WO2013156302A1 - Winding machine and method for operating a winding machine - Google Patents

Abstract

The invention relates to a method for operating a winding machine having a plurality of winding stations (1) for respectively transferring a thread (3) from a supply coil (2) to a receiver coil (4). A drive (5) is respectively associated with the winding stations (1) for rotating the individual receiver coils (4) so as to wind the thread (3) drawn off from the respective supply coil (2) onto the corresponding receiver coils (4). According to the invention, when the winding machine is in operation, individual coil data and/or at least one thread-specific characteristic which is individually monitored when transferring to each winding station (1), is continuously taken into account in order to maximize the quality and/or the time-related number of receiver coils (4) completely wound by the winding machine. The invention also relates to a winding machine having a plurality of winding stations (1), characterized in that said winding machine comprises a control and/or a regulating device (6) which is designed to operate the winding machine according to the claimed method.

Description

 Winding machine and method for operating a winder

The present invention relates to a method for operating a winding machine with a plurality of winding units for each rewinding of a yarn from a supply spool on a receiver spool, wherein the winding units each having a drive is assigned, with the aid of the individual receiver coils are placed in a rotary motion and thereby the Thread withdrawn from the respective supply spool is wound onto the corresponding receiver spool. In addition, a winding machine with a plurality of winding units for each rewinding of a yarn from a supply spool is proposed on a receiver coil, wherein the winding units each have a drive is assigned to enable the individual receiver coils in a rotational movement and thereby an individual winding of the of the allow each delivered coil withdrawn thread on the corresponding receiver coil.

Generic winding machines (other designation: automatic winder) are known from the prior art and are usually used to rewind a wound on a spinning machine and wound on a supply spool thread on a receiver coil (the capacity or shape of the corresponding parameters of the supply spool differs). The coils usually have a cylindrical or frusto-conical hollow bobbin on which the thread can be wound up. The drive of the respective receiver coils is carried out via a central drive unit whose speed is controlled centrally. Although this drive concept results in a low control and monitoring effort. However, a consideration of coil specific conditions is not possible.

In addition, already winding machines with individual drives are known, ie each winding unit is assigned a separate drive whose speed can be controlled individually. Even if this already wisser degree of customization can be achieved, the speed specifications or their changes in the course of Umspulprozesses for all winding units are uniformly specified and vary only depending on the material to be transposed.

The object of the present invention is to propose a winding machine or a method for operating a winding machine, which permit a rewinding process that is optimized over the prior art.

The object is achieved by a method and a winding machine with the features of the independent claims.

According to the invention, the method for operating a winding machine having a plurality of winding stations for winding a yarn from a supply bobbin onto a receiver bobbin is characterized in that bobbin-individual data and / or at least one thread-specific characteristic individually monitored during winding at each winding station during operation of the winding machine is taken into account continuously in order to maximize the quality and / or time-related number of receiver coils fully wound by the winder.

In contrast to known winding machines, in addition to the type of thread, further parameters are taken into account in order to maximize the length of thread rewound per unit of time on the winding machine or to optimize the quality of the receiver coils produced. Information on the number of yarn breaks at the respective winding units, the origin of the supply bobbins (ie data on the spinning unit which has produced the respective supply bobbin) or also the number of yarn connection points and / or or thread breaks of the contained on the supply spool or the already rewound on the receiver coil thread include. Flow the data into the distribution of the individual supply spools on the individual winding units or the Speeds of the respective receiver or supply spools at the individual winding units, so individual optimizations can be made.

Thus, in a preferred embodiment, the individual bobbins are no longer delivered to an arbitrary winding station and rewound with a centrally predetermined winding speed that is uniform for all winding stations. Rather, individual data are taken into account, so that the operation of the winding machine can be adapted to the actually existing supply spools or the actual spooling process at the respective winding station (eg a lot or a few thread breaks) without the adjustment of a winding station automatically also the identical adjustment of all other winding units would result.

It is particularly advantageous in this case if at least the majority of the receiver coils are each driven by means of a separate drive, wherein the rotational speed of the individual drives is controlled individually by means of a control and / or regulating device. This results in a number of advantages, which are explained in detail below.

In particular, the speed of the receiver coil at a winding unit is no longer dependent on the rotational speeds of the corresponding drives to the other winding units. This in turn makes it possible to optimize the productivity of each winding unit, ie the length of the rewound yarn per unit time, in a winding unit-individual manner. Namely, if a rei ßfesterer thread rewound at a first winding station than at a second winding station, the speed of the drive of the first winding unit (based on the same winding progress or the same bobbin diameter) can be set higher, without causing excessive thread breaks (which would result in a reduced efficiency of the winding unit despite higher winding speed). It is also possible to rewind at different winding stations threads of different batches or of different material, since the speeds of the respective drives can be set individually to the thread. It is particularly advantageous if at least at the plurality of winding points yarn breaks (ie a breakage of the thread) are detected during the rewinding and the speed of the drive of the corresponding winding unit is adapted to the number of yarn breaks per unit time or rewound yarn length to the effectiveness (Length of the per unit time of the supply spool on the receiver spool rewound thread) to optimize each winding unit individually (the said number of thread breaks thus represents in this case the coil-individual characteristic, which takes into account inventive manner). The speed is thus increased in this case, if the number of detected at this winding unit yarn breaks per unit time or rewound thread length falls below a minimum value. Likewise, the speed of this drive is reduced when the number of said thread breaks per unit time exceeds a maximum value. The time unit is a predetermined period of time, the time should only be added when a thread is actually spooled. This avoids that a longer standstill time (in which there can be no inevitable thread break) leads to an increased speed when resuming the rewinding. The increase or decrease in the speed can be carried out continuously or at predetermined intervals, if the above limits were exceeded in a certain period. Alternatively or additionally, it is of course also possible to use the cleaner cuts made by the respective winding unit (ie, the release of a thread misalignment and the subsequent joining of the resulting thread ends) as a basis for the regulation of the respective drive speeds. In this case, it would again be useful to increase the respective rotational speed if the number of cleaner cuts or the sum of the number of cleaner cutters and the number of thread breakages falls below a minimum value or to reduce the rotational speed if the stated values exceed a maximum value. The mentioned quantities can finally be considered as absolute values. It is also conceivable to be relativised, taking into account the tion of the corresponding quantities of elapsed time or the length of the string rewound in a defined time window.

It also brings advantages when the rotational speeds of the individual drives vary individually taking into account the thread-specific parameter (s) mentioned, d. H. is controlled by means of the control and / or regulating device. The thread-specific characteristic monitored during rewinding can be the strength or hairiness of the thread, the thread tension, the thread width, the length of the already rewound thread, the length of the thread rewound since the last thread break or other physical parameters of the thread. the change of which may result, for example, in an increased or lesser risk of thread breakage. Finally, for the parameter, a first and a second limit value and thus a defined range are defined, wherein the rotational speed of the drive at the respective winding station is increased (or reduced) if the characteristic value lies outside the specified range. If, for example, the strength of the thread exceeds an upper limit value, the winding speed can be increased while the thread quality remains the same (that is to say without increasing the thread breakage rate).

Likewise, it is advantageous if the respective drives are operated at start and / or after an interruption of a rewinding operation with a uniformly defined initial rotational speed, which is determined individually on the basis of the thread to be rewound, for example. In the further course, finally, an optimization of the individual winding units by the rotational speeds of the individual drives are adjusted individually. The adaptation can take place taking into account the above-mentioned variables (thread-specific characteristics, yarn breakage rate, etc.) or also taking account of coil-individual data. These include, for example, the current diameter of the supply and / or receiver coil or the past (net) winding time since the last thread break. Likewise, it brings advantages when the coil-individual data, in particular in the form of the respective supply coil identifying or characterizing or the thread contained characterizing data are taken into account to set the initial speed of the respective drives individually based on the above data. Corresponding data are, for example, data on the geometry of the delivery and / or receiver coil (for example, existing imbalances, diameter, length or inclination of the outer surfaces). If, for example, it has been shown in the past that thread breaks are to be recorded more frequently in the case of a specific spool (which can be individualized, for example, with the aid of optical or electronic marking), it would be conceivable to reduce the initial rotational speed when using this spool, the reduction would have no effect on the initial speeds of the remaining drives. The individual coils could be linked in this case, for example, in a database with individual initial speeds, so that always the optimum initial speed can be selected.

Furthermore, it is advantageous if the coil-specific data contain information about the spinning position of the spinning machine, which has produced the respective supply spool. For example, it is known that not all spinning stations of a spinning machine produce threads with exactly the same properties. If, however, the origin of the delivery bobbin is taken into account, then the corresponding characteristics of the respective spinning station can be discussed. For example, if it is known that the spinning station A of the ring spinning machine B produces a thread which has a lower strength compared to the other spinning stations, it makes sense to reduce the initial speed of the drive of that winding station compared to a standard value, the same with the rewinding Delivery coil is entrusted. Similarly, the initial speed can be increased when the corresponding supply spool comes from a spinning station, which produces a particularly tear-resistant thread. Corresponding data about the individual spinning stations or coils can be stored in a data base of the winding machine. chert and are always available when a known coil is handled by the winder.

It is advantageous if the coil-individual data information about the number of connection points (which were created in the case of the supply spool at the spinning station or in the case of the receiver coil at the winding unit) and / or the number of thread breaks, the distribution of joints or thread breaks over the length of the wound thread or the diameter of the coil, the thread material and / or other thread-specific characteristics, such as hairiness, rotation and / or the strength of the thread included. In this case, the winding unit can be adjusted individually to the thread to be wound on this winding unit. If, for example, the thread contained on the supply spool has excessively large number of connection points (which, for example, originate at the spinning position produced by the thread) and / or relatively many thread breaks, then it may be useful to reduce the initial speed relative to a standard value to an excessively high number To avoid yarn breaks during rewinding.

It is particularly advantageous if the supply spools are assigned to the individual winding stations, taking into account the individual data of the bobbins, in particular taking into account the number of connecting points and / or the yarn breaks of the yarn contained on the respective supply bobbin. For example, it would be conceivable to rewind a supply reel with a number of connection points lying above a limit value or at thread windings at a winding station, which is known to produce a relatively small number of thread breaks compared to the other winding units during the rewinding operation. In this way, the total number of joints (number of joints of the yarn contained on the supply spool plus number of joints created during rewinding due to yarn breaks) per receiver coil can be kept below a tolerable limit. In return, it would be possible to have a supply spool with relatively few connection points or thread benders. Chen (ie with a number of joints or thread breaks, which is below a threshold value) to rewind at a winding station, which is known to produce a relatively high number of yarn breaks compared to the other winding units during the rewinding process.

It may also be useful to distribute the supply spools on individual winding units due to the already described thread-specific parameters. For example, the rewinding of a supply spool with a thread whose strength is below a defined limit would make sense at a winding station, which is known to produce relatively few thread breaks. In general, it should be made clear at this juncture that the named connection points do not necessarily have to be connection points of two thread ends. Likewise, the term "connection point" is understood to mean a so-called piecing (that is to say a connection point between a thread end and the individual fibers introduced into a spinning rotor, for example, on a rotor spinning machine).

The number of connection points or yarn breaks of a supply spool (or other individual coil data, such as data, which individualize the winding unit, which has produced the supply spool or thread-specific characteristics) can for example on the spool itself in the form of z. B electronic identifications (eg RFID chips) be deposited. The yarn breaks at the respective winding station are preferably also detected by means of a sensor, so that the total number of connection points of the wound on the receiver coil thread is always known.

It is likewise advantageous if the supply spools are assigned to the individual winding stations, taking into account the current degree of spillover of the respective receiver spool and / or the number of connection points of the thread already wound on the respective receiver spool. For example, the rewinding of a supply spool with a number of connection points lying above a limit value or at yarn breaks make sense at a winding unit, the receiver coil already has a diameter above a reference value in particular relatively small number of connection points (usually several supply coils are rewound on a receiver coil). It would also be conceivable to rewind such a supply spool onto a receiver spool with a still relatively low spooling level. Such a receiver coil is still relatively quick to stop and restart in comparison to a relatively full coil due to their lower mass, so that the time required for the correction of yarn breaks total time can be minimized. In return, a supply spool with a low number of connection points (or a small number of thread breakages) should be assigned to a winding unit whose receiver spool either already has an already above a threshold Bespulungsgrad or based on their diameter lying above a limit total number of connection points. As a result, the total number of junctions of a fully-wound receiver coil can be kept within certain limits by the appropriate allocation of matching supply coils, so that the quality of all receiver coils corresponds to the specifications.

Particular advantages arise when the rotational speeds of the respective drives can only be regulated within predefined limit values, with the limit values for all drives being defined and / or modified uniformly or separately for each drive. For example, it is conceivable that the same minimum and maximum speeds for the individual drives (eg, electric motors) are specified for all the winding stations for rewinding a yarn of type XY. This ensures that the speeds at individual spinning stations can not be regulated to arbitrarily high or low values. On the contrary, limits are defined which are known to result in a deterioration of the thread quality during rewinding when exceeding or falling below these limits. The speeds of the individual drives can thus be measured on each winding However, the control and / or regulating unit avoids exceeding or falling below certain limit values.

In addition, it is advantageous if the limit values are individually determined at each winding station as a function of the coil-specific data, in particular as a function of the data identifying or characterizing the respective supply spool or characterizing the thread contained thereon. As a result, a particularly individual adaptation of the speeds is possible. So it would be conceivable, for example, that at some of the winding units a different type of thread is rewound than at the other winding units. The limit values could in this case be determined individually depending on the type of thread. Also, the variation of the limits for each winding unit is possible individually. For example, it may be useful to reduce the maximum limit of the speed at a winding station, if this winding unit is supplied to a supply spool from a spinning station of the upstream spinning machine, which is known to produce a thread with relatively low strength. The corresponding data are either entered manually into the control and / or regulating unit or detected by a corresponding sensor (which detects, for example, the origin of the supply spool) before rewinding.

Basically, it should be noted at this point that the term control and / or control unit either a central unit of the winder is to understand, which adapts the rotational speeds of the drives at the individual winding units individually to various factors. Alternatively, it is of course also possible that the control and / or regulating unit consists of subunits, which are assigned either to a group of winding units or in each case only a single winding unit. In turn, the respective subunits can work independently or be linked to one another in order to specify general specifications valid for all drives (such as, for example, the maximum and minimum permissible rotational speeds). Specify penden specific.

It is advantageous if the rotational speed during rewinding is individually controlled at each winding station, taking into account the data of the individual bobbins, in particular the data identifying or characterizing the respective supply bobbin, or characterizing the thread contained thereon. In this way, it is possible to optimize the effectiveness of the individual winding units during rewinding separately from the other winding units and also continuously. The maximum speeds at which the yarn breakage rate is just below a certain tolerable limit can be stored in a database for each winding unit in conjunction with corresponding characteristics of the coils or the type of thread and at a later date (to which a comparable thread rewound or a already known supply coil of the winding unit is supplied) can be retrieved again.

The winding machine according to the invention is finally distinguished by the fact that it has a control and / or regulating device which is designed to operate the winding machine according to one or more of the preceding aspects. With regard to the respective features or their advantages, reference is made to the previous description.

It is particularly advantageous if at least the majority of the winding units each have a separate drive, wherein the individual drives are each in operative connection with a control and / or regulating device, and wherein the control and / or regulating device is designed, the rotational speeds to regulate the individual drives individually. In particular, it is provided that the winding machine can be operated according to the method described so far, wherein the respective aspects can be implemented individually or in (as far as is technically feasible) any combination. In particular, it is advantageous if at least the majority of the winding stations each comprise a sensor for detecting a yarn break at the corresponding winding station. The control and / or regulating device (comprising only a central unit or comprising several units of the winding unit) is also advantageously designed to increase the speed of the drive of this winding unit if the number of yarn breaks detected per unit of time falls below a minimum value and the speed to reduce this drive when the number of said thread breaks per unit time exceeds a maximum value. This creates a control loop that allows optimization of the effectiveness of the respective winding unit.

It is likewise particularly advantageous if at least the majority of the winding stations each comprise one or more sensors for detecting the yarn-specific parameter (s) mentioned. The control and / or regulating device should in this case be designed to individually increase (or reduce) the rotational speed of the drive of the corresponding winding unit if the measured value transmitted by the sensor is outside a predetermined range. With regard to the possible thread-specific parameters, reference is made to the previous description, the list is not exhaustive.

Likewise, it brings advantages when the control and / or regulating device is designed to operate the respective drives at start and / or after an interruption of a rewinding operation with a defined and preferably uniformly defined for all drives initial speed. In general, it is therefore assumed that the basic conditions at all winding units should be the same. Only when the control and / or regulating unit recognizes during the rewinding of individual threads that the productivity (ie the length of the per unit rewound thread) or the yarn break rate varies at individual winding units, a winding unit individual optimization of the winding process is necessary. Here, the speeds of the individual drives in the course of Umspulvorgangs be adjusted independently of the speed of the other drives, in which case one or more thread-specific characteristic (s) or coil and / or winding individual data can be considered.

Finally, it is extremely advantageous if at least the majority of the winding units have a sensor for detecting coil-individual data, in particular in the form of data identifying or characterizing the respective supply bobbin or characterizing the yarn contained thereon, and the control and / or regulating device is designed, determine the initial speed of the respective drives individually based on the data transmitted by the respective sensor. In this way it is already avoided from the beginning of the rewinding process that excessive thread breakages occur due to excessive winding speeds. However, too low initial speeds can be avoided if the above data is taken into consideration individually or in combination. The data may eventually be retrievable from a database to allow rapid adaptation of the initial speeds to a particular reel, a particular type of thread or the spinning station that has reeled the corresponding supply reel.

Further advantages of the invention are described in the following exemplary embodiments. Show it:

Figure 1 is a schematic view of a winding unit of a winding machine according to the invention, and

Figure 2 shows a time course of the rotational speed of a drive a

 Winding station in comparison to the time course of the yarn breakage rate.

1 shows a schematic view of a winding unit 1 of an inventive according to the present invention (in which only the components relevant for the following description are shown).

In principle, a corresponding winding machine (which preferably has a plurality of juxtaposed and generally similar winding units 1) is used when rewinding threads. Thus, for example, a thread 3 produced on a ring spinning machine is wound on the corresponding spinning station of the ring spinning machine on a spool whose capacity is generally relatively low. In order to simplify the further processing or the transport of the produced threads, it is known to rewind the threads of several of said coils onto a larger coil with a higher capacity. Also, by rewinding, the position of the thread 3 on the spool core or also the shape of the finished spool (as seen in FIG. 1) can be changed.

In any case, a yarn 3 is supplied to one of the winding stations 1 of the winding machine on a reel referred to below as a supply spool 2, which was produced for example by a spinning station of a ring spinning machine, to rewind the yarn 3 onto a receiver reel 4. For this purpose, supply spool 2 and receiver spool 4 are fixed, for example, on a rotatable shaft 10.

The thread 3 is brought by means of a corresponding auxiliary device (for example, a service robot or a Spulstelleneigenen thread handling device) or manually with the receiver coil 4 in contact. If this is then offset by a spool own drive 5 in a rotary motion, the withdrawal of the thread 3 from the supply spool 2 and at the same time winding of the withdrawn thread 3 to the receiver coil 4. The drive 5 of the receiver coil 4 can either directly via a compound of Drive 5 with the coil body bearing shaft 10 done. Alternatively, the receiver coil 4 can also be provided by frictional engagement between the thread surface and a drive unit 5 connected to the drive 5. Binding drive roller 9 done.

It is essential that the drive 5 is connected to a control and / or regulating unit 6, which is designed to vary the rotational speed U of the drive 5 of the respective winding unit 1 independently of the rotational speed U of the drives 5 of the remaining winding stations 1. The control and / or regulating unit 6 can either be designed as a winding machine-central unit which is in communication with the individual drives 5. Alternatively, each of the drives 5 may be connected to its own subunit, wherein the individual subunits together represent the control and / or regulating unit 6 in the sense of the present invention.

In addition, a thread changer 8 is usually present, which ensures a back and forth of the thread 3 on the surface of the receiver coil 4 during the rewinding operation and thus a uniform coil surface.

Finally, each of the winding units 1 has a sensor 7 for monitoring the thread 3, d. H. its presence in the region of the sensor 7 and / or one or more thread-specific characteristics (hairiness, width, etc.). It may also, as explained in more detail below, be advantageous if the winding unit 1 comprises a (for example, optical) sensor 12, with the aid of a label 1 1 of the coil can be detected, for example, data on the geometry of the supply spool 2, via the spinning station, which has spooled the supply spool 2 with the thread 3, or else data which permits unambiguous identification of precisely this delivery spool 2 (ie its spool core on which the thread 3 is wound).

On the basis of the data supplied by the sensor 7 and / or by the sensor 12, it is now possible to optimize the effectiveness of the respective winding unit 1 individually during the winding process, without this affecting the rotational speeds U of the drives 5 of the remaining winding stations 1. So For example, it is conceivable to monitor the yarn breakage rate F (ie the number of yarn breaks per unit of time) with the aid of the sensor 7. If the yarn breakage rate F is below a predetermined minimum value Mi, where would it be possible to increase the rotational speed U of the corresponding drive 5 and thus also the winding speed. On the other hand, if the yarn breakage rate F exceeds a defined maximum value Ma, it would be expedient to reduce the rotational speed U of said drive 5, in order to reduce the yarn breakage rate F in turn.

Exemplary profiles of the rotational speed U of a drive 5 at a winding station 1 in comparison to the yarn breakage rate F are shown in FIG. 2.

From the beginning of the rewinding the yarn breakage rate F is monitored. Decreases this (time ti) below a predefined minimum value Mi, the speed U of the corresponding drive 5 is increased by a certain amount. If the minimum value Mi falls below again, the rotational speed U and thus the winding speed can be increased again (t ₂ ). However, in order to prevent the rotational speed U from increasing too high a value by this type of self-optimization of the winding station 1 (which could result in a reduced quality of the yarn 3), it makes sense to set an upper limit value G1 for the rotational speed U equally apply to all winding units 1 (alternatively, it is of course also possible to set the limit G1 depending on the winding unit 1, the type of the supply spool 2, the individual properties of the supply spool 2, etc.). If the said limit value G1 is reached, no further increase in the rotational speed U occurs, even if the minimum value Mi of the yarn breakage rate F (t ₃ ) is undershot again. Analogously, what has been said also applies to a possibly existing lower limit value G2 (for reducing the rotational speed U, see times t ₄ and T ₆ ).

The specification of the limit values G1, G2, the change in the rotational speed U of the respective drives 5, or the initial rotational speeds A of the same can for example, on the basis of the data, which can be removed from a marking 1 1 of the supply spool 2, in particular with the aid of said sensor 12. The data may, for example, contain information about the spinning station at which the supply spool 2 was spooled with a thread 3. If, for example, from a corresponding database it is known that the spinning station XY produces a thread 3 of low strength, then the initial rotational speed A and also the upper limit G1 of the rotational speed U of the corresponding drive 5 can be reduced compared to predetermined standard values.

As a result, a winding machine and a method for operating the same are proposed, which enable individual optimization of individual winding stations 1. In particular, in this case, data of the spinning machine producing the thread 3 and winding onto the corresponding supply bobbins 2 can be taken into account in the regulation of the drives 5, so that the productivity of the winding machine can be significantly increased.

Incidentally, the invention is not limited to the illustrated embodiments. Rather, all combinations of the individual features described, as shown or described in the claims, the description and the figures and as far as a corresponding combination is technically possible or seems reasonable, the subject of the invention.

In particular, it may be advantageous, for example, if the winding machine is directly connected to an upstream spinning machine (eg in the form of a ring spinning machine) in order to forward data regarding the individual bobbins or the thread wound thereon from the spinning machine to the winding machine. The data can finally be taken into account in the distribution of the supply spools on the individual winding units or in the choice or adjustment of the speeds of the receiver coils at the individual winding units. LIST OF REFERENCES

1 winding unit

 2 delivery spools

 3 threads

 4 receiver coil

 5 drive

 6 control and / or regulating device

7 sensor

 8 thread changer

 9 drive roller

 10 wave

 1 1 marking

 12 sensor

U speed

 G1 upper limit

 G2 lower limit

 A initial speed

 Ma maximum value

 Mi minimum value

 F yarn break rate

t time

Claims

Patent claims

1 . Method for operating a winding machine with a plurality of

 Spooling points (1) for the respective rewinding of a thread (3) from a supply spool (2) to a receiver spool (4), the spooling points (1) each having a drive (5) associated with it, with the aid of which the individual receiver spools (4) a rotary motion are offset while the thread (3) withdrawn from the respective supply spool (2) is wound onto the corresponding receiver spool (4), characterized in that during operation of the spooling machine spool-individual data and / or at least one rewinding at each winding spool (1) individually monitored thread-specific characteristic is taken into account continuously in order to maximize the quality and / or time-related number of fully wound by the winder receiving coils (4).

2. Method according to the preceding claim, characterized in that at least the majority of the receiver coils (4) in each case by means of a separate drive (5) is driven, wherein the rotational speed (U) of the individual drives (5) by means of a control and / or control device (6) is controlled individually.

3. The method according to one or more of the preceding claims, characterized in that at least at the plurality of winding units (1) yarn breaks during the rewinding be detected and increases the speed (U) of the drive (5) of the corresponding winding unit (1) is, if the number of at this winding unit (1) detected thread breaks per unit time or rewound thread length below a minimum value (Mi) and the speed (U) of this drive (5) is reduced, if the number of said thread breaks per unit time or rewound thread length exceeds the maximum value (Ma).

4. The method according to one or more of claims 2 and 3,

 characterized in that the rotational speeds (U) of the individual drives (5) of the respective winding units (1) are changed individually, if the thread-specific parameters determined during rewinding are outside a predetermined range.

5. The method according to one or more of claims 2 to 4,

 characterized in that the respective drives (5) at start and / or after an interruption of a rewinding operation with a, preferably for all drives (5) uniformly, defined initial speed (A) are operated, and that the speeds (U) of the individual drives (5) in the course of the rewinding individually and preferably according to one of claims 3 and 4 or taking into account coil and / or winding unit individual data to be adjusted.

6. The method according to the preceding claim, characterized in that the coil-individual data, in particular in the form of the respective supply spool (2) identifying or characterizing or the thread contained on it (3) characterizing data are taken into account, the initial speed (A) of the respective Define drives (5) individually on the basis of the specified data.

7. The method according to one or more of the preceding claims, characterized in that the coil-individual data contain information about the spinning position of the spinning machine, which has produced the supply spool (2).

8. The method according to one or more of the preceding claims, characterized in that the coil-individual data Information about the number of joints and / or the thread breaks of the thread contained on the spool (3), the distribution of the joints or thread breaks over the length of the wound thread (3) or the diameter of the coil, the thread material and / or more thread-specific parameters, such as the hairiness, rotation and / or the strength of the thread (3) included.

9. The method according to one or more of the preceding claims, characterized in that the supply spools (2) the individual winding units (1) taking into account the coil-individual data, in particular taking into account the number of connection points and / or the thread breaks of the respective supply spool ( 2) contained thread (3) can be assigned.

10. The method according to one or more of the preceding claims, characterized in that the supply spools (2) the individual winding units (1) taking into account the current Bespu- tion of the respective receiver coil (4) and / or the number of connection points of the respective Receiver coil (4) already wound up thread (3) are assigned.

1 1. Method according to one or more of the preceding claims, characterized in that the rotational speeds (U) of the respective drives (5) can be regulated only within predefined limit values (G1; G2), the limit values (G1; G2) for all drives (5 ) uniformly or separately for each drive (5) and / or modified.

12. Method according to the preceding claim, characterized in that the limit values (G1; G2) are determined as a function of the coil-individual data, in particular as a function of the respective voltage. Spool (2) identifying or characterizing or the yarn contained on it (3) characterizing data to be set individually at each winding unit (1).

13. The method according to one or more of the preceding claims, characterized in that the rotational speed (U) during rewinding in consideration of the coil-individual data, in particular the respective supply spool (2) identifying or characterizing or the yarn contained on it (3) characterizing data , is individually controlled at each winding unit (1).

14. Winding machine with a plurality of winding units (1) for each rewinding of a thread (3) from a supply spool (2) on a receiver spool (4), wherein the winding units (1) is associated with a respective drive (5) to the individual To enable reciprocating coils (4) in a rotary motion and thereby allow an individual winding of the withdrawn from the respective supply spool (2) thread (3) to the corresponding receiver coil (4), characterized in that the winder a control and / or Control device (6) which is designed to operate the winder according to one or more of the preceding claims.

15. Winding machine according to the preceding claim, characterized in that at least the plurality of winding units (1) each have a separate drive (5), wherein the individual drives (5) with the control and / or regulating device (6) are in operative connection , and wherein the control and / or regulating device (6) is designed to regulate the rotational speeds (U) of the individual drives (5) individually.

16. Winding machine according to the preceding claim, characterized in that at least the plurality of winding units (1) each have a sensor (7) for detecting a yarn break at the corresponding the winding unit (1), wherein the control and / or regulating device (6) is adapted to increase the speed (U) of the drive (5) of this winding unit (1), if the number of at this winding unit (1) de - Tected thread breaks per unit time a minimum value (Mi) falls below and to reduce the speed (U) of this drive (5) when the number of said thread breaks per unit time exceeds a maximum value (Ma).

17. Winding machine according to one or more of claims 14 to 16, characterized in that at least the plurality of winding units (1) each comprise a sensor (7) for detecting the thread-specific characteristic, wherein the control and / or regulating device (6) is formed is to change the speed (U) of the drive (5) of the corresponding winding unit (1) individually if the measured value transmitted by the sensor (7) is outside a predetermined range.

18. Winding machine according to one or more of claims 14 to 17, characterized in that the control and / or regulating device (6) is formed, the respective drives (5) at start and / or after an interruption of a rewinding with a defined and Preferably for all drives (5) uniformly defined initial speed (A) to operate and the speeds (U) of the individual drives (5) in the course of Umspulvorgangs regardless of the speed (U) of the other drives (5) and preferably according to one of the claims 3 and 4 or taking into account coil and / or winding unit individual data.

19. Winding machine according to the preceding claim, characterized in that at least the plurality of winding units (1) via a sensor (12) for the detection of coil individual data, in particular in the form of the respective supply spool (2) identifying or characterizing or the thread contained thereon (3 ) characterize- the data, and the control and / or regulating device (6) is designed to set the initial speed (A) of the respective drives (5) individually based on the data transmitted by the respective sensor (12).