DE2634070A1 - Open=end spinning rotor shaft mounting - has an assembly of permanent magnets at shaft end to hold shaft rigidly against its supporting rollers - Google Patents

Abstract

The mounting for the shaft of a spinning rotor, in an open-end spinning unit, uses magnetic forces to hold the shaft in the wedge-shaped gap between two supporting rollers. At least two magnetised permanent magnets are located at the end of the shaft, according to its dia., with each disc pole shoe being homopolar and attached to reverse against each other. Each of the shaft magnets is arranged in the mounting block with a ring magnet with an air space between it and the shaft as the magnet is positioned axially with it, with a ring pole shoe of the same axial length as each pole. The polarity of the ring magnet is reversed in relation to the shaft magnets. The arrangement of the magnets gives a rigid support to the rotor shaft while allowing the shaft to be inserted and removed easily.

Description

Storage for the shaft of a spinning rotor

Be a known bearing for the shaft of a spinning rotor (OE-PS 270 459), in which the shaft is radially positioned between two pairs of supporting rollers Wedge gap is held and axially fixed by magnetic force are at the free end of the shaft with axial spacing from one another, two ring magnets of larger diameter attached than that of the shaft, which they are about half of their circumference encompassing trained pole shoes attached to the side of the shaft on the bearing hock Permanent magnets are assigned. This pole shoe education requires a relatively large and therefore having to use bulky magnets, and also are for inserting and removing the shaft in or out of this storage as a result of the ring magnets protruding radially over the shaft, in addition to the axial movement considerable lateral shaft movements are required, especially when a tangential drive belt holding it in the wedge gap can be assigned to the shaft should go far enough, even in the case of the shaft, to interrupt the drive connection lifted belt is not yet readily possible -The present invention The underlying task is to provide a high level of spring stiffness and thereby A secure axial fixation of the shaft it ensures a compact magnet arrangement To create structure, which at the same time also only through an axial displacement of the Shaft possible insertion into and removal from the wedge gap.

This object is achieved by the invention mentioned in claim 1.

It is known (DT-OS 2 108 590) on the shaft of a spinning rotor several axially magnetized, disk-shaped ones lying next to one another in the axial direction Magnets whose diameter is greater than that of the shaft are homopolar to each other to be arranged facing and assigned to these magnets, also encompassing them radially axially magnetized ring magnets on the most rigid bearing housing to provide the have the same pole sequence as the shaft magnet. They are then homopolar to each other opposite shaft and housing magnets help here but a magnetic one Radial neck bearing for the rotor shaft axially supported in a thrust bearing, the In addition, it is not stored on pairs of supporting rollers, so that the problem of the Insertion and detachment of the shaft in or from such a storage not at all represents.

It is also known (DT-OS 2 012 490), one on a pair of supporting rollers or in the wedge gap between two pairs of supporting rollers superimposed spinning rotor shaft To keep magnetic force in radial contact with the support rollers, with the most locally fixed Bearing block on the side of the shaft in the axial direction of the shaft superimposed, Axially magnetized magnets accommodating plate-shaped pole shoes between them are arranged with the same poles facing each other.

The magnets act on the ferromagnetic one by means of their pole shoes Material existing shaft, the free end of which is axially supported in a thrust bearing is and by a further permanent magnet arranged on the other side of the shaft end, the one attached to the end of the shaft and which protrudes considerably in diameter ferromagnetic disk is assigned, held axially in this thrust bearing is. So here the axial position of the shaft is mechanically determined by the thrust bearing, and the magnet arrangement there only serves to prevent the shaft from loosening secure from this thrust bearing. The designs made require when inserting of the shaft in the storage and when it is removed from this considerable lateral Movements of the shaft in relation to the support rollers.

Finally, it is known to stand between two pairs of support rollers Wedge gap to hold false twist tubes radially and axially by magnetic force (GD-PS 998 091). Dahei is an axially magnetized one that is connected to the Falschswallrührchen and a ring magnet of the same type with pole pieces at both ends, at the Support roller-mounted ring magnet assigned with its opposite poles. Since these one-sided magnet arrangements made to each other mainly the radial holder of the false twist tube on the support rollers, it results that the false twist tube with its ring magnet is inhomogeneous in the circumferential direction Magnetic field reverses, which inevitably leads to magnetic reversal losses are portable for such a relatively low mass to be held part, for one Holder of the genus according to the invention with regard to the occurring essential but coarser forces cannot be accepted without disadvantage. In addition, towers above also here the ring magnet connected to the rotating part of this part considerably in the radial direction, what for this bracket, in and out of the rest exposed false twist tubes inserted or removed in the radial direction

is taken out, although it is irrelevant when storing the but genus according to the invention because of the housing enclosing the spinning rotor not possible.

Through the development of the invention mentioned in claim 2 an optimal utilization of the magnetic forces and thus a particularly high spring stiffness reached the axial bracket. It is - - -so guaranteed that the on the shaft acting axial forces, for example from the acting on the spinning rotor Air currents are caused in the housing surrounding the spinning rotor According to the existing negative air pressure prevail there, a large magnetic restoring force opposes, which increases sharply with relatively small axial displacements.

The invention is explained below using an exemplary embodiment explained in more detail.

The figure shows a partially sectioned side view so-called indirect bearing for a spinning rotor of an open-end spinning device.

In the bearing block designated 1 are adjacent, but axially offset to each other, two bearing housings for one shaft 2 and 3 respectively. the Shaft 2 carries a pair of support rollers 4, 4 ', and shaft 3 carries a pair of support rollers 5, 5'. A shaft is supported in the wedge gap between these two pairs of supporting rollers 6, the radial of a tangential drive belt 7 resting on it on the other hand is pushed into the wedge gap. The shaft 6 reaches through on both sides with game shields of the bearing block 1 and carries at one end a spinning rotor 8, which is within a housing is not shown.

The axial fixation of the shaft 6 and thus the precise mounting of the spinning rotor 8 with respect to its associated walls of the housing and others Components of the spinning device, e.g. the fiber feed channel and the thread take-off tube, The magnet arrangement provided at the other end of the shaft is used.

At the free end of the illustrated shaft 6 are three identical, axially magnetized permanent magnets 9 attached '. Between the magnets and both ends the row of magnets are disc-shaped pole pieces 10, and the magnets 9 are arranged facing each other with the same poles.

The magnets 9 and their pole shoes 10 can be glued to one another and be connected to the shaft 6, then given them the same diameter that the shaft 6 has.

In addition to or without bonding, a mechanical Fixing the magnets and their pole pieces to each other and made on the shaft be, e.g. 8. through a through the magnets and the pole shoes, in the shaft inserted screw.

The figure shows that the magnets 9 and their pole pieces 10 in one correspondingly large, end-open cavity of a shaft attachment II from not magnetic material are used, and held in this, e.g. by gluing are. The shaft attachment 11 has the same external diameter as the shaft 6.

This shaft-side magnet arrangement is one with the bearing block 1 associated magnet assembly, which is attached to the bracket plate 12 in a Housing 13 is housed. In this housing 13 is for each of the shaft magnets 9 an axially magnetized ring magnet 14 encompassing it, corresponding axial Arranged length, and between these ring magnets 14 and both ends of this Ring magnet row there are ring-shaped pole shoes 15.

These ring magnets 14 are also facing each other homopolar but associated with the shaft magnets 9 in the opposite pole sequence, so that between the pole pieces 10 and 15 is a magnetic flux that the pole shoes 10 and thus also the rotor shaft 6 in the given position by the location of the pole shoes 15 forces and holds on in this.

The ring parts 14, 15 encompass the shaft attachment 11 with a narrow air gap. A cover 16 closing the housing 13 at the end holds these parts in their Fixed position.

The thickness of the pole shoes 10 and 15, that is to say their axial length, is advantageous slightly greater than the thickness they would be when saturated by the magnet have flow. This choice of thickness results in an optimal utilization of the magnetic forces and thus also the optimal spring stiffness of the axial bracket.

The compact magnet arrangement described allows when the belt 7 is not lifted much from the shaft 6, i.e. after the drive connection has been released, the shaft 6 by overcoming the magnetic force only in its axial direction to take out the outgrowths from its storage and insert them into them to be able to.

It is within the scope of the invention, instead of the three shown Magnet systems a different number of systems end in @ u @.

Claims (3)

Claims 1. Storage for the shaft of a spinning pot in which the Shaft held radially in a wedge gap between two pairs of supporting rollers and is fixed axially by magnets between the magnets attached to the shaft and there is associated magnets attached to the bearing block, d a d Lt r c h g e k e n n -z e i c h n e t that at the end of the shaft (6) while maintaining its diameter has at least two axially magnetized permanent magnets (9j with disc-shaped pole piece (10) assigned to each pole facing each other with the same poles are fixed and that each of these Schaf-tmagnete (9) a fixed on the bearing block (1), Axially magnetized Ftingmagnet arranged around the shaft with air gap spacing (14) of the same axial length with an annular pole piece arranged at each pole (15) is assigned and the ring magnets (14) in opposite to the shaft magnets (9) opposite pole sequence are arranged. 2. Storage according to claim 1, characterized in that the permanent magnet (9, 14) associated pole pieces (10, 15) has a thickness that is slightly is greater than the pole piece thickness existing at saturation by the magnetic flux. 3. Storage according to claim 1 and 2, characterized in that the Shaft-side magnets (9) with their pole pieces (10) in a cavity of a shaft attachment (11) are specified.