FR2561850A1 - Device for powering pulse discharge tubes - Google Patents

Abstract

The device for powering pulse discharge tubes includes a pulse generator 1 whose output is connected to a pulse discharge tube 3 and a set-up, comprising a source 5 for powering the auxiliary arc of the tube and a self-inductor 6 in series, these being connected in parallel with the pulse generator 1 via a diode 4. In parallel with the said set-up, there is a device 7 for short-circuiting current from the auxiliary arc during the pulses produced by the pulse generator including in series a voltage source 8 and a valve 9. The device according to the invention is suitable for laser technology and in particular for the powering of solid-state lasers and pulsed lighting installations.

Description

DEVICE FOR A2iiENTATiON OF TUBES A
IMPULSE DISCHARGE
The present invention relates to pulse technique and more particularly to devices for feeding pulsed discharge tubes.

 The device for supplying pulsed discharge tubes is best suited to the laser technique, and in particular to the supply of solid-state lasers, as well as to pulsed lighting installations.

 One of the most significant constraints for pulsed discharge tubes is the reliability and the maximum lifetime resulting from the adequate design of the device for their supply.

 These imperatives, as we know, are best satisfied when the device is capable of ensuring the auxiliary arc regime imposing on the tube a weak discharge which maintains it in the conducting state (Passing). These devices for feeding pulsed discharge tubes 9 are either complicated, lack reliability, or have a low efficiency.

 For the device to be reliable, the output characteristic of the auxiliary arc power source must be close to that of the current source (cf. "Pulsed light sources" under the editorship of IS Marchak, "Snergia" editions). , 1978, p.403 -or "Elements of laser technique" by BH Belostotsky et al., M., Editions "Sov. Radio", 1972, p. 261). This condition can be fulfilled by power sources of the auxiliary arc provided with an inductor at the output provided that the inductance of the inductor is sufficient to ensure the current stability of the auxiliary arc. the presence of a choke at the output of the auxiliary arc power source, in addition to hampering the ignition of the tube, delays the establishment of the nominal current of the auxiliary arc beyond the duration of the powerful discharge pulse which can lead to the extinction of the tube.

 To eliminate the drawbacks indicated in the device, the inductor current is maintained during the powerful discharge pulse and in rest time between two consecutive pulses.

 existing devices for supplying pulsed discharge tubes include a pulse generator with a supply circuit and the output of which is connected to the pulsed discharge tube, an assembly comprising a supply source of the auxiliary arc of the pulse discharge tube and a series inductor, connected in parallel to said pulse generator by a diode, and an auxiliary arc current short-circuiter during the pulses produced by the pulse generator, placed in parallel on said assembly.

 Thus in the device for feeding pulsed discharge tubes which is the subject of the inventor's certificate dtURSS N 527035, cl.

H05K 1/04, published on 30.08.76, the auxiliary arc current short-circuiter is presented as a thyristor with an anode blocking device.

 The blocking device by anode of the thyristor dissipates energy which leads to the lowering of the efficiency of the device. Another disadvantage to note of this body is that it increases the complexity of the device and compromises its reliability.

 In the existing device for supplying pulsed discharge tubes which is the subject of the USSR inventor's certificate N 352420, cl.

 X05B41 / 32, published on 09.21.72, the function of the auxiliary arc current short-circuiter is made by a Zener diode. This solution, although simpler than the previous one, is not, either, immune to energy dissipation which makes it even less efficient in yield than the previous one.

 The invention aims to create a device for feeding pulsed decilarge tubes provided with a current short-circuiting of the auxiliary arc of the pulse discharge tube making it possible to increase the efficiency of the device.

 The solution consists of a device for supplying pulsed discharge tubes comprising a pulse generator with a supply circuit and the output of which is connected to a pulsed discharge tube, a circuit comprising a source of ali - indentation of the auxiliary arc of the pulse discharge tube and a serine inductor, connected in parallel to said pulse generator by a diode, and a current short-circuiter of the auxiliary arc during the pulses from the generator of pulses, placed in parallel on said assembly; according to the invention the auxiliary arc current short-circuit contains, in series, a voltage source and a valve.

 It is reasonable that the power supply device uses the supply circuit as a voltage source.

mentation of the pulse generator.

 It is also reasonable that in the supply device the valve function is performed by a thyristor, the trigger of which receives pulses in synchronism with the pulses produced by the pulse generator.

 It is useful for the power supply device to include a current sensor circulating in the pulse generator - discharge tube circuit, electrically connected to the trigger of the thyristor.

 It is advantageous that the power supply device contains a radiation sensor of the pulse discharge tube, electrically connected to the trigger of the thyristor.

 The device for supplying pulsed discharge tubes according to the invention enjoys a good performance because the short-circuiting of the current of the auxiliary arc by the voltage source does not produce energy dissipation. It should also be noted that the presence of a thyristor ensures safe operation of the device, even when the amplitude of the pulses produced by the pulse generator is largely variable, which is essential when the discharge tubes at power supply have substantially different characteristics, notably internal resistance.

 Being able to use the supply circuit of the pulse generator as a voltage source simplifies the device.

In what follows, the invention will be explained at the heart of the description of some particular embodiments thereof, made with reference to the appended drawings in which:
Figure 1 shows the block diagram of a device for supplying pulsed discharge tubes according to the invention;
Figure 2, id. that in the figure with a supply circuit of the pulse generator as a voltage source according to the invention;
Figure 3, id. than in FIG. 1, with a thyristor controlled by a pulse generator according to the invention ;;
Figure 4, id. that in Figure 3 with a thyristor control circuit from a current sensor according to the invention;
Figure 5, id. than in Figure 3 with a thyristor control circuit from a radiation sensor of the discharge tube according to the invention.

 The device for supplying pulsed discharge tubes comprises a pulse generator 1 (FIG. 1) with supply circuit 2, in this case a direct current circuit. The output of generator 1 is connected to a pulse discharge tube 3. The pulse generator 1 is connected by a diode 4 in parallel to a circuit comprising a source 5 for supplying the auxiliary arc of the discharge tube by pulses and a self 6 in series.

 I1 is good that the role of power source 5 is filled by a source whose characteristic is similar to that of the current source. : However source 5 can be a voltage source with a certain internal resistance.

 The device also contains a short circuit 7 for the auxiliary arc current during the pulses emitted by the pulse generator placed in parallel on the circuit comprising the power source 5 and the inductor 6 in series. The short-circuiter 7 comprises, connected in series with a voltage source 8 and a valve 9, in what follows the diode 9. The voltage of the source 8 exceeds that of the tube 3 under the auxiliary arc regime.

 According to the considered embodiment of the device, the pulse generator 1, the source 5 for supplying the auxiliary aro and the voltage source 8 have their positives joined together. Diode 4, like diode 9, has its cathode connected to inductor 6.

 The device for supplying pulsed discharge tubes according to the invention can exist in a second particular embodiment, similar to the previous except that the voltage source function 8 is performed by the generator supply circuit 2 of pulses l, which simplifies the device $ figure 2).

 The device for supplying pulsed discharge tubes can exist under a third particular embodiment standard, analogous to the first particular embodiment which has just been described except for the difference that the arc current short-circuiter 7 auxiliary uses as a valve a thyristor 10 (figure 3) whose cathode is connected to the inductor 6.

 The trigger of the thyristor 10 receives the pulses simultaneously with the pulses coming from the generator 1, the trigger of the thyristor 10 being connected to the respective output of the generator 1.

 I1 should also be noted that in this case the diode 4 is connected by its anode to the positive of the power source 5 of the auxiliary arc.

 The device for feeding pulsed discharge tubes can exist in a fourth particular embodiment, analogous to the third particular embodiment described above, except that the trigger of the thyristor 10 is in electrical connection. with a current sensor 11 (FIG. 4) circulating in the pulse generator circuit 1 - discharge tube 3. It should also be noted that in this particular embodiment of the invention the diode 4 has its cathode connected to the negative of the auxiliary arc power source 5, the inductor 6 being placed between the positive of the power source 5 and a point common to the positives of the pulse generator 1 and the voltage source 8.

The device for feeding pulsed discharge tubes can exist in a fifth form of
particular embodiment, similar to the third particular embodiment, except that the trigger of the thyristor 10 is electrically connected to a sensor 12 of radiation of the pulse discharge tube (Figure 5), in particular to a light sensor. It should also be noted that diode 4 has its anode connected to inductor 6.

-The device for feeding pulsed discharge tubes works as follows:
When the device is started up, a voltage appears at the output of the source 5 of the auxiliary arc (FIG. 1). It is applied by the inductor 6 to the cathode of the diode 9. The anode of the diode 9 is at this time brought to the voltage of the source 8. When the voltage at the output of the source S passes above that of the source 8, diode 9 goes into conduction. The effect is the rise of current in the power source circuit 5- self 6 - diode 9 - voltage source 8 - power source 5. This current is established at a level determined by the power source 5. At the instant of priming of the tube 3 by a high voltage and low power pulse, emitted by a priming block forming part of the pulse generator 1, the tube 3 becomes conductive and its voltage goes below that of the source 8. In this case the iodine 4, turned on, conducts the current from the inductor 6 to the tube 3 to keep it in conductive state. The ignition voltage of the tube 3 being lower than the voltage of the source 8, the diode 9 stops driving.

 On application to the tube 3 of a powerful discharge pulse by the generator 1 the voltage drop in that increases. The voltage on the cathode of the diode 4 increases, too, by the effect of the energy stored by the inductor 6 and that of the power source 5. However at the moment when this voltage exceeds the voltage from source 8 diode 9 enters into conduction and Current from inductor 6 closes through diode 9 and voltage source 8. Diode 4, reverse biased, goes out.

 At the instant when the discharge pulse ends the voltage on the tube 3 decot. When it falls below that of the source 8 the diode 4 becomes on and the diode 9 cuts; the current from inductor 6 then flows through the tuhe 3 to maintain it in the conducting state.

 In this way, until the appearance of a new powerful pulse produced by the generator L, the tube 3 is passing due to the presence of an auxiliary arc which makes it unnecessary to multiple re-ignition of the tube 3 by a high voltage pulse. and low power.

 As is apparent from the description of the operation of the device, it is designed so as to dissipate only little energy, hence its excellent efficiency.

 In the particular embodiment of the invention shown in Figure 2, the behavior of the device is similar to the previous one.

 The operation of the device in its particular embodiments, shown in FIGS. 3, 4 and 5, is similar, with a few details, to the previous one.

 The difference consists in the fact that after the end of the powerful pulse coming from the generator 1 the resistance of the tube 3 (figures 3,4 and 5) increases for a certain time by persistent effects of a temperature and a pressure of gases raised by the action of the impulse on the tube 3. The growth of the resistance increases the voltage cost in the tube 3 produced by the current of the auxiliary arc. This drop in voltage can sometimes (by example with gas pressure tubes) exceed the voltage of the source 8 which carries the risk that the current of the auxiliary arc can flow through the thyristor circuit 10 - source 8 instead of that of the tube 3 as is necessary to keep it in conduction and that, consequently, the tube 3 can go out.

 The application of thyristor 10 makes it possible to combat this drawback. When the powerful pulse from the generator 1 disappears, the thyristor 10 switches off and the current from the auxiliary arc flows through the circuit of the tube 3 to prevent it from being extinguished.

so that the thyristor 10 is conductive during the powerful pulse from the generator 1, its trigger receives, in synchronism with the pulses of the generator, pulses produced either by the generator 1 itself (FIG. 3), or by the sensor of current 11 (Figure 4), or by the radiation sensor of the tube 12 (Figure 5). in conduction, the thyristor 10 behaves e diode 9; also after the priming of the thyristor 10 the operation of the device operates in a similar fashion to that described above
The sensors 11 and 12 allow the circuits to be electrically decoupled and the margin of noise to be extended when the thyristor 10 starts.

Claims (5)

 1. device for feeding pulsed discharge tubes comprising a pulse generator (1) with a supply circuit (2) and the output of which is connected to a pulsed discharge tube (3), an assembly , comprising a source (5) for supplying the auxiliary ar @ of the tu @ e with pulsed discharge and a choke (6) in series, connected in parallel by one. diode (4) to said pulse generator (1), and a short circuit (7) of current that the auxiliary arc during the pulses produced by the pulse generator, placed in parallel @ le on said nontabe, caract 6 due to the fact that the short circuit (7) of the auxiliary ar @ contains, in series, a voltage source (8) and a valve (9).  2. Device for power supply according to claim 1, characterized in that the power source function (8) is fulfilled by the power supply circuit (2) of the pulse generator (1) .  3. Device for power supply according to claims 1 and 2, characterized by the fact that the valve function (9) is performed by a thyristor (10) the trigger of which receives pulses in synchronism with the pulses produced by the pulse generator (1).  4. A device for power supply according to claim 3, characterized in that it incorporates a sensor (11) of current flowing in the pulse generator circuit (1) - discharge tube (3), electrically connected to the trigger thyristor (10).  5. Device for power supply according to claim 3, which is due to the fact that it contains a radiation sensor (12) to the pulse discharge tube, electrically connected to the trigger of the thyristor (10).