DE4344093C1 - Circuit arrangement for protection of the semiconductor switches when a mains converter bridge, which feeds energy back into an electrical mains power supply, switches over in a DC intermediate-circuit converter - Google Patents

Abstract

The main Patent P 4322379 describes switching-over protection for two mains converter bridges, which are connected to the electrical mains power supply via radio suppression filters, are operated without any circulating current and are connected in parallel in opposition, in a DC intermediate-circuit converter operating in the four-quadrant mode. In this case, a short-circuiting thyristor which bridges over the terminals, on the intermediate-circuit side, of the mains converter bridges is triggered when the generated intermediate-circuit current or the input voltage on the mains side exceed upper limits. In order that the short-circuiting thyristor is not triggered in the case of mains converter bridges which are protected by input fuses on the mains side, in the event of external mains overvoltages and operation of the motor mains converter bridge, and in order that the fuses are thus not triggered, the rectified input voltage (UGmains) on the mains side is passed, according to the invention, via an AND gate (19) in addition to the evaluation of the generated intermediate-circuit current (IdG') for triggering of the short-circuiting thyristor, which AND gate (19) at the same time receives a signal (GEN) which indicates operation of the generator mains converter bridge. <IMAGE>

Description

The invention relates to a circuit arrangement according to the features listed in the preamble of the claim according to patent P 43 22 379.

The circuit arrangement according to the main patent is shown in the basic circuit diagram of FIG. 2 of the drawing.

A line converter connected via a radio interference filter 3 , input fuses 14 and commutation reactors 4 to a three-phase network L1, L2, L3 and an intermediate circuit of a DC link converter, which is to operate in four-quadrant mode, are shown. The line-guided converter consists of a six-pulse line converter bridge 1 constructed from thyristors for charging an intermediate circuit capacitor 9 with an intermediate circuit voltage Ud and a second line converter bridge 2 connected to it in antiparallel and likewise consisting of thyristors for discharging the intermediate circuit capacitor 9 . The line converter bridges 1 , 2 are controlled in a circuit-free operation.

The radio interference filter 3 between the mains L1, L2, L3 and the terminals of the mains converter prevents repercussions via the mains-operated converter bridges 1 , 2 , the DC voltage intermediate circuit and a pulse inverter (not shown) connected to the intermediate circuit capacitor 9 with its voltage U _D (the one with a likewise load, not shown, ie generally connected to a motor) to the supply network L1, L2, L3. The combinations of choke coils and capacitors contained in the radio interference suppression filter 3 act as a voltage-increasing energy store when the mains voltage fails while operating the energy from the intermediate circuit feeding the mains converter bridge 2 back into the mains.

A DC converter 5 detects a current, depending on the direction in the intermediate _circuit, labeled I _dG or I _dM via the intermediate _circuit-side terminals of the line _{converter bridges} 1 , 2 and carries a corresponding quantity I _dG '(not shown in FIG. 2) of a control logic of an anti-tip device for evaluation to.

In its power section, the anti-tipper itself consists of a short-circuit thyristor 6 and a relief diode 8 . The latter is intended to prevent DC link chokes 7 from being demagnetized only via free-wheeling diodes (not shown) of a connected self-commutated converter (pulse-controlled inverter).

If only this self-commutated converter is off IGBT (Insulated Gate Bipolar Transistor) elements formed are only free-wheeling diodes integrated in the IGBTs available. However, these integrated freewheeling diodes are from Switch-off integral not for those occurring in the event of a short circuit Dimensioned surge currents.

If, on the other hand, freewheeling diodes are present in the self-commutated converter (pulse inverter) at the connection of the intermediate circuit capacitor, which can lead to high short-circuit currents, the relief diode 8 may be dispensed with.

The short-circuit thyristor 6 is always ignited by an ignition signal Z when the current detected by the DC-DC converter 5 exceeds a certain current amplitude or the voltage amplitude reaches impermissible values. The ignition signal Z is conducted via a drive amplifier 13 for the short-circuit thyristor 6 . A mains transformer 10 with a rectifier bridge 11 connected downstream is provided for detecting the mains voltage or overvoltages at the input of the mains converter. At the output of the rectifier bridge 11 there is a smoothing capacitor 12 which provides a quantity U _GNet control logic of the anti-tipper that is proportional to the mains voltage.

By igniting the short-circuit thyristor 6 when a certain level of the voltage amplitude at the line-side input of the line converter bridges or the current amplitude of the direct current flowing through the intermediate circuit terminals of the line converter bridges, the intermediate circuit voltage U _D predetermined by the intermediate circuit capacitor 9 is short-circuited via the intermediate circuit chokes 7 . The short-circuit thyristor 6 is dimensioned so that it can temporarily take over the stored intermediate circuit energy. The resulting upon ignition of the Kurzschlußthyristors 6 resonant circuit, formed from the intermediate circuit capacitor 9 and the intermediate circuit coils 7, stores the energy by a current half-wave in the intermediate reactors. 7 As mentioned, the intermediate circuit chokes 7 are then demagnetized via the relief diode 8 (or the freewheeling diodes in the self-commutated converter, not shown, connected to the intermediate circuit capacitor 9 ).

The ignited short-circuit thyristor 6 is intended to specifically dissipate the energy of the intermediate circuit capacitor 9 when the line-guided converter bridge 2, which feeds the energy from the intermediate circuit into the network, so that the input fuses 14 do not respond. In addition, it is prevented that semiconductor components are destroyed by overvoltages when the mains voltage is switched off by the radio interference filter 3 acting as an energy store and the mains converter bridge 2 is operated simultaneously.

During operation of the power from the network converter bridge 1 , unwanted voltage peaks can now occur due to external switching actions in the supply network L1, L2, L3, which control the short-circuit thyristor 6 via the detection for the line voltage amplitude of the control logic of the anti-tipper and thus by a short circuit on the output side allow mains-operated converter bridge 1 to respond to input fuses 14 .

By Holtz, J .: "Stresses in Frequency inverters with uncontrolled supply circuit in the stationary operation and pulse-shaped when it occurs Network surges "In:" etz-Archiv "Volume 11 (1989) Issue 6, Pages 169 to 178 is a protective device for the Valves of a pulse inverter in one Frequency converter with an uncontrolled Feed circuit in the form of a three-phase diode bridge known. The protective device closes the DC-side terminals of the diode bridge through a protection thyristor short if a pulse-shaped Mains overvoltage occurs. With that and with additional Melt upstream from the diode bridge Mains fuses prevent further energy from coming out downstream of the network in one of the diode bridges Support capacitor is fed. But in particular, too achieved that occurs on the backup capacitor, for the  Valves of the downstream pulse inverter dangerous overvoltage is quickly eliminated. One of the Support capacitor in parallel and opposite to operational polarity directional diode prevents Run subsequent vibrations in one by one in the DC circuit lying choke and Support capacitor formed resonant circuit training negative voltages at the backup capacitor.

The invention has for its object at the outset specified circuitry to prevent that Operation of energy from the grid Converter bridge and occurring simultaneously Surge peaks in the network are the input fuses address unnecessarily.

This object is achieved according to the invention by the Characteristics characterized solved.

The operational safety of the line-guided converter is thus advantageously increased, since the anti-tip only specifically addresses when it is necessary.

The invention will be explained below with reference to an exemplary embodiment for the control logic of the anti-tipper shown in FIG. 1 of the drawing:

The inputs of a voltage _comparator 15 are supplied on the one hand via an input resistor 21 with the _value U _GNet corresponding to the rectified mains voltage and, on the other hand, a reference voltage corresponding to the mains _{overvoltage limit is input} via voltage divider resistors 22 , 23 . If the voltage level determined by the reference voltage is exceeded by the variable U _GNet , the output A _{U of} the voltage _comparator 15 reports an H signal, which is fed to an AND gate 19 via a first monostable multivibrator 17 with a defined pulse length. The AND gate 19 transmits this input signal for the purpose of firing the short-circuit thyristor 6 ( FIG. 2) to an OR gate 20 only when the regenerative power converter bridge 2 , ie the energy that feeds back into the network L1, L2, L3 from the intermediate circuit, is in operation is what is indicated by a signal GEN also supplied to the AND gate 19 . Ignition of the short-circuit thyristor 6 by a signal Z at the output of the OR gate 20 during operation of the motor-driven power converter bridge 1 , ie drawing energy from the network L1, L2, L3, is prevented since the signal GEN does not occur during its operation.

In parallel to the voltage comparator 15 , a current comparator 16 works , at one input of which a decoupling diode 27 for detecting the regenerative intermediate _circuit current, _i.e. a current I _dG via the intermediate circuit terminals of the power converter bridge 2 feeding the energy back into the network, and an input resistor 24 the signal supplied by the current transformer 5 I _dG 'is placed. Via two further divider resistors 25, 26 , the other input of the current comparator 16 is supplied with a reference signal corresponding to the overcurrent limit at which the anti-tipper is to respond. The output signal at the output A _{I of} the current comparator 16 , which is emitted when the size I _dG 'corresponding to the generator intermediate circuit current' exceeds the reference signal, is the input variable of a second monostable multivibrator 18 with a likewise defined pulse length. The output of this second monostable multivibrator 18 is also connected to the OR gate 20 for emitting the ignition signal Z for the short-circuit thyristor 6 .

Claims (1)

Circuit arrangement for protecting the semiconductor switches when a line-guided, power converter bridge that feeds energy back into the network is operated, which is operated in a four-quadrant mode DC link converter converter, which operates in four-quadrant mode, with a second, DC-link converter converter operating in a four-quadrant mode, with a second, line-connected energy drawing from the network in antiparallel Clamps of a load-side, self-commutated converter DC link capacitor is connected to the two line converter bridges via at least one DC link choke and the DC link side output of the two line converter bridges is bridged and connected in parallel with a short-circuit thyristor which flows through a mains overvoltage and / or an overcurrent flowing through the DC link terminals of the line converter bridges whose intermediate circuit capacitor is opposite to the operational polarity of the intermediate circuit ndensator-directed relief diode is connected according to patent P 43 22 379, characterized in that

• - That in the case of line-side input _fuses ( 14 ) protected by line converter bridges ( 1 , 2 ), the rectified line voltage (U _GNETZ ) is _fed to one input of a voltage _comparator ( 15 ) connected on the output side to a first monostable multivibrator ( 17 ), at the other input one of which Mains overvoltage limit corresponding reference voltage,
• - That the first monostable multivibrator ( 17 ) is connected on the output side to an input of an AND gate ( 19 ), the second input of which is supplied with a signal (GEN) indicating the operation of the energy feeding the energy back into the power supply bridge ( 2 ),
• - That an input of a current comparator ( 16 ) has a signal (I _dG ') corresponding to the current flowing back through the intermediate circuit terminals of the energy feeding the power converter bridge ( 2 ), and the other input of the current comparator ( 16 ) represents an overcurrent limit Reference signal are supplied and
• - That the output of the current comparator ( 16 ) is connected to the input of a second monostable multivibrator ( 18 ), the output of which, like the output of the AND gate ( 19 ), is connected to an OR gate ( 20 ) which ignites the short-circuit thyristor ( 6 ) are.