DE102009048295A1 - Open-end spinning rotor for use in textile industry, has spring element that is stretched during insertion of stub into borehole such that element transfers torque from shaft to cup, where element is detachably connected with cup and shaft - Google Patents

Abstract

The rotor (1) has a rotor shaft (3) and a rotor cup (2) detachably connected with one another. A shaft stub (5) is firmly connected with the cup and inserted into a borehole (4) in the shaft. The stub and the borehole have a circumferential groove (6) in which a spring element (8) is arranged such that the element projects over the groove. The element is stretched during insertion of stub into the borehole such that the element transfers torque from the shaft to the cup. The element is detachably connected with the cup and the shaft. The element is made of spring steel.

Description

The The invention relates to an open-end spinning rotor having a rotor cup and a rotor shaft over which the rotor cup drivable is, wherein the rotor cup and the rotor shaft detachably connected to each other are and the rotor shaft has a bore, a stub shaft rotatably connected to the rotor cup and the stub shaft in the Bore is insertable.

The Most of the open-end rotor spinning machines currently used in the textile industry have spinning rotors, with their rotor shaft in the Lagerzwickeln a so-called support disk storage are stored and driven by a machine-tangential belt become.

These Spinning rotors in which the rotor shaft and the rotor cup usually over a press fit are almost inextricably linked, If necessary, for example, during wear, from in front through the opened rotor housing get extended.

Furthermore, for example by the EP 0 972 868 A2 , single motor driven spinning rotors are known, which are supported with their rotor shaft in a magnetic bearing assembly.

The Magnetic bearing assembly consists of a front and a rear bearing, these bearings in turn each about have axially facing permanent magnet rings. One of these permanent magnet rings is in each case fixed on the stator, while the other permanent magnet ring with the rotor shaft circulates. In addition, mechanical safety bearings are provided, the support the rotor shaft in the event of failure of the magnetic bearing. Damage to the spinning rotor and its drive can be avoided as far as possible.

There the installation or removal of such stored spinning rotors not one insignificant assembly effort is required in these spinning rotors the rotor cup each releasably connected to the rotor shaft. The means, the rotor cup can, if necessary, for example removed from wear or during a batch change or be replaced, without causing the rotor shaft must be expanded with.

The DE 100 24 020 A1 discloses a coupling device via which the rotor cup and the rotor shaft are detachably connected to each other. The coupling device consists of a magnetic device for axial locking of the rotor cup on the rotor shaft and a mechanical rotation. This rotation is preferably made of a firmly connected to the rotor shaft receiving sleeve in which a polygonal socket is arranged and an outer polygon on the rotor cup, which corresponds in the installed state with the polygon. This positive rotation has proven itself in practice. However, their production is quite expensive. In addition, the installation of the rotor cup is possible only in a certain angular position.

Another coupling device in connection with a support disk bearing is in the EP 0 808 923 A1 described. This known coupling device is constructed in the manner of a clip connection, wherein a part of the clip connection are arranged on the rotor cup and the other part on the rotor shaft. At least part of the clip connection is acted upon by an elastic element. The elastic element should consist of a plastic and be connected to a part of the clip connection and depending on the version either with the rotor shaft or the rotor cup by means of gluing solvable. Such adhesive bonds become unreliable after repeated mounting and dismounting of the rotor cup. Plastics lose their elasticity over time. However, an efficient replacement is not possible due to the adhesive bonds.

It is the object of the present invention, the releasable Improve connection between rotor shaft and rotor cup.

The The object is achieved by the characterizing Characteristics of claim 1 solved. Advantageous developments The invention are the subject of the dependent claims.

to Solution of the task has the stub shaft or the hole a circumferential groove in which a spring element is arranged so that it protrudes beyond the circumferential groove and that the spring element during Introduce the stub shaft in the hole so tense is that it transmits a torque from the rotor shaft to the rotor cup, wherein the spring element with the rotor cup and the rotor shaft detachable connected is.

The spring element is thus not connected by an adhesive bond with the rotor cup or with the rotor shaft, but by locking in a circumferential groove. So that not only the connection of rotor cup and rotor shaft is solvable, but also the spring element is easily replaceable. It can be easily replaced with wear. The spring force is completely sufficient for transmitting the force in the radial direction. For this purpose, no positive connection is required. The rotor cup or its stump can in each Angular position are introduced into the bore of the rotor shaft. The required circumferential groove is easy to manufacture. The spring element also causes a torque limiter. If the allowable torque is exceeded in a system error, the spring element slips through easily, and greater damage can be prevented. The spring element here forms the weakest link and is thus damaged first. However, as already described above, the spring element is easily replaceable.

to axial locking can be used the known magnetic device become. However, it is particularly advantageous that the other one Element additionally has a circumferential groove and the circumferential grooves of the stub shaft and the bore a circumferential groove arranged so are that they in cooperation with the spring element an axial Enable locking of the rotor cup against the rotor shaft. This construction is particularly simple. The additional Circumferential groove means no significant additional effort. The space requirement is lower, since the magnet arrangement is omitted and for the Groove no additional space is required.

According to one preferred embodiment of the invention is the spring element designed as a cage-like rotationally symmetrical structure and has at the ends in each case a sleeve, and the sleeves are in the direction of the axis of rotation extending in radial Direction arched walkways connected with each other. Depending on, in which circumferential groove the spring element is axially fixed are the webs curved inwards or outwards.

advantageously, have the sleeves in the direction of the axis of rotation one Slot up. So the spring element can easily over the stub shaft be pushed into the groove, or the spring element can be easily inserted into the hole.

advantageously, the spring element consists of a metallic material, preferably a spring steel. This material guarantees a long life.

In Connection with a known magnetic bearing of the rotor shaft It is particularly advantageous that the stub shaft in conjunction arranged with one between the rotor cup and the rotor shaft stationary sleeve forms a radial fishing camp. By design The rotor shaft has a larger diameter as the stub shaft, since the rotor shaft absorb the stub shaft got to. Due to the concomitant smaller circumference of the stub shaft opposite the rotor shaft, occurs on contact in the fishing camp on a significantly lower sliding friction, since the peripheral speed correspondingly lower at the same speed. The wear in the Fishing camp can thus be lowered and the life can be increased become.

In Connection with the described fishing camp, it is particularly special advantageous to arrange a stop in the bore, the Inserting the stub shaft the movement of the stub shaft limited in the axial direction. By such a stop will prevents the stub shaft over an axial Arretierungspunkt the spring element moved out. If not a fishing camp is provided between the rotor cup and the rotor shaft can the limitation of movement when inserting the stub shaft for the sake of simplicity, by striking the rotor cup against take the rotor shaft.

The Invention will be illustrated below with reference to the drawings Embodiments explained in more detail.

It demonstrate:

1 a spinning rotor having a circumferential groove on the stub shaft of the rotor cup;

2 a spinning rotor having a circumferential groove on the bore of the rotor shaft;

3 a spinning rotor each having a circumferential groove on the stub shaft of the rotor cup and on the bore of the rotor shaft;

4 a spinning rotor with a direct bearing of the stub shaft;

5 a cage-like spring element.

The invention is preferably used in conjunction with a single motor driven and magnetically mounted spinning rotor. Such a spinning rotor is known in the art and, for example, in the above cited EP 0 972 868 A2 described in detail, so that is omitted at this point on a new presentation of the drive and storage.

The 1 shows an inventive design of a spinning rotor 1 , It's the rotor cup here 2 with her stump 5 and the rotor shaft 3 with the hole 4 shown. The stub shaft 5 is in the hole 4 introduced. The rotor cup 2 So is in its installed state and the spinning rotor 1 is ready for use. According to the stub shaft has a circumferential groove 6 on, in which a spring element 8th is arranged. By inserting into the groove 6 is the spring element 8th safely with the stub shaft 5 and the rotor cup 3 connected and stays still solvable. When inserting the stub shaft 5 into the hole 4 a spring bias is imposed on the spring element. So can a torque from the driven rotor shaft 3 on the rotor cup 2 be transmitted. The axial locking takes place here in a known manner by the magnet 15 ,

The 2 shows another embodiment of the present invention. In contrast to 1 has the hole here 4 a circumferential groove 7 on. The stub shaft of the rotor cup 2 on the other hand has no groove. Analog here is a spring element 8a in the circumferential groove 7 brought in. The spring element 8a is there, in contrast to the spring element 8th , which is curved outward, curved inward, so that a radial force on the stub shaft 5 the rotor cup 2 is exercised and can transmit torque. Except for the differences described, the spinning rotors are the 1 and 2 identically constructed.

In the in the 3 represented spinning rotor 1 has both the stub shaft 5 the rotor cup 2 a circumferential groove 6 on, as well as the hole 4 of the rotor shaft 3 a circumferential groove 7a , This spinning rotor builds on the spinning rotor according to the 1 on, leaving the stub shaft 5 the rotor cup 2 matches. In particular, the circumferential groove 6 and the spring element 8th identical. When removing the rotor cup 2 from the rotor shaft 3 So remains the spring element 8th with the stub shaft 5 connected. In addition to the stub shaft here also has the bore 4 a circumferential groove 7a on. This circumferential groove 7a is designed so that an axial locking of the rotor cup 2 is possible.

At the same time, the axial holding force remains surmountable, so that the rotor cup 2 can be exchanged. To when inserting the stub shaft 5 pushing out beyond the locking point of the spring element 8th To prevent the dimensions are chosen so that the rotor cup strikes against the rotor shaft upon reaching the locking point.

The 4 shows a further embodiment of the invention. The coupling device between the rotor cup 2 and the rotor shaft 3 that is, the spring element 8th and the circumferential grooves 6 and 7a are with the spinning rotor according to the 3 essentially identical. As described above, the invention is preferably used together with a magnetic bearing, wherein a magnetic bearing usually additionally has mechanical safety bearings. According to the in the 4 illustrated embodiment of the invention, the fishing camp from the stub shaft 5 and one between the rotor shaft 3 and the rotor cup 2 arranged socket 9 educated. In the hole 4 is a stop 15 arranged when inserting the stub shaft 5 limits the movement in the axial direction and a pushing over the axial locking point of the spring element 8th prevented. It will be without extension of the spinning rotor 1 an immersion depth of the stub shaft which is sufficient for the stability 5 into the hole 4 reached. The space required for the fishing camp is generated by the elimination of the axial holding magnet.

The 5 shows a possible embodiment of the spring element 8th , It is a with respect to a rotation axis 12 symmetrical cage-like structure, which consists of a spring steel. At the ends, the spring element in each case has a sleeve 11 with a slot 14 on. The pods 11 are through in the direction of the axis of rotation 12 running bridges 13 connected with each other. The bridges 13 are arched outwards. This is this spring element 8th in the embodiments according to the 1 . 3 and 4 used. For use according to the 2 would have the webs 13 to be curved inwards.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0972868 A2 [0004, 0026]
• - DE 10024020 A1 [0007]
• EP 0808923 A1 [0008]

Claims (8)

Open-end spinning rotor ( 1 ) with a rotor cup ( 2 ) and a rotor shaft ( 3 ) over which the rotor cup ( 2 ) is drivable, wherein the rotor cup ( 2 ) and the rotor shaft ( 3 ) are detachably connected to each other and to the rotor shaft ( 3 ) a hole ( 4 ), a stub shaft ( 5 ) rotatably with the rotor cup ( 2 ) and the stub shaft ( 5 ) into the hole ( 4 ) is insertable, characterized in that the stub shaft ( 5 ) or the bore ( 4 ) a circumferential groove ( 6 . 7 ), in which a spring element ( 8th . 8a ) is arranged so that it over the circumferential groove ( 6 . 7 protrudes) and that the spring element ( 8th . 8a ) during insertion of the stub shaft ( 5 ) into the hole ( 4 ) is tensioned so that there is a torque from the rotor shaft ( 3 ) on the rotor cup ( 2 ), wherein the spring element ( 8th . 8a ) with the rotor cup ( 2 ) and the rotor shaft ( 3 ) is releasably connected. Open-end spinning rotor ( 1 ) according to claim 1, characterized in that the respective other element ( 4 . 5 ) additionally a circumferential groove ( 6 . 7a ) and the circumferential grooves ( 6 . 7a ) of the stub shaft ( 5 ) and the bore ( 4 ) are arranged so that they in cooperation with the spring element ( 8th ) an axial locking of the rotor cup ( 2 ) against the rotor shaft ( 3 ) enable. Open-end spinning rotor ( 1 ) according to one of the preceding claims, characterized in that the spring element ( 8th ) is formed as a cage-like rotationally symmetrical structure and at the ends in each case a sleeve ( 11 ) and that the sleeves by in the direction of the axis of rotation ( 12 ) extending in the radial direction arched webs ( 13 ) are connected to each other. Open-end spinning rotor ( 1 ) according to claim 3, characterized in that the sleeves in the direction of the axis of rotation ( 12 ) a slot ( 14 ) exhibit. Open-end spinning rotor ( 1 ) according to one of the preceding claims, characterized in that the spring element ( 8th . 8a ) consists of a metallic material. Open-end spinning rotor ( 1 ) according to claim 5, characterized in that the spring element ( 8th . 8a ) consists of a spring steel. Open-end spinning rotor ( 1 ) according to one of the preceding claims, characterized in that the rotor shaft ( 3 ) is magnetically supported and the stub shaft ( 5 ) in conjunction with one between the rotor cup ( 2 ) and the rotor shaft ( 3 ) arranged stationary socket ( 9 ) a radial fishing camp ( 10 ). Open-end spinning rotor ( 1 ) according to claim 7, characterized in that in the bore ( 4 ) an attack ( 16 ), which during insertion of the stub shaft ( 5 ) the movement of the stub shaft ( 5 ) is limited in the axial direction.