SU989715A1 - Induction electric motor starting device - Google Patents

Description

(5k) DEVICE FOR STARTING ASYNCHRONOUS MOTOR

one

The invention relates to electrical engineering and can be used in general industrial electric drives: mechanisms.

A device for starting an asynchronous motor contains a thyristor switch in the stator winding circuit of an electric motor, a thyristor switch-on unit in two switch phases, a thyristor turn-on unit in the third phase of the switch, a phase control unit, whose input is connected to the synchronization unit, and an output with thyristor turn-on units switch Cl 1

The known device provides a shock-free start of the asynchronous electric motor, however, it has the complexity of making switch thyristor switching units and low reliability of operation due to the dependence of the operation of the phase control unit on the voltage fluctuation of the power source.

Claims (1)

The closest to the proposed technical entity is an asynchronous electric motor starting device containing a thyristor switch connected to the stator winding of the electric motor, a rectifier connected to the three phases of the AC source, the decoupling diodes, two of which are connected by anodes through the first resistor rectifier output, and cathodes with control electrodes of the respective two switch thyristors, control electrode of the third switch thyristor through the third switch The electrode is connected to the output of the rectifier, an additional diode, the anode of which is connected to the first phase of the AC source, and the cathode to the output of the second resistor, a switch connected to the third resistor in the switch 2 circuit of the thyristors. 3 A disadvantage of this device is that the start-up of an electric motor is carried out with the appearance of significant electromagnetic shock moments, which increase the dynamic load on the elements of the electric-drive mechanism and thereby reduce the reliability of its operation. The purpose of the invention is to increase the reliability of operation due to the suppression of the shock electromagnetic moments during the start of the electric motor. This circuit is achieved by introducing three optocouplers, a fourth resistor, five and sixth resistors into the asynchronous motor starting device, some of the terminals of which are combined and connected to the other terminals of the second resistor and the neutral wire of the AC source, input the first optocoupler with one output is connected to the cathode of an additional diode, and the other output is connected to the second phase of the AC source, the output of the first optocoupler with one output is connected to the anodes of two dissociating diodes, and the other This is connected to the anode of the third decoupling diode and to the output of the second optocoupler connected in series with the third optocoupler, the output of which is connected to another key output, one output of the input of the second optocoupler is connected to another output of the fourth resistor, and the other output of its input is connected to the third the phase of the alternating current source and one output of the third optocoupler input, the second output of which is connected to another output of the fifth resistor and through the sixth resistor connected to the second phase of the alternating current source. FIG. 1 shows the schematic diagrams of the device; in fig. 2 graphics; voltages; Device for starting an asynchronous motor 1 contains an AC source 2, thyristors 3, and 5 | forming a switch connected to the stator winding of electromotor 1, rectifier 6, connected to AC source 2, resistor 7. one pin of which is connected to rectifier 6, and the other pin is connected to one output of the optocoupler 8, connected optro 9 and 10, resistor. 11, one output of which through 4 cut key 12 is connected to the output of the optocoupler 10, and the other output is connected to the neutral wire of the alternating current source 2, the decoupling diodes 13, 1 and 15, the cathodes of which are connected respectively to the control electrodes of the thyristors 3, and 5, the anodes of the decoupling diodes 13 and H are combined and connected to one output of the optocoupler 8, the anode of the switching diode 15 is connected to the output of the Optocoupler 9 and connected through resistor 16 to rectifier 6, resistor 17, one output of which is connected to one output of the optocoupler 8, another pin of which input It is connected to the second phase of the alternating current source 2, a triode 18 that connects the first phase of the alternating current source 2 to one output of resistor 17, the other output of which is connected to one output of resistor 19 and resistor 20, as well as to the neutral wire of the alternating current source 2, the other the output of resistor 19 is connected to one output of the optocoupler 9, the other output of the junction is connected to the third phase of the AC source 2 and to one output of the third optocoupler 10, the other input of which is connected to another output of the resistor 20 and A resistor 21 with a second phase of an alternating current source 2, another output of an optocoupler 8 is connected through pin 22 to an output of an optocoupler 9. Fig. 2 shows a three-phase voltage 23 of an alternating current source 2, a voltage of 24 and 25 of the second and third phases of an alternating current source and control pulses 26, the device operates as follows. Switching the device into operation is carried out by closing the key 12. 8cv with so that the phase voltage is applied to the input of the optocoupler 9, and the phase and linear voltage of the second and third phase of the source 2 of the alternating voltage to the input of the optocoupler 10, the voltage from the zero wires from the output of optocouplers 9 and 10 are fed to the control electrode of the switch thyristor 5, which turns on at the time of maximum linear voltage of the alternating current source corresponding to the time interval ti-tT, H diagram 59 voltages 23, 2 and 25. Optocouplers 9 and 10held in the open state along the circuit resistor P - switch 12 resistor 6 -. transducer 6 - source 2 of alternating current. The next stage of the start occurs when a voltage is applied to the input of the optocoupler 8V at time t, when this voltage exceeds the voltage coming from the alternating current source through triode 18. The optocoupler 8 opens and the voltage from its output goes to the control electrode of the thyristor 4 switch. Thyristor 4 opens at the time of maximum phase voltage. Optocoupler 8 is held open across the circuit by resistor 11 - key 12 - optocoupler 9 and 10 - pin 22 - optocoupler 8 - resistor 7 rectifier 6 - alternating current source 2. Next, a control pulse is applied to the thyristor 3, which is turned on and closes the stator winding of the electric motor 1, which develops a torque. To stop the motor 1, the contact 22 opens, leaving the thyristor 5 on. A rectified current passes through the motor winding and dynamic braking takes place. Thus, the connection of the stator winding to the alternating current source initially to the maximum of the linear voltage and then to the maximum of the phase voltage is provided to suppress the shock electromagnetic moments in the electric motor, thus increasing the reliability of the elements and assemblies of the electric wire. The invention The device for starting an asynchronous electric motor, containing a thyristor switch connected to the stator winding of an electric motor, a rectifier connected to the three phases of an alternating current source, decoupling diodes, two of which are connected to the rectifier output by 5 anodes through the first resistor and the cathodes connected to the control electrodes of the respective two-thyristors of the switch, the control electrode of the third thyristor of the switch through the third decoupling electrode is connected to the output terminal of the rectifier l, an additional diode, the anode of which is connected to the first phase of the alternating current source, and the cathode is connected to one output of the second resistor, a key, one output of which is connected to one output of the third resistor, so that increase reliability, it introduced three optocouplers, the fourth resistor, the fifth and the sixth resistors, some of the terminals of which are combined and connected to other terminals of the second and third resistors and the zero wire of the AC source, the input of the first optocoupler is connected to one cathode An additional diode is connected to the second phase of the alternating current source with another output, the output of the first optocoupler is connected to the anodes of two uncoupling diodes by one output, and the other output is connected to the anode of the third decoupling diode and connected to the third optocoupler in series which is connected to another output of the key, one output of the input of the second optocoupler is connected to another output of the fourth resistor, and the other output of its input is connected to the third phase of the AC source and to one output the input of the third optocoupler, the second output of which is connected to another output of the fifth resistor and through the sixth resistor is connected to the second phase of the AC source. Sources of information taken into account in the examination 1. USSR author's certificate ff 221117, CL. H 02 R 1/26, 1966. 2, Petrov L.P. and others. Asynchronous electric drive with thyristor switches. M., Energie, 1970, p. 108-109.