DE1563178C3 - Process for starting a load-commutated resonant circuit converter and circuit arrangement for carrying out the process - Google Patents

Description

can swing.

In order to stimulate the oscillating circuit to oscillate, either the supply current i _s from the rectifier to the downstream inverter must be quickly switched to the oscillating circuit, but this is technically not very easy because of the filter throttle 3 in the DC link, the inductance of which is considerably greater than the inductance of the consumer 2 or to supply the oscillating circuit with a starting auxiliary current in increasing slowly compared to the period "of the converter output voltage and quickly switch off this auxiliary current in relation to the expected oscillating circuit resonance frequency after reaching its setpoint value. The method according to the invention makes use of the last-mentioned possibility after the oscillation continues at its resonance frequency and thus the control pulses for the controllable electrical valves of the inverter can also be picked up, the inverter is activated by opening a pair of thyristors - in advance lying embodiment the thyristors 6 and 7 - from the controllable rectifier an initial supply current is, which is below the value of the starting auxiliary current /// and below the value of the nominal inverter current, which is directed in the opposite direction to the expected auxiliary starting current in via starting thyristor 4. The setpoint value of this initial feed current i _s is set either by adjustment by means of the controllable rectifier or by switching on a direct current partial voltage which results in the setpoint value of the initial feed current. The rise time of the initial supply current i _s is defined by the inductance of the filter choke 3 and the direct current resistance of the entire circuit, consisting of consumer 2 filter choke 3 and the supplying network. Since the direct current resistance in the exemplary embodiment mentioned was extremely small compared to the loss resistance of the oscillating load circuit, the rise time of the initial feed current i _s was of the order of magnitude of a second. The inductance of the filter choke 3 in the direct current intermediate circuit results from other considerations, such as, for. B. the short-circuit behavior of the converter. In the case of differently dimensioned circuits, however, the rise time could go down to approximately four times the period duration of the converter output voltage without the inductance of the consumer 2 causing a disturbance in the oscillation process.

When the initial feed current i _{s has reached} its setpoint value, the auxiliary starting current i _{H is switched on} with the aid of the starting thyristor 4. If the starting auxiliary current i'h has reached its setpoint value, then it is - as already stated above - quickly interrupted in relation to the expected resonant circuit resonance frequency by extinguishing the starting thyristor 4. After the auxiliary starting current in has been switched off , the initial supply current i _s supports the oscillation of the oscillating circuit.

The method according to the invention makes an auxiliary circuit necessary in terms of circuitry, but allows the initial feed current i _s to be adjusted to its setpoint value before the converter is actually put into operation, whereby the inductance of consumer 2 in the resonant circuit does not come into effect due to the smallness of the current rise and consumer 2 acts practically as a short circuit. There is also practically no charging of the resonant circuit capacitor 1, since there is no potential difference at its connections. As soon as the nominal value of the initial feed current i _{s is} reached, the starting thyristor 4, as already mentioned above, switches on the auxiliary starting current i _H , which is opposite to the initial feed current i _s in the consumer 2. The auxiliary starting current i'h also increases slowly compared to the period duration of the converter output voltage, which is ensured by the auxiliary choke 10 in the auxiliary circuit. As far as the ratio of the initial supply current i _s to the auxiliary starting current in is concerned, these currents should behave roughly like the active and reactive power of the load circuit, since then optimum oscillation occurs. In the exemplary embodiment, the auxiliary starting current i'h is significantly greater than the initial feed current i _s . As far as the rise time of the auxiliary starting current in is concerned, this is closely related to the output frequency of the converter. In the present exemplary embodiment, the output frequency was 1.5 to 4 kHz; this results in a minimum permissible rise time of around 2.5 ms. Thus, since the final value (target value) from the starter auxiliary power in during a half cycle of the supplying AC voltage (50 Hz mains) can be reached, a half-wave rectifier circuit has been used with Anlaßthyristor 4 as a rectifier for the occasion auxiliary circuit, which represents in this case the cheapest option.

Since the auxiliary starting current also rises relatively slowly, as previously described, the inductance of the consumer 2 in the resonant circuit does not have any effect and the consumer 2 is practically a short circuit; there is therefore no significant charging of the resonant circuit capacitor 1 by the auxiliary starting current in . The cause auxiliary power in which, as already mentioned, i is substantially greater than the initial feed stream _s is initially reverses the effect of the current i _s in the load 2, and then establishes a strong magnetic field. Deleting the Anlaßthyristors 4 occurs rapidly in relation to the expected resonant circuit resonance frequency as soon as the occasion auxiliary power has reached its setpoint. After the starting thyristor 4 has been extinguished, the starting current caused by the self-induction (collapse of the magnetic field) of the consumer 2 and the initial feed current / _s in the resonant circuit capacitor 1 add up, which charges it and stimulates the resonant circuit and can oscillate at its resonance frequency. The resonant circuit voltage occurring here is used to control the thyristors 5 to 8 of the inverter in the converter with the interposition of a corresponding control device. When the current in the resonant circuit passes through zero, the thyristors open up to this point in time - in the exemplary embodiment (Fig. 1) the thyristors 6 and 7, which enable the initial supply current i _s to be set - are blocked by the control device and the other thyristor

bo couple before the zero crossing of the Resonant circuit voltage ignited. By igniting the last-mentioned thyristors - in the example the Thyristors 5 and 8 - is connected to the previously open thyristor pair - thyristors 6 and 7 - counter voltage

Iv-, voltage placed so that the extinguishing process is shortened and the resonant circuit is further stimulated to oscillate by the supply current i _s. The load can now be controlled with the help of the controllable direct current source or rectifier

bJ i 78

corresponding nominal current can be set.

The frequency with which the inverter works in the converter depends only on the resonance frequency of the oscillating circuit. For a given inductance of the consumer 2, the influence is the Working frequency only possible by changing the resonant circuit capacitance. The upper limit frequency is of the Recombination time of the controllable electrical valves used in the inverter addicted. Since a load-controlled converter receives its control pulses from the consumer, preferably one inductive load with a capacitor in a resonant circuit circuit, if its operating frequency is not constant, since this can change during operation. In the illustrated embodiment, the inverter works of the converter to a resonant circuit with low inductance and a resonance frequency of 1.5 up to 4 kHz.

In the embodiment shown in the drawing (FIG. 1), the auxiliary starting current required for starting the resonant circuit is taken from an alternating current network, the starting thyristor 4 being connected as a half-wave rectifier. However, this is only possible if the resonant is small enough and ensured that the occasion auxiliary reached its target value during a half period of the network. The starting thyristor 4 is extinguished by igniting the extinguishing thyristor 9 as soon as the auxiliary starting current has reached its nominal value. Shortly after the firing of the quenching thyristor 9 - since the auxiliary choke 10 does not allow a rapid increase in the auxiliary starting current and the resonant circuit voltage is initially small compared to the voltage of the auxiliary capacitor 12 - almost the entire voltage of the auxiliary capacitor 12 is applied as a blocking voltage to the starting thyristor 4, which results in the desired rapid interruption of the auxiliary circuit is reached; 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 of the first secondary winding of the auxiliary transformer 11 - auxiliary capacitor 12 - resistor 14 - diode 15 - auxiliary contact 16 - transformer winding. An electrolytic capacitor can also be used as an auxiliary capacitor, if with an auxiliary capacitor 13 care is taken that no counter-tension can arise on it. Also then must the ohmic resistance of the circuit extinguishing thyristor 9 - auxiliary choke 10 - winding of the auxiliary transformer 11 - Auxiliary diode 13 must be large enough so that the permissible current in this circuit during a half cycle of the Network is not exceeded. The auxiliary contact 16 enables the extinguishing thyristor 9 to be deleted, if this contact is opened shortly before the ignition of this thyristor.

Instead of an AC-powered auxiliary circuit, a correspondingly powerful DC circuit can also be provided. A DC auxiliary circuit must, however, be provided if, when using an AC auxiliary circuit - even with a possibly lower frequency than the normal mains frequency - it is not ensured that the auxiliary starting current i'h will reach its nominal value within half a period. Corresponding quenching circuits for the ¹ starting thyristor 4 when using a direct current auxiliary circuit, which enable a quick and reliable interruption of the auxiliary circuit during the starting process, can be assumed to be known.

For this purpose 2 sheets of drawings

Claims (1)

ι ο υ _j i / o 1 2 valves are ignited alternately. Claims: The invention is based on the object of providing a method of the type specified in the introduction as well as 1. A method for starting a load-controlled circuit arrangement for carrying out its oscillating circuit converter, to create its controllable 5, which allow an inverter equipped with an oscillating circuit electric valve to be started by contactless triggering or excitation consisting of an inductive consumer and a load parallel oscillating circuit.
This object is achieved by the features characterized in claim 1, which is based on an auxiliary starting circuit,
indicates that the resonant circuit is designed as an arrangement for carrying out the parallel resonant circuit method, which is characterized in claim 2.
Starting auxiliary circuit an auxiliary starting current (i'h) in such a way using the drawings, which are part of an implementation, that the load represents a game of a load-controlled converter, the strong magnetic field is to be built up, the invention being explained in more detail.
Auxiliary starting current (in) an initial feed current flowing in via the AC circuit diagram in FIG. The converter consists (i _s ) counteracts the value of which is below the value from the controllable rectifier Λ in, known per se, of the auxiliary starting current (in) and below the value execution and the downstream inverter of the inverter rated current, that the A B, which with a Filter choke 3 and the thyristors 5 circuit of the auxiliary starting current (in) only then 20 to 8 is equipped. The resonant circuit C contains which is made when the initial feed resonant circuit capacitor 1 and the actual current (i _s ), which via the inverter of the predominantly inductive consumer 2, z. B. the coil oscillating circuit converter the parallel oscillation of an induction furnace. The resonant circuit is supplied in Fig. 1, its setpoint has reached within the thyristor bridge of the inverter and that the starting auxiliary current (i _H ) is shown quickly with respect to 25, the same designations being applied to the resonant frequency of the parallel resonant circuit. D is the auxiliary power source (alternating switching off as soon as it has reached its setpoint value or direct current source) which has reached the required level. Similar performance via the starting thyristor 4 for 2. Circuit arrangement for carrying out the excitation of the resonant circuit supplies. In Fig. 1 the method according to claim 1, characterized in that the inverter of the converter with the oscillating circuit is characterized in that the auxiliary starting current (i _H ) is alternating current by means of a (capacitor 1 and consumer 2) and a controllable electrical valve (starting thyristor 4) Auxiliary circuit that is switched on and blocked via the terminals. R and S is fed to excite the Resonant circuit including the starting thyristor 4, 35 of a quenching thyristor 9 and the other facilities '.,. shown for the auxiliary circuit. The invention relates to a method for a controllable rectifier in a known per se Starting a load-commutated oscillating circuit converter. Execution with supply from an inverter or according to the preamble of claim 1. One such method for starting a load source of electricity is to supply power to the exchangeable The oscillating circuit converter is from the BBC converter bridge and for controlling the converter Nachrichten, December 1964, pages 637-647, the power to be delivered to the consumer 2 is provided. The oscillating circuit is there as a series of oscillations. As is well known, a thyristor is either blocked circuit and it is a starting auxiliary circuit or current-permeable and can be switched from the blocked to the Charging device is provided, which only transmits the oscillating conductive state by means of a control pulse circular capacitor and be transferred for the choice of its control electrode. A blocking frequency range There is no switchable compensation cone for the thyristor by means of the control electrode precharges capacitors to a certain voltage, so that easily possible; normally this can only after closing the switch the load oscillation can be achieved by at least for the circle of the oscillating circuit converter the necessary 50 duration of the so-called recombination time voltage Receives control signals in time with the resonance frequency. placed in the blocking direction on the thyristor and thus a From AT-PS 2 26 829 a circuit arrangement current zero crossing is achieved. tion for starting a self-oscillating As the name suggests, a load-controlled conducts Thyristor oscillator with parallel resonant circuit to de- converter its control pulses from the load. in the take, in which the ignition process of the thyristors 55 present case, the consumer 2 forms the by means of a capacitor and a part of an oscillating circuit that is inductive for direct current. It is therefore a Permeable impedance triggered and thus the control device required, which is the vibrating ^; Resonant circuit is triggered. Furthermore, transistor circuit pulses are to be decreased in ignition pulses for the / Inverter circuits known iDE-ASlOOg 675), converts inverter thyristors, whereby each in which the oscillation of the resonance 60 these thyristors in pairs - thyristor 5 and 8 or 6 ■ circle is triggered by means of a and 7 - are ignited. However, this facility is Voltage pulse from a capacitor is not an object of the invention, but only the ' of the two in the inverter circuit are listed for the sake of completeness and therefore not in which transistors are made conductive and thus contain that of the drawing. To get the commissioning ' Oscillator is excited. After one of the trans- 65 of the inverter in the inverter required i- sistors has been made conductive, the self-control pulses from the resonant circuit To be able to oscillate the oscillator through a feedback menu, the oscillating circuit must be excited. circuit can be achieved, whereby the semiconductors are so that it adapts to its resonance frequency