SU649111A1 - Device for starting and brushless excitation of two-motor electric drive - Google Patents

Description

 AC, and through the working contacts, a fixed triac converter and a power transformer are connected to the synchronous machine core winding, asynchronous motor, the exciter stage has an additional stator winding, electrically combined with the excitation winding of the reversed synchronous exciter, connected with its three-phase clamps to resistance m

The drawing shows a schematic diagram of the proposed device.

It contains the winding I of the synchronous machine core, the winding 2 of the synchronous maschina excitation, the rotating rectifier 3, the winding 4 of the rotor of the induction motor-exciter, the main winding 5 of the stator of the induction motor-exciter, the winding 6 of the inverted synchronous exciter core, an electrically combined winding 7 for the excitation of the excitation of the synchronous exciter, electrically combined winding Who is the exciter and supplement, ny winding. (7) motor stator induction motor, stationary controlled rectifier 8, starting resistors 9, stationary triac converter 10, power transformers I and 12, two-position switch 13, automatic excitation controller 14 (APB) with control systems of the stationary rectifier 8 and a fixed triac converter 10, 15, 16, 17, respectively, the input signal of the APB, the synchronization input of the control system of the fixed controlled rectifier 8, & synchronization progress of the control system of the fixed sym historical converter 10.,

The winding 4 of the rotor of the induction motor-exciter and the winding 6 of the core of the inverted synchronous exciter are connected in series and connected to the input of the rotating rectifier 3, the output of which is connected to the excitation winding 2 of the ganchronous maschine. The main winding 5 of the stator of the asynchronous motor-exciter is connected through the starting contacts of the two-position switch 13 to the network alternately Gotok, and through the working contacts of this switch, the triac converter .10 and the power transformer 11- to the winding 1 of the synchronous masking box.

The additional winding 7 of the stator of the asynchronous motor-driver is connected to the starting resistances 9, and the electrically combined winding 7 of the exciter of the inverted synchronous driver is connected to the output of the fixed controlled rectifier 8, the input of which through the power transformer 12 is connected to the winding 1.

Automatic excitation controller 14 is made with control systems of a fixed controlled rectifier 8 and a fixed simistor converter.

10. The outputs of the control systems are connected to the control electrodes of the rectifier 8 and the converter 10.

When the synchronous machine is started up, the base winding 5 of the stator of the induction motor of the exciter by the starting contacts of the two-position switch 13 is disconnected from the triac converter 10 and connected to the AC network. In the process of acceleration, control signals to the electrodes of the stationary thyristor rectifier 8 are not given, and it is in the closed state.

Thus, at start-up, the starting moment is generated due to the currents flowing in the circuits of the windings 5. 4 induction motor as well as due to the currents flowing in the internal asynchronous cascade (churning 4, winding 7, pu, the resistance 9). An additional circuit at start-up is a circuit formed by rotating windings 6, 4 and the equivalent resistance of the winding 2 of the synchronous machine excitation, reduced to the AC side of the rotating rectifier 3. The stationary, starting resistances 9 may, if necessary, have water cooling. It is possible to form an improved starting characteristic of the .pHtTHKH synchronous machine with increased operational reliability by non-contact output of slip losses from the rotating part of the installation. /

. When the synchronous mask reaches the subsynchronous speed by the rotor, the machine is switched on to the network by the method of self-synchronization. Ito terminating the synchronization process, the main winding 5 of the stator of the asynchronous motor-driver by the working contacts of the two-position switch 13 is disconnected from the AC network and connected to the fixed triac converter 10. At the same time, the control systems of the fixed controlled rectifier 8 and the triac converter 10 set the adjustment angles triacs in working positions for the implementation of two group control of the excitation current of the synchronous maschine.

In Static modes of operation, the stationary controlled rectifier 8 is a working group and the synchronous masking is excited by the reversible synchronous pathogen (windings 7, 6). The triacs of the fixed converter 10, which is a forcing group, are practically closed in normal operation and are opened by the APB and control system to provide forcing excitation through the rotations 5, 4 of the asynchronous exciter.

The presence of the working and force groups allows to obtain a high power factor of the synchronous-asynchronous motor.