DE3601451A1 - Self turning-off invertor - Google Patents

Abstract

The invention relates to a self turning-off invertor using a neutral or bridge circuit having valves which can be controlled by a control circuit, in reverse parallel with which there is connected in each case one diode. The invention is intended to create an invertor which turns itself off and in the case of which it is ensured at a relatively low cost and nevertheless with high reliability (safety) that the turning-on of a push-pull branch or of a bridge diagonal in each case takes place at the earliest when the hold-off interval (which is necessary for reaching the blocking capability of the opposing side) has with certainty elapsed. This is achieved according to the invention in that at least two valves, which are controlled in a push-pull manner, have allocated to them in each case one circuit arrangement which evaluates the voltage between the anode and cathode of the controllable valve, especially with respect to its polarity, and produces a corresponding binary signal, the input of which circuit arrangement is respectively connected to the cathode and the anode, and its output operates on the control circuit.

Description

Self-extinguishing inverter

The invention relates to a self-extinguishing inverter in the center or bridge circuit with valves controllable by a control circuit, which one diode is connected in antiparallel to each other. or bridge circuit arranged controllable valves with self-extinguishing work are well known. As a means of erasing the controllable valves Usually either the controllable valves are used in parallel Series oscillating circuits. which are to be dimensioned accordingly and symmetrically or the capacitive series-compensated load with an inductive component caused by a series inductance can be supplemented.

With inverters of this type, it is extremely important that the triggering of a push-pull branch or a bridge diagonal takes place at the earliest when the free time necessary to achieve the blocking capability of the opposite side has definitely expired. This requirement is met in a known inverter circuit in that a process-dependent controlled switching frequency is used which must not exceed a maximum value below the resonance frequency of the series resonant circuit implemented by the series-compensated load , that is, when the inverter is controlled with an impermissibly high switching frequency, the thyristors are at high risk due to short-circuit control Blocking ability to switch back to the forward-conducting state when only a small part of the thyristor tablet is then available for the power line -OS 26 04 260). The load current curve is recorded with the aid of a current converter or transformer that is switched into the load circuit. A control circuit ensures that the two control signals change their state only after a period of time that is at least as long as the switch-off time of the switch with the longest switch-off time, after the change in direction of the current through the load has occurred The transmission of the useful signal also means that disturbances are passed on to the control circuit, which leads to problems with regard to interference-free functioning, especially with higher power consumption. Furthermore, this principle can only be used for inverter circuits that work with the series-compensated load as a means of self-extinguishing.

The invention is based on the object of an inverter To create the type mentioned at the beginning, in which with relatively little effort and yet great security is guaranteed that the ignition of the controllable Valves of a push-pull branch or the controllable valves of a bridge diagonal takes place at the earliest when the to achieve the blocking ability of the Opposite side the necessary free time has certainly expired, that is, a The controllable valves are largely endangered by controlling for a short circuit is avoided.

This object is achieved according to the invention by the features specified in the characterizing part of claim 1, Particularly advantageous embodiments of the invention are the subject matter of claims 2 to 5.

The invention is intended below by means of an example and an associated one Drawing will be explained in more detail. The drawing shows: FIG. 1: the one according to the invention Connection of two push-pull controlled thyristors of a self-extinguishing change richters in the block diagram, Fig, 2: in a diagram the principle time Voltage curve between the anode and cathode of a thyristor-diode pair connected in anti-parallel of the inverter, Fig. 3: a particularly favorable embodiment of the voltage between anode and cathode of the respectively push-pull controlled thyristors in particular circuit arrangement evaluating their polarity.

Fig. 4: and further embodiments Fig. 5: Fig. 6: the basic circuit an inverter in mid-point connection with quenching circuits assigned to the thyristors, Fig. 7: the basic circuit of an inverter in a bridge circuit with the thyristors associated quenching circuits Fig. 8: The basic circuit of an inverter in a bridge circuit with series-compensated load for self-extinguishing and Fig, 9: the basic circuit of an inverter in a bridge circuit with self-extinguishing by means of a series resonant circuit connected in parallel to the load.

According to FIG. 1, a first thyristor 1, which is connected in anti-parallel with a diode 2, is a circuit arrangement 3 and a second thyristor 4 to which a diode 5 is connected in anti-parallel. a circuit arrangement 6 is assigned. The two thyristors 1, 4, each connected to a diode, are part of a self-extinguishing inverter and are controlled in push-pull mode by a control circuit 7 via their control electrodes.

In detail, the cathode of the thyristor 1 has a connection point 8 and the anode of the same thyristor 1 connected to a connection point 9 to which if separate quenching circuits are used for the thyristors, one quenching circuit, for example consisting of a series connection of a capacitor and an inductance, is switched (see, Fig. 6 and 7), the thyristor 4 is also connected via connection points 10, 11 wired with such a quenching circuit4 While also the anode of the thyristor 1 to a connection point 12 and the anode of the thyristor 4 to a connection point 13 is performed, the cathodes of both thyristors 1, 4 are connected to one another and are at a connection point 26. The circuit arrangement 3 is on the input side a connection point 14 to the cathode of the thyristor 1 and via a connection point 15 to the anode of this thyristor 1 and on the output side via a connection point 18 connected to the control circuit 7. The circuit arrangement 6 is also on the input side Via a connection point 16 to the cathode of the thyristor 4 and weber a connection point 17 connected to the anode of the same thyristor 4.

On the output side, the circuit arrangement 6 operates via a connection point 19 likewise to the control circuit 7, which in turn has connection points at the output 20 to 24.

The control electrodes of the thyristors are connected via the connection points 20 and 22 1 and 4 in push-pull either directly or electrically isolated with ignition pulses, While with an inverter in mid-point connection (Fig. 6) the other two Connection points 21 and 23 are not required, each of these connection points is 21 or 23 in the case of an inverter in a bridge circuit (Fig. 7 to 9) with the Control electrode connected to another thyristor. In this case the thyristors are paired applied in push-pull with Zürdimpulses. At connection point 24 the control circuit becomes 7 via a further connection point 25 with the connection point 26 and thus with the Cathode potential of thyristors 1 and 4 connected.

With the circuit arrangements 3 and with the same polarity on the input side 6 shows the time profile of the voltages U, shown in simplified form in FIG detected and evaluated at the anodes of the thyristors 1 and 4 based on their cathodes.

This curve of the voltages U is in the thyristor-diode pairs 1, 2 or 4.5 out of phase with each other 1800.

The circuit arrangements 3 and 6 evaluate the detected voltage profiles mainly with regard to polarity and give at their outputs 18 and 19, respectively a corresponding binary signal, which is supplied to the control circuit 7 separately will.

As shown in Fig. 2, the voltage U increases during the inverter operation to a value UD which, depending on the circuit, is twice the supply voltage of a thyristor. On the switched current-carrying thyristor, ie from the point in time t1, however, the voltage U is uniformly at a value UFT from + 2.0 ... 2.5 V, the time t1 marks the beginning of the lead phase of the thyristor immediately after it has been triggered, the duration of the conducting phase is determined by the resonance frequency of the respective effective series resonant circuit and extends until time t2. At time t2, the thyristor is through from the quenching circuit forced current flow without current. The current then goes on in the reverse direction the anti-parallel diode across whose forward voltage drop on the thyristor as Reverse voltage acts and its; inert UFD is around -1.7 ... -2.5 V.

The thyristor must now be under the influence of this reverse voltage Have regained blocking ability if the opposite side ignited at time t3 and the anode voltage again approximately sinusoidally in the blocking direction on the value With the recording and evaluation of the voltage curves directly the push-pull operated thyristor-diode pairs 1,2 and 4,5 by the circuit arrangements 3 or 6 and the supply of corresponding binary signals to the control circuit 7, where these signals are appropriately taken into account via logical linking elements, is taken care of, z. through there. Grant the necessary Free time on a thyristor that is no longer carrying forward current Blocking ability is restored and thus this thyristor at the earliest after this minimum time has elapsed, again with blocking voltage by igniting the opposite side is charged. This means that the switching frequency of the inverter can reach its maximum permissible and a too fast firing sequence that endangers the thyristors does not come about.

An advantageous, because not very expensive, embodiment provides that the circuit arrangements 3 and 6 each consist of an input side with a Resistor 311 or 611 and anti-parallel connected diodes 312, 313 or 612, 613 connected operational amplifier 314 or 614 exist, whose output with the Connection point 18 or 19 is connected. The resistor-diode combination 311, 312, 313 or 611, 612, 613 has the task of reducing voltage peaks to a permissible Limit level. The operational amplifier 314 or 316 is used as a comparator Switching hysteresis operated (Fig. 3).

When particularly high requirements are placed on interference immunity » it is favorable, in each case between the circuit arrangement 3 or 6 and the control circuit 7 to switch an optocoupler 27 or 28, whereby the control circuit 7 of the actual inverter circuit is galvanically isolated (Fig. 4), another possible embodiment provides that the Circuit arrangements 3 and 6 are constructed exclusively with passive switching elements by respectively one with its primary winding via a diode 322 or 622 and one connected in parallel therewith Resistor 321 or 621 with the connection points 14, 15 and 16, 17 connected transformer 323 or 623 is provided, the secondary winding with the interposition of a Zene rdiode-diode-wide resistor combination 324, 325, 326 or 624, 625, 626 the optocoupler 27 resp.

28 works. The resistor-diode combination 321, 322 resp.

621, 622 causes a defined weakening of the at the connection points 14, 15 or 16, 17 occurring positive voltage to such a level on the transformer 323 or 623 that this is magnetized approximately symmetrically when the inverter is in action, The circuit elements 321 to 326 and 621 to 626 are so with the associated optocoupler 27 or 28 interconnected that its light emitting diode is active during the blocking phase of the associated thyristor (s), Da the driving voltage for this state in relation to the voltage drop the light emitting diodes and the diodes 322, 622 is relatively small and depends on the specimen Subject to fluctuations »are the upper carriers 323 and 623 for a corresponding upward transformation dimensioned. The Zener diode-diode-resistor combinations 324, 325, 326 and 624, 625, 626 each limit the reverse voltage at the light emitting diodes an allowable value.

The inventive connection of two push-pull controlled thyristors 1, 4 with the circuit arrangement 3 and 6 operating on the control circuit 7 both with self-extinguishing inverters in mid-point connection (Fig, 6) as Can also be used with self-extinguishing inverters in a bridge circuit (Fig. 7 to 9). In the case of the inverters in a bridge circuit, the load current overflows alternately the diagonal branches. The prerequisite for this is that the diagonal branches are in push-pull and the two switching paths of a diagonal branch in unison being controlled.

It is therefore sufficient to use only one switching path for bridge circuits of the diagonal branches to be provided with the circuit arrangement 3 or 6, it being shown in is cheap in any case. select those thyristors whose cathodes are connected to each other are connected and at the negative pole of the supply voltage source designated by 29 in the drawing of the inverter. The inverters shown in FIGS. 7 to 9 in the bridge circuit differ only in the type of extinction of the ThyristDren, While in the inverter according to Figure 7, each thyristor has a separate quenching circuit assigned and a transformer between the connection points 12 and 13 as a load 30 is switched on. the series-compensated one is used in the inverter according to FIG Burden of self-extinguishing. by a series connection between the connection points 12 and 13 consisting of a capacitor 31, an inductor 32 and the load 30 connected With the inverter according to Figure 9, self-extinguishing is achieved by that the series connection of the load consisting of capacitor 31 and inductance 32 30 is connected in parallel.

Claims (1)

Patent claims 1, self-extinguishing inverter in focus- or bridge circuit with valves controllable by a control circuit one diode is connected in anti-parallel in each case. characterized. that at least two push-pull controlled valves (1, 4) one each for the voltage (U) between the anode and cathode of the controllable valve (1, 4), in particular with regard to their polarity evaluating circuit arrangement generating a corresponding binary signal (3rd or, 6) is assigned, the input of which is connected to the cathode and the anode and whose output works on the control circuit (7), 2. self-extinguishing Inverter according to claim 1. characterized in that the circuit arrangements (3, 6) those Push-pull valves (1, 4) are assigned, the cathodes of which have a common The connection point (26) to the power source (29) of the inverter have 4 3. Self-extinguishing Inverter according to Claims 1 and 2, characterized in that the circuit arrangements (3, 6) each contain a comparator (314, 614) whose paired input connections same polarity to a resistor-diode combination (311, 312, 313 or 611, 612, 613) and connected to the cathode and anode of the grounded controllable valves (1 or 4) are connected. 4. Self-extinguishing inverter according to claim 1 and 2, characterized characterized in that the circuit arrangements (3, 6) each have a Clbertrager (323 or 623), its Primary winding via a diode (322 or 622) and a resistor (321 or 621) connected in parallel with the cathode and the anode of the associated controllable valve (1 or 4) is connected and its Secondary winding, if necessary with the interposition of a Zener diode-diode-resistor combination (324, 325, 326 or 624, 625, 626) on the control circuit (7) works 5. Self-extinguishing Inverter according to Claims 1 to 4. characterized in that each arrangement between the circuit (3 or 6) and the control circuit (7) an opto-coupler (27 or 28) switched on is.