DE19822587B4 - Thrust bearing of an open-end spinning device - Google Patents

Abstract

Axial bearing of an open-end spinning device having a spinning rotor mounted without axial thrust, with a stationary magnetic bearing component arranged in a bearing housing and a magnetic bearing component revolving around the spinning rotor,
characterized,
- That the Statorlagerkomponente (36) is integrated in a bearing bush (40) which is slidably mounted within the bearing housing (34) of the thrust bearing (18) and
- That an adjusting and adjusting device (35) is provided, which allows a defined axial displacement of the stator bearing component (36).

Description

The The invention relates to a thrust bearing according to the preamble of the claim 1.

Magnetic thrust bearings for OE spinning rotors are known in principle and, for example, in the post-published DE 197 29 191 A1 described.

The Magnetaxiallager according to DE 197 29 191 A1 has a rotor bearing component rotating with the spinning rotor and a stator bearing component arranged stationarily in the bearing housing of the open-end spinning device. The rotor bearing component consists of three rotorschaftendseitig arranged, optimized with respect to their dimensions and positioning, ferromagnetic ring approaches, while the Statorlagerkomponente is formed by two enclosed between pole disks permanent magnet rings whose magnetic orientation is chosen so that the same direction poles of the permanent magnet rings face each other.

Such a trained Magnetaxiallager are not only almost wear and maintenance-free but, especially in connection with axial thrust bearing mounted spinning rotors, even at speeds well above 100,000 min ^-1 sufficiently stiff.

adversely in such constructions, however, that is integrated by the fixed in the bearing housing Stator bearing component also the position of the spinning rotor on the support disk bearing is fixed. This means, in such a configuration, there is no possibility, if necessary, the axial Position of the spinning rotor on the support disk bearing to correct.

Furthermore, by the DE 195 42 079 A1 a magnetic thrust bearing for an open-end spinning machine is known, comprising a rotating magnetic bearing component, which is releasably fixed to the rotor shaft of the spinning rotor and disposed between two magnetic bearing parts of a Statorlagerkomponente. For assembly or disassembly of the rotating magnetic bearing component, the rear magnetic bearing part of the stator bearing component can be removed.

The is called, during assembly of the spinning rotor, the spinning rotor is first with his rotor shaft inserted from the front into the thrust bearing housing and passes through the already mounted, front stationary magnetic bearing part.

Subsequently, will inserted from behind the rotatable magnetic bearing component in the thrust bearing housing and fixed to the rotor shaft. Finally, the rear stationary magnetic bearing part mounted, which is set in a screw.

On the Screw insert can only the position of the rear stationary magnetic bearing part and thus the axial dimensioning of the thrust bearing can be changed or the width of the air gaps between the stationary magnetic bearing parts and the rotatable magnetic bearing component can be adjusted.

The The width of the air gaps influences the hardness of the air gap magnetic thrust bearing.

There the front magnetic bearing part of the stator bearing component always immovable in a predetermined position remains, is also in this known Thrust bearing a defined adjustment of the working position of the spinning rotor, in particular a defined axial positioning of the in the gusset one Support disk bearing supported Spinning rotor not possible.

By the DE 40 09 375 A1 or the DE 39 14 777 A1 Bearing arrangements for OE spinning rotors are known in which the rotor shaft of the spinning rotor, due to the restricted arrangement of the support disk pairs, is subjected to an axial thrust component. The axial thrust component is intercepted by a rotor shaft end side arranged mechanical thrust bearing having a rotatably mounted ball. The ball is supported in a dome whose axial position is adjustable within the bearing housing via a support bolt.

outgoing From the aforementioned prior art, the invention is the task underlying, a magnetic thrust bearing for axial thrust bearing spinning rotors to create a defined axial positioning, in particular one in Lagerzwickel a support disk storage circulating spinning rotor allows.

These The object is achieved by a Device solved, as described in claim 1.

advantageous Embodiments of the invention are the subject of the dependent claims.

By the inventive design of Magnetaxiallagers with an adjustment and adjustment for Positioning the stator bearing component manages to get the benefits a usable in axial thrust-free storage of a spinning rotor Magnetic thrust bearing with the advantages of an axialschubbeaufschlagten to connect mechanical thrust bearing and their disadvantages to avoid.

That is, although a lubricant-free, almost completely maintenance-free thrust bearing is used, is a relatively simple way an exact one Position of the spinning rotor position in Lagerzwickel a support disk storage possible.

The axial position of a rotatable in Lagerzwickel a support disk storage stored spinning rotor can therefore, if necessary, at any time, even subsequently, easily can be corrected.

A such additional Correction of the spinning rotor, for example, in connection with the replacement of an open-end spinning unit or during initial assembly the open-end spinning machine to be required.

The Stator bearing component is integrated in a bearing bush, which in turn mounted linearly displaceable within a bearing housing is.

The is called, the arranged between pole disks permanent magnet rings are Although fixed rigidly in the bearing bush, can be due to axial displacement the bearing bush with respect of the bearing housing However, also slightly shifted axially.

A Device as described in claims 2 and 3, guaranteed not only that Bearing bush secured within the bearing housing against rotation, linear but displaceable remains, but also offers also the possibility the axial displacement of the bearing bush and thus also the adjustment the stationary magnetic bearing component to limit exactly.

On this way can be reliable be prevented that the stationary Magnetic bearing component is shifted to a position in which the Spinning rotor can start to stationary components of the spin box.

In advantageous embodiment is also as set forth in claim 4, provided that the bearing bush by a radially attacking clamping device can be acted upon. This clamping device, preferably by a vertically acting from above clamping screw is formed, ensures that this Bearing clearance with which the bearing bush in the central receiving bore of the bearing housing guided is while the spinning process is balanced down.

The is called, by the clamping device, the stator bearing component and thus the rotor shaft of the spinning rotor in the direction of the Lagerzwickel the Support disk bearing shifted, which has a positive effect on the running of the spinning rotor.

Also through the clamping screw is a limitation of the maximum adjustment the bushing possible.

The Clamping screw engages in this case with a corresponding guide lug in a slot-like recess of the bearing bush.

The Adjustment according to the invention and adjusting device of the magnetic thrust bearing can be various embodiments exhibit.

In a first advantageous embodiment has the adjustment and adjustment one in the bearing housing out Screw bolt (claim 5). The bolt can, for example, in bearing housing rotatable but axially fixed, be arranged and with one end arranged threaded approach in a corresponding threaded hole the bearing bush run. In such an arrangement, each leads Turn the bolt to secure axial displacement the bearing bush.

In kinematic reversal of the above construction, the Bolt, of course also rotatable, but axially fixed, connected to the bearing bush be. In this case, running the threaded bolt with a threaded neck in a corresponding Threaded hole of the bearing housing. Even such a training leads to an exact adjustment for the Statorlagerkomponente.

A comparable, particularly advantageous embodiment is in the claim 6 described.

Of the Screw bolt has in this case end each threaded sections with each opposite Thread, preferably fine thread, on.

one the two opposing ones Thread sections corresponds with a corresponding Threaded hole in the bearing housing, during the other threaded section in a threaded bore of the bearing bush running. In such a training leads already a minor one Twist the bolt to an effective displacement the stator bearing component.

A second alternative embodiment a setting and adjusting device for a magnetic thrust bearing is described in claim 7.

The Setting and adjusting device is designed as an eccentric. Such an eccentric is on the one hand very robust and low maintenance, on the other hand, eccentrics are their production relatively inexpensive.

Of the Eccentric preferably has a bearing pin and a thereto eccentrically arranged cylindrical switch body.

Of the Journal, which forms the axis of rotation of the eccentric, is in one rotatably mounted bearing bore of the bearing housing during the switching body a bore cutout in the guide body of Bearing bushing.

Further Details of the invention are explained with reference to the drawings embodiments removable.

It shows:

1 1 schematically shows an open-end spinning device with a spinning rotor positioned by a magnetic thrust bearing, the thrust bearing having an adjusting and adjusting device according to the invention,

2 a plan view of the mounting of an open-end spinning rotor, the rotor shaft end is supported in one, a setting and adjusting device according to the invention, having magnetic thrust bearing,

3 a first Ausführugsform of the in the 1 and 2 merely indicated magnetic thrust bearing with adjusting and adjusting device, in section,

4 a further embodiment of a magnetic thrust bearing with a setting and adjusting device,

5 a bearing bush for receiving the stator bearing component, according to the embodiment 4 ,

This in 1 shown open-end spinning aggregate bears the reference number 1 ,

The spinning unit 1 has, as usual, a rotor housing 2 in which the spinning cup of a spinning rotor 3 revolves at high speed. The spinning rotor 3 is with his rotor shaft 4 in the bearing gusset of a support disk bearing 5 supported by a machine-length tangential belt 6 that by a pressure roller 7 is hired. The axial fixation of the rotor shaft 4 on the support disk storage 5 via a permanent magnetic thrust bearing 18 , The magnetic thrust bearing 18 has an adjusting and adjusting device according to the invention 35 on. Various embodiments of such an adjustment and adjustment 35 are in the 3 and 4 shown in detail.

As is known, the forwardly open itself to the rotor housing 2 during the spinning operation by a pivotally mounted cover element 8th , in which a (not shown) channel plate with a seal 9 let in, locked. The rotor housing 2 is also via a corresponding suction line 10 to a vacuum source 11 connected in the rotor housing 2 necessary spin negative pressure generated.

In the lid element 8th is a channel plate adapter 12 arranged, which the thread take-off nozzle 13 and the mouth region of the fiber guide channel 14 having. To the thread take-off nozzle 13 closes, as usual, a thread withdrawal tube 15 at.

On the cover element 8th that is about a pivot axis 16 is limited rotatably mounted, is also an opening roller housing 17 established. The cover element 8th also has bearing brackets on the back 19 . 20 for storage of an opening roller 21 or a sliver draw-in cylinder 22 on. The opening roller 21 is doing in the field of her whorl 23 by a circumferential, machine-long tangential belt 24 driven during the (not shown) drive the sliver feed cylinder 22 preferably via a worm gear arrangement, which is on a machine-length drive shaft 25 is switched.

The 2 shows the storage of an open-end spinning rotor 3 in plan view. As indicated, this is from a spinning cup 26 and a rotor shaft 4 existing spinning rotor 3 with its rotor shaft 4 in the gussets a total with 5 supported support bearing supported.

Such support disk bearings 5 have two support disk pairs 29 . 30 whose axes 31 are arranged parallel to each other. The support disk pairs 29 . 30 form with their support disks 29 ' . 30 ' and 29 '' . 30 '' Bearing gland for the rotor shaft 4 , The support discs connected via axes are with their bearing housings 27 . 28 on a warehouse console 32 which in turn (in 2 not shown) on the spinning box frame of the open-end spinning unit 1 is attached.

The warehouse console 32 is in the range of the rotor axis 33 , for receiving a magnetic thrust bearing 18 , as bearing housing 34 educated.

The magnetic thrust bearing 18 , especially in the 3 and 4 is shown in detail, as shown in the DE 197 29 191 already known, a stationary magnetic bearing component 36 and a rotating magnetic bearing component 37 on.

The stationary magnetic bearing component 36 consists of permanent magnet rings 38 between the pole discs 39 arranged and together with these in a bushing 40 are fixed.

The rotating magnetic bearing component 37 is arranged by rotorschaftendseitig, ferromagnetic ring approaches 41 educated.

The bearing bush 40 is in a central receiving hole 42 of the bearing housing 34 mounted axially displaceable; their axial position within the bearing housing 34 is about an adjustment and adjustment 35 exactly adjustable.

At the bearing bush 40 grip except the adjustment and adjustment 35 , another twist lock 43 and a clamping device 46 at.

The anti-twist device 43 consists preferably of a radially arranged screw 44 that with a guide lug in an axial groove 45 the bearing bush 40 slides. Through the into the axial groove 45 engaging set screw 44 is the bearing bush 40 on the one hand reliably secured against rotation, on the other hand, the axial displacement of the bearing bush remains 40 fully exist. The in the axial groove 45 engaging set screw 44 also offers the possibility of the degree of maximum axial displacement of the bearing bush 40 inside the bearing housing 34 pretend.

The anti-twist device 43 radially opposite arranged clamping device 46 consists of a clamping screw 47 radially on the bearing bush 40 is adjustable.

That is, by means of the clamping device 46 can the bushing 40 with bearing play in the receiving hole 42 of the bearing housing 34 is stored, slightly shifted down. This shift of the bearing bush 40 also leads to a slight displacement of the stator bearing component 36 in the direction of the bearing gussets of the support disk bearing 5 and on the associated increase in the contact pressure, with the spinning rotor shaft 4 on the support disks 29 ' . 29 '' . 30 ' . 30 '' overall, stabilizes the spinning process.

The clamping screw 47 the clamping device 46 can be directly on the bushing 40 act or take in a (not shown) slot in the bearing bush 40 is incorporated. In this case is also about the clamping device 46 a limitation of the maximum adjustment of the bearing bush 40 inside the bearing housing 34 possible.

The adjusting and adjusting device according to the invention 35 for shifting the bearing bush 40 can, for example, as in 3 indicated by a bolt 48 or alternatively, as in 4 shown by an eccentric 49 be formed.

According to embodiment 3 has the adjustment and adjustment 35 preferably a bolt 48 with two threaded sections 48 ' and 48 '' , The threaded sections 48 ' and 48 '' each have opposing threads.

That is, the threaded portion 48 '' has, for example, a left-handed fine thread, with a correspondingly formed threaded hole 50 in the bearing bush 40 corresponds during the threaded section 48 ' has a right-hand thread, which then in a corresponding, in the bearing housing 34 arranged threaded hole 51 running.

In or on the outwardly directed end portion of the bolt 48 In addition, a connection device (not shown) for a tool is provided.

The bolt 48 can then be defined by a suitable tool twisted and thus the bearing bush 40 with the stator bearing component 36 exactly in the desired position within the bearing housing 34 be positioned. The set position can then via the lock nut 52 be secured reliably.

The 4 shows a further, alternative embodiment of a setting and adjusting device 35 for a magnetic thrust bearing. The axial displacement of the bearing bush 40 inside the bearing housing 34 takes place via an eccentric 49 ,

This eccentric 49 has, as indicated, a journal 53 with an end thread 54 and a cylindrical switch body 55 on. The central axis 56 of the cylindrical switch body 55 is opposite to the central axis 57 of the journal 53 , which is the axis of rotation of the eccentric 49 forms arranged offset by the measure e.

The switch body 55 of the eccentric 49 preferably ends in a head 58 , For example, has connection options for a tool or the like.

As in 5 represented, the switch body passes through 55 of the eccentric 49 a hole cutout 60 in the guide body 59 the bearing bush 40 ,

That is, through the hole in the hole 60 mounted switch body 55 can the rotational movement of the eccentric 49 be converted into a linear movement, resulting in an axial displacement of the bearing bush 40 inside the bearing housing 34 leads. Because every axial displacement of the bearing bush 40 also to a displacement of the stator bearing component 36 with respect to the bearing bush 34 leads, is with the above adjustment and adjustment 35 at any time a sensitive axial positioning of the in the Lagerzwickeln the support disc bearing 5 rotatably mounted spinning rotor 3 possible.

critical is that the magnetic thrust bearing has a setting and adjusting device, the a defined displacement of a bushing arranged in a bearing housing, in which a Statorlagerkomponente is integrated, allows.

Claims (8)

Axial bearing of an open-end spinning device having a spinning rotor mounted without axial thrust, with a arranged in a bearing housing, stationary magnetic bearing component and a rotating with the spinning rotor magnetic bearing component, characterized in that - the stator bearing component ( 36 ) in a bushing ( 40 ) integrated within the bearing housing ( 34 ) of the thrust bearing ( 18 ) is displaceably mounted and - that an adjusting and adjusting device ( 35 ) is provided which a defined axial displacement of the stator bearing component ( 36 ). Thrust bearing according to claim 1, characterized in that in a receiving bore ( 42 ) of the bearing housing ( 34 ) slidably guided bearing bush ( 40 ) by an anti-rotation device ( 43 ) is secured against rotation. Thrust bearing according to claim 2, characterized in that the rotation ( 43 ) by a radially arranged, in an axial groove ( 45 ) slidably guided safety bolts ( 44 ) is formed. Thrust bearing according to one of the preceding claims, characterized in that a clamping device ( 46 ) is provided, the bearing bush ( 40 ) acted upon radially in the operating state. Thrust bearing according to one of the preceding claims, characterized in that the adjusting and adjusting device ( 35 ) by an axial to the rotor axis ( 33 ) arranged bolts ( 48 ) is formed. Thrust bearing according to claim 5, characterized in that the bolt ( 48 ) two threaded sections ( 48 ' . 48 ' ') having opposing threads, wherein the threaded portion ( 48 ' ') with a threaded hole ( 50 ) in the bearing bush ( 40 ) corresponds, while the threaded portion ( 48 ' ) in a corresponding threaded hole ( 51 ) of the bearing housing ( 34 ) running. Thrust bearing according to one of claims 1 to 6, characterized in that the adjusting and adjusting device ( 35 ) as an eccentric ( 49 ) is trained. Thrust bearing according to claim 7, characterized in that the eccentric ( 49 ) via a bearing journal ( 53 ) in the bearing housing ( 34 ) is rotatably mounted and with respect to the journal ( 53 ) eccentrically arranged, cylindrical switch body ( 55 ) a bore cutout ( 60 ) in the guide body ( 59 ) of the bearing bush ( 40 ).