CH715344A1 - Sleeve holder for a coil frame of a winding device. - Google Patents

Abstract

The invention relates to a sleeve holder (7) for a coil frame of a winding device, with a conical sleeve holder element (23), with a holding element (24) and with a spring element (25). The sleeve receiving element (23) is connected in a rotationally fixed manner to the holding element (24) via the spring element (25) and the spring element (25) is designed as a spring ring.

Description

The present invention relates to a sleeve holder for a coil frame of a winding device, and a coil frame with such a sleeve holder.

Such tube receptacles are used to hold bobbin tubes in winding devices of textile machines of various types, for example end spinning machines or winding machines. Spooling sleeves are held between two tube receptacles, which are set in rotation by a drive and thereby wind a thread or a yarn. Various types of winding tubes in cylindrical or conical form made of different materials, for example plastic or paper, are used. The bobbin tubes can be designed with or without side flanges. The thread is moved back and forth with a traverse along a longitudinal axis of the bobbin during winding, whereby different types of windings are formed in structure and shape. The bobbin tube is driven directly by a motor which rotates at least one of the bobbin receptacles or indirectly via a friction roller arranged parallel to the bobbin tube. The friction roller can be designed as a so-called grooved drum. The groove drum is provided with a thread guide which is guided in slots by the rotation of the groove drum in such a way that the thread is moved back and forth. When the bobbin tube is driven directly, the traversing of the thread is to be provided by a separate laying unit and the bobbin tube is supported by a support roller. The thread is clamped between the support roller and the bobbin tube or the thread already on the bobbin tube and thereby deposited on the bobbin tube.

The coil sleeve is clamped between two opposite sleeve receptacles. The sleeve receptacles are each rotatably attached to a holding arm, which are attached to a common swivel arm. As a result of a winding process, the diameter of the thread wound on the bobbin tube increases continuously. As a result, the distance between the support roller and the longitudinal axis of the coil sleeve increases, which is compensated for by a movement of the holding arms about a pivot axis of the pivot arm. After the winding process has ended, the tube receptacles are moved apart in the direction of the longitudinal axis of the bobbin tube, so that the bobbin can be removed and an empty bobbin tube can be inserted. A movement of one or both spool sleeves is possible, the movement being linear or in the form of a pivoting movement. Manual or motorized versions for the movement of the sleeve receptacles as well as the holding arms are known from the prior art.

The requirements for a concentricity of the bobbin tubes and thus for a uniform system of the bobbin tubes on the support or friction roller have steadily increased for achieving good bobbin quality through increased productivity and diversity of the threads and yarns to be processed. The concentricity of the bobbin tubes is influenced on the one hand by the tolerances in the structural design of the winding device and on the other hand by the geometric shape of the bobbin tube itself. Coil tubes are used several times, which means that they also show signs of wear in addition to the tolerances in the manufacture, which leads to a Reinforcement of unbalance can result in rigid clamping of the coil tube between the tube receptacles. Sleeve receptacles are known in which an attempt has been made to achieve flexible clamping of the coil sleeve through a selection of materials or a combination of different types of materials. Furthermore, as disclosed, for example, in WO 2008/128 590 A1, sleeve receptacles with a ball joint were proposed.

A disadvantage of the known designs of the sleeve receptacles is that a perfect concentricity of the coil sleeve due to a flexible sleeve receptacle is only achieved by contacting the backup roller under a high force. In the case of an articulated version of the tube holder, a direct drive of the coil tube via the tube holder is not possible.

The object of the present invention is therefore to propose a sleeve receptacle, which results in centering the coil sleeve by clamping the coil sleeve between the sleeve receptacles with a compensation of the tolerances and inaccuracies of the coil sleeve, whereby by creating a rotationally fixed connection of the coil sleeve with the Sleeve receptacle allows transmission of a torque due to the clamping.

The object is achieved by the devices with the features of the independent claim.

It is proposed a sleeve holder for a coil frame of a winding device, with a conical sleeve receiving element, with a holding element and with a spring element. The sleeve receiving element is non-rotatably connected to the holding element via the spring element and the spring element is designed as a spring ring. The rotationally fixed connection of the sleeve receiving element to the holding element makes it possible to transmit a torque from the holding element via the spring element to the sleeve receiving element. This enables a direct drive of the coil sleeve held on the sleeve receiving elements. An indirect drive with a distribution roller, which transmits the driving force via a friction between the distribution roller and the yarn already wound on the bobbin tube, can be replaced by a direct drive of the bobbin tube, which has the advantage of spooling that is gentle on the yarn.

A spring ring is to be understood as an annular design of a spring, wherein ring-shaped means that the spring ring has an outer peripheral edge and an opening in the middle. The outer peripheral edge and the central opening are not necessarily circular, in the sense of the application, for example, configurations with an outer peripheral edge in the form of a polygon and a square opening are to be understood under a spring washer. Likewise, the resilient or damping effect of the spring ring can be strengthened by shaping slots or bulges or directed in a certain direction. Combinations of materials, such as steel and plastic, or differently shaped cross-sectional profiles are also conceivable. A wide variety of shapes and designs of spring washers are known in the prior art, which can be used here. The spring ring used in any case brings with it the stability to be able to transmit a torque for driving the coil sleeve.

Advantageously, the spring ring is formed from a spring plate with a central opening and at least four mounting holes arranged concentrically to the central opening. It has been shown that the use of a spring plate is suitable for transmitting the required torque and at the same time the necessary flexibility or spring action in this drive to compensate for inaccuracies in the coil sleeve clamping. The required spring action must be provided by the sections of the spring ring which are available between the fastenings in the fastening holes of the spring ring on the sleeve receiving element and on the holding element. Through the central opening in the spring plate, the resilient effect of the spring element in the areas between the mounting holes is increased. As an alternative, it is also possible to provide slots, a plurality of openings or other measures which change the cross section. Three fastening holes are preferably provided in the spring ring for fastening the sleeve receiving element on the one hand and the holding element on the other hand. Because of the necessary fastening holes for the fastenings, a hexagonal peripheral edge with a circular central opening has proven to be advantageous as a shape for the spring ring.

It is also advantageous if the spring ring is composed of at least four ring-shaped spring plate elements, the individual spring plate elements being movably connected to one another by hollow pins at their mutually facing ends. In this embodiment, the hollow pins, in addition to ensuring the formation of a ring from the individual spring sheet metal elements, also provide the fastening holes necessary for fastening the sleeve receiving element and the holding element. It is particularly preferable if the spring ring is composed of six ring-shaped spring plate elements, the individual spring plate elements being movably connected to one another by hollow pins at their ends facing each other. Of the six hollow pins required to connect the individual spring sheet metal elements, three can each be used to fasten the sleeve receiving element and the holding element.

It is further advantageous if the spring plates or spring plate elements are each formed as a spring assembly consisting of several individual plates. This advantage can be applied to any of the spring washer types mentioned above. If a spring plate or spring plate element is built as a spring assembly, this has the advantage that, on the one hand, the spring action can be exactly determined and, on the other hand, if a single sheet within a spring assembly fails, the entire spring action is not lost.

In a preferred embodiment, the sleeve receiving element is screwed to the spring element and the holding element is connected to the spring element from an opposite side of the spring element. This embodiment of a spring element installed between the sleeve receiving element and the holding element is preferred for reasons of simple and space-saving construction. However, other embodiments are also conceivable in which, for example, the spring element is used as a connecting element or the holding element engages around the spring element, so that the sleeve receiving element and the holding element are connected to the spring element from the same side.

It is further proposed that the connections are provided with screws, the screws for connecting the sleeve receiving element with the spring element reach through the holding element without contact and are each in engagement with an internal thread in the sleeve receiving element and the screws for connecting the holding element to the spring element Reach through the sleeve receiving element without contact, each with an internal thread in the holding element. In this design, the spring element can be inserted into this interior space by a corresponding design of an interior space of the sleeve receiving element and the holding element. This has the advantage of reducing the susceptibility to dirt of the spring system. This also makes it possible to retrofit old machines due to the overall low overall height of the sleeve receptacle. The overall height of the tube holder can be adapted as desired to existing device stanchions, so that no conversion of existing winding machines is necessary when using a tube holder according to the invention.

As an alternative to the above embodiment of the connections, the hollow pins can have an internal thread. This means that screws can be used that do not have to be passed through the opposite component. The sleeve receiving element and the holding element can be screwed directly to the spring element through the internal thread of the hollow pins.

Furthermore, a coil frame with two holding arms arranged in parallel is proposed, a first sleeve receptacle being provided on a first holding arm and a second sleeve receptacle opposite the first sleeve receptacle being provided on a second holding arm. At least one of the sleeve receptacles is designed as described above and the holding element is rotatably attached to the holding arm. Such equipment of a coil frame advantageously enables the mounting of a direct drive for the coil tube, whereby the second tube holder is connected to a drive. The first sleeve receptacle is preferably arranged displaceably in its longitudinal axis. Due to the axially displaceable arrangement of the sleeve receptacle, it can be moved in its axial position when a full bobbin is reached, the full bobbin can be removed from the sleeve receptacle and a new, empty bobbin tube can be inserted.

Furthermore, a winding device for winding yarn onto a sleeve is proposed with a bobbin frame as described above.

[0018] Further advantages of the invention are described in the following exemplary embodiments. It shows: <tb> Fig. 1 <SEP> is a schematic view of a coil frame according to the prior art; <tb> Fig. 2 <SEP> is a schematic side view of the coil frame according to Fig. 1; <tb> Fig. 3 <SEP> is a schematic representation of an embodiment of a sleeve receptacle according to the invention; <tb> Fig. 4 <SEP> is a schematic illustration of an embodiment of a spring element according to the invention; <tb> Fig. 5 <SEP> is a schematic representation of a further embodiment of a spring element and <tb> Fig. 6 <SEP> is a schematic sectional illustration at the point X-X according to FIG. 5.

Fig. 1 shows a schematic view and Fig. 2 is a schematic side view of a coil frame 1 according to the prior art. The spool frame 1 consists of a swivel arm 4 with a swivel axis 5 and a first holding arm 2 and a second holding arm 3. The holding arms 2 and 3 are fixed in a rotationally fixed manner opposite one another at the respective end of the swivel arm 4. As a result, the holding arms 2 and 3 are pivoted about the pivot axis 5 by a pivoting movement 38 of the pivot arm 4. The swivel arm 4 is held in a machine frame 22 via corresponding supports 20. Furthermore, a sleeve receptacle 6 and 7 are rotatably mounted opposite each other on the end of the holding arms 2 and 3 facing away from the swivel arm 4 via a bearing pin 11 and 12. The first bearing pin 11 with a first sleeve receptacle 6 and a second bearing pin 12 with a second sleeve receptacle 7 are arranged in a common longitudinal axis 8. A coil sleeve 9 is clamped between the sleeve receptacles 6 and 7. One of the two sleeve receptacles, for example the sleeve receptacle 6, or its bearing pin 11 is held in the holding arm 2 so as to be displaceable in the direction of the longitudinal axis 8. As a result, a coil sleeve 9 can be inserted between the sleeve receptacles 6 and 7 and the sleeve receptacle 6 can then be pressed against the sleeve receptacle 7 and the coil sleeve 9 can thus be clamped. In the embodiment shown, the sleeve receptacle 7 is connected to a drive wheel 13 in the longitudinal axis. The drive wheel 13 is set in rotation by a drive element 14, for example a chain drive, which leads to a rotation of the coil sleeve 9 due to the connection with the sleeve receptacle 7.

A support roller 10 is arranged parallel to the longitudinal axis 8 of the coil sleeve 9, on which the coil sleeve 9 comes to rest due to the pivoting movement 35 of the pivot arm 4 about the pivot axis 5. The support roller 10 is rotatably fastened in the machine frame 22 by corresponding brackets 21. By rotating the bobbin tube 9 in a corresponding direction of rotation 19, a thread 17 placed on the bobbin tube 9 is wound onto the bobbin tube 9 and a bobbin 18 is formed. During this winding process, the thread 17 is moved back and forth along the longitudinal axis 8 of the bobbin tube 9 with a traverse 15. With the help of this direction of movement 16 of the oscillation 15, different types of windings or coils 18 can be produced on the coil sleeve 9. Due to the formation of a winding on the bobbin tube 9, the bobbin 18 increases in diameter, as a result of which the bobbin frame 1 is pivoted about the pivot axis 5 by the backup roller 10 due to the abutment on the support roller 10. During the winding process, the thread 17 is clamped between the bobbin tube 9 or the thread 17 already wound on the bobbin tube 9 and the support roller 10, so that there is a tight-fitting winding on the bobbin tube 9.

Fig. 3 shows a schematic representation of an embodiment of a sleeve receptacle 7 according to the invention. The sleeve receptacle 7 is fastened to the holding arm 3 via a bearing pin 12. The bearing pin 12 is held rotatably in the holding arm 3 about the longitudinal axis 8, the sleeve receptacle 7 being attached to the bearing pin 12 in a rotationally fixed manner. The sleeve receptacle 7 is formed from a sleeve receiving element 23, a holding element 24 and a spring element 25. The sleeve receiving element 23 has an internal thread 26 for fastening the spring element 25. For fastening the sleeve receiving element 23 to the spring element 25, screws 30 are provided which pass through a passage opening 29 in the holding element 24 without contact and are in engagement with the internal thread 26 in the sleeve receiving element 23. For fastening the holding element 24 to the spring element 25, screws 32 are provided, which pass through a passage opening 27 in the sleeve receiving element 23 without contact and are in engagement with an internal thread 31 in the holding element 24. The spring element 25 is provided in the illustration shown in an embodiment according to FIG. 5 and has fastening holes in the form of hollow pins 28. For fastening the sleeve receiving element 23 and the holding element 24 to the spring element 25, the screws 30 and 32 are guided through the hollow pins 28.

Fig. 4 shows a schematic representation of an embodiment of a spring element 25 according to the invention. The spring element 25 is formed from a spring plate 33 in an annular shape. The spring plate 33 has a hexagonal shape with rounded corners and has a central circular opening 34. For fastening in the sleeve receptacle 7 (see FIG. 3), six concentrically arranged fastening holes 35, which are evenly distributed over the circumference, are provided, three fastening holes 35 each being used for fastening the sleeve receiving element 23 and the holding element 24.

5 shows a schematic illustration of a further embodiment of a spring element 25 according to the invention and FIG. 6 shows a schematic sectional illustration at the point X-X according to FIG. 5. The spring element 25 is composed of six elongated spring plate elements 36, 37, which are arranged in a hexagon. The spring plate elements 36, 37 are movably connected to one another at their respective ends with a hollow pin 28. At the position of a respective hollow pin 28, a first spring plate element 36 and a second spring plate element 27 overlap and have a corresponding opening for receiving the hollow pin 28.

The present invention is not limited to the illustrated and described embodiments. Modifications within the scope of the claims are possible as well as a combination of the features, even if these are shown and described in different exemplary embodiments.

Reference list

[0025] <tb> 1 <SEP> coil frame <tb> 2 <SEP> First holding arm <tb> 3 <SEP> Second holding arm <tb> 4 <SEP> swivel arm <tb> 5 <SEP> swivel axis <tb> 6 <SEP> First sleeve holder <tb> 7 <SEP> Second sleeve holder <tb> 8 <SEP> longitudinal axis of the bobbin tube <tb> 9 <SEP> coil sleeve <tb> 10 <SEP> backup roller <tb> 11 <SEP> First bearing pin <tb> 12 <SEP> Second bearing pin <tb> 13 <SEP> drive wheel <tb> 14 <SEP> drive element <tb> 15 <SEP> traversing <tb> 16 <SEP> direction of movement traversing <tb> 17 <SEP> thread <tb> 18 <SEP> coil <tb> 19 <SEP> Direction of rotation of the coil <tb> 20 <SEP> prop <tb> 21 <SEP> Support roller support <tb> 22 <SEP> machine frame <tb> 23 <SEP> sleeve receiving element <tb> 24 <SEP> holding element <tb> 25 <SEP> spring element <tb> 26 <SEP> internal thread <tb> 27 <SEP> passage opening in the sleeve receiving element <tb> 28 <SEP> hollow pin <tb> 29 <SEP> passage opening in the holding element <tb> 30 <SEP> screw for sleeve receiving element <tb> 31 <SEP> internal thread <tb> 32 <SEP> screw for holding element <tb> 33 <SEP> spring plate <tb> 34 <SEP> Central opening <tb> 35 <SEP> mounting hole <tb> 36 <SEP> First spring plate element <tb> 37 <SEP> Second spring plate element <tb> 38 <SEP> swivel movement

Claims (12)

1. sleeve receptacle (6, 7) for a coil frame (1) of a winding device, with a conical sleeve receiving element (23), with a holding element (24) and with a spring element (25), characterized in that the sleeve receiving element (23) over the Spring element (25) is rotatably connected to the holding element (24) and the spring element (25) is designed as a spring ring. 2. sleeve receptacle (6, 7) according to claim 1, characterized in that the spring ring (25) from a spring plate (33) with a central opening (34) and at least four concentric to the central opening (34) arranged mounting holes (35) is. 3. sleeve receptacle (6, 7) according to claim 1, characterized in that the spring ring (25) is composed of at least four ring-shaped spring plate elements (36, 37), the individual spring plate elements (36, 37) at their ends facing each other are movably connected to one another by hollow pins (28). 4. sleeve receptacle (6, 7) according to claim 1, characterized in that the spring ring (25) is composed of six annular spring plate elements (36, 37), the individual spring plate elements (36, 37) at their ends facing each other through Hollow pins (28) are movably connected to one another. 5. sleeve receptacle (6, 7) according to one of claims 2 to 4, characterized in that the spring plate (33) or the spring plate elements (36, 37) are each formed as a spring assembly consisting of several individual plates. 6. sleeve receptacle (6, 7) according to one of the preceding claims, characterized in that the sleeve receiving element (23) with the spring element (25) is screwed and the holding element (24) from an opposite side of the spring element (25) with the spring element ( 25) is connected. 7. sleeve receptacle (6, 7) according to claim 6, characterized in that the connections are provided with screws (30, 32), the screws (30) for connecting the sleeve receiving element (23) to the spring element (25) without contact by a Pass through the opening (29) in the holding element (24) and engage each with an internal thread (26) in the sleeve receiving element (23) and the screws (32) for connecting the holding element (24) to the spring element (25) contact-free through the sleeve receiving element ( 23) engage with an internal thread (31) in the holding element (24). 8. sleeve receptacle (6, 7) according to one of claims 3 to 6, characterized in that the hollow pins (28) have an internal thread. 9. Coil frame (1) with two holding arms (2, 3) arranged in parallel, a first sleeve receptacle (6) on a first holding arm (2) and a second sleeve receptacle opposite the first sleeve receptacle (6) on a second holding arm (3) (7) are provided, characterized in that at least one of the sleeve receptacles (6, 7) is designed according to one of claims 1 to 8 and the holding element (24) is rotatably attached to the holding arm (2, 3). 10. Coil frame (1) according to claim 9, characterized in that the first sleeve receptacle (6) is arranged displaceably in its longitudinal axis (8). 11. Coil frame (1) according to claims 9 or 10, characterized in that the second sleeve receptacle (7) is connected to a drive element (13, 14). 12. winding device for winding yarn onto a tube, with a bobbin frame (1), characterized in that the bobbin frame (1) is designed according to one of claims 9 to 11.