DE2014273A1 - Commutation device for converters - Google Patents

Description

WESTINGHOUSE Erlangen, March 2nd. 1370

ELECTRIC CORPORATION - Werner-von-Siemens-Str. 50

Pittsburgh, Pa., USA

VPA 70/8319 C / month Oasis 38 739

Commutation device for converters

The priority of the corresponding patent application in the USA, Serial-No. 813 074, from 3.4.1969 is used.

In addition to rectifying or increasing the direction of Currents and voltages are also generally used as switches that can be tampered with be used in DC or AC circuits.

When feeding a consumer from a "DC voltage source with an interconnected controlled converter this would continuously carry current, regardless of whether there is an ignition voltage on its control electrode or a Ignition necessary current flows. Do you want your electricity in the converter to extinguish in order to reveal the blocking capability of the converter in the forward direction again, so must temporarily the voltage at the converter can be reversed. Such a voltage reversal to block thyristors or other controllable converters becomes a commutation circuit connected to the respective converter. This commutation circuit contains e.g. capacitive and inductive Elements. A voltage is stored in the capacitive elements, the voltage reversal at the anode and cathode of the Converter is placed.

The inductive elements form resonance circuits with the capacitive ones and thus ensure that the voltage on the capacitive element is present at a sufficient level and with the correct polarity is. These arrangements have the disadvantage of using inductive elements in the commutation circuit a relatively high weight, so that they are poorly suited for aircraft and for applications under water.

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You can avoid the inductive elements in the commutation circuit of converters if you have an additional charging circuit for the capacitors used. Such a circuit always contains resistance elements, which lead to unnecessary Loss of energy and thus impair the efficiency of the system. The object of the present invention is the creation of a commutation device according to the The preamble of claim 1, which is lightweight and simple in design, the Zwangskommutierurtg of a DC voltage-fed Converter enables. This problem is solved by one in the characterizing part of claim 1 and in the other claims described device. One embodiment of a commutation device is shown in Pig. 1 shown. Another embodiment is shown by Pig. 3, while Pig. 2 shows a diagram to explain the mode of operation the circuit according to Pig. 1 contains. Pig. 4 shows an application of the commutation device for a three-phase inverter in the bridge circuit and in Fig. 5 is the associated voltage diagram to explain the operation of the circuit according to Pig. 4 shown.

In Pig. 1 shows a circuit for feeding a load from a DC voltage source. Here is the consumer Z, which consists of a resistor R and an inductance L, via two controlled converters Sp1, Sp2 to the positive pole + and the negative pole - a DC voltage source E connected. The controlled converter Sp1 is the series connection of a commutation converter Sd a common commutation capacitor 01 and a diode D1 connected in parallel, while in parallel with the controlled converter Sp2 the commutation converter So2, which is for both Converters Sp1 and Sp2 common commutation capacitor C1 and another diode D2 is connected.

If we now consider the stress diagram according to Pig. 2, it is noted that at a time before time ti, both converters Sp1 and Sp2 are conducting. The curve A in Fig. 2 shows the voltage drop across the converter Sp1. Since this converter is conductive at the time before the point in time ti, only one occurs

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small voltage drop. A similar voltage drop will be adjust themselves to the converter Sp2. The voltage drop across the consumer Z is thus about the same as the voltage of the DC voltage source E. This is shown in curve B. Curve C in Fig. 2 shows the current curve in the consumer Z, the rises steadily in the period under consideration up to the point in time ti. The commutation capacitor C1 is charged in the manner indicated by + and - in FIG. 1, so that its voltage (see curve D in Fig. 2) is also approximately as large as the voltage of the DC voltage source E.

In order to extinguish the current in the converter Sp1 at the time ti to bring, the commutation converter Sd is controlled, so that the commutation capacitor C1 is ütier the diode D1 and the consumer Z can discharge. This is due to the converter Sp1 a voltage acting in the reverse direction, which the current extinguishes in him. Added as seen from consumer Z. the voltage of the commutation capacitor C1 becomes the voltage the .DC voltage source.E. When the capacitor C1 discharges is, the converter Sp1 is loaded again in the forward direction. However, it blocks because it does not receive an ignition pulse. The voltage source E therefore feeds its current via the commutation capacitor C1 into consumer Z into it. The polarity of the voltage on the commutation capacitor 01 is reversed around until this corresponds to one of the voltage of the voltage source E. negative voltage is charged. This state is reached at time t2. This puts the voltage on the consumer Z has become zero, so that due to the inductance L im Consumers Z continues flowing current closes via the diodes DT and D2. Depending on the desired current in the consumer Z After a certain time, the converter Sp1 receives a control pulse again. In Fig. 3 this happens at time t3. The same conditions are then established as before Time ti, with the difference that the ^ commutation capacitor C1 negative - i.e. opposite to that indicated in Fig. 1 Polarity - is charged. The commutation capacitor C1 is thus able to generate a voltage acting in the reverse direction to be applied to the converter Sp2, so that the commutation converter Sc2 is ignited at time t4 in the same way brought the voltage at the consumer Z to zero

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with simultaneous charge reversal of the commutation capacitor C1, until here, too, after a time dependent on the desired current, an ignition pulse is given again to the converter Sp2.

Another switching option for the commutation circuit of a converter in the connecting line between DC voltage source E and consumer Z is shown in FIG. A controllable converter Spo is connected between the consumer Z and the DC voltage source E. A free-wheeling diode Do is located parallel to the consumer Z. A bridge circuit comprising controllable converters Sea, Sea ', Scb and Scb ¹ , in the bridge diagonal of which the commutation capacitor 02 is located, is used for commutation.

Assuming that a current flows through the converter Spo to the consumer Z and that the commutation capacitor 02 is charged to a voltage with the specified polarity, then, by igniting the commutation converters Scb and Scb ¹ , a voltage corresponding to the voltage of the DC voltage source E can be generated to be placed on the converter Spo. In this case, the commutation capacitor 02 is reloaded like the commutation capacitor 01 in FIG. 1. A current then flows through the freewheeling diode Do until the converter Spo is ignited again. The next deletion of the converter Spo takes place by ignition of the commutation converters Sea and Sea ^1, which in turn switch the commutation capacitor 02 with the correct polarity in parallel with the converter Spo.

Such a converter arrangement with a commutation capacitor can also be used for inverter circuits, as shown in FIG. 4 using the example of a three-phase inverter bridge circuit for feeding a consumer with the resistors Za, Zb and Zc for three-phase current is shown. Again is to the poles + and - of the same voltage source E a circuit connected according to the circuit of FIG. The components used here are provided with the same reference numerals. In contrast to FIG. 1, the external connections of the diodes D1 and D2 do not feed the consumer directly, but rather Converters SA1, SA2 controlled via a bridge circuit SB1, SB2, SC1 and SC2. In addition, the connections of the

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(DC voltage source E is connected to another circuit made up of controlled converters, which are switched on here instead of simple reactive current diodes and, like reactive current diodes, have the task of feeding power back from the consumer into the (DC voltage source E * The feedback current converter SA2 «belonging to this bridge circuit , SA1 ¹ , SB2 », SBI ', SC2 ^! And SCI ¹ are therefore each antiparallel to one of the converters in the inverter bridge circuit. The connections Ta, Tb and Td of the resistors Za, Zb, Zc are connected to the alternating voltage connections of the two Bridge circuits are connected from the converters SAl to SC2 and the regenerative converters SAl ¹ to SC2 ^1. By using controllable converters for power feedback, it can be prevented that, for example, when the commutation capacitor Cl to the converter SpI is connected in parallel, a short-circuit current over the converter S, which is currently conducting A1 and the regenerative converter SA2 ^r . For this reason, the regenerative converters SA2 ¹ , SB2 · and SC2 * are blocked when the associated commutation converter Sc1 is conducting. In a corresponding manner, the regenerative converters SAI ^r , SBl ¹ and SGl * are blocked when the commutation * · converter Sc2 is conductive. At all other times, the regenerative converters SA1 ^r to SC2 ^{1 are} conductive and behave like diodes.

In Pig. 5 a diagram is now shown which shows the firing sequence of the individual converters. The individual curves are given the same designations as the associated converters. The last three corners in Pig. 5 show the output voltages VAB between the connections Ta and Tb, VBC between the connections Tb and Tc and the voltage VCA between the connections Tc and Ta. At time t11, the converters SpI and Sp2 are both conductive, together with the converters SA1ι SB2 and SCl in the inverter circuit, so that there is a strobe path via this converter and via the resistors Za, Zb, Zc. At time t12, the converter SAl of the inverter circuit is to be blocked. For this purpose, the control voltages are removed from the converters SpI and the converters SA1, SCt. In addition, the commutation current *

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riehter Sd is activated and the reverse power currentVlchter £ a2 · and SC2 ¹ are blocked. As described in FIG. 1, the parallel connection of the compaction capacitor C1 to the converter SpT causes the latter to be extinguished.

When the commutation capacitor C1 is then reloaded, the Ruckapeiseetroarichter SA1 'takes over the current from the converter SA1. In the same way, the current commutates from the converter SC1 to the Rückapeisestromrichter SC1 ¹ . The converter Sp1 is then re-ignited and the control pulse is returned to the converter SC1 of the inverter bridge circuit.

At time t13, the converter SA2 of the inverter circuit is ignited and takes over the current from the regenerative converter SA1V when its polarity changes.

At the time t14, the control pulse from the converter Sp2 and removed from the converters SB2 and SA2 and given a control pulse to the commutation converter Sc2. At the same time, the feedback converters SB2 'and SA2' are restored ignited so that they can take over electricity »if the Commutation capacitor C1 is reloaded.

Through the converter connected upstream of the bridge circuit with a commutation circuit, the converters in the inverter circuit are commutated so that at the terminals TA, Tb, To of the resistors Za, Zb and Zo which, shown in curves YAB, YBC and YCA, results in “three-phase alternating voltage.

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Claims (4)

VPA 70/8319 patent claims 1.)) Commutation device for converters that are used for supply a consumer from a DC voltage source, with a commutation capacitor connected in parallel to the converter, which is in series with a commutation converter acting as a switch, characterized in that that at least one converter (Sp1, Sp2, Spo) with a commutation capacitor (01, C2) connected in parallel switched into the connection line to the DC voltage source (E) is. : 2.) Commutation device for converters in inverter bridge circuit according to claim 1, characterized in that a commutation capacitor (01) only for the converters (Sp1, Sp2) switched on in addition to the converters (SA1 to SC2) in the connecting line to the DC voltage source (E) is provided and that instead of reactive current diodes each of the converters (SA 1 to SC2) in the inverter circuit and the upstream converters (Sp1, Sp2) in the connection line to the DC voltage source (E) a controlled return current »riohter (SA1 · to SC2 ¹ ) connected anti-parallel is. 3.) commutation device according to claim 1 or 2, characterized characterized in that a converter (Sp1, Sp2) is switched on and that each of these converters has a series connection of a commutation current riohters (Sd, Sc2), a common commutation capacitor (C1) and one Diode (D1, D2) is connected in parallel and that the ignition of the commutation capacitors (Sd, Sc2) alternately depends on the respective polarity of the voltage on the commutation capacitor (CT). 4.) Commutation device according to claim 1 or 2, characterized in that switched on in parallel with one in the connecting line to the DC voltage source (E) Converter (Spo) a bridge circuit made up of four commu- 009842/1196 - -β - VPA 70/8319 tion converters (Sea, Sea ¹ , Scb, Scb ') is connected in parallel and that the commutation capacitor (C2) is located in the bridge arm of this bridge connection. 009842/1196 Blank page