SU390848A1 - METHOD OF TRANSPORTING ELECTRIC WIRING NON-FERROMAGNETIC SHEETS IN ELECTROMAGNETIC - Google Patents

Description

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The invention relates to metallurgical equipment, namely, equipment for the transport of electrically conductive non-ferromagnetic sheets in a state of levitation in an electromagnetic field.

A known method of transporting electrically conductive peferromagnetic sheets in an electromagnetic field is that the sheets are placed in an alternating electromagnetic field, the sources of which are placed below the sheet transport plane, and the induction forces acting on the sheet in a pulsating magnetic field balance the force of the sheet weight, resulting in the sheet is transported in suspension. However, this method cannot be applied in the areas of finishing, where it is not allowed to place any nodes above the sheet transport plane, for example, in the section for sorting and stacking sheets in packages.

The purpose of the invention is to provide transportation of the sheets when placing the electromagnetic system over the transport plane and preserving the quality of the sheet surface.

The proposed method consists in additionally creating a stationary, directed along the transport plane, magnetic field, and from one side face

sheet to another pass a constant current, creating conductive forces in a stationary magnetic field, directed against the force of the sheet weight.

FIG. 1 shows a diagram of magnetic fields, currents and forces; in fig. 2 - the curve of change of the forces acting on the sheet, as a function of the gap between the sheet and the sources of the magnetic field.

The electromagnetic system is located above the xx transport plane and with its working surface a-a facing this plane. Sources I of a pulsating and traveling magnetic field create forces acting on the sheet, directed normally and tangentially to its surface. Sources € 2 with magnetic cores 3 stationary magnetic fields exude a stationary magnetic field directed along

xx transport planes Through sheet 4, from one side of the side to the other, direct current is passed in the direction shown by the sign O- Kopducciioppa force FK acting on the sheet in this direction

current in the sheet is directed against the effect of the weight of the sheet G.

The magnitude of the current in the sheet and the induction of the stationary magnetic field ensures that the force FK exceeds the force of weight G. The normal component of the induction force is

The FH created by the alternating magnetic field of the inductors / prevents the sheet from being pressed against the surface aa, and the sheet is stationary under the conveyor in a suspended state, not touching the working surface of the inductors 1.

When the inductors 1 are switched to a running magnetic field, the sheet is moved along the transport line and is braked when the running magnetic field is reversed. FIG. Figure 2 shows the variation curves of the conductive force (5) and the sum of the inductive forces of an alternating magnetic field with a sheet weight force 2 / (6) depending on the gap b between the sheet and the surface aa.

To compare the forces FK and G + Sfn on the positive part of the graph, the dotted line shows the curve (b), obtained by changing the sign of the curve G-j-SfH f2 (6).

The point b-intersection of the curves i (6) and / 3 (b) corresponds to a stable sheet equilibrium in the state of being at a distance (b) from the surface aa, i.e., FK G + SFn.

Subject invention

A method of transporting electrically conductive non-ferromagnetic sheets in an electromagnetic field, which consists in placing the sheets in an alternating electromagnetic field, characterized in that, in order to transport the sheets when the electromagnetic system is placed over the transport plane and to maintain the surface quality of the sheets, the magnetic field, and from one side of the sheet to the other, a rotor current is passed through, creating conductive forces in a stationary magnetic field directed against the force of the sheet weight.

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