DE3120469A1 - Circuit arrangement for relieving electronic pairs of arms of the dissipation power during the turn-on and -off process - Google Patents

Abstract

Apart from the elements turn-on limiting reactor (Le) and turn-off limiting capacitor (Ca), which are necessary in any case in turn-on and -off networks of an electronic pair of arms formed by a controllable switch (Th) and a first freewheeling diode (Df1), a third energy store - a unipolar storage capacitor (CSp) - is provided which temporarily buffers the energy of the two reactive elements (Le) and (Ca). The energy of this storage capacitor (CSp) is delivered into the load via a second freewheeling diode (Df2) after the turn-off process. The turn-off limiting capacitor (Ca) is recharged after the controllable electronic switch (Th) has been turned on, the turn-on limiting reactor (Le) acting as a ring-around reactor. A turn-off limiting diode (Da), a blocking diode (Ds) and the second freewheeling diode (Df2) provide a circuit path which does not allow the voltage at the controllable electronic switch (Th) to rise above the direct voltage (UD). <IMAGE>

Description

Description

The invention relates to a circuit arrangement according to the The preamble of claim 1. Such a circuit arrangement is e.g. DE-OS 26 44 715 known.

When operating power semiconductors as electronic switches in As is well known, power converter circuits must have forward current and reverse voltage also their rate of change during the switch-on and switch-off process below certain limit values are maintained in order to avoid malfunctions or destruction. The circuits required for this task consisting of dummy elements, diodes, linear ones and non-linear resistances have the most favorable configuration if they are designed appropriately Effect, including the peak power loss that occurs during switching operations in the controllable semiconductor switches occurs to reduce. This relief effect is in particular because of the resulting reduction in the average power loss, -die leads to heating of the semiconductor system during periodic switching operation, very desirable.

With conventional wiring networks, however, the Reactive elements stored energies in linear or non-linear resistances in heat, so that the losses are ultimately only shifted (DE-OS 21 28 454).

In DE-OSes 26 39 589 and 26 41 183, however, are solutions for Shutdown relief networks are specified that work without principle-related losses. In the DE-QS mentioned at the beginning 26 44 715 are also networks for switch-on relief and combination of these with switch-off relief networks specified. However, the switch-on reliefs shown work with implementation of the stored energies in thermal losses. You can also do it with the combined Switch-on and switch-off relief networks are not able to avoid losses due to the principle involved. The circuit complexity is also high.

Further electronic circuits for feeding back the stored Provide energies, for example in the form of DC choppers (DE-OS 26 44 715, Claim 9), requires considerable additional effort and also only provides one Postponing the problems.

Also occurs in the well-known switch-on relief networks Shutdown of the controllable electronic switch on this due to the principle Overvoltage on.

The present invention is therefore based on the object To design the circuit arrangement specified at the outset such that - they are a combination a switch-on and switch-off relief network, without principle-related Losses occur, - the least possible expenditure on components, in particular also a recovery of the stored energies without the use of additional controllable ones electronic switch is achieved and - overvoltages that are controllable claim electronic switches are avoided.

According to the invention, this object is characterized by what is stated in claim 1 Features solved.

In the circuit according to the invention is therefore advantageously a third energy storage - a unipolar operated storage capacitor - provided, the switch-on relief for the energy of the two basically necessary dummy elements The choke and cut-off relief capacitor are only temporarily stored. The energy of this storage capacitor is not converted into energy loss after the shutdown process implemented, but usefully supplied to the load via the second freewheeling diode. The switch-off discharge capacitor is recharged after the controllable electronic switch, whereby the switch-on relief throttle, which is required anyway as a reversing throttle. Via the diodes next to the first freewheeling diode there is a circuit path that controls the voltage at the controllable electronic switch does not let rise above the DC supply voltage.

Advantageous designs and developments of the invention are set out in the claims 2 to 5 marked.

Is used for reasons of more permissive circuit dimensioning separate resonance circuit introduced (claim 3), leads the circuit path, which does not allow the voltage at the switch to rise above the DC supply voltage, via the second switch-off relief diode and the second freewheeling diode.

With a capacity of the storage capacitor that is significantly larger is selected as that of the switch-off discharge capacitor, it results advantageously that the reverse voltage stress going beyond the DC supply voltage the first freewheeling diode is low.

Basically the same favorable mode of operation of the circuit arrangement according to the invention it arises when the Polarity of all diodes, of the controllable electronic switch and the DC voltage source vice versa is, so "positive" pole for "negative" pole and "anode '* for" cathode "interchanged are.

The invention is to be shown in the following with reference to in the drawing Embodiments are explained. 1 shows a basic circuit diagram of a Circuit arrangement according to the invention, FIG. 2 shows a circuit variant with modified ones Free-wheeling diode connections, FIG. 3 shows a circuit variant with a separate oscillating circuit, 4 shows a circuit variant with a modified connection of the switch-off relief capacitor, FIG. 5 shows a circuit variant with the opposite of the basic circuit diagram of FIG. 1 Polarity and FIG. 6 shows an anti-parallel connection of two pairs of electronic branches.

In Fig. 1, a DC voltage source is shown, between the positive and the negative pole is a DC voltage UD. Between the poles lies an electronic Branch pair consisting of a controllable electronic switch Th, e.g. a thyristor and a (first) free-running diode D is formed.

In series with the controllable electronic switch Th is a switch-on relief choke Le provided that the rate of rise of the current through the switch Th at its switching on is limited. Furthermore, a switch-off relief capacitor is parallel to the switch Th C, the speed of climbing of the blocking voltage on the switch Th limited when it is switched off.

To relieve this circuit arrangement of the energy loss when On and off operation of the switch Th are the following measures according to the invention required: To the one connected to the negative pole of the DC voltage source UD The anode of the free-wheeling diode Df1 of the branch pair (first free-wheeling diode) is the anode a second freewheeling diode Df2 connected. Between the cathodes of the first and the second freewheeling diode Df1 .und Df2 is a unipolar operated storage capacitor c switched. The cathode Sp of the first freewheeling diode Df1 is via the switch-on choke Le connected to the cathode of the controllable electronic switch Th. Whose Cathode is also connected to the cathode of a shutdown discharge diode D, the anode of which via a the switch-off discharge capacitor C to the positive pole a of DC voltage source UD is connected. The anode of switch Th is direct also at the positive pole of the DC voltage source UD. Between the anode the shutdown discharge diode D and the cathode of the second Freia running diode Df2 is a blocking diode Ds-connected with the forward direction to the turn-off relief diode D.

a The connection of the from the direct current source UD via the-.

electrical switch Th powered consumer can optionally - as indicated in the drawings at the points marked A or B. In addition, the connection is to a tap of the switch-on relief inductance Le possible. Further possible connection points arise when the switch-on relief inductance is formed from the series connection of several inductances However no fundamental advantages. These options regarding the connection exist for the load current, because there is generally a significant in series with the load Inductance is present. If this were not the case, the freewheeling diodes would be superfluous and the use of a pair of branches for switching would not make sense.

The one provided as the third energy storage device, which is only operated in a unipolar manner and large in its capacitance compared to the turn-off discharge capacitor Ca. Storage capacitor Csp, stores the energy of the two basically necessary Blind elements L and C temporarily between. This stored e a energy is after supplied to the load via the second freewheeling diode Df2 after the switch-off process. That The switch-off discharge capacitor Ca is then recharged after switching on of the controllable electronic switch Th, whereby the switch-on relief throttle, which is required anyway Le acts as a reversing throttle. In addition, there is Df2 via the diodes Da, D and 5 a circuit path that does not control the voltage at the controllable electronic switch Th can rise above the DC voltage UD.

In contrast to the circuit arrangement according to FIG. 1, the in The circuit variant shown in FIG. 2 does not show the anode of the first freewheeling diode Df1 with the negative pole of the DC voltage source UD, but with the cathode of the second freewheeling diode D f2 connected. However, this results in minor increased forward losses due to the series connection of the two freewheeling diodes Df1 and Qf2.

The circuit variant shown in FIG. 3 has directly in series with the blocking diode D5 as a further inductance a ringing throttle. Additionally is with the cathode of the second freewheeling diode D f2 the anode of a second turn-off discharge diode D a2 connected. Their cathode is at the cathode of the controllable electronic Switch Th.

These newly inserted elements form a more revealing sake Circuit dimensioning a separate oscillating circuit. The introduction of the separate Umschwingkreises for the charge reversal of the shutdown discharge capacitor Ca allows it, the amplitude of the ringing current, the a the controllable electronic switch Th is additionally charged after it has been switched on, to be reduced as required.

The circuit path that the voltage on switch Th does not have the Lets DC voltage UD rise, leads in this case via the diodes Da2 and Df2.

In Fig. 4 a circuit variant is shown in which the one Electrode of the cut-off discharge capacitor C a instead of the positive pole of the DC voltage source UD (see. Fig. 1) is connected to the negative pole.

Fig. 5 shows the circuit of Fig. 1 with reversal of the polarity of all Diodes, the controllable electronic switch Th and the direct voltage UD.

Can combinations of several inventive circuit arrangements in the form of anti-parallel and / or bridge circuits to achieve multi-quadrant operation insert.

Corresponding circuits are for example for the electronic Regenerative braking or reversing of DC motors as well as in self-commutated inverters needed.

6 shows an anti-parallel connection of a circuit arrangement according to the invention accordingly. 1 with one according to FIG. 5. Such a circuit enables both directions of the load current Iv. In the case of anti-parallel connections, it is necessary to the two pairs of branches by using decoupling diodes Dk and / or inductors - so-called transverse chokes Lk. - to be decoupled.

This prevents capacities from developing from the wiring of one branch pair when the other branch pair is switched on like a short circuit can discharge.

For the use of the measures according to the invention in anti-parallel connections the coupling shown in Fig. 6 is favorable. The inductance of the cross choke Lk only needs to be selected in the order of magnitude of the switch-on relief inductances Le to become. With appropriate control of the branch pairs, it could be completely omitted. However, it should be used for safety reasons, in particular to limit the short-circuit current in the event of malfunctions.

Claims (5)

Circuit arrangement for the relief of electronic pairs of branches from the Energy loss when switching on and off. Circuit arrangement for an electronic one between the poles of a DC voltage source (UD) Branch pair consisting of a controllable electronic switch (Th) and a free-wheeling diode (Df1) is formed to relieve the loss of energy when switching on and off, with one the rate of rise of the current through the controllable electronic Switch (Th) during its switch-on process limiting switch-on relief choke (Le) and one the rate of rise of the blocking voltage on the controllable electronic Switch (Th) during its shutdown limiting shutdown discharge capacitor (Ca), characterized in that to the with the negative pole of DC voltage source (UD) connected anode of the (former) freewheeling diode (Df1) the anode of a second freewheeling diode fl (Df2) is connected and between the Cathodes of the first and second freewheeling diode a storage capacitor (Csp) is connected that the cathode of the first freewheeling diode via the switch-on discharge choke (Le) is connected to the cathode of the controllable electronic switch (Th), the cathode of a shutdown discharge diode (D) is also connected to its cathode whose anode is connected to the positive via the cut-off discharge capacitor (Ca) Pole of the DC voltage source (UD), to which the anode of the controllable electronic Switch is connected, is connected, and that the anode of the shutdown discharge diode (D) -with a the cathode of a blocking diode (D5) is connected, the anode of which is connected to the The cathode of the second freewheeling diode (Df2) leads (Fig. 1). 2. Circuit arrangement according to claim 1, characterized in that that the anode of the first freewheeling diode instead of the negative pole of the DC voltage source (UD) is connected to the cathode of the second freewheeling diode (Df2) (Fig. 2). 3. Circuit arrangement according to one of claims 1 and 2, thereby characterized in that directly in series with the blocking diode (Ds) a reversing choke (tau) is inserted and that with the cathode of the second freewheeling diode (Df2) the anode of a second shutdown discharge diode (Da2) is connected, whose Cathode connected to the cathode of the controllable electronic switch (Th) is (Fig. 3). 4. Circuit arrangement according to one of claims 1, 2 or 3, characterized in that the electrode of the switch-off discharge capacitor (Ca) not with the positive pole of the DC voltage source (UD), but with its negative Pole or with another circuit point opposite the points mentioned has a largely constant potential difference, is connected. 5. Circuit arrangement according to one of claims 1 to 4, characterized characterized in that the capacitance of the storage capacitor (Csp) is large compared to the capacitance of the shutdown discharge capacitor (Ca).