SU1198680A1 - Linear asynchronous motor - Google Patents

Description

The invention relates to electrical engineering and is intended to provide centering in the transverse direction of the secondary element of a linear asynchronous motor. The extreme rods of a III-shaped laminated magnetic stator of an engine stator are equipped with short-circuited turns. Shielding of a part of cores of magnetic cores Causes a shift of magnetic fluxes of shielded parts in phase relative to unshielded. The transverse magnetic fields, arising in this case, move on different rods in different directions. The displacement of the secondary element in the transverse direction causes a weakening of the interaction of the transverse magnetic field with the secondary element on the vanishing side. The edge of the secondary element from the core of the magnetic circuit. When this occurs, the returning transverse force under the action of the transverse magnetic field of the opposite edge of the magnetic circuit, 1 Il.

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The invention relates to electrical engineering, in particular to linear asynchronous motors, and can be used for the translational movement of the moving element.

The aim of the invention is to provide centering of the secondary element in the transverse direction.

The drawing shows the proposed engine, the overall appearance.

A linear asynchronous motor contains a stator, states of individual magnetically coupled laminated W-like magnetic cores 1, the middle rods of which are covered by the coils of the multiphase winding 2. The nonmagnetic secondary element 3 is made of electrically conductive material and is located above the inductor. Extreme rods of the magnetic cores are equipped with short-circuited coils 4, made of non-magnetic electrically conductive material. The coils partially cover the outer cores of the magnetic cores, with the coils on each core located on opposite sides of the rods.

The engine works as follows. Powering a multiphase motor winding from a three-phase voltage source causes a magnetic field running in the longitudinal direction, which excites currents in an electrically conductive secondary element that interact with the traveling magnetic field, as a result of which the longitudinal directional force acts on the secondary element.

The presence of short-circuited coils on the extreme rods of the magnetic drives causes shielding

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the turns of the part of the cores of the magnetic cores, the shift of the magnetic fluxes of the shielded parts of the rods in phase relative to the unshielded parts.

5 The latter leads to the appearance in the transverse direction of the magnetic fields moving on the different rods of the magnetic circuit in different directions, as a result of the arrangement

10 turns of the magnetic cores on different sides of the rods. With a symmetric arrangement of the secondary core relative to the extreme cores of the magnetic cores, the total transverse, 5th force acting on the secondary element is zero. The displacement of the secondary element in the transverse direction causes a weakening of the interaction of the transverse magnetic field with the secondary element on the vanishing side of the edge of the secondary element from the magnetic core.

In this case, a returning transverse force arises under the action of a transverse-traveling magnetic field of the opposite edge of the magnetic circuit.

Claims (1)

Claim The linear induction motor comprising a stator consisting of a W-shape of the stacked cores, central rods are covered by the coils of the polyphase winding, and an electrically conductive secondary member, characterized i in that, in order to ensure centering of the secondary element in the transverse direction, the end ^1, the rods of each magnetic circuit provided with short-circuited coils, covering the area of the rod facing the central rod. 1198680