EP0419828A1 - Method of running a spinning machine, in particular a ring spinning machine, and a service carriage for carrying out the method - Google Patents

Abstract

What are described are a method and a service carriage 12 for running a ring spinning machine 10, in which a check of the spinning stations 14 is conducted after each doffing operation by means of an integral doffer as to whether a spinning tube 18 has been slipped onto the respective spindle 16 or not. The position of the particular spinning tube is also checked in addition. If a spinning tube is absent or if the spinning tube slipped onto a particular spindle is not in the desired position, the roving stop device 26 of the respective spinning station 14 is actuated automatically. By means of the service carriage 12, in order to rectify a fault, only those spinning stations, the roving stop device 26 of which is not actuated, are operated. <IMAGE>

Description

The invention relates to a method for operating a spinning machine comprising a plurality of spinning stations, in particular a ring spinning machine, using an operating robot which can be moved along the spinning stations each having a drivable spindle for receiving a spinning sleeve and in particular ensures that a thread break at a relevant spinning station is eliminated. that the material to be spun supplied by a drafting system is rewound onto the spinning tube assigned to the spinning station, for which purpose in particular an auxiliary thread is wound on the spinning tube at one end and is attached to the other end to connect it to the material to be spun. The invention further relates to an operating robot according to the preamble of claim 13.

From US 4 640 088 an open-end spinning machine is known, in which the winding tube of a respective spinning station is held between two arms, which between a lower position, in which the winding tube is driven by a friction roller, and an upper one, of which Distributor roller position are pivotable. In response to a call signal from a respective spinning station, a movable control unit checks whether the arms are in the upper or the lower position and whether there is a winding tube between the arms. If these arms take up their upper position when the winding tube is missing, the automatic control unit first inserts a new winding tube before starting to attach it. The doffing takes place separately for the individual spinning positions as required.

A ring spinning machine is known from US Pat. No. 3,626,680, in which the upper delivery roller of the drafting system is checked by means of an automatic control unit to determine whether it is on it Roller has formed a wrap. If such a winding is found, the automatic control unit actuates the sliver clamping device of the relevant spinning station. The doffing takes place separately for the individual spinning positions as required.

In today's ring spinning machines, doffing takes place predominantly by means of a so-called integral doffing device, i.e. a device that removes all spinning heads from one machine side at the same time and replaces them with empty spinning tubes. With such a doffing process, common to all spinning positions of at least one machine side, it can now happen that an empty spinning tube is lost or the tube magazine of the doffer device has not been fully loaded.

This means that not all spindles of the ring spinning machine may be equipped with empty spinning sleeves. There is therefore a risk that a thread end in question is wound directly onto the spindle of a respective spinning station, which generally leads to a considerable disturbance in the normal operating sequence of the ring spinning machine.

The invention has for its object to further develop the method and the operating robot of the type mentioned in such a way that errors occurring during the doffing process are recognized reliably and in good time and even in the case of a faulty doffing process it is ensured that the winding is always carried out without errors.

The object is achieved according to the invention in that after each replacement of the spinning heads by empty spinning sleeves serving doffing and / or before each winding or attaching process by means of the operating robot automatically first A check of the spinning stations is then carried out to determine whether or not a spinning sleeve is attached to the respective spindle, that if the spinning sleeve is missing, a roving stop device assigned to the spinning station concerned is automatically actuated or this spinning station is deactivated and this is at least visibly signaled to the operating robot is, and that by means of the operating robot only yarn breaks at such spinning positions are always remedied, whose roving stop device is not actuated or which are not put out of operation.

Due to this design, it is achieved that only one spinning sleeve or one spinning cop is always wound on, and thus operational failures of the ring spinning machine caused by direct winding on the spindles are reliably excluded. This applies primarily to the case that errors occur during the common doffing process, in particular for all spinning positions on one machine side, which lead to the spindles of certain spinning positions not being equipped with empty spinning sleeves. If the operating robot detects such an error, the spinning position in question is deactivated, in particular by the fact that the associated roving stop device is actuated. As soon as the next pass, for example to correct the fault, the operating robot recognizes that the spinning station in question is out of operation, so that this spinning station is not operated. The invention is based on the knowledge that the detected error can not be remedied by the operating robot and overall more effective operation is achieved if the spinning station in question is temporarily put out of operation and the operating robot skips the relevant spinning stations until they in particular be put back into operation by an operator.

So that the spinning stations which are put out of operation by the operating robot can be put back into operation as quickly as possible after a corresponding error correction, the actuation of the respective roving stop device or the decommissioning of the respective spinning station is preferably also additionally signaled for the relevant operator in a recognizable manner. This can be done, for example, by means of a lever connected to the relevant roving stop device, which lever is particularly raised when it is actuated.

It can now happen that a spinning sleeve is present on a respective spindle, but this spinning sleeve is not completely placed on the spindle, so that the spindle is still exposed below the lower edge of the spinning sleeve and direct winding onto the spindle is still possible in this area is. In order to reliably exclude such a winding on the spindle in any case, it is advantageously provided that the spinning positions are additionally checked by the operating robot as to whether or not a spinning sleeve fitted to a respective spindle assumes a predetermined target position, and also in the case a spinning sleeve having a position deviating from the predetermined target position, the roving stop device assigned to the spinning station in question is actuated or this spinning station is put out of operation. Here it is checked, for example, whether a respective spinning sleeve is completely fitted onto the spindle, which is generally shorter than the spinning sleeve. Only if this is the case will the spinning station in question be used or started.

To check the presence of a spinning sleeve on the respective spindle, which is shorter in comparison to the spinning sleeve an area is scanned between the upper edge of the spindle and the upper edge of a spinning sleeve fitted onto the spindle and taking up the predetermined target position. It is assumed here that the spinning sleeve is plugged onto the spindle in question from top to bottom and, in its nominal position, sits with its lower edge, for example, on a flange connected to the spindle.

By expediently scanning an area immediately above the upper edge of the spindle, the spinning sleeves are reliably recognized even in a case in which these spinning sleeves are only slightly longer than the assigned spindle and accordingly only protrude slightly above the spindle.

To check the position of a spinning sleeve fitted onto a respective spindle, the position of the upper and / or lower edge of the spinning sleeve is preferably checked. After the two edges of the spinning sleeve are at a predetermined height in the target position, this height range can be scanned or checked for the presence of the relevant edge. In this way, for example, the presence of the spinning sleeve can also be checked at the same time. This means that it can only be rolled up or attached if the relevant edge of the spinning sleeve is at the respective predetermined height, for example the lower edge is seated on a flange connected to the spindle or the upper edge is at a predetermined distance from the upper edge of the spindle.

In particular, to check the position of a spinning sleeve attached to a respective spindle, the area immediately above the lower edge of a spinning sleeve attached to the spindle and taking up the predetermined position is advantageously scanned. For example the area immediately above a flange connected to the spindle, on which the spinning sleeve is seated with its lower edge in its desired position. If the lower end of the spinning tube enters this area, it has at least essentially already reached its target position, so that when the spinning tube enters this area, the presence of the target position is detected at the same time. In general, it is sufficient to scan this area so that a respective winding or attaching process is permitted even when the spinning sleeve end is detected in this area. On the other hand, however, it is also possible to separately check the presence of the spinning sleeve and its position.

In particular, when scanning within a range predetermined by the spindle length, the presence of a spinning sleeve on the respective spindle and / or the position of the spinning sleeve can be checked on the basis of the resulting diameter or cross-sectional difference.

If scanning is carried out within the range predetermined by the length of the spindle, the presence of a spinning sleeve on the respective spindle and / or the position of the spinning sleeve can advantageously also be checked by means of detectors which detect different materials and / or colors or the like of the spinning sleeve and spindle or address their surface differently.

During a first pass of the operating robot following at least a part of the spinning stations, only a check of the presence of the respective spinning sleeves and, if appropriate, their position is preferably carried out during a troubleshooting, during a troubleshooting, that is to say in particular a thread break repair, only during a subsequent one, in particular during the next one Continuity is carried out. During the first, on the Doffvor The following pass of the operating robot can already simultaneously detect the thread breaks that occurred during the doffing process and expediently store them. In the second pass, the yarn breaks of those spinning positions whose roving stop device is not actuated or which are not deactivated are then eliminated.

By checking the presence of a respective spinning sleeve and, if necessary, its position, any yarn residues present on the relevant spinning crown are advantageously removed at the same time. This preferably takes place again during the first pass of the operating robot following a doffing process, which is accordingly determined by a control, monitoring and cleaning function, while other functions of the operating robot are suppressed during this one-time run.

The operating robot according to the invention, which can be moved along the spinning stations, is distinguished by the fact that it comprises a device for checking the presence of a spinning sleeve on a respective spindle, a device for actuating a roving stop device and means for detecting an actuated roving stop device or a spinning station that has been deactivated. and that the device for actuating the roving stop device and the automatic thread applicator can each be controlled by the electronic control unit in such a way that the roving stop device is actuated in the absence of a spinning sleeve and that the automatic roving device only fixes a thread break present at those spinning stations whose roving stop device is not actuated or not except Operation are set.

The device for checking the presence of a spinning sleeve and / or the device for checking the position the spinning sleeve can, for example, be designed as a light barrier, the transmitter and receiver of which are preferably each arranged on the operating robot.

Preferably, the light beam of the light barrier, which is directed at least substantially perpendicular to the respective spindle axis A, intersects the spindle axis, this light beam reflecting in the absence of a spinning sleeve on the spindle or, in the case of a higher light barrier, on a reflector arranged above the spindle on the spinning machine, in particular a ring spinning machine spinning sleeve attached to the spindle is at least partially absorbed by the latter. The fact that the spinning sleeves generally consist of cardboard, paper, plastic or the like and the spindles usually consist of steel, aluminum or the like is particularly exploited.

According to another advantageous embodiment variant, the light beam of the reflection light barrier is offset radially outward with respect to the spindle axis or the spindle such that, in the absence of a spinning sleeve, the light beam passing laterally on the spindle reflects on a reflector arranged on the spinning machine, in particular a ring spinning machine, and on the Spindle attached to the spinning sleeve is at least partially absorbed by this.

The control unit of the operating robot can in particular be designed in such a way that during the first pass following a doffing operation not only checks the presence of a respective spinning tube and, if necessary, its position, but also expediently also detects the yarn breaks that occurred during the doffing operation. The thread breaks can be determined, for example, by monitoring the rotor rotation, as is described in particular in DE-OS 23 36 079. Furthermore, the zuver The suitability of the doffer can be monitored in particular by evaluating the thread breaks found.

Further advantageous embodiment variants of the invention are specified in the subclaims.

• Fig. 1 eine schematische Seitenansicht einer Ringspinnma­schine mit zugeordnetem Bedienroboter,
• Fig. 2 eine schematische Seitenansicht einer Spinnstelle der Ringspinnmaschine sowie des gegenüber dieser Spinnstelle positionierten Bedienroboters,
• Fig. 3 eine vereinfachte schematische Darstellung der Spin­del der Spinnstelle bei fehlender Spinnhülse sowie der zur Abtastung des Spindelbereichs dienenden Lichtschranken,
• Fig. 4 eine Figur 3 vergleichbare Darstellung, wobei je­doch eine Spinnhülse teilweise auf die Spindel auf­gesteckt ist,
• Fig. 5 einen Schnitt durch die Spindeljspinnhülsen-Anord­nung gemäß der Linie I - I in Figur 4, wobei der zur Abtastung verwendete Lichtstrahl der unteren Lichtschranke die Spindelachse schneidet, und
• Fig. 6 eine Figur 5 vergleichbare Darstellung, wobei je­doch der zur Abtastung verwendete Lichtstrahl der unteren Lichtschranke bezüglich der Spindelachse bzw. der Spindel radial nach außen versetzt ist.

The ending is explained in more detail below using exemplary embodiments with reference to the drawing; in this shows:

• 1 is a schematic side view of a ring spinning machine with an associated operating robot,
• 2 shows a schematic side view of a spinning station of the ring spinning machine and of the operating robot positioned opposite this spinning station,
• 3 shows a simplified schematic illustration of the spindle of the spinning station in the absence of a spinning sleeve and of the light barriers serving to scan the spindle area,
• 4 shows a representation comparable to FIG. 3, but with a spinning sleeve partially fitted onto the spindle,
• Fig. 5 shows a section through the Spindeljspinnhülsen arrangement along the line I - I in Figure 4, wherein the light beam used for scanning the lower light barrier intersects the spindle axis, and
• FIG. 6 shows a representation comparable to FIG. 5, but with the light beam of the lower light barrier used for scanning with respect to the spindle axis or the spindle is offset radially outwards.

A ring spinning machine 10 with a head part 48 and a foot part 50 is shown in a schematic side view in FIG.

A row of spinning stations 14 is provided between the head part 48 and the foot part 50 on both machine sides, of which only one can be seen. For example, 500-600 such spinning stations 14 can be provided on each machine side. In the present case, only seven of these spinning stations 14 are shown for the sake of simplicity. The distance between the head part 48 and the foot part 50 is actually much larger than shown.

At each of the spinning stations 14, roving 54 coming from a roving spool 52 is drawn in a drafting device 56 and the drawn yarn is wound onto a spinning tube 18 by means of a ring traveler 58. The resulting package 60 is built up in a known manner from below on the spinning sleeve 18 and results in the so-called spinning cop. For this purpose, the spinning sleeve 18 is driven by a spindle 16, on which it is attached. The drawn roving runs through a yarn sensor 62 and a so-called anti-balloon ring 64 to a ring traveler 58 which is caused to rotate on an annular path 66 due to the rotating movement of the spinning cop, whereby the drawn roving undergoes a rotation.

The spindles 16 are driven in pairs by belts 68 rotating in the direction of the arrow 70. The spindles 16 are rotatably mounted in a crossbar 72 of the ring spinning machine 10. In contrast, the ring tracks 66 are arranged on the so-called ring bench 74 which, in a manner known per se, forms a continuous stroke in order to form a respective spinning cop upward movement and this lifting movement is superimposed by an oscillating movement.

Before entering the drafting unit 56, the roving 54 runs through each of the spinning stations 14 through a funnel 76, which is mounted on a rail 78, which carries out an oscillating back and forth movement in the direction of the double arrow 80.

The roving 54 is then passed through a sliver or roving stop device 26. Such roving stop devices are generally known and are used to break off roving 54 and thus to interrupt the material supply to the subsequent drafting device 56.

The drafting device 56 is driven by three driven shafts 82, 84 and 86, which extend over the entire length of the ring spinning machine 10.

Arranged below each drafting device 56 is a suction nozzle 88 which, in the event of a thread breakage, sucks off the yarn supplied by the drawing device 56. At the first of the three spinning positions 14 shown on the right-hand side in FIG. 1, there is a thread break of this type, so that there the yarn is sucked off through the suction nozzle 88.

The ring spinning machine 10 is assigned an operating robot 12 which is guided along an upper guide rail 90 and a lower guide and positioning rail 92. This operating robot 12 can be moved in the direction of the double arrow 94 along the spinning positions 14 by means of a motor (not shown) flanged to the frame of the robot, which drives wheels 98 on the lower guide rail 92 (cf. also FIG. 2). The control robo ter 12 has further wheels running on the guide rail 66. Furthermore, a guide roller 100, which runs in the inverted U-shaped guide rail 90, is arranged at the upper end of the frame of the operating robot 12.

On the frame of the operating robot 12 there is also an automatic thread application device 20 (see FIG. 1) which can be moved up and down in accordance with the double arrow 102 with respect to the robot frame.

At the free end of an upper, obliquely downward arm 106, the operating robot 12 has a light barrier 104 which detects the yarn at the outlet of the drafting unit 56 and thus checks the relevant spinning station as to whether there is a thread break or not. In principle, other known thread break monitors can also be provided, for example inductive, capacitive or piezo thread break monitors.

As can be seen in FIG. 1, each roving stop device has a lever 108, which is pivoted upward for the respective operator when the device is actuated. At the free end of this lever 108 there is also a reflector 110 which cooperates with a light barrier 112 provided on the operating robot 12 (see FIG. 2), so that the operating robot 12 also recognizes whether a respective roving stop device 26 is actuated or not.

Both the automatic thread applicator 102 (see FIG. 1) and the light barriers 104 and 102 are connected to a preferably programmable electronic control unit 22 of the operating robot 12, which can have at least one microprocessor.

A light barrier 24 for checking the presence of a spinning sleeve 18 on a respective spindle 16 and a light barrier 28 for checking the position of a spinning sleeve 18 plugged onto a respective spindle 16 are also connected to this electronic control unit 22. These light barriers 24 and 28 are reflective light barriers, the transmitters and receivers of which are each arranged on the frame of the operating robot 12 and which are used to monitor the spinning station in the area of the spindle or the spinning sleeve with reflectors arranged on the frame of the ring spinning machine 10 40 and 42 cooperate in the manner described below.

A device 46 for actuating the sliver stop device 26 is also connected to the electronic control unit 22 via the lever 108 connected to it (see FIG. 1) and a device 44 for removing spinning residues on the spinning crowns.

In FIG. 2, the spinning sleeve 18 placed on the spindle 16 assumes its desired position, in which its lower edge rests on a flange 114 connected to the spindle 16.

The light beam 36, which serves to check the presence of a spinning sleeve 18 on the spindle 16, the light barrier 24 runs perpendicular to the spindle axis A and intersects (in the absence of a spinning sleeve) this spindle axis A. The light barrier 24 and thus the light beam 26 is arranged at such a height, that an area between the upper edge 30 of the spindle 16 and the upper edge 32 of the spinning sleeve 18 taking the desired position according to FIG. 2 is scanned. At the same height as and aligned with the robot-side light barrier 24, a reflector 40 is arranged on the frame of the ring spinning machine 10.

The light barrier 28 used to check the position of the spinning sleeve 18 plugged onto the spindle 16 in turn also has a transmitter and receiver, both of which are arranged on the outside of the frame of the operating robot 12. The light beam 38 of this light barrier 38 in turn runs perpendicular to the spindle axis A, with its extension intersecting the spindle axis A. This light barrier 28 and thus its light beam 38 is arranged at such a height that a region of the spindle 16 directly above the flange 114 connected to the spindle, on which the spindle is seated in its desired position, is scanned.

If the spinning sleeve 18 is missing or this spinning sleeve is not completely fitted onto the spindle 16, the light beam 38 strikes the metal spindle, where it is reflected back to the robot-side receiver. If, on the other hand, the spinning sleeve 18 assumes its desired position, as shown in FIG. 2, the beam 38 of the light barrier 28 hits the spinning sleeve 18, which is usually made of cardboard or the like, where it is at least partially absorbed.

3 to 5, the light barriers 24 and 28 are arranged in exactly the same way as in FIG. This means in particular that only the upper light barrier 24 interacts with a machine-side reflector 40.

In contrast, according to the embodiment variant shown in FIG. 6, the lower light barrier 28 is also assigned a reflector 42 attached to the frame of the ring spinning machine 10, the robot-side reflection light barrier 28 and the machine-side reflector 42 being arranged such that the light beam 38, which in turn extends perpendicular to the spindle axis A 'This light barrier 28 with respect the spindle axis A or the spindle 16 is offset radially outwards. Here, this light beam 38 'is offset so far that, in the absence of the spinning sleeve 18, the light beam 38' passing laterally on the spindle 16 'reflects on the reflector 42 arranged on the ring spinning machine 10 and impinges on this spinning sleeve 18 when the spinning sleeve 18 is attached to the spindle 16 and is at least partially absorbed by this. The presence of the spinning sleeve 18 or its position is thus determined on the basis of the resulting difference in diameter or cross section.

The method according to the invention and the mode of operation of the operating robot 12 according to the invention will now be explained in particular with reference to FIGS. 3 to 5:

After each doffing operation using an integral doffer for all spinning positions 14 on one machine side, the operating robot 12 first checks the spinning positions to determine whether or not a spinning sleeve 18 is fitted on the respective spindle 16. This check is carried out by means of the upper light barrier 24, whose light beam 36 is reflected by the machine-side reflector 40 when there is no spinning sleeve (see FIG. 3), while this light beam 36 is present when the spinning sleeve 18 is present on the spindle 16 (see FIGS. 4 and 5) strikes the spinning sleeve 18 made of cardboard, for example, and is at least partially absorbed there.

The light barrier 24 supplies the corresponding information to the electronic control unit 22, which controls the device 46 for actuating the roving stop device 26 in the absence of a spinning sleeve 18.

When the roving stop device 26 is actuated, the lever 108 connected to it is pivoted upward.

This dead center of the relevant spinning position is thus signaled both to the operator concerned and to the operating robot 12 by means of the reflector 110 provided on the lever 108.

During a later run, the operating robot 12 recognizes by means of the light barrier 112 whether the roving stop device 26 of a respective spinning station 14 is actuated or not.

The electronic control unit 22 is programmed in such a way that the automatic thread applicator 102 is only ever activated at those spinning stations for the purpose of eliminating thread breaks whose roving stop device is not actuated and which are therefore not dead. The dead spinning stations are only included in the normal monitoring and troubleshooting once an operator concerned has put the spinning station back into operation, i.e. the relevant match stop device is no longer actuated and the lever 108 of the match stop device is pivoted back.

During the first pass of the operating robot 12, the spinning positions 14 are additionally checked by means of the lower light barrier 28 as to whether or not a spinning sleeve fitted to a respective spindle assumes the target position according to FIG. 2.

In the example according to FIG. 4, although a spinning sleeve 18 is present on the spindle 16, this spinning sleeve 18 is not seated on the flange 114 connected to the spindle 16, so that the spindle is exposed in the region immediately above the flange 114 and the light beam 38 is lower light barrier 28 is thus reflected on the spindle. This lower light barrier 28 thus signals the electronic control unit 22 of an incorrect position on the Spindle attached to the spinning sleeve, whereupon the relevant roving stop device 56 is actuated by means of the device 46, for example by means of an air jet. This lower light barrier 28 also delivers the same error signal if, as in the case of FIG. 3, the spinning sleeve is completely missing.

While in the described exemplary embodiments separate devices or light barriers 24, 38 are provided for checking the presence of the spinning sleeve and their position, it is also conceivable in principle, for example, to use only a lower light barrier which scans the area immediately above the flange 114 of the spindle 16 . Such a light barrier provides a corresponding error signal both in the case of a missing spinning sleeve and in the case of a spinning sleeve incorrectly placed on the spindle.

As already mentioned, in the exemplary embodiment according to FIGS. 1 to 5, the light beam 38 of the lower reflection light barrier 28 hits the spindle 16 in the absence of a spinning sleeve, so that it is reflected on the latter. In principle, however, the light barrier can also be arranged as shown in FIG. 6, according to which the light beam 38 'strikes a reflector 42 on the frame of the ring spinning machine in the absence of a spinning sleeve 18 and is reflected back there to the robot-side receiver.

On the other hand, the position of the upper edge 32 and / or the lower edge 34 (cf. FIG. 4) of the spinning sleeve 18 can also be checked directly to check the position or the presence of a spinning sleeve attached to a respective spindle. It is conceivable, for example, to arrange and design a light barrier in such a way that when a relevant sleeve edge is present at a predetermined height for example, half of the emitted light hits the relevant end of the sleeve and the other half hits a reflector and the presence of the edge in question is detected at the desired height by the fact that the amount of light received is half as large as the amount of light emitted.

If the area directly above the flange 114 connected to the spindle 16 is scanned by means of the lower light barrier 28 or its light beam 38, this light barrier 28 practically only delivers a corresponding release signal to the electronic control unit 22 when the lower edge 34 of the spinning sleeve 18 (see FIG. 4) sits on the flange 114 and thus the desired position is reached.

During the first run of the operating robot 12 following the doffing process, the yarn breaks that occurred during the doffing process are recorded simultaneously with the monitoring of the spinning tubes and, if necessary, stored for later removal of the yarn breaks. Such thread breaks are detected by means of the reflection light barrier 104 arranged on the arm 106 of the operating robot 12.

During this first pass of the operating robot 12, any spinning residues that may be present on the spinning crowns can also be removed simultaneously via the device 44.

If this first run is ended, during a second run of the operating robot 12 by means of the thread application machine 20, thread breakage removal is carried out at such spinning positions, the roving stop device of which is not actuated. As soon as the operator in question has put the dead spinning positions into operation again, which the operating robot 12 is concerned with by means of the lever 108 which is pivoted back detects roving stop device 26, these spinning stations are again included in the normal checking and troubleshooting.

In particular, the checking of the presence of a respective spinning tube or its position can in principle also be carried out before each winding or piecing process.

Claims (25)

1.Method for operating a spinning machine comprising a large number of spinning positions, in particular a ring spinning machine, using an operating robot which can be moved along the spinning positions which each have a drivable spindle for receiving a spinning sleeve and in particular for eliminating a thread break at a relevant spinning position, ensuring that this material to be spun supplied by a drafting device is rewound onto the spinning tube assigned to the spinning station, for which purpose in particular an auxiliary thread is wound on the spinning tube at one end and attached to the other end to connect it to the material to be spun,
characterized by
that after each replacement of the spinning bobbins by empty spinning sleeves and / or before each winding or attaching process using the operating robot, the spinning stations are first checked automatically to determine whether a spinning sleeve is attached to the respective spindle or not, if none The spinning sleeve automatically actuates a roving stop device assigned to the spinning station concerned or this spinning station is deactivated and this is at least visibly signaled for the operating robot, and
that by means of the operating robot only yarn breaks at such spinning positions are eliminated, whose roving stop device is not actuated or which are not put out of operation. 2. The method according to claim 1,
characterized by
that the actuation of the respective roving stop device or the decommissioning of the respective spinning station is additionally signaled to be recognizable for the operator concerned. 3. The method according to claim 1 or 2
characterized by
that the spinning positions are additionally checked by means of the operating robot as to whether or not a spinning sleeve fitted to a respective spindle assumes a predetermined target position, and
that even in the case of a spinning tube having a position deviating from the predetermined target position, the roving stop device assigned to the spinning station in question is actuated or this spinning station is put out of operation 4. The method according to any one of the preceding claims,
characterized by
that in order to check the presence of a spinning sleeve on the respective spindle, which is shorter in comparison to the spinning sleeve, an area between the upper edge of the spindle and the upper edge of a spinning sleeve which is plugged onto the spindle and takes up the predetermined target position is scanned. 5. The method according to claim 4,
characterized by
that the area immediately above the top edge of the spindle is scanned. 6. The method according to any preceding claim,
characterized by
that to check the position of a spinning sleeve attached to a respective spindle, the position of the upper and / or the lower edge of the spinning sleeve is checked. 7. The method according to any one of the preceding claims,
characterized by
that to check the position of a spinning sleeve attached to a respective spindle, the area immediately above the lower edge of a spinning sleeve attached to the spindle and taking up the predetermined position is scanned. 8. The method according to any one of the preceding claims,
characterized by
that the presence of a spinning sleeve on the respective spindle and / or the position of the spinning sleeve is checked on the basis of the resulting diameter or cross-sectional difference. 9. The method according to any one of the preceding claims,
characterized by
that the presence of a spinning tube on the respective spindle and / or the position of the spinning tube is checked by means of detectors which respond differently to different materials and / or colors of the spinning tube and spindle or their surface. 10. The method according to any one of the preceding claims,
characterized by
that during a first pass of the operating robot following at least a part of the spinning stations, only a check of the presence of the respective spinning tubes and, if appropriate, their position is carried out and a troubleshooting, in particular removal of thread breaks, is carried out during a subsequent, in particular during the next, run. 11. The method according to any one of the preceding claims,
characterized by
that during the first pass of the operating robot following a doffing process along at least part of the spinning stations, in addition to checking the presence of the respective spinning tubes and, if appropriate, their position, the thread breaks that have occurred during the doffing process are also automatically detected by the operating robot. 12. The method according to any one of the preceding claims,
characterized by
that by checking the presence of a respective spinning sleeve and, if necessary, its position, any remaining yarn on the spinning crown in question is removed at the same time. 13. Operating robot for operating a spinning machine, in particular a ring spinning machine (10), which has a multiplicity of spinning positions (14), each with a spindle (16) for receiving a spinning sleeve (18), with an automatic thread applicator (20) and an electronic, in particular programmable Control unit (22), in particular for performing the method according to one of the preceding claims,
characterized by
that the operating robot (12) which can be moved along the spinning positions (14) has a device (24) for checking the presence of a spinning sleeve (18) on a respective spindle (16), a device (46) for actuating a roving stop device (26) and means ( 28) for detecting an actuated roving stop device (26) or a decommissioned spinning station (14), and that the device (46) for actuating the roving stop device (26) and the automatic thread application device (20) can each be controlled by the electronic control unit (22),
that, in the absence of the spinning sleeve (18), the roving stop device (26) is actuated and the automatic thread-setting device (20) only fixes a thread break present only at those spinning stations (14) whose roving stop device (26) is not actuated or which are not deactivated. 14. Operating robot according to claim 13,
characterized by
that additionally a device (28) for checking the position of a spinning sleeve (18) attached to a respective spindle (16) is provided, and
that the device (46) for actuating the roving stop device (26) can be controlled by the electronic control unit (22) even when the spinning sleeve (18) is present, provided that its position on the spindle (16) deviates from a predetermined target position. 15. Operating robot according to claim 13 or 14,
characterized by
that the device (24) for checking the presence of a spinning sleeve (18) on the respective spindle (16), which is shorter in comparison to the spinning sleeve (18), for scanning an area between the upper edge (30) of the spindle (16) and the upper edge ( 32) a spinning sleeve (18) which is plugged onto the spindle (16) and takes up the predetermined desired position is designed and arranged. 16. operating robot according to claim 15,
characterized by
that the device (24) for checking the presence a spinning sleeve (18) for scanning the area immediately above the upper edge (30) of the spindle (16) is designed and arranged. 17. Operating robot according to one of the preceding claims,
characterized by
that the device (28) for checking the position of a respective spinning sleeve (18) responds to the upper edge (32) and / or the lower edge (34) of the spinning sleeve (18). 18. Operating robot according to one of the preceding claims,
characterized by
that the device (28) for checking the position of a respective spinning sleeve (18) for scanning an area immediately above the lower edge (34) of a spinning sleeve (18) which is plugged onto the spindle (16) and takes up the predetermined desired position is designed and arranged. 19. Operating robot according to one of the preceding claims,
characterized by
that the device (24) for checking the presence of a spinning sleeve (18) and / or the device (28) for checking the position of the spinning sleeve responds to the diameter or cross-sectional differences that arise in the monitored area. 20. Operating robot according to one of the preceding claims,
characterized by
that the device (24) for checking the presence of a spinning sleeve (18) and / or the device (28) for checking the position of the spinning sleeve (18) is designed such that it is adapted to different materials and / or colors or the like of the spinning sleeve ( 18) and Spindle (16) responds differently to its surface. 21. Operating robot according to one of the preceding claims,
characterized by
that the device (24) for checking the presence of a spinning sleeve (18) and / or the device (28) for checking the position of the spinning sleeve (18) is designed as a light barrier (24 or 28), the transmitter and receiver of which are preferably each are arranged on the operating robot (12). 22. Operating robot according to claim 20,
characterized by
that the light beam (36, 38) of the light barrier (24 or 28) is directed at least substantially perpendicular to the respective spindle axis (A) and intersects this spindle axis (A), the light beam (36, 38) in the absence of a spinning sleeve (18) reflected on the exposed spindle (16) or a reflector (40) arranged above the spindle (16) on the spinning machine, in particular a ring spinning machine (10), and is at least partially absorbed by the spinning sleeve (18) attached to the spindle (16) . 23. Operating robot according to claim 20,
characterized by
that the at least substantially perpendicular to the respective spindle axis (A) light beam (38 ') of the light barrier (28) with respect to the spindle axis (A) or the spindle (16) is displaced radially outwards in such a way that if there is no spinning sleeve (18) the light beam (38 ') passing the side of the spinning (A6) reflects on a reflector (42) arranged on the spinning machine, in particular a ring spinning machine (10) and at the spindle (16) of the attached spinning sleeve (18) is at least partially absorbed by the latter. 24. Operating robot according to one of the preceding claims,
characterized by
that the electronic control unit (22) is designed in such a way that only the device (24) for checking the presence of a spinning tube (18), possibly the device (28) for checking, during a first pass of the operating robot (12) following a doffing process the position of the spinning sleeve (18) and, if appropriate, a device (44), which is also assigned to the operating robot (12), for removing spinning residues on the spinning crowns and, in particular, during a subsequent, in particular during the next pass for troubleshooting, the threading machine (20) can be activated. 25. Operating robot according to claim 24,
characterized by
that an additional device (46) for detecting the yarn breaks that occurred during the doffing process can be activated via the control unit (22) during the first pass.

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