JPH05326172A - Discharge lamp lighting device - Google Patents

Abstract

PURPOSE:To light an incandescent lamp to compensate a luminous flux shortage at the time of starting a discharge lamp, and minimize the change of the luminous flux in which the output luminous fluxes of the discharge lamp and the incandescent lamp are added. CONSTITUTION:A power source circuit la rectifies a commercial AC power source AC and outputs a DC voltage raised in voltage. A lighting circuit 1b reduces the output voltage of the power source circuit 1a and supplies it to a discharge lamp La. A power source control circuit 3a keeps the output voltage of the power source circuit 1a nearly constant. As the output luminous flux of the discharge lamp La is increased, the power source control circuit 3a extends the on-period of a switching element Q1. A signal the ON/OFF of which is reversed from a control signal for controlling the switching element Q1 is inputted to a light control circuit 2, and the light control circuit 2 lights an incandescent lamp Lb on the basis of this signal. Thus, according to an increase in output light quantity of the discharge lamp La, the output light quantity of the incandescent lamp Lb is reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention mainly relates to a discharge lamp lighting device for lighting an incandescent lamp in order to compensate a shortage of luminous flux during a period until a high pressure discharge lamp reaches a steady lighting state.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG. 8, an incandescent lamp Lb is provided in a main circuit 1 for lighting a discharge lamp La which is a high pressure discharge lamp.
It is considered to add the light compensation circuit 2 for lighting the lamp to light the incandescent lamp Lb during the period when the discharge lamp La is not in the steady lighting state. That is, since the high-pressure discharge lamp has a relatively long time from the power-on to the steady lighting state and has a low luminous flux until the steady-lighting state, the light amount is insufficient for a relatively long time from the power-on. Therefore, in order to compensate for the shortage of the amount of light, the incandescent lamp Lb is turned on during the period when the discharge lamp La has a low luminous flux.

In the circuit configuration of FIG. 8, the discharge lamp La is connected to a commercial AC power source AC via a choke coil CH which is a current limiting element constituting the main circuit 1. Further, the fact that the discharge lamp La has reached the steady lighting state is estimated by detecting the voltage across the discharge lamp La (lamp voltage). That is, the light compensation circuit 2 constitutes a light compensation device together with the incandescent lamp Lb, and the lamp voltage detection circuit 21 for detecting the lamp voltage and the comparison circuit 22 for comparing the detected lamp voltage with a predetermined reference voltage. And a drive circuit 23 that generates a trigger signal at a predetermined phase synchronized with the power supply frequency of the commercial AC power supply AC when it is determined that the discharge lamp La is not in the steady lighting state based on the comparison result of the comparison circuit 22.
A series circuit including the incandescent lamp Lb is connected to the commercial AC power supply AC, and includes a switch element 24 formed of a triac that is turned on when a trigger signal is generated from the drive circuit 23.
The lamp voltage detection circuit 21 rectifies and smoothes the voltage across the discharge lamp La and outputs the average value of the lamp voltage. The comparator circuit 22 includes two upper and lower reference voltages V _A and V _B (V _A > V).
_B ) is set, the output voltage V of the lamp voltage detection circuit 21
_L is compared with both reference voltages V _A and V _B. If the output voltage V _L is a value between the reference voltages V _A and V _B (V _A ≧ V _L ≧
V _B ), the discharge lamp La is regarded as a steady lighting state, and the switch element 24 is kept in the off state. On the other hand, when the output voltage V _L is outside the range of the reference voltages V _A and V _B (V _A <V _L or V _L <V _B ), it is considered that the discharge lamp La is not in the steady lighting state, and the switch element 24 is turned on. It is controlled so as to be turned on at a predetermined phase in synchronization with the power supply frequency of the commercial AC power supply AC. That is, if the discharge lamp La is not in the steady lighting state,
The incandescent lamp Lb is turned on to compensate for the shortage of luminous flux.

[0004] As shown in FIG. 9, the power is turned at time t _0, the discharge lamp La is lighted becomes time t _1, the output voltage V _L becomes a time t ₂ becomes equal to or higher than the reference voltage V _B I shall. In this case, the output voltage V _L of the lamp voltage detection circuit 21
, As in FIG. 9 (a), from power of the time t ₀ until time of lighting time t ₁ has exceeded the reference voltage V _A, the discharge lamp La is lighted at time t ₁ the lamp voltage detecting circuit 21. The output voltage V _{L of} 21 instantaneously decreases, then the output voltage V _L increases, and at time t ₂ , the output voltage V _{L changes} to the reference voltage V _L.
B or higher. Therefore, as shown in FIG.
The incandescent lamp Lb is lit during a period from time t ₀ when the power is turned on to time t ₂ when the output voltage V _L of the lamp voltage detection circuit 21 becomes equal to or higher than the reference voltage V _B. Here, the incandescent lamp Lb is lit with a constant luminous flux.

By the way, as a discharge lamp lighting device, FIG.
As shown in FIG. 0, there is known an electronic circuit that controls the power supplied to the discharge lamp La. The main circuit of this discharge lamp lighting device is a power supply circuit 1 which is a chopper type booster circuit.
a and a lighting circuit 1b which is a chopper type step-down circuit. That is, the power supply circuit 1a includes a rectifier Re ₁ that is a diode bridge that full-wave rectifies the commercial AC power supply AC, and a series circuit that includes a choke coil CH ₁ and a switching element Q _{1 that} is an FET between the output terminals of the rectifier Re _1. , A series circuit of a diode D ₁ and a capacitor C ₁ is connected in parallel to the switching element Q ₁ , and a series circuit of resistors R ₁ and R ₂ is further connected in parallel to the capacitor C ₁ . Therefore, the energy accumulated in the choke coil CH ₁ during the ON period of the switching element Q ₁ is supplied to the output side through the diode D ₁ in the OFF period of the switching element Q _1. That is, if the duty ratio of the ON period of the switching element Q ₁ is adjusted, the energy stored in the choke coil CH ₁ can be changed to adjust the output voltage. The switching element Q ₁ is on / off controlled by the power supply control circuit 3a at a frequency of several tens of kHz, and the power supply control circuit 3a detects the potential at the connection point of the resistors R ₁ and R ₂ to detect the voltage across the capacitor C ₁ . Is adjusted to a substantially constant voltage, the duty ratio of the ON period of the switching element Q ₁ is adjusted.

On the other hand, in the lighting circuit 1b, a switching element Q ₂ formed of an FET and a choke coil CH ₂ forming a smoothing circuit are provided between both ends of the capacitor C ₁ of the power supply circuit 1a.
And a capacitor C _2, a series circuit connected in parallel with the resistor R ₃ is for detection of the lamp current to be described later, connected in parallel a diode D ₂ in series circuit of a choke coil CH ₂ and capacitor C ₂ and a resistor R ₃ It has a configuration. In this circuit configuration, since the smoothing circuit constitutes a choke input type filter, the average value of the input voltage of the smoothing circuit becomes the voltage across the capacitor C ₂ , and the duty ratio of the switching element Q ₂ during the ON period is large. Can be adjusted to adjust the voltage across the capacitor C ₂ . The switching element Q ₂ is several tens of k depending on the lighting control circuit 3b.
It is on / off controlled at a frequency of Hz. Capacitor C ₂
The discharge lamp La is connected in parallel to, I child stranded for detecting the lighting control circuit lamp current in 3b as voltage across the resistor R _3, the duty of the ON period switching element Q ₂ as the lamp current is maintained substantially constant Adjust the ratio. The diode D ₂ is a flywheel diode and forms a path for releasing the energy accumulated in the choke coil CH ₂ when the switching element Q ₂ is turned on when the switching element Q ₂ is turned off.

Power supply control circuit 3a and lighting control circuit 3b
Is a pulse width control circuit that adjusts the duty ratio of the ON periods of the switching elements Q ₁ and Q ₂ , respectively. In the power supply control circuit 3a, by the output voltage is controlled in the direction to reduce the ON period of the switching element Q ₁ when raised, the output voltage conversely controlled so as to increase the on period of the switching element Q ₁ when lowered, Power supply circuit 1
The output voltage of a is maintained at a substantially constant voltage. Further, the lighting control circuit 3b, the lamp current of the discharge lamp La is detected as the voltage across the resistor R ₃ to increase the switching element Q ₂
The ON period of the switching element Q ₂ is controlled so as to decrease, and conversely, when the lamp current decreases, the ON period of the switching element Q ₂ is controlled so as to increase, whereby the fluctuation range of the lamp current is reduced.

[0008]

By the way, in the above-mentioned conventional configuration, as shown in FIG. 9B, since the incandescent lamp Lb is lit with a constant luminous flux, the discharge lamp La is lit before and after the lighting of the discharge lamp La. Of the discharge lamp La and the incandescent lamp Lb increase at the stage where the combined luminous fluxes of the discharge lamp La and the incandescent lamp Lb increase and the luminous flux gradually increases until the steady lighting state after the discharge lamp La is lit. The combined luminous flux of the output luminous fluxes gradually increases. That is, immediately before the discharge lamp La shifts to the steady lighting state, there is a problem in that the total luminous flux becomes unnecessarily large, which is unnatural and uneconomical in terms of power consumption. Further, since the incandescent lamp Lb is arranged close to the discharge lamp La in order to achieve the purpose of compensating for the shortage of the luminous flux, the incandescent lamp La is in a lighting state and the discharge lamp L is in a lighting state.
There is a problem that the life of the incandescent lamp Lb is shortened due to the thermal influence from a.

An object of the present invention is to solve the above-mentioned problems, and in addition to lighting the incandescent lamp in order to compensate the shortage of the luminous flux during the period when the discharge lamp is not in the steady lighting state, the discharge lamp and the incandescent lamp are combined. An object of the present invention is to provide a discharge lamp lighting device capable of keeping the total amount of light flux substantially constant and reducing the influence of heat emitted from the discharge lamp on an incandescent lamp.

[0010]

According to the present invention, there is provided a main circuit which is interposed between a power source and a discharge lamp to adjust the electric power supplied to the discharge lamp, and a main circuit which discharges electricity depending on the power supply state to the discharge lamp. A control circuit that generates a control signal to adjust the power supplied to the lamp, and an incandescent lamp that compensates the output luminous flux of the discharge lamp during the period after the main circuit is energized and the discharge lamp is not in the steady lighting state. A discharge lamp lighting device having a light compensating device for lighting is used as a common structure.

In order to achieve the above object, the invention according to claim 1 is directed to reduce the fluctuation range of the light flux of the output light flux of the incandescent lamp and the output light flux of the discharge lamp based on the control signal from the control circuit. In addition, a compensation control circuit for controlling the output light flux of the incandescent lamp is provided in the light compensation device. According to the invention of claim 2, the main circuit is provided with a lighting circuit having a current limiting element and a power supply circuit for supplying power to the lighting circuit, and when the discharge lamp is lit, the output voltage of the power supply circuit is lower than before the lighting. Compensation to turn off the incandescent lamp after a certain time has elapsed from the time when the control circuit controls the power supply circuit, power is supplied to the light compensation circuit from the power supply circuit, and the decrease in the output voltage of the power supply circuit due to lighting of the discharge lamp is detected The control circuit is provided in the optical compensation circuit.

According to a third aspect of the present invention, a lighting circuit having a current limiting element and a power supply circuit for supplying power to the lighting circuit are provided in the main circuit, and when the discharge lamp is lit, the output voltage of the power supply circuit is lower than that before lighting. The power supply circuit is controlled by the control circuit so that the output voltage of the power supply circuit is further lowered when it is in the steady lighting state after lighting, compared to before the steady lighting state.
The light compensation circuit is provided with power from the power supply circuit, and the light compensation circuit is provided with a compensation control circuit that turns off the incandescent lamp when it detects a decrease in the output voltage of the power supply circuit when the discharge lamp is in the steady lighting state. is there.

[0013]

According to the structure of claim 1, the output light flux of the discharge lamp and the output light flux of the incandescent lamp are combined by utilizing the fact that the control signal generated from the control circuit is interlocked with the output light flux of the discharge lamp. Since the output light flux of the incandescent lamp is controlled based on the control signal so as to reduce the fluctuation range of the light flux, the output light flux of the incandescent lamp changes corresponding to the change of the output light flux of the discharge lamp. That is, since the output luminous flux of the incandescent lamp continuously decreases as the output luminous flux of the discharge lamp increases, it is possible to prevent the luminous flux from unnecessarily increasing at the time of starting the discharge lamp. The power consumption combined with the device can be reduced as compared with the conventional one. In addition, compared to the conventional configuration, the power supplied to the incandescent lamp is reduced, and as the amount of heat released from the discharge lamp is increased, the amount of heat released from the incandescent lamp is decreased and the heating amount of the incandescent lamp is reduced. The life of the incandescent lamp is extended because it is reduced.

According to the second aspect of the present invention, the output voltage of the power supply circuit provided in the main circuit is controlled so as to be lower when the discharge lamp is lit than before lighting, and the power supply circuit feeds power to the optical compensation circuit. At the same time, the drop of the output voltage of the power supply circuit due to lighting of the discharge lamp is detected and the incandescent lamp is turned off after a certain period of time.Therefore, there is a line for inputting the lighting state of the discharge lamp to the optical compensation device and the power supply to the optical compensation device. It will be shared and the number of connections will be reduced. In addition, since the light compensator is powered by the power supply circuit whose output voltage decreases as the discharge lamp lights up, the output light flux of the incandescent lamp decreases when the discharge lamp lights up. It is possible to reduce the fluctuation range of the light flux including the output light flux of (1) as compared with the related art.

According to the third aspect of the invention, the output voltage of the power supply circuit provided in the main circuit is lower than that before lighting when the discharge lamp is lit, and when the discharge lamp is in the steady lighting state, it is before the steady lighting state. The power supply circuit supplies power to the optical compensation circuit, and the optical compensation circuit detects a decrease in the output voltage of the power supply circuit when the discharge lamp is in the steady lighting state. Since the incandescent lamp is turned off by doing so, the power supply to the light compensating device and the line for inputting the lighting state of the discharge lamp to the light compensating device are shared as in the case of the structure of claim 2, and the number of connections is reduced. Will decrease. Further, since the power supply circuit whose output voltage decreases with lighting of the discharge lamp supplies power to the optical compensation device, the output luminous flux of the incandescent lamp gradually decreases at the time when the discharge lamp is lit and when the steady lighting state is reached. As a result, the fluctuation range of the combined luminous flux of the discharge lamp and the luminous flux of the incandescent lamp can be reduced as compared with the conventional case. Moreover, since the light compensation device detects that the steady lighting state has been reached by the decrease in the output voltage of the power supply circuit, the lighting state of the discharge lamp changes from the lighting state to the steady lighting state due to variations in the operating characteristics of the discharge lamp and changes in the surrounding environment. Even if there is a difference in time until, the incandescent lamp can be turned off at an appropriate time.

[0016]

【Example】

(Embodiment 1) In this embodiment, as shown in FIG.
The main circuit has the same configuration as the conventional configuration shown in FIG. That is, the main circuit is composed of a power supply circuit 1a which is a step-up type chopper circuit and a lighting circuit 1b which is a step-down type chopper circuit. Further, as a control circuit that detects the lighting state of the discharge lamp La and generates a control signal that controls the power supplied to the discharge lamp La by the main circuit, it controls the power supply control circuit 3a that controls the power supply circuit 1a and the lighting circuit 1b. Lighting control circuit 3b.

The power supply control circuit 3a and the lighting control circuit 3b are general-purpose integrated circuit ICs for switching regulators.
₁ , IC ₂ (for example, IR3M02 manufactured by Sharp)
It is configured using. This integrated circuit IC ₁ , IC ₂
Represents a triangular wave with a time constant determined by capacitors C ₄ and C ₅ and resistors R ₄ and R ₅ connected to terminals 5 and 6, respectively, and the input voltage of terminal 1 and the potential of the triangular wave. By comparing with, the pulse signal that is turned off when the potential of the triangular wave is higher than the input voltage and turned on when the potential of the triangular wave is lower than the input voltage is output from the 11th terminal. Therefore, the higher the input voltage to the 1st terminal, the longer the ON period of the output signal from the 11th terminal.

In the power supply control circuit 3a, the input voltage to the 1st terminal of the integrated circuit IC ₁ is the voltage at the connection point of the resistors R ₁ and R ₂ and is proportional to the output voltage of the power supply circuit 1a, and the 11th terminal The output is inverted by the drive circuit having the transistors Q ₄ and Q ₅ which form a complementary pair, and controls the switching element Q ₁ . If the voltage across the capacitor C ₁ rises, the on-duty of the output signal from the 11th terminal of the integrated circuit IC ₁ increases, and the on-duty of the drive circuit turns on.
Since the OFF state is inverted, the ON period of the switching element Q ₁ is shortened, the stored energy of the choke coil CH ₁ is reduced, and the voltage across the capacitor C ₁ is controlled to be reduced. On the contrary, if the voltage across the capacitor C ₁ decreases, the ON period of the switching element Q ₁ increases, and as a result, the voltage across the capacitor C ₁ is controlled to increase. That is, the voltage across the capacitor C ₁ is maintained at a substantially constant voltage.

In the lighting control circuit 3b, the input voltage to the first terminal of the integrated circuit IC _{2 is} the terminal voltage of the resistor R ₃ and is proportional to the lamp current of the discharge lamp La, and the output of the 11th terminal is a complementary repair. Constituting transistors Q ₆ and Q ₇
And is inverted by the drive circuit including the pulse transformer PT ₁ to control the switching element Q ₂ . Here, the terminals a and b of the lighting control circuit 3b and the terminals a and b of the lighting circuit 1a are connected to each other. If the lamp current increases, the on-duty of the output signal from the 11th pin increases, and the on / off state is reversed in the drive circuit.
The ON period of the switching element Q ₂ is shortened, the voltage across the capacitor C ₂ is reduced, and the lamp current of the discharge lamp La is controlled to decrease. On the contrary, if the lamp current decreases, the ON period of the switching element Q ₂ becomes longer, and the lamp current is controlled to increase. That is, the fluctuation range of the lamp current is controlled to be small.

By the way, the output signal of the 11th terminal of the integrated circuit IC ₁ provided in the power supply control circuit 3a (that is, the signal whose on / off state is inverted from the control signal for controlling the switching element Q ₁ ) is transmitted together with the incandescent lamp Lb. It is also input to the light compensation circuit 2 which constitutes the light compensation device. The light compensation circuit 2 includes a lighting circuit 2a and a compensation control circuit 2b. Lighting circuit 2a
Is a choke by connecting a series circuit of a switching element Q ₃ that is an FET, a choke coil CH ₃ and a capacitor C ₃ that form a smoothing circuit in parallel between the output terminals of the power supply circuit 1a, as in the lighting circuit 1b. A diode D ₃ as a flywheel diode is connected in parallel to a series circuit of a coil CH ₃ and a capacitor C _3, and an incandescent lamp Lb is connected between both ends of the capacitor C ₃ . Therefore, the output luminous flux of the incandescent lamp Lb can be adjusted by controlling the on-duty of the switching element Q ₃ . Moreover, since the output of the power supply circuit 1a is used as the power supply source of the incandescent lamp Lb, the discharge lamp La and the incandescent lamp Lb share the power supply circuit 1a. Here, the optical compensation circuit 2
The terminals A and B are connected to the terminals A and B of the power supply circuit 1a.

On the other hand, the compensation control circuit 2b includes a charging resistor R ₆
There a delay circuit comprising a capacitor C ₆ of the discharge resistor R ₇ is connected in series are connected in parallel, the transistor Q _8, Q ₉ constituting the complementary pair, the pulse transformer PT
₂ and. Integrated circuit I constituting the power supply control circuit 3a
The output signal from the 11th terminal of C ₁ is delayed by the delay circuit and then controls the switching element Q ₃ via the complementary repair and the pulse transformer PT ₂ . Here, the complementary pair is connected so as not to invert the output signal of the delay circuit. If the voltage across the capacitor C ₁ of the power supply circuit 1a rises, the power supply control circuit 3a
Since the on-duty of the output signal from the integrated circuit IC ₁ increases, the on-duty of the output signal of the compensation control circuit 2b also increases, and the voltage across the capacitor C ₃ is controlled to increase. That is, the output light flux of the incandescent lamp Lb increases.

The operation of the optical compensation circuit 2 will be described in more detail with reference to FIG. After the power is turned on, when the discharge lamp La is not lit or the discharge lamp La is not connected (no load), the lamp circuit 1b consumes less power because no lamp current flows. The ON period of the switching element Q ₁ is kept short. That is, the output signal of the 11 th terminal of the integrated circuit IC ₁ using the power supply control circuit 3a, the on-duty is increased at no load, as shown in FIG. 2 (a), the switching element Q ₁
The ON period of is shortened as shown in FIG. Therefore, as shown in FIG. 2C, the ON period of the switching element Q ₃ of the optical compensation circuit 2 becomes long. That is, although the output light flux of the discharge lamp La is 0 as shown in FIG.
The output light flux of the incandescent lamp Lb becomes large as shown in FIG. During the starting process in which the discharge lamp La lights up and the luminous flux gradually increases, the power consumption in the discharge lamp La gradually increases,
Since the voltage across the capacitor C ₁ of the power supply circuit 1a tends to decrease and the power supply control circuit 3a controls the voltage across the capacitor C ₁ to increase, the voltage of the integrated circuit IC ₁ 11
The on-duty of the output signal of the No. terminal gradually decreases as shown in FIG. 2A, and the ON period of the switching element Q ₃ gradually increases as shown in FIG. 2B. That is, the ON period of the switching element Q ₃ of the optical compensation circuit 2 is as shown in FIG.
Will be gradually reduced. As a result, in the starting process, the output luminous flux of the discharge lamp La gradually increases as shown in FIG. 2D, and the output luminous flux of the incandescent lamp Lb increases as shown in FIG.
As described above, the light flux is gradually reduced as described above, and is controlled so as to reduce the change in the light flux of the combined output light flux of the discharge lamp La and the incandescent lamp Lb. After that, when the discharge lamp La is in a steady lighting state, the ON period of the switching element Q ₁ becomes longer as shown in FIG. 2B, and the output signal from the 11th terminal of the integrated circuit IC ₁ of the power supply control circuit 3a becomes The on-duty becomes small as shown in FIG. put it here,
The time constant of the delay circuit in the optical compensation circuit 2 is set so that the charge charged in the capacitor C ₆ does not turn on the transistor Q ₈ when the on-duty of the output signal from the terminal 11 is minimum. As a result, the transistor Q ₃ is kept off as shown in FIG. That is, as shown in FIG. 2E, the incandescent lamp Lb is turned off.

As described above, the output luminous flux of the incandescent lamp Lb is large when the discharge lamp La is not lit, and the incandescent lamp Lb is large when the output luminous flux of the discharge lamp La gradually increases.
Is controlled so that the change of the combined output light flux of the discharge lamp La and the incandescent lamp Lb becomes small. When the discharge lamp La is in a steady lighting state, the incandescent lamp Lb is turned off. In this way, the output light flux of the discharge lamp La can be estimated based on the power supply state to the discharge lamp La, and the output light flux of the incandescent lamp Lb is combined based on the estimated output light flux of the discharge lamp La. The electric power supplied to the incandescent lamp Lb is controlled so that the change becomes small, and therefore the changing directions of the output luminous fluxes of the discharge lamp La and the incandescent lamp Lb are controlled in opposite directions. As a result, it is not necessary to make the output light flux of the incandescent lamp Lb larger than necessary at the time of starting the discharge lamp La, and it is possible to suppress the power consumption as a whole. Further, since the radiant heat of the incandescent lamp Lb is controlled to decrease as the radiant heat from the discharge lamp La increases,
The influence of the radiant heat of the discharge lamp La on the life of the incandescent lamp Lb is reduced, and the life of the incandescent lamp Lb is extended.

(Embodiment 2) In this embodiment, as shown in FIG. 3, as a power supply to the optical compensation circuit 2, a rectifier Re ₂ consisting of a diode bridge for full-wave rectifying a commercial AC power supply AC.
The rectified output of is used. That is, in the first embodiment, the power supply circuit 1a is shared by the discharge lamp La and the incandescent lamp Lb, but in the present embodiment, power is supplied to the incandescent lamp Lb without passing through the power supply circuit 1a. Of.

As an input signal to the light compensating circuit 2, an output signal from the 11th terminal of the integrated circuit IC ₂ of the lighting control circuit 3b whose on-duty increases with an increase in lamp current is output by the inverting circuit NOT. Inverted and used. According to this configuration, the discharge lamp L uses the fact that the lamp current increases when the output luminous flux of the discharge lamp La increases.
The output light flux of a can be estimated.

That is, since the lamp current does not flow when the discharge lamp La is not lit and the lamp current does not flow, the voltage across the resistor R ₃ is substantially 0, and the output signal from the 11th terminal of the integrated circuit IC ₂ is turned on. The duty becomes smaller. Since the switching element Q ₃ of the light compensation circuit 2 is controlled by using a signal obtained by inverting this signal by the inverting circuit NOT, the ON period of the switching element Q ₃ becomes long and the output light flux of the incandescent lamp Lb becomes large when there is no load. In the starting process in which the output luminous flux of the discharge lamp La gradually increases, the voltage across the resistor R ₃ increases as the lamp current increases, and the on-duty of the output signal from the 11th terminal of the integrated circuit IC ₂ gradually increases. Since it becomes larger, the ON period of the switching element Q ₃ of the light compensation circuit 2 gradually becomes shorter, and the output luminous flux of the incandescent lamp Lb gradually decreases. In this way, when the discharge lamp La is in the steady lighting state, the on-duty of the output signal of the inverting circuit NOT becomes small, and the capacitor C ₆ is no longer charged enough to turn on the transistor Q _8. As a result, the switching element Q ₃ Is turned off and the incandescent lamp Lb is turned off. In short, it operates similarly to the first embodiment. Other configurations are similar to those of the first embodiment.

(Embodiment 3) By the way, in the case of the constitutions of the above-mentioned respective embodiments, a pair of electric wires for supplying power to the incandescent lamp Lb and a discharge lamp La are connected to the optical compensation circuit 2 as electric wires.
It is necessary to have at least a pair of electric wires to which a signal corresponding to the lighting state of is input, and at least four wires are necessary as electric wires. Further, since a signal including a high frequency component output from the power supply control circuit 3a or the lighting control circuit 3b passes through the electric wire for detecting the lighting state of the discharge lamp La, depending on the way the electric wire is routed to the outside. Radiation noise increases and the internal circuit malfunctions. If the light compensation circuit 2 is configured to include a timer circuit that turns off the incandescent lamp La after a certain time has passed after the power is turned on, the electric wire for detecting the lighting state of the discharge lamp La is not necessary, and the above problem is solved. However, when the timer circuit is provided, the incandescent lamp Lb is extinguished after a certain period of time even if the discharge lamp La is no longer lit due to the life of the discharge lamp La. Will not be achieved.

This embodiment solves this problem. That is, as shown in FIG. 4, the control circuit for controlling the main circuit is provided with a lighting determination circuit 3c for detecting the lamp current and determining whether the discharge lamp La is lit, and the output voltage of the power supply circuit 1a is set to the discharge lamp. When La is lit, it is forcibly lowered compared to before lighting. The light compensating circuit 2 has a power supply circuit 1a as in the first embodiment.
The output light flux of the incandescent lamp Lb is controlled according to the output light flux of the discharge lamp La by detecting the decrease in the output voltage of the power supply circuit 1a.

The lighting determination circuit 3c compares the voltage across the resistor R ₃ for detecting the lamp current of the discharge lamp La with the comparator CP.
Type ₁ is compared with the reference voltage E _1. Comparator C
When the voltage across the resistor R ₃ is equal to or lower than the reference voltage E ₁ , P ₁ sets the output to the H level and turns on the transistor Q ₁₀ . The emitter of the transistor Q ₁₀ - the collector resistor R ₈ are connected in series, the series circuit is connected in parallel with resistor R ₂ which is provided to detect the output voltage of the power supply circuit 1a. Therefore, when transistor Q ₁₀ turns on,
By connecting the resistor R ₂ and the resistor R ₈ in parallel,
The potential of the 1st terminal of the integrated circuit IC ₁ is forcibly pulled down, the on-duty of the output signal of the 11th terminal of the integrated circuit IC ₁ decreases, and as a result, the on-duty of the transistor Q ₁ increases. That is, if the voltage across the resistor R ₃ is less than or equal to the predetermined value, it is considered that the discharge lamp La is not lit, and at this time, the output voltage of the power supply circuit 1a is forcibly raised. The discharge lamp when La is current flows through the resistor R ₃ lit off the transistors Q _10, returning the output voltage of the power supply circuit 1a to normal disconnect the resistor R _8. That is, by providing the lighting determination circuit 3c, the output voltage of the power supply circuit 1a becomes higher before lighting the discharge lamp La than before lighting.

On the other hand, the optical compensation control circuit of the compensating circuit 2, the oscillation control circuit 2c for on-off controlling the switching element Q ₃ of the lighting circuit 2a, the lighting state of the discharge lamp La on the basis of the output voltage of the power supply circuit 1a Oscillation control circuit 2c
And a determination control circuit 2d for controlling the operation of. The light compensation circuit 2 shares the lighting circuit 1b and the power supply circuit 1a as a power supply source. That is, the output of the power supply circuit 1a is shared by the power supply for the incandescent lamp Lb and the signal for detecting the lighting state of the discharge lamp La. Therefore,
There are only two connecting lines from the light compensating circuit 2 to the outside, and moreover, signals containing high-frequency components from the power supply control circuit 3a and the lighting control circuit 3b are not superimposed on the connecting line.
There is almost no influence of radiation noise or the like.

A more specific description will be given. Judgment control circuit 2
d is started by utilizing the fact that the output voltage of the power supply circuit 1a decreases with the lighting of the discharge lamp La. Therefore, the timer unit T provided in the determination control circuit 2d uses the output voltage of the power supply circuit 1a. The timed operation is started when the potential at the connection point of the pair of resistors R ₁₁ and R ₁₂ that divides the voltage is reduced to a predetermined voltage, and the output is set to H level during the timed operation. Also, the resistance R ₁₁ ,
The potential at the connection point of R ₁₂ is also input to the comparator CP ₂ . The reference voltage E ₂ of the comparator CP ₂ is the discharge lamp La.
Is not lit, the output of comparator CP ₂ is H
When the level reaches the level and the discharge lamp La lights up, the comparator C
The output of P ₂ is set to L level. The outputs of the timer unit T and the comparator CP ₂ are NOR circuits NOR
Entered in. Therefore, if the discharge lamp La is still lit after the elapse of the fixed time set in the timer unit T after the discharge lamp La is lit, the output of the NOR circuit NOR becomes L level, and in other states, The output of the circuit NOR becomes H level. The output terminal of the NOR circuit NOR is connected to the base of the transistor Q ₁₂ , and when the output of the NOR circuit NOR is at H level, the transistor Q ₁₂ is turned on. A resistor R ₁₆ is connected in series with the emitter-collector of the transistor Q ₁₂ .

The oscillation control circuit 2c is formed by using a general-purpose integrated circuit IC ₄ for switching regulator (for example, IR3M02 manufactured by Sharp Corp.) like the power supply control circuit 3a and the lighting control circuit 3b. The first terminal of the integrated circuit IC ₄ is connected to the connection point of the voltage dividing resistors R ₁₄ and R ₁₅ connected between both ends of the DC power supply. Judgment control circuit 2d
The emitter of the transistor Q ₁₂ which is provided on - the series circuit of the collector and the resistance R ₁₆ is connected in parallel with resistor R ₁₄ of the positive electrode side of the resistor R _14, R ₁₅ voltage dividing. Therefore, during the period when the transistor Q ₁₂ is off, the integrated circuit IC ₄ has 5
A pulse signal having a constant cycle and a constant on-duty determined by a capacitor C ₁₃ and a resistor R ₁₃ respectively connected to the terminal No. 6 and the terminal No. 6 is output from the terminal No. 11. When the transistor Q ₁₂ is turned on, the resistance R ₁₄
By connecting the resistor R ₁₆ and the resistor R ₁₆ in parallel, the input voltage to the first terminal of the integrated circuit IC ₄ becomes high and the generation of the pulse signal from the 11th terminal is stopped. The output signal of the 11th terminal of the integrated circuit IC ₄ is supplied to the transistors Q ₁₃ and Q ₁₄ and the pulse transformer PT which form a complementary pair.
_{After the} on / off state is inverted through the drive circuit composed of ₃ , the switching element Q ₃ is controlled. Here, the terminal c, d of the oscillation control circuit 2c, the terminal c of the switching element Q _3, and is connected to the d.

According to the above construction, the incandescent lamp L is provided if the discharge lamp La is turned on after a certain time has passed since the discharge lamp La was turned on.
b is turned off, but before the discharge lamp La is turned on,
The incandescent lamp La is turned on for a certain period of time after a is turned on, or when the discharge lamp La is not turned on due to a life or the like. That is, the operation is as shown in FIG. 5, and before the discharge lamp La is turned on at time t ₁ , the output voltage of the power supply circuit 1a is changed by the operation of the lighting determination circuit 3c as shown in FIG. 5A. Since it is high, the output of the comparator CP ₂ becomes H level as shown in FIG. At this time, since the timer unit T is not performing the timed operation, the output of the timer unit T is at the L level as shown in FIG. 5 (c). That is, the output of the NOR circuit NOR is at the L level as shown in FIG. 5D, the oscillation control circuit 2c controls the switching element Q ₃ with a constant cycle and a constant on-duty, and as shown in FIG. , Turn on the incandescent lamp Lb.

When the discharge lamp La is turned on at time t ₁ , the output voltage of the power supply circuit 1a is lowered as shown in FIG. 5 (a), so that the comparator CP as shown in FIG. 5 (b).
The output of ₂ becomes L level, and at the same time, the output of the timer section T becomes H level for a certain time t _ON (FIG. 5 (c)). That is, the output of the NOR circuit NOR is still maintained at the L level as shown in FIG. Here, since the output voltage of the power supply circuit 1a is reduced by lighting the discharge lamp La, the power supplied to the light compensation circuit 2 also decreases, and the voltage across the incandescent lamp Lb also decreases as shown in FIG. 5 (e). The output luminous flux of the incandescent lamp Lb decreases. That is, when the discharge lamp La lights up and the output light flux is obtained from the discharge lamp La, the output light flux of the incandescent lamp Lb is reduced, and the total amount of the output light flux is prevented from increasing to an unnecessary degree. is there. Further, when the time to the extent that the discharge lamp La shifts to the steady lighting state has elapsed, both the outputs of the comparator CP ₂ and the timer unit T become L level, and as shown in FIG. 5D, the NOR circuit NOR
Output goes high and the incandescent lamp Lb goes out. Further, if the discharge lamp La stops lighting for some reason, the output voltage of the power supply circuit 1a rises.
The output of P ₂ becomes H level, and the incandescent lamp Lb lights up.

According to the above configuration, the power supply to the incandescent lamp Lb and the detection of the lighting state of the discharge lamp La are performed by the output of the power supply circuit 1a which changes with the change of the lighting state of the discharge lamp La. The light compensation circuit 2 can be connected to the discharge lamp lighting device 1 by two wires, and the wiring becomes easy. In addition, the output of the power supply circuit 1 a
Since the connection is made so as to be input to the power supply circuit, almost no high frequency component is superposed on the electric wire connecting the power supply circuit 1a and the optical compensation circuit 2, and it is possible to prevent the influence of radiation noise on the outside and the malfunction of the internal circuit. Become. Moreover, since the output luminous flux of the incandescent lamp Lb decreases after the discharge lamp La is turned on, the life of the incandescent lamp Lb is improved and the increase in power consumption can be suppressed. Other configurations and operations are similar to those of the first embodiment.

(Embodiment 4) In this embodiment, the optical compensation circuit 2 is used.
Is configured as shown in FIG. 6A, and the lighting determination circuit 3c is configured as shown in FIG.
The configuration is as shown in (b), and the other configurations are similar to those of the third embodiment. The lighting determination circuit 3c is used in the third embodiment.
In addition to the above structure, a comparator CP ₃ , a transistor Q ₁₁ , and a resistor R ₉ are added. Here, the terminals C and D in FIG. 6A are replaced with the lighting determination circuit 3c in FIG. 4 and connected to the portions C and D. The comparator CP ₃ is a resistor R that detects the lamp current of the discharge lamp La.
_When the voltage between both ends of _{3 is} equal to or lower than the reference voltage E ₃ , the transistor Q ₁₁ is turned on. The emitter of the transistor Q ₁₁ - resistor in the collector R ₉ are connected in series, the series circuit is connected in parallel to the resistor R ₂ of the power supply circuit 1a. here,
The reference voltage E ₃ is set so that the transistor Q ₁₁ is turned off with respect to the voltage across the resistor R ₃ when the discharge lamp La is in the steady lighting state. Therefore, the lighting determination circuit 3
c is the state in which the discharge lamp La is not lit, and the discharge lamp La
It is possible to discriminate the three states of the starting process in which the output luminous flux is gradually increasing and the steady lighting state of the discharge lamp La based on the voltage across the resistor R ₃ corresponding to the lamp current. That is, since the transistors Q ₁₀ and Q ₁₁ are both turned on before the discharge lamp La is turned on, the resistors R ₈ and R ₉ are turned on.
Is connected in parallel to the resistor R ₂ and the discharge lamp La is lit up to reach a steady lighting state. In the starting process, the transistor Q ₁₀ is turned off and the transistor Q ₁₁ is turned on, so only the resistor R ₉ is connected in parallel with the resistor R ₂ . Will be connected. Further, if the discharge lamp La is in a steady lighting state, the transistor Q ₁₀ ,
Since both Q ₁₁ are turned off, the resistors R ₈ and R ₉ are
It is separated from ₂ . As a result, the output voltage of the power supply circuit 1a gradually decreases in the three states of the discharge lamp La before lighting, the starting process, and the steady lighting state.

On the other hand, the judgment control circuit 2d in the optical compensation circuit 2 has a structure in which the timer section T and the NOR circuit NOR are omitted. That includes a resistance R _11, R ₁₂ for dividing the output voltage of the power supply circuits 1a, the resistors R _11, the reference voltage E ₄ the potential at the connection point of R ₁₂ by the comparator CP ₄
Compare with. The comparator CP ₄ outputs H when the potential at the connection point of the resistors R ₁₁ and R ₁₂ is higher than the reference voltage E _4.
Set to level and turn on transistor Q ₁₂ . A resistor R ₁₆ is connected in series to the emitter-collector of the transistor Q ₁₂ as in the third embodiment, and this series circuit is connected to the first terminal of the integrated circuit IC ₄ constituting the oscillation control circuit 2c as in the third embodiment. Control the input voltage of. That is, when the transistor Q ₁₂ is turned on, the input voltage of the first terminal of the integrated circuit IC ₄ rises and the generation of the pulse signal from the 11th terminal is stopped.

According to the above construction, at the time t ₁ , the discharge lamp La
Before is turned on, as shown in FIG.
Since the output voltage of a is forcibly raised,
As shown in (b), the output of the comparator CP ₄ is at L level, and the voltage across the incandescent lamp Lb is high as shown in FIG. 7 (c). That is, the output light flux of the incandescent lamp Lb at this time becomes large. When the discharge lamp La is turned on at time t ₁ , the output voltage of the power supply circuit 1a is forcibly lowered as shown in FIG. 7A, and the voltage across the incandescent lamp Lb also falls as shown in FIG. 7C. It will be. That is, the output light flux of the incandescent lamp Lb decreases. At this time, the output of the comparator CP ₄ is maintained at the L level as shown in FIG. 7 (b). Further, when the discharge lamp La enters the steady lighting state at the time t ₂ , the output of the power supply circuit 1a further decreases as shown in FIG. 7 (a). In this state, the output of the comparator CP ₄ becomes H level as shown in FIG. 7B, the determination control circuit 2d turns on the switching element Q ₁₂ , and turns off the incandescent lamp Lb as shown in FIG. 7C.

In the configuration of this embodiment, since the transition of the discharge lamp La to the stable lighting state is detected on the basis of the voltage across the resistor R ₃ , the discharge lamp La is kept constant from lighting as in the third embodiment. The stable lighting state can be detected more accurately, and the extinction timing of the incandescent lamp Lb can be set accurately according to the lighting state of the discharge lamp La, as compared with the case where it is considered that the stable lighting state has been transitioned after a certain time. it can. That is,
The time from the lighting of the discharge lamp La to the transition to the steady lighting state varies depending on various conditions, but the extinguishing timing of the incandescent lamp Lb can be set regardless of such time variation. Of. The other configurations and operations are the same as those in the third embodiment, and thus the description thereof is omitted.

In each of the above embodiments, the power supply circuit 1a, which is a chopper circuit, and the lighting circuit 1b are used, but a lighting circuit or a rising lighting circuit may be used instead of the power supply circuit 1a. Instead of the lighting circuit 1b, a high-frequency lighting circuit or a rectangular-wave lighting circuit may be used to obtain a high-frequency output or a rectangular-wave output from a DC power source.

[0041]

According to the first aspect of the present invention, the output light flux of the discharge lamp and the output light flux of the incandescent lamp are combined by utilizing the fact that the control signal generated from the control circuit is interlocked with the output light flux of the discharge lamp. Since the output light flux of the incandescent lamp is controlled based on the control signal so as to reduce the fluctuation range of the light flux, the output light flux of the incandescent lamp changes corresponding to the change of the output light flux of the discharge lamp. That is, since the output luminous flux of the incandescent lamp continuously decreases as the output luminous flux of the discharge lamp increases, it is possible to prevent the luminous flux from unnecessarily increasing at the time of starting the discharge lamp. It is possible to reduce the power consumption of the device and the power consumption of the device. In addition, compared to the conventional configuration, the power supplied to the incandescent lamp is reduced, and moreover,
As the amount of heat released from the discharge lamp increases, the amount of heat released from the incandescent lamp decreases, and the heating amount of the incandescent lamp is reduced as compared with the conventional case. Therefore, there is an advantage that the life of the incandescent lamp is extended.

According to a second aspect of the present invention, the output voltage of the power supply circuit provided in the main circuit is controlled so as to be lower when the discharge lamp is lit than before the lighting, and the power supply circuit supplies power to the optical compensation circuit. Since the incandescent lamp is turned off after a certain period of time when the drop in the output voltage of the power supply circuit due to lighting of the discharge lamp is detected, the power supply to the optical compensation device and the line for inputting the lighting state of the discharge lamp to the optical compensation device are shared. This has the effect of reducing the number of connections. In addition, since the light compensator is powered by the power supply circuit whose output voltage decreases as the discharge lamp lights up, the output light flux of the incandescent lamp decreases when the discharge lamp lights up. There is an advantage that the fluctuation range of the light flux including the output light flux of 1 can be reduced as compared with the related art.

According to the third aspect of the present invention, the output voltage of the power supply circuit provided in the main circuit becomes lower than before the lighting when the discharge lamp is lit, and when the discharge lamp is in the steady lighting state, it is further than before the steady lighting state. Since it is controlled so as to decrease, the power supply circuit supplies power to the optical compensation circuit, and
Since the light compensation circuit detects a decrease in the output voltage of the power supply circuit when the discharge lamp is in a steady lighting state and turns off the incandescent lamp, the power supply to the light compensation device and the light are performed similarly to the configuration of claim 2. Since the line for inputting the lighting state of the discharge lamp is shared with the compensator, the number of connections can be reduced. Further, since the power supply circuit whose output voltage decreases with lighting of the discharge lamp supplies power to the optical compensation device, the output luminous flux of the incandescent lamp gradually decreases at the time when the discharge lamp is lit and when the steady lighting state is reached. Therefore, there is an advantage that the fluctuation range of the light flux of the output light flux of the discharge lamp and the output light flux of the incandescent lamp can be reduced as compared with the conventional case. Moreover, since the light compensation device detects that the steady lighting state has been reached by the decrease in the output voltage of the power supply circuit, the lighting state of the discharge lamp changes from the lighting state to the steady lighting state due to variations in the operating characteristics of the discharge lamp and changes in the surrounding environment. Even if there is a difference in time until, the incandescent lamp can be turned off at an appropriate time.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a first embodiment.

FIG. 2 is an operation explanatory diagram of the first embodiment.

FIG. 3 is a circuit diagram showing a second embodiment.

FIG. 4 is a circuit diagram showing a third embodiment.

FIG. 5 is an operation explanatory diagram of the third embodiment.

6A and 6B show a fourth embodiment, FIG. 6A is a circuit diagram of a lighting determination circuit, and FIG. 6B is a circuit diagram of a light compensation circuit.

FIG. 7 is an operation explanatory diagram of the fourth embodiment.

FIG. 8 is a circuit diagram showing a conventional example.

FIG. 9 is an operation explanatory diagram of a conventional example.

FIG. 10 is a circuit diagram showing another conventional example.

[Explanation of symbols]

 1a Power supply circuit 1b Lighting circuit 2 Light compensation circuit 2a Lighting circuit 2b Compensation control circuit 2c Oscillation control circuit 2d Judgment control circuit 3a Power supply control circuit 3b Lighting control circuit 3c Lighting judgment circuit AC Commercial AC power supply La Discharge lamp Lb Incandescent lamp

Claims (3)

[Claims] 1. A main circuit interposed between a power source and a discharge lamp to adjust the power supplied to the discharge lamp, and the power supplied to the discharge lamp by the main circuit according to the power supply state to the discharge lamp. As described above, a control circuit that generates a control signal and a light compensation device that lights the incandescent lamp so as to compensate the output luminous flux of the discharge lamp during a period after the main circuit is energized and the discharge lamp is not in the steady lighting state are provided. In the discharge lamp lighting device provided with, a compensation control circuit for controlling the output light flux of the incandescent lamp in a direction of reducing the fluctuation range of the light flux of the output light flux of the incandescent lamp and the output light flux of the discharge lamp based on the control signal. A discharge lamp lighting device, which is provided in a light compensation device. 2. A main circuit interposed between a power supply and a discharge lamp to adjust the power supplied to the discharge lamp, and the power supplied to the discharge lamp by the main circuit according to the power supply state to the discharge lamp. As described above, a control circuit that generates a control signal and a light compensation device that lights the incandescent lamp so as to compensate the output luminous flux of the discharge lamp during a period after the main circuit is energized and the discharge lamp is not in the steady lighting state are provided. In the provided discharge lamp lighting device, a lighting circuit having a current limiting element and a power supply circuit for supplying power to the lighting circuit are provided in the main circuit so that when the discharge lamp is lit, the output voltage of the power supply circuit is lower than that before lighting. The control circuit controls the power supply circuit, power is supplied to the light compensation circuit from the power supply circuit, and the incandescent lamp is turned off after a certain time has elapsed from the time when the decrease in the output voltage of the power supply circuit due to lighting of the discharge lamp was detected. Compensation control circuit provided in optical compensation circuit A discharge lamp lighting device characterized by comprising: 3. A main circuit interposed between a power supply and a discharge lamp to adjust the power supplied to the discharge lamp, and the power supplied to the discharge lamp by the main circuit according to the power supply state to the discharge lamp. As described above, a control circuit that generates a control signal and a light compensation device that lights the incandescent lamp so as to compensate the output luminous flux of the discharge lamp during a period after the main circuit is energized and the discharge lamp is not in the steady lighting state are provided. In the provided discharge lamp lighting device, a lighting circuit having a current limiting element and a power supply circuit for supplying power to the lighting circuit are provided in the main circuit, and when the discharge lamp is lit, the output voltage of the power supply circuit becomes lower than that before lighting. The control circuit controls the power supply circuit so that the output voltage of the power supply circuit will be lower than before the steady lighting state when the steady lighting state is reached after lighting. At the time of steady lighting In the discharge lamp lighting device, the light compensation circuit is provided with a compensation control circuit for turning off the incandescent lamp when a decrease in the output voltage of the power supply circuit is detected.