SU1272454A1 - Device for starting induction phase-wound rotor motor - Google Patents

Abstract

The invention relates to electrical engineering. The aim of the invention is to simplify the device. Starting an asynchronous motor 1 with a rotor rotor is provided by connecting the rotor circuit via a rectifier 2 to a starting resistor. The latter is also connected to the output of the second rectifier 4, the input of which is through the inductive-capacitive converter 5 connected to the mains. Inductive-capacitive converter maintains a constant current value in the rotor circuit without any additional regulation for the entire start-up time, which simplifies the device, 1 sludge. (LU NU SL 4

Description

The invention relates to electrical engineering and can be used in drives of the mechanisms of the winch, the rotor of drilling rigs, mine lifts of machines operating in constant acceleration mode.

The aim of the invention is to simplify the device.

The drawing shows an electrical schematic diagram of the device.

The device for starting the asynchronous motor 1 with the phase rotor contains the first three-phase bridge rectifier 2, the unit 3 forming the current of the rotor circuit of the asynchronous motor 1, the connection points of the anodes and cathodes of the diodes of each phase of the first three-phase bridge rectifier 2 are equipped with clamps for connecting the rotor winding of the sync cord 1, the cathodes and anodes of the diodes of the first three-phase bridge mittel 2 are combined and connected respectively to the first and second outputs of the asynomotor rotor circuit current generating unit 3 the central motor 1, the three KOTcfporo inputs are equipped with terminals for connecting the stator windings of the induction motor 1 and the phases of the mains supply, the unit 3 for forming the current of the rotor circuit of the induction motor 1 is composed of the second three-phase bridge rectifier 4, the inductive-capacitive converter 5, the starting resistor 6 first 7, second 8 third 9 and fourth 10 control resistors, capacitor 11, thyristor 12, relay with winding 13 and two disconnecting 14 and closing 15 contacts, anodes of diodes of the second three-phase bridge rectifier 4 and 4 are combined, connected to the same terminals of the first control resistor 7 and the first disconnecting contact 14 of the relay and form the first output of the rotor circuit of the induction motor 1, the other outputs of the first control resistor 7 and the breaking contact 14 of the relay, and through the winding 13 of the relay connected to one end of the starting resistor 6, to the cathode of the thyristor 12, to the same terminals of the second control resistor 8 and the capacitor 11, which form the second output of the rotor circuit of the asynchronous motor 1, another terminal of the starting resistor 6 is connected to the anode of the thyristor 12, to the connection point of the cathodes of the diodes of the second three-phase bridge rectifier 4 and through the relay contact 15 of the relay connected in series and the third control resistor 9 to one terminal of the fourth control resistor 10 and to another terminal of the capacitor 11, another terminal of the fourth control resistor 10 is connected to another terminal of the second control resistor 8 and to the control electrode of the thyristor 12, the input of the second three-phase bridge rectifier 4 is connected to the output one terminals of the inductive-capacitive converter 5, the input terminals of which form the three inputs of the current forming unit 3 of the rotor circuit of the asynchronous motor 1.

The supply voltage is supplied to the induction motor 1 by means of a line contactor 16.

The device operates as follows. When the line contactor 16 is turned on, an alternating voltage is applied to the stator of the asynchronous motor 1 and to the input of the inductive-capacitive converter 5. At the DC outputs of the three-phase bridge rectifiers 2 and 4 there is a voltage, when summed up to flow during the entire starting period the constant current in the starting resistor biv winding the rotor of the electric motor 1. The starting current sets and stabilizes the inductive-capacitive converter 5 benefit the gift of resonant tuning of reactive electrons & mektov, which are included in its composition.

Claims (1)

At the initial start-up time (at slides close to unity), the relay is turned on via its first disconnecting contact 14. In order to prevent the thyristor 12 from turning on at this time, an integrating circuit is provided consisting of a capacitor 11 and a resistor 9. The motor 1 starts up constant current in the rotor and, therefore, with constant acceleration and dynamic loads on the equipment. The engine start tachogram is absolutely linear, with the result that the starting process is extremely fast. When the motor 1 exits to the section of the natural mechanical characteristic, the relay automatically switches off and closes its contact 15. After that, with some delay, it switches on the thyristor 12, which bypasses the starting resistor 6 in order to reduce energy consumption. With the turning on of the thyristor 12, the inductive-capacitive converter 5 switches to the short-circuit mode and practically does not consume active energy from the network. The capacitive reactive energy consumed by the converter 5 makes it possible to improve the power factor of the electric motor 1 (with an appropriate choice of the elements of the inductive-capacitive converter 5, the power factor of only 5 devices can be equal to one). Thus, the proposed device allows for equally accelerated start of the engine with maximum speed. and admissible dynamic loads. This makes it possible to improve the performance of the mechanism and facilitate the operation of the equipment. In the steady state mode of operation of an electric motor, the device improves its power factor, which results in energy savings. Claims An apparatus for starting an asynchronous motor with a phase-rotor, comprising a first three-phase bridge rectifier, a current-forming circuit of a torno circuit. the cathodes and anodes of the diodes of the first three-phase bridge rectifier are combined and connected respectively to the first and second outputs of the current-forming unit rotor A 5 jg asynchronous motor circuit, three inputs of which are equipped with terminals for connecting the outputs of the stator winding of the asi 1 synchronous motor and the mains supply phases, characterized in that, for the purpose of simplification, the rotor circuit of the asynchronous motor produces a second three-phase bridge generator inductively -capacitating converter, starting resistor, first, second, third and fourth control resistors, capacitor, thyristor, relay with winding and opening and closing contacts, anodes of second diodes the three-phase bridge rectifier are combined, connected to the same terminals of the first control resistor and the relay opening contact, and form the first output of the inductor motor's rotor circuit, the other terminals of the first control resistor and the relay contact are combined and connected to one output of the starting resistor through the winding of the relay , to the thyristor cathode, to the same terminals of the second control resistor and the capacitor, which form the second output of the rotor circuit current shaping unit About the motor, another output of the starting resistor is connected to the thyristor anode, the second three-phase bridge rectifier diode to the cathodes junction point and the relay contact and the third control resistor connected in series to one output of the fourth control resistor and another capacitor output, another output of the fourth control resistor connected to another output of the second control resistor and to the control electrode of the thyristor; the input of the second three-phase bridge rectifier is connected to the output Agim inductive-capacitive transducer input terminals which form the three inputs of the current block forming circuit induction motor rotor.