied to will be limited. Therefore, at the end of life of the discharge lamps LP ₁ and LP ₂ , when an abnormality such as wear of the filament emitter or filament breakage occurs, for example, the switching element T of the inverter circuit INV that supplies high-frequency power to the discharge lamps LP ₁ and LP ₂ .
without applying excessive stress to r ₃ and Tr ₄ ,
Tr ₃ of the switching element in the inverter circuit INV,
It is possible to prevent the destruction of Tr ₄ .

The lamp abnormality detection circuit of this embodiment detects the instantaneous lamp voltages of the first and second discharge lamps LP ₁ and LP _{2 by} the non-smooth type detection units I and II, and detects the detected first and second instantaneous lamps. The absolute value of the voltage difference is compared with the reference value, and when the absolute value of the difference exceeds the reference value, an abnormal signal is generated from the comparison unit III. Therefore, the first and second discharge lamps LP ₁ , LP _{2 in} the event of an abnormality in either one of the first and second discharge lamps LP ₁ , LP ₂ even if there is no difference in amplitude between them, if there is a difference in phase, A large difference appears between the first and second instantaneous lamp voltages, and by comparing the absolute value of the difference between the first and second instantaneous lamp voltages with the reference value, the first and second instantaneous lamp voltages are compared.
It is possible to easily and reliably detect the abnormality of either _one of the discharge lamps LP ₁ and LP ₂ .

A second embodiment of the present invention will be described with reference to FIGS. 4 to 6. As shown in FIG. 4, this lamp abnormality detecting circuit is replaced with a comparing unit II in place of the comparing unit III in FIG.
I'is used, and the others are the same as those in FIG.

This comparison section III ′ connects the collectors of the transistors Tr ₁ and Tr ₂ in common, and also connects the transistors Tr ₁ and T 2.
The emitter of r ₂ through the resistor R _5, R ₆ are respectively connected to the base of the transistor Tr _2, Tr _1, to connect the emitter of the transistor Tr _2, Tr ₁ a ₁ point, respectively, to the _two points a, transistor Tr ₂ , the common collector of Tr ₁ is connected to the parallel circuit of the capacitor C ₃ and the resistor R ₇ via the diode D ₅ , and the voltage V across the capacitor C ₃ is applied.
_The switch S ₁ is controlled by _C3 .

The operation will be described. Now, the discharge lamps LP ₁ and LP ₂
If there is no abnormality in both, the voltage V _{a1 at the} point a _{1 and} the voltage V _{a2 at the} point a ₂ are in phase, and the absolute value | V _a1 −V _a2 | of the differential voltage between the voltage V _a1 and the voltage V _a2 is , Σ is a transistor Tr ₁ ,
When the voltage between the base and the emitter is required to make Tr ₂ conductive, | V _a1 −V _a2 | ≦ σ and both transistors Tr ₁ and Tr ₂ are cut off.

However, for example, the voltage V _{a1 at the} point a ₁ becomes as shown by the broken line G ₁ in FIG. 5 due to occurrence of abnormality such as exhaustion of the filament emitter and filament breakage at the end of the life of the discharge lamp LP _{1, and at} the point a ₂ The voltage V _a2 is the solid line G in FIG.
_As shown by ₂ , a phase difference occurs between the voltages V _a1 and _a2 .

When a phase difference occurs between the voltages V _a1 and V _a2 , the period T ₁ ,
At T ₃ and T ₆ , the absolute value of the difference voltage | V _a1 −V _a2 | between the voltage V _a1 and the voltage V _a2 is higher than the voltage σ and is higher than the voltage V _C3 across the capacitor C ₃ , and therefore the transistor Tr.
Either _one of Tr ₁ and Tr ₂ becomes conductive and the diode D ₅ becomes conductive, and the capacitor C ₃ is charged by the absolute value of the difference voltage between the voltage V _a1 and the voltage V _a2 | V _a1 −V _a2 | The voltage V _C3 across C ₃ is the thick line G _{3 in} FIG.
It is rising as shown in. However, the periods T ₂ and T ₅
, The absolute value of the voltage difference between the voltage V _a1 and the voltage V _a2 |
Since V _a1 −V _a2 | is lower than the voltage σ, the transistor Tr
_{Both 1} and Tr ₂ are cut off, the capacitor C ₃ is discharged,
The voltage V _C3 drops. In the period T ₄ , the absolute value of the difference voltage | V _a1 −V _a2 | between the voltage V _a1 and the voltage V _a2 is higher than the voltage σ but lower than the voltage V _C3 across the capacitor C ₃ .
The capacitor C ₃ is not charged and the voltage V _C3 across the capacitor C ₃ drops. At this time, the discharge current of the capacitor C ₃ is blocked by the diode D ₅ in the transistor Tr.
₁ , does not flow into Tr ₂ .

Then, as in the case of the first embodiment, the on / off of the switch S ₁ is controlled by the voltage V _C3 across the capacitor C ₃ .

This embodiment can be applied not only to a two-lamp type discharge lamp lighting device but also to a multi-lamp type (even number) discharge lamp lighting device. In this case, for example, a non-smooth type is used for 2n discharge lamps. Each of the detection circuits is provided, and as shown in FIG. 6, the output terminals of the non-smoothness detection circuits provided in the n discharge lamps are connected to the terminals a _{11 to} a _1n to output the non-smoothness detection circuits. The voltages are combined and input to the emitter of transistor Tr ₂ ,
The output terminals of the non-smooth detection circuits provided in the remaining n discharge lamps are connected to terminals a _{21 to} a _{2n so} that the output voltages of the non-smooth detection circuits are combined and input to the emitter of the transistor Tr _2. It is the one.

Since the output voltages of the non-smooth type detection circuits provided in the same number of discharge lamps are combined and supplied to the emitters of the transistors Tr ₁ and Tr ₂ described above, when all the discharge lamps are normal, the transistor Tr _1, Tr ₂ of the voltage of the phase applied to the emitter in phase, the transistors Tr _1,
Both Tr ₂ are cut off and the capacitor C ₃ is not charged. On the other hand, if any one of the discharge lamps becomes abnormal, the voltages applied to the emitters of the transistors Tr ₁ and Tr ₂ are out of phase with each other, which can be detected as described above.

The operation other than the above is the same as that of the discharge lamp lighting device of FIG.

The effects of this embodiment are similar to those of the first embodiment. A third embodiment of the present invention will be described with reference to FIG.
This lamp abnormality detection circuit does not detect the lamp voltage as in the above embodiment, but rather discharge lamps LP ₁ , LP ₂
Impedance elements I'and II 'such as resistors for detecting a lamp current are inserted and connected in series to detect the abnormality of the discharge lamps LP ₁ and LP ₂ from the phase difference of the lamp current. The absolute value of the voltage difference between the two terminals' and II 'is input to a comparison section similar to the comparison section III or III' in FIG. 1 or 4, and the abnormality detection procedure is the same as in the above embodiment. Is the same as.

The effects of this embodiment are similar to those of the above-mentioned embodiments.

A fourth embodiment of the present invention will be described with reference to FIG.
This lamp abnormality detection circuit detects the difference between the currents flowing in the capacitors C ₁ and C ₂ by the AC device TS, and compares the absolute value of the obtained difference current with the reference value in the same manner as the case of the difference voltage to discharge. An abnormality of the lamps LP ₁ and LP ₂ is detected.

In this case, in the AC device TS, the first and second primary windings n ₁₁ and n ₁₂ having the same number of turns are wound around a toroidal core or the like in opposite polarities, and the secondary winding n ₂ is attached to the toroidal core. It is wrapped around. In this AC device TS, when the currents flowing through the first and second primary windings n ₁₁ and n ₁₂ have the same phase and the same amplitude, the magnetic flux due to the mutual currents is canceled and the output of the secondary winding is zero. However, the first and second primary windings n
_If either the amplitude or the phase of the current flowing through ₁₁ and n ₁₂ is different, a predetermined output appears at the secondary winding n ₂ .

When both the _two discharge lamps LP ₁ and LP ₂ are normal, the currents flowing through the capacitors C ₁ and C ₂ have the same amplitude and the same phase, so the secondary winding corresponding to the difference between the two currents. n
The output of ₂ is zero. However, two discharge lamps LP
_If any _{one of 1} and LP ₂ becomes abnormal, the currents flowing through the capacitors C ₁ and C ₂ will have at least a phase difference, and as a result, the discharge lamp LP ₁ , LP ₂ abnormality will be detected.

Incidentally, in this embodiment, and it detects the current flowing through the capacitor C _1, C _2, which is a discharge lamp LP _1, LP
If the lamp current flowing in ₂ changes, it changes accordingly, and it can be said that the lamp current is detected indirectly.

The effects of this embodiment are similar to those of the above-mentioned embodiments.

In addition, this embodiment shows the one in which the discharge lamps are lit in parallel by using the balancer, but the present invention can be applied to the one in which the discharge lamps are lit in parallel without using the balancer.

〔The invention's effect〕

According to the lamp abnormality detection circuit of the present invention, the non-smooth detection section detects the instantaneous lamp voltage or the instantaneous lamp current of the first and second discharge lamps, and detects the detected first and second instantaneous lamp voltage or the instantaneous lamp voltage. The absolute value of the difference between the lamp currents is compared with a reference value set to a predetermined level, and when the absolute value of the difference exceeds the reference value, an abnormal signal is generated from the comparison blow. When one of the two discharge lamps is normal and the other is abnormal, even if there is no difference in amplitude between the instantaneous lamp voltage or the instantaneous lamp current of the first and second discharge lamps, the phase If there is a difference, there will be a large difference in the first and second instantaneous lamp voltages or instantaneous lamp currents.
By comparing the absolute value of the difference between the instantaneous lamp voltage or the instantaneous lamp current with the reference value, it is possible to easily and surely detect that one of the first and second discharge lamps is normal and the other is abnormal. be able to.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing the configuration of the first embodiment of the present invention,
FIGS. 2 and 3 are waveform diagrams of the respective parts of FIG. 1 for explaining the abnormality detecting operation, and FIG. 4 is a second embodiment of the present invention.
FIG. 5 is a circuit diagram showing the configuration of the embodiment of FIG. 5, FIG. 5 is a waveform diagram of each part of FIG. 4 for explaining the abnormality detection operation, and FIG. 6 is a circuit diagram showing a modification of the circuit of FIG. Fig. 3 of the present invention
FIG. 8 is a circuit diagram of a main part showing the structure of the embodiment of the present invention, FIG. 8 is a circuit diagram of the main part showing the structure of a fourth embodiment of the present invention, and FIGS. 9 and 10 show the structure of a conventional example. It is a circuit diagram. I, II ... Non-smooth detector, III ... Comparison section

Claims (1)

[Claims] 1. A first and a second non-smooth type detecting section for detecting an instantaneous lamp voltage or an instantaneous lamp current of a first and a second discharge lamp respectively, and the first and second non-smooth type detecting sections. The absolute value of the difference between the first and second instantaneous lamp voltage or the instantaneous lamp current detected by is compared with a reference value set at a predetermined level, and an abnormal signal is generated when the absolute value of the difference exceeds the reference value. Lamp abnormality detection circuit including a comparison unit for