DE19822587A1 - Magnetic axial end bearing for open end spinning rotor with provision for adjustment in axial direction - Google Patents

Abstract

The stator components (36) of the magnetic end bearing are held in a housing (40) that can be moved and adjusted axially within the bearing body (34). Adjustment can be by a double set screw (48) or alternatively by an eccentric cam bolt. The housing (40) is prevented from rotating by a bolt (44) in a groove (45) and is fixed in position by a radial clamping bolt (47).

Description

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

Magnetic axial bearings for OE spinning rotors are in principle known and for example in the post-published DE 197 29 191.0.

The magnetic axial bearing according to DE 197 29 191.0 has one with the Spinning rotor rotating rotor bearing component and one in Bearing housing of the open-end spinning device stationary arranged stator bearing component. The rotor bearing component consists of three rotor shaft ends, optimized in terms of their dimensions and positioning, ferromagnetic ring approaches while the Stator bearing component by two between pole disks enclosed permanent magnet rings is formed, the magnetic alignment is chosen so that there is the same direction The poles of the permanent magnet rings face each other.

Such trained Magnetaxiallager are not only virtually wear and maintenance-free but, particularly in the context of axial thrust bearings spinning rotors, even at speeds far sufficiently rigid than 100,000 min ^-1.

A disadvantage of such constructions, however, is that the stator bearing component integrated in the bearing housing also the position of the spinning rotor on the support disc bearing is fixed. That is, with such training there is no possibility, if necessary, the axial position of the Correct the spinning rotor on the support disc bearing.  

By DE 40 09 375 A1 or DE 39 14 777 A1 Bearing arrangements for OE spinning rotors known in which the Rotor shaft of the spinning rotor, due to the set Arrangement of the pairs of support disks, with an axial Thrust component is applied. The axial thrust component is by a mechanical arranged on the rotor shaft end Axial bearing intercepted, which is a rotatably mounted ball having. The ball is supported in a spherical cap, their axial position within the bearing housing via a Support bolt is adjustable.

Starting from the aforementioned prior art, the Invention, the object of a magnetic thrust bearing for creating axially thrust-free spinning rotors, one defined axial positioning, especially one in Bearing gusset of a support disc bearing rotating Spinning rotor enables.

This object is achieved by a device solved, as described in claim 1.

Advantageous embodiments of the invention are the subject of Subclaims.

Due to the inventive design of the magnetic axial bearing an adjustment and adjustment device for positioning the Stator bearing component manages to take advantage of one Axial thrust-free storage of a spinning rotor can be used magnetic thrust bearing with the advantages of a to connect axial thrust mechanical axial bearings while avoiding their disadvantages.

That is, although a lubricant-free, almost completely maintenance-free thrust bearing is used, is relative  simple way to set the spinning rotor position exactly possible in the gusset of a supporting disc bearing.

The axial position of one in the bearing gusset Support disc storage rotatably mounted spinning rotor can therefore at any time, even retrospectively, without any problems can be corrected.

Such a subsequent position correction of the spinning rotor can for example in connection with the exchange of a Open-end spinning unit or during the initial assembly of the open-end Spinning machine may be required.

As set out in claim 2, the stator bearing component is in a bearing bush integrated, which in turn within a Bearing housing is linearly displaceable.

That is, those arranged between pole disks Permanent magnet rings are rigid in the bearing bush can be determined by axial displacement of the bearing bush with respect to the bearing housing, however, also slightly axially be relocated.

A device as described in claims 3 and 4 is not only ensures that the bearing bush secured against rotation within the bearing housing, linear however remains movable, but also offers the possibility of the axial adjustment of the bearing bush and thus also the adjustment path of the stationary Limit the magnetic bearing component exactly.

In this way, the stationary magnetic bearing component moved to a position is in which the spinning rotor on standing components of the spinning box can start.  

In an advantageous embodiment is also, as in Claim 5 set out that the bearing bush through a radially acting clamping device can be acted upon. This clamping device, preferably by a vertical clamping screw acting from above, ensures that that the bearing play with which the bearing bush in the central Location bore of the bearing housing is guided during the Spinning process is balanced down.

That is, the clamping device Stator bearing component and thus the rotor shaft of the spinning rotor in the direction of the bearing gusset of the support disc bearing shifted, which positively affects the run of the spinning rotor affects.

The clamping screw also limits the maximum Adjustment path of the bearing bush possible.

In this case, the clamping screw engages with one corresponding guide approach in a slot-like recess the bearing bush.

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

In a first advantageous embodiment, the adjustment and adjusting device a guided in the bearing housing Screw bolts (claim 6). The screw bolt can for example rotatable in the bearing housing, but axially fixed, be arranged and arranged with an end Thread approach in a corresponding threaded hole in the Run bushing. With such an arrangement, each leads Rotation of the bolt to a secure axial Relocation of the bearing bush.  

In kinematic reversal of the construction described above can the bolt is of course also rotatable, however axially fixed, be connected to the bearing bush. In this The threaded bolt runs with a threaded shoulder in one case corresponding threaded hole in the bearing housing. Also one such training leads to an exact setting for the stator bearing component.

A comparable, particularly advantageous embodiment is described in claim 7.

In this case, the screw bolt has an end at each end Thread sections with opposite threads, preferably fine thread.

One of the two opposite thread sections corresponds with a corresponding threaded hole in the bearing housing, while the other threaded section in a threaded bore of the Bearing bush is running. Such training already leads a slight twist of the bolt to one effective displacement of the stator bearing component.

A second alternative embodiment of a setting and Adjustment device for a magnetic thrust bearing is in the Claim 8 described.

The setting and adjustment device is an eccentric educated. On the one hand, such an eccentric is very robust and low maintenance, on the other hand are eccentric in terms of their Manufacturing relatively inexpensive.

The eccentric preferably has a bearing journal and one for this purpose eccentrically arranged cylindrical switch body. The bearing journal that forms the axis of rotation of the eccentric is in a corresponding bearing bore of the bearing housing is rotatable stored while the switch body has a hole cutout in Guide body of the bearing bush passed through.

Further details of the invention are based on the Drawings of exemplary embodiments explained.

It shows:

Fig. 1 shows schematically an open-end spinning device with a positioned by an axial magnetic bearing rotor spinning, wherein the thrust bearing has an adjustment and alignment device according to the invention,

Fig. 2 is a plan view, magnetic axial bearing is supported on the bearing of open-end spinning rotor, the rotor shaft having its end in a an adjustment and alignment device according to the invention,

Fig. 3 shows a first embodiment of the, in FIGS. 1 and 2 merely indicated magnetic axial bearing including setting and adjusting, in section

Fig. 4 shows a further embodiment of a magnetic thrust bearing having an adjustment and alignment device,

Fig. 5 is a bearing bush for receiving the Statorlagerkomponente, according to Embodiment Fig. 4.

The open-end spinning unit shown in FIG. 1 bears the overall reference number 1 .

As usual, the spinning unit 1 has a rotor housing 2 in which the spinning cup of a spinning rotor 3 rotates at high speed. The spinning rotor 3 is supported with its rotor shaft 4 in the bearing gusset of a support disk bearing 5 and is acted upon by a machine-long tangential belt 6 , which is started by a pressure roller 7 . The rotor shaft 4 is axially fixed on the support disk bearing 5 by means of a permanent magnetic axial bearing 18 . The magnetic axial bearing 18 has an adjusting and adjusting device 35 according to the invention. Various embodiments of such an adjustment and adjustment device 35 are shown in detail in FIGS. 3 and 4.

As is known, the rotor housing 2 , which is open towards the front, is closed during the spinning operation by a pivotably mounted cover element 8 , into which a channel plate (not shown) is inserted with a seal 9 . The rotor housing 2 is also connected via a corresponding suction line 10 to a vacuum source 11 , which generates the spinning vacuum required in the rotor housing 2 .

In the cover member 8 is a channel plate adapter 12 is disposed, which has the yarn withdrawal nozzle 13 as well as the mouth area of the fiber guide channel fourteenth As usual, a thread take-off tube 15 connects to the thread take-off nozzle 13 .

On the cover element 8 , which is rotatably supported to a limited extent about a swivel axis 16 , an opening roller housing 17 is also fixed. The cover element 8 furthermore has bearing brackets 19 , 20 on the back for mounting an opening roller 21 or a sliver feed cylinder 22 . The opening roller 21 is driven in the region of its whorl 23 by a circumferential, machine-long tangential belt 24 , while the (not shown) drive of the sliver feed cylinder 22 is preferably carried out via a worm gear arrangement which is connected to a machine-long drive shaft 25 .

Fig. 2 shows the mounting of an open-end spinning rotor 3 in plan view. As indicated, the existing of a spinning cup 26 and a rotor shaft 4 spinning rotor 3 is supported by its rotor shaft 4 in the bearing interstices of a support disk bearing, generally designated by 5.

Such support disc bearings 5 have two support disc pairs 29 , 30 , the axes 31 of which are arranged parallel to one another. The pairs of support disks 29 , 30 , with their support disks 29 ′, 30 ′ and 29 ″, 30 ″, form bearing gussets for the rotor shaft 4 . The support disks connected via axles are fixed with their bearing housings 27 , 28 to a bearing bracket 32 , which in turn (not shown in FIG. 2) is attached to the spinning box frame of the open-end spinning unit 1 .

The bearing bracket 32 is designed as a bearing housing 34 in the region of the rotor axis 33 for receiving a magnetic axial bearing 18 .

The magnetic axial bearing 18 , which is shown in detail in particular in FIGS . 3 and 4, has, as already known from DE 197 29 191, a stationary magnetic bearing component 36 and a rotating magnetic bearing component 37 .

The stationary magnetic bearing component 36 consists of permanent magnet rings 38 which are arranged between pole disks 39 and are fixed together with them in a bearing bush 40 .

The circumferential magnetic bearing component 37 is formed by ferromagnetic ring extensions 41 arranged on the rotor shaft end.

The bearing bush 40 is axially displaceably mounted in a central receiving bore 42 in the bearing housing 34 ; their axial position within the bearing housing 34 can be exactly adjusted by means of an adjusting and adjusting device 35 .

In addition to the setting and adjustment device 35 , an anti-rotation device 43 and a clamping device 46 also engage on the bearing bush 40 .

The anti-rotation device 43 preferably consists of a radially arranged adjusting screw 44 which slides with a guide projection in an axial groove 45 of the bearing bush 40 . By the adjusting screw 44 engaging in the axial groove 45 , the bearing bush 40 is on the one hand reliably secured against rotation, on the other hand the axial displaceability of the bearing bush 40 remains fully intact. The adjusting screw 44 engaging in the axial groove 45 also offers the possibility of specifying the extent of the maximum axial displacement of the bearing bush 40 within the bearing housing 34 .

The clamping device 46, which is arranged radially opposite the anti-rotation device 43, consists of a clamping screw 47 which can be adjusted radially onto the bearing bush 40 .

That is, by means of the clamping device 46 , the bearing bush 40 , which is mounted with bearing play in the receiving bore 42 of the bearing housing 34 , can be displaced slightly downwards. This displacement of the bearing bush 40 also leads to a slight displacement of the stator bearing component 36 in the direction of the bearing gusset of the support disk bearing 5 and via the associated increase in the contact pressure with which the spinning rotor shaft 4 on the support disks 29 ', 29 '', 30 ', 30 ''overall stabilizes the spinning process.

The clamping screw 47 of the clamping device 46 can act directly on the bearing bush 40 or grasp in an elongated hole (not shown) which is incorporated in the bearing bush 40 . In this case, a limitation of the maximum adjustment path of the bearing bush 40 within the bearing housing 34 is also possible via the clamping device 46 .

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

According to the embodiment of FIG. 3, the setting and adjustment device 35 preferably has a screw bolt 48 with two threaded sections 48 'and 48 ''. The threaded sections 48 'and 48 ''each have opposite threads.

This means that the threaded section 48 '' has, for example, a left-handed fine thread, which corresponds to a correspondingly designed threaded bore 50 in the bearing bush 40 , while the threaded section 48 'has a right-handed thread, which then runs in a corresponding threaded bore 51 arranged in the bearing housing 34 .

A connection device (not shown) for a tool is also provided in or on the outward end region of the screw bolt 48 .

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

FIG. 4 shows a further alternative embodiment of an adjustment and alignment device 35 for a magnetic thrust bearing. The axial displacement of the bearing bush 40 within the bearing housing 34 takes place via an eccentric 49 .

As indicated, this eccentric 49 has a bearing journal 53 with an end thread 54 and a cylindrical switching body 55 . The central axis 56 of the cylindrical switching body 55 is offset from the central axis 57 of the journal 53 , which forms the axis of rotation of the eccentric 49 , by the dimension e.

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

As shown in FIG. 5, the switching body 55 of the eccentric 49 includes a bore cutout 60 in the guide body 59 of the bearing bush 40 .

That is, the switching body 55 mounted in the bore cutout 60 enables the rotary movement of the eccentric 49 to be converted into a linear movement, which leads to an axial displacement of the bearing bush 40 within the bearing housing 34 . Since any axial displacement of the bearing sleeve 40 also with respect to the bushing results in a displacement of the Statorlagerkomponente 36 34, any time a sensitive axial positioning of the rotatably mounted in the bearing interstices of the support disk bearing 5 the spinning rotor 3 is possible with the above described adjustment and alignment device 35th

The invention is not based on those described in the Exemplary embodiments shown for drawings for and adjustment devices limited.

Within the scope of the general inventive concept are quite further embodiments conceivable without the general inventive idea is left. It is crucial that the magnetic thrust bearing and adjusting device having a defined Relocation of one arranged in a bearing housing  Bearing bush into which a stator bearing component is integrated, enables.

Claims (9)

1. Axial bearing of an open-end spinning device which has a spinning rotor mounted without axial thrust, with a stationary magnetic bearing component arranged in a bearing housing and a magnetic bearing component rotating with the spinning rotor, characterized in that

• - That the stator bearing component ( 36 ) is slidably mounted within the axial bearing ( 18 ) and
• - That an adjusting and adjusting device ( 35 ) is provided, which enables a defined axial displacement of the stator bearing component ( 36 ).

2. Axial bearing according to claim 1, characterized in that the stator bearing component ( 36 ) is integrated in a bearing bush ( 40 ) which is guided linearly displaceably within the bearing housing ( 34 ). 3. Axial bearing according to claim 1 and 2, characterized in that in a receiving bore ( 42 ) of the bearing housing ( 34 ) displaceably guided bearing bush ( 40 ) is secured against rotation by an anti-rotation device ( 43 ). 4. Axial bearing according to claim 3, characterized in that the anti-rotation device ( 43 ) is formed by a radially arranged, in an axial groove ( 45 ) slidably guided locking bolt ( 44 ). 5. Axial bearing according to one of the preceding claims, characterized in that a clamping device ( 46 ) is provided which acts on the bearing bush ( 40 ) radially in the operating state. 6. Axial bearing according to one of the preceding claims, characterized in that the adjusting and adjusting device ( 35 ) is formed by a screw bolt ( 48 ) arranged axially to the rotor axis ( 33 ). 7. thrust bearing according to claim 6, characterized in that the screw bolt ( 48 ) has two threaded portions ( 48 ', 48 '') which have opposite threads, the threaded portion ( 48 '') with a threaded bore ( 50 ) in the bearing bush ( 40 ) corresponds while the threaded section ( 48 ') runs in a corresponding threaded bore ( 51 ) of the bearing housing ( 34 ). 8. thrust bearing according to one of claims 1 to 5, characterized in that the adjusting and adjusting device ( 35 ) is designed as an eccentric ( 49 ). 9. Axial bearing according to claim 8, characterized in that the eccentric ( 49 ) is rotatably mounted via a bearing pin ( 53 ) in the bearing housing ( 34 ) and with a cylindrical switching body ( 55 ) eccentrically arranged with respect to the bearing pin ( 53 ), a bore cutout ( 60 ) in the guide body ( 59 ) of the bearing bush ( 40 ).