JP2754531B2 - Directly connected discharge lamp lighting device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a direct connection type discharge lamp lighting device for a plurality of discharge lamps using a series inverter or the like. 2. Description of the Related Art Conventionally, there is a direct-discharge lamp lighting device of this type which has a dimming function. Here, there is a conventional circuit configuration as shown in FIG. This is because, in addition to the two switching transistors Q ₁ and Q ₂ constituting the main part of the inverter 1, which are driven alternately by the drive circuit to perform the oscillating operation, four return diodes D _{1 to} D ₄ and In a circuit configuration using two DC cut capacitors C ₁ and C ₂ , a capacitor y and a yoke 4 (inductance L) as a current-limiting inductor are connected in series via the filaments 2 a and 2 b of the discharge lamp 2 to form an LC series. It is formed by forming a resonance circuit. As a result, a sine wave flows through the LC resonance circuit according to the switching transistors Q ₁ and Q ₂ that are turned on and off alternately, and after the discharge lamp 2 is turned on, the Q of the LC resonance circuit decreases and the LC resonance circuit is not in a resonance state. , A triangular wave is supplied. According to this circuit, when the discharge lamp 2 is replaced, the LC resonance loop is opened, so that the problem of electric shock does not occur. However, for example, during dimming, in order to reduce the lamp current of the lamp (discharge lamp), the impedance increases and the lamp voltage increases. In general, the frequency is increased during dimming. As a result, the reactance of the resonance capacitor C decreases and the lamp voltage increases, so that the filament current increases.
As a result, the filament voltage V- at the time of dimming becomes excessive as compared with the full lighting, and the lamp life becomes short. It is clear from the above description that this occurs not only at the time of dimming but also with a change in lamp voltage and a change in frequency. Therefore, in order to avoid such a fluctuation of the filament voltage V- at the time of dimming, an impedance element such as a capacitor is used for each filament 2a, 2b of the discharge lamp 2 for adjusting the filament voltage V-. What is necessary is just to connect in parallel. Problems to be Solved by the Invention However, in the case where the impedance element is provided as described above, since the direct connection type having no separate transformer is used, when one of the filament sides is removed at the time of lamp replacement, the discharge lamp is used. There is a danger of electric shock when current flows through the human body. Therefore, in the case where the impedance element is connected in parallel to the filament, the problem of V− can be solved, but it is necessary to take measures against electric shock when replacing the lamp. Means for solving the problem Connect an impedance element in parallel to each filament of each discharge lamp, connect a resonance capacitor between one end of each filament, and connect one filament of these discharge lamps in common. And the other filament is connected to the resonance capacitor via a resonable inductor and connected in parallel with each other to be energized by the output of the inverter. A bias circuit for flowing a DC bias current to the common side filament of the discharge lamp, a current detection circuit for detecting the DC bias current value is provided, and an inverter is provided when a value detected by the current detection circuit falls below a predetermined value. An oscillation stop circuit is provided to stop the oscillation operation. Operation First, since the filament of each discharge lamp is connected in parallel with a filament voltage adjusting impedance element, the fluctuation of the filament voltage is small even during dimming. Then, a DC bias current is supplied to the common side filament by a bias circuit, so that if the common side filament side of the discharge lamp is removed, this current will be reduced to a set value or less. Such a decrease in the bias current is detected by the current detection circuit. Then, the oscillation stop circuit is operated by the detection output of the current detection circuit to immediately stop the oscillation operation, thereby avoiding the risk of electric shock. On the other hand, when the non-common side filament side of the discharge lamp is removed, it is disconnected from the high potential side, so that the problem of electric shock does not occur. Embodiment An embodiment of the present invention will be described with reference to FIGS. First, an inverter oscillation circuit 9 including a drive circuit 8 is connected to the power supply circuit 7. The inverter oscillating circuit 9 mainly includes two switching transistors 10 and 11 connected in series, which are turned on and off alternately by the driving circuit 8 to perform an oscillating operation. Four reflux diodes D ₅ between 11
And to D _8, 2 two capacitors C ₃ for DC Katsuhito, and C ₄ are connected. As the discharge lamp, for example, two discharge lamps 12 and 13 are provided for two lamps. Here, the discharge lamp 12 has two filaments 12a and 12b, a capacitor 14 connected between the filaments 12a and 12b, and a capacitor connected in series with the capacitor 14 (capacitance C).
An LC series resonance circuit with 15 (current limiting inductor) is provided. The same applies to the discharge lamp 13 side. A capacitor 16 is connected between the filaments 13a and 13b, and a chi-yoke 17 (current limiting inductor) is connected in series with the capacitor 16 to form an LC series resonance circuit. These discharge lamps 12, 13 are directly connected in common on the side of the filaments 12b, 13b, and are connected in parallel by connecting one ends of the chiyokes 15, 17, so that the filaments 12b, 13b are common side filaments. Therefore, the filaments 12a and 13a are non-common side filaments. Further, capacitors 19, 20, 21, 22 as impedance elements are connected in parallel to these filaments 12a, 12b, 13a, 13b. In addition, a bias circuit 23 for supplying a DC bias current to the common-side filaments 12b and 13b among the filaments 12a, 12b, 13a and 13b is provided. The bias circuit 23 includes a common resistor R ₁ which is connected to the DC power supply lines, the resistors R ₁ and each filament 12
b, 13b and resistors R ₂ , R ₃ are connected in series. A current detection circuit 24 for detecting the magnitude of the DC bias current for these filaments 12b and 13b is connected to the bias circuit 23. Circuit to a logical sum by the current detecting circuit 24 to be connected in series with a transistor 26 whose base is connected to the resistor R ₃ and a transistor 25 whose base is connected to the resistor R ₂ (OR)
It is a configuration. Then, the base side of the transistor 25 is parallel circuit of a resistor R ₄ and the capacitor C ₅ is connected parallel circuit of the base side of the transistor 26 and the resistor R ₅ and capacitor C ₆ is connected. Furthermore, the oscillation stopping circuit 27 for stopping the operation is connected via a diode D ₉ is the drive circuit 8 for the base drive of the scan Germany quenching transistors 10 and 11. The oscillation stop circuit 27 is predominantly composed thyristor 28 comprising series-connected also serves for holding current the resistor R _1. A series circuit of resistors R ₆ , R ₇ and R ₈ is connected in parallel to the thyristor 28, and a capacitor C ₇ is connected in parallel to the resistor R ₈ . The gate of the thyristor 28 is connected to a connection point between the resistors R ₇ and R ₈ . Further, such a thyristor 28 is turned on when the DC bias current to the filament 12b or 13b becomes a predetermined value or less, and one end of the transistor 26 is connected to the resistors R ₆ and R _7.
It is connected to the midpoint of the connection. In such a configuration, when the two discharge lamps 12 and 13 are connected, a DC bias current flows through the bias circuit 23. That is, the discharge lamp resistance R ₁ in 12 side, filaments 12b, the resistor R _2, the DC bias current flows through the filament 12b in the path of the transistor 25. The same applies to the discharge lamp 13 side, the resistor R _1, filament 13b, the resistor R _3, the DC bias current flows through the filament 13b in the path of the transistor 26. That is, the filament 1 of the two discharge lamps 12 and 13
When the 2b and 13b sides are normally connected, the transistor
25 and 26 are both on. Therefore, the voltage between the gate and the cathode of the thyristor 28 does not exceed the threshold value by the bypass path of the transistors 25 and 26, and is maintained in the off state. This allows the oscillation stop circuit
The reference numeral 27 does not perform the operation of stopping the oscillation of the drive circuit 8, and the drive circuit 8 performs the normal operation so that the switching transistors 10 and 11 oscillate. When the filament 12b of the discharge lamp 12 comes off during lamp replacement or the like, for example, the DC bias current path is cut off by this removal, and the current becomes less than a predetermined value. Is detected. When the transistor 25 is turned off, the bypass path between the cathode and the gate of the thyristor 28 is released, and the voltage between the cathode and the gate becomes equal to or higher than the threshold, so that the thyristor 28 is turned on. This allows
The output of the drive circuit 8 is bypassed by the thyristor 28, and the drive circuit 8 stops the base drive of the switching transistors 10 and 11 and stops the oscillation operation. The same applies to the case where the filament 13b side of the discharge lamp 13 is disconnected and the transistor 26 is turned on. As described above, when the filament 12b or 13b of the discharge lamp 12 or 13 comes off, the oscillation operation is immediately stopped, so that the risk of electric shock is prevented. Here, it is a function of time and current value that the electric current flows through the human body,
If the oscillation is stopped for a short time, for example, 0.1 second after the discharge lamp 12 or 13 is removed from the filament 12b or 13b, the electric shock can be hardly felt or can be considerably reduced, which is a measure against electric shock. Now, consider a case where the filament 12a or 13a, which is a non-common side of the discharge lamp 12 or 13, is removed. In such a case, no countermeasures against electric shock are taken in this embodiment. This is for the following reason. For example, considering the potentials at both ends of the discharge lamp 12, the resonance capacitor 14 and the
(12) The filament 12 on the connection point side with the (current limiting inductor)
The a side has a high potential, and the common filament 12b side has a low potential. Therefore, when the filament 12b is removed, the high potential of the filament 12a can flow to the human body via the discharge lamp 12, so that the above-described countermeasures against electric shock are required. However, when the filament 12a is detached, the discharge lamp 12 is cut off from its high potential, so that there is no problem of electric shock, so that no measures against electric shock are required. This is the same in the case of the discharge lamp 13. Incidentally, the circuit configuration shown in FIG. 1 is more specifically incorporated in a specific circuit shown in FIG. First,
The power supply circuit 7 is based on 200 V AC, and includes a noise reduction / power factor improvement circuit 29 and a full-wave rectification circuit 30.
The driving circuit 8 includes switching transistors 10 and 11 respectively.
, And time constant circuits 33 and 34 connected to the base side of these transistors 31 and 32 (light is adjusted by changing the constants of these time constant circuits) and the like. . Here, this drive circuit 8
Is driven by supplying a voltage based on a current transformer 35 connected in series to the chiyokes 15 and 17 for the discharge lamps 12 and 13, and is provided with two windings 35a and 35b. Then, the oscillation stopping circuit 27 for holding the resistor R ₁ as described above to the power supply line at the preceding stage is predominantly composed thyristor 28 connected in series to the drive circuit 8 is connected. Here, in addition to the above-described resistor R ₈ and capacitor C ₇ on the gate side of the thyristor 28, a Zener diode ZD
₁ , a resistor R ₉ , a capacitor C ₈ , a resistor R ₁₀ , a capacitor C ₉ and a resistor R ₁₁ are connected. Further, diode D ₉ described above is connected between the thyristor 28 and the driving circuit 8. Also, lamp non-point detecting circuit 36 is connected to the resistor R _11. The lamp failure point detection circuit 36 is provided before the driving circuit 8 and includes a diode D ₁₀ , a zener diode ZD ₂ , a diode D _{11, a} capacitor C ₁₀ , and a resistor R _12.
It consists of. The resistance R ₁₃ is relative to the when to quenching transistor 11, a diode D _12, a resistor R _14,
Starting circuit is connected by a capacitor C ₁₁ and Toraiatsuku 37 are configured so as to start driving the transistor 11. In FIG. 2, a differential current transformer 38 is separately connected to the common side filaments 12b, 13b of the discharge lamps 12, 13, and the output from the detection winding 38d is transmitted through a full-wave rectifier circuit 39. It is input to the oscillation stop circuit 27. The differential current transformer 38, the full-wave rectifier circuit 39 and the like constitute a lamp end-of-life detecting circuit. As a result, the thyristor 28 does not normally turn on,
A predetermined voltage is supplied to the drive circuit 8, and the switching transistors 10 and 11 are alternately turned on and off to perform an oscillating operation. However, when one of the lamps reaches the end of its life due to deterioration over time or the like, a half-wave current flows through the lamp as is well known. Thus, the differential current signal is generated in the detection winding 38d of transformer 38, the signal is full-wave rectifier circuit 39, a capacitor C _9, via the C ₈ and forces the conduct Zener diode ZD ₁ and thyristor 28
Turn on. As a result, the power supply to the drive circuit 8 is cut off by the thyristor 28, the operation of the drive circuit 8 is stopped, the switching transistors 10, 11 are both turned off, and the oscillation operation is stopped. In this way,
When the lamps (discharge lamps 12 and 13) reach the end of life, a safety circuit function is provided to automatically stop the oscillation operation. When the lamps 12 and 13 do not light up for some reason, the output of the lamp fault detection circuit 36 increases. That is, as the series resonance continues, the output of the current transformer 35 is maintained in a large state. Accordingly, the voltage of the capacitor C ₁₀ is increased to conduct the Zener diode ZD _2, the capacitor C ₉ as described above, C ₈
I like to conduct the Zener diode ZD ₁ through. As a result, the thyristor 28 is turned on, and the oscillation operation is stopped even when a point is detected. In this embodiment, the oscillation stop circuit 27 that operates at the time of lamp replacement is provided as described in FIG. 1, but this circuit itself also serves as the oscillation stop safety circuit for the end of lamp life as described above. The current detection circuit 24 is connected in parallel to the gate side of the thyristor 28. That is, since the safety circuit at the time of lamp replacement is almost shared with the safety circuit for the end of lamp life, the circuit configuration is economical. The present invention is based on the premise that the impedance element is connected to each filament in parallel as described above.
Even when dimming, the fluctuation of the filament voltage can be kept small, and a bias circuit for supplying a DC bias current is provided for the common-side filament, and the current value is detected by a current detection circuit. Therefore, when the current value is equal to or less than the set value, it is determined that the common filament side of the discharge lamp has been removed and the oscillation stop circuit is operated to stop the oscillation operation. In such a case, it is possible to ensure safety when removing the common filament side where electric shock is a problem.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a circuit diagram showing one embodiment of the present invention, FIG. 2 is a circuit diagram showing a detailed configuration, and FIG. 3 is a circuit diagram showing a conventional example. 12,13 ... discharge lamp, 12a, 13a ... non-common side filament,
12b, 13b: Common side filament, 23: Bias circuit, 24: Current detection circuit, 27: Oscillation stop circuit

Claims (1)

(57) [Claims] An impedance element is connected in parallel with each filament of each discharge lamp, a resonance capacitor is connected between one end of each filament, one filament of these discharge lamps is commonly connected, and the other filament is connected. In a direct-coupled discharge lamp lighting device that is connected in parallel with each other via a resonant capacitor and a resonable inductor and is energized by the output of an inverter, the common-side filament of a plurality of discharge lamps A bias circuit for flowing a DC bias current is provided, and a current detection circuit for detecting the DC bias current value is provided. When the value detected by the current detection circuit becomes a predetermined value or less, the oscillation stop of the inverter is stopped. A direct connection type discharge lamp lighting device comprising a circuit.