DE1563178A1 - Starting circuit for a load-controlled converter - Google Patents

Description

Dlpl.-lng. Dipl. Oec. publ.

DIETRICH LEWINSKY ^ ZZZ ,,, *, 1563178 Nov. 18, 1966

Phone 56 17 62

ELIN-Union Aktiengesellschaft for electrical industry in Vienna

Start-up circuit for a load-commutated converter

Self-diffusing oscillators, in which some controlled calibrators or thyristors are used, are known. Thus, from the Austrian patent specification No. 226.829, a switching arrangement for “starting a self-oscillating thyristor oscillator can be found, with velcher the ignition process of the thyristors by means of a capacitor, a non-linear element, e.g. B. Gasent «charge tube, and an impedance permeable to direct current, triggered and thus the resonant circuit is triggered. Furthermore, transistor inverter circuits are known from patents in which the oscillation of the resonant circuit is triggered by making one of the two transistors in the inverter circuit conductive by means of a voltage pulse from a capacitor, thereby exciting the resonant circuit. After one of the transistors or thyristors becomes conductive *. the self-oscillation of the oscillator can be achieved by means of a feedback circuit, whereby the semiconductor valves are alternately ignited.

The invention relates to a switching arrangement for starting a load-controlled converter, with velcher for the charging process a separate auxiliary circuit is available, using the drawings that show an embodiment "in a load-controlled converter" represent »the invention is to be explained in more detail.

The exemplary embodiment is in the form of a block diagram in

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Fig. 2 shows · The converter consists of the controllable rectifier A in a known design and the downstream inverter, which is equipped with a filter throttle 3 and the thyristors 5 to 8. The resonant circuit C contains the resonant circuit capacitor 1 and the actual, predominantly inductive consumer 2, e.g. B. Coil of an induction furnace referred to below as load coil · The resonant circuit is shown in Fig. 1 within the thyristor bridge, the same designations being used. The auxiliary power source (alternating or direct current source) is designated with D, which supplies the necessary power via the start-up thyristor 4 to excite the resonant circuit.In Fig. 1, the inverter of the converter with the resonant circuit (capacitor 1 and load coil 2) and an alternating current Auxiliary circuit for the anrogen of the Schvingkreises, including the AnlaOthyristor 4, a Löschthyristor 9 and the other facilities for the Kilfskreis shown.

A controllable rectifier in a known design with feed from an alternating current or three-phase network or another controllable direct current source is provided for regulating the power to be supplied by the converter to the load coil 2. As is well known, a thyristor is either blocked or current-permeable and can only be converted from the blocked to the conductive state by means of a control pulse via its control electrode. Blocking the thyristor by means of the control electrode is not easily possible; this can normally only be achieved by applying reverse voltage to the thyristor for at least the duration of the so-called recombination time and thus a current zero crossing is achieved.

As the name suggests, a load-controlled converter derives its control impulses from the consumer or from the load. In the present "in the case of a resonant circuit in which the load coil 2 the inductive part of the Schvingkreises forms · Ss therefore a control device is required, which remove" the * a resonant circuit * the pulses in the firing pulses for the respective inverter ^·: converts ■ thyristors, where these thyristors in pairs -

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Thyristor 5 and 8 or 6 and 7 - ignited verden. However, this device is not the subject of this patent and is not included in the drawings. In order to be able to pick up the control pulses required to start up the inverter * in the converter, the oscillating circuit must be excited so that it can oscillate at its resonance frequency.

In order to stimulate the Schvingkreis, either the storage current i _fl from the rectifier to the downstream inverter must be quickly switched to the Schvingkreis, but because of the filter choke 3, the inductance of which is considerably greater than the Schvingkreisinduktivität 2 (load coil), technically not that easy, or to supply a slowly increasing auxiliary current i _H to the Schving circuit and to interrupt this auxiliary current quickly in relation to the expected Schving circuit resonance frequency after reaching its target value. In the invention, use is made of the last-mentioned possibility.To ensure that the Schving circuit continues to oscillate with its resonance frequency after the oscillation and thus the control pulses can also be picked up, the inverter is opened by opening a pair of thyristors - in the present example the thyristors 6 and 7 _{• An initial supply current i s is} supplied by the adjustable rectifier, which is opposite to the expected auxiliary current i _H via thyristor 4 and which, after this auxiliary _{current (i R} ) has been switched off, supports the starting process, with the auxiliary _{current i H} via the start-up thyristor, as mentioned above 4 after its target value has been reached, it is interrupted quickly in relation to the expected Schving circuit resonance frequency.

The switching arrangement according to the invention makes an auxiliary circuit necessary, but allows the initial _{supply current i s} to be slowly adjusted to its nominal value before the converter is actually put into operation, whereby the inductance 2 (load coil) in the shear circuit does not decrease due to the smallness of the current rise comes into effect and vircts the load coil as a short circuit. Ss there is practically no charging of the Schvingkreiskondensators 1 instead, since there is no potential difference at its connections. As soon as the nominal value of the initial supply current i _{ß is} reached, the auxiliary current i "which is significantly greater than the initial"

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The supply current must be switched on · The auxiliary current is also increased so slowly that the inductance of the load coil 2 in the resonant circuit does not take effect and there is practically a short circuit; there is therefore no significant charging of the resonant circuit capacitor 1 by the auxiliary power supply i _H. However, a strong magnetic field is built up in the load coil 2 due to the auxiliary _{starting current i H.} The starting thyristor 4 is switched on as soon as the output current i _{H has reached} its target value.After the starting thyristor 4 has been extinguished, the starting current caused by the self-induction (breakdown of the magnetic field) of the load coil 2 and the initial supply current i _fi in the oscillating circuit capacitor add up 1, through which this is charged and the resonant circuit is excited and can start to oscillate at its resonance frequency Thyristors open at this point in time - thyristors 6 and 7 in exemplary embodiment 1 - made it possible to set the initial feed current, blocked by the control device and the other pair of thyristors ignited before zero crossing of the resonant circuit voltage. By the ignition of letstgenannten thyristors - in the example the thyristors 5 and β - is at the open front · ago Thyristorenpaar thyristors 6 and 7 - Oegenspannung "placed so that the deletion verkUrst and the resonant circuit on the supply current i _s Veiter to swing stimulated. The rated current corresponding to the load can now be set with the aid of a 4-way controllable direct current source or rectifier. '

The frequency with which the inverter works in the converter, is only dependent on the resonance frequency of the oscillating circuit · Bei a given inductance of the load coil 2 is dl · Flux the working frequency only by changing the SchwingkrelskapazltXt possible. The upper limit frequency is from the recombination side the thyristors used in the inverter. Since a load-controlled converter receives its control pulses from Consumer, preferably an inductive load with capacitor j in oscillating circuit, its working frequency is not derived

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constant, as this can change during operation. Im dar « The inverter in the converter operates on a resonant circuit with low inductance in the case of a Resonance frequency from 1.5 to 4 kHz «

In the exemplary embodiment shown in the drawing (Fig. 1), the auxiliary current required to start the resonant circuit is taken from an alternating current network, whereby the start-up thyristor 4 is connected as a single-ended rectifier. This is only possible, however, if the switching circuit inductance is small enough and thus assured that the auxiliary _{current i H will reach} its nominal value during a half-cycle of the network. The starting thyristor a 4 is extinguished by igniting the extinguishing thyristor 9 »as soon as the auxiliary _{current i H} has reached its nominal value. Shortly after the firing of the extinguishing thyristor 9 is - since the auxiliary choke 10 does not allow a rapid increase in the auxiliary current and the Schvingkreisspan * voltage is initially small compared to the voltage of the capacitor 12 - the desired rapid interruption of the auxiliary circuit is achieved; the auxiliary capacitor 12 is then discharged via the ignited quenching thyristor 9 and via the auxiliary choke 10.

The charging of the auxiliary capacitor 12 takes place via the circuit 1. Secondary winding of auxiliary transformer 11 - auxiliary capacitor 12 - Resistor 14 - Diode 15 - Auxiliary Contact 16 - Transformatorvick « An electrolytic capacitor can also be used as an auxiliary capacitor if a diode 13 ensures that that no counter-tension can arise in it. Also then must the ohmic resistance of the circuit of the extinguishing thyristor 9 - auxiliary resistor » sol 10 - winding of the auxiliary transformer 11 - auxiliary diode 13 large be enough so that the permissible current in this circuit is not exceeded during a half cycle of the network · The contact 16 er « Enables the deletion of the thyristor 9, if this contact course is opened before the ignition of this thyristor

Instead of an AC-powered auxiliary circuit · can also

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• provided in a correspondingly powerful DC circuit. A DC auxiliary current circuit must, however, be provided if it is not ensured that when an AC circuit is used - even with a possibly lower frequency than the normal mains frequency - the auxiliary current i _H will reach its target value within a half period. Corresponding cut-out circuits for the starting thyristor 4 when using direct current, which enable a quick and safe interruption of the auxiliary circuit during the starting process, can be assumed as known.

Claims (2)

Claims Starting circuit for a load-guided converter whose inverter, which is equipped with controllable electrical valves - preferably thyristors - feeds a parallel resonant circuit, consisting of an inductive consumer and a capacitor, characterized in that an auxiliary circuit is available by means of which the predominantly inductive consumer (2) ( Load coil) is traversed by a current which acts against a small initial feed current from the main current side and thus a strong magnetic field is built up, with practically no voltage drop occurring at the load coil (2), and this auxiliary current is rapid with respect to the resonance frequency The oscillating circuit is interrupted, whereupon the energy stored in the load coil is transferred to the oscillating circuit capacitor (1) and the oscillating circuit starts to oscillate at its resonance frequency. 2. Circuit according to claim 1 »characterized in that the, helps · Circuit the inverter valves (thyristors 5 to 8) to «goes around, but by means of its own controllable electrical Valve (start-up thyristor 4) can be switched on and blocked 3 »Circuit according to claims 1 and 2, characterized thereby, that the auxiliary circuit when the current is flowing by means of a control. 909883 / <ifr $ 0 *: - W " ⁷ " 15631/8 electrical valves (thyristor 4) and a second extinguishing electrical valve (hole thyristor 9) can be quickly interrupted 4. Circuit according to claim 1, 2 or 3, characterized in that the auxiliary current is switched on only after the power supply of the inverter, which is presumably high inductance (choke 3), has been energized by igniting those electrical valves, which conduct the initial supply current (I ₈ ) through the predominantly inductive consumer (load coil 2) in the direction opposite to the auxiliary current that begins later and reaches a higher amount. 5 · Circuit according to one of Claims 1 to 4 »characterized in that there is one sufficient for supplying the auxiliary circuit A generous alternating current source is used «which operates at a frequency at which the auxiliary current Solla is certain value is reached in half a period. 6 · Circuit according to claim 1, 2, 3 or 4 · characterized in that that for the supply of the auxiliary circuit there is a fairly abundant direct current source with a quenching device for the driving thyristor (4) is used. 909883/0860