NO148131B - SEQUENCE CONTROLLABLE, SWITCHABLE BRIDGING. - Google Patents

Description

The invention relates to a single- or multi-sequence controlled, forcibly switchable bridge connection device, which on the direct current side for each direct current pole comprises an equal number of m bridge branches with controllable semiconductor valves, where m is an integer and greater than or equal to 2, and which on the alternating current side via a rectifier trans -former is connected to an inductance-loaded alternating current source, where at least one semiconductor rectifier with the same conduction direction is connected in the m bridge branches between the relevant connection point for the rectifier transformer and the controllable semiconductor valve,

where this semiconductor rectifier's connection point facing away from the rectifier transformer is connected via a commutation capacitor to the connection point on the alternating current side for the controllable semiconductor valve for any subsequent bridge branch, and where, in addition to the commutation capacitor(s), an auxiliary capacitor for up- or down-commutation is arranged.

Such bridging connections are described in the German Offenlegungsschrift

2 530 961. They can be advantageously used for electric drive vehicles.

As is well known, a distinction is made between fully controlled and semi-controlled bridge connections. The invention relates to both embodiments.

Sequence control means the series connection of partial rectifiers, where at any time only one rectifier runs through the entire control area, while all the others are in one of the two control end positions. The single-phase bridge connection can be understood as the successive connection of two two-pulse center connections. There is thus a sequence control also for the semi-controlled bridge connections.

In connection with the sequence control, it is also known to carry out

a section and section management, a so-called sector management.

In addition to the sequence control on the direct current side, sequence control of several rectifiers is also known on the alternating current side.

A significant disadvantage of the hitherto known two- or multi-stage couplings which can be switched online is that they require reactive distortion effect ("Grundschwingungsblindleistung".

The invention is based on the task of providing a bridge connection, with the help of which the distortion power factor cos ø" between mains voltage and mains current can be set capacitively, inductively or to 1, i.e. with the help of which a power factor optimization is achieved with relatively little coupling effort.

This task is solved according to the invention in that the auxiliary capacitor's first electrode is connected to a central winding outlet of the rectifier transformer on the secondary side and that the auxiliary capacitor's second electrode is connected at all times, at least via a charging diode, to the rectifier transformer's winding terminal on the secondary side.

Due to the use of a rectifier transformer with a central outlet, auxiliary thyristors and charging diodes can advantageously be dispensed with, which contributes to a minimization of the switching effort.

The additionally used auxiliary capacitor as a support capacitor is advantageous for all forced commutations in rectifier and inverter operation. Operationally, it lies parallel to the commutation capacitor and prevents accidental overcharging of this capacitor by demagnetizing the transformer's line and dissipation inductance. It is also suitable for absorbing overvoltages on the website and can be discharged towards the direct current side.

In the case of a bridge connection for two bridge branches with controllable semiconductor valves, the second electrode of the auxiliary capacitor is conveniently connected via two auxiliary thyristors. at all times connected to the commutation capacitor.

For the operation of the used auxiliary capacitor, the transformer partial windings on the secondary side must be magnetically tightly (ie ideally) connected.

The magnetically tight coupling of the sub-windings is necessary by the arrangement of only one auxiliary capacitor to enable the sudden changes of the amperage and direction of the currents through the commutation capacitor and the clamp capacitor. A non-ideal connection would lead to an unfortunate delay in the current change between the two capacitors involved and thus to a higher overvoltage of the commutation capacitor. A magnetically tight coupling of the partial windings can be realized by the special constructive winding structure in the rectifier transformer.

In the case of a bridge connection device for three bridge branches with controllable half-conductor valves, the second electrode of the auxiliary capacitor is preferably . at all times connected via an auxiliary thyristor, which is connected anti-parallel to the charging diode, to the rectifier transformer's winding sender on the secondary side.

In a continuation of the invention, a further auxiliary capacitor's first electrode is connected to the rectifier transformer's winding outlet on the secondary side, its second electrode is at all times via a parallel connection of a further charging diode with an auxiliary thyristor with the opposite polarity, connected to the rectifier transformer's winding terminal on the secondary side, where the similar semiconductor elements for the parallel connection which are connected to the second electrode of the second auxiliary capacitor have the opposite polarity in relation to the similar semiconductor elements for the parallel connections which are connected to the first auxiliary capacitor.

This second auxiliary capacitor is advantageously used when there is a non-ideal connection between the transformer windings, which results in a higher overvoltage of the commutation capacitor (Shutdown capacitor). It is achieved with each forced commutation that one auxiliary capacitor connects directly and the other transformerically in parallel with the relevant commutation capacitor. •

The drawings show embodiments of the invention. Fig. 1 shows a fully controlled switchable bridge connection, where one electrode for the auxiliary capacitor is connected to a central outlet of the current rectifier transformer. Fig. 2 shows a two-stage switchable and switchable fully controlled bridge connection, where a bridge branch and one electrode of the auxiliary capacitor are connected to a central outlet for the rectifier transformer. Fig. 3 shows a two-stage switchable and switchable fully controlled bridge connection, where a bridge branch and at any time an electrode of two auxiliary capacitors, which are connected to a center-point connection with opposite polarity, are connected to a central outlet for the rectifier transformer.

The fully controlled, switchable single-phase bridge connection shown in fig. 1, includes in its branches main thyristors - n-^, n2, n^ and n^ - and in series with n-^ respectively n^ - diodes n-^ respectively n^ Between the branches formed by n-^ and n^ is a commutation capacitor C^. An auxiliary capacitor (supporting capacitor) C is connected via one of its terminals to one direct current pole, while its other terminal via the charging diodes n^ 2 °9 ni 3 is led to the branches with n-^ and n, and via the auxiliary thyristors 2 °9 n23 is connected to the commutation capacitor C, electrodes.

The negative pole of the auxiliary capacitor C2 is connected to a central outlet for the secondary transformer winding which feeds the rectifier connection. On the primary winding of the rectifier transformer is the mains alternating voltage U^, the supply alternating current is denoted by 1^ and the mains and transformer inductance is represented by LN in

the primary circuit. The primary voltage is denoted by U^, secondary

the voltages ^1 fall at all times between the terminal 2 of the sub-windings

more. The short-circuit inductance between the two winding halves constitutes L1.

The output current on the direct current side is denoted by 1^ and the output voltage on the direct current side is denoted by U^.

Compared to the connection known from German Offenlegungsschrift 2 530 961 (fig. 14), the still necessary auxiliary thyristors and charging diodes will be omitted as a result of the use of a rectifier transformer with a central outlet. With this new arrangement of the auxiliary capacitor C2, the valve insert for connecting its negative pole is advantageously avoided, which

would be required for inverter operation on the grid.

When there is a tight coupling of the two winding halves, i.e. when L^<j£ LN, the auxiliary capacitor C2, which now intervenes in parallel with one winding half at all times, will in the same way

C2

as an auxiliary capacitor ^— on the entire winding. The design effect of the auxiliary capacitor is the same with the known connection according to German Offenlegungsschrift 2 530 961 as with the design according to fig. 1.

The idea just mentioned can also be used for equipping a sequence-controlled, multi-stage, switchable and switchable, fully controlled bridge connection on the alternating current side. The auxiliary capacitor C2, which is arranged additionally according to the invention, is effective for all forced commutations in rectifier and inverter operation. It is, however, a prerequisite that the sub-windings of the transformer are connected closely enough to each other.

Fig. 2 shows the design of a two-stage switchable and switchable switch. In addition to the design according to the state of the art (German Offenlegungsschrift 2 530 961), the input transformer, which is connected on the primary side in the same way as in fig. 1, added again with a central outlet on the secondary side, and the short-circuit inductance between the two partial windings is denoted by L-^.

The main bull in the big one in the branches is denoted by n-^, n2, , n^, n^ and n^, the commutation or lick capacitors between these branches are denoted by and C, and we see the diodes n^^, n^ and n^

which are connected in series with the main thyristors n^, n^ and n^. The auxiliary capacitor C2 is connected with its one electrode to the central outlet of the transformer and at the same time to the central branches, with its other electrode it is via an antiparallel connection of charging diodes n-^ 2 and n^ 3 as well as auxiliary thyristors n2 2 and n23 connected to the secondary winding of the transformer and the outer branches.

The operation of the coupling according to fig. 2 will now be briefly explained.

UN is assumed to be> 0. The direct current 1^ is based on the free run ("Freilauf") via n2~ nl l~nl 9^tt into two stages with mains commutation on the section ng - the entire winding - n-^ ^ ; The direct voltage U-, is equal to the instantaneous mains voltage UN, where a turnover ratio of 1 is assumed.

First extinguishing is initiated by ignition of n^ and n2 1 instead of via n-^ 1^ now flows over C-^ - n3. At the same time, a discharge current from the auxiliary capacitor C2, which is charged to more than UN/2, flows via the auxiliary thyristor n2 2 to the upper winding half and weakens the mains current. The initially negatively charged commutation capacitor is recharged by I, , until the diode n^ begins to conduct at equal voltage of and C2. Thus and C2 are directly connected in parallel via the conducting valves ^, n3^ and n2 2' They jointly absorb the current which is driven on by LN, until approximately ±N = 1^/2. Id then flows via ng - lower winding half - n^ ^ - n^.

When transitioning from the first to the second phase of the commutation, the current abruptly changes its value in C-^ and its direction and value in C2>

Second stage of the forced shutdown, where In and 1^/2 must be brought to zero, is initiated by switching on n5 and n2 2. The first phase of the linear recharging of C 3 and discharge of C2 against mains voltage is completed, as in the first commutation, until n^ ^ becomes conductive at equal capacitor voltage. But then C and C2 are not directly in parallel, but connected via both winding halves.

The abrupt current changes in the redistribution of the capacitor currents are only possible with ideal coupling. The non-ideal coupling, expressed by the inductance L-,/4 in the transformer's central outlet, leads to a slower current shift between the two capacitors involved and, in unfavorable cases, to a higher overvoltage of

the commutation capacitor.

In order to avoid this effect in the case of a connection that is not tight enough, 'is arranged as shown in fig. 3 a second auxiliary capacitor in a midpoint connection with opposite polarity.

In addition to the connection according to fig. 2, the second auxiliary capacitor is located with its one electrode connected to the central outlet of the transformer, with its other electrode via the extra antiparallel arranged auxiliary thyristors n4 2 and n4 3 and the charging diodes n^ 2 °<9> n3 3 connected to the secondary terminals of the rectifier transformer.

With each forced commutation, an auxiliary capacitor can thus be connected directly and the other transformer-like connected in parallel to the relevant commutation or extinguishing capacitor. As both contribute to limiting the overvoltage, the capacitor input is as large as with a single auxiliary capacitor.

Claims (4)

1. Single- or multi-sequence controlled, forcibly switch-off bridge connection device, which on the direct current side for each direct current pole comprises an equal number of m bridge branches with controllable semiconductor valves, where m is an integer and greater than or equal to 2, and which on the alternating current side via a rectifier transformer is connected to a inductance-loaded AC voltage source, where at least one semiconductor rectifier with the same conduction direction is connected in the m bridge branches between the relevant connection point for the rectifier transformer and the controllable semiconductor valve, where the outlet for this semiconductor rectifier facing away from the rectifier transformer via a commutation capacitor is connected to the outlet on the alternating current side for the controllable semiconductor valve for the subsequent bridge branch at all times, and where, in addition to the commutation capacitor, one (e) for or down commutation, an auxiliary capacitor is arranged, characterized in that the first electrode of the auxiliary capacitor (C2) is connected to a central winding outlet for the rectifier transformer on the secondary side and its second electrode at all times via at least one charging diode (n^ 2 * nl 3^ is' connected to the winding terminal of the rectifier transformer on the secondary side. 2. Bridge connection device as specified in claim 1 for two bridge branches with controllable semiconductors, characterized in that the second electrode of the auxiliary capacitor (C2) is connected via two auxiliary thyristors (n2 2, n2 2) at all times to the commutation capacitor (C1) (fig. 1). 3. Bridge connection device as stated in claim 1 for three bridge branches with controllable semiconductor valves, characterized in that the second electrode of the auxiliary capacitor (C2) is connected to the winding terminal of the rectifier transformer on the secondary side at all times via an auxiliary thyristor (n2 2, n2 3) which is anti-parallel connected to the charging diode (n-j^ 2, n-^ 3) (fig. 2) . 4. Bridge connection device as specified in claim 3, characterized in that the first electrode of a second auxiliary capacitor (C4) is connected to the winding outlet of the rectifier transformer on the secondary side and that the second electrode of the additional auxiliary capacitor is at all times connected to the winding terminal of the rectifier transformer on the secondary side via a parallel connection of a further charging diode (n3 2, n33) with an auxiliary thyristor (n42, n43), which in polarity is oppositely directed to the-V~" ne, where the similar semiconductor elements for the parallel connection connected to the second electrode of the further auxiliary capacitor (C4) has the opposite polarity in relation to the similar semiconductor elements for the parallel connections which are connected to the first auxiliary capacitor (C2) (fig. 3).