DE1638236A1 - Control circuit with thyristors - Google Patents

Description

Sven iiils Johannes Lirinr-.cn, Lldin ^ ^: ö / oc2

Control circuit with thyristors,

The present invention relates to a control circuit for power control of direct current, the one Sutzkreis flows through with a certain resistance and inductance. In such circuits a main thyristor with the Mutzkreis, and an auxiliary thyristor for clearing the main thyristor a capacitor connected in series with an auxiliary resistor. The main thyristor is activated by applying a control pulse its control electrode is brought into the conductive state, i.e. "ignites", and is activated by the application of a control pulse to the Control electrode of the auxiliary thyristor in its blocking state brought, i.e. "extinguished".

Control circuits that work on this principle are already known per se. By supplying control pulses to the control electrodes of the main and auxiliary thyristors with different Time intervals, the periods during which the main thyristor is ignited can be varied as desired, with the Average value of the current flowing through the main thyristor will also vary. During the deletion periods of the main thyristor, the auxiliary thyristor will be ignited instead. Even if it is possible to dimension the circuit in such a way that the current flowing through the auxiliary thyristor is significant receives a smaller value than the current through the main thyristor, however the current source, e.g. a battery, is always through the one or the other of the thyristors in operation

109835/0278
BAD ORIGINAL ^

₂ T638236

burdened. The useful performance utilized in the useful circle will, however, as already indicated, exclusively from the relationship between the current passage time of the main thyristor and the time during which the current through this thyristor is zero, addicted.

An object of the present invention is a control circuit which is designed and dimensioned in such a way that, under certain special conditions, both the main thyristor and the auxiliary thyristor can be extinguished. This avoids unnecessary loading of the battery, for example in the case of a low power consumption by the useful circuit, ie during long periods of time when the main thyristor remains extinguished. In a previously known, "conventional" control circuit, the current source is otherwise heated by the resistor connected in series with the auxiliary thyristor during those time periods during which the current through the useful circuit is zero.

Another object of the control circuit according to the invention is that they can operate as a "conventional" circuit under certain different conditions should, i.e. become the auxiliary thyristor and the main thyristor alternately ignited and extinguished. This Arbelts— wise is updated by the user group in the event of high performance exceptions.

The circuit according to the invention can, for example, be used at home of vehicles are used, the useful circuit containing an electric motor with a certain resistance and inductance. at heavier load on the motor, the control circuit is operated in a "conventional" manner with alternating current-carrying main

109835/0278
BADORfGINAL

and working groups. To with a lower power exception not unnecessarily loading the voltage source, both the main thyristor and the auxiliary thyristor during part of the period must be deleted at the same time.

According to the invention, this is achieved by the fact that the The capacitor and the inductance together with the resistances of the main circuit and the auxiliary circuit form a series oscillating circuit with such a characteristic that when the time interval between one of the control electrodes of the auxiliary thyristor and a control pulse supplied to one of the control electrodes of the main thyristor, a certain amount due to the natural angular frequency of the series oscillation circuit exceeds a certain value, a damped LC oscillation when the main thyristor is extinguished is generated in the oscillation circuit via the auxiliary resistance develops a voltage drop matched in such a way that the auxiliary thyristor is biased in its reverse direction and is thereby deleted.

The control circuit according to the invention functions in "Conventional" way, if the time interval between said control pulses to the or control electrodes by determined the natural angular frequency of the series oscillation circuit Value falls below. If this is the case, the auxiliary thyristor is extinguished as the control pulse of the control electrode of the main thyristor is supplied.

A previously known circuit and a circuit according to the invention Control circuit are described in more detail below with reference to the accompanying drawing, namely show?

1 shows the circuit diagram of the previously known circuit,

109835/0278
BATH ORIGINAL,

■ h

2 shows the circuit diagram of the control circuit according to the invention and

fig. 3 partly shows the voltage / time diagram of the two thyristors in the case where the main and auxiliary thyristors are deleted at the same time during part of the period, partly the current-time diagrams of the supplied or control electrodes Control pulses as well as the load current.

According to FIG. 1, the useful circuit consists of a pure resistance, ie an ohmic resistance R ^. The main thyristor T ^ is ignited by a control pulse and remains in its ignited state until the auxiliary thyristor T ₂ is ignited by a pulse supplied to its control electrode. When this happens, an equally large voltage drop will initially occur on the two layers of the capacitor C at the beginning. The connection point between the loading resistor R ^ and the main thyristor T »receives a negative potential, which means that the main thyristor goes out. As a result, a current will flow through the auxiliary circuit during the entire extinguishing time of T 1, and a certain amount of power will be consumed in the auxiliary resistor R ₂ . When the main thyristor T ₁ is subsequently triggered, the connection point between the auxiliary resistor and the auxiliary thyristor receives a negative bias voltage in the same way, which causes _{the deletion of T 2.} From this discussion it can be seen that current flows all the time through one or the other of the thyristors and that power consumption occurs through either the main resistor R 1 or the auxiliary resistor R ₂ . Because only the power across the main resistor is useful power, the efficiency becomes the

1098 3 5/0278

** '£> ~ »«' T »if * ν ·; BATH

Circuit low, which is a major disadvantage, in particular in battery operation, where the storage capacity of the power source is limited.

According to FIG. 2, the load on the useful circuit consists of a resistance R- and an inductance L. In order to make the control circuit according to the invention more understandable, various points will now be made in Pig. 3 registered and with the reference numerals 1 to h referenced time moments. When the main thyristor T ^ is ignited at time 1 by a control pulse supplied to its control electrode G, the voltage across this thyristor drops to approximately zero, and a current through the useful circuit begins to flow. The instantaneous voltage drop through the main thyristor T is transferred through the capacitor C to the connection point between the auxiliary resistor R ₂ and the auxiliary thyristor T ₂ . The voltage drop through T ₂ is therefore initially the same as the voltage drop through T-,. Because of the time constant of the capacitor, it then takes a certain time until the voltage across T _{2 has increased} to its full value. Due to the effect of the inductance L in the useful circuit, the current through this circuit is initially zero, but gradually increases to a value that depends on the battery voltage. At time 2, the auxiliary thyristor T ₂ is ignited by a pulse fed to its control electrode G _2. As a result, the voltage across T ₂ drops from the value of the battery voltage to approximately zero, and for the reasons mentioned above, a corresponding voltage drop will occur at the connection point between the useful circuit and the main thyristor T ^. This point, which had approximately zero potential before the ignition of T ₂ , thus receives a negative bias voltage, which causes the extinction

109835/0278

BATH '

of the main thyristor T causes. A current now flows through the useful circuit, which tries to positively charge the right-hand side of the capacitor, and due to the effect of the inductance, the voltage across the main thyristor is significantly higher than the battery voltage. At time 3, the capacitor has absorbed the maximum amount of energy from the inductance, and the current through the inductance and the resistance R is therefore reversed. This current will not be fed back to the battery, but instead will flow from the right-hand side of the capacitor into the friction-oscillation circuit that is made up of the inductance L and the resistances R-. and R2 and the left plate of the capacitor C is formed. However, this results in a voltage drop through the auxiliary resistance R ₃ . At time h , the current through R ₂ has reached such a large value that the voltage drop through this resistor is greater than the battery voltage U. The auxiliary thyristor T _{2 is given} a negative bias and is extinguished. After a dampened transient process, the circuit quickly returns to its initial state, in which both the main thyristor T ₁ and the auxiliary thyristor Tp are deleted, whereupon the cycle thus described is repeated. The voltage / time diagram of the auxiliary thyristor shows that the latter is only triggered during a small part of the extinction time of the main thyristor T ^. The time during which the current flows through the auxiliary resistor R ₂ will therefore depend on the natural angular frequency of the series oscillation circuit, ie on the time it takes for the capacitor C to absorb the maximum charge energy from the inductance L and then the To start discharging,

109835/0278

SAD ORIGINAL

and while the voltage drop required to extinguish the auxiliary thyristor T «is built up _{across the auxiliary resistor R 2.}

As is apparent from the voltage / time diagram of the auxiliary thyristor, but the inventive control circuit can also be made to function in the manner of a "conventional" circuit according to the figure 1, and that if the time interval between the control electrode G ₂ of the auxiliary thyristor and the control pulses supplied to the control electrode G 1 of the main thyristor falls below that value which corresponds to the distance between the points 2 and Λ.

In order to prevent in the time 3 the tension reaches an unnecessarily high value, a diode D lying in series with a resistance R- * can be connected in parallel with the useful circuit are, as indicated by dashed lines in FIG. When the voltage across the main thyristor T becomes greater than the battery voltage, a current will flow through the diode and the resistance R ^, some of which is stored in the inductance L. Energy in the resistance R ^ is consumed.

Thus, the auxiliary thyristor T is cleared in the timing h _2, it is necessary to dimension the circuit elements of the tank circuit such that effects the desired reverse voltage across the auxiliary thyristor T ₂ during discharging of the capacitor C, the voltage drop by _R.sub.2. The inductance and resistance of the useful circuit are usually predetermined values, and the nominal values of the capacitor C and the auxiliary resistance must therefore be selected taking these values into account. The load impedance can of course also be derived from a Dhm resistance

1098 35/0278 BAD ORIGINAL ^{; i:} *

exist ^ in this case, however, there must be an inductance in the stressful The useful circuit can be switched on so that the desired LC oscillation can arise. The capacitance of the capacitor is taking into account, on the one hand, the maximum current through the useful circuit and, on the other hand, the switch-off time and the working voltage of the main thyristor. The Minimum value of the auxiliary resistance fU established, which in turn has a determining effect on the maximum working frequency of the circuit.

1 0 9 c T-, / 0? 7 8
BAOORlQtMAt,

Claims (1)

1638238 Pat tans claims Control circuit for regulating the power of direct current, which traverses a useful circuit with certain resistance (R-,) and inductance (L), in which circuit a main thyristor (T.) with the useful circuit, and an auxiliary thyristor (Tp) to extinguish the main thyristor via a capacitor (C) are connected in series with an auxiliary resistor (R), the main thyristor (T-,) being ignited by supplying a control pulse to its control electrode (G-.) And being extinguished by supplying a control pulse to the control electrode (Gp) of the auxiliary thyristor is, characterized in that the capacitor (C) and the inductance (L) together with the resistances (R, and Rp) represent a friction-oscillation circuit with such a characteristic that, if the time interval between one of the control electrode of the auxiliary thyristor and a the control electrode of the main thyristor supplied control .erimpuls a certain value determined by the natural angular frequency of the series oscillating circuit increases, when the main thyristor is extinguished, a damped LC oscillation is generated in the oscillation circuit, which develops _{a voltage drop across the auxiliary resistor (R 2} ) in such a way that the auxiliary thyristor (Tp) is biased in its reverse direction and is therefore extinguished. 2, control circuit according to claim 1, characterized in that that if the time interval between successive control pulses that the control electrodes of the auxiliary thyristor resp. -109835 / .ΓΙ278 BATHROOM ^ J 1RT8236 of the main thyristor are fed by the eigen-angle frequency of the series oscillating circuit falls below a certain value, the extinction of the auxiliary byyristor is then effected as the control pulse is fed to the control electrode of the main thyristor will. 3. Control circuit according to claim 1, characterized in that that a diode (D) in series with a resistor (R-.) connected in parallel to the useful circuit for the purpose of damping the LC oscillation is. 109835/0278 BATH ORIGINAL