SU464058A1 - Device for controlling an electromechanical transducer - Google Patents

Description

one

A device is known for controlling an electromechanical transducer, for example, an electromagnetic hammer, containing thyristors connected in series with the converter windings and a discharge circuit connected in parallel with the windings consisting of a series-connected capacitor and a resistor.

In order to increase the impact energy and efficiency in the proposed device, an additional thyristor is connected to the discharge circuit, connected in series with the discharge capacitor, and two resistors, one of which bypasses the capacitor, and the other connects the anode to the additional thyristor by the same electrode of the same thyristor.

The drawing shows the principal electrical circuit of the proposed device.

The device consists of main thyristors 1 and 2, alternately connecting the windings 3 and 4 of the electromagnetic hammer to a DC power source. Thyristors 1 and 2 are switched by capacitor 5.

The discharge circuit of the proposed device contains diodes 6 and 7, a thyristor 8, in the control electrode circuit of which resistor 9 is connected, resistor 10 connected in series with thyristor 8 and resistor 10 and capacitor 11 shunted by resistor 12. The device operates as follows. The alternating switching of thyristors 1 and 2, carried out by capacitor 5, ensures the interruption of operating currents in the windings 3 and 4 of the hammer.

Under the influence of induced e. d. self-induction, for example in winding 3 (polarity

is shown in the drawing), a current begins to flow in the control electrode circuit of the discharge thyristor 8. When this current reaches the current value of unlocking, the thyristor opens and the discharge of discharge capacitor 11 across the circuit occurs: thyristor 8 - resistor 10 -

capacitor 11-diode 6. It also occurs

partial discharge current through the bit

resistor 12.

At the moment when electromagnetic energy

the windings are completely converted into electrical energy of the charged capacitor 11 (the voltage on the capacitor and the emf of the self-induction are equal, under the action of which the capacitor is charged) at the cathode

thyristor 8 is Vits positive potential, and it closes. We direct the moving shock part e. d. the amplitude motion is significantly less than e. d. self-induction arising at break in the circuit

windings. Therefore, the resistance of the resistor 9

should be selected in such a way that the opening of the thyristor occurs only when the em. with. self-induction. Consequently, when the shock part moves relative to the disconnected winding 3 and the occurrence of e. d. the thyristor 8 remains in a locked state, and the current in the circuit does not flow, which significantly increases the impact energy and the efficiency of the hammer.

During the disconnected state of the winding 3, the charged capacitor 11 is discharged to the resistor 12, and all stored energy is released in it.

The switching process of the winding 4 is the same as described, but in this case, the current passes through diode 7.

Subject invention

A device for controlling an electromechanical transducer, for example an electromagnetic hammer, containing thyristors connected in parallel with the converter windings and a discharge value connected in parallel to the windings, consisting of a series-connected capacitor and a resistor, in order to increase the impact energy and to d., an additional thyristor, connected in series with the discharge capacitor, and two resistors, one of which bypasses the capacitor, and the other connected yvaet anode of the thyristor with the control electrode of the thyristor.

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