EP3591106B1 - Thread supply device and method for operating same - Google Patents

Description

The invention relates to a thread delivery device and a method for delivering a thread to a textile machine.

The thread feeding device is provided with a housing and with a storage device, the thread being drawn off from the storage device by the textile machine. Such a yarn feeding device is also called a storage yarn feeding device.

A storage thread feeding device, referred to as a weft thread buffer store, is shown in FIG DE-AS 15 35 641 described. The thread feeding device comprises a storage device referred to as a storage body, a shaft on which the storage body is cantilevered, and a winding element which is referred to as a rotary body with a weft thread feed member. The accumulator is secured against rotation. To reduce fly, fluff or dust deposits in the area of the storage body, the rotary body is designed in the manner of a fan wheel.

From the DE-U 79 02 821 a device for storing thread-like material with a housing, a winding body and a feed eyelet is known. The winding body and the feed eyelet rotate relative to one another. The housing has at least one slot running parallel to the circumference of the housing for the escape of air, airborne dust and dirt.

the EP-B1 335 055 describes a weft feed device for textile machines with a motor housing, a stationary drum, with a motor shaft and a pivot arm which winds a weft thread onto the stationary drum. The drum is supported coaxially and rotatably on the motor shaft of the swivel arm. The device has a first set of magnets on the motor housing and a second set of magnets on the drum. The drum is held in a fixed angular position by mutual attraction between the first and second sets of magnets.

In this structure of the yarn feeders, the entry of z. B. dust and lint and corresponding deposits, preferably in the area of the swivel arm, do not completely avoid. One way to clean these devices is to take them apart. This and the subsequent assembly are complex.

The object of the invention is to develop a storage yarn feeder that can be cleaned more easily.

This problem is solved as follows.

A thread delivery device according to the invention for delivering a thread to a textile machine is provided with a housing and with a storage device from which the thread is drawn off by the textile machine. The thread feeding device has a winding element for winding the thread onto the storage device and a drivable shaft for driving the winding element. The yarn feeding device comprises a magnet arrangement for fixing the storage device on the housing with a first magnet unit on the housing and with a second magnet unit on the storage device. It has a bearing device for the rotatable mounting of the shaft with respect to the storage device with the second magnet unit and a locking device for axially fixing the bearing device. The winding element is designed to be rotatable with the shaft and is arranged between the two magnet units. The storage device has a storage body and a wobble body. The locking device has a locking element which is arranged at the outer end of the shaft and is connected to the shaft via a thread.

For cleaning, a unit, which is formed from the storage device, the second magnet unit and the storage device, is designed to be movable along a cleaning path. The formation of a movable unit enables the storage device with the second magnet unit and the storage device to be withdrawn jointly from the winding element by a defined distance, namely the cleaning distance. By pulling off the unit along the cleaning path, an intermediate space is freed between the unit and the winding element for cleaning, e.g. for removing deposits.

The locking element is arranged on the unit. The unit can be moved along the cleaning path by releasing the locking element. The locking element is released by pulling it off via a threaded connection, i. H. is moved. When the locking element is released, the unit is, as mentioned, pulled off the winding element and a free space is formed for the winding element. The arrangement of the locking element simplifies the removal of the unit in that the locking element only has to be released.

In one example the locking element is connected to the unit. In another example, the locking element is in contact with the unit.

In one embodiment, the cleaning path along which the unit is designed to be displaceable is 3 mm to 10 mm. This cleaning section enables a corresponding distance between the second magnet unit and the winding element, which is sufficient to remove contaminants such as lint and dust.

In one embodiment, the magnet arrangement is designed as a magnet coupling, the second magnet unit being coupled to the first magnet unit in an operating state for fixing the storage device to the housing. The magnet units include, for example, permanent magnets, the permanent magnets of the first magnet unit and the second magnet unit being arranged during operation in such a way that there is an attractive force.

In one embodiment, the shaft in a drive section is designed as a hollow shaft through which the thread is guided. A winding element is arranged on the shaft, the thread being guided from the hollow shaft through the winding element to a thread guide element during operation.

In one embodiment, the bearing device and the winding element are designed to be axially braced, with the axial bracing being able to be generated by actuating the locking device. By releasing the locking element, the axial tension can be released and the unit can be removed for cleaning along the cleaning path.

Providing an axial bracing of the bearing device and the winding element makes it possible to design the unit and possibly the winding element to be axially displaceable when the tension is released, without impairing the functions of the thread delivery during operation. The axial bracing prevents individual parts of the bearing device from shifting axially with respect to one another or with respect to the winding element during operation.

For cleaning, the axial tensioning of the bearing device and the winding element is first released by loosening the locking element and then the unit is moved by the winding element on the shaft along the cleaning path in order to create a free space.

In one embodiment, the winding element for cleaning, ie when the axial tension is released, is designed to be movable on the shaft along the cleaning path. For cleaning, the unit is first removed by releasing the locking element along the cleaning path and the first space between the second magnet unit of the unit and the winding element is cleaned. Then the The winding element is pulled off around the cleaning section to the second magnet unit. The second magnet unit serves as a stop. The second space between the take-up element and the first magnet unit is also cleaned.

In one embodiment, the winding element is designed to be axially displaceable and is guided radially. As a result, when the winding element is moved for cleaning, the radial position of the winding element in relation to the shaft is retained. This ensures that the thread is guided through the shaft, designed for example as a hollow shaft, to the winding element. The radial position of the winding element necessary for thread guidance does not have to be set after the shift. Additional adjustment measures are not necessary.

In one embodiment, the locking element is arranged in the direction of the outer end of the shaft in front of the storage body. The locking element is z. B. on the storage body, the storage body, and with it the unit, can be removed by loosening the locking element. When the locking element is released, the storage body with the locking element is pulled off the shaft.

In one embodiment, the storage body has a disk-shaped bottom or ceiling part which protrudes below the locking element, so that the locking element rests on the bottom or ceiling part.

In one embodiment, the locking element extends cylindrically so far perpendicular to the shaft that it rests on an annular bottom or top part of the storage body.

In one embodiment, the bearing device has a first bearing unit, by means of which the shaft is mounted rotatably with respect to the storage body with the second magnet unit, and a second bearing unit, by means of which the shaft is mounted rotatably with respect to the wobble body.

In one embodiment, the shaft extends through the storage device. A bearing of the first bearing unit is arranged on the locking element in the region of a lower end of the storage body. The arrangement of a bearing of the first bearing unit on the locking element, which is connected to the shaft via a thread, enables the unit to be withdrawn via the bearing. The arrangement enables the unit to be pulled off by the locking element and, when the unit is moved, makes it easier to overcome the attraction force of the magnetic coupling and frictional forces.

In one embodiment, the second bearing unit for the wobble body is arranged axially displaceably on the shaft and is guided radially.

Due to the radial guidance of the second bearing unit, its radial position, in particular that of the wobble body relative to the shaft, is retained when the unit is moved. The winding element applies turns of thread to the storage body, which turns are moved along the storage body by the wobble body. By maintaining the radial position of the wobble body relative to the shaft, the alignment of its radial position with the radial position of the take-up element is obtained. An undisturbed operation of the yarn feeding device, namely the conveyance of the yarn turns on the storage body by the wobble body, is ensured after a cleaning process without additional measures.

In one embodiment, the second bearing unit for the wobble body comprises a bearing bush which is arranged axially displaceably on the shaft and is guided radially.

In one embodiment, the bearing bush comprises at least one wobble section referred to as an inclined hub. The inclined hub has a cylindrical lateral surface, the axis of which is inclined to the axis of the shaft, d. H. is arranged at an angle. At least one bearing of the second bearing unit for the wobble body is arranged on the outer surface of the inclined hub, also referred to as inclined cylindrical. When the shaft rotates, a wobbling movement of the wobble body is generated by the lateral surface.

The wobble body is arranged in the interior of the storage body. It comprises conveying elements which, during the wobbling movement of the wobble body, come out at least in part through openings in the storage body over an outer circumference of the storage body and are withdrawn. Thread windings on the storage body are moved in the axial direction by the conveying elements. In one embodiment, the bearing bush is designed as a guide bush.

In one embodiment, the shaft has an inclined section with an obliquely cylindrical lateral surface, the axis of which is inclined to the axis of the shaft, i. H. is arranged at an angle. In operation, the second bearing unit is arranged on the wobble section. As a result, the second bearing unit for the wobble body is arranged axially displaceably on the shaft and is guided radially.

In one embodiment, the second bearing unit can be displaced in the inclined section of the shaft at least by the cleaning distance.

In one embodiment, a separate fitting element is arranged on the shaft and on one of the above-mentioned bearing bushes of the second bearing unit, the bearing bushing being axially displaceable and being guided radially at least along the cleaning path. The fitting element is designed, for example, as an elongated, roughly cuboid-shaped part.

In one embodiment, the fitting element is arranged in a guide opening of the bearing bush and sits in a guide groove of the shaft. When pulling off for cleaning, the bearing bush is moved along the cleaning path with the guide opening over the fitting element.

In an alternative embodiment, the fitting element is arranged in a guide opening in the shaft and sits in a guide groove in the bearing bush.

In one embodiment, the length of the guide opening in the shaft is longer than the length of the fitting element by the length of the cleaning path. The width of the guide opening in the shaft is slightly wider than the width of the guide groove in the guide bushing, the fitting element being seated in the guide groove, i. H. is arranged for example by a form fit. For cleaning, the guide bushing with the fitting element is pulled off along the cleaning path by releasing the locking device.

For dismantling, the guide groove in the bearing bush allows a movement of the bearing bush over the fitting element, which strikes at the end in the guide opening after overcoming the possibly low clamping force of the form fit, when it is pulled off further.

In one embodiment, the yarn feeding device has at least one connecting element, by means of which, in order to form the unit, the second magnet unit and the storage body are designed such that they can be connected to one another.

In one embodiment, the connection element or elements are each arranged on one of the two parts, namely on the second magnet unit or on the storage body. In the connected state, the connecting element or elements are each guided radially in the other part and have play in the axial direction. A play in the axial direction between the second magnet unit and the storage device ensures an axial bracing of the bearing device and the winding element. The axial bracing is not produced via the connecting element or elements between the second magnet unit and the storage body.

The features and advantages of the method claims correspond to those of the device claims.

In a method for operating a thread feeding device with a housing, a thread is supplied to a textile machine, the thread being drawn off by the textile machine from a storage device of the thread feeding device. The thread is wound onto the storage device by a winding element. The winding element is driven by a drivable shaft. The storage device is fixed to the housing by a magnet arrangement with a first magnet unit on the housing and a second magnet unit on the storage device. The shaft is mounted rotatably with respect to the storage device with the second magnet unit by a bearing device. The bearing device is locked by a locking device. The winding element arranged between the two magnet units is rotated with the shaft. The storage device has a storage body and a wobble body. The locking device has a locking element which is arranged at the outer end of the shaft and is connected to the shaft via a thread.

A unit, which is formed from the storage device, the second magnet unit and the storage device, is moved along a cleaning path, the unit being moved by releasing the locking element, i. H. is deducted.

In one embodiment, an axial bracing of the bearing device and the winding element is generated by actuating the locking element. For cleaning, the axial tension is released by loosening the locking element.

In one embodiment, for cleaning, the winding element is displaced on the shaft by a cleaning distance L in the axial direction and is guided radially.

In one embodiment, the locking device is released by holding a locking element of the locking device which is arranged at the outer end of the shaft and which is connected to the shaft by means of a thread and by rotating the shaft.

This method has the advantage that it can be activated automatically. The locking element can be fixed, for example, by a tool. The drive of the shaft can then be controlled automatically. I. E. Torque and number of revolutions can e.g. B. can be specified via the control of a drive motor forming the drive of the shaft.

A thread delivery device according to the invention is designed to deliver a thread to a knitting machine. The knitting machine is a circular knitting machine or a flat knitting machine or a knitting machine or a similar machine. A The yarn delivery device according to the invention is designed as an alternative to the delivery of a weft thread to a weaving machine.

• Fig. 1 eine schematische Darstellung eines Fadenlieferrades anhand einer Seitenansicht eines erfindungsgemäßen Fadenliefergerätes eines ersten Beispiels;
• Fig. 2 einen Teilschnitt durch das Fadenliefergerät der Figur 1 parallel zur Achse der Welle in einem Betriebszustand;
• Fig. 3 einen Teilschnitt durch das Fadenliefergerät der Figur 1 parallel zur Achse der Welle in einem Reinigungszustand; und
• Fig. 4a einen Schnitt durch eine zweite Magneteinheit, einen Speicherkörper und einen Taumelkörper;
• Fig. 4b ein vergrößertes Detail der Fig. 4a;
• Fig. 4c ein weiteres, vergrößertes Detail der Fig. 4a;
• Fig. 5 einen Schnitt durch das Fadenliefergerät eines zweiten Beispiels parallel zur Achse der Welle in einem Betriebszustand, wobei die Lagereinrichtung axial verspannt ist.

The invention is further explained with reference to examples shown schematically in the drawings. Show it:

• Fig. 1 a schematic representation of a yarn delivery wheel based on a side view of a yarn delivery device according to the invention of a first example;
• Fig. 2 a partial section through the thread feeder of Figure 1 parallel to the axis of the shaft in an operating state;
• Fig. 3 a partial section through the thread feeder of Figure 1 parallel to the axis of the shaft in a cleaning state; and
• Figure 4a a section through a second magnet unit, a storage body and a wobble body;
• Figure 4b an enlarged detail of the Figure 4a ;
• Figure 4c another enlarged detail of the Figure 4a ;
• Fig. 5 a section through the yarn feeding device of a second example parallel to the axis of the shaft in an operating state, wherein the bearing device is axially braced.

First example

An in Figure 1 The illustrated thread feeding device 1 for delivering a thread 40 to a textile machine is designed as a storage thread feeding device. The thread feeding device 1 has a housing 2 and a storage device with a storage body 3, from which the thread 40 is drawn off by the textile machine. The textile machine is, for example, a circular knitting machine.

The housing 2 comprises a holder 2a and a drive housing 2b. The holder 2a is provided with a fastening device for fastening the thread feeder 1 to the textile machine, for example to a machine ring of the circular knitting machine. In one embodiment, the fastening device is attached on the side opposite the holder 2a. This is indicated by an arrow 4a. In this embodiment the housing comprises a contact plate 2c.

In a further embodiment, the fastening device, instead of the contact plate 2c, is attached to the side of the holder 2a. This is indicated by an arrow 4b.

The yarn feeding device 1 has a drivable shaft 5 on which the storage body 3 is arranged, the shaft 5 being rotatably mounted with respect to the storage body 3. I. E. the storage body 3 can be fixed when the shaft 5 is rotating. An axis A of the shaft 5 is in the Figures 1 to 3 indicated by a dashed line. A drive for the shaft 5, not visible in the figures, is arranged in the drive housing 2b. The holder 2a extends parallel to the shaft 5 along the storage body 3.

the Figures 2 and 3rd show a section through the yarn feeding device 1 of FIG Figure 1 parallel to the axis A of the shaft 5, namely Figure 2 in operation and Figure 3 when cleaning.

The yarn feeding device 1 has a magnet arrangement by means of which the storage device with the storage body 3 can be fixed on the housing 2. The magnet arrangement comprises a first magnet unit 6, which is arranged on the housing 2, and a second magnet unit 7, which is arranged on the storage body 3 of the storage device. The first magnet unit 6 has a first ring 6a, which is formed on the lower end of the drive housing 2b in the drawing and concentric to the shaft 5, and first permanent magnets 6b arranged on the ring 6a. The second magnet unit 7 has a second ring 7a formed concentrically to the shaft 5 and second permanent magnets 7b arranged on the ring 7a.

The permanent magnets 6b of the first ring 6a and the permanent magnets 7b of the second ring 7a are arranged during operation in such a way that there is an attractive force between the two rings 6a and 7a.

In this example, the second magnet unit 7 is designed as a separate element which is rotatably arranged on the shaft 5. The second magnet unit 7 is designed to be connectable to the storage body 3 of the storage device.

The storage device with the storage body 3 is fixed during operation by the magnet arrangement with the two magnet units 6, 7 on the housing 2, specifically on the drive housing 2b.

The storage body 3 is designed as a storage drum with a body axis which runs parallel to the axis A of the shaft 5 and essentially corresponds to this.

The storage body 3 is at its withdrawal end, ie in Figure 1 and 2 rounded lower end to form a clamping surface 3a. It has axially extending openings 3b on its outer circumference. I. E. the openings 3b extend in an envelope surface of the storage body 3 parallel to the axis A of the shaft 5.

The storage body 3 is provided with a level sensor FS, which is arranged in the lower region of the storage body 3.

At the winding end of the storage body 3, in the Figures 1 to 3 above, a winding element 8 is arranged for winding the thread 40 onto the storage body 3 of the storage device. The thread 40 is wound onto the storage body 3 in turns, which are referred to as thread or yarn turns.

The winding element 8 is arranged on the shaft 5. The winding element 8 can be fixed on the shaft 5 and can be driven by the shaft 5. The winding element 8 is arranged between the first magnet unit 6 and the second magnet unit 7.

The winding element 8 is designed concentrically around the shaft 5 and in the shape of a disk. In this example, the winding element 8 is designed as a conical disk. A thread guide element 8a is formed on the outer circumference of the winding element 8.

The winding element 8 is arranged on the shaft 5 so as to be displaceable in the axial direction.

The upper section of the shaft 5 is designed as a hollow shaft with a cylindrical cavity 5a. The cavity 5a ends at a level in the area of the winding element 8. Starting from the cavity 5a, the shaft 5 has an opening 5b. The one in the Figures 2 and 3 The thread 40, not shown, is guided through the cavity 5a and the opening 5b to the winding element 8 during operation. The winding element 8 has a guide channel 8b which ends at the thread guide element 8a.

In operation, the winding element 8 protrudes with its guide channel 8b into the opening 5b of the shaft 5. In the area of the opening 5b of the shaft 5, which has a groove running in the axial direction, which cannot be seen in the figures, the winding element 8 is in the axial direction displaceable and guided at least along a cleaning path L in the radial direction.

The yarn feeding device 1 has a bearing device which rotatably supports the shaft 5 relative to the second magnet unit 7 and the storage device. The bearing device is arranged on the shaft 5 so as to be displaceable in the axial direction.

In addition to the storage body 3, the storage device comprises a wobble body 9 which is arranged in the interior of the storage body 3. The wobble body 9 has a bushing 9a, conveying elements 9b connected to the bushing 9a, and an elastic element 9c. The conveying elements 9b are arranged in the axially extending openings 3b of the storage body 3.

The elastic element 9c is designed as a foam body which extends annularly around the shaft 5. The elastic element 9c is connected to the storage body, wherein the The wobble body 9 is movable to a small extent with respect to the storage body 3 due to the elasticity of the elastic element 9c.

The bearing device comprises a first bearing unit 10 for the rotatable mounting of the shaft 5 with respect to the storage body 3 with the second magnet unit 7 and a second bearing unit 11 for the rotatable mounting of the shaft 5 with respect to the wobble body 9.

In this example, the shaft 5 extends through the storage device. The first bearing unit 10 has a first bearing 12 designed as a ball bearing and a second bearing 13 designed as a ball bearing. The first bearing 12 is arranged for the rotatable mounting of the shaft 5 with respect to the second magnet unit 7 on the shaft 5 below the winding element 8 and above the storage body 3. The second bearing 13 is for the rotatable mounting of the shaft 5 with respect to the storage body 3 at the lower end of the storage body 3 and in the area of the outer, d. H. the lower end of the shaft 5 is arranged.

The second bearing unit 11 adjoins the bearing 12 for the second magnet unit 7 in the direction of the outer end of the shaft, at the bottom in the figures. It is located between the bearings 12 and 13 of the first storage unit. The second bearing unit comprises a bearing bush 14 with sections with a jacket surface 14a, 14c which is cylindrical to the axis A of the shaft 5 and with a central wobble section with an oblique cylindrical, i.e. H. cylindrical and oblique to the axis A, lateral surface 14b. I. E. In the wobble section, an axis of the lateral surface runs obliquely, specifically at an acute angle to the axis A of the shaft 5 and intersects it in a region of the storage device, which is lower in the figures. In this example, the axis of the inclined cylindrical lateral surface intersects the axis A of the shaft 5 in the area of a lower take-off height of the storage body 3. The second bearing unit 11 also has two bearings 15, 16 designed as ball bearings, arranged next to one another, which are mounted on the wobble section of the bearing bush 14 are arranged.

The bearing bush 14 is formed in several parts in this example. A part of the bearing bush 14 comprises the upper section with the cylindrical jacket surface 14a and the wobble section with the inclined cylindrical jacket surface 14b of the bearing bush 14. This part with the wobble section, which carries the bearings 15, 16 and causes the wobble movement of the wobble cylinder 9, is also referred to as the inclined hub. The other part, also referred to as the clamping bush, comprises the lower section with the cylindrical jacket surface 14c. The inclined hub and the clamping bush can be connected to one another by means of a form fit.

The two bearings 15, 16 are arranged in the wobble section of the bearing bush 14 on the shaft 5. In this example, the bearings 15, 16 are firmly connected to the wobble body 9. They are injected into the socket 9a, for example. The wobble body 9 is rotatable on the two bearings 15, 16 and is thus supported in a wobbling manner on the shaft 5.

The second bearing unit 11 for the wobble body 9 is arranged axially displaceably on the shaft 5 and is guided radially. It comprises a fitting element 17 which is arranged on the bearing bush 14 and on the shaft 5. It is designed as an elongated, cuboid-shaped element.

On its inner diameter, the bearing bush 14 has a guide groove 14d in which the fitting element 17 is arranged. The fitting element 17 is arranged in the guide groove 14d with a form fit. The shaft 5 has a corresponding guide opening 5c extending in the axial direction. The length of the guide opening 5c in the axial direction corresponds to the length of the fitting element 17 plus the length of the cleaning section L. In this guide opening 5c, the fitting element 17 is guided along the cleaning section L radially.

The yarn feeding device 1 comprises a locking device for tensioning the bearing device and the winding element 8. The locking device has a locking element 18 which is arranged on the outer end of the shaft 5, which is the lower end in the figures. The locking element 18 is connected to the shaft 5 via a thread. I. E. the locking element 18 is designed to be displaceable on the shaft 5 via the threaded connection.

The second bearing 13 of the first bearing unit 10 is arranged on the locking element 18. The second bearing 13 with the locking element 18 is designed to be displaceable on the shaft 5 via the threaded connection. The storage body 3 is rotatably mounted on the second bearing 13.

In this example, the second magnet unit 7 has a plurality of connecting elements 19, by means of which the second magnet unit 7 is designed such that it can be connected to the storage body 3 of the storage device. Each connecting element 19 is guided radially through the storage body and has play in the axial direction with respect to the storage body.

Figure 4a shows a section through the second magnet unit 7 and the storage body 3, which are shown in isolation to clarify the connection. the Figures 4b and 4c show enlarged detailed views of a connecting element 19.

The connecting elements 19 are designed as clip elements, for example. The connecting elements 19 are molded onto the second magnet unit 7. They have the shape of a hook, with a first section 19a and a second section 19b. With the In the second section 19b, the connecting element 19 protrudes into an opening 3b of the storage body 3. The second section 19b is guided radially in the opening 3b and has play in the axial direction.

As described, the storage body 3 can be connected to the second magnet unit 7 via the connecting elements 19 and is connected during operation. By fixing the second magnet unit 7 to the first magnet unit 8, the storage body 3 connected to the second magnet unit 7 is fixed to the housing 2. The rotatable mounting by the first bearing unit 10 enables a stationary storage body 3 with the shaft 5 rotating.

The storage device with the storage body 3 and the wobble body 9, the second magnet unit 7 and the bearing device form a unit which can be moved along the cleaning path L for cleaning.

The locking element 18 is arranged on the unit, the second bearing 13 of the first bearing unit 10 being formed in one piece with the locking element 18. The unit can be moved along the cleaning path L on the shaft by releasing the locking element 18.

The bearing device and the winding element 8 are designed to be axially braced. I. E. the bearing device and the winding element 8 can be moved on the shaft 5, a stop, not shown in the drawing, being provided on the shaft. When operating the locking device, d. H. When the locking element 18 is tightened, the bearing device is pressed against the winding element 8 and this against the stop of the shaft 5, thus generating an axial tension.

The braking device for adjusting a thread tension of the thread 40 has a braking body 20 and an adjusting device for the braking body 20. The braking device is arranged in the thread run after the storage body 3, the braking body 20 being arranged at the withdrawal end of the storage body 3.

The brake body 20 is conical, specifically as a resilient brake body cone in the form of a regular truncated cone jacket. It is made of a plastic and / or metal, for example. Corresponding or similar brake bodies are, for example, in WO 2006/045410 A1 described.

The axis of the brake body 20 is essentially correct, that is, apart from slight deviations, e.g. B. by lifting off by the thread 40 or deformation of the elastic braking body 8, coincides with the axis A of the shaft 5. The withdrawal end of the storage body 3 is rounded and forms an annular clamping surface 3a in the area of the rounding. The larger diameter of the brake body 20 projects beyond the clamping surface 3a. It can be pressed against the clamping surface 3 a at the withdrawal end of the storage body 3 by the adjustment device.

When the thread 40 is withdrawn by the textile machine, the thread 40 runs from the storage body 3 through the gap between the withdrawal end of the storage body 3 and the braking body 20 over the clamping surface 3a.

The brake body 20 is at its smaller diameter, i. H. provided with an inner ring 21 and an outer ring 22 at its end pointing away from the storage body 3. The inner ring 21 and the outer ring 22 are connected to one another by locking connections.

The adjustment device comprises an extraction pipe 23 with an extraction eyelet 24, two magnet units 25, 26 and an outlet eyelet 27.

The take-off tube 23 extends parallel to the axis A, possibly up to installation tolerances. The take-off tube 23 guides the thread 40 from its inlet end facing the storage body 3 to its opposite outlet end; H. through the adjuster.

The exhaust pipe 23 is arranged on the holder 2 a of the housing 2. The upper magnet unit 25 comprises a ring with permanent magnets 25b, the ring being designed as an outer ring 22 of the brake body 20.

The lower magnet unit 26 comprises a ring 26a with permanent magnets 26b. The rings 22, 26a are arranged on the exhaust pipe 23 at a distance from one another.

The permanent magnets 25b of the first ring, i.e. H. of the outer ring 22, and the permanent magnets 26b of the second ring 26a are arranged such that there is a repulsive force between the two rings 22 and 26a. The distance between the lower ring 26a and the upper ring, i.e. H. the outer ring 22 can be changed by rotating the lower ring 26a. When the distance is reduced, the repulsive force between the rings 22 and 26a, and thus the braking force on the brake body 20, is increased, and when the distance is increased, the repulsive force is decreased.

In operation of the thread feeding device 1 with the housing 2, a thread 40 is supplied to a textile machine, the thread 40 being withdrawn from the storage device by the textile machine. The thread 40 is through the winding element 8 on the Storage device wound up. The take-up element 8 is driven by the driven shaft 5.

The storage device is fixed to the housing 2 by the magnet arrangement with a first magnet unit 6 on the housing 2 and a second magnet unit 7 on the storage device. The storage device with the second magnet unit 7 is stored by the storage device. The storage device has a storage body 3 and a wobble body 9. The winding element 8 arranged between the two magnet units 6, 7 is rotated with the shaft 5. The bearing device is locked by the locking device, the locking device having a locking element 38 which is arranged at the outer end of the shaft 5 and is connected to the shaft 5 via a thread.

The unit, which is formed from the storage device, the second magnet unit 7 and the storage device, is moved along the cleaning path L, the unit being moved by releasing the locking element 38.

By actuating the locking element 38, an axial bracing of the bearing device and the winding element 8 is generated. For cleaning, the axial tension is released by releasing the locking element and the unit, which is formed from the storage device, the second magnet unit 7 and the bearing device, is withdrawn along the cleaning path L. The guide bush of the storage device, d. H. the bearing bush 14 is displaced axially and guided radially.

For cleaning, the winding element 8 is axially displaced along the cleaning path L and guided radially.

The locking device is released by holding the locking element 38 and rotating the shaft 5.

In an alternative, the locking element 18 is rotated with the shaft 5 stationary.

In an alternative, the thread feeding device has one, for example, in FIG DE 10 2016 117 506 B3 brake described.

In an alternative, the thread feeding device has one, for example, in FIG DE 10 2013 113 122 B4 brake described.

Second example

An in Figure 5 The illustrated yarn feeding device 1 of the second example corresponds to the yarn feeding device 1 of the first example except for the features shown below.

As in the first example, one unit is formed from a storage device, a lower magnet unit 7 and a storage device.

The bearing device comprises a first bearing unit 31 for the rotatable mounting of a shaft 50 with respect to a storage body 30 with a second magnet unit 7 and a second bearing unit 31 for the rotatable mounting of the shaft 50 with respect to a wobble body 9.

In this example, the drivable shaft 50 for driving the winding element 8 ends in an upper region of the storage device. I. E. the shaft 50 extends through the second magnet unit 7 and the upper region of the storage body 30. It also has a cavity 50a and an opening 50b.

The first bearing unit 31 has a first bearing 33 designed as a ball bearing and a second bearing 34 designed as a ball bearing. For the rotatable mounting of the second magnet unit 7 and the storage body 3, the two bearings 33, 34 are arranged next to one another on the shaft 50 below the winding element 8 and above the storage body 3.

The second magnet unit 7 is designed to be connectable to the storage body 30. In this example, it is connected to the storage body 30 by screws (not shown).

The second bearing unit 32 has a first bearing 35 designed as a ball bearing and a second bearing 36 designed as a ball bearing. The two bearings 35, 36 are arranged next to one another on a lower section of the shaft 50 for the rotatable mounting of the wobble body 9. The lower section of the shaft 50 is designed as an inclined section 50d, the axis of its lateral surface running obliquely to the axis A of the shaft 50 in the upper area.

The wobble body 9 is rotatable on the two bearings 35, 36 and is thus supported in a wobbling manner on the shaft 50.

The locking device has a locking element 37 which is arranged at the outer end of the shaft 50 and is connected to the shaft 50 via a thread.

The locking element 37 is designed as a threaded screw by means of which the bearing device, namely the second bearing unit 32, can be braced and released against the first bearing unit 31 and the latter against the winding element 8.

The locking element 37 is in contact with the storage body 30. The storage body 30 has a base element with an inner cylinder 30b. The inner cylinder protrudes below a head of the locking element 37. This is indicated by the arrow C.

The inner cylinder 30b, i. H. Storage body 30, and with it the unit of storage body 30, second magnet unit 7 and bearing device can be moved by loosening the locking element, i. H. removable.

For cleaning, the locking element 37 is released to such an extent that the unit is pulled off along the cleaning path L.

List of reference symbols

1

Fadenliefergerät

2

Gehäuse
2a Halter
2b Antriebsgehäuse
2c Kontaktplatte

3

Speicherkörper
3a Klemmfläche
3b Öffnung

4

(Befestigungsvorrichtung)
4a Pfeil (Befestigungsvorrichtung)
4b Pfeil (Befestigungsvorrichtung)

5

Welle
5a Hohlraum
5b Öffnung
5c Führungsöffnung

6

erste Magneteinheit
6a erster Ring
6b erste Permanentmagnete

7

zweite Magneteinheit
7a zweiter Ring
7b zweite Permanentmagnete

8

Aufwickelelement
8a Fadenführungselement

9

Taumelkörper
9a Buchse
9b Förderelement
9c elastisches Element

10

erste Lagereinheit

11

zweite Lagereinheit

12

Lager

13

Lager

14

Lagerbuchse
14a zylindrische Mantelfläche
14b schräge Mantelfläche
14c zylindrische Mantelfläche
14d Führungsnut

15

Lager

16

Lager

17

Passelement

18

Arretierungselement

19

Verbindungselement

20

Bremskörper

21

Innenring

22

Außenring

23

Abzugsrohr

24

Abzugsöse

25

Magneteinheit
25b Permanentmagnet

26

Magneteinheit
26a Ring
26b Permanentmagnet

27

Auslauföse

40

Faden

A

Achse

Zweites Beispiel

30

Speicherkörper
30b Boden

31

erste Lagereinheit

32

zweite Lagereinheit

33

Lager

34

Lager

35

Lager

36

Lager

37

Arretierungselement

50

Welle
50a Hohlraum
50b Öffnung
50c Schrägabschnitt

40

Faden

A

Achse

P1

Pfeil

P2

Pfeil

C

Pfeil

1

Yarn feeding device

2

casing
2a holder
2b drive housing
2c contact plate

3

Storage body
3a clamping surface
3b opening

4th

(Fastening device)
4a arrow (fastening device)
4b arrow (fastening device)

5

wave
5a cavity
5b opening
5c guide opening

6th

first magnet unit
6a first ring
6b first permanent magnets

7th

second magnet unit
7a second ring
7b second permanent magnets

8th

Winding element
8a thread guide element

9

Wobble body
9a socket
9b conveyor element
9c elastic element

10

first storage unit

11

second storage unit

12th

warehouse

13th

warehouse

14th

Bearing bush
14a cylindrical outer surface
14b inclined lateral surface
14c cylindrical outer surface
14d guide groove

15th

warehouse

16

warehouse

17th

Fitting element

18th

Locking element

19th

Connecting element

20th

Brake body

21

Inner ring

22nd

Outer ring

23

Exhaust pipe

24

Trigger eyelet

25th

Magnet unit
25b permanent magnet

26th

Magnet unit
26a ring
26b permanent magnet

27

Outlet eyelet

40

thread

A.

axis

Second example

30th

Storage body
30b floor

31

first storage unit

32

second storage unit

33

warehouse

34

warehouse

35

warehouse

36

warehouse

37

Locking element

50

wave
50a cavity
50b opening
50c inclined section

40

thread

A.

axis

P1

arrow

P2

arrow

C.

arrow

Claims (12)

1. Thread feeding device (1) for feeding a thread (40) to a textile machine comprising a housing (2), a storage device, from which the thread (40) is drawn off by the textile machine, a winding element (8) for winding the thread (40) onto the storage device, a drivable shaft (5, 50) for driving the winding element (8), a magnet arrangement for fixing the storage device onto the housing (2) with a first magnet unit (6) on the housing (2) and a second magnet unit (7) on the storage device, a bearing device for the rotatable bearing of the shaft (5, 50) relative to the storage device with the second magnet unit (7) and a locking device for fixing the bearing device, wherein the winding element (8) is designed to be rotatable with the shaft (5, 50) and is arranged between the two magnet units (6, 7), wherein the storage device has a storage body (3) and a wobble body (9), and wherein the locking device has a locking element (18, 37), which is arranged at an outer end of the shaft (5, 50) and is connected via a thread to the shaft (5, 50),
   characterised in that
   for cleaning purposes a unit, which comprises the storage device, the second magnet unit (7) and the bearing device, is designed to be movable on the shaft (5, 50) along a cleaning section (L), and
   in that the locking element (18, 37) is arranged on the unit, wherein the unit can be moved by releasing the locking element (18, 37).
2. Thread feeding device (1) according to claim 1, characterised in that the bearing device and the winding element (8) are designed to be axially tensionable, wherein the axial tensioning can be achieved by tightening the locking element (18, 37) and for cleaning purposes the axial tensioning can be released by releasing the locking element (18, 37).
3. Thread feeding device (1) according to claim 1 or 2, characterised in that the locking element (37) is arranged in the direction of the outer end of the shaft (50) in front of the storage body (3), wherein by releasing the locking element (37) the storage body (3), and with the latter the unit, can be moved.
4. Thread feeding device (1) according to any of claims 1 or 2, wherein the bearing device has a first bearing unit (10) for the rotatable bearing of the shaft (5) relative to the storage body (3) and the second magnet unit (7) and a second bearing unit (11) for the rotatable bearing of the shaft (5) relative to the wobble body (9), characterised in that the shaft (5) extends through the storage device, and in that a bearing (13) of the first bearing unit (10) is arranged in the area of a lower end of the storage body (3) on the locking element (18), wherein by releasing the locking element (18) the bearing (13), and with the latter the unit, can be removed.
5. Thread feeding device (1) according to any of claims 1 to 4, wherein the bearing device has a first bearing unit (10) for the rotatable bearing of the shaft (5, 50) relative to the storage body (3) and the second magnet unit (7) and a second bearing unit (11) for the rotatable bearing of the shaft (5, 50) relative to the wobble body (9), characterised in that the second bearing unit (11) for the wobble body (9) is arranged to be axially displaceable on the shaft (5, 50) and is guided radially.
6. Thread feeding device (1) according to claim 5, characterised in that a separate fitting element (17) is arranged on the shaft (5) and on a bearing bush (14) of the second bearing unit (11), and in that the bearing bush (14) is guided radially by the fitting element (17) along the cleaning section (L).
7. Thread feeding device (1) according to any of claims 1 to 6, characterised in that to form the unit the second magnet unit (7) and the storage body (3) can be connected to one another by at least one connecting element (19).
8. Thread feeding device (1) according to claim 7, characterised in that the connecting element(s) (19) is/are arranged respectively on one of the two parts, namely on the second magnet unit (7) or on the storage body (3), and in the connected state are guided radially in the other part and have play in axial direction.
9. Method for operating a thread feeding device (1) with a housing (2), wherein a thread (40) is supplied to a textile machine, wherein the thread (40) is drawn off by the textile machine from a storage device, wherein the thread (40) is wound by a winding element (8) onto the storage device, wherein the winding element (8) is driven by a drivable shaft (5, 50), wherein the winding element (8) arranged between the two magnet units (6, 7) is rotated with the shaft (5, 50), wherein the storage device is fixed by a magnet arrangement with a first magnet unit (6) on the housing (2) and a second magnet unit (7) on the storage device is fixed on the housing (2), wherein the shaft (5, 50) is supported to be rotatable relative to the storage device with the second magnet unit (7) by a bearing device, and wherein the bearing device is locked by a locking device, wherein the storage device comprises a storage body (3) and a wobble body (9), and wherein the locking device comprises a locking element (18, 38) which is arranged on an outer end of the shaft (5, 50) and is connected via a screw thread to the shaft (5, 50),
   characterised in that
   for cleaning purposes a unit, which comprises the storage device, the second magnet unit (7) and the bearing device, is moved on the shaft (5, 50) along a cleaning section (L), wherein the unit is moved by releasing the locking element (18, 38).
10. Method according to claim 9, characterised in that by tightening the locking element the bearing device and the winding element (8) are axially tensioned and in that for cleaning purposes the axial tensioning is released by releasing the locking element.
11. Method according to claim 9 or 10, characterised in that for cleaning purposes firstly the unit on the shaft (5, 50) is moved along a cleaning section (L), a first intermediate space between the unit and the winding element (8) is cleaned, afterwards the winding element (8) on the shaft (5, 50) is moved along the cleaning section (L), wherein it is guided radially, and a second intermediate space between the winding element (8) and the first magnet unit (6) is cleaned.
12. Method according to any of claims 9 to 11, characterised in that for cleaning purposes the locking element (18) is released in that it is held and the shaft (5, 50) is rotated.

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