DE3110554C2 - Self-commutated inverter in three-phase bridge circuit - Google Patents

Abstract

In a self-commutated inverter with a smoothing capacitor between the DC voltage connections and commutation capacitors arranged in a triangle between the main valve branches to cancel the phase sequence of the main valves, the charging of the commutation capacitors to a value higher than the DC voltage should be avoided. For this purpose, a series connection of a diode (n13 to n63) and an impedance (r13, i13; r43, i43) is connected between the branch connection of two commutation capacitors (k1 to k6) and a DC voltage connection of the smoothing capacitor (C) in such a way that the charging current of the third commutation capacitor (k1 to k6) is diverted to the smoothing capacitor (C) via this series connection as soon as the voltage on the third commutation capacitor (k1 to k6) exceeds the voltage on the smoothing capacitor (C).

Description

Description

The invention relates to a self-commutated inverter according to the preamble of the patent claim. Such an inverter is known from US-PS 39 80 941.

In this inverter, the series connection of the diode and the impedance, which is each connected to the DC voltage connection of the corresponding half of the bridge, serves as a recharge circuit. The recharge circuit has the task of making the recharge time of the capacitors independent of the charging current and thus enabling low-load operation in the first place. The recharge circuit also solves the task of diverting the reversal current from the capacitor into a secondary path at the time the capacitor voltage passes through zero.

However, if the inverter has a structure as described in Heumann/Stumpe "Thyristors" 1969, BG. Teubner, Stuttgart, page 184, i.e. a constant voltage input guaranteed by a smoothing capacitor between the DC voltage connections, the first task mentioned above is solved without loss by oscillating circuits formed from the commutation capacitors and oscillation inductances (cross chokes) arranged on the AC voltage side. The second task mentioned above is then carried out by the loss-free demagnetization of the chokes via reverse current diodes connected antiparallel to each main valve branch to the counter voltage of the smoothing capacitor.

To limit the current increase, it is usual and, particularly in the case of inverters with a higher output (> 3 MVA), absolutely necessary to provide additional chokes. However, these current increase limiting chokes and other parasitic inductances in the inverter circuits cause the commutation capacitors to charge up to approximately twice the DC voltage supplying the inverter during the commutation process due to their demagnetization. This means that the commutation capacitors must be designed with a correspondingly high voltage. The other power components of the inverter must also be designed in this way.
From the Patents Abstracts of Japan, May 23, 1979, Vol 3, No. 60, E 112 (Kokai No. 54-38 523) it is known that in order to protect against unusual overvoltages occurring on the commutation capacitors of an inverter with phase sequence cancellation and constant current input, the capacitors of both halves of the bridge can be connected in series with a diode and an ohmic resistor via a switch. Apart from the fact that operational overvoltages cannot occur on the commutation capacitors because of the different type of inverter, the voltage on the commutation capacitors must be measured in order to operate the switch. Due to the heat that occurs, particularly in inverters with higher output, it is not possible to combat the overvoltage using the ohmic resistor in a sensible way.

The invention is based on the task of preventing the charging of the commutation capacitors to a value higher than the direct voltage in a circuit arrangement of the type mentioned at the beginning in an inverter with a constant voltage input with low losses and using simple means.

This object is achieved according to the invention by the features characterized in the patent claim.

Advantageously, the excess voltage on the commutation capacitors that exceeds the voltage on the smoothing capacitor does not occur because the excess charge is diverted to the smoothing capacitor via the path specified by the diodes. The power section of the inverter can therefore be designed to be lower in terms of voltage, while the cost of the additional components is low. The losses due to the impedance are also not significant compared to the other losses.

The invention will be described below for an embodiment with reference to the drawing.

The drawing shows the basic circuit diagram of a three-phase self-commutated inverter, which has a smoothing capacitor C between its DC connections. The AC load is connected in a delta between the connections U, V, W. The inverter can, for example, work as a reactive power converter, with the primary windings of a transformer for feeding reactive power into a network located between the connections U, V, W.

Each of the six inverter branches has a main valve (thyristor) π 10 to /; 60 with an anti-parallel reverse current diode π 12 to π 62. In series with the main valves π 10 to π 60 and the reverse current diodes π 12 to π 62 there are chokes π /11 to /61 and /12 to /62 respectively, which limit the current rise. The main valves π 10 to π 60 are extinguished via commutation capacitors Ar 1 to π 6 arranged between the main valve branches in known phase sequence extinguishing. In order to prevent the commutation capacitors π 1 to Ar 6 from discharging when the load is in reverse voltage, blocking diodes π 11 to /761 are arranged in

3 4

series with the main valves η 10 to η 60. and to avoid costly additional load, the excess commutation energy must be decoupled from the antiparallel reverse current diodes η 12 to η 62 by means of cross-throttling until the commutation in the group under consideration. The main valves η 10 to η 60 are decoupled from the antiparallel reverse current diodes η 12 to η 62 by means of cross-throttling, at whose center taps the terminals U, V, W for the AC side 5 act as the load. The excess energy is delivered with as little loss as possible to the smoothing capacitor C , whose capacity is approximately lO^ times the load.

A commutation of the load current, e.g. from This purpose is served by the connection of the three three-

Main valve &pgr; 10 to the main valve &eegr; 30, runs as follows: corner points of a bridge half to which the commutation capacitors are connected, via a

Before the main valve &pgr; 30 is fired, the upper half of the bridge consists of a diode &pgr; 13 to &eegr; 63 and a commutation capacitor JtI; Jt3; kS with the upper ohmic-inductive impedance rl3, /13 or /-43, /43 the poles written above for them with the DC voltage connection of the other half of the bridge. When the main valve &pgr; 30 is fired, the main valve &pgr; 10 is blocked and the load current passes through the branch with the main valve &lgr; 30. The load current is superimposed on an oscillation process in which the commutation capacitor kS and the series connection of the commutation capacitors kS in parallel with the main valve &lgr; 30 30 — current rise limiting chokes ArI and k 3, the current rise limiting choke /31 — capacitor k5 in parallel with /31, the main valve π 30, the smoothing capacitor C, the two capacitors kl and Jt 3 — blocking diode, the impedance r 13, /13 and the diode π 13 is formed
&pgr; 11 - shunt choke /14 - current rise limiting choke /12 - reverse current diode &pgr; 12 - main valve &eegr; 30. Under the effect of these currents, the commutation capacitor k 5 is recharged after a short current-free pause, which takes over the much larger load current of phase V and is kept conductive by the commutation capacitor k 1 from 0 to the value of the current rise limiting choke / 12 - reverse current diode &pgr; 12 - main valve &Lgr; 13 is thereby conducted in the blocking direction, is not a contradiction, because this current changes the path via the blocking diode &pgr; 30. 31, the shunt choke /34, the capacitor k3 from the amount of DC voltage to 0 current rise limiting choke /32 and the reverse charged current diode &pgr; 32 open.

The new polarities of the commutation capacitors - Due to the use of as few components as possible

tors are written below in brackets. is a common impedance (consisting of

When the voltage at the commutation capacitor 30, the ohmic resistor r13 and the inductance /13 sator k5 (and the parallel series connection of the further ohmic resistor r43 and the commutation capacitors k6 and k3) has reached the value of the further inductance /43) for all diodes polarized in the same direction to the DC voltage at the smoothing capacitor C , the connection point of the blocking diode π13 , π33 , π53 or π23 , π43 , π63 is arranged.
&pgr; 11 with the shunt choke /14 and the current rise limiting choke /42 at the same potential as the &eegr; 23 connected in series with the diodes &pgr; 13, &eegr; 33, &eegr; 53 or &eegr; 43, &pgr; 63, the impedances rl3, /13 or the negative electrode of the smoothing capacitor C; the -43, /43 are necessary because without them the laser current diode &eegr; 42 does not react quickly enough to the reverse current diodes &pgr; 12 to &eegr; 23.

Without the current rise limiting chokes /31 π 62 commutated, but temporarily via the di- and / 42 and the parasitic inductances of the affected circuits 40 π 13, π 11; π 33 , π 31 ; π 53 , π 51 and π 43, π 41; π 63, the current would flow at this moment.

Main valve &pgr; 30 de-energized, the load current instantaneous

transferred to the branch with the reverse current diode &pgr; 42 - For this purpose 1 sheet of drawings

hen and the cross choke /14 transfers its energy via the

Reverse current diodes &pgr; 42 and &eegr; 12 at the smoothing con- 45

capacitor C. The commutation capacitor

k 5 with the parallel series connection of the

Commutation capacitors k 1 and k 3 would thus be

recharged to the amount of direct voltage.

Since the current rise limiting chokes /31, /42 50
taking into account the permissible current rise rate
with a certain value
must, the current transfer to the branch mii the
Reverse current diode &pgr; 42 does not take place in time 0, so
that the voltage of the commutation capacitors 55
further, i.e. increases beyond the DC voltage
If the voltage of the commutation capacitors
If we leave the figures at this higher level,
at the next commutation process in the considered
Commutation group due to the increased demand 60
the amplitudes of the mentioned oscillation process
increase proportionally, and the result
would be a further increase in the voltage of the capacitors.

This process would be possible with lossless switching 65
circles continue indefinitely; for real circles
there is a nci\en equilibrium state at
approximately twice the DC voltage. To eliminate this superfluous

Claims (1)

Patent claim Self-commutated inverter in a three-phase bridge circuit, which has commutation capacitors connected in a delta for the purpose of phase sequence cancellation, each delta point between a main valve and a blocking diode of a half-bridge being connected to a main valve branch and each of the delta points of a half-bridge being connected to one of the DC voltage connections feeding the inverter via the series connection of a diode and an ohmic-inductive impedance, characterized in that in an inverter which has a "constant voltage input" ensured by a smoothing capacitor (C) between the DC voltage connections, reverse current diodes (π 12, π 22 ... π 62) antiparallel to each main valve branch (n 10, π 20 ... π 60), ring-over inductive capacitors (H4, /34, /54) arranged on the AC voltage side and in P.rows to the main valves or reverse current diodes have chokes (711 ... /61; /12 - /62) for limiting the current rise, for operational demagnetization of the chokes (i 11... / 61; /12... /62) each of the triangle points of one bridge half is permanently connected to the DC voltage connection of the other bridge half via the series connection of the diode (n 13, π 23 ... η 63) and the ohmic-inductive impedance (r 13, /13; r 43, /34).