JPH06251886A - Discharge lamp lighting device - Google Patents

Abstract

PURPOSE:To provide a discharge lamp lighting device capable of making the light quantities of two discharge lamps uniform at low cost. CONSTITUTION:A lighting power is supplied to discharge lamps DL1, DL2 through a resonance inductor, a DC power is superposed on the lighting power and supplied to the discharge lamps DL1, DL2, and a preheating power is supplied to the discharge lamps DL1, DL2. Resonance inductors L1, L2 interposed in the feed passages to the discharge lamps DL1, DL2 have current taking windings for independently taking out a part of the lamp currents carried to the discharge lamps DL1, DL2, so that the output of a rectifying circuit SE1 is supplied to the discharge lamp DL2 as a DC power containing the light quantity correcting power, and the output of the rectifying circuit SE2 is supplied to the discharge lamp DL1 as a DC power containing the light quantity correcting power.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention illuminates a discharge lamp having a filament such as a fluorescent lamp at a high frequency by using an inverter circuit, and dims, illuminates (fade-in) and extinguishes the discharge lamp according to a dimming signal. The present invention relates to a discharge lamp lighting device for multiple lights capable of performing fade-out) and the like.

[0002]

2. Description of the Related Art FIG. 6 shows a block diagram of a conventional discharge lamp lighting device of this type (see Japanese Patent Application No. 1-182847), and FIG. 7 shows a specific circuit diagram thereof. In FIG.
A ₁ , A ₂ , and A ₃ are lighting blocks having the same structure. AC is a commercial power source supplied to each lighting block A ₁ , A ₂ , A ₃ . V ₁ is each lighting block A ₁ ,
It is a common dimming signal supplied to A ₂ and A ₃ , and each lighting block A ₁ , A ₂ and A ₃ is dimmed in common according to the dimming signal V ₁ .

The lighting block A ₁ is composed of a lighting circuit 1 ₁ , a light amount detection section 11 ₁ , a comparison section 12 ₁ , a preheating control section 13 ₁ and a discharge lamp LP ₁ . Similarly, lighting block A
₂ is a lighting circuit 1 ₂ , a light amount detection unit 11 ₂ and a comparison unit 12 ₂
And a preheat controller 13 ₂ and a discharge lamp LP ₂ . The same applies to the lighting block A ₃ . Then, each lighting block A ₁ , A ₂ , A ₃ matches the light quantity of its own discharge lamp with the light quantity of the discharge lamp of another lighting block. In the configuration of FIG. 6, between the lighting blocks A ₁ and A _{2 and} between the lighting blocks A ₂ and A ₃ ,
The respective light amounts of the discharge lamps of the other party are matched with each other so as to eliminate the variation of the light amount.

Incidentally, the description of the circuit shown in FIG.
Since it is described in detail in No. 82847, it is omitted.
Japanese Patent Application No. 1-75572 is an example of a discharge lamp lighting device capable of dimming a discharge lamp to a low luminous flux region.

[0005]

In the conventional discharge lamp lighting device shown in FIG. 6, in order to eliminate the variation in the light amount of LP ₁ and LP ₂ of each discharge lamp, the light amount detecting units 11 ₁ and 11 are provided.
₂ and the comparison units 12 ₁ and 12 ₂ are provided, but this configuration is very disadvantageous in terms of cost. Therefore, an object of the present invention is to provide a discharge lamp lighting device capable of inexpensively adjusting the light quantity of a discharge lamp without employing a special light quantity control configuration such as detecting the light quantity and comparing it with a constant reference voltage. It is to be.

[0006]

According to another aspect of the present invention, there is provided a discharge lamp lighting device for supplying lighting power to the first and second discharge lamps through an inductance element.
First and second individually extracting a part of the lamp current flowing in the first and second discharge lamps to the inductance element
Is provided, the output of the first current extraction winding is supplied to the second discharge lamp as light amount correction power, and the output of the second current extraction winding is supplied to the first discharge lamp. It is designed to be supplied to the lamp as light amount correction power.

According to another aspect of the present invention, there is provided a discharge lamp lighting device which supplies lighting power to the first and second discharge lamps through resonance inductors, respectively, and superimposes DC power on the lighting power. And the second discharge lamp, and the first and second discharge lamps are respectively inserted in the power supply paths to the first and second discharge lamps. Current extraction windings for individually extracting a part of the lamp current flowing through the first and second resonance inductors, respectively, and first and second rectification circuits for rectifying the outputs of the current extraction windings of the first and second resonance inductors, respectively. The output of the first rectifier circuit is supplied to the second discharge lamp as direct current power including the light quantity correction power, and the output of the second rectifier circuit is supplied to the first discharge lamp. It is to be supplied as a DC power.

In the discharge lamp lighting device according to the third aspect of the present invention, the lighting power is supplied to the first and second discharge lamps through the resonance inductor, and the preheating power is supplied to the first and second discharge lamps. Of the lamp current flowing through the first and second discharge lamps to the first and second resonance inductors respectively inserted in the power supply paths to the first and second discharge lamps. Each of the current extraction windings for individually extracting the parts is provided, and the output of the current extraction winding of the first resonance inductor is supplied to the second discharge lamp as preheating power including light amount correction power, The output of the current extraction winding of the second resonance inductor is supplied to the first discharge lamp as preheating power including light amount correction power.

In the discharge lamp lighting device according to the fourth aspect of the present invention, lighting power is supplied to the first and second discharge lamps via a balancer, and direct current power is superimposed on the lighting power to provide first and second lighting power. The balancer is provided with first and second current-extracting windings for individually extracting a part of the lamp currents flowing through the first and second discharge lamps, respectively. The first and second rectifying circuits for rectifying the outputs of the first and second current extraction windings of the first and second rectifying circuits are provided respectively, and the output of the first rectifying circuit is supplied to the second discharge lamp for light amount correction power. In addition to being supplied as DC power, the output of the second rectifier circuit is supplied to the first discharge lamp as DC power including light quantity correction power.

In the discharge lamp lighting device according to the present invention, lighting power is supplied to the first and second discharge lamps via a balancer, and preheating power is supplied to the first and second discharge lamps. The balancer is provided with first and second current extraction windings for individually extracting a part of the lamp current flowing through the first and second discharge lamps, respectively, and the first current extraction coil for the balancer is provided. The output of the winding is supplied to the second discharge lamp as preheating power including the light amount correction power, and the output of the second current extraction winding of the balancer is supplied to the first discharge lamp. Is supplied as preheating power.

[0011]

According to the structure of the first aspect, the light amount correction power corresponding to the lamp current of the first discharge lamp is supplied to the second discharge lamp and the lamp current of the second discharge lamp is handled. The light amount correction power is supplied to the first discharge lamp, and the light amounts of the first and second discharge lamps due to the difference in the lamp power supplied to the first and second discharge lamps are corrected. As a result, the difference between the two is reduced, and the light amounts of the first and second discharge lamps are equalized.

According to the second aspect of the present invention, the DC power including the light amount correction power corresponding to the lamp current of the first discharge lamp is supplied from the current extraction winding of the first resonance inductor to the first DC power. Direct current power supplied to the second discharge lamp through the rectifier circuit and including light amount correction power corresponding to the lamp current of the second discharge lamp is output from the current extraction winding of the second resonance inductor. First through the second rectifier circuit
Will be supplied to the discharge lamp of the first and second
First due to the difference in lamp power supplied to the discharge lamp
Also, the light amounts of the second discharge lamp are corrected and the difference between the two is reduced, and the light amounts of the first and second discharge lamps are made uniform.

According to the third aspect of the present invention, the preheating power including the light amount correction power corresponding to the lamp current of the first discharge lamp is supplied from the current extraction winding of the first resonance inductor to the second coil. Is supplied to the discharge lamp of the second discharge lamp, and the preheating power including the light amount correction power corresponding to the lamp current of the second discharge lamp is supplied from the current extracting winding of the second resonance inductor to the first discharge lamp. Will be supplied, first
And the light amount of the first and second discharge lamps due to the difference in lamp power supplied to the second discharge lamp is corrected, and the difference between the two is reduced, and the light amount of the first and second discharge lamps is reduced. Will be available.

According to the fourth aspect of the present invention, the DC power including the light amount correction power corresponding to the lamp current of the first discharge lamp is supplied from the first current extracting winding of the balancer to the first rectifying circuit. Is supplied to the second discharge lamp via the second discharge lamp, and the DC power containing the light amount correction power corresponding to the lamp current of the second discharge lamp is supplied to the second rectification from the second current extraction winding of the balancer. It is supplied to the first discharge lamp through the circuit, and the light amounts of the first and second discharge lamps due to the difference in the lamp power supplied to the first and second discharge lamps are corrected and both are corrected. Will be reduced, and the light amounts of the first and second discharge lamps will be equalized.

According to the fifth aspect of the present invention, the preheating power including the light amount correction power corresponding to the lamp current of the first discharge lamp is supplied from the first current extracting winding of the balancer to the second current extracting coil.
And the preheating power including the light amount correction power corresponding to the lamp current of the second discharge lamp is supplied from the second current extracting winding of the balancer to the first discharge lamp. Therefore, the light amounts of the first and second discharge lamps due to the difference in the lamp power supplied to the first and second discharge lamps are corrected, and the difference between the two is reduced. The light quantity of the second discharge lamp is equalized.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. [First Embodiment] FIG. 1 shows a circuit diagram of a discharge lamp lighting device according to a first embodiment of the present invention. This discharge lamp lighting device includes two lighting blocks A ₁₁ , which receive a common dimming signal V ₁ .
Consist A _12, the lighting block A _11, (which may include a smoothing circuit) rectified circuit voltage of the commercial power source AC is rectified by DB _1, the DC is supplied the output of the rectifier circuit DB ₁ to the inverter IN ₁ power Is converted to high frequency power. The inverter IN ₁ is controlled by the inverter control unit IC ₁ to which the dimming signal V ₁ is input, and oscillates at a frequency according to the dimming signal V ₁ .

The inverter IN ₁ discharges a fluorescent lamp or the like through a resonance circuit composed of a coupling capacitor C ₁ , a resonance inductor (corresponding to an inductance element in the claims) L ₁ and a resonance capacitor C _3. the high-frequency power to the lamp DL ₁ is supplied as the lighting power, the discharge lamp DL ₁ is made to high frequency lighting. At this time, when the oscillation frequency of the inverter IN ₁ is changed according to the dimming signal V ₁ , the impedance of the resonance circuit changes and the lamp power supplied to the discharge lamp DL ₁ changes, whereby dimming is performed.

Further, the output of inverter IN ₁ is supplied to the primary winding of the preheating transformer T ₁ via the coupling capacitor C ₁ and capacitor C _5, the preheating transformer T ₁
Preheating power is supplied from the two secondary windings to both filaments of the discharge lamp DL ₁ to preheat both filaments of the discharge lamp DL ₁ . In addition, a resonance inductor L ₁ that is inserted in a power supply path to the discharge lamp DL ₁ to form a resonance circuit is provided with a current extraction winding that extracts a part of the lamp current flowing in the discharge lamp DL ₁ . , and direct current output of the current extraction winding of the resonant inductor L ₁ diode D _1, the capacitor C _7, by the rectifier circuit SE ₁ consisting inductor L ₃ and a diode D _2, the rectifier circuit SE ₁
DC power is supplied to the discharge lamp DL ₂ from the superposed high frequency power.

On the other hand, the lighting block A₁₂Then commercial power supply A
Rectifier circuit for C voltage (may include smoothing circuit) DB
₂Rectified by, rectifier circuit DB₂Output of inverter IN₂
DC power is converted to high frequency power by being supplied to. Inn
Barta IN₂Is the dimming signal V ₁Inverter to which is input
Control unit IC₂Controlled by the dimming signal V₁According to
It oscillates at the wave number.

The inverter IN ₂ discharges a fluorescent lamp or the like through a resonance circuit including a coupling capacitor C ₂ , a resonance inductor (corresponding to an inductance element in the claims) L ₂ and a resonance capacitor C _4. the high-frequency power to the lamp DL ₂ is supplied as the lighting power, the discharge lamp DL ₂ is made to high frequency lighting. At this time, when the oscillation frequency of the inverter IN ₂ is changed according to the dimming signal V ₁ , the impedance of the resonance circuit changes and the lamp power supplied to the discharge lamp DL ₂ changes, whereby dimming is performed.

Further, the output of inverter IN ₂ is supplied to the primary winding of the preheating transformer T ₂ via a coupling capacitor C ₂ and the capacitor C _6, preheating transformer T ₂
The preheating power is supplied from the two secondary windings to both filaments of the discharge lamp DL ₂ to preheat both filaments of the discharge lamp DL ₂ . In addition, a resonance inductor L ₂ that is inserted in a power supply path to the discharge lamp DL ₂ to form a resonance circuit is provided with a current extraction winding that extracts a part of the lamp current flowing in the discharge lamp DL ₂ . , and direct current output of the current extraction winding of the resonant inductor L ₂ diode D _3, capacitor C _8, the inductor L ₄ and the diode D ₄ than consisting rectifier circuit SE _2, the rectifier circuit SE ₂
DC power is superposed on the high frequency power and supplied to the discharge lamp DL ₁ .

In other words, this discharge lamp lighting device has a discharge run.
DL₁To the inverter IN₁From resonance inductor
L₁High frequency power is supplied as lighting power via
Vibration inductor L₂From the current extraction winding of the
DC power including power is superimposed on the high frequency power and supplied.
Inverter IN₁From preheat transformer T₁Via preheating for electricity
Power supply, also discharge lamp DL₂To the inverter
IN₂To resonance inductor L₂High frequency power through
Resonance inductor L supplied as lighting power ₁Current
High frequency DC power including light intensity correction power from the extraction winding
Inverter IN₂From preheat
Lance T₂Power for preheating is supplied via. Sanawa
This discharge lamp lighting device is designed for DC power superimposition.
Flow circuit SE₁, SE₂And discharge lamp DL₁, DL₂And
They are cross-connected.

With this structure, the discharge lamp DL ₁
DC power including light intensity correction power corresponding to the lamp current is supplied to the discharge lamp DL ₂ from the current extraction winding of the resonance inductor L ₁ via the rectifier circuit SE ₁ , and the discharge lamp DL ₂ DC power including light intensity correction power corresponding to the lamp current is discharged from the current extracting winding of the resonance inductor L ₂ through the rectifier circuit SE ₂ to the discharge lamp DL.
_Will be supplied to ₁ . That is, the discharge lamp D
DC power is supplied to the discharge lamps DL ₁ and DL ₂ contrary to the magnitude relation of the high frequency lamp currents of L ₁ and DL ₂ .

[0024] reducing the difference between to correct the light quantity of the discharge lamp DL _1, DL ₂ due to difference in lamp power difference between the direct current power to be superimposed in this manner is supplied to the discharge lamp DL _1, DL ₂ Therefore, the light amounts of the discharge lamps DL ₁ and DL ₂ can be made uniform, and the two discharge lamps DL ₁ and D 2 can be arranged.
It is possible to reduce the variation in the light amount of L ₂ . Therefore, the light quantity detecting unit and the comparing unit as in the conventional example are not required, and it is sufficient to cross-connect the rectifier circuits SE ₁ and SE ₂ and the discharge lamps DL ₁ and DL ₂ for superimposing the DC power. The cost is cheap.

[Second Embodiment] FIG. 2 shows a circuit diagram of a discharge lamp lighting device according to a second embodiment of the present invention. This discharge lamp lighting device is composed of two lighting blocks A ₂₁ and A ₂₂ for inputting a common dimming signal V ₁ , and in the lighting block A ₂₁ , the coupling capacitor C ₁ and the resonance inductor are connected from the inverter IN _1. L ₅ (corresponding to the inductance element in the claims) and the resonance capacitor C ₃
Discharge lamp D such as a fluorescent lamp through a resonance circuit consisting of
High frequency power is supplied to L ₁ as lighting power.

The output of the inverter IN ₁ is supplied to the primary winding of the DC voltage superposition transformer T ₃ via the coupling capacitor C ₁ and the capacitor C _9, and the secondary winding of the DC voltage superposition transformer T ₃ is supplied. Output of diode D ₅ ,
Capacitor C ₁₁ , inductor L ₇ and diode D ₆
This rectifier circuit SE ₃ is converted into direct current, and this rectifier circuit SE 3
DC power is supplied from ₃ to the discharge lamp DL ₁ superimposed on the high frequency power.

Further, the resonance inductor L ₅ which is inserted in the power supply path to the discharge lamp DL ₁ and constitutes a resonance circuit,
Two current extraction windings (preheating windings) for extracting a part of the lamp current flowing through the discharge lamp DL ₁ are provided, and the output of the current extraction winding of the resonance inductor L ₁ is connected to that of the discharge lamp DL ₂ . Supplying electric power for preheating to both filaments,
Both filaments of the discharge lamp DL ₂ are preheated.

On the other hand, in the lighting block A ₁₂ , from the inverter IN ₂ , a resonance circuit including a coupling capacitor C ₂ , a resonance inductor (corresponding to an inductance element in claims) L ₆ and a resonance capacitor C ₄ is provided. High frequency power is supplied as lighting power to the discharge lamp DL ₂ such as a fluorescent lamp via the
₂ is lit at high frequency.

The output of the inverter IN ₂ is supplied to the primary winding of the DC voltage superposition transformer T ₄ via the coupling capacitor C ₂ and the capacitor C _10, and the secondary winding of the DC voltage superposition transformer T ₄ is supplied. Output of diode D ₇ ,
Capacitor C ₁₂ , inductor L ₈ and diode D ₈
This rectifier circuit SE ₄ is converted into direct current, and this rectifier circuit SE
DC power is supplied from ₄ to the discharge lamp DL ₂ superimposed on the high frequency power.

Further, the resonance inductor L ₆ which is inserted in the power supply path to the discharge lamp DL ₂ and constitutes a resonance circuit,
Two current extraction windings (preheating windings) for extracting a part of the lamp current flowing through the discharge lamp DL ₂ are provided, and the output of the resonance inductor L ₂ current extraction winding is supplied to the discharge lamp DL ₁ . Supplying electric power for preheating to both filaments,
Both filaments of the discharge lamp DL ₁ are preheated.

[0031] That is, the discharge lamp lighting device, the discharge to the lamp DL ₁ supplies high-frequency power as the lighting power from the inverter IN ₁ via the resonance inductor L _5, a DC voltage superimposed transformer T from the inverter IN ₁ DC power is supplied via _3, and preheating power including light amount correction power is supplied from the current extraction winding of the resonance inductor L ₆ .
Further, to the discharge lamp DL ₂ , high frequency power is supplied as lighting power from the inverter IN ₂ via the resonance inductor L _6, and DC power is supplied from the inverter IN ₂ via the DC voltage superposition transformer T ₄ . Resonance inductor L
_The preheating power including the light power correction power is supplied from the ₅ current extraction winding. That is, this discharge lamp lighting device includes a resonance inductor L ₅ , for supplying preheating power,
The current extracting winding of L ₆ and the discharge lamps DL ₁ and DL ₂ are cross-connected.

The configuration other than the above is the same as that of the embodiment of FIG. With this configuration, the preheating power including the light amount correction power corresponding to the lamp current of the discharge lamp DL ₁ is supplied from the current extraction winding of the resonance inductor L ₅ to the discharge lamp D 5.
The preheating power supplied to the L ₂ and including the light amount correction power corresponding to the lamp current of the discharge lamp DL ₂ is discharged from the current extraction winding of the resonance inductor L ₆ to the discharge lamp D 6.
Will be supplied to L ₁ . That is, the discharge lamp DL
_1, the preheating power magnitude relationship opposite to the discharge lamp DL _1, DL ₂ of DL ₂ of the high frequency of the lamp current will be supplied.

[0033] to reduce the difference therebetween to correct the light quantity of the discharge lamp DL _1, DL ₂ due to difference in lamp power difference of the thus preheating power supply is supplied to the discharge lamp DL _1, DL ₂ Therefore, the discharge lamps DL ₁ and DL ₂
Of the two discharge lamps DL ₁ ,
It is possible to reduce variations in the light amount of DL ₂ . Further, for that reason, the light amount detection unit and the comparison unit unlike the conventional example are not required,
Resonance inductors L ₅ and L ₆ for supplying preheating power
It suffices to cross-connect the current extraction winding and the discharge lamps DL ₁ and DL ₂ and the cost is low.

[Third Embodiment] FIG. 3 shows a third embodiment of the present invention.
The circuit diagram of the discharge lamp lighting device of an Example is shown. This discharge light point
The lighting device uses a rectifier circuit (smoothing circuit
(May include) DB ₃Rectified by, rectifier circuit DB₃Out of
Power IN inverter₃DC power is supplied to the high frequency power
Has been converted to. Inverter IN₃Is the dimming signal V₁But
Input inverter control IC₃Controlled by
Optical signal V₁It oscillates at a frequency according to.

Inverter IN₃From the coupling
Indexer C₁₃And a resonance inductor (see the claims)
Corresponding to the inductance element) L₉And preheating
Resonance capacitor C₁₄Through the resonance circuit consisting of
Discharge lamp DL₁High frequency power for lighting
And the discharge lamp DL for supplying as preheating power.₁High
The frequency is turned on. Similarly, coupling capacitors
C₁₃And a resonance inductor (in the claims
Equivalent to the inductance element) L_TenAnd for preheating and resonance
Indexer C₁₅Through a resonant circuit consisting of
Discharge lamp DL ₂High frequency power for lighting power and preheating
Supply as electric power for discharge lamp DL ₂High frequency lighting
I am letting you. At this time, the dimming signal V₁According to the inverter
IN₃If you change the oscillation frequency of the
Dance changes and discharge lamp DL₁, DL₂Supplied to
Lamp power changes, which causes dimming
It

Further, the resonance inductor L ₉ forming a resonance circuit by being inserted in the power supply path to the discharge lamp DL ₁ is
A current extracting winding for extracting a part of the lamp current flowing in the discharge lamp DL ₁ is provided, and the output of the current extracting winding of the resonance inductor L ₉ is a diode D ₉ and a capacitor C.
_A rectifier circuit SE _{5 including} an inductor ₁₆ , an inductor L ₁₁ and a diode D ₁₀ converts the rectified current into a direct current, and the rectified circuit SE ₅ supplies the direct current power to the discharge lamp DL ₂ in superposition with the high frequency power.

Further, the resonance inductor L ₁₀ which is inserted in the power supply path to the discharge lamp DL ₂ and constitutes a resonance circuit,
A current extracting winding for extracting a part of the lamp current flowing in the discharge lamp DL ₂ is provided, and the output of the current extracting winding of the resonance inductor L ₁₀ is a diode D ₁₁ and a capacitor C.
_A rectifier circuit SE ₆ composed of an inductor ₁₇ , an inductor L ₁₂ and a diode D ₁₂ converts the DC power into direct current power, and the DC power is supplied from the rectifier circuit SE ₆ to the discharge lamp DL ₁ while being superimposed on the high frequency power.

That is, this discharge lamp lighting device supplies high-frequency power as lighting power to the discharge lamp DL ₁ from the inverter IN ₃ through the resonance inductor L ₉ and extracts the current from the resonance inductor L ₁₀ . DC power including power for light amount correction is superimposed and supplied from the winding on the high frequency power, and preheating power is supplied from the inverter IN ₃ through the preheating / resonance capacitor C ₁₄ to the discharge lamp DL ₂ . Is
High frequency power is supplied from the inverter IN ₃ through the resonance inductor L ₁₀ as lighting power, and DC power including light intensity correction power is superimposed on the high frequency power from the current extracting winding of the resonance inductor L _9. Supply and inverter IN ₃
The preheating power is supplied via the preheating and resonance capacitor C ₁₅ . That is, in this discharge lamp lighting device, the rectifier circuits SE ₅ and SE ₆ for superimposing DC power and the discharge lamps DL ₁ and DL ₂ are cross-connected.

With this structure, the discharge lamp DL ₁
DC power including the light amount correction power corresponding to the lamp current is supplied from the resonance inductor L ₉ to the discharge lamp DL ₂ via the rectifier circuit SE ₅ , and the discharge lamp D
DC power including the light amount correction power corresponding to the lamp current of L ₂ is supplied from the resonance inductor L ₁₀ to the discharge lamp DL ₁ through the rectifier circuit SE ₆ . That is, the discharge lamp DL _1, DC power to the magnitude relation opposite to the discharge lamp DL _1, DL ₂ of DL ₂ of the high frequency of the lamp current will be supplied.

The effect of this embodiment is similar to that of the first embodiment.
is there. [Fourth Embodiment] FIG. 4 shows the discharge according to the fourth embodiment of the present invention.
The circuit diagram of a lamp lighting device is shown. This discharge lamp lighting device
The voltage of the power supply AC for the rectification circuit (including the smoothing circuit in some cases
DB) ₃Rectified by, rectifier circuit DB₃Invert the output of
Tain₃DC power to high frequency power
It Inverter IN₃Is the dimming signal V₁Is entered
Inverter control unit IC₃Controlled by the dimming signal V₁To
It oscillates at the corresponding frequency.

Inverter IN₃From the coupling
Indexer C₁₃And resonance inductor L ₁₃And for preheating and resonance
Indexer C₁₄A resonant circuit and a balancer (claimed
BL equivalent to the inductance element in the range)₁of
Discharge lamp DL such as a fluorescent lamp through one winding₁
Supply high frequency power as lighting power to the discharge lamp
DL₁Is lit at high frequency.

Similarly, the coupling capacitor C ₁₃ , the resonance inductor L _13, and the preheating / resonance capacitor C _{15 are used.}
And supplying high-frequency power as the lighting power to the discharge lamp DL ₂ such as a fluorescent lamp via become more other winding of the resonant circuit and the balancer BL _1, the discharge lamp DL ₂ is made to high frequency lighting. At this time, when the oscillation frequency of the inverter IN ₃ is changed according to the dimming signal V ₁ , the impedance of the resonance circuit is changed and the lamp power supplied to the discharge lamps DL ₁ and DL ₂ is changed, whereby dimming is performed. Done.

The balancer BL ₁ has a discharge lamp D.
A current extraction winding (coupled to one winding) n ₁ for extracting a part of the lamp current flowing in L ₁ and a current extraction winding (another winding) for extracting a part of the lamp current flowing in the discharge lamp DL ₂ N ₂ ) and a current extracting winding n ₁
Output diode D ₁₃ of the capacitor C _18, and direct current in the inductor L ₁₄ and the diode D ₁₄ consisting of the rectifier circuit SE _7, supplied by superimposing the high-frequency power to DC power from the rectifier circuit SE ₇ to the discharge lamp DL ₂ , The output of the winding n ₂ for current extraction is a rectifier circuit SE ₈ comprising a diode D ₁₅ , a capacitor C ₁₉ , an inductor L ₁₅ and a diode D _16.
Then, the rectification circuit SE ₈ supplies the DC power to the discharge lamp DL ₁ by superimposing it on the high frequency power.

That is, this discharge lamp lighting device supplies high-frequency power as lighting power to the discharge lamp DL ₁ from the inverter IN ₃ through the resonance inductor L ₁₃ and one winding of the balancer BL ₁ . DC power including power for light amount correction is superimposed on the high frequency power and supplied from the current extraction winding n _{2 of the} balancer BL ₁ , and preheating power is supplied from the inverter IN ₃ through the preheating / resonance capacitor C _14. and, also, the discharge into the lamp DL _2, and supplying high-frequency power as the lighting power from the inverter iN ₃ via the other winding of the resonant inductor L ₁₀ and the balancer BL _1, winding current extraction balancer BL ₁ Direct-current power including light-amount correction power is superimposed and supplied from the line n ₁ on high-frequency power, and preheating power is supplied from the inverter IN ₃ via the preheating / resonance capacitor C ₁₅ . That is, this discharge lamp lighting device includes rectifier circuits SE ₇ , SE for superimposing DC power.
₈ and the discharge lamps DL ₁ and DL ₂ are cross-connected.

With this structure, the discharge lamp DL₁
DC power that includes light intensity correction power corresponding to the lamp current of
Power balancer BL₁Current extraction winding n₁From rectifier circuit
SE ₇Through the discharge lamp DL₂To be supplied to
The discharge lamp DL₂Light intensity correction corresponding to the lamp current of
DC power including the power for the balancer BL₁For current extraction
Winding n₂From rectifier circuit SE₈Through the discharge lamp DL₁
Will be supplied to. That is, the discharge lamp DL₁，
DL₂Contrary to the magnitude relationship of the high frequency lamp current,
DL₁, DL₂DC power will be supplied to.

The effects of this embodiment are similar to those of the first embodiment. [Fifth Embodiment] FIG. 5 shows a circuit diagram of a discharge lamp lighting device according to a fifth embodiment of the present invention. In this discharge lamp lighting device, a resonance circuit including a coupling capacitor C ₁₃ , a resonance inductor L _13, and a resonance capacitor C ₂₂ and a balancer (corresponding to an inductance element in claims) BL ₂ from the inverter IN _3. High-frequency power is supplied as lighting power to the discharge lamp DL ₁ such as a fluorescent lamp through one of the windings to light the discharge lamp DL ₁ at a high frequency. Similarly, high frequency power is supplied to the discharge lamp DL ₂ such as a fluorescent lamp through the resonance circuit including the coupling capacitor C ₁₃ , the resonance inductor L _13, and the resonance capacitor C ₂₃ and the other winding of the balancer BL ₂ . It is supplied as electric power and the discharge lamp DL ₂ is lit at high frequency.

Further, the balancer BL ₂ has a discharge lamp D.
Current extraction winding for extracting a part of the lamp current flowing in L ₁ (winding for preheating coupled to one winding) n ₃ , n ₄ and current extraction for extracting a part of the lamp current flowing in the discharge lamp DL ₂ Winding (preheating winding coupled to the other winding)
n ₅ and n ₆ are provided, and the current extracting windings n ₃ and n _{4 are provided.}
Is supplied to the filament of the discharge lamp DL ₂ as preheating power to preheat the filament of the discharge lamp DL ₂ and the outputs of the current extraction windings n ₅ and n ₆ are supplied to the discharge lamp DL.
The filament of the discharge lamp DL ₁ is preheated by supplying the filament of _{No. 1} as electric power for preheating.

Further, the inverter IN₃In the caplin
Condenser C₁₃And C₂₀DC voltage superposition via
T_FiveThis is connected to the primary winding of
T_FiveOutput of the primary winding of the diode D₁₇， Conden
SA C_{twenty one}, Inductor L₁₆And diode D₁₈Consists of
Rectifier circuit SE₉This is a rectifier circuit SE₉Straight from
Current flow discharge lamp DL₁, DL₂Superimposed on high frequency power
And then supply. In other words, this discharge lamp lighting device
Electric lamp DL₁To the inverter IN₃From resonance for in
Ducta L₁₃And balancer BL₂Through one winding
High frequency power is supplied as lighting power to balancer BL₂
Current extraction winding n₃, N_FourIncluding power for light intensity correction
Power for preheating is supplied to the inverter IN₃From DC voltage
Superimposing transformer T_FiveDC power over high frequency power via
Tatami mat is supplied, and the discharge lamp DL₂To the Inver
Tain₃To resonance inductor L₁₃And balancer BL
₂High-frequency power as lighting power through the other winding of
Supply and balancer BL ₂Current extraction winding n_Five, N₆Or
Supply the power for preheating including the power for light intensity correction from the
Data IN₃To DC voltage transformer T_FiveDirect current through
Power is supplied by superimposing it on high-frequency power. That is,
This discharge lamp lighting device is designed to supply power for preheating.
Sensor BL₂Current extraction winding n₃, N_Four, N_Five, N₆When
Discharge lamp DL₁, DL₂And are cross-connected.

The configuration other than the above is the same as that of FIG. this
With this configuration, the discharge lamp DL₁Against the lamp current of
The balancer B is the preheating power that includes the corresponding light intensity correction power.
L₂Current extraction winding n₃, N_FourFrom discharge lamp DL₂
Is supplied to the discharge lamp DL₂Lamp current
The power for preheating that includes the power for light intensity correction that corresponds to
BL₂Current extraction winding n_Five, N ₆From discharge lamp D
L₁Will be supplied to. That is, the discharge lamp DL
₁, DL₂Contrary to the magnitude relationship of the high-frequency lamp current, discharge
Lamp DL₁, DL₂To be supplied with preheating power
Become.

The effects of this embodiment are similar to those of the second embodiment. In addition, although the above-described embodiments have been described with respect to the discharge lamp lighting device for two lamps, the present invention is also applied to the discharge lamp lighting device for three or more multiple lamps to control the brightness of each discharge lamp. Needless to say, it can be made uniform. Further, the configuration of the inverter circuit for supplying the high frequency power may be any configuration.

Further, in each of the above-described embodiments, the one in which the discharge lamp is lit at high frequency has been described, but the effect of matching the brightness of a plurality of discharge lamps can be obtained even in the case of lighting at a commercial frequency. Further, in each of the above-described embodiments, the one in which the discharge lamp is dimmed has been described, but even in the case where the dimming is not performed, the effect of matching the brightness of the plurality of discharge lamps can be obtained.

[0052]

According to the discharge lamp lighting device of the first aspect of the present invention, the output of the first current extracting winding of the inductance element is supplied to the second discharge lamp as the light amount correction power, and at the same time, the second Since the output of the current extraction winding is supplied to the first discharge lamp as the light amount correction power, the output of the first and second discharge lamps varies depending on the difference in the lamp power supplied to the first and second discharge lamps. The amount of light can be corrected to reduce the difference between the two, the amounts of light of the first and second discharge lamps can be made uniform, and the variations in the amount of light of the first and second discharge lamps can be reduced. Further, for that reason, the light quantity detecting unit and the comparing unit as in the conventional example are not required, and only the first and second current extraction windings and the first and second discharge lamps need to be cross-connected, and the cost can be reduced. Economically cheap.

According to the second aspect of the present invention, the output of the first rectifier circuit for rectifying the current output winding output of the first resonance inductor is supplied to the second discharge lamp with light amount correction power. In addition to being supplied as DC power, the output of the second rectifying circuit that rectifies the current extraction winding output of the second resonance inductor is supplied to the first discharge lamp as DC power including light quantity correction power. , The amount of light of the first and second discharge lamps due to the difference in lamp power supplied to the first and second discharge lamps is corrected to reduce the difference between the two, and the first and second discharge lamps are reduced. The light amounts of the lamps can be made uniform, and the variation in the light amounts of the first and second discharge lamps can be reduced. Further, for that reason, the light quantity detecting unit and the comparing unit as in the conventional example are not required, and only the first and second rectifying circuits for superimposing DC power and the first and second discharge lamps are cross-connected. It's good, and it's cheap.

According to the third aspect of the present invention, the output of the current extracting winding of the first resonance inductor is supplied to the second discharge lamp as preheating power including light amount correction power, and Since the output of the current extraction winding of the second resonance inductor is supplied to the first discharge lamp as preheating power including light quantity correction power, the lamp power supplied to the first and second discharge lamps is First and second due to the difference
The light amount of the discharge lamp is corrected to reduce the difference between the two, the light amounts of the first and second discharge lamps can be made uniform, and the variation in the light amount of the first and second discharge lamps can be reduced. . Further, for that reason, the light quantity detecting unit and the comparing unit as in the conventional example are not required, and the current extraction windings of the first and second resonance inductors and the first and second resonance inductors for supplying the preheating power are not required. All you have to do is cross-connect the discharge lamp, and the cost will be low.

According to the structure of claim 4, the output of the first rectifying circuit for rectifying the output of the first current extracting winding of the balancer is supplied to the second discharge lamp, and the DC power containing the light amount correcting power is supplied. And the output of the second rectifier circuit that rectifies the output of the second current extracting winding of the balancer is supplied to the first discharge lamp as DC power including light intensity correction power. The light amount of the first and second discharge lamps is corrected by reducing the light amount of the first and second discharge lamps due to the difference in the lamp power supplied to the second discharge lamp. It is possible to make them uniform, and it is possible to reduce variations in the light amounts of the first and second discharge lamps. Further, for that reason, the light quantity detecting unit and the comparing unit as in the conventional example are not required, and only the first and second rectifying circuits for superimposing DC power and the first and second discharge lamps are cross-connected. It's good, and it's cheap.

According to the fifth aspect of the present invention, the output of the first current extracting winding of the balancer is supplied to the second discharge lamp as preheating power including the light amount correction power, and the balancer first The output of the current output winding 2 of the first
Is supplied as preheating power including the light amount correction power to the first discharge lamp, the light amounts of the first and second discharge lamps due to the difference in the lamp power supplied to the first and second discharge lamps are corrected. As a result, the difference between the two can be reduced, and the light quantities of the first and second discharge lamps can be made uniform.
It is possible to reduce variations in the light amounts of the first and second discharge lamps. Further, for that reason, the light quantity detecting unit and the comparing unit as in the conventional example are not required, and the first and second current extracting windings of the balancer for supplying the preheating power and the first and second
All you have to do is cross-connect with the discharge lamp of, and the cost will be low.

[Brief description of drawings]

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

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

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

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

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

FIG. 6 is a circuit diagram showing a configuration of an example of a conventional discharge lamp lighting device.

FIG. 7 is a circuit diagram showing a specific configuration of the discharge lamp lighting device of FIG.

[Explanation of symbols]

AC commercial power supply DB ₁ , DB ₂ rectifier circuit IN ₁ , IN ₂ inverter IC ₁ , IC ₂ inverter control unit DL ₁ , DL ₂ discharge lamp SE ₁ , SE ₂ rectifier circuit T ₁ , T ₂ preheating transformer L ₁ , L ₂ Resonance inductor C ₁ , C ₂ Coupling capacitor C ₃ , C ₄ Resonance capacitor D ₁ , D ₂ , D ₃ , D ₄ Diode T ₃ , T ₄ DC voltage superposition transformer L ₅ , L ₆ Resonance inductor SE ₃ , SE ₄ Rectifier circuit DB ₃ Rectifier circuit IN ₃ Inverter IC ₃ Inverter control unit L ₉ , L ₁₀ Resonance inductor SE ₅ , SE ₆ Rectifier circuit C ₁₄ , C ₁₅ Resonance capacitor L ₁₃ Resonance inductor SE ₇ , SE ₈ Rectifier circuit BL ₁ balancer BL ₂ balancer SE ₉ Rectifier circuit T ₅ DC voltage superposition transformer C ₂₂ , C ₂₃ Resonant capacitor

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location H05B 41/392 M 9032-3K

Claims (5)

[Claims] 1. A discharge lamp lighting device in which lighting power is supplied to the first and second discharge lamps through an inductance element, wherein the inductance element flows to the first and second discharge lamps. First and second current extraction windings for individually extracting a part of the current are provided, and the output of the first current extraction winding is supplied to the second discharge lamp as light quantity correction power. A discharge lamp lighting device, wherein the output of the second current extraction winding is supplied to the first discharge lamp as light amount correction power. 2. The first and second discharge lamps are each supplied with lighting power via a resonance inductor, and DC power is superimposed on the lighting power to the first and second discharge lamps. In the discharge lamp lighting device configured to respectively supply the first and second resonance inductors, which are respectively inserted in power supply paths to the first and second discharge lamps, the first resonance inductor is provided.
And a current extraction winding for individually extracting a part of the lamp current flowing through the second discharge lamp,
And first and second rectifying circuits for rectifying the output of the current extracting winding of the second resonance inductor,
The output of the first rectifier circuit is supplied to the second discharge lamp as direct-current power including light amount correction power, and the output of the second rectifier circuit is supplied to the first discharge lamp. A discharge lamp lighting device, characterized in that it is supplied as DC power containing 3. A discharge device adapted to supply lighting power to the first and second discharge lamps via a resonance inductor and preheat power to the first and second discharge lamps respectively. In the electric lamp lighting device, the first and second resonance inductors are respectively inserted in power supply paths to the first and second discharge lamps.
And a current extraction winding for individually extracting a part of the lamp current flowing through the second discharge lamp,
The output of the current extracting winding of the resonance inductor of
Is supplied to the discharge lamp as preheating power including light intensity correction power, and the output of the current extraction winding of the second resonance inductor is supplied to the first discharge lamp as preheating power including light intensity correction power. A discharge lamp lighting device characterized in that it is supplied as electric power for use. 4. The lighting power is supplied to the first and second discharge lamps via a balancer, and the DC power is superimposed on the lighting power and supplied to the first and second discharge lamps, respectively. In the discharge lamp lighting device configured as described above, the balancer is provided with first and second current extraction windings for individually extracting a part of the lamp current flowing through the first and second discharge lamps, respectively. First and second rectifying circuits for rectifying the outputs of the first and second current-extracting windings, respectively, are provided, and the output of the first rectifying circuit is supplied to the second discharge lamp with light amount correction power. Discharge in which the output of the second rectifier circuit is supplied to the first discharge lamp as DC power including light amount correction power while being supplied as DC power including Lighting device. 5. A discharge lamp lighting device, wherein lighting power is supplied to the first and second discharge lamps via a balancer, and preheating power is supplied to the first and second discharge lamps, respectively. In the balancer, first and second current extraction windings for individually extracting a part of the lamp currents flowing through the first and second discharge lamps are provided, respectively, and the first current extraction winding of the balancer is provided. The output of the line is supplied to the second discharge lamp as preheating power including light amount correction power,
The output of the second current extracting winding of the balancer is set to the first output.
The discharge lamp lighting device is configured to be supplied as preheating power including light amount correction power to the discharge lamp.