DE102013106687A1 - Thrust bearing for a shaft mounted on support shafts of a rotor of a rotor spinning machine - Google Patents

Abstract

The invention relates to an axial bearing for a shaft (3) of a rotor (4) of a rotor spinning machine mounted on support rollers (2a-2d), with a bearing housing (5), with an axial stop (6) arranged on the bearing housing (5) for supporting an a spinning cup (7) of the rotor (4) opposite the free end (8) of the shaft (3) in an axial direction (AR) and with a permanent magnet arrangement (9) for producing a shaft (4) during operation of the rotor (4) 3) acting axial force that the free end (8) is pressed against the axial stop (6), the permanent magnet arrangement (9) being arranged on a side of the bearing housing (5) facing the spinning cup (7).

Description

The invention relates to a thrust bearing for a shaft mounted on support shafts of a rotor of a rotor spinning machine, comprising a bearing housing, with an arranged on the bearing housing axial stop for supporting a spinning cup of the rotor opposite free end of the shaft in an axial direction and with a permanent magnet assembly for generating a during operation of the rotor so acting on the shaft axial force that the free end is pressed against the stop.

The object of the present invention is to improve such a thrust bearing.

The object is achieved in a thrust bearing mentioned above in that the permanent magnet arrangement is arranged on a side facing the spinning cup side of the bearing housing.

Conventional rotor spinning machines include a plurality of juxtaposed spinning stations, each of which has a spinning device. The core element of each spinning device is a so-called rotor having a spinning cup and a shaft. In this case, the spinning cup is used for the actual spinning process, in which individually fed staple fibers are aligned and twisted by a rotation of the rotor, so that a yarn is formed. The shaft of the rotor serves to support and drive the rotor. Due to the high rotational speeds of the rotor, which are more than 100 000 U / min, it is not possible to store the shaft with conventional bearings, for example with deep groove ball bearings.

Rather, it has proven to be advantageous to store the shaft in the radial direction in a bearing gap formed by rotatable support disks. The support disks in this case have a substantially larger diameter than the shaft of the rotor, so that the support disks have a much lower rotational speed than the rotor and can therefore be stored by means of conventional rolling bearings. The drive of the rotor can be done by means of a high-speed drive belt, which bears against the shaft of the rotor and the rotor by frictional rotation. The drive belt can rest against the bearing gap radially opposite side of the shaft, so that the shaft is pressed into the bearing gap.

In order to support the rotor in the axial direction, it is common practice to support the spinning cup opposite the free end of the shaft in an axial direction by means of an axial stop. The axial stop may comprise a fixed or a rotatable stop element. In order to reduce the friction between the free end of the shaft and the axial stop, means for producing a fluid film, such as air or oil, may be provided between the free end of the shaft and the axial stop. The axial stop and the free end of the shaft of the rotor are usually arranged in a substantially closed bearing housing, and thus protected from contamination. In this case, the rotor is acted upon at least during its operation with an axial force which presses the rotor against the axial stop so as to fix the rotor in the axial direction. In practice, this axial force is caused by a skewed arrangement of the axes of the support disks. As a result, however, due to increased friction of the energy consumption of the rotor spinning machine, as well as the wear of the support disks, increased.

In addition, proposals have become known to generate this axial force by a permanent magnet arrangement. Under a permanent magnet arrangement is understood an arrangement of one or more permanent magnets. For example, it has been proposed to provide on the side facing away from the shaft of the radial stop a pull magnet which is to pull the existing of a ferromagnetic material free end to the axial stop. In practice, however, this solution could not prevail because the axial forces thus generated were too small to safely store the rotor.

According to the invention, the generic thrust bearing is further developed such that the permanent magnet arrangement is arranged on a side facing the spinning cup side of the bearing housing.

The shaft may comprise any magnetic and / or magnetizable material. In particular, a ferromagnetic material, such as iron, nickel and / or cobalt, may be provided here.

In this case, it is possible to place the permanent magnet arrangement at a smaller distance from the shaft of the rotor than is the case with solutions in which the permanent magnet arrangement is arranged on that side of the bearing housing on which the axial stop is also formed, since thus the axial stop the positioning of the permanent magnet assembly is not hindered. As a result, the magnetically generated axial force can be increased, so that the rotor is securely guided in the axial direction.

Since both the axial stop and the permanent magnet arrangement are arranged or fixed on the bearing housing, the axial stop and the permanent magnet arrangement can be positioned very accurately relative to one another, so that also the shaft can be accurately positioned with respect to the permanent magnet assembly in the axial direction. Thereby, the distance between the tapered portion of the rotor and the permanent magnet assembly can be further reduced, so that the axial force can be further increased.

In addition, it is possible to bring a larger volume of the shaft in the range of action of the permanent magnet assembly, as in the solutions of the prior art, in which the permanent magnet assembly is disposed on that side of the bearing housing on which the axial stop is formed, possible would.

Overall, the thrust bearing according to the invention causes a sufficient magnetic axial force to the rotor even when undesirable opposing forces, which are caused for example by an imbalance in the rotor, defective or dirty support disks, a defective or dirty drive belt and / or defective pressure rollers for the drive belt to press safely against the axial stop.

According to an advantageous development of the invention, the permanent magnet arrangement is designed to cooperate with a section of the shaft which tapers towards the free end of the shaft. In this case, a section of the shaft which tapers towards the free end is understood as meaning a section in which the cross-section of the shaft is reduced. The tapering section may in particular have a stepped decrease in the cross section and / or a continuous decrease in the cross section. Such a tapered portion can be easily provided between the support discs and the axial stop, since in this area at most low axial forces act on pressure and virtually no radial forces. The shaft and / or in particular the tapering section may comprise any magnetic and / or magnetizable material. In particular, a ferromagnetic material, such as iron, nickel and / or cobalt, may be provided here.

In this way, it is possible to bring a larger volume of the shaft in the range of action of the permanent magnet assembly, without that on the shaft an additional magnetic or magnetizable volume is formed, in which an expanding towards the free end of the shaft portion, ie a Section with increasing cross section, is provided.

According to an advantageous development of the invention, the permanent magnet arrangement comprises a ring magnet. Under a ring magnet is understood to be an annular permanent magnet. With a ring magnet, a magnetic field can be generated in a simple manner, which is rotationally symmetrical with respect to the axis of the rotor and thus of the shaft. In this way, the formation of eddy currents in the shaft can be prevented, which would brake the rotor as a whole and thus increase the energy consumption of the rotor spinning machine.

According to an advantageous development of the invention, the permanent magnet arrangement is arranged in a region around a passage opening of the bearing housing for the shaft. In this way results, in particular in the axial direction, a compact construction of the thrust bearing.

According to an advantageous development of the invention, the permanent magnet arrangement is part of a sealing cap, preferably an exchangeable sealing cap, of the bearing housing. In this way, the permanent magnet arrangement fulfills two tasks, namely the sealing of the bearing housing on the one hand and the generation of the axial force on the other. The sealing cap can for example be made of a fine-grained permanent magnetic material, which is mixed with a binder and then brought into permanent form. It is also possible that the sealing cap has a particular non-magnetic base body, for example made of plastic, in which the or the actual permanent magnets cast, latched, glued, pressed or the like. If the sealing cap replaceable, that is non-destructive replaceable, defective permanent magnets can be easily replaced.

According to an advantageous embodiment of the invention, a radially spaced from the shaft run-up stopper is provided, which prevents the shaft from bouncing against the permanent magnet arrangement during a radial movement of the shaft. A radial movement is understood to mean a radially directed movement of the shaft from its intended operating position. The radially spaced starting stopper can prevent damage to the permanent assembly in such, usually unwanted movement. For example, the main body of the sealing cap can be designed as a starting stop.

According to an advantageous embodiment of the invention, a substantially closed lubricant chamber for a lubricant for lubricating the axial stop and the free end is formed in the bearing housing. In this way, the bearing housing takes over several functions, namely the protection of the thrust bearing against external influences, such as mechanical effects and contamination, the bearing of the axial stop and the permanent magnet arrangement and now additionally providing a lubricant for lubricating the axial stop and the free end, thereby reducing the friction between the axial stop and the free end and thereby reducing wear. The lubricant may in particular be a grease or an oil.

According to an advantageous development of the invention, the permanent magnet arrangement is separated from the lubricant chamber by a seal formed on the bearing housing with a second passage opening for the shaft. In this way, contamination of the permanent magnet assembly by lubricant can be largely prevented. Further, if a said sealing cap is provided, then the seal and the sealing cap form a two-stage sealing system, so that leakage of lubricant from the thrust bearing is largely avoided.

According to an advantageous embodiment of the invention, the axial stop has a stop element for abutment with the free end of the shaft and a support element for supporting the stop element in the axial direction. This makes it possible to adapt the two elements concretely to their task. Thus, the stop element may consist of a particularly abrasion-resistant and low-friction first material and the support member of a different material.

According to an advantageous development of the invention, the stop element is designed as a ball and / or the support element as an adjusting element for adjusting the axial position of the rotor, for example as an adjusting screw. If the stop element is designed as a ball, the friction between the stop element and the free end of the shaft can be reduced. In addition, the ball can be freely rotatably mounted, so that an excited by the rotating shaft rotation of the ball leads to a transport of lubricant in the contact area between the free end of the shaft and the ball and between the bearing points of the ball and the ball. If the support element is designed as an adjusting element, the position of the rotor in the axial direction can be set exactly, so that the distance between the tapering section of the shaft and the permanent magnet arrangement can be minimized.

According to an advantageous embodiment of the invention, the thrust bearing is designed as an integral structural unit, which is a total of at least one attachment portion on the rotor spinning machine can be fixed. An integral structural unit is understood to mean such a structural unit in which the essential elements are interconnected. In this way, the thrust bearing can be completely pre-assembled and then easily attached to the rotor spinning machine. This results in manufacturing advantages both in the construction of new rotor spinning machines and in retrofitting existing rotor spinning machines.

Furthermore, the invention relates to a spinning device for a rotor spinning machine with a rotor comprising a spinning cup and a shaft, wherein the shaft has a spinning cup opposite free end, wherein the free end of the shaft is supported by a thrust bearing according to one of the preceding claims. This results in the advantages described above.

According to an advantageous embodiment of the invention, the shaft of the rotor at least from the support rollers to the tapered portion has a constant cross-section. In this way, the rotor can be made easily and with low weight.

Furthermore, the invention relates to a rotor spinning machine, which has at least one spinning device according to the invention.

The above-explained and / or reproduced in the subclaims advantageous embodiments and refinements of the invention can - in addition to z. B. in cases of clear dependencies or incompatible alternatives - individually or in any combination with each other.

The invention and its advantageous embodiments and further developments and advantages thereof are explained in more detail below with reference to a drawing. It shows in a schematic outline sketch:

1 An embodiment of a spinning device according to the invention with a thrust bearing and an associated rotor in a schematic side view.

In the 1 only those components of a spinning device are provided with reference numerals and explained which are necessary for the understanding of the invention. It goes without saying that the spinning device according to the invention can comprise further parts and assemblies.

In the 1 is a schematic side view of a spinning device for a rotor spinning machine according to an embodiment shown. The spinning device comprises a thrust bearing 1 for the on support rollers 2a - 2d stored shaft 3 of the rotor 4 , Here are the support disks 2a and 2c on the front side of the rotor 4 and the support disks 2 B and 2d on the rear side of the rotor 4 rotatably mounted. The rotor 4 is in a through the support rollers 2a and 2c on the one hand and through the support rollers 2 B and 2d stored on the other hand storage gap. The drive of the rotor 4 can be done by means of a fast-running, not shown drive belt on the shaft 3 of the rotor 4 abuts and the rotor 4 rotated by friction. The drive belt can be at the bearing gap radially opposite side of the shaft 3 abut, so that the shaft 3 is pressed into the bearing gap.

The thrust bearing 1 has a bearing housing 5 , one on the bearing housing 5 arranged axial stop 6 for supporting one of a spinning cup 7 of the rotor 4 opposite free end 8th of the shaft 3 in an axial direction AR and a permanent magnet arrangement 9 for generating a during operation of the rotor 4 so on the shaft 3 acting axial force that the free end 8th against the attack 6 is pressed.

According to the invention, the permanent magnet arrangement 9 at one to the spinning cup 7 facing side of the bearing housing 5 arranged. Conveniently, the permanent magnet arrangement 9 to interact with one to the free end 8th of the shaft 3 towards the rejuvenating section 10 of the shaft 3 educated. The tapered section 10 can in particular a stepped decrease of the cross section and / or, as in 1 shown to have a continuous decrease in the cross section. Such a tapered section 10 can easily between the support discs 2a - 2d and the axial stop 6 be provided because at most low axial forces act on pressure and virtually no radial forces in this area. The shaft 3 and / or in particular the tapered section 10 may comprise any magnetic and / or magnetizable material. In particular, a ferromagnetic material, such as iron, nickel and / or cobalt, may be provided here.

In this case, it is possible to place the permanent magnet arrangement at a smaller distance from the shaft of the rotor than is the case with solutions in which the permanent magnet arrangement is arranged on that side of the bearing housing on which the axial stop is also formed, since thus the axial stop the positioning of the permanent magnet assembly is not hindered. As a result, the magnetically generated axial force can be increased, so that the rotor is securely guided in the axial direction.

Because both the axial stop 6 as well as the permanent magnet arrangement 9 on the bearing housing 5 are arranged or fixed, are the axial stop 6 and the permanent magnet assembly 9 relative to each other very accurately positionable, so that the shaft 3 with respect to the permanent magnet assembly 9 in the axial direction AR can be accurately positioned. This allows the distance between the tapered section 10 of the rotor 4 and the permanent magnet assembly 9 be further reduced, so that the axial force can be further increased.

It is also possible, a larger volume of the shaft 3 in the sphere of action of the permanent magnet arrangement 9 to bring, as in the solutions of the prior art, in which the permanent magnet arrangement 9 on the side of the bearing housing 5 is arranged, on which also the axial stop 6 is attached, would be possible. In particular, this can be achieved without being on the shaft 3 an additional magnetic or magnetizable volume is formed, in which a to the free end 8th of the shaft 3 towards widening section, so a section with increasing cross-section, is provided.

Overall, the thrust bearing according to the invention causes 1 a sufficient magnetic axial force to the rotor 4 even when undesirable opposite forces occur, which, for example, by an imbalance in the rotor 4 , defective or dirty support disks 2a - 2d , a defective or dirty drive belt and / or caused by defective pressure rollers for the drive belt, safely against the axial stop 6 to press.

Advantageously, the permanent magnet arrangement comprises 9 a ring magnet 9 , Under a ring magnet 9 becomes an annular permanent magnet 9 Understood. With a ring magnet 9 can be generated in a simple manner, a magnetic field with respect to the axis of the rotor 4 and thus of the shaft 3 is rotationally symmetric. In this way, the formation of eddy currents in the shaft 3 what prevents the rotor 4 braking altogether and thus increasing the energy consumption of the rotor spinning machine.

The permanent magnet arrangement is preferred 9 in an area around a passage opening 11 of the bearing housing 5 for the shaft 3 arranged. In this way, in particular in the axial direction AR results in a compact construction of the thrust bearing 1 ,

Conveniently, the permanent magnet arrangement 9 Part of a sealing cap 12 , preferably a replaceable sealing cap 12 , the bearing housing 5 , In this way, the permanent magnet arrangement fulfills 9 two tasks, namely the sealing of the bearing housing 5 on the one hand and the generation of the axial force on the other.

Advantageously, one is radially from the shaft 3 spaced start-up stop 19 provided that prevents the shaft 3 with a radial movement of the shaft 3 against the permanent magnet arrangement 9 rebounds. Under a radial movement is thereby a radially directed movement of the shaft 3 understood from its intended operating position. The radially spaced start stop 19 can damage the permanent assembly in such, usually unwanted movement 9 prevent. As in 1 shown, the basic body can 19 the sealing cap 12 as start-up stop 19 be educated.

Preferred is in the bearing housing 5 a substantially closed lubricant chamber 13 for a lubricant for lubricating the axial stop 6 and the free end 8th educated. In this way, the bearing housing takes over 5 several functions, namely the protection of the thrust bearing 1 against external influences, such as mechanical effects and soiling, the bearing of the axial stop 6 and the permanent magnet assembly 9 and now additionally providing a lubricant for lubricating the axial stop 6 and the free end 8th , where by the latter, the friction between the axial stop 6 and the free end 8th reduced and thereby wear is reduced. The lubricant may in particular be a grease or an oil.

Advantageously, the permanent magnet arrangement 9 through one on the bearing housing 5 trained seal 14 with a second passage opening 15 for the shaft of the lubricant chamber 13 separated. In this way, contamination of the permanent magnet arrangement 9 be largely prevented by lubricant. If furthermore a said sealing cap 12 is provided, then form the seal 14 and the sealing cap 12 a two-stage sealing system, allowing leakage of lubricant from the thrust bearing 1 is largely avoided.

Preferably, the axial stop 6 a stop element 16 to concern at the free end 8th of the shaft 3 and a support element 17 for supporting the stop element 8th in the axial direction AR. This makes it possible to use the two elements 16 . 17 to be adapted to their task. Thus, the stop element 16 made of a particularly abrasion-resistant and low-friction first material and the support element 17 made of a different material.

Conveniently, the stop element 16 as a ball 16 and / or the support element 17 as an adjustment 17 for adjusting the axial position of the rotor 4 , for example as an adjusting screw 17 , educated. If the stop element 16 as a ball 16 is formed, the friction between the stopper element 16 and the free end 8th of the shaft 3 be reduced. If the support element 17 as an adjustment 17 is formed, the position of the rotor 4 be adjusted exactly in the axial direction, so that the distance between the tapered section 10 of the shaft 3 to the permanent magnet arrangement 9 can be minimized.

Preferably, the thrust bearing 1 as an integral unit 1 executed, which total of at least one attachment portion 18a - 18b can be fixed to the rotor spinning machine. Under an integral unit 1 In this case, such a unit is understood, in which the essential elements are interconnected. In this way, the thrust bearing 1 completely pre-assembled and then attached in a simple manner to the rotor spinning machine or the spinning station. This results in manufacturing advantages both in the construction of new rotor spinning machines and in retrofitting existing rotor spinning machines.

The sealing cap 12 For example, it can be made from a fine-grained, permanent-magnetic material, which is mixed with a binder and then brought into permanent form. It is also possible that the sealing cap 12 a particular non-magnetic body 19 , For example, made of plastic, in which or the actual permanent magnets 9 cast in, snapped, glued, pressed or the like. Unless the sealing cap 12 interchangeable, that is non-destructively replaceable, can defective permanent magnets 9 simply be exchanged.

To the axial position of the rotor 4 to be able to adjust, in the exemplary embodiment, the adjustment as an adjustment 17 educated. The adjusting screw 17 has a head 20 by moving it further into the bearing housing 5 into or out of this can be turned out. When the exact position is reached, the adjusting screw can 17 by means of the locknut 21 be fixed.

The ball 16 can be freely rotatably mounted, so that one through the rotating shaft 3 excited rotation of the ball 16 to transport lubricant into the contact area between the free end 8th of the shaft 3 and the ball 16 as well as between the bearings 17 . 22a - 22b the ball 16 and the ball 16 leads. In the exemplary embodiment, the ball is axially through the support element 17 and radially through webs 22a - 22b stored, which in the lubricant chamber 13 on the bearing housing 5 are formed.

Appropriately, the shaft has 3 of the rotor 4 at least from the support rollers 2a - 2d up to the tapered section 10 a constant cross section. In this way, the rotor can 4 be made easily and with low weight.

LIST OF REFERENCE NUMBERS

1

thrust

2

supporting role

3

shaft

4

rotor

5

bearing housing

6

axial stop

7

spinning cup

8th

free end

9

Permanent magnet arrangement, ring magnet

10

tapering section of the shaft

11

Through opening

12

sealing cap

13

lubricant chamber

14

poetry

15

second passage opening

16

Stop element, ball

17

Support element, adjusting element, adjusting screw

18

attachment section

19

Base of the sealing cap, starting stop

20

Head of adjusting screw

21

locknut

22

web

AR

axial direction

Claims (14)

Thrust bearing for one on support rollers ( 2a - 2d ) mounted shaft ( 3 ) of a rotor ( 4 ) of a rotor spinning machine, with a bearing housing ( 5 ), with one on the bearing housing ( 5 ) arranged axial stop ( 6 ) for supporting a spinning cup ( 7 ) of the rotor ( 4 ) opposite free end ( 8th ) of the shaft ( 3 ) in an axial direction (AR) and with a permanent magnet arrangement ( 9 ) for generating a during operation of the rotor ( 4 ) so on the shaft ( 3 ) acting axial force that the free end ( 8th ) against the axial stop ( 6 ), characterized in that the permanent magnet arrangement ( 9 ) on one to the spinning cup ( 7 ) facing side of the bearing housing ( 5 ) is arranged. Thrust bearing according to the preceding claim, characterized in that the permanent magnet arrangement ( 9 ) to interact with one to the free end ( 8th ) of the shaft ( 3 ) tapering section ( 10 ) of the shaft ( 3 ) is trained. Thrust bearing according to one of the preceding claims, characterized in that the permanent magnet arrangement ( 9 ) a ring magnet ( 9 ). Thrust bearing according to one of the preceding claims, characterized in that the permanent magnet arrangement ( 9 ) in an area around a passage opening ( 11 ) of the bearing housing ( 5 ) for the shaft ( 3 ) is arranged. Thrust bearing according to one of the preceding claims, characterized in that the permanent magnet arrangement ( 9 ) Component of a sealing cap ( 12 ), preferably a replaceable sealing cap ( 12 ), of the bearing housing ( 5 ). Thrust bearing according to one of the preceding claims, characterized in that a radially from the shaft ( 3 ) spaced start stop ( 19 ) is provided, which prevents the shaft ( 3 ) during a radial movement of the shaft ( 3 ) against the permanent magnet arrangement ( 9 ) bounces. Thrust bearing according to one of the preceding claims, characterized in that in the bearing housing ( 5 ) a substantially closed lubricant chamber ( 13 ) for a lubricant for lubricating the axial stop ( 6 ) and the free end ( 8th ) is trained. Thrust bearing according to the preceding claim, characterized in that the permanent magnet arrangement ( 9 ) by a on the bearing housing ( 5 ) formed seal ( 14 ) with a second passage opening ( 15 ) for the shaft ( 3 ) from the lubricant chamber ( 13 ) is disconnected. Thrust bearing according to one of the preceding claims, characterized in that the axial stop ( 6 ) a stop element ( 16 ) to concern at the free end ( 8th ) of the shaft ( 3 ) and a support element ( 17 ) for supporting the stop element ( 16 ) in the axial direction (AR). Thrust bearing according to the preceding claim, characterized in that the stop element ( 16 ) as a ball ( 16 ) and / or the support element ( 17 ) as adjusting element ( 17 ) for adjusting the axial position of the rotor ( 4 ), for example as an adjusting screw ( 17 ), is trained. Thrust bearing according to one of the preceding claims, characterized in that it is designed as an integral structural unit, which comprises a total of at least one attachment portion ( 18a . 18b ) is fixable to the rotor spinning machine. Spinning device for a rotor spinning machine with a rotor ( 4 ), which has a spinning cup ( 7 ) and a shaft ( 3 ), wherein the shaft ( 3 ) one of the spinning cup ( 7 ) opposite free end ( 8th ), characterized in that the free end ( 8th ) of the shaft ( 3 ) by a thrust bearing ( 1 ) is supported according to one of the preceding claims. Spinning device according to the preceding claim, characterized in that the shaft ( 3 ) of the rotor ( 4 ) at least from the support rollers ( 2a - 2d ) to the tapered section (FIG. 10 ) has a constant cross-section. Rotor spinning machine, characterized in that it comprises at least one spinning device according to one of claims 12 to 13.

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