EP0417599B1 - Method and apparatus for transferring a yarn to a winding station of a textile machine - Google Patents

Description

The invention relates to a method for transferring a thread into the normal thread run at a winding point of a textile machine after a thread interruption, the thread after establishing the thread connection between the thread supply point and the package from a thread transfer of a device restoring the thread path into its normal thread running position to one - And hereby passing thread guide at the winding station, as well as a device for performing the method.

In addition to winding machines, textile machines with winding units are also, for example, open-end spinning machines, air spinning machines or twisting machines. If the thread run is interrupted on one of these machines, it must be restored on winding machines by connecting the lower thread to the upper thread. This can be done by splicing or by knots. In the case of spinning machines, a thread is fed to the spinning station and spun there again.

Establishing a thread connection to the thread delivery point by splicing, knotting or re-spinning at a spinning point usually takes place outside the normal thread path.
In winding machines, the thread connection is in a knot or Splicing device restored at the winding unit itself or in a device that moves back and forth in front of a large number of winding units and carries out corresponding service work. In the case of open-end spinning machines, re-spinning is usually carried out with the help of a so-called piecing carriage, which serves a large number of spinning positions.

If the thread connection between the take-up spool and the thread delivery point is restored, the thread must be returned to its normal thread running position. In the case of winding machines, the thread is removed from the knot or splicing element and handed over to the thread guide for placement on the bobbin. In open-end spinning machines, the spun thread is transferred from the piecing device of the piecing carriage to the take-off rollers of the spinning station and the thread guide.

From DE-PS 26 20 805 a method and an apparatus for piecing a thread on an open-end spinning machine are known. In the patent, a program is presented that controls all processes of re-piecing. When the thread run is restored, thick spots can form on the take-up spool, which reduce the quality, that is to say deteriorate the running behavior of the package.

It is therefore an object of the invention to propose a method for transferring the thread in which there are no quality reductions which impair the running behavior of the bobbin. Furthermore, a device for carrying out this method is to be presented.

This object is achieved according to the invention by the method which is characterized by the features of claim 1. The method according to the invention is carried out with the aid of the device according to the invention.

The production of a thread connection and the subsequent transfer of the thread into the normal thread run at a winding point and the traversing movement of the thread guide to which the thread is to be transferred have hitherto been carried out completely separately, without one process being coordinated with the other. The resulting faults in the thread layers can be effectively avoided if the production of the thread connection and the traversing movement of the thread guide are monitored over time and if, depending on this, the transfer movement of the thread transfer device and the traversing movement of the thread guide are coordinated so that the thread and the thread guide essentially arrive at the transfer point of the thread at the same time. If the traversing movement of the thread guide is monitored, it is advantageously possible to be able to precisely predetermine the temporal course of the movement of the thread guide and, depending on this, to control the movement of the thread transfer device to the transfer point.

It is ideal if the thread and thread guide arrive at the transfer point in time. Since such an ideal setting can only be achieved with great effort, it is sufficient to carry out the idea according to the invention that the thread guide and thread arrive essentially simultaneously at the transfer point, i.e. the thread may arrive slightly before the thread guide, but not after Thread guide.

A thread transfer that is coordinated with one another in this way can only take place if both the traversing movement of the thread guide and the production of the thread connection are monitored over time. For this purpose, sensors can be installed at the reversal points as a means of monitoring the movement of the thread guide, which send out pulses when the thread guide reaches them. The thread guide needs the time that elapses between the impulses to go there and back. After It is therefore advantageous to send out an impulse in which direction the thread guide is moving and what time will pass before it arrives at its second reversal point. In addition, the time that has elapsed since the last pulse was sent can be used to determine the respective position of the thread guide that the thread guide is currently occupying. The times of the respective back and forth movements of the thread guide are recorded, stored and added up.

To ensure that the movements of the thread guide and thread feeder can be coordinated, the production of the thread connection must also be monitored beforehand. The times required for the production of a thread connection by piecing or by splicing are fixed if these operations are carried out by automatic devices, which is usually the case. Due to the times for carrying out the thread connection, which are predetermined by mechanical means, for example cams, or electronic means, for example pulse generators, the point in time at which a thread connection is established and the thread is taken over by the thread transmitter can be calculated and foreseen. From this point in time at the latest, the thread must be handed over to the thread guide quickly, so that there are no waiting times and therefore winds on the bobbin which impair the quality of the thread and thus later the unwinding behavior.

For the transfer movement of the thread transfer device to the transfer point of the thread, a time will also be fixed which corresponds to a very specific number of pulses. The thread feeder is therefore only set in motion when the time available for the thread guide to arrive at the transfer point is just as long as the time it takes for the thread feeder from its starting point to the transfer point. With the help of monitoring the thread guide and monitoring the production of the thread connection it is advantageously possible to initiate the thread transfer only when it has been ensured that the thread guide and the thread arrive essentially simultaneously at the transfer point and thus there are no waiting times for the thread. The thread is gripped directly by the thread guide and the thread is inevitably deposited on the spool in accordance with the traversing movement of the thread guide.

For carrying out the method, it is advantageous if the thread is always transferred to the thread guide at the same transfer point. As a rule, this will already be the case if the thread is handed over by means of a device installed at the respective winding unit or a walkable service facility. If the handover of the thread always takes place at the same handover point, the time which the thread guide needs to reach the handover point can be determined in advance.

It is also advantageous for the method if the transfer point is at a short distance from a turning point of the thread guide. If the thread guide takes hold of the thread, this is usually jerky because the thread guide has a high speed. The thread is already deflected in front of the reversal point and it only travels a short distance to the reversal point of the thread guide, so that the additional tensile load acting on the thread only acts briefly at the time of transfer.

The method according to the invention for transferring the thread is to be explained in more detail with the aid of a flow chart. For this, three constellations of thread to thread guide have been selected.

UKPl

= Umkehrpunkt links

UKPr

= Umkehrpunkt rechts

I_l, I_r

= Impulsabgabe durch Registrierung des Fadenführers in den jeweiligen Umkehrpunkten

Ü

= Übergabepunkt

X

= Fadenverbindung wiederhergestellt

B

= Beginn der Fadenübergabe

B′

= Fadenübergabe nicht möglich

T_ff

= Zeit für einen Hin- und Hergang (Doppelhub) des Fadenführers

n

= Anzahl der Hin- und Hergänge des Fadenführers (ganzzahlig), (im Ausführungsbeispiel ist n = 1)

t_imp

= seit der letzten Impulsabgabe verstrichene Zeit

t_w

= Wartezeit bis zum Beginn der Fadenübergabe

t_ü

= für die Übergabe des Fadens erforderliche Zeit

In dem Ablaufdiagramm nach Fig. 1 sind die Funktionsabläufe bei der Übergabe des Fadens an den Fadenführer auf einer waagerecht verlaufenden Zeitachse aufgetragen. Die Funktionsabläufe beginnen zum Zeitpunkt T_ff = 0. Zu diesem Zeitpunkt ist der Fadenführer am linken Umkehrpunkt UKPl, wo von einem Mittel zur Überwachung der Changierbewegung des Fadenführers, beispielsweise einem optischen Sensor, ein Impuls I_l abgegeben wird. Damit werden in der Steuereinrichtung der Textilmaschine Mittel zum Erfassen und Speichern der Zeiten für die Hin- und Herbewegung des Fadenführers aktiviert, beispielsweise eine Uhr, welche die Zeit für den Ablauf eines Hin- und Hergangs des Fadenführers oder eine ganzzahlige Anzahl vom Vielfachen eines Hin- und Hergangs des Fadenführers mißt, das heißt, bis daß der Fadenführer wieder nach einmaligem Hin- und Hergang oder nach dem vorgegebenen ganzzahligen Vielfachen denselben Sensor wieder erreicht. Im vorliegenden Beispiel soll n = 1 sein. Diese Annahme vereinfacht die Erläuterung des Ablaufdiagramms.The flow chart is shown in FIG. 1. The following symbols and designations are used in this flow chart:

UKPl

= Reversal point on the left

UKPr

= Reversal point on the right

I _l , I _r

= Pulse delivery by registering the thread guide in the respective reversal points

Ü

= Transfer point

X

= Thread connection restored

B

= Start of thread transfer

B ′

= Thread transfer not possible

T _ff

= Time for a return movement (double stroke) of the thread guide

n

= Number of back and forth movements of the thread guide (integer), (in the exemplary embodiment n = 1)

t _imp

= elapsed time since the last pulse

t _w

= Waiting time until the thread transfer begins

t _ü

= time required for handing over the thread

In the flowchart according to FIG. 1, the functional sequences when the thread is transferred to the thread guide are plotted on a horizontal time axis. The functional sequences begin at time T _ff = 0. At this time the thread guide is on Left reversal point UKPL, where a pulse I _{l is} emitted by a means for monitoring the traversing movement of the thread guide, for example an optical sensor. This activates means in the control device of the textile machine for recording and storing the times for the to-and-fro movement of the thread guide, for example a clock, which measures the time for the back and forth movement of the thread guide or an integer number of multiples of a return. and the course of the thread guide measures, that is, until the thread guide reaches the same sensor again after a single round-trip or after the predetermined integer multiple. In the present example, n = 1. This assumption simplifies the explanation of the flow chart.

After the thread guide has gone back and forth after having passed the reversal point on the right (UKPr), he returns to the left reversal point. At this point the time T _{ff has} passed. The thread guide triggers another pulse I _l .

For the first example of a thread transfer:
Even before the thread guide has reached the reversal point on the right (UKPr), the thread connection is restored at time X and the thread is ready to be handed over to the thread guide. Up to this point is the time for a back and forth movement of the thread guide, T _ff, the time t _imp elapsed. The time t _ü , the time required for the transfer of the thread to the thread guide, is machine-related and is determined by the mechanical processes during the transfer. So it is not variable.

The transfer point was placed in the reversal point on the left (UKPl) to simplify the description of the flow chart. The thread should only be transferred if the thread guide is at the reversal point on the left.

Since the control device for transferring the thread in addition to the clock also has a computer for determining the time remaining during one or a multiple of a back and forth of the thread guide until the transfer point is reached, the point in time B at which the Handover of the thread must be initiated. From the point in time X at which the thread connection is reestablished, a waiting time t _w now passes until the thread transfer begins at the point in time B. From this point in time, the transfer time t _ü determined by the mechanical sequence for the thread to be transferred to the transfer point and the transfer takes place the thread guide.

The condition for the transfer of the thread still being able to take place within the time T _ff for a return and return of the thread guide is that t _{imp is} smaller than the difference from the time for a return and return or n times Number of trips of the thread guide to and from and the transfer time.

The second case shows the ideal condition for the transfer of the thread to the thread guide. At the point in time X at which the thread connection has been reestablished, the thread guide has exactly as long a time until the transfer point is reached as is required for the thread to be transferred. In this case, the time X at which the thread connection has been reestablished and the time B at which the thread transfer begins match. There is therefore no waiting time t _w . The prerequisite for this ideal case is that the time that has elapsed since the last pulse was given is equal to the difference between the time for a return trip or a multiple of this time and the transfer time.

The third example relates to the case where the thread connection is restored at a point in time X at which the time which remains for the thread guide until the reversal point is reached is less than the time required for the thread to be transferred. In this case, the time that has elapsed since the last delivery of the pulse is greater than the difference between the time for a return trip of the thread guide or a multiple thereof and the time required for the thread transfer. If the remaining time is shorter than the time required for the transfer of the thread, the next pulse is first waited for. The waiting time thus extends beyond the subsequent pulse until time B, at which the time remaining for the thread guide until the transfer point has been reached corresponds to the time required for the thread transfer. Only at this point in time, i.e. only after the subsequent impulse, does the thread transfer begin.

During the waiting time t _w , the thread must not be wound onto the package, because otherwise a thick spot will appear on the package due to the missing traversing movement. In the case of winding machines, the easiest way to bridge the waiting time is because during this time only the withdrawal of the thread from the thread delivery point has to be stopped. In the case of spinning machines, measures must be taken to prevent thread delivery during the waiting time t _w . One possibility is to interrupt the fiber feed into the spinning station and stop the thread take-off. Another possibility is to delay the fiber feed for the formation of the piecer until the waiting time t _{w has} elapsed. During the waiting time, no thread may be drawn from the spinning station either.

Particularly in the case of open-end spinning machines, the ideal state should therefore be sought, as is the case in the second case according to FIG. 1. The one needed to make a piecer The time and the transfer of the thread to the thread feeder are precisely determined due to the automation and the mechanical processes. They only depend on the yarn parameters to which the piecing mechanism can be adjusted. These times can be stored in a memory of a control device of the open-end spinning machine and can be called up if necessary. If, for example, a thread made of cotton of a certain thread number is spun on again, a very specific, fixed time is required from the return to the spinning position until the thread is drawn off and transferred to the thread transfer device. This time can be added to the transfer time t _ü , so that the waiting time no longer occurs between the production of the thread connection and the start of the transfer of the thread. The start of the production of the thread connection is already included in the timing. The production of the thread connection thus begins as a function of an impulse signal from the thread guide after a waiting time t _{w has} elapsed.

A device for carrying out the method according to the invention is explained in more detail using an exemplary embodiment. This device is installed on an open-end spinning machine, a rotor spinning machine. Irrespective of this exemplary embodiment, such a device can also be installed at each winding station of another textile machine.

Fig. 2

zeigt das Abziehen eines wiederangesponnenen Fadens durch die Anspinneinrichtung.

Fig. 3a

zeigt die Übergabe an die Abzugswalzen der Spinnstelle.

Fig. 3b

zeigt die Anspinneinrichtung und die Spule von oben, um den Fadenweg zu demonstrieren.

Fig. 4a

zeigt den Zeipunkt, an dem der Fadenlauf wiederhergestellt ist.

Fig. 4b

zeigt diese Situation in einer Ansicht von oben.

Fig. 5a

zeigt den Zeitpunkt der Fadenübergabe an den Fadenführer.

Fig. 5b

zeigt diese Situation in einer Ansicht von oben.

2 to 6 show the transfer of a thread to a rotor spinning machine in the various stages from the withdrawal of the thread from the spinning position by the piecing device to the takeover by the thread guide.

Fig. 2

shows the withdrawal of a re-spun thread by the piecing device.

Fig. 3a

shows the transfer to the take-off rollers of the spinning station.

Fig. 3b

shows the piecing device and the bobbin from above to demonstrate the thread path.

Fig. 4a

shows the point at which the thread path is restored.

Fig. 4b

shows this situation in a top view.

Fig. 5a

shows the time of thread transfer to the thread guide.

Fig. 5b

shows this situation in a top view.

2 shows the spinning station of a rotor spinning machine and the associated winding station and is designated by 1. The piecing device 21 is positioned opposite the spinning and winding unit. Only those parts of the rotor spinning machine are shown which contribute to an understanding of the invention. For example, it is not shown how the piecing device is arranged to be movable on the machine frame.

At the spinning station 1, sliver 3 is introduced into the spinning box 2. It is dissolved in a manner not shown here by a dissolving set and sucked into the rotor 4, where it is spun in a known manner into a thread 5a, which is drawn out of the spinning box through the thread take-off tube 6.

In the present exemplary embodiment according to FIG. 2, the normal thread run to the package 7 was interrupted. The thread connection between the bobbin and the spinning station was restored by the piecing device 21. The thread must now be transferred to the normal thread running position. The thread 5a runs onto the package 7 to be wound, which is carried by the bobbin holder 8. The coil holder 8 is in his Swivel joint 9 pivotally mounted on the machine frame of the open-end spinning machine. In normal winding operation, the bobbin 7 rests on the drive roller 10 and the thread is deposited on the bobbin in crosswise positions by means of the thread guide 11. The traversing movement of the thread guide 11 takes place with the help of the thread guide rod 12. This runs over the entire length of the machine and carries all thread guides of the individual winding stations and is driven centrally. However, an individually driven thread guide is also possible. Whether the thread guide is driven centrally via a thread guide rod or individually by a single drive means no difference for the implementation of the method according to the invention. With a central drive of the thread guide via a thread guide rod along the entire machine, as is the case, for example, with rotor spinning machines, the thread guide need only be observed at a single spinning position.

During the spinning process, the thread must be pulled off the spinning position. This is done by the take-off device, which consists of a driven take-off roller 13 and a pinch roller 14. The take-off device is arranged above the spin box 2, above the thread take-off tube 6. The pinch roller 14 sits at the end of a pivot lever 15 which is mounted in a pivot point 15a. The pivot lever 15 can be pivoted so that the pinch roller 14 is lifted off the take-off roller 13 and releases the thread so that it is no longer pulled off the take-off roller.

The presence of the thread is checked by means of a thread monitor 16. It consists of a pivotable thread monitor wire 17 and a contact 18. If the thread is wound on the package 7, it is under tension during the bobbin travel and lifts the thread monitor wire 17 from the contact 18. In the event of a thread breakage and consequently the absence of the thread, the thread monitor wire 17 falls on the contact 18 the thread break is reported to a control device 39 via the signal line 19. This then stops the fiber sliver 3 from being drawn into the spin box 2 via a signal line 40, so that no new thread can be spun. At the same time, the bobbin holder 8 is pivoted up so far via a signal line 41 via a device not shown here but known from the prior art that the cross-wound bobbin 7 is lifted off the drive roller 10.

At the same time, a signal is given to the piecing device 21 via the signal line 38 and the piecing device 21 is thus ordered to produce a new thread connection to the disturbed spinning station.

The piecing device 21 comprises all the devices required for the piecing process of the thread, the restoration of the thread connection and its transfer to the spinning position in the normal thread running position. These devices are known from the already mentioned patent DE 26 20 805. For this reason, only the facilities required for the transfer of the thread into its normal thread running position are shown and explained in more detail.

After the thread connection has been restored by the piecing device 21, the thread 5a must first be removed from the piecing device itself. The taut thread 5a is pulled out of the spin box 2 by means of a take-off device on the piecing device 21, consisting of the take-off roller 26 and the pinch roller 27. As soon as the take-off roller 26 rotates in the take-off direction of the thread, which is reported to the control device 33 via the signal line 26b , the thread connection is considered established. This is the point in time which is designated by X in the flowchart according to FIG. 1. The control device calculates the time remaining until the thread guide arrives at the transfer point.

The thread transmitter 29 must now remain in the position shown in FIG. 4b until the time t _{w has} elapsed in accordance with the flow chart according to FIG. 1. The waiting time is communicated to the control device 33 via the control device 39. During this time the thread delivery must be interrupted. The interruption of the thread delivery can be omitted if, as already mentioned, the production of the thread connection and the thread transfer take place sequentially in time and the time for the thread connection, the time for the spinning, and the transfer time are added. The start of the piecing is then started by the control device on a pulse triggered by the thread guide, possibly taking a waiting time into account beforehand.

1, the thread transfer begins, which, as already mentioned in the description of the flow chart according to FIG. 1, comprises a technically determined, precisely defined time t _u . During this time, the thread transfer device 29 pivots in the direction of the transfer point 44 and places the thread guide 11 in the direction of the thread guide 11 which is brought up to the reversal point 42 (FIG. 5b).

Since the package 7 is lifted from its drive roller 10, it is driven by the piecing device 21 to wind up the thread. This has a drive arm 22 which is rotatably mounted on the piecing device in a swivel joint 23. At the head of the drive arm 22 there is a drive roller 24 which is driven by a chain drive 25. The drive is not shown here and is controlled by the control device 33 of the piecing device 21 via a signal line 23a. If the cheese 7 is to be driven by the piecing device 21, the drive arm 22 rests on the cheese with its drive roller 24. Then over the chain drive 25 Drive roller 24 rotated in the direction of the arrow so that the thread is wound onto the package.

In Fig. 2 there is already a continuous thread connection 5a from the rotor 4 of the spinning box 2 to the package 7. The thread 5a is still drawn off the take-off roller 26 of the piecing device 21 and has already been transferred to the thread transfer device 29 to him to be handed over to the take-off device of the spinning station. For this purpose, the control device 33 in the piecing device 21 gives the signal to the take-off device via the signal line 28b to open the pinch roller 27. The pinch roller 27 is lifted off the take-off roller 26 by means of the pivot lever 28 about the pivot point 28a. Due to the thread tension, the thread takes the course 5b. It is now on the take-off roller 13 and the pinch roller 14 is pivoted to a signal from the control device 39 of the open-end spinning machine via the signal line 15b to the take-off device by means of the pivot lever 15 on the take-off roller 13. The take-off roller 13 is switched on via the signal line 13b. The take-off device of the spinning station is thus in operation and pulls the thread out of the thread take-off tube. The take-off speed corresponds to the take-off speed during the normal spool travel.

In order to transfer the thread back into its normal thread running position, the thread transfer device 29 swivels under the tension of the thread in the direction of the spinning position. The cheese 7 is driven via the drive arm 22 at an increased speed in order to use up the thread reserve resulting from the piecing process.

This situation is shown in Fig. 3a. The thread takes the thread course 5b. It is drawn off at the spinning station 1 by the take-off device, take-off roller 13 and pinch roller 14 and wound onto the cheese 7 driven by the drive arm 22.

The thread pull causes the thread transfer device 29 to pivot about its pivot axis 30 against the force of the return spring 31. The return spring 31 serves on the one hand to return the thread transfer device 29 to its initial position and on the other hand it generates the thread tension that is desirable during the winding process during the transfer process.

In Fig. 3a, the thread transfer device 29 is on the way to transfer the thread into the normal thread running position. The thread transmitter 29 has already migrated away from its initial position in FIG. 2, in which the thread has been transferred to it. The movement of the thread transfer device 29 is registered by three sensors 34, 35 and 36 as a means for monitoring the feed movement. These sensors can be opto-electrical sensors, but other sensors, for example magnetic sensors, can also be used.

The starting position of the thread transmitter 29 (FIG. 2) is registered with the aid of the sensor 34 and reported to the control device 33 via its signal line 34a. If the thread transmitter 29 swivels out of the area of the sensor 34, this is also reported to the control device 33.

3b shows the thread transfer device from above. All parts that could impair the overview have been omitted from the piecing device 21 and the spinning station 1.

In its initial position, the thread transmitter 29 is pivoted back completely, so that the reflector 37 on the thread transmitter is directly opposite the opto-electrical sensor 34.

The pivot axis 30, about which the thread transmitter 29 is pivoted, is arranged obliquely to the bobbin axis. This avoids that the thread is always deposited at one and the same place on the bobbin during the thread transfer. The thread transfer to the thread guide always takes place in the direction of one of the reversal points of the thread guide. If the thread transfer device 29 now moves to the transfer point during the transfer of the thread to the thread guide, the thread is deposited next to one another on the cross-wound bobbin in parallel positions 71 due to the inclined arrangement of its pivot axis 30.

In the meantime, the thread guide 11 travels back and forth between its two reversal points, the reversal point 42 on the left and the reversal point 43 on the right. The two reversal points are marked by sensors as means for monitoring the traversing movement of the thread guide. These sensors can be influenced optically or magnetically. When a reversal point is reached, the thread guide covers the sensors with its flag 11a or 11b. The left sensor 42 is covered by the flag 11a when it reaches the left turning point. This signal is given to the control device 39 via the signal line 42a. If the thread guide reaches the right reversal point 43, his right flag 11b covers the sensor 43. This signal is also reported to the control device 39 via the signal line 43a. In Fig. 3b the thread guide is moving towards the right reversal point 43 in the direction of the arrow. Then its right flag 11b will cover the sensor 43, so that a signal is reported to the control device 39 via the signal line 43a.

On the basis of the signals received by the sensors, the control device 39 is able, with the aid of corresponding storage means, to record and store the times of a back and forth movement of the thread guide and to determine the direction in which the thread guide moves between two pulses emotional. In addition, the control device contains a computer which makes it possible to calculate the time remaining during one or a multiple of a back and forth movement of the thread guide until the transfer point is reached. The transfer point 44 is the point which the transfer roller 32 reaches to a maximum when the thread transfer device 29 transfers the thread to the thread guide 11.

Via the signal line 38, with which the control device 33 of the piecing device is connected to the control device 39 of the spinning station or the entire open-end spinning machine, the transfer sequence of the thread to the thread guide can be precisely controlled in time by exchanging the required data between the two control devices are so that it resembles one of those shown in Fig. 1 and described there. Both control devices can also be combined to form a common control device. This could, for example, be arranged centrally in the textile machine and connected to the individual spinning bobbins and the piecing device by control and signal lines.

It is particularly advantageous to start the production of the thread connection only when its time sequence together with the thread transfer result in a predeterminable time which begins on a pulse triggered by the thread guide, possibly taking into account a waiting time t _w .

4a and 4b, the reflector 37 of the thread transmitter 29 is located opposite the sensor 35. This is reported to the control device 33 via the signal line 35a. In addition, the control device 39 receives a pulse via the signal line 38, which informs this control device 39 of the following: the thread reserve created by the restoration of the thread connection has been used up. The winding of the thread must now be carried out at the winding speed specified by the drive roller 10. The control device 39 then causes the bobbin holder 8 to be lowered via the control line 41, so that the cheese 7 comes to rest on the drive roller 10. At the same time, the control device 33 causes the drive arm 22 to pivot back from the cheese 7 via the signal line 23a. The drive roller 24 is turned off.

5a and 5b show the point in time at which the thread has been transferred to the thread guide of the winding station in its normal thread running position 5c.

The transfer roller 32 on the thread transfer device 29 has reached the transfer point 44 after the transfer time t _ü has expired. The thread lifting wire has been caused to fold down by the control device 39 via the signal line 20a. The thread lifter wire 20 had previously prevented the thread from getting into the area of the thread guide 11 during the transfer. The thread lifter wire 20 now lies below the transfer roller 32. When the transfer roller 32 arrives at the transfer point 44, the thread lifter wire pushes the thread from the transfer roller and the thread falls into the area of the thread guide 11. This takes hold of the thread 5c, as shown in FIG 5b can be seen. The thread is taken along by the thread guide and executes its traversing movements. As a result, it is placed in the desired cross wrap.

The thread transmitter 29 is now in its most extreme swivel position. It is registered with the help of sensor 36. On the basis of its signal, the piecing device 21 is caused to withdraw the thread transmitter 29, to pivot the drive arm 22 back into its starting position and to switch off the chain drive 25. If these method steps have been carried out, the piecing device 21 can turn to a further spinning station which has a fault, for example a thread break.

Claims (7)

1. Method for transferring a yarn into the normal yarn path at a winding station of a textile machine after breaking of the yarn, in which case after establishing the yarn connection between the yarn delivery point 2 and the take-up bobbin 7 the yarn being transferred by yarn transfer means 29 of a device re-establishing the yarn path, in its normal yarn path position to a reciprocating yarn guide 11 at the winding station, characterized in that establishing the yarn connection and the traversing motion of the yarn guide 11 are monitored in timed sequence and that depending thereon the transfer movement of the yarn transfer means 29 and the traversing motion of the yarn guide 11 are coordinated with each other so that the yarn and the yarn guide 11 arrive substantially simultaneously at the transfer point 44 of the yarn.
2. Method according to Claim 1, characterized in that the transfer of the yarn to the yarn guide 11 is initiated when, during a reciprocating movement of the yarn guide 11, namely a double stroke, or a whole multiple of a reciprocating movement, the time remaining for reaching the transfer point 44 is equal to the time which is necessary for the transfer movement of the yarn transfer means 29 to the transfer point 44.
3. Method according to Claim 1 or 2, characterized in that the reciprocating movement of the yarn guide 11 is ascertained by means of sensors, that the sensors 42, 43 in this case emit pulses, that these pulses are used for ascertaining the time for a reciprocating movement as well as for ascertaining the direction of movement of the yarn guide 11 and that depending on a predetermined number of pulses, whereof the total duration must correspond to the time necessary for the movement of the yarn transfer means 29 to the transfer point 44, the transfer of the yarn by the yarn transfer means 29 to the transfer point 44 is initiated.
4. Method according to one of Claims 1 to 3, characterized in that the transfer of the yarn to the yarn guide 11 always takes place at the same transfer point 44.
5. Method according to one of Claims 1 to 4, characterized in that the transfer point 44 is located at a short distance in front of a reversing point of the yarn guide 11.
6. Apparatus for carrying out the method at a winding station of a textile machine according to one of Claims 1 to 5, characterized in that means 42, 43 are provided for monitoring the reciprocating movement of the yarn guide 11, that these means 42, 43 are connected by way of signal leads 42a, 43a to a device 39 for monitoring and processing the signals, in order in each case to ascertain the time still remaining for the yarn guide 11 until it reaches the transfer point 44, that a device 21 is provided for re-establishing the yarn connection between the take-up bobbin 7 and the yarn delivery station 2, which device 21 comprises yarn transfer means 29 and that means 33 for the timed coordination of establishing the yarn connection are provided, that the means 33 are connected by way of a signal lead 38 to the device 39 and that the transfer movement of the yarn transfer means 29 is initiated depending on the signals from the device 39.
7. Apparatus according to Claim 6, characterized in that the means 42, 43 for monitoring the reciprocating movement of the yarn guide 11 are pulse-emitting sensors.

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