SU1453533A1 - Induction motor - Google Patents

Abstract

The invention relates to electrical engineering, in particular to asynchronous motors with two stators. The aim of the invention is to increase the starting torque and the expansion of the rotational speed range. The asynchronous motor contains the rotor cores 1 and 2 and the rods 3 and 4 of the main rotor winding, the rods 5 and 6 of the additional rotor winding, the common shaft 7 of the electric motor, the stator cores 8 and 9, the housing 10, the bearing shields 11 and 12. the currents are redistributed in the rotor windings and the total rotor resistance changes, which allows to expand the range of the rotational frequency and change the starting torque. 1 il.

Description

The invention relates to electrical engineering, in particular to asynchronous electric motors with two stators.

The purpose of the invention is to increase the starting torque and expand the range of speed control.

The drawing shows an engine, a longitudinal section.

An asynchronous electric motor contains rotor cores 1 and 2, rods 3 and 4 of the main rotor winding, rods 5 and 6 of the additional rotor winding, common motor shaft 7, stator cores 8 and 9, housing 10, 15 and bearing shields 11 and 12.

The electric motor operates as follows.

When voltage is applied to the stator core windings, they create rotating magnetic fluxes. These magnetic fluxes induce an EMF in each rotor winding. If in the initial position the shift between the axes of the magnetic fluxes of the stator cores is 25 zero, the EMF in the rotor rods of the main winding coincide in phase and the current in this rotor winding is maximally possible and is determined by its resistance. Since the rods of the additional rotor winding have a shift between themselves of 180 zl. hail, then the EMF in the rods of this winding is directed in the opposite direction, therefore, the current in the winding is equal to zero.

By rotating one of the stator cores around the axis of the stator cores of rotation or by changing the phase shift between the supply voltages of the windings, a relative angular shift of the axes of the magnetic flux generated by the windings located in the grooves of the stator cores is carried out. This leads to a phase. EMF shift in the rods of the main and additional rotor windings. Consequently, the current in each rotor winding changes.

Thus changing the angle of rotation between the axes of the magnetic fluxes of the stator cores, a current redistribution is obtained between the main and additional rotor windings. If the active resistances of the rotor windings are different, then such a change is equivalent to a change in the resulting resistance of the rotor windings. This changes the magnitude of the starting torque and the critical slip value of the rotor of the engine, which extends the range of the frequency of its rotation.

I. The redistribution of currents between the rotor windings can be performed by changing the supply voltage of the winding of one of the stator cores with fixed values of the supply voltage of the winding of the other stator core and the relative angular position of the stator cores.

Claims (1)

Claim An asynchronous motor containing two stator cores with windings, one of which is rotatable, two rotor cores with a common short-circuited winding, characterized in that, in order to increase the starting torque and expand the control range, rotational speed, each rotor core is provided with additional short-circuited windings, the rods of which are installed in the grooves made in the cores, and the winding rods of one rotor core are connected to the windings of the second core and the rotor with a shift of 180 e. hail.