UA134894U - ELECTRIC MACHINE OF BIINDUCTOR TYPE - Google Patents

Abstract

The electric machine of the bi-inductor type contains a stator consisting of a number of separate, magnetically unconnected, ferromagnetic elements - teeth of the W-shaped form, and in intervals - grooves of the stator, the sections of an armature winding covered by two excitation windings consisting of a series of ferromagnetic poles on a non-magnetic shaft. One armature winding is placed on the stator without shifting the sections during the transition from the middle part of the W-shaped magnetic circuit to the extreme parts. The rotor is made of two cylindrical double-sided combs mounted on a non-magnetic shaft. The teeth (poles) of the combs on each side are placed with a center-to-center distance in two pole divisions h and on one side of the comb the teeth are shifted by the magnitude of the pole division relative to the teeth (poles) of the other side. Together, the two combs form a different-pole system under the middle part of the W-shaped stator and the same-pole - the extreme parts. The back of each comb is a ferromagnetic ring.

Description

The utility model belongs to the field of electrical engineering and can be used in electric drives of industrial mechanisms.

The design of an electric machine of the bi-inductor type (1|) is known, the stator of which consists of a number of separate, magnetically unconnected, ferromagnetic elements - W-shaped teeth. Sections of the armature winding, covered by two excitation windings of the toroidal type, are inserted into the gaps - grooves of the stator. Unwinding the cylindrical rotor consists of a number of magnetically uncoupled ferromagnetic poles arranged in a checkerboard pattern on a non-magnetic shaft.

This design requires three armature windings (one winding in the middle part of the W-shaped magnetic conductor and two windings - under the extreme parts) or one complex winding, in which, when moving from the middle part to the extreme sections, the windings are made with a shift in pole division, i.e.

This is a disadvantage of the design, because: the cost of copper for the armature winding increases; the manufacturing technology of the armature winding in the second option is complicated; the distance between the middle and extreme parts of the W-shaped magnetic conductor increases for laying the armature winding in both variants of its implementation.

The basis of the useful model is the task of simplifying the manufacturing technology of the armature winding, reducing the copper consumption of the armature winding and partially reducing the steel consumption of the W-shaped magnetic conductor.

The problem is solved by the fact that in an electric machine of the bi-inductor type, which contains a stator, which consists of a number of separate, magnetically unconnected, ferromagnetic elements - W-shaped teeth, and in the gaps - slots of the stator, sections of the armature winding, covered with two toroidal excitation windings, an unwound cylindrical rotor consisting of a number of ferromagnetic poles on a non-magnetic shaft, according to a useful model, one armature winding is placed on the stator without shifting sections when moving from the middle part of the W-shaped magnetic field to the extreme parts, and the rotor is made from two cylindrical double-sided combs fixed on a non-magnetic shaft, while the teeth (poles) of the combs on each side are placed with a center-to-center distance of two pole

From the division t and on one side of the comb, the teeth are shifted by the value of the pole division x relative to the teeth (poles) of the other side, and together the two combs form a different-pole system under the middle part of the W-shaped stator and a same-pole system at the extreme parts, and the back of each comb is a ferromagnetic ring .

The drawing shows the sweep of the rotor on a plane for a four-pole machine.

The following are marked on the scan: 1 - poles of the left comb; 2 - poles of the right comb; With and 4, respectively, the backs (rings) of the left and right combs.

An electric car in engine mode works as follows.

When unidirectional current flows around two excitation windings, a magnetic field arises, the polarity of which is shown in the drawing. When the armature winding is connected to a source of constant voltage, currents flow in the sections of the winding, under the poles of polarity M of one direction, and under the poles of polarity 5 - in the opposite direction (the width of the section is equal to the pole division t). An electromagnetic force (moment) from two poles of the same polarity acts on each side of the section, and the rotor begins to rotate.

An electromechanical or semiconductor commutator ensures, depending on the position of the rotor, currents of one direction in the conductors under the poles of polarity M, and the opposite - under the poles of polarity 5.

Thus, a unified electric machine provides an electromechanical moment, as in an electric machine, according to the || patent, with lower consumption of copper for the armature winding and a simpler manufacturing technology, and also reduces the consumption of steel for the stator magnet wire due to the reduction of the distance between the middle and extreme poles

Claims (1)

UTILITY MODEL FORMULA An electric machine of the bi-inductor type, containing a stator, which consists of a number of separate, magnetically unconnected, ferromagnetic elements - W-shaped teeth, and in the gaps - stator slots, sections of the armature winding are inserted, covered by two toroidal excitation windings, an unwound cylindrical rotor consisting of a number of ferromagnetic poles on a non-magnetic shaft, which differs in that , that one armature winding is placed on the stator without shifting sections when moving from the middle part of the W-shaped magnetic conductor to the extreme parts, and the rotor is made of two cylindrical double-sided combs fixed on a non-magnetic shaft, while the teeth (poles) of the combs are placed on each side with an intercenter distance of two pole divisions x and on one side of the comb the teeth are shifted by the value of the pole division t relative to the teeth (poles) of the other side, and together the two combs form a different-pole system under the middle part of the W-shaped stator and a same-pole system in the extreme parts, and the back each comb has a ferromagnetic ring. yes -x S! 4 of 4 chi o i gi Y | and -8 and | With | | i Z Z g z i Mo. -k! not І І 5 ше и | | 7