KR830002610B1 - Discharge lamp lighting device - Google Patents

Abstract

No content.

Description

Discharge lamp lighting device

1 is a circuit diagram showing an example of a conventional two-light direct-connect discharge lamp lighting apparatus which is the background of the present invention.

2 is a principle block diagram of the present invention.

3 is a variation of the principle block diagram of the present invention.

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

5 is an electric circuit diagram of a discharge lamp lighting apparatus of another embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a discharge lamp lighting device, and more particularly, to a discharge lamp lighting device capable of reliably starting each discharge lamp at a relatively small high frequency voltage in a two-light (2kW) series lighting circuit.

1 is a circuit diagram showing an example of a conventional two-row direct-connect discharge lamp lighting apparatus which is the background of the present invention.

In the configuration, for example, the low-frequency AC power supply 1, such as a commercial power supply, is interposed between the discharge lamps 3a and 3b via a current-limiting device 2 containing a current-flow choke. The series circuit is connected. Thus, the high frequency power generation circuit 4 is connected to both ends of the series connection of the discharge lamps 3a and 3b. The high frequency power generation circuit 4 includes, for example, a power generation capacitor 41 and a series connection of the boost inductor 42 and the thyristor 43 connected to both ends of the oscillation capacitor 41. The operation of such an oscillation circuit 4 has already been known, and the description thereof is omitted here. In operation, when the AC power supply 1 is turned on, power is supplied to the power generation circuit 4 via the current-limiting device 2 so that the oscillation circuit 4 operates, and the oscillation circuit 4 operates at a high frequency voltage. This is obtained and applied to the series circuits of the discharge lamps 3a and 3b. Thus, although not shown, when the discharge lamp requires preheating, if the filaments of the discharge lamps 3a and 3b are sufficiently preheated by suitable preheating means, the high frequency high voltage from the high frequency oscillation circuit 4 described above The discharge lamps 3a and 3b are started by application. Therefore, when the discharge lamps 3a and 3b are started, the voltage at both ends of the series circuit of the discharge lamps 3a and 3b is lower than the breakdown voltage VBO of the thyristor 43 of the power generation circuit 4. Therefore, the oscillation circuit 4 stops the oscillation operation.

In this way, in order to light up the conventional two-line series circuit, the voltage of twice the starting voltage of each discharge lamp 3a, 3b is needed, and the oscillation circuit 4 becomes large and expensive. As shown in this drawback, a solution is solved by gradually starting the discharge lamps 3a and 3b by gradually connecting the starter capacitors 6 in parallel to one discharge lamp 3b, for example. . However, such a configuration is based on the current flowing through the starting capacitor 6, except that the filament transformer is separately provided when the discharge lamps 3a and 3b require filament preheating. The filament preheating of the connection points of the discharge lamps 3a and 3b is made impossible.

In particular, when the simple oscillation capacitor 51 is directly connected to the oscillation circuit 4 and is lit by the cycle cycle star art lighting method, the effect of the starter capacitor 96 gradually changes every half cycle of the power supply. Increasingly, the capacity of the starting capacitor 6 has a fatal defect that the variation of the lamp current due to the power supply voltage becomes remarkably large. The reason for this is that the high frequency power generation voltage shows a substantially constant voltage with respect to the power supply voltage fluctuation. However, the low frequency charging voltage given to the starting capacitor 6 gradually fluctuates with the power supply voltage due to the lighting of the discharge lamp. 3a) is given as a voltage of great fluctuation rate. Or, in addition, the start voltage of the discharge lamp changes itself due to a change in the ambient temperature, whereby the firing phase changes every half cycle, further worsening the total change rate. Therefore, the main object of the present invention is not only to start each discharge lamp with a relatively small high-frequency voltage, such as for starting one lamp, but also a lamp caused by a power voltage fluctuation lamp, especially in every cycle star art lighting method. An object of the present invention is to provide a discharge lamp lighting apparatus having an improved rate of change of current.

Summary of the Invention The present invention summarizes a block inductor between at least two discharge lamps in series to connect each discharge lamp in series, and connect capacitors in parallel with each other in series connection of the discharge lamp block inductors. High frequency and high voltage output is applied to each discharge lamp which is electricity through capacitor through direct heat.

The above and other objects, features, and drawings of the present invention will become more apparent from the following detailed description.

2 is a principle block diagram of the present invention. In this configuration, the direct-current circuits of the discharge lamp 3a, the block inductor 7 and the discharge lamp 3b are slowed through the current-flow choke 2 at both ends of the AC power supply 1. The first condenser 6a is radiated and connected to the indirect heat circuit of the discharge lamp 3a with the block inductor 7, and the second condenser (2) is connected to the direct circuit of the discharge lamp 3b and the block inductor 7. 6b) are connected in parallel. A power generation circuit 4 as shown in FIG. 1 is connected in parallel to both ends of the series circuit of the discharge lamp 3a, the block inductor 7 and the discharge lamp 3b.

In operation, when the AC power supply 1 is turned on, both ends of the series circuit and the oscillation circuit 4 of the discharge lamp 3a, the block inductor 7, and the discharge lamp 3b are interposed through the Hall current choke 2. Is given the low frequency supply voltage. As a result, the oscillation capacitor 41 is charged, and when the voltage applied to the thyristor 43 becomes equal to or higher than the breakdown voltage, the thyristor 43 conducts. The oscillation capacitor 41 and the boost inductor 42 cooperate with each other to generate a high frequency high voltage. This high frequency high voltage is applied to the series circuit of the discharge lamp 3a, the block inductor 7 and the discharge lamp 3b, and is provided to the discharge lamp 3b and the second capacitor via the first capacitor 6a. As seen from the oscillation circuit 4 via 6b, it is applied to the discharge lamp 3a in parallel. As a result, the discharge lamps 3a and 3b cause a discharge breakdown by a high frequency high voltage and glow discharge. The discharge lamp 3a, the block inductor 7, and the discharge lamp 3b flow in the direct heat circuit, and the operation proceeds to arc discharge, and the discharge lamps 3a and 3b start up. When the discharge lamps 3a and 3b are turned on, the voltages at both ends thereof are not filled with the breakdown voltage VBO of the thyristor 43 constituting the oscillation circuit 4, and the oscillation circuit 4 starts the oscillation operation. After that, each of the discharge lamps 3a and 3b is fired by the low frequency AC power supply 1 every half cycle.

In this manner, at the time of starting the discharge lamps 3a and 3b, a high frequency high voltage is applied in parallel to the discharge lamps 3a and 3b, and a low frequency power supply voltage is applied to the discharge lamps 3a and 3b. By applying the arc directly and causing arc discharge, the voltage value of the high frequency high voltage can be reduced by 30% as compared with the case where the gradual starting capacitor 6 is not used as the two-light series lighting circuit shown in FIG. will be. When the short circuit capacitor 51 is connected in series with the oscillation circuit 4, the discharge lamps 3a and 3b can be turned on by the cycle cycle art lighting method. That is, the power supply voltage is applied to the thyristor 43 via the short oscillation capacitor 51, and the oscillation circuit 4 starts the oscillation operation to cause the thyristors 43 to break over. This oscillation operation is continued without the short oscillation capacitor 51. However, since the short oscillation capacitor 51 is present, the oscillation is simply performed at every half cycle in the rising part of the power supply voltage. .

Therefore, in this oscillation circuit, a simple oscillation output is generated for each predetermined phase of each half cycle of the AC power supply voltage. Thus, by this simple oscillation output, the discharge lamps 3a and 3b can be started up and lighted as described above. After the lighting of the discharge lamps 3a and 3b, the oscillation circuit 4 stops the oscillation operation for the same reason as described above in the remaining period of the half cycle, but the condenser for short oscillation of the next half cycle ( Since the terminal voltage of 51) is superimposed on the power supply voltage to charge the oscillation capacitor 41, each of the discharge lamps 3a and 3b is generated by the simple oscillation output of the oscillation circuit 4 for each half-cycle. Is fired again.

3 is a variation of the principle block diagram of the present invention. In the configuration, this block diagram is the same as the block diagram shown in FIG. 2 except for the following. In other words, the primary winding 21 as the Hallyu choke and the secondary winding 22 as the Hallyu choke and block inductor are provided in the current-limiting device 2. In other words, by winding the primary winding 21 and the secondary winding 22 in the direction of increasing magnetic force, the primary winding 21 and the secondary winding 22 are different from each other. It is worn as a multi-magnetism choke, and the reflux device 2 is not enlarged, and thus the block inductor as a component can be omitted.

4 is an electric circuit of a lighting apparatus according to the Mechastar Star Art lighting method according to an embodiment of the present invention. In the constitution, the capacitor 8 is connected to the AC power supply 1 with the Hall current choke 2 interposed therebetween, and the discharge lamp 3a, the block inductor 7, and the discharge lamp 3b are connected. The in series circuit with is connected in parallel. The high voltage circuit 5 is connected between the non-power supply side of the filament 31a of the discharge lamp 3a and the non-power supply side of the filament 32b of the discharge lamp 3b. The high-voltage circuit 5 is a short oscillation capacitor for the oscillation circuit 4 formed by parallel connection of a booster inductor 42 and a series circuit of two thyristors 43 and 44 to the power generation capacitor 41. The parallel circuit between 51 and the resistor 52 is connected in series. In addition, between the boost inductor 42 and the thyristor 43, a low frequency source voltage is applied from the AC power supply 1 via the resistor 53 for stabilizing the terminal voltage of the short oscillation capacitor 51. Again, the first capacitor 6a is connected between the non-power source side of the filament 31a of the discharge lamp 3a and the free end of the filament 31b of the discharge lamp 3b. The second capacitor 6b is connected between the free end of the filament 32a of the discharge lamp 3a and the non-power side of the discharge lamp 32b.

In operation, when the AC power source 1 is turned on, the oscillation capacitor 41 is interposed between the Hallyu choke 2, the filament 31a, the short oscillation capacitor 51, the oscillation capacitor 41, and the filament 32b. ) Is charged. At this time, the capacitor 8 and the capacitors 6a and 6b are also charged. The thyristors 43 and 44 conduct when the voltage at both ends of the power generation capacitor 41 exceeds the breakdown voltage VBO of the thyristors 43 and 44.

As a result, the oscillation capacitor 41 and the boost inductor 42 work together, and the power generation circuit 4 starts the oscillation operation, and the filaments 31a, 31b, 32a, and 32b are preheated. Since the oscillation operation includes the short oscillation capacitor 51, the oscillation is simply performed at every half cycle in the granular portion of the power supply voltage. Therefore, in this high voltage circuit 5, a simple oscillation output is generated for each predetermined phase of each half cycle of the AC power supply voltage.

The aforementioned oscillation output is superimposed on the low frequency voltage at both ends of the short oscillation capacitor 51 by the high frequency blocking action of the block inductor 7, and is discharged to the discharge lamp 3b via the capacitor 6a. It is applied in parallel to the discharge lamp 3a with 6b interposed therebetween.

As a result, when each filament is sufficiently preheated, a large low frequency current is supplied to the discharge lamps 3a and 3b so that the discharge lamps 3a and 3b transition to arc discharge and light up.

More preferably, leakage of the oscillation output to the outside can be completely prevented by connecting the high frequency pass capacitor 9 to the AC power supply 1 in parallel.

5 is an electric circuit diagram of a lighting apparatus according to the cycle cycle star art lighting method of another embodiment of the present invention. In the configuration, this embodiment is the same as the embodiment shown in FIG. 4 except for the following. That is, the condenser 6c is connected to the power supply side of the filament 31a in parallel with the condenser 6a, and the condenser 6d is connected to the power supply side of the filament 32b in parallel with the condenser 6b. Such a connection can be achieved by filaments 31a, 31b, 32a, 32 (a) in all short-circuit current paths including the power supply 1, even if any of the capacitors 6a-6b is broken. By including at least one of 32b), these filaments are melted due to excessive short-circuit current, thereby fulfilling the function of fuse, thereby ensuring safety. Incidentally, in the above-described embodiment, the case of the series lighting circuit of 2 lamps has been described as an example, but this is connected so as to apply a high frequency voltage in parallel with a capacitor connected to each of the discharge lamps, in addition to the series connection of 2 lamps or more. do.

As described above, according to the present invention, the high frequency high voltage is applied in parallel to the discharge lamp to glow discharge, and the low frequency power supply voltage is applied directly to the discharge lamp to arc discharge. Therefore, the high frequency high voltage can be significantly lowered. In addition, in every cycle lighting system, the fluctuation of the lamp current accompanying the fluctuation of the power supply voltage and the like can be improved.

Claims (1)

A low-frequency AC power supply, a current-limiting device including a Hall current choke, at least two discharge lamps, and an open circuit are interposed between each discharge lamp, and at least two discharge lamps are connected in series. High frequency high voltage output of the high frequency high voltage generating means provided with the block inductor, the high frequency high voltage generating means for generating the high frequency high voltage, and each discharge lamp which has been electrically connected, and a plurality of condensers connected in parallel to the series circuit of the block inductor. Is provided in parallel to each of the discharge lamps provided through each of the capacitors described above, and the low-frequency voltage of the low-frequency AC power sourced in this manner is directly applied to the discharge lamps connected to the direct series. Discharge lamp lighting device.

Images