DE2552660A1 - Self:regulating polyphase rectifier - has in each phase common commutation capacitor for two main diodes connected to auxiliary voltage source - Google Patents

Abstract

The self regulating rectifier has two main diodes each connected to a free running diode in each phase. There is an extinguishing controlled diode allocated to each, and a commutation inductor and one common commutation capacitor are provided for the two main diodes. The commutation capacitor (Ck) is connected through controlled extinguishing diodes (n5, n6) and also through the recharging path (R, n7, n8) to the auxiliary voltage source (2). Either two like potentials, or the centre points of the two voltage sources are connected together.

Description

Self-commutated power converter

The invention relates to a self-commutated power converter with a series connection of two to a DC supply voltage source in each phase connected controllable main valves, with two associated with the main valves Free-wheeling valves and with a device for forced commutation, for everyone A controlled extinguishing valve is assigned to the main valve u be.

the at least one commutation throttle and one for both main valves common commutation capacitor is provided via controlled valves is connected to an auxiliary voltage source and to which a recharging path to a voltage source is assigned, which contains a return valve and a return resistor.

In such a self-commutated converter with forced commutation should have a sufficient commutation capability of the main valves even with fluctuating DC supply voltage and high scanning current must be ensured.

In a known self-commutated converter, the common Commutation capacitor via additional controlled valves with an auxiliary voltage source connected (DT-OS 2 007 567). When the current in a main valve is interrupted should, the extinguishing valves are ignited and the commutation capacitor is discharged over the main valve in question so that it goes out. Once the main valve is extinguished, the commutation capacitor swings over the extinguishing valves that Commutation reactor and a free-wheeling valve around. The load current continues to overflow the quenching valves, the commutation capacitor and a commutation reactor and superimposed on the oscillation current. The commutation capacitor has after the oscillation process again approximately the same voltage, but with the opposite sign, as before the interruption of the current ii concerned Main valve. To recharge the commutation capacitor, the additional controlled Valves in the reloading branch ignited in each case at the right time, so that a reloading current flows, which charges the commutation capacitor euf a voltage that is slightly greater is than the voltage of the auxiliary voltage source. The charging voltage of the coupling capacitor is independent of the DC supply voltage. The well-known converter k & nli can be operated with a variable DC input voltage. However, the disadvantage is high expenditure on additional valves and a special choke coil.

In another known device of the type mentioned above the commutation capacitor is again initially from the DC supply voltage source charged (DT-OS 2 408 609).

For recharging the commutation capacitor from an auxiliary voltage source a reloading branch is provided, which consists of a series connection of a reloading resistor with a controllable reload valve. For recharging the commutation ring capacitor A controllable recharge valve is provided in the DC supply voltage source, which can then be ignited, nn the voltage at the commutation capacitor is a predetermined value Exceeds limit. In the case of this known self-commutated power converter, it is disadvantageous that that the recharging takes place via a resistor and is therefore lossy. An additional reloading valve is also required. By reloading on the DC supply voltage and the charging on the auxiliary DC voltage must the closed periods for both the reloading valves and the reloading valves be respected. This limits the output frequency of this converter.

The present invention is based on the object of a self-guided Converter of the type mentioned above using the lowest possible The number of additional valves also provides sufficient commutation capability to ensure strongly fluctuating DC supply voltage.

According to the invention, this object is achieved in that the commutation capacitor via the controlled extinguishing valves on the one hand and via the reload path on the other hand is connected to the auxiliary voltage source, with either two of the same name Foteniale or the midpoints of the two sources of voltage connected to one another are.

In the self-commutated converter according to the invention, the energy for the commutation capacitor taken primarily from the auxiliary voltage source. Additional charging of the commutation capacitor can only occur with very high load currents come. This overvoltage, which exceeds the normal charging voltage, is converted into the Auxiliary voltage source fed back. By coupling the commutation capacitor to the auxiliary voltage source via those already present in the converter circuit Extinguishing valves, no additional loading valves are required. Only for reloading an excess amount of charge, depending on the selected circuit on or two. Reloading valves additionally required as uncontrolled or controlled Valves can be formed. The commutation capacitor is charged practically lossless. The self-commutated converter according to the invention can with high output frequency.

In the figures of the accompanying drawings, exemplary embodiments of the invention and its embodiments characterized in more detail in the subclaims explained.

Fig. 1 shows the circuit of a self-commutated according to the invention Converter with a series connection of two a DC supply voltage source 1 connected controllable main valves n1 and n2, for example thyristors. Uncontrolled free-wheeling valves n3 and n4 are assigned to the main valves. An institution for forced commutation contains controlled extinguishing valves n5 and n6, for example Thyristors associated with main valves n1 and n2 and one for both Main valves common commutation capacitor CK and the commutation reactors Lk1 and Lk2. The output terminal is at the connection point of the two main valves n1, n2 7 connected.

The DC supply voltage source 1 is shown schematically as a rectifier shown, for example, e en ei. rbhstromnetz can be connected, and its output voltage is smoothed by the series-connected capacitors C1 and C2 will. The entire arrangement thus represents an intermediate circuit deflector with an embossed DC link voltage.

Furthermore, an auxiliary voltage source 2 is provided, which attacks is shown as a rectifier that its output voltage to the series-connected Capacitors C3 and C4 is tapped.

With the rectifiers in the DC supply voltage source 1 and The auxiliary voltage source 2 can in particular also be controlled rectifiers Act.

The commutation capacitor common to both main valves ni, n2 CK is connected to the auxiliary voltage source via the controlled extinguishing valves r5 and n6 2 connected. The commutation capacitor CK is on the Auxiliary voltage 62 charged.

The commutation capacitor Ck is assigned a recharging path contains a reloading resistor R and the two reloading valves n7 and n8. the Return valves can be designed as diodes or as controlled valves, for example as thyristors. The return valves connect the commutation capacitor CK with the auxiliary voltage source 2.

The connection point of capacitors C1 and C2 in the DC supply voltage source-r 1 is with the connection point of the capacitors C3 and C4 in the auxiliary voltage source 2 connected. In this way, the center point is the DC supply voltage source 1 connected to the center point of the auxiliary voltage source 2.

During a commutation process, one of the two quenching thyristors n5 or n6 is ignited. The commutation capacitor Ck discharges to the relevant main valve n1 or n2, which goes out. The oscillating current flows, for example, from the commutation capacitor Ck via the two commutation chokes Lki and Lk2, the freewheeling valve n3, the capacitor C1, the capacitor C3 and the quenching thyristor n5 to CR, or from C, via n6, C4, C2, n4, Lkl, Lk2 after Ck. A part of the load current that flows into the commutation circuit is superimposed on this oscillation current. The commutation capacitor CK is charged both independently of the current from the auxiliary voltage source U2 and also dependent on the current from the load current. where iL is the load current, L is the effective inductance in the commutation circuit and C is the capacitance of the commutation capacitor.

The commutation capacitor Ck is returned to the value uc2 according to equation (2) via the return path with the return resistor R and diodes as return valves n7 or n8: If it is assumed that the constant voltage U2 of the auxiliary voltage source 2 corresponds to the maximum possible value of the voltage Ul of the variable DC supply voltage source 1, half the maximum possible load current can be commutated at Ul # 0 volts, for example. With increasing values of Ul, the commutation capacity increases accordingly. The constant auxiliary voltage U2 is expediently chosen so that the maximum possible load current for the smallest possible value of the DC supply voltage Ul can be commutated. The components of the converter are designed for the largest possible value of the DC supply voltage Ul. In comparison to the known self-commutated converters mentioned at the beginning, the elements of the cooling circuit of the converter according to the invention can be designed to be significantly less powerful. The output frequency of the converter can be increased because the swing times are shorter.

If the return valves n7 U: n8 controlled valves, for example Thyristors. a desired commutation voltage on Commutation capacitor Ck as the maximum permitted capacitor voltage in one known ignition control unit for the controlled return valves n7, n8 set will.

The maximum possible span g results from equation (1).

If the DC supply voltage source cannot accept current 1 the open circuit resistance of the converter circuit shown can be achieved by the two Limiter diodes n9 and n10 can be reached.

The DC supply voltage is thus derived from the value of the auxiliary voltage held. If the DC supply voltage U1 is to remain at zero volts, leave it the voltage on the intermediate circuit capacitors C3 and C4 of the auxiliary voltage source Hold 2 at this value when the intermediate circuit capacitors C and C2 of the DC supply voltage source 1 In each case from the series connection of a zero resistor 3 with a switch t or a zero resistor 5 are bridged with a switch 6 The power loss through the zero resistances 3 and 5 is low, since the reversing current is mainly divided between the substitute resistors of the intermediate circuit.

Fig. 2 shows an asymmetrically constructed converter circuit.

The reference potential of the DC supply voltage source 1 is with connected to the reference potential of the auxiliary voltage source 2. As commutation voltage the voltage U2 of the auxiliary voltage source 2 is always available. However, since Overcharging of the commutation capacitor Ck is possible, the recharging losses increase.

Fig. 3 shows a converter circuit in which reversing diodes nil and n12 are connected to the auxiliary voltage source 2. With this circuit can the full load current even with a DC supply voltage of Ul almost zero volts be commutated. The main valves ni and n2 have double the closed time available against the case of the voltage equality of Ul and U2. So on Output 7 also loads with a reactive component, for example electrical machines, connected free-wheeling valves are considered to be controlled Freewheel valves t3 and t4 designed, for example as thyristors.

This is a freewheel over the DC supply voltage source 1 possible.

The invention has so far been for ease of explanation only for the single-phase case. An extension to the three-phase case is a matter of course possible and is also within the scope of the invention.

L e r s e i t e

Claims (4)

Self-commutated converters with one in each phase Series connection of two connected to a DC supply voltage source controllable main valves, with two free-wheeling valves assigned to the main valves, and with a device for forced commutation, each with a main valve controlled extinguishing valve is assigned, and at least one commutation reactor and a commutation capacitor common to both main valves is provided, which is connected to an auxiliary voltage source via controlled valves and the a return path is assigned to a voltage source, which has a return valve and contains a recharging resistor, characterized in that the commutation capacitor (CK) via the controlled extinguishing valves n6, n6) on one side and via the reloading path (R, n7, n8; R, n11) on the other hand is connected to the auxiliary voltage source (2), where either two potentials of the same name or the midpoints of the two Voltage sources (1, 2) are connected to one. 2. Converter according to claim 1, characterized in that the same name Potentials of DC supply voltage source 1) and auxiliary DC voltage source (2) are connected to one another via limiter diodes (n9, n1O). 3. Converter according to claim 1, characterized in that the Capacitors (C1, C2) of the DC supply source (1) each from the Series connection of a zero resistance (3 or 5) and a switch (4 or 6) are bridged. 4. Converter according to claim 1, characterized in that the commutation circuit is connected to the auxiliary voltage source (2) via reversing diodes (n11, n12).