DE1205197B - Arrangement for controlling the ignition circuit of electrical discharge vessels with the aid of a switching diode - Google Patents

Description

Arrangement for controlling the ignition circuit of electrical discharge vessels with the help of a switching diode. Addition to registration: W 22627 VIII c / 21 g - Auslegeschrift 1161645 The invention relates to an arrangement for starring the ignition circuit electrical evacuation vessel, in which a memory is used to deliver the ignition rome5 electrical energy is used and the ignition by an electronic in the ignition circuit Switch is controlled.

It is, for example, be4apnt that stored in a condensate test Energy via a thyratron aitf the ignition path of an electrical discharge device, z. B. an Ignitron to switch.

In the past, capacitance thyratron ignition circuits have been used for the excitation of the electrical discharge devices, such as B. Ignitron rectifiers, been used.

J circuits of this type were desired primarily because these types of Circuits are easy to calculate in order to predict circuit properties to reach. These circuits were also desirable because of the wide range the phase control and the high response speed, due to the low Time constant, which is her own. Difficulty finding the application of this Circuit are the high initial costs, since each pin. special Ignition circuit is required for each detonator, and that the L5ppensurance of the thyratron tubes is limited, which results in high folding costs.

Nasty difficulties were overcome in large part by firing circuits with non-, Prosseln which have the advantage that they are able to ignite two diametrically opposed igniter with a circuit so that di in this way; e first costs are reduced, and the further advantage to be a static network with drawn life characteristics inherent in transformer equipment. However, there are problems with the application of this circuit with regard to its design with properties to be sawed, with regard to the limitation of the available phase control range and higher time constants, combined with a resulting low rate of change in the phase control.

It is an object of the present invention to provide an integrated ignition circuit for electrical discharge vessels.

It is another object of the invention to provide an improved ignition circuit to be provided for electrical discharge devices, which have the disadvantages of the short duration of the discharge while taking advantage of your wide phase control range and a Maintains high response speed. The control arrangement according to the invention of the ignition circuit of electrical discharge vessels for supplying the ignition current a store of electrical energy is used and ignition by one in the ignition circuit lying electronic switch is controlled, is characterized in that as an electronic switch a switching diode according to patent application W 22627 VIII c / 21 g (German Auslegeschrift 1161645) is provided, which in the ignition circuit so is switched on that, as soon as their reverse voltage is exceeded, the energy storage discharges via the switching diode in the reverse direction.

The F i g. 1 shows an exemplary circuit diagram of a circuit according to the invention Ignition circuit for electric discharge vessels; F i g. Fig. 2 is a graph the curve shape of at selected points in the arrangement according to FIG. 1 existing Tensions; F i. G. 3 is also a graph of the waveforms of at selected points in a circuit according to FIG. 1 resulting stresses; F. i g. Fig. 4 is a graph showing the characteristics of a switching diode such as this in the device according to FIG. 1 is used; F i g. 5 a is a schematic representation a second exemplary embodiment of the invention; F i g. 5 is a graphic Representation of the curve shapes of voltages, which at selected points of a in Fig. 5 a illustrated device occur; F i g. 6 is a schematic Representation of a third exemplary embodiment according to the invention; F i g. 7 is a graphical representation of the waveform of voltages applied to selected Points of a circuit according to FIG. 6 are present; F i g. 8 is a schematic Representation of a fourth exemplary embodiment according to the invention; F i g. 8 a is a schematic representation of an optional arrangement for a part of the in FIG. 8; F i g. 8b is a schematic representation another optional in the device of FIG. 8 usable arrangement.

In Fig. 1 is an ignition circuit for an electrical discharge vessel illustrated. In general, the one in FIG. 1 an illustrated arrangement Ignitron rectifier 10, an energy storage circuit 30, a switching diode 40 with negative resistance characteristic according to the main patent and a trip circuit 80 for the aforementioned switching diode 40.

The advent of a switching diode, which has the property that it when a certain reverse current or a certain reverse voltage is exceeded becomes highly conductive in the reverse direction and then a considerable reverse current at low voltage has led to many new electronic applications. The phenomenon described above is neither a zener breakdown nor an avalanche breakdown. The unique breakdown characteristic of this switching diode can be unlimited be repeated. This breakthrough is known as a "hyperconductive breakthrough" has been, and a diode having such properties will therefore be described in the following be referred to as semiconducting switching diode or hyperconductive diode.

Such a switching diode is the subject of patent application W 22627 VIII c / 21 g (German Auslegeschrift 1161645). With regard to a more detailed explanation of the construction, the properties and the mode of operation of such a switching diode, reference is therefore made to patent application W 22627 VIII c / 21 g (German Auslegeschrift 1161 645).

Such a switching diode with a controllable breakdown characteristic in the reverse bias contains a first zone made of semiconductor material, the is doped with an impurity to provide a first type of semiconductor capability, d. H. to represent either the n- or the p-type. Located on this first zone an outer zone, which consists of a semiconductor material, which with the opposite type of semiconductor capability is doped. This outer zone can by alloying a pill containing a dopant with a plate made of semiconductor material which forms the first zone. Between there is a pn junction in the two zones. To turn on the diode in To facilitate an electrical circuit, a layer of silver or can be used another highly electrically conductive metal on the upper surface of the outer Zone be melted, soldered or alloyed. A lead copper wire can then easily be soldered to this position.

A second outer zone of opposite electrical conductivity is provided on the other surface side of the first zone. Between these there is a second pn junction in both zones.

Subsequent to the last-named outer zone is a metal mass present, which is a source of charge carriers that plays a crucial role in how the diode works. This metal mass can be neutral, or they can have the same doping properties as the second outer zone. The metal mass can be applied to the second outer zone by soldering, alloying, melting or in one applied in a similar manner.

The circuit symbol for such a switching diode is shown in FIG. 1 denoted by 40. The characteristic in FIG. 4 shows how the switching diode responds to the application of different voltages. If the upper right-hand part or the forward quadrant is considered, if a voltage of the order of magnitude of 1 volt was applied in the forward direction, a current of about 3 amps results. When the voltage was reversed it rose in the reverse direction to approximately 55 volts with only a small fraction of an ampere current flowing. Then the diode suddenly became highly conductive and the voltage dropped to about 1 volt as shown in the lower left quadrant. The diode becomes a conductor with a low ohmic resistance, and the current strength increases rapidly up to several amperes.

As can be seen from the characteristic curve in the blocking range, the voltage drops after the breakdown on a nearly straight line down to about 1 volt, and it is thus in maintaining the hyperconductivity state of the diode consumes very little power. The diode can go back to its high state Resistance can be returned by reducing the current strength below one Minimum threshold while the voltage is below the breakdown value. Thus, if desired, the curve can be repeatedly traversed by a suitable control of the magnitude of the reverse current and reverse voltage.

According to FIG. 1, the energy storage circuit 30 includes a transformer 20, which has a primary winding 21, which via a rectifier 23 to a Capacity 31 is connected. The capacitance 31 is connected to the igniter-cathode control path 11-12 of the Ignitron 10 via the series connection of the inductance 32, a rectifier 33 and the switching diode 40 connected.

The trip circuit 80 contains a transformer 60, which has a secondary winding 61 which is connected to the switching diode 40 via the series connection of the rectifier 62, an output winding 52 of the magnetic amplifier 50 and a current limiting resistor 63. The magnetic amplifier 50 contains a saturable core 51 on which the output winding 52 and a control winding 53 are inductively linked. The control winding 53 is connected through a potentiometer 70 to a DC bias voltage source, not shown, and which is connected to the terminals 71 and 72.

The operation of the in F i g. The device illustrated in FIG. 1 is as follows: According to FIG. 2 charges the voltage Ei at the primary winding 21 of the transformer 20, the capacitance 31 via the rectifier 23. When the voltage E2 at the capacitance 31 is equal to the charging voltage Ei, the charging current Il stops flowing and the capacitance 31 is fully charged. The ignition circuit is designed in such a way that the voltage E2 at the capacitance 31 is significantly lower than the breakdown voltage of the switching diode 40 . The capacitance 30 is therefore blocked against discharge by the rectifier 23 and the switching diode 40 and retains its charge until these states are modified. In the tripping circuit 80, a voltage source E3, which is supplied by the secondary winding 61 of the transformer 60, is applied to the switching diode 40 via the rectifier 62, the output winding 52 of the magnetic amplifier 50 and the current limiting impedance 63. The control winding 53 of the magnetic amplifier 50 is applied to a direct current bias voltage source which is to be connected to the terminals 71 and 72 and which at the same time may be common to a number of other ignitron ignition circuits which, however, are not shown. In Fig. 3 it can be seen that the voltage ES is initially taken over by the output winding 52 of the magnetic amplifier 50, as shown in FIG. 3 is represented by the voltage E4 until the magnetic amplifier becomes saturated. The time cycle in which the saturation occurs can be controlled by the DC bias and changed as desired either by manual control or electrical means, such as are e.g. B. are known in magnetic amplifier technology. For purposes of illustration, potentiometer 70 is used.

When the magnetic amplifier 50 saturates, the voltage source ES appears at the impedance 63 as voltage E5 and at the switching diode 40 as voltage E6. Initially, the resistance of the switching diode 40 is very high, so that the voltage drop across the diode makes up most of this voltage. The magnitude of the initial voltage E i is such that it is greater than the critical voltage of the switching diode 40 by a sufficient amount to ensure that the switching diode 40 breaks down in this way. Once the diode 40 has broken down, the resistance of the switching diode has become very low, and the main component of the power source voltage ES now appears at the impedance 63 as the voltage E5, and the impedance 63 limits the flow of current.

With the resistance of the switching diode 40 now reduced, the capacitance 31 can discharge via the igniter 11 of the ignitron 10 and in this way cause the ignitron 10 to ignite.

A number of different triggering means can be used to control the switching diode 40. Such devices, such as pulse generators with a rectangular waveform, tip transformers, or sine wave transformers, can supply a pulse or a trip voltage to the switching diode 40 and in this way cause the diode to breakdown. Either mechanical or electrical means can be provided to vary the time-dependent tripping of the diode in the duty cycle.

In Fig. 5 a shows a second embodiment which an energy storage circuit 130, a switching diode 140, a trigger circuit 180 and an electrical discharge vessel 150, which is used here as an ignitron rectifier is illustrated.

The energy storage circuit 130 contains a transformer 120 which has a secondary winding 122 which is connected in series with a rectifier 123 and a capacitor or another energy storage device 131. An energy source, which is not shown, is intended to be connected to the primary winding 121 of the transformer 120. The capacitance 131 is connected to the igniter-cathode path 151-152 of the ignitrone 150 via a reactance 132 and the emitter-collector path 141-142 of the switching diode 140.

The trip circuit 180 includes a square wave generator 160 and a transformer 170 which has a primary winding 171 and secondary windings 172 and 173. The generator feeds the primary winding 171 of the transformer 170. The secondary winding 172 is connected to the electrodes 141 and 142 of the switching diode 140 via the series-connected rectifier 174 and a current limiting impedance 181. The second secondary winding 173 of the transformer 170 can be connected in a similar manner to initiate an ignition circuit for another ignitron.

In Fig. 5 illustrates the output voltage E7 at the square wave generator 160 as it appears at the primary winding 171 of the transformer 170. Because of the rectifying action of the rectifiers 174 and 175, the voltages E $ and E9 appear on the secondary windings 172 and 173 , as in FIG. 5 illustrates. The energy storage circuit 130 operates in a manner similar to the energy storage circuit shown in FIG. 1 and charges the capacitor 131 to the desired level. In the one shown in FIG. 5 a illustrated device, the switching diode 140 is controlled by the output voltage ES of the secondary winding 172 in successive alternating voltage half-waves into its state of high conductivity and reverse direction. When the breakdown of the switching diode occurs, the capacitance 131 discharges via the choke 132 and the switching diode 140 to the igniter 151 of the ignitrone 150 and in this way brings about an ignition of the ignitrone 150.

The secondary winding 173 of the transformer 180 can thus be connected be that they have a different switching diode in the ignition circuit of another discharge tube triggers, but such tripping occurs in a diametrically opposite one Phase is going on.

In Fig. 6, a third embodiment of the invention is illustrated which, viewed generally, includes an energy storage circuit 230, a switching diode 240, a pair of ignitrons 250 and 260, and a trigger circuit 280.

A secondary winding 222 of the transformer 220 is connected to a capacitance 231 via a choke 232 . An energy source, which is not shown, is intended to be applied to the primary winding 221 of the transformer 220. The capacitance 231 is connected in series with the linear choke 233, a rectifier 236, an igniter 251 and a cathode 252 of the ignitron 250, the switching diode 240 and a rectifier 238. The capacitance 231 is also connected in series with a rectifier 239, an igniter 261 and a cathode 262 of the second ignitron 260, the switching diode 240, and the choke 233.

The trip circuit 280 includes a full wave rectifier 270 Center tap, the output of which is via an output winding 293 of a magnetic amplifier 290 and a current limiting impedance 295 is connected to the switching diode 240. -The magnetic amplifier 290 includes a saturable core 291 on which A control winding 292 and the output winding 293 are arranged inductively coupled are. One source of bias, which is not specifically shown, is to the control winding 292 connected.

During operation, the supply voltage, which is connected to the primary winding 221, charges the capacitance 231 via the transformer 220 and the choke 232. The charging voltage .der -Capacitance 231 is continuously applied to the linear choke 233, which can have an iron core or air core, the rectifier 236, the igniter 251 and the cathode 252 of the igniter 250, the switching diode 240 and the rectifier 238. The value of the The voltage across the capacitance 231 does not exceed that of the critical breakdown voltage of the switching diode 240. The trip circuit operates in the same way as that in FIG. 1 illustrated trip circuit to apply a breakdown voltage to the switching diode 240 .

In Fig. 7 the corresponding curve shapes are illustrated. The tension El. is the output voltage of operating in a center tap connection full-wave rectifier 270. The voltage Eil is the voltage drop across the output winding 293 of the magnetic amplifier 290 may be that changes by the magnitude of the bias voltage which is applied to the control winding 292nd The voltage Eia is the voltage which is required to bring about the breakdown of the switching diode 240 , while the voltage El. illustrates the voltage drop across the current limiting impedance 295 during and after the breakdown of the switching diode 240. If full-wave DC voltage is used for tripping, the magnetic amplifier 290 returns the voltage at the switching diode 240 to zero and in this way allows the switching diode 240 to be reset.

The trip circuit 280 triggers the switching diode 240 at the desired time during the period off and that caused by the spontaneous drop in resistance the switching diode 240 the capacitance 231 itself via the choke 233, the rectifier 236, the igniter 251, the cathode 252, the switching diode 240 i and the pond rectifier 238 can discharge. -In - the following half-wave results in a similar way a discharge path via rectifier 239, igniter 261 and cathode 262 of the Ignitron 260, the switching diode 240, the rectifier 237 and the choke 233.

In Fig. 8 illustrates a fourth embodiment of the invention. Generally speaking, it includes an energy storage circuit 339, switching diodes 340 and 342, a trip circuit 80, and ignitrons 360 and 370. The energy storage circuit 330 is identical to that in FIG. 6 and also operates in the same manner. The capacitance 331 of the energy storage circuit 330 is connected to a choke 333, a connection terminal 382, a parallel connection of a switching diode 340 and a rectifier 341, a parallel connection of the switching diode 342 and a rectifier 343, your terminal 383 and a primary winding 351 of a transformer 35Q in A, one line switched. A trip circuit arrangement 3 $ 0 is connected to terminals 382 and 383 via the current limiting impedance 3.81 .

The transformer 350 has a secondary winding 352 which is connected in series with a rectifier 354, the igniter 361 and the cathode 362 of the ignitrone 360. The other secondary winding 353 of the transformer 350 -is connected in series with a rectifier 355 and the igniter-cathode path 371-372 of the -Ignitron 370.

The trip circuit 380 can operate according to one of the various methods described above in order to bring about the breakdown of the switching diodes 340 and 342 in the reverse direction. The voltage at the capacitance 331 has a discharge path in one half cycle via the choke 333, the switching diode 340 in the reverse direction, the rectifier 343 and the primary winding 351 of the transformer 350. In the next half cycle, the capacitance 331 is via the primary winding 351 of the transformer 350, the switching diode 342 in the reverse direction, the rectifier 341 and the inductor 333 are discharged. The length of time in each half-cycle during which the switching diodes 340 and 342 are conductive in their blocking direction is of course dependent on the point in time at which the tripping circuit 380 brings about the breakdown of the respective switching diode. In each half-cycle, the discharge via the primary winding 351 will induce a voltage in the secondary winding 352, which causes a current to flow via the rectifier 354 to the igniter 361 and ignites the ignitron 360. During this half cycle, the rectifier 355 will block ignition of the Ignitron 370. In the next half-wave, the discharge through the primary winding 351 will induce a voltage of opposite polarity in the secondary winding 353 and in this way cause a current to flow through the rectifier 355 to the igniter 371, so that the ignitron 370 ignites. During this half-wave the rectifier 354 will block the ignition of the Ignitron 360.

The use of the usual rectifiers 341 and 343 will only be necessary depending on the magnitudes that the forward voltage drop in the flow direction of the switching diodes 340 and 342 brings with it. This means that if this forward voltage drop of the switching diodes 340 and 342 is very small, the switching diodes 340 and 342 can also be arranged directly in opposition to one another, as shown in FIG. -8 a is illustrated, which also allows satisfactory operation. If .the forward voltage drop of the switching diodes 342 and 343 is very high, then the -in F i g. 8b illustrated anti-parallel arrangement can be applied. If, in the described and illustrated exemplary embodiments, the voltage and current properties of the ignitrons used cannot be reconciled with the nominal values that can be achieved for the switching diodes, then igniter coupling transformers, as shown in FIG. 8 can be applied. Such squib coupling transformers can also be used in any of the other circuits shown in FIGS. 1, 5 a and 6 are illustrated, can be used to ensure the necessary current or voltage transformation.

The description of the various embodiments of the invention has shown the advantages listed, which are achieved by the invention can be. In addition, in FIGS. 6 and 8 pointed out that with the switching diodes a linear choke 333 instead of the more expensive phase-shifting chokes or the throttle network can be used to control the phase shift, which results in a significant reduction in the time constant of the ignition circuit.

Claims (7)

Claims: 1. Arrangement for controlling the ignition circuit electrical Discharge vessels in which an electrical storage device is used to supply the ignition current Energy is used and the ignition by an electronic located in the ignition circuit Switch is controlled, characterized in that the electronic switch a switching diode according to patent application W 22627 VIII c / 21 g (German Auslegeschrift 1161645), which is switched on in the ignition circuit so that, as soon as its reverse voltage is exceeded, the energy storage device via the switching diode in the reverse direction discharges. 2. Arrangement according to claim 1, characterized in that as a memory electrical energy a capacitor (31, 231, 331) is used. 3. Arrangement according to Claims 1 and 2, characterized in that a throttle (32) in the ignition circuit is switched on, which gives the ignition current pulse a certain desired curve shape and duration imposes. 4. Arrangement according to claim 1 or one of the following, characterized in that the switching diode is controlled time-dependent in each period of the alternating current via a direct-current bias saturable choke (50) according to a voltage-time integral taken over by this on passage. 5. Arrangement according to claim 1 or one of the following, characterized in that the switching diode by means of a pulse voltage source of rectangular voltage waveform is controlled on passage. 6. Arrangement according to claim 1 or one of the claims 2 to 4, characterized in that the switching diode by means of a pulse transformer Sharp output voltage or a sine wave transformer controlled to pass will. 7. Arrangement according to claim 1 or one of the following, characterized in that the ignition circuits of two discharge vessels (250, 260) working in opposite phase in the converter via the same switching diode (240) connected to their electrically interconnected cathodes in the course of a period of Alternating current can be controlled alternately by controlling the switching diode once in each half cycle of the alternating voltage to be open and the ignition circuits are fed via a switch system of electrical valves (FIG. 6). B. Arrangement according to claim 7, characterized in that the switching diode lies with its control path in a circuit with a direct current biased saturation choke which is fed by a full-wave rectifier. 9. Arrangement according to claim 1 or one of claims 1 to 6, characterized in that for two discharge vessels (360, 370) of the converter working in opposite phase, the one for each of the half-wave alternating current permeable electrical valve (354, 355) containing The ignition circuit of each individual discharge vessel is fed via a secondary winding (352, 353) of a transformer (350) , the primary winding (351) of which is fed by the energy storage circuit via a controllable semiconductor arrangement which is fed by a control voltage or control current source for each current direction from the energy storage circuit Contains switching diode (340, 342) which can be forward-controlled (FIG. 8). 10. Ignition circuit according to claim 9, characterized in that the primary winding of the transformer via the series connection of two oppositely polarized parallel connections each consisting of a normal diode (341, 343) and a switching diode (340, 342) is fed (Fig. 8). 11. Ignition circuit according to claim 9, characterized in that two switching diodes are used in opposing series connection and are alternately controlled to pass, in each case in the control of one switching diode, the conductivity given on the other switching diode is used for the current conduction (F i g 8 a). 12. Ignition circuit according to claim 9, characterized in that two switching diodes with a relatively high resistance in the forward direction in anti-parallel connection as a controllable semiconductor arrangement in the primary circuit of the ignition transformer (350) are used (FIG. 8 b). Considered publications: German Patent Nos. 943 785, 919 303; Belgian Patent No. 548 745; U.S. Patent No. 2,637,770; "Transactions of the American Institute of Electrical Engineers", Vol. 74, Part 1, 1955, pp. 111 to 121. Earlier patents considered: German Patents No. 1061 829, 1061830.