KR830002175B1 - Discharge lamp lighting device - Google Patents

Abstract

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Description

Discharge lamp lighting device

1 is a circuit diagram of the macycle star art lighting method that is the background of the present invention.

2 is a block diagram illustrating the principles of the present invention.

3 is a circuit diagram of a discharge lamp lighting apparatus of an embodiment of the present invention.

4 is a waveform diagram for explaining the operation of FIG.

5 and 7 are circuit diagrams of another embodiment of the present invention.

6 is a circuit diagram showing a modification of the switch means of FIG.

8 is a circuit diagram of a discharge lamp lighting apparatus in the case of turning on two-light series in another embodiment of the present invention.

The present invention relates to a discharge lamp lighting apparatus, in particular, at the start of the discharge lamp, the start-up light is turned on at a voltage overlapping the high frequency oscillation voltage and the pulse voltage. Relates to a device.

The present applicant first proposed the Macycle star art lighting method, which is useful for improving the efficiency and at the same time miniaturization and weight reduction of the Hallyu choke, and is very useful with regard to living resources and living energy.

1 is an electric circuit diagram showing a discharge lamp lighting apparatus using the Macycle star art lighting method which is the background of the present invention. In the configuration, reference numeral 1 denotes a high-frequency power source having a commercial frequency, and a series circuit of the current-limiting choke 2 and the discharge lamp 3 as an example of the current-limiting device is connected. A simple high frequency high voltage generation circuit (hereinafter, a high voltage circuit) 4 is connected to the non-power side of the filaments 31 and 32 of the discharge lamp 3.

The high voltage circuit 4 described above generates a high frequency high voltage configured by connecting a series circuit of a thyristor 52 and a boost inductor 53 as an example of a current controlled nonlinear resistance element to an oscillation capacitor 51 in parallel. A circuit in which a short oscillation capacitor 6 is connected in series to a circuit (hereinafter referred to as a booster circuit) 5.

The high-voltage circuit 4 described above can be replaced with a high-voltage generator circuit using a thyristor with a gate such as a triac or the like, as long as the high-frequency oscillation operation is performed briefly.

Next, the operation of the configuration of FIG. 1 will be described.

When the power supply 1 is supplied to the power supply 1, the power supply voltage is applied to the discharge lamp 3 via the current flow choke 2, and the power supply voltage is also applied to the high voltage circuit 4. In the high voltage circuit 4, a power supply voltage is applied to the thyristor 52 via the simple oscillation capacitor 6, and the boost circuit 5 starts the oscillation operation in order to brake over the thyristor 52. . This oscillation operation is continued without the short oscillation capacitor 6, but the short oscillation capacitor 6 is gradually charged in accordance with the oscillation operation of the booster circuit 5, and the short oscillation capacitor 6 Terminal voltage of

This oscillation output is applied to the discharge lamp 3 in superimposition with a power supply voltage. At the same time, during the oscillation period of the over-pressure circuit 4, the high-voltage circuit through the path of the power supply 1, the Hallyu choke 2, the filament 31, the high voltage circuit 4, the filament 32, the power supply 1 As the input current i _f of (4) flows, the filaments 31 and 32 are preheated.

Thus, when the filaments 31 and 32 are sufficiently preheated, the discharge lamp 3 is started by triggering the oscillation output from the high voltage circuit 4. When the discharge lamp 3 starts up, the high voltage circuit 4 stops the oscillation operation because the voltage at both ends of the discharge lamp 3 decreases to the tube voltage.

Subsequently, the discharge lamp 3 is re-ignited by the short oscillation output of the high voltage circuit 4 for each half cycle of the power source 1, and is kept lit by the power source voltage.

According to the above-described Macycle star art lighting method, the discharge lamp 3 is re-ignited by the simple oscillation output of the high-voltage circuit 4, so that the power supply voltage is compared with the conventional lighting method of re-igniting the discharge lamp by the power supply voltage. In addition, the difference voltage between the power supply voltage and the tube voltage of the discharge lamp becomes small, and the current flow choke 2 sharing this difference voltage can be miniaturized. The accumulated energy and required inductance of the current-flow choke 2 are about 1/4 and 1/5, respectively, compared with the conventional glow lighting method, and can be miniaturized accordingly.

And compared with the stabilizer of the rapid star art system of a boost transformer structure, these downsizing ratio becomes more remarkable.

Furthermore, according to this lighting method, since the phase difference between the power supply voltage and the tube current is smaller than that of the conventional lighting method, the power factor improvement capacitor can be made unnecessary or extremely small.

Here, the tube voltage is a square wave having a rest period due to the short oscillation period, and its effective value is slightly lower than that of the conventional lighting method. In addition, the concise input current of the high voltage circuit 4 flows through the current-flow choke 2, so that the waveform of the tube voltage is slightly increased under the influence of the input current. The phase of appearance of the input current is constant in spite of the fluctuation of the power supply voltage. Therefore, the phase phase of the tube current is constant in spite of the fluctuation of the power supply voltage. Is maintained in a constant phase despite the change in the power supply voltage. In addition, if the tube current increases due to an increase in the power supply voltage, the above-described input current has a characteristic of decreasing as the rear end of the tube current waveform is fed into the next half cycle of the input current appearance, i.e., negative. It has a coefficient of variation of. These are the reasons why the fluctuation rate of the tube current in the every cycle star lighting method is kept good despite the decrease in the stable impedance.

As described above, the macycle star art lighting method, which is the background of the present invention, has a great advantage in terms of living resources and living energy.

By the way, when the oscillation output voltage of the high voltage circuit 4 is increased in the Macycle star art lighting method, which is the background of the present invention, it is possible to obtain a large oscillation energy and reliably start the discharge lamp. When the discharge lamp is re-ignited with this large oscillation output voltage, there is a problem that the damage of the filament is relatively large and the life of the discharge lamp is short.

In addition, when the discharge lamp 3 is of the hot cathode type as in the illustrated example, there is a problem that the filament preheating electrode and the lamp lighting efficiency are opposed.

That is, the macycle star art lighting device shown in FIG. 1 preheats the filaments 31 and 32 as a simple input current to the high voltage circuit 4, so that the filament preheating current is likely to be insufficient. In order to increase the filament preheating current, for example, it is considered to increase the capacity of the short oscillation capacitor 6 to increase the short oscillation period of the high voltage circuit 4. However, by simply increasing the capacity of the short oscillation capacitor 6, the short oscillation period of the high-voltage circuit 4 during the lighting of the discharge lamp 3 also becomes long, which is the ratio of the discharge lamp 3 by the short oscillator. In addition to the increase in the light emission period, the power loss due to the heating of the filament during the short oscillation period also increases, which causes a decrease in the luminous efficiency of the discharge lamp 3. Therefore, conventionally, in order to increase the filament preheating current at the start of the discharge lamp 3, there is a request to increase the capacity of the short oscillation capacitor 6, and increase the luminous efficiency during the lighting of the discharge lamp 3. In order to meet the demand for reducing the capacity of the short oscillation capacitor 6 for two purposes, the capacity of the short oscillation capacitor 6 was set to a compromise value in the two requirements described above. Therefore, the capacity of the short oscillation capacitor 6 is excessive in view of the filament preheating current, and is excessive in view of the luminous efficiency of the discharge lamp 3, and there is room for improvement. Left.

Therefore, the main object of the present invention is to start the discharge lamp with a voltage which overlaps the oscillation voltage and the pulse voltage at the start of the discharge lamp, and to re-ignite only the oscillation voltage after the discharge lamp is turned on. After the start-up, it is possible to prevent the application of a pulse voltage (high voltage) to the filament to achieve a long life of the discharge lamp, and furthermore, to provide a cheap, discharge lamp lighting device.

FIG. 2 is a block diagram showing the principle of the present invention. Referring to FIG. The oscillation circuit 5 'of one example of the high frequency voltage generating means is selected such that the oscillation voltage is equal to or higher than the voltage required for re-ignition for each half cycle of the discharge lamp 3, i.e., The booster circuit 5 shown in FIG. 1 is used. The pulse generating circuit 7 of the pulse generating means generates a pulse voltage having a high crest value, but the peak value of the superimposed voltage overlapping the pulse voltage and the oscillating voltage of the oscillating circuit 5 'is the discharge lamp 3. The generated pulse voltage is selected so that the initial starting voltage of E _st or higher. The pulse generating circuit 7 is closed at the start of the discharge lamp 3 and is formed after the lighting of the discharge lamp 3 so as to invalidate the switch to invalidate the pulse generating circuit 7. It comprises a means (8). At the start of the discharge lamp, since the switch means 8 is closed, the pulse voltage generated by the pulse generating circuit 7 and the oscillation voltage generated by the oscillating circuit 5 'overlap each other and the discharge lamp ( It is supplied at both ends of 3). For this reason, the discharge lamp 3 is started up by the high voltage more than the superimposed start voltage of a pulse voltage and an oscillation voltage. After the lamp of the discharge lamp 3 is turned on, the switch means 8 is individualized, thereby invalidating the pulse generating circuit 7. For this reason, since the oscillation circuit 95 'is oscillated only after the discharge lamp 3 is turned on, the discharge lamp 3 starts at every half cycle of the AC voltage 1 at the oscillation voltage of the oscillation circuit 5'. It is kept on by the power supply voltage.

Next, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a specific circuit diagram of the discharge lamp lighting apparatus according to the embodiment of the present invention. In the configuration, the AC power source 1 includes a current-limiting choke 2 of an example of a current-limiting device and a hot cathode discharge lamp 3 as an example of a discharge lamp. ) Is connected in series. At the non-power-side end of the filament 31, 32 of the discharge lamp 3, a series circuit of the secondary winding 92 of the short oscillation capacitor 6 and the pulse transformer 9 and the oscillation circuit 5 '. Is connected in parallel. This oscillation circuit 5 'is constituted of a circuit like the booster circuit 5 shown in FIG. The oscillation circuit 5 'and the short oscillation capacitor 6 constitute a simple high frequency generating means 4'. The series circuit of the primary winding 91 of the pulse transformer 9 and the thyristor 8 of an example of a switch means is connected in parallel to the short oscillation capacitor 6. The pulse generating circuit 7A is formed as the short oscillation capacitor 6, the primary winding 91, the thyristor 8, and the secondary winding 92. As shown in FIG.

FIG. 4 is a waveform diagram of each part for explaining the operation of FIG. 3, in particular, (a) shows the oscillation voltage V ₀ of the oscillation circuit 5 'and the pulse voltage of the pulse circuit 7A at the start of the discharge lamp. The voltage waveform superimposed on V _P is shown. (B) shows the simple oscillation voltage V ₀ of the oscillation circuit 5 'after the discharge lamp is turned on.

Next, the specific operation of the present embodiment will be described with reference to FIGS. 3 and 4 as follows.

First, the operation at the start of the discharge lamp 3 will be described. As the AC power source 1 is inputted, the paths of the Hallyu choke 2, the filament 31, the short oscillation capacitor 6, the secondary winding 92, the oscillation capacitor 51, the filament 32 are routed. Through this, the oscillation capacitor 51 is charged. When the terminal voltage of the oscillation capacitor 51 exceeds the brake over voltage of the thyristor 52, the thyristor 52 conducts, and the oscillation capacitor 51 and the boost inductor 53 cooperate with each other to perform a high frequency oscillation operation. .

Only the oscillation voltage V ₀ of the oscillation circuit 5 ′ does not enable the start of the discharge lamp 3. During the oscillation operation of the oscillation circuit 5 ₁ , the short oscillation capacitor 6 is charged as an input current to the oscillation circuit 5 ′, and the filaments 31 and 32 are preheated. Then, as the oscillation operation of the oscillation circuit 5 'causes the short oscillation capacitor 6 to be gradually charged, and if the terminal voltage exceeds the breakover voltage of the thyristor 8, the thyristor 6 is conducted. The discharge current of the short oscillation capacitor 6 flows through the closed circuit of the short oscillation capacitor 6-thyristor 8-primary winding 91-6. As a result, the pulse voltage V _P boosted by the secondary winding 92 is induced. The pulse voltage V _P and the oscillation voltage V ₀ of the oscillation circuit 5 ′ overlap and are applied to the discharge lamp 3.

At the start-up of this discharge lamp 3, since the short oscillation capacitor 6 is charged and discharged as described above, the oscillation circuit 5 'is shown in Fig. 4 (a). It oscillates continuously. Due to the continuous oscillation operation of the oscillation circuit 5 ', the preheating currents of the filaments 31 and 32 significantly increase. Thus, when the filament is sufficiently preheated, the discharge lamp 3 is turned on by the high voltage exceeding the starting voltage required by overlapping the oscillation voltage V ₀ and the pulse voltage V _P.

When the discharge lamp 3 starts up, the tube current flows through the discharge lamp 3, and the tube voltage of the discharge lamp 3 decreases. As a result, the short oscillation capacitor 6 is not charged until it reaches the breakover voltage of the thyristor 8, and the pulse generation circuit 7A stops the pulse generation operation. In the next half cycle, the short oscillation capacitor 6 is gradually charged in accordance with the oscillation operation of the oscillation circuit 5 ', but the terminal voltage of the short oscillation capacitor 6 is the break-out of the thyristor 8. Before reaching the burr voltage, the discharge lamp 3 depends on the oscillation output voltage of the oscillation circuit 5 '.

In this way, compared to the conventional pneumatic circuit of the every cycle star art lighting method, the applied energy at the time of starting and re-ignition of the discharge lamp 3 can be reduced, and damage to the filaments 31 and 32 is prevented. There is an advantage that the discharge lamp 3 has a long life by being reduced. In addition, since the pulse generating circuit 7A uses the short oscillation capacitor 6, there is an advantage that the circuit configuration is simple.

Furthermore, in the hot cathode discharge lamp 3, since the short-circuit condenser 6 is substantially shorted as the thyristor 8 at the start-up, the filament preheating is performed even if the capacity of the short-condensation capacitor 6 is smaller than before. The current can be made large enough. In addition, since the capacity of the short oscillation capacitor 6 is small after the start-up of the discharge lamp 3, the short oscillation period of the oscillation circuit 5 'can be shortened, and the filament damage can be made small. There is also an advantage that can improve the luminous efficiency.

As a modification of the present embodiment, the secondary winding 92 is formed between the positions of the X marks shown, that is, the connection points between the condenser 6 and the primary winding 91, or the AC power source 1 and the filament ( It may be connected in the middle between the connection points of (32).

Instead of the series overlapping of the pulse voltage V _P and the oscillation voltage V ₀ , the secondary winding 92 and the capacitor 74 are connected in series, and the series circuit is connected to the filament 31 of the discharge lamp 3, By connecting in parallel to the power supply side end of (32), the oscillation voltage V ₀ and the pulse voltage V _P may be superimposed in parallel. In another variation, the bias coil 54 is magnetically coupled to the boost inductor 53, and the bias coil 54 is coupled to the short-circuit capacitor 6 thyristor 8-1 primary winding ( You may insert into the closed circuit of 91)-(6). In other words, there is an advantage that the oscillation voltage at the time of generating the pulse voltage, that is, at the start of the discharge lamp 3, can be increased without increasing the capacity of the circuit component. As another modification, the oscillation capacitor 51 may be connected in parallel to the power supply side ends of the filaments 31 and 32. In this way, the filaments 31 and 32 can be preheated as the oscillation current of the oscillation circuit 5 '. The terminal on the side of the short oscillation capacitor 6 of the thyristor 8 may be connected to the power supply side of the filament 31. In brief, the filament 31 can be preheated as the discharge current of the short oscillation capacitor 6.

FIG. 5 is a circuit diagram of the discharge lighting apparatus of another embodiment of the present invention. This embodiment differs from FIG. 3 in that the pulse generating circuit 7B is configured as follows. That is, between the non-power source side end of the filament 31 of the discharge lamp 3 and the power supply side end of the filament 32, the secondary winding 92 of the filament transformer 9, the oscillating circuit 5 'and the primary winding (91) and the series circuit of the short oscillation capacitor 6 are connected, and the bias coil 54, the thyristor 81, and the diode 82 are between the oscillation circuit 5 'and the non-power-side end of the filament 32. Connect the series circuit of In this circuit, the liver

Since the operation of this embodiment is almost the same as in FIG. 3 after the discharge lamp is turned on, only the operation at the start of the discharge lamp 3 will be described here. When the AC power source 1 is supplied, the oscillation capacitor 51 is charged. When the terminal voltage of the oscillation capacitor 51 exceeds the brake over voltage of the thyristor 52, the thyristor 52 conducts and the oscillation circuit 5 'starts oscillating. During the oscillation operation period of this oscillation circuit 5 ', the short oscillation capacitor 6 is charged by the input current to the oscillation circuit 5. As shown in FIG. In the polarity shown in the AC power supply 1, the terminal voltage of the short oscillation capacitor 6

On the other hand, if the power supply voltage of the AC power supply 1 is in the opposite configuration to that shown in the figure, even if the capacitor for short oscillation 6 is charged in the opposite polarity according to the oscillation operation of the oscillation circuit 5 ', the diode ( Since 82 is open in the opposite direction, the thyristor 81 does not conduct, and the pulse circuit 7B does not generate a pulse voltage.

Thereafter, similarly, for each polarity of the power source voltage e, a voltage in which the oscillation voltage V ₀ is increased by twice the pulse voltage V _P is generated, and only the oscillation voltage V ₀ is generated in the opposite polarity. Then, when the discharge lamp 3 is turned on by the voltage overlapping the pulse voltage V _P and the oscillation voltage V ₀ in one polarity of the power supply voltage e, the pulse generating circuit 7B is operated as in the above-described embodiment of FIG. ) Stops the pulse generation operation. Then, the discharge lamp (3) is a short oscillation before the action of the oscillation circuit (5 ') and the short oscillation capacitor (6)

In addition, various other modifications can be considered by switching to the switch means 8 as a series circuit of the thyristor 81 and the diode 82 of FIG.

6 (a) and 6 (b) are circuit diagrams of another embodiment of the switch means 8.

In FIG. 6 (a), the thyristor 83 is connected to the parallel circuit of the thyristor 81 and the diode 82 in series. In operation, the pulse voltage V _P is generated when the terminal voltage of the short oscillation capacitor 6 exceeds the breakover voltage of the sum of the thyristors 81 and 83 in one polarity of the AC voltage e. In the other polarity of the AC voltage e, the pulse voltage V _P is generated when the terminal voltage of the short oscillation capacitor 6 exceeds the breakover voltage of one thyristor 83.

In FIG. 6 (b), the thyristor 84 with a gate is used as the switch means 8.

7 is a circuit diagram of a discharge lamp lighting apparatus according to another embodiment of the present invention. The secondary winding 92 of (9) is connected in series. At the non-power side ends of the filaments 31 and 32 of the discharge lamp 3, the secondary winding 2b of the Hallyu choke 2, the oscillation circuit 5 'and the reciitter The serial circuit of the 81 and the diode 82 is connected. In addition, between the oscillation circuit 5 'and the power supply side end of the filament 32, a series circuit of the short oscillation capacitor 6 and the primary winding 91 of the pulse transformer 9 is opened. . Moreover, the high frequency bus capacitor 10 is connected in parallel with the DC power supply 1 as needed.

The operation of this embodiment is almost the same as in FIG. 5, and can be easily understood with reference to FIG. 8. Thus, detailed description thereof will be omitted.

8 is a circuit diagram of a discharge lamp lighting apparatus according to another embodiment of the present invention. In particular, FIG. 8 shows a case where two lamps are discharged in series. (3a) and (3b) are connected in series. The series circuit of the pulse generation circuit 7D and the oscillation circuit 5 'is connected between the non-power source side end of the filament 31a of the discharge lamp 3a and the non-power source side end of the filament 32b of the discharge lamp 3b. do. The pulse generating circuit 7D connects the primary circuit 91 of the pulse transformer 9 and the series circuit of the triac 85 in parallel to the short oscillation capacitor 6, and pulses them.

In operation, similarly to the above-described one-lighting circuit, the short oscillation capacitor 6 is charged in the oscillation operation period of the oscillation circuit 5 '. When the short oscillation capacitor 6 is charged to a predetermined voltage, the triac 85 conducts when a gate signal is given to the triac 85 by an appropriate gate means. Therefore, the pulse-shaped discharge current flows through the closed circuit of the primary winding 91-the triac 85 in the short oscillation capacitor 6, and the pulse voltage V _P boosted by the secondary winding 92 is induced. The pulse voltage V _P is applied to the connection points of the discharge lamps 3a and 3b via the capacitor 11. At this time, a voltage is induced in the filament winding 12 by the discharge current flowing in the primary winding 91, and the filaments 32a and 31b are preheated by the induced voltage. During the repetitive movement, if the filaments 31a and 32b are sufficiently preheated by the input current to the oscillation circuit 5 ', the filaments 32a and 31b are also caused by the discharge current of the pulse generating circuit 7D. When sufficiently preheated to the induced voltage, the discharge lamp 3a is turned on by the overlapping voltage between the oscillation voltage V ₀ of the oscillation circuit 5 'and the pulse voltage V _P of the pulse generating circuit 7D. Subsequently, the discharge lamp 3b is turned on by the overlapping voltage between the oscillation voltage V ₀ and the pulse voltage V _P. In this manner, when the discharge lamps 3a and 3b are turned on, the gate signal of the triac 85 is not given. For this reason, the short oscillation capacitor 6 becomes effective, and by canceling the power supply voltage e, the oscillation circuit 5 is made to oscillate simply every predetermined phase of each half cycle of the power supply voltage e. Accordingly, the discharge lamps 3a and 3b are turned on by the simple oscillation output V ₀ ′ of the oscillation circuit 5 '.

As described above, according to the present invention, at the start of the discharge lamp, the start lamp is obtained by the start voltage based on the superposition voltage of the oscillation voltage and the pulse voltage, and the start lamp is turned on. By re-ignition with only the necessary oscillation voltage, it is possible to prevent the damage of the electrode without applying a high voltage after the start of the discharge lamp, thereby providing a unique effect of extending the life of the discharge lamp.

Claims (1)

In a discharge lamp lighting device in which a low frequency alternating current power source, a current-limiting device, and a discharge lamp are connected in series, pulse generating means generating a pulse voltage having a high peak value, which is biased by the low frequency alternating current power source, and a low frequency alternating current power supply. And high frequency voltage generating means for generating an oscillation voltage of a level required for re-ignition of the discharge lamp, the pulse voltage generating means comprising an oscillation voltage of the high frequency voltage generating means output and the pulse voltage. A discharge lamp lighting device characterized by generating a pulse voltage selected so that the peak voltage of the superimposed voltage superimposed over is greater than the starting voltage of the discharge lamp and giving the superimposed voltage to the oscillation lamp to start up the lamp.

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