SU813655A1 - Device for regulating rotational speed of traction motor with m-phase excitation system - Google Patents

Description

valve motor with three-phase exciter; in fig. 2 is a vector diagram of the magnetic fluxes of the phases of the inductor winding.

The device contains an inverter 1, to the output of which is connected the phases 2 - 4 windings of the core of a valve engine, connected by a star, a three-phase inductor with star-connected windings 5 - 7, in this case the linear terminals of the windings 5 and 7 of the non-junction terminal to the network phases A and C, and the linear terminal of the winding 6 to the zero point of the controlled valves 8-10, connected by a star and connected by linear terminals to the phases of network A, B, C.

The operation of the device is performed by alternately unlocking the valves 8-10, depending on the desired vector position of the resulting magnetic flux. When alternately unlocking the valves 8 and 10 (depending on the polarity of the voltage applied to the CMB) and the valve 9 is closed, the rectifier is: the unnumbered mains current flows through the windings of the inductor 6 and 7 (with a positive potential in phase A and the open valve 8 ), n the discharge current of the winding 5 is closed through the valve 8 pa winding 6 or through the windings 6 and 5. When put; 1ny potential, will be in phase C and the valve 10 is open, the discharge current of the winding 7 is closed through the valve 10 to the winding 6 Taking into account that the currents, the size of the d1Pz1Y and the downstream of the mains, are almost the same, The induction between the currents of the phases of the inductor 5 - 7, creating the magnetic currents we create with them, will be correlated as 1: 2: 1.

 The resulting magnetic flux vector, equal to the geometric sum of the individual; Phase flows, takes the order of Fr (Fig. 2).

With open control valves 9 and 10 (positive phase potential B), the primary network current flows through the windings 6 and 7, and their discharge current to the non-conductive floor of valve 9 is closed (valve K through floor). Therefore, phase 5 does not create a flow. and phases 6 and 7 create equal currents. The resulting magnetic flux vector in this case

-01

occupies the position of Fr., i. e.

rotates relative to the vector Fr by an angle di 2 7t / 3 counterclockwise.

Similarly, the process runs

with open valves 8 and 9 (positive potential in phase B), i.e., current will flow through windings 6 and 5, and the resulting magnetic flux will hold the position Fr relative to Fr by an angle dj 27t / 3 in a clockwise direction. By smoothly adjusting the angles of unlocking the valves 8 and 9 or 9 and 10, the vector of the resulting magnetic flux gradually changes relative to FR or relative to the switching core section (if its position coincides with the flux guide FR) and the speed of the valve motor changes accordingly.

The device allows you to smoothly adjust the speed of the valve motor, redistributing the currents in the inductor phases, without using damper valves, allows you to significantly simplify the excitation of the valve motor, increase its reliability in operation and reduce the cost of manufacturing and operating the valve motor.

Claims (2)

1. Vane engines and their application on an electric rolling stock. “Transport, 1976, p. 230 - 237. 2. Kananov A. I. Electronic and ion converters. SEI, 1956, p. nineteen.