DE4023207C1 - Driving branches of inverter - sing common DC source for parallel branches formed by semiconductor switches controlled in same direction and supplying load via choke - Google Patents

Abstract

The parallel current regulator circuit uses a number of parallel current regulator paths between a DC source and a common load. The current in each regulator path is detected to provide a mean current value, at least two current values compared with the latter to provide difference values used to adjust the phases of the ignition pulses for the different thyristors, to maintain the symmetry between the currents obtained from each current regulator path. The current regulator paths are coupled galvanically via the throttle coils supplying the load and the ignition pulses for the thyristors in the paths with current values outside the mean value band are adjusted while the pulses for the thyristors in the remaining paths also delayed or advanced. ADVANTAGE - Ensures current symmetry.

Description

The invention relates to a method according to the preamble of Claim. Such a method is described in DE 36 02 496 C2 known.

Due to the different switching times of the controllable semiconductor valves ent are additional when connecting inverter branch pairs in parallel Loads caused by equalizing currents that the feeding DC voltage source drives the same-controlled inverter branches. These equalizing currents must be limited or avoided by additional measures.

The different switching times of the semiconductor switches can, for. B. adjust to each other in that from a sufficiently large number of Semiconductor switches are selected those that have approximately the same property have ten. Such selection is uneconomical and half usually not feasible in practice.

In the simplest way, however, it offers itself instead, at the exit of the To arrange the inverter choke coils (see K. Heumann and C. Stumpe "Thyristors", B.G. Teubner, Stuttgart, 1969, especially pages 301 and 302). However, since the different circuit symbols of the semiconductor switches have a mean non-zero voltage across the choke coils, A suitable counter voltage must be provided. This can e.g. B. can be achieved in that ohmic resistors in series with the chokes to be ordered. With high performance and high efficiency one However, this solution is the inverter because of the power dissipation would be uneconomical.

The method described in the aforementioned DE 36 02 492 C2 is based on parallel inverter branches that apply galvanically  their output are not connected. Rather, the individual work Inverters via choke coils on separate primary windings of a trans formators, which has a single secondary winding. The currents through the primary windings are used to form an average.

In this known method, n-1 of the n are the inverter currents compared with the mean and the control deviations in each case fed to a current regulator. The regulation of the deviations leaves one rapid setting of the current by shifting the ignition pulses for the semiconductor switches for the purpose of balancing the currents. Can too there are difficulties, an adjustment range sufficient for symmetrization for the ignition pulses, especially when the ignition is brought forward impulses to ensure.

The invention has for its object the method of the aforementioned Type in such a way that when using unselected semiconductors switches in the inverter branches of the inverters working in parallel an adequate counter without additional expenditure on power components, in particular ohmic resistances voltage for symmetrizing the currents generated by the inverter branches is, with a very fast position of the current to be balanced over there is a tax rate and a sufficient time range for the Ignition pulses are made available.

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

Everyone As soon as the set bandwidth is exceeded, electricity can be shift of the start and / or the end time of the ignition pulses immediately  (i.e. not only by adjustment), which also the effort required for the choke coils is reduced. A temporal Shift of the ignition pulses is always more advantageous by the fundamental delay of the deployment points or advance of the end time points of the ignition pulses possible.

The method according to the invention is described below with reference to the drawing be explained for an application example. It shows

Fig. 1, the formation flow of a mean value of each inverter branch,

FIG. 2 shows the comparison of the mean value formed in FIG. 1 with one of the branch flows and

Fig. 3 shows the timing of control signals for the semiconductor switch of an inverter branch.

The further explanations are based and not shown here, n parallel inverter branches that are fed from a common DC voltage source and each work via a choke coil on a common load. The n inverter branches are formed from semiconductor switches with different switching times. Their currents are to be symmetrized in accordance with the method according to the invention: FIG. 1 shows a summing element A to which current _values i _zw1 , i _zw2 , ... i _zwl,. .. i are _supplied by currents flowing through the n parallel inverter _branches . The summing element A sums up the current values supplied to it to the value of the load current I. A divider T connected downstream of the summing element A divides the load current I by the number n of the inverter branches involved and thus forms an average i _between all branch currents.

This mean value i _zw is compared with the actual current _values i _zw1 ... i _zwn . Fig. 2 shows as an example i _zw with the current value i _ZWL any inverter branch by a comparison element D. At the output of the comparing section D the comparison of the average value is a signal i to the deviation of both the comparator D values supplied _zw and i _ZWL each other corresponds.

This deviation is fed to two comparators K 1 and K 2 , which emit signals K _1l = 0 and K _2l = 0 if the deviation remains within a bandwidth ± Δi _l .

If the deviation exceeds the bandwidth upwards, ie if i _zw <Δ _1l , the output signal K _{1l of} the comparator K 1 jumps to level 1 (K _1l = 1). If the deviation _falls below the bandwidth downwards, ie _if i _zwl -i _zw <-Δi _2l , the output signal on comparator K 2 changes to K _2l = 1.

The outputs of the respective comparators K 1 , K 2 thus indicate whether the branch _current i _{zwl lies} within, above or below the tolerance band i _zw ± Δi _l , as the following table shows:

The two signals K _1l , K _2l are now used to change a control signal S for the semiconductors in the parallel-connected inverter branches so that the cross currents between the inverter branches remain limited. It is sufficient to influence either the switch-on command (S from 0 to 1) or the switch-off command (S from 1 to 0) for the semiconductor switches of the respective inverter branch. In principle, both commands can also be changed simultaneously.

In Fig. 3 the described method is shown only for influencing the switch command:

The switch-on command for the control signal S (time profile a) is generally delayed by the time t _0l (time profile b) for the desired inverter branch l (time profile b) in order to have a sufficient period of time if the ignition point of the semiconductor switch is brought forward (time profile c) . The control signal S _l thus obtained for the inverter branch now controls the semiconductor switches of this branch l if the output signals of the two comparators K 1 , K 2 in FIG. 2 are K _1l = 0 and K _2l = 0, ie the branch _current within the Tolerance band lies.

If the branch _{current value} i _is below the tolerance _band , ie if the output signal K _1l = 0 and K _2l = 1, the switch-on _{command of} the signal S _l is _brought forward by the time t _2l t _0l (time _curve c).

If the branch current is greater than i _zw + Δi _1l , ie if the output signal K _1l = 1 and K _2l = 0 supplied by the comparator K 1 , the switch-on _command S _l for the semiconductor switches of the inverter branch l is further delayed by t _1l (time elapses d). By a suitable choice of the time shifts t _0l , t _1l , t _2l , the respective branch _flows are _definitely limited.

Instead of using an inverter, the method is applied according to Invention z. B. can also be used with advantage in parallel choppers.

Claims (2)

Method for operating a common DC voltage source on closed inverters working with their branches formed from semiconductor switches in parallel operation, each feeding a common load via a choke coil, in which

• - The currents are detected by the inverters operating in parallel, the mean value is formed from these currents and
• - at least two current values are compared with the mean value and
• - In accordance with the deviation of the respective current value from the mean value, the current flowing through the inverter branch is phase-shifted by shifting the ignition pulse for the semiconductor switches in the inverter branch to such an extent that all currents flowing through the individual inverter branches are balanced,

characterized by

• - that in the case of inverters working in parallel operation with inverter branches galvanically connected via the choke coils, according to the deviation of the respective current value from the mean value beyond a predetermined bandwidth, the times of use and / or the end times of the ignition pulses advance or delay the semiconductor switches of the individual inverter branches,
• - And that in principle branch for all semiconductor switches in the inverter, the current values of which are within the range specified by the mean value, the time of use of the ignition pulses is also delayed by a predetermined time and / or the end time of the ignition pulses is brought forward by a predetermined time.