DE102018126346B4 - Winding device and method for winding a thread - Google Patents

Abstract

Spooling device (10) for winding up a thread (11), comprising a spool mandrel (12) which is rotatably driven about a first axis (A1) and on which a bobbin tube (H) can be attached, in order to transfer the thread (12) thereon upon rotation of the bobbin mandrel (12). 11) to be wound into a thread package (13), a holding device (14) on which a drivable feeler roller (16) rotatable about a second axis (A2) is attached, the second axis (A2) running parallel to the first axis (A1) and a distance (S1, S2) of the feeler roller (16) to the spool mandrel (12) is variable, characterized by a magnetic coupling device (17) with which the feeler roller (16) can be driven to rotate about the second axis (A2), the Magnetic coupling device (17) comprises a first polarized magnetic ring (18) mounted on the reel mandrel (12) and a second polarized magnetic ring (19) mounted on the feeler roller, the holding device (14) having a rocker (15) which, relative to the reel mandrel (12 ) is pivotable, un d the magnetic coupling device (17) automatically becomes inactive when the feeler roller (16) is in contact with a thread package (13) wound on the bobbin mandrel (12) and the bobbin tube (H) attached to it, and thereby the thread package (13) attached to the feeler roller (16) second polarized magnetic ring (19) has attained an enlarged distance from the first polarized magnetic ring (18) attached to the spool mandrel (12).

Description

The invention relates to a winding device for winding a thread, with a spool mandrel rotatably driven about a first axis on which a bobbin tube can be attached in order to wind the thread into a thread package when the bobbin mandrel rotates, and with a holding device on which a drivable to a second axis rotatable feeler roller is attached. Here, the second axis runs parallel to the first axis, and the distance between the feeler roller and the bobbin mandrel can be changed, especially during the winding process. The invention also relates to a method for winding a thread according to the preamble of claim 10.

According to the prior art, for winding a thread onto a bobbin bobbin winder or winding devices are known in which a so-called feeler roller is provided parallel to a driven bobbin mandrel on which the bobbin tube can be attached to take up the thread, which is provided with its peripheral surface the piecing of the thread, ie shortly after the start of the winding process, bears against the wound thread or a thread package formed from it.

In a cost-effective solution of a winding device, no separate drive is provided for the feeler roller, as is the case, for example, from DE 102 01 118 A1 is known. This has the consequence that the feeler roller, when its outer circumferential surface comes into contact with the thread package forming on the bobbin tube, is “dragged along” by the driven bobbin mandrel. However, such a solution is subject to the disadvantage that the bobbin tube and the thread package formed thereon are particularly stressed when piecing. Furthermore, due to the transmission of high drag torques between the feeler roller and the bobbin mandrel, thread and tube damage cannot be ruled out.

According to the prior art, an improvement in the winding quality can be achieved in that the feeler roller is also driven by an electric motor, as is shown, for example, in FIG EP 0 861 800 A2 is known. Here, the feeler roller is driven at the same speed as the bobbin mandrel, especially at the beginning of the winding process. A separate drive for the feeler roller represents a solution that is gentle on the thread, because no torques have to be transmitted from the lap or thread package to the feeler roller. Nevertheless, the provision of a separate electric motor with which the feeler roller is driven is disadvantageous with regard to the outlay on equipment, because this requires a precisely controllable motor including a clutch and an associated frequency control. Depending on the installation situation, it may also be necessary to provide, for example, a belt drive between the electric motor and the feeler roller, which further increases the effort and costs.

The DE 10 2006 061 289 B4 shows a magnetic coupling for a cheese in which the torque is transmitted from a drive wheel via an intermediate wheel to a lead roller. All shafts are fixed in place on a carrier.

The DE 10 2006 008 339 A1 discloses a feeler roller which is designed as a rotor of an electric motor and which together with an externally arranged stator form an electric motor. This means that the feeler roller is part of an electric motor, which is always regulated to the speed of the winding shaft by means of a sensor.

Accordingly, the invention is based on the object of designing a winding device and a corresponding method for winding a thread in a simpler and more cost-effective manner with regard to the drive of the feeler roller.

The invention achieves the object set by a winding device with the features specified in claim 1, and by a method according to claim 10.

Advantageous further developments of the invention are defined in the dependent claims.

A winding device according to the present invention is used for winding a thread onto a bobbin tube and comprises a bobbin mandrel which is rotatably driven about a first axis and on which the bobbin tube can be attached in order to wind the thread into a thread package upon rotation of the bobbin mandrel. The thread package consists of the sleeve and the wound thread. The winding device further comprises a holding device on which a drivable feeler roller is attached which can be rotated about a second axis, the second axis running parallel to the first axis and a distance between the feeler roller and the bobbin mandrel being variable. In particular, at the beginning of the winding process, the outer circumferential surface of the feeler roller is not yet in contact with the thread or thread package wound on the bobbin.

The invention includes the technical teaching that a magnetic coupling device is provided for the above winding device, with which the feeler roller can be driven to rotate about the second axis. This magnetic coupling device comprises a first polarized magnetic ring mounted on the spool mandrel and a second polarized magnetic ring mounted on the feeler roller Magnetic ring. If the feeler roller is sufficiently close to the spool mandrel and thus the second polarized magnetic ring lies within the effective magnetic field of the first polarized magnetic ring, the second polarized magnetic ring is "dragged along" by the first polarized magnetic ring and the feeler roller is thereby set in rotation about the second axis or driven.

In the same way, the present invention also provides a method for winding a thread onto a bobbin tube, in which a bobbin mandrel, on which the bobbin tube is attached, is set in rotation about a first axis by a drive and a feeler roller, which rotates about a parallel axis the second axis extending to the first axis is rotatable, comes into contact with a thread package which is formed by the winding of the thread on the bobbin tube. This method is characterized in that the feeler roller is driven, especially when the thread is pieced, by a magnetic coupling device which comprises a first polarized magnetic ring mounted on the bobbin mandrel and a second polarized magnetic ring mounted on the feeler roller. As already explained for the above winding device, the feeler roller is driven around the second axis when the feeler roller is sufficiently close to the spool mandrel and thereby the second polarized magnetic ring attached to the feeler roller is polarized by the first one attached to the spool mandrel Magnetic ring is "dragged along".

The invention is based on the essential knowledge that no separate electric motor is required for the feeler roller to drive it about the second axis. Instead, the feeler roller is driven around the second axis by means of the explained magnetic coupling device and its polarized magnetic rings, which are each mounted on the spool mandrel and on the feeler roller. Here, the magnetic coupling device is always active and causes the feeler roller to be driven around the second axis when the feeler roller is positioned sufficiently close to the spool mandrel and the second polarized magnetic ring, which is attached to the feeler roller, is within the magnetic field of the first polarized magnetic ring.

With the magnetic coupling device, the feeler roller is only driven about the second axis when it is positioned directly adjacent to the bobbin mandrel. In the context of the present invention, the feature "immediately adjacent" is to be understood as meaning that a distance between the feeler roller and the spool mandrel is sufficiently small that the second polarized magnetic ring mounted on the feeler roller is located within the effective magnetic field of the first polarized magnetic ring Interaction between the second polarized magnetic ring mounted on the feeler roller and the first polarized magnetic ring mounted on the coil mandrel can take place. This then has the consequence that a rotation of the bobbin mandrel about the first axis also simultaneously causes a rotation of the feeler roller about the second axis. When the second polarized magnetic ring is entrained by the first polarized magnetic ring, the speed of the feeler roller around the second axis is advantageously always matched to the speed of the spool mandrel - ideally, the speed of the feeler roller matches the speed of the spool mandrel. Separate devices for speed or frequency control of the feeler roller are therefore not required.

The holding device, on which the feeler roller is mounted rotatably, is designed to be movable such that a distance between the feeler roller and the bobbin mandrel can be changed in the course of the winding process for the thread. Thus, a continuous contact of the outer circumferential surface of the feeler roller with a thread package formed on the bobbin tube during the winding process is ensured that the distance between the feeler roller and the spool mandrel can be changed or increased as the diameter of the thread package formed increases. From a certain diameter of the thread package formed on the bobbin, the distance between the feeler roller and the bobbin mandrel is so great that the second polarized magnet ring mounted on the feeler roller passes outside the magnetic field of the first polarized magnet ring. In this case, the feeler roller is then no longer driven about the second axis, but simply runs freely with the thread package wound on the bobbin as a result of the contact system. In other words, the magnetic coupling device is automatically inactive from a certain winding diameter of the thread and the resulting increased distance between the feeler roller and the bobbin mandrel.

In an advantageous development of the invention, a polarized magnetic ring comprises a sequence of north / south magnetic elements or corresponding magnetic fields with such a polarization along its circumference. The above-described entrainment of the second magnetic ring by the first magnetic ring, if the feeler roller is positioned directly adjacent to the spool mandrel, is achieved in that when the feeler roller rotates about the second axis, a magnetic element on the second magnetic ring (e.g. with a "north" Polarization) always comes in opposition to a magnetic element provided on the first magnetic ring with the opposite polarization (for example “south”).

In an advantageous development of the invention, the feeler roller with the mounted on it second polarized magnetic ring be attached in such a way with respect to the coil mandrel and the first polarized magnetic ring mounted thereon that the second magnetic ring is brought into radial opposition to the first magnetic ring, at least when the feeler roller is positioned sufficiently close to the coil mandrel. As an alternative to this, it can also be provided that the magnetic rings for the bobbin mandrel and the feeler roller are designed in such a way that they can be brought into opposition in a coaxially adjacent manner. With both of these variants, it is ensured that the second magnetic ring is "dragged along" by the first magnetic ring when the feeler roller is sufficiently close to the spool mandrel and the second magnetic ring lies within the effective magnetic field of the first magnetic ring a drive of the feeler roller around the second axis.

In an advantageous development of the invention, the magnetic forces of attraction that act between the polarized magnet rings when the second magnet ring is carried along by the first magnet ring can be reduced or weakened by additional rings that are radially magnetized. This means that such an additional ring is provided with a “north” polarization in its outer area and with a “south” polarization in its inner area, or vice versa. In any case, at least one such radially magnetized additional ring is attached to each of the first and second magnetic rings, with the proviso that the polarity of these additional rings in their outer area when the additional rings are compared when the spool mandrel and the feeler roller rotate about the first or second axis arrive, then is in the same direction, e.g. "North-North" or "South-South". As a result, a magnetic repulsion is achieved between the additional rings, with which the magnetic attraction between the first and second magnetic rings is weakened. The strength of the magnetization of the additional rings is suitably selected so that the feeler roller rotates together with the spool mandrel due to the entrainment of the second polarized magnetic ring by the first polarized magnetic ring with the lowest possible radial forces.

When using the above-mentioned additional rings on the first and second polarized magnetic ring, it is useful to use ring-shaped shielding elements with a high magnetic permeability, which are each arranged between an additional ring and the north / south magnetic elements of a magnetic ring. With the help of such shielding elements, magnetic shielding is advantageously achieved in the axial direction of the magnet rings in order to minimize mutual magnetic interference.

• - Verschleißfreiheit, weil die Mitnahme des zweiten Magnetrings durch den ersten Magnetring berührungslos erfolgt.
• - Kein separater Motor zum Antrieb der Tastwalze erforderlich.
• - Keine Kontamination des Fadens und dessen Fasern, weil es keinen Abrieb von Reibbelägen oder dergleichen gibt.
• - Keine Schädigung von Spulenhülsen.
• - Möglichkeit der Nachrüstung einer bereits bestehenden Spulvorrichtung.

The use of the non-contact magnetic coupling device leads to the following additional advantages:

• Wear-free, because the second magnetic ring is carried along by the first magnetic ring without contact.
• - No separate motor required to drive the feeler roller.
• - No contamination of the thread and its fibers, because there is no abrasion from friction linings or the like.
• - No damage to bobbin tubes.
• - Possibility of retrofitting an already existing winding device.

• 1 eine schematisch vereinfachte Seitenansicht einer erfindungsgemäßen Spulvorrichtung;
• 2 die Spulvorrichtung von 1, wenn darauf ein Faden zu Beginn eines Wickelvorgangs aufgewickelt ist;
• 3 eine Querschnittsansicht einer Spulvorrichtung nach einer weiteren Ausführungsform der Erfindung;
• 4 eine Querschnittsansicht durch Magnetringe, die Teil einer Spulvorrichtung nach den 1-3 sind;
• 5 eine Schnittansicht entlang der Linie A-B von 4,
• 6 eine Querschnittsansicht durch Magnetringe, die Teil einer Spulvorrichtung nach den 1-3 sind, nach einer weiteren Ausführungsform der Erfindung;
• 7 eine Stirnseitenansicht auf die Magnetringe von 6;
• 8 eine schematisch vereinfachte Seitenansicht der Spulvorrichtung von 1, wenn darauf ein Faden mit im Vergleich zu 2 zunehmenden Wickeldurchmesser aufgewickelt ist;
• 9 eine Querschnittsansicht der Spulvorrichtung von 3, mit einer Betriebsstellung einer Tastwalze in Entsprechung von 8, und
• 10 eine Querschnittsansicht einer Spulvorrichtung nach einer weiteren Ausführungsform der Erfindung.

Further features and advantages of the present invention emerge from the following description of preferred embodiments. Show it:

• 1 a schematically simplified side view of a winding device according to the invention;
• 2 the winding device of 1 when a thread is wound thereon at the start of a winding process;
• 3 a cross-sectional view of a winding device according to a further embodiment of the invention;
• 4th a cross-sectional view through magnetic rings, which are part of a winding device according to the 1-3 are;
• 5 a sectional view along the line AB of 4th ,
• 6th a cross-sectional view through magnetic rings, which are part of a winding device according to the 1-3 are, according to a further embodiment of the invention;
• 7th an end view of the magnetic rings of 6th ;
• 8th a schematically simplified side view of the winding device of FIG 1 if on it a thread with compared to 2 increasing winding diameter is wound;
• 9 FIG. 3 is a cross-sectional view of the winder of FIG 3 , with an operating position of a feeler roller corresponding to 8th , and
• 10 a cross-sectional view of a winding device according to a further embodiment of the invention.

With reference to the 1 to 10 preferred embodiments of a winding device according to the invention 10 explains how to wind a thread 11 on a Bobbin case H serves. The same features in the drawing are each provided with the same reference symbols. At this point it goes without saying that the drawing is only shown in a simplified manner and, in particular, without a scale.

In the 1 and 2 are components of the winding device 10 shown in principle simplified in a side view. The winding device 10 includes a spool mandrel 12 around a first axis A ₁ is rotatably mounted and by a motor M. (see. 3 ) around the first axis A ₁ is driven in a direction of rotation symbolized by an arrow.

On the mandrel 12 can be a bobbin tube H (see. 3 ) are attached or attached to take up a thread 11 that occurs when the bobbin mandrel rotates 12 around the first axis A ₁ on the bobbin H is wound up. To simplify matters, there is such a bobbin case H in the 1 and 2 not shown, and will be explained separately below.

The winding device 10 further comprises a holding device 14th with a swing arm 15th , on which a rotatably mounted feeler roller 16 is appropriate. The 1 and 2 Make it clear that the feeler roller is about a second axis A ₂ is rotatable, which is parallel to the first axis A ₁ runs. The swing arm 15th can around a hinge (not shown) attached to the holding device 14th is provided to be pivoted. The holding device 14th with the swing arm attached to it 15th is arranged in such a way that the on the rocker 15th attached feeler roller 16 in comparison to the spool mandrel 12 is located. By pivoting the rocker 15th around their joint can during the winding process for the thread 11 a distance of the feeler roller 16 to the mandrel 12 appropriately changed or adapted.

At the beginning of a winding process in which a thread 11 on the bobbin H is wound, or when piecing such a thread 11 on the bobbin H , has the feeler roller 16 to the mandrel 12 initially a distance S ₁ , each related to the respective axes of rotation A ₁ and A ₂ (see. 1 ). This distance is for the functioning of a magnetic coupling device 17th of importance, as will be explained in detail below.

The magnetic coupling device 17th (see. 3 ), which are part of the winding device according to the invention 10 comprises a first polarized magnetic ring 18th that on the spool mandrel 12 mounted, and a second polarized magnetic ring 19th , the one on the feeler roller 16 is mounted. Along a perimeter of the polarized magnetic rings 18th , 19th North / South magnetic elements or corresponding magnetic fields with such a North / South polarization are provided. These magnetic rings 18th , 19th are provided for the purpose that when the feeler roller 16 immediately adjacent to the spool mandrel 12 is positioned while the second polarized magnetic ring 19th in the effective magnetic field of the first polarized magnetic ring 18th then the second magnetic ring 19th from the first magnetic ring 18th magnetically "dragged along", which drives the feeler roller 16 around the second axis A ₂ causes. Such an entrainment of the second magnetic ring 19th through the first magnetic ring 18th when the mandrel 12 and feeler roller 16 around their respective axes A ₁ , A ₂ rotate is realized in that a magnetic element of the second magnetic ring 19th (eg with the polarization "north") always with a magnetic element of the first magnetic ring 18th with opposite polarization (eg "South") comes into opposition.

In one embodiment of the winding device 10 according to the 3-5 it is provided that the magnetic rings 18th , 19th can be brought into a radial opposition relative to one another, for example in the cross-sectional view of 4th is easy to see. The 5 which is a sectional view taken along line AB of FIG 4th shows, shows that along the circumference of the magnetic rings 18th , 19th each individual magnetic element 20th are attached that have the polarization "N" (= north) radially on the outside and the polarization "S" (= south) on the radial inside and vice versa. Furthermore, in the 5 to see that the individual magnetic elements of the two magnetic rings 18th , 19th that during a rotation of the bobbin mandrel 12 and feeler roller 16 come into opposition with each other, each having an opposite polarization. In the example of 5 this is the "south" polarization of the magnetic element 20th on the first magnetic ring 18th which is the polarization "north" of the opposing magnetic element 20th on the second magnetic ring 19th assigned. In this way it is ensured that when the motor turns M. driven reel mandrel 12 around the first axis A ₁ the second polarized magnetic ring 19th from the first polarized magnetic ring 18th is magnetically "dragged along" and thereby the feeler roller 16 around the second axis A ₂ is driven.

The 6th and 7th show a modification for the magnetic rings 18th , 19th that are suitable for the embodiment of the winding device according to 3 suitable. Here are the north / south magnetic elements 20th only in an axial section on the first and second magnetic rings 18th , 19th provided, namely in their respective middle part 21st what by the cross-sectional view of 6th is made clear.

The cross-sectional view of 6th also shows that in the axial edge areas of the magnet rings 18th , 19th additional rings each 22nd are attached, which from the adjacent north / South magnetic elements 20th each by ring-shaped shielding elements 23 are separated or shielded. These shielding elements 23 each have a high magnetic permeability so that it is in the axial direction of the magnet rings 18th , 19th not to a mutual influence between the north / south magnetic elements 20th and the additional rings 22nd comes. 7th shows an end view of those on the magnet rings 18th , 19th attached additional rings 22nd and shows that these additional rings 22nd are each magnetized radially, with a “north” polarization radially outside and a “south” polarization radially inside.

By means of the additional rings 22nd is in the embodiment of the magnetic rings 18th , 19th according to 6th and 7th causes the radial forces acting between the first polarized magnetic ring 18th and the second polarized magnetic ring 19th as a result of the magnetic force of attraction of the individual opposing magnetic elements 20th act with different polarization, weakened or compensated. This is achieved by changing the polarity of the additional rings 23 is in the same direction at their outer areas, as shown by the 6th is shown with the example "north-north". Nevertheless, the magnetic force is the polarization of the additional rings 22nd only designed so high that this has the effect of “dragging along” the second polarized magnetic ring 19th through the first polarized magnetic ring 18th - when the mandrel is rotating 12 and feeler roller 16 around the respective axes A ₁ or. A ₂ - is not canceled.

• Zu Beginn eines Aufwickelvorgangs für den Faden 11 wird die Schwinge 15 mit der daran angebrachten Tastwalze 16 um das Gelenk in Richtung des Pfeils R1 (vgl. 1) verschwenkt, so dass damit die Tastwalze 16 mit geringem Spalt angrenzend zum Spulendorn 12 positioniert wird. Hierbei nimmt der Abstand zwischen der Tastwalze 16 und dem Spulendorn 12 den Wert S₁ an, der ausreichend gering ist, dass sich damit der zweite polarisierte Magnetring 19 innerhalb des magnetischen Wirkfelds des ersten polarisierten Magnetrings 18 befindet. Anders ausgedrückt, ist die Tastwalze 16 zu Beginn des Aufwickelvorgangs bzw. vor dem Anspinnen zunächst dicht genug an dem Spulendorn 12 angeordnet, so dass bei einer Rotation des angetriebenen Spulendorns 12 um die erste Achse A₁ in Folge des erläuterten magnetischen „Mitschleppens“ des zweiten Magnetrings 19 durch den ersten Magnetring 18 die Tastwalze 16, zunächst auch ohne eine Berührung einer auf dem Spulendorn 12 aufgebrachten Spulenhülse H, um die zweite Achse A₂ beschleunigt und damit auf Betriebsdrehzahl gebracht wird, die mit der Drehzahl des Spulendorns 12 übereinstimmt.

The invention now works as follows:

• At the beginning of a winding process for the thread 11 becomes the swing arm 15th with the feeler roller attached to it 16 around the joint in the direction of arrow R1 (cf. 1 ) pivoted so that the feeler roller 16 with a small gap adjacent to the spool mandrel 12 is positioned. The distance between the feeler roller increases 16 and the mandrel 12 the value S ₁ that is sufficiently small that the second polarized magnetic ring is located 19th within the effective magnetic field of the first polarized magnetic ring 18th is located. In other words, it is the feeler roller 16 at the beginning of the winding process or before piecing, initially close enough to the spool mandrel 12 arranged so that upon rotation of the driven bobbin mandrel 12 around the first axis A ₁ as a result of the explained magnetic “dragging” of the second magnetic ring 19th through the first magnetic ring 18th the feeler roller 16 , at first even without touching one on the spindle 12 applied bobbin case H to the second axis A ₂ accelerated and thus brought to operating speed, which is the speed of the bobbin mandrel 12 matches.

The just mentioned piecing of the thread 11 on the bobbin H corresponds to the representation in 2 and 3 . The feeler roller then arrives 16 with their outer peripheral surface in contact with the thread 11 on the bobbin H to a thread package 13 is wound up. What is important here is that the distance is also important when piecing S ₁ between the feeler roller 16 and the mandrel 12 is still sufficiently low so that the magnetic coupling device 17th to drive the feeler roller 16 around the second axis A ₂ is active by moving the second magnetic ring 19th in the magnetic field of the first magnetic ring 18th and is taken along as a result. In other words, it becomes the feeler roller 16 at the beginning of the winding process by means of the magnetic coupling device 17th synchronous to the spool mandrel 12 driven.

In the further course of the winding process, in which the thread 11 onto the bobbin H to a thread package 13 is wound up, the winding diameter for the thread increases 11 to. In principle, this is simplified in the 8th illustrated. As the winding diameter increases, the distance between the feeler roller increases 16 to the mandrel 12 what by pivoting the rocker arm 15th in the direction of arrow R ₂ (cf. 8th ) is made possible. For example, this distance increases between the feeler roller 16 and mandrel 12 the value S ₂ that is greater than the value S ₁ at the beginning of piecing. Anyway, for this example is the distance S ₂ become so large that the magnetic coupling device 17th becomes inactive because the second polarized magnetic ring 19th from the effective magnetic field of the first polarized magnetic field 18th got out. This then becomes the feeler roller 16 no further about the second axis A ₂ driven, but runs due to the contact system or with the thread package 13 that comes out of the sleeve H and the thread 11 exists, only freely with as long as the spool mandrel 12 around the first axis A ₁ is driven.

The cross-sectional view of 9 shows the embodiment of the winding device 10 according to 3 in an operating position of the feeler roller 16 representing the representation of 8th corresponds. This means that a distance between the feeler roller 16 and the second polarized magnetic ring mounted thereon 19th as a result of the increase in the winding diameter of the thread package 13 (= H +11) opposite the bobbin mandrel 12 has become so large that the magnetic coupling device 17th has become inactive, as already explained above.

The 10 shows a cross-sectional view of a winding device according to the invention 10 according to a further embodiment. Here are the magnetic rings 18th , 19th designed such that they can be brought into opposition to one another coaxially. The 10 shows the winding device 10 in an operating position that corresponds to the representation of 3 corresponds to, the distance between the feeler roller 16 and the mandrel 12 is small enough that the magnetic coupling device 17th is active. This means that then the feeler roller 16 around the second axis A ₂ is driven because of the magnetic "dragging" of the second magnetic ring 19th through the first magnetic ring 18th .

Regarding the embodiment of 10 it goes without saying that when the winding diameter increases, for example to the value S ₂ how it for that 8th has been explained, then the magnetic coupling device 17th in the same way as in 9 illustrated becomes inactive because then the second magnetic ring 19th far enough from the first magnetic ring 18th is spaced and thereby outside the magnetic field of the first magnetic ring 18th got.

Finally, it should be noted that during the winding process the rocker 15th by an actuator (not shown), for example in the form of a pneumatic cylinder, in the direction R ₁ (cf. 1 ) against the mandrel 12 can be employed, so that thereby the feeler roller 16 in the radial direction against the thread package 13 (= H + 11) is pressed. The pressing force that is generated by means of the actuator can be suitably set and / or regulated. This improves the winding quality for the thread package 13 optimized.

List of reference symbols

10

Winding device

11

thread

12

Spool mandrel

13

Thread package

14th

Holding device

15th

Swing arm

16

Feeler roller

17th

Magnetic coupling device

18th

first polarized magnetic ring

19th

second polarized magnetic ring

20th

North / South magnetic elements

21st

Middle part

22nd

Additional ring

23

annular shielding element

A ₁

first axis

A ₂

second axis

H

Bobbin case

M.

engine

S ₁

Distance (when piecing)

S ₂

(increased) distance

Claims (11)

A winding device (10) for winding up a thread (11), comprising a bobbin mandrel (12) which is rotatably driven about a first axis (A ₁ ) and on which a bobbin tube (H) can be attached to the thread upon rotation of the bobbin mandrel (12) (11) to wind up to form a thread package (13), a holding device (14) on which a drivable feeler roller (16) rotatable about a second axis (A ₂ ) is attached, the second axis (A ₂ ) being parallel to the first axis ( A ₁ ) and a distance (S ₁ , S ₂ ) between the feeler roller (16) and the spool mandrel (12) is variable, characterized by a magnetic coupling device (17) with which the feeler roller (16) rotates about the second axis (A ₂ ) is drivable, the magnetic coupling device (17) comprising a first polarized magnetic ring (18) mounted on the spool mandrel (12) and a second polarized magnetic ring (19) mounted on the feeler roller, the holding device (14) having a rocker (15) that are relative to the spool mandrel (12) is detachable, and the magnetic coupling device (17) automatically becomes inactive when the feeler roller (16) is in contact with a thread package (13) wound on the bobbin mandrel (12) and the bobbin tube (H) attached to it and thereby the thread package (13) on the feeler roller ( 16) attached second polarized magnetic ring (19) has attained an enlarged distance from the first polarized magnetic ring (18) attached to the spool mandrel (12). Winding device (10) after Claim 1 , characterized in that a polarized magnetic ring (18, 19) has a sequence of north / south magnetic elements (20) or corresponding magnetic fields along its circumference. Winding device (10) after Claim 1 or 2 , characterized in that the magnetic coupling device (17) is active by an interaction between the second polarized magnetic ring (19) and the first polarized magnetic ring (18) when the feeler roller (16) is positioned adjacent to the spool mandrel (12). Spooling device (10) according to one of the preceding claims, characterized in that the holding device (14) with the feeler roller (16) mounted thereon is positioned with respect to the spool mandrel (12) in such a way that the second polarized magnetic ring (19) can be brought radially in opposition to the first polarized magnetic ring (18). Winding device (10) after Claim 4 , characterized in that the north / south magnetic elements (20) of the polarized magnetic rings (18, 19) are each provided in an axial section thereof, preferably in a central part (21) of the magnetic rings (18, 19). Winding device (10) after Claim 5 , characterized in that the magnetic rings (18, 19) each have at least one additional ring (22) in an axial section thereof, which are radially magnetized, the additional rings (22) being attached to the magnetic rings (18, 19) in such a way, that the polarity of the additional rings (22) is in the same direction (north-north, or south-south) when the magnetic rings (18, 19) are opposite. Winding device (10) after Claim 6 , characterized in that the at least one additional ring (22) is attached to a magnetic ring (18, 19) adjacent to the north / south magnetic elements (20) and is separated therefrom by an annular shielding element (23) with high magnetic permeability. Winding device (10) after Claim 6 or 7th , characterized in that two radially magnetized additional rings (22) are provided on each of the first and second magnetic rings (18, 19), which are attached adjacent to the central part (21) of a magnetic ring (18, 19) in the axial edge regions thereof. Spooling device (10) according to one of the Claims 1 to 3 , characterized in that the holding device (14) with the feeler roller (16) mounted thereon is positioned in relation to the spool mandrel (12) such that the second polarized magnetic ring (19) can be brought coaxially opposite the first polarized magnetic ring (18). A method for winding a thread (11) onto a bobbin tube (H), in which a bobbin mandrel (12) on which the bobbin tube (H) is attached is set in rotation by a drive about a first axis (A ₁ ) and a Sensing roller (16), which is rotatable about a second axis (A ₂ ) running parallel to the first axis (A ₁ ), in contact with a thread package (13), which is moved by winding the thread (11) on the bobbin tube (H ), characterized in that the feeler roller (16) is driven by a magnetic coupling device (17), especially when the thread (11) is pieced, which has a first polarized magnetic ring (18) mounted on the spool mandrel (12) and one on the feeler roller (16) comprises mounted second polarized magnetic ring (19), the feeler roller (16) being attached to a holding device (14) in particular with a rocker (15), the holding device (14) being designed such that a distance (S ₂ ) the feeler roller (16) relative to m bobbin mandrel (12) becomes larger with increasing winding diameter of the thread (11) on the bobbin tube (H), and that with contact between the feeler roller (16) and the thread package (13) wound on the bobbin tube (H) after piecing from one certain winding diameter, the distance (S ₂ ) between the feeler roller (16) and the spool mandrel (12) is increased so that the magnetic coupling device (17) automatically becomes inactive and the feeler roller (16) is no longer driven by the second polarized magnetic ring (19 ) comes outside the magnetic field of the first polarized magnetic ring (18). Procedure according to Claim 10 , characterized in that the feeler roller (16) during piecing, before its periphery comes into contact with the thread (11) wound on the bobbin tube (H), automatically about the second axis (A ₂ ) by the magnetic coupling device (17) is accelerated in such a way that the feeler roller (16) thus reaches a speed which corresponds to the spool mandrel (12).

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