DE3513239A1 - Circuit network for feeding back circuit energy for semiconductor switches (for example GTO thyristors, power thyristors) - Google Patents

Abstract

The invention relates to a circuit network for feeding back circuit energy for semiconductor switches (for example GTO thyristors, power thyristors). It comprises the provision of a transformer (15) whose primary winding (15a) is connected on the one hand to the junction point (C) of the circuit capacitor (8) and of the circuit diode (6) and, on the other hand, is connected to a main connection of a semiconductor auxiliary switch (17), the other main connection of the semiconductor auxiliary switch (17) being connected to the junction point (B) of the circuit diode (5) and the circuit capacitor (7), the secondary winding (or windings) (15b) of the transformer being connected by means of rectifier diodes (13, 14) at the centre point to a voltage source (E2), which can also be the main voltage source (E1) on the converter, the semiconductor auxiliary switch (17) either being driven by an external control circuit or being switched on or off independently, by the voltage direction between the node points (B) and (C) of the circuit itself. <IMAGE>

Description

Wiring network for the return

Wiring power for semiconductor switches (e.g. GTO thyristors0 Power thyristors) The invention relates to a wiring network for feedback the wiring energy for semiconductor switches according to claim 1.

Circuits for semiconductor switches (hereinafter abbreviated to HLS) are intended to reduce the current and voltage stress on the HLS when switching it on and off.

A throttle that is connected in series with the HLS is used the rate of current rise when switched on is limited and by a, about a diode in parallel to the HLS capacitor will increase the rate of voltage rise limited when switched off.

The disadvantage of such circuits are the power losses that caused by the stored energy in the wiring elements. To one To effectively relieve HLS, the relevant wiring elements must be in one are almost in a de-energized state; that is, before switching on the HLS the inductor current must be zero and the capacitor voltage must be zero before switching off. Therefore, with each switching cycle, which includes a switch-on and a switch-off process, the saved Completely dissipate energy from the wiring elements.

The easiest way to do this is to transform these energies in heat loss through ohmic resistors. To do this, a resistor is placed parallel to the Wiring diode of the capacitor branch and accordingly a resistor with a Diode connected in parallel to the wiring choke.

In particular, at higher switching frequencies there is a power loss that increases the efficiency of the converter in question by a few percentage points worsened.

A circuit arrangement is already known which has the aim of the wiring energy almost loss-free either from the supply voltage source or to feed the load (Marquart, R. "Investigation of converter circuits with GTO thyristors ", dissertation TU Hannover, 1982).

The disadvantage of this wiring arrangement is, on the one hand, its large number the components required in addition to the actual relief circuit (storage capacitors, Chokes, blocking diodes), on the other hand, that they have a load current-dependent behavior shows that there is an additional capacitor, which the circuit energy of the relief circuit in the meantime stores, has to be discharged from the load current.

The task is therefore to create a wiring network for feedback Specify the wiring energy for semiconductor switches, through which the wiring energy is returned with almost no loss. This object is achieved according to the invention solved the features listed in the characteristics of the claims.

The wiring network according to the invention is shown in the following described embodiments explained in more detail with reference to drawings.

In Figures 2 and 3, E is that of the rectifier one Inverter referred to impressed DC voltage in the intermediate circuit. Instead of this Voltage can also be the voltage of a special DC voltage source will.

The GTO thyristors 1 and 2 form a valve branch pair of an inverter 100. The GTO thyristor 1 is a flyback diode 3, the GTO thyristor 2 is a flyback diode 4 connected in parallel in opposite directions. With terminal A is the AC connection designated. In parallel with the GTO thyristor 1, there is also the series connection of a wiring capacitor 7 and a diode 5 arranged, this diode in the same direction as the GTO thyristor 1 is polarized. In parallel with the GTO thyristor 2 is in a corresponding manner the series connection of a diode 6 and a circuit capacitor 8 arranged, this diode being polarized in the same direction as the GTO thyristor 2.

With 15a is the primary winding, with 15b is the secondary winding Feedback transformer 15 referred to. The primary winding 15a is on the one hand over a semiconductor auxiliary switch, here a field effect transistor (MOSFET), 17 and a wiring diode 5 connected to the switch-on relief choke 16, on the other hand via the other wiring diode 6 to the other connection of the switch-on relief choke tied together.

The secondary winding 15b of the feedback transformer 15 is via a uncontrolled rectifier two-way circuit, consisting of diodes 13 and 14 with connected to a voltage source E2, which can also be the supply voltage source El.

The semiconductor auxiliary switch 17 is then always conductive in the current direction controlled from D to S when the potential is at the point marked Connection of the secondary winding 15a positive compared to that with a B. designated The junction of the circuit. The semiconductor auxiliary switch 17 has the task of to enable demagnetization of the feedback transformer 15 on the secondary side. The necessary reverse voltage of the semiconductor auxiliary switch 17 is low in comparison to that of the main valve of the circuit and depends on the transmission ratio of the feedback transformer, which will be approximately 1:10 to 1:20 in practice; That means, that only a tenth to a twentieth of the supply voltage as a positive reverse voltage to the semiconductor auxiliary switch can occur. In reverse direction prevents one Diode connected in parallel in opposite directions the creation of a reverse voltage.

The following is the mode of operation of the circuit according to the invention are explained in more detail. Let us assume the initial state that there is a constant load current IL flows through the diode 4 to the output terminal A and that the HLS 1 is currently conducting is switched. The current then commutates from the flyback diode 4 via the choke 16 in HLS 1.

As soon as the HLS 1 has then completely taken over the load current and the diode 4 is blocked, oscillating currents begin via the wiring capacitors 7 and 8 and the circuit choke 16 to flow. The one oscillating current, the one over the capacitor 7, the HLS 1, the choke 16, the diode 6, the transformer winding 15a and the auxiliary switch 17 flows back to the capacitor 7, leads to discharge of the capacitor 7, while at the same time the capacitor 8 is charged to the same extent is caused by an oscillating current that is generated via the supply source EI, the HLS 1, the throttle 16, the diode 6 and the capacitor 8 flows back to the supply source. Since the discharge oscillation current of the capacitor 7 leads via the transformer 15, part of the wiring energy is already used of the capacitor 7 delivered to the supply source. Once the capacitor 7 is complete discharged and the capacitor 8 is charged to El, the choke 16 begins its energy to submit via the transformer 15. It does this by drawing a current from the choke above the diode 6, the primary winding 15a, the auxiliary switch 17 and the diode 5 back flows to the throttle 16. The energy delivery of the throttle 16 is complete as soon as the inductor current has fallen back to the value of the load current IL. So is the energy of the switch-off discharge capacitor apart from the ohmic losses in the switching circuits have been completely fed back to the supply source. This The process is repeated in a similar way when the HLS 2 becomes conductive. When switching off of a valve, the wiring capacitors of both HLS are effective at the same time, so that the effective capacity for the voltage rise at the HLS doubles compared to conventional RCD wiring arrangements. To the same extent as the voltage a circuit capacitor increases, it decreases with the others, so that these in their effect when switching off two capacitors of the same size connected in parallel correspond.

With the present invention it is possible to reduce the wiring energy both the switch-on discharge choke and the switch-off discharge capacitor after each switching process of the HLS concerned directly via a transformer of the supply source or to another voltage source with almost no loss. The network after the invention can be used in inverters (FIGS. 1 and 2) as well as in DC converters (Fig. 3) or DC converters are used.

An additional advantage of the present invention is in inverter applications (Execution in Fig. 1) in that the wiring capacitors of an inverter branch pair (Phase) cooperate when switching off an HLS and thus only half of each Capacity compared to conventional RCD circuits.

Claims (3)

Wiring network for the return of the wiring series for semiconductor switches (e.g. GTO thyristors, power thyristors) Claims 1. Wiring network to return the wiring energy for semiconductor switches (e.g. GTO thyristors, Power thyristors), characterized in that in the case of pairs of valve branches of converters with intermediate circuit (or inverters with DC voltage source), where parallel to each semiconductor switch (1,2) a series circuit consisting of one Wiring capacitor (7,8) and one - in the same direction as the semiconductor switch polarized - diode (5,6), as well as between the cathode (emitter) of a semiconductor switch (1) and the anode (collector) of the other semiconductor switch (2) a choke (16) lies, a) a transformer (15) is provided, the primary winding (15a) of which on the one hand to the connection point (C) of the wiring capacitor (8) and the wiring diode (6) is connected and on the other hand to a main terminal of a semiconductor auxiliary switch (17) is connected, the other main terminal of the semiconductor auxiliary switch (17) with the connection point (B) .the wiring diode (5) with the wiring capacitor (7) is connected, b) the secondary winding (or windings) (15b) of the wiring capacitor (15) with rectifier diodes (13, 14) in the center with a voltage source (E2), which is also the main voltage source (E1) of the converter can be, are connected, c) the semiconductor auxiliary switch (17) either by one external control circuit is controlled or depending on the voltage direction between the nodes (B) and CC) of the circuit itself switched on or off will. 2. wiring network according to claim 1, characterized in that for the valve branch pairs of converters with intermediate circuit voltage (or inverters with DC voltage source), with a parallel to one of the semiconductor switches (2) Series connection, consisting of a wiring capacitor (8) and one - in same direction as the semiconductor circuit polarized diode (6), as well as between the cathode (emitter) of a semiconductor switch (2) and the negative terminal the intermediate circuit voltage (11) has a choke (16), a) a transformer (15) is provided is, whose primary winding (15a) on the one hand with the negative connection of the intermediate circuit voltage (11) and on the other hand with a main connection of a semiconductor auxiliary switch (17) is connected, the other main connection of the semiconductor auxiliary switch (17) with the connection point (B) of the wiring diode (6) with the wiring capacitor (8) is connected, b) the secondary winding (or windings) (15b) of the transformer with rectifier diodes (13,14) in the center with a voltage source (E2), the also be the main voltage source (El) of the converter can, are connected, c) the semiconductor auxiliary switch (17) either from an external Control circuit is controlled or depending on the voltage direction between the nodes (B) and (C) of the circuit itself is switched on or off. 3. wiring network according to claim 1, characterized in that with a DC chopper in the network parallel to the semiconductor switch (2) a series circuit consisting of a wiring capacitor (8) and the same Direction like the semiconductor switch polarized diode (6) as well as between the anode a freewheeling diode (3) and the anode of the semiconductor switch (2) a choke (16) lies, a) a transformer (15) is provided, the primary winding (15a) of which on the one hand to the connection point (C) of the wiring capacitor (8) and the wiring diode (6) is connected and on the other hand to a main terminal of a semiconductor auxiliary switch (17) is connected, the other main terminal of the semiconductor auxiliary switch (17) with the connection point (B) of the wiring diode (5) with the wiring capacitor (7) is connected, b) the secondary winding (or windings) (15b) of the transformer with rectifier diodes (13, 14) with a voltage source (E2), which is also the main voltage source (El) of the converter can be connected, c) the semiconductor auxiliary switch (17) is either controlled by an external control circuit or dependent on the voltage direction between nodes (B) and (C) of the circuit itself turned on or off.