EP0805224A3 - Open-end spinning rotor - Google Patents

Abstract

For the improvement of open-end spinning rotors, the spinning rotor being connected to its shaft via a coupling, it is provided that the coupling (2) is a separate component. The coupling has a first receptacle (21) for the rotor pot (11) and a second receptacle (22) for the carrier part (12). It is also provided that the coupling has a locking body (25) which is spherical and which, as a result of the centrifugal force, locks the rotor pot (11) with its carrier part (12) when the spinning rotor is in operation.

Description

The present application relates to an open-end spinning rotor according to Preamble of claim 1. DE-A 38 15 182 discloses a spinning rotor known, in which the rotor pot with the rotor shaft via a Coupling assembly is connected. The clutch arrangement is either formed on the rotor pot or on the rotor shaft. In one embodiment, at which the clutch assembly is attached to the rotor shaft, this consists of two elastic hook, which when joining the rotor pot and rotor shaft into one Engage the undercut on the rotor pot. This undercut is in the form of a inclined surface formed. When the spinning rotor is in operation, the hooks press as a result the centrifugal force on these inclined surfaces, whereby the pot of the spinning rotor in Direction on the rotor shaft is pulled, so that the connection between Rotor pot and rotor shaft is intensive and safe even when the spinning rotor is in operation. In another embodiment, the clutch arrangement is on the rotor plate appropriate. The disadvantage of the known spinning rotors is that the Coupling arrangement either on the rotor pot or on the rotor shaft is arranged, which on the one hand significantly increases the cost of these components and on the other hand, the production of the coupling on the corresponding component is complex and costly.

From DE-A 43 42 539 an open-end spinning rotor is known in which the rotor pot is attached to its supporting and driving body in that a kind of screw connection is provided. In this version there is in addition, the risk that the rotor pot during acceleration or Delay processes solves.

The object of the present application is to address the disadvantages of the prior art to avoid and an open-end spinning device with a spinning rotor to propose that is simpler in construction and cheaper to manufacture. The The present problem is solved by the features of claim 1.

The inventive design of an open-end spinning rotor achieves that both the support part and the rotor pot are designed simply can, so that they can be manufactured inexpensively, what in particular therefore it is necessary, as both the rotor pot and, in part, the support part Wear or replacement parts are. The clutch itself is practically subject to no wear and tear and can be used over and over again, you can about it also manufactured inexpensively and in particular in a simple manner because it is not formed in one piece with a rotor pot or support part. In addition, there are significantly more due to the separate design of the coupling Possibilities in their design. The training is particularly advantageous Coupling, if this is designed with locking bodies, which as a result of Centrifugal force during operation of the spinning rotor, become effective. This achieves that a secure locking between the coupling and the spinning rotor is achieved also, and this is safe and reliable in particular when the spinning rotor is in operation. At the same time this causes a separation of rotor pot and support part in the Standstill is made easier because the locking body is missing Centrifugal force can be unlocked much more easily. It is particularly cheap if the locking body is spherical or, even more advantageously, directly as a ball, are designed, since then particularly inexpensive mass parts as Locking body can be used, so that the coupling is inexpensive can be produced. In addition, spherical locking bodies have the advantage that they offer favorable geometric conditions for the interaction with the them cooperating surfaces on the carrier part or rotor pot. It is beneficial in addition, at least one receptacle of the coupling in the form of a Screw head, which cooperates positively with the rotor pot, to train. This ensures that the rotor pot is securely fixed to the coupling reached. It is particularly favorable if the rotor pot has a central bore for this purpose possesses through which the coupling is passed so that they can with their screw head-shaped part pulls the rotor base against the carrier part. Especially It is advantageous if the locking body has inclined surfaces work together if they are so inclined that pressing the The locking body generates an axial force component as a result of the centrifugal force, whereby the rotor pot and the carrier part are pressed against each other. Still advantageous it is when both the first recording of the clutch, which grips the rotor pot, with Locking bodies is formed, as well as the second receptacle, which the Support part captured. It is then particularly favorable for both opposing surfaces, both the on the rotor pot as well as on the carrier part, than against the axis of rotation of the rotor pot to form inclined surface in such a way that a force component caused by the locking body on these surfaces that rotor pot and Support part are pressed against each other. This makes a particularly high Speeds secure connection between the two parts achieved. In cheaper Design of the clutch, this has a handle or an approach for a Tool, e.g. B. a coupling point for coupling a trigger device, so that the clutch can be easily removed to put the spinning rotor in its To dismantle components or to separate the coupling from the rotor pot. Thereby can be advantageous to dismantle the clutch and thus also the rotor pot can be achieved with no load on the carrier part. One example The puller used may change when removing the coupling on Support the rotor pot. This is particularly advantageous for open-end spinning devices, in which the support part from the storage of the spinning rotor is not readily available can be taken, e.g. B. in storage where the shaft of the spinning rotor is mounted by means of ball bearings. In a particularly advantageous development of the Invention connects the clutch rotor pot and support part with each other in such a way that at the same time a form fit between the coupling to the rotor pot and the carrier part is created. This advantageously ensures that no relative movement in The circumferential direction takes place between the carrier part and the rotor pot. This is especially when accelerating the spinning rotor and when braking it to Standstill is important. The positive connection is made via the coupling, for which purpose this both with the rotor pot and with the carrier part in the circumferential direction of the Spinning rotor is positively connected. In another embodiment of the Spinning rotor this is designed to achieve the same purpose that the The rotor pot is designed in relation to the carrier part in the circumferential direction so that both cannot twist with respect to each other.

In the following the invention is based on drawings described.

Figur 1

einen erfindungsgemäß ausgestalteten Offenend-Spinnrotor auf einem schaftlos gelagerten Trägerteil.

Figur 2

einen Offenend-Spinnrotor mit einem Trägerteil, das einen Schaft zur Lagerung des Spinnrotors in einem Lager zeigt.

Figur 3

einen Offenend-Spinnrotor mit Zentrierflächen zwischen Rotortopf und Trägerteil.

Figur 4

eine Darstellung einer Kupplung mit kugelförmigen Verriegelungselementen.

Show it

Figure 1

an open-end spinning rotor designed according to the invention on a support part mounted without a shaft.

Figure 2

an open-end spinning rotor with a carrier part which shows a shaft for mounting the spinning rotor in a bearing.

Figure 3

an open-end spinning rotor with centering surfaces between the rotor pot and the carrier part.

Figure 4

a representation of a coupling with spherical locking elements.

FIG. 1 shows an open-end spinning rotor 1 designed according to the invention, consisting of a rotor pot 11, a carrier part 12 and a coupling 2. The rotor pot 11 and the carrier part 12 are connected to one another via the coupling 2. The Clutch 2 is for this purpose through a bore 111 of the rotor pot 11 into the Support part 12 passed through. With their first recording 21, which is similar to a Screw head is formed, the coupling is supported on the bottom 110 of the Rotor pot 11. The second receptacle 22 of the coupling 2 engages the carrier part 12 via two locking bodies 25, which are designed as balls. At a standstill of the spinning rotor, the locking body 25 via the elastic element 26, viewed in relation to the axis of rotation of the spinning rotor, pressed outwards, whereby they are pressed against the inclined surface 3 of the support part 12. The inclined Surface 3 is the lateral surface of a conically widened bore 121 of the Support part 12. The elastic element 26 is in the form of a rubber block formed, which is arranged between the locking bodies 25. in the In the assembled state shown in FIG. 1, the elastic element 26 is below Pressure and presses the locking body 25 outwards on the inclined surface 3, whereby the clutch 2 via the first receptacle 21 the rotor pot 11 in the direction pulls onto the carrier part 12. For dismantling the rotor pot 11 from the carrier part 12 the coupling is pulled off the carrier part 12 together with the rotor pot 11. The locking body 25 is against the elastic element 26 after pressed inside and the coupling out of the bore 121 of the carrier part 12 pulled out. In order to separate the clutch from the rotor pot, it then needs only to be pushed through the bore 111 in the rotor pot 11. At Operation of the spinning rotor 1 is set in rotation, whereby the Locking body 25 due to the centrifugal force radially outward, against the inclined surface 3 are pressed and a secure lock between Effect rotor pot and carrier part. For centering the rotor pot on the carrier part the rotor pot 11 has a centering surface 13 that forms the wall of the bore 110 corresponds to. The carrier part 12 also has a centering surface 14 that of the wall the bore 121 in its cylindrical part corresponds. They work for this Centering surfaces 13 and 14 together with the centering surface 27 of the coupling 2. The Centering surface 27 of clutch 2 corresponds to its cylindrical outer surface. The support part 12 of the spinning rotor 1 of Figure 1 is made of several parts composed. In particular, the part of the rotor pot 11 facing away from Support part 12 is used to store the spinning rotor 1 in a known manner and to drive.

FIG. 2 shows a spinning rotor 1 which is mounted by means of a shaft 10. The Storage can be done in a known manner by supporting disks that are used for Example are arranged in two pairs or by direct storage of the Shank 10 via roller bearings or air bearings. The storage of the spinning rotor is in Not important to the present invention. The shaft 10 of the spinning rotor 1 of Figure 2 merges into the support part 12, the design of which like that of the Support part of Figure 1 is. The receptacle 21 of the coupling 2 has two holes 210, in which two mandrels of an extraction device, not shown, engage can to pull the coupling 2 out of the carrier part 12. The holes 210 form a coupling point for the trigger device, which is when pulling out the Coupling is supported against the bottom of the rotor pot 11, so that the removal of the Coupling without a load on the storage of the spinning rotor, such as. B. also train or Compressive forces, is possible.

FIG. 3 shows a shaftless spinning rotor similar to that of FIG. 1. The clutch 2 has a second receptacle 22, which like that of Figure 1 with Locking bodies 25 is designed and over an inclined surface 3 of the Support part 12 cooperates with this. The first recording 21 is similar formed a screw head of a countersunk head screw. This has the advantage that the bottom 110 of the rotor pot 11 forms a flat surface which is below Certain circumstances can be advantageous for the spinning operation of the spinning rotor 1. The elastic element 26 consist here, unlike that of Figure 1, from a spring-loaded ball 260, which is pushed by the loading spring 261 towards the Locking body 25 is pressed so that it can also be used when the Put the spinning rotor on the inclined surface 3 and for a locking of Take care of the spinning rotor and rotor pot. The centering of the rotor pot on the carrier part at Figure 3 takes place over part of a conical surface 270 of the support part with which a corresponding centering surface 271 of the rotor pot 11 cooperates.

The coupling 2 of FIG. 3 is shown enlarged in FIG. The Locking elements 25 are guided in transverse bores 250 and protrude this from the clutch 2 by the pressure of the elastic element 26 radially out. The lower edge 251 of the transverse bores is so in his Reduced diameter that the locking body 25 is not completely out of the Clutch 2 can emerge radially. This prevents the Locking elements can fall out of the coupling. The elastic Element 26 is seated in an axial bore 260 which, at its open end, has a Closure body 261 is closed, so that neither the elastic element 26 the locking body 25 can still fall out of the coupling 2. The Locking body 25 are in the representations of Figure 1 to Figure 4 as Balls formed, but can also act as cylinders or similar geometric bodies are formed. At the same time as an anti-twist device To act between the rotor pot 11 and the support part 12, the clutch 2 can also be used as a be designed with a non-rotationally symmetrical part, e.g. with a square Cross-section. The openings in the rotor pot and support part are then trained accordingly. The same effect can also be achieved by that the contact surfaces between rotor pot 11 and support part 12 are designed so that a rotary movement relative to one another is not possible. It can do just as well Carrier part one or more pins inserted in the axial direction (not shown) that engage axially in the rotor pot to prevent twisting.

Claims (13)

Open-end spinning rotor consisting of a rotor pot and a support part which receives it and via which the rotor pot is mounted and driven, the rotor pot and support part being connected to one another via a coupling, characterized in that the coupling (2) is a separate component, the first Has receptacle (21) for the rotor pot (11) and has a second receptacle (22) for the carrier part (12). Open-end spinning rotor according to Claim 1, characterized in that the first (21) and / or the second receptacle (22) has at least one locking body (25) which, as a result of the centrifugal force when the spinning rotor (1) is in operation, the rotor pot (11) and / or the carrier part (12) is locked with the coupling (2). Open-end spinning rotor according to Claim 2, characterized in that the locking body (25) is spherical. Open-end spinning rotor according to claim 2 or 3, characterized in that an elastic element (26) is assigned to the locking body (25), which keeps the locking body (25) in contact with the rotor pot (11) or the rotor even when the spinning rotor (1) is at a standstill Carrying part (12) brings. Open-end spinning rotor according to one or more of Claims 2 to 4, characterized in that the locking body (25) cooperates with a surface (3) of the rotor pot (11) or carrier part (12) inclined to the axis of rotation of the rotor pot (11), the Surface is inclined in such a way that the locking body (25), rotor pot (11) and support part (12) press towards each other. Open-end spinning rotor according to one or more of Claims 1 to 5, characterized in that the first receptacle (21) is designed in the form of a screw head, acting positively. Open-end spinning rotor according to Claim 6, characterized in that the first receptacle (21) is designed in the form of a countersunk screw. Open-end spinning rotor according to one or more of Claims 1 to 7, characterized in that the coupling (2) extends through an opening (111) in the rotor pot (11) into the carrier part (12). Open-end spinning rotor according to one or more of Claims 1 to 8, characterized in that the rotor pot (11) and / or the carrier part (12) have a centering surface (27, 270, 271) for the central assignment of the rotor pot (11) to the carrier part (12 ) own. Open-end spinning rotor according to Claim 19, characterized in that the coupling (2) has centering surfaces for the central allocation of the rotor pot to the carrier part. Open-end spinning rotor according to one or more of Claims 1 to 10, characterized in that the coupling (2) has a coupling point (210) for a take-off device. Open-end spinning rotor according to one or more of Claims 1 to 11, characterized in that the coupling (2) connects the rotor pot (11) and the carrier part (12) to one another in a form-fitting manner in the circumferential direction. Open-end spinning rotor according to one or more of claims 1 to 11, characterized in that the contact surface (270) of the carrier part (12) with the counter surface (271) of the rotor pot (11) result in a form-fitting connection in the circumferential direction.