Method for Controlling a Setting Process for Re-setting a Yarn at a Work Station of a Textile Machine

Abstract

With a method for controlling a setting process for re-setting a yarn (G) at a textile machine, in particular a spinning machine (1), by means of a setting device (5), a multiple number of work steps as preparation for the actual setting operation are carried out successively in a chronological sequence. In each case, a predetermined time period is allocated to the work steps within which the respective work step is carried out. For at least one of the work steps, the predetermined time period can be varied, whereas the current time period of the at least one work step is determined as a function of a yarn characteristic (GC) of the currently produced yarn (G and/or as a function of a utilization of the setting device (5). A textile machine features a control unit (12), which is designed to operate the textile machine according to this method.

Claims

1. Method for controlling a setting process for re-setting a yarn (G) at a work station of a textile machine, in particular a setting process for spinning back in a yarn (G) on a spinning unit (7) of a spinning machine (1), by means of a setting device (5), with which multiple work steps as preparation for the actual setting operation are carried out successively in a chronological sequence, whereas a predetermined time period is allocated to the work steps within which the respective work step is carried out, characterized in that, for at least one of the work steps, the predetermined time period can be varied, whereas the current time period of the at least one work step is determined as a function of a yarn characteristic (GC) of the currently produced yarn (G and/or as a function of a utilization of the setting device (5) and/or as a function of a success rate of the work step and/or as a function of the success of the individual work step.

2-13. (canceled)

Description

[0035] Additional advantages of the invention are described on the basis of the following presented embodiments. The following is shown:

[0036] FIG. 1 a spinning station of a spinning machine with a multiple number of handling elements for spinning in a yarn in a schematic side view and

[0037] FIG. 2 a schematic view of the adjustment to the time period for a particular work step.

[0038] FIG. 1 shows a spinning station 2 of a spinning machine 1 in a schematic side view. The spinning machine 1 typically has a multiple number of spinning stations 2 arranged next to each other, each of which has a multiple number of working elements for producing a yarn G. For this purpose, each spinning station 2 has at least one spinning unit 7 with one spinning element 8 and one draw-off element 10. In the regular spinning mode, the yarn F produced by the spinning element 8 is drawn off by a draw-off device 11, and is fed to a coil 6 onto which it is wound. For this purpose, the coil 6 is mounted in a rotatable and drivable manner, whereas, in the present case, a roller 4 is provided for driving the coil 6. During regular spinning operation, the coil 6 is driven by the roller 4 into the yarn draw-off direction (dashed arrow). Alternatively, the coil 6 can also be driven by a direct drive.

[0039] Furthermore, the spinning machine 1 has a setting device 5, which has a multiple number of handling elements 14, 15, 16, 17, 18, 19, 20, 21, 22 for spinning in the yarn G. In the present case, a suction nozzle 14, a pneumatic handling element 15, a yarn catcher 16, a feed unit 17 with a clamping device 18, a yarn preparation unit 19 and a separating device 20, along with auxiliary pair of rollers 21, are shown as handling elements. According to the present example, the setting device is arranged within a maintenance device 3 that can be moved along the spinning stations 2. Likewise, however, a setting device can also be arranged at the spinning station 2. In addition, the handling elements 14, 15, 16, 17, 18, 19, 20, 21, 22 listed here are merely exemplary. Depending on the version of the spinning machine 1, some of the specified handling elements 14, 15, 16, 17, 18, 19, 20, 21, 22 are not required, or are provided instead of the specified other handling elements 14, 15, 16, 17, 18, 20, 21, 22, which can also be combined to form different assemblies. Thereby, some of the handling elements 14, 15, 16, 17, 18, 19, 20, 21, 22 can also be exhibited with a sensor S, in order to monitor the presence of the yarn G. Sensors S can also be provided, which sensors detect the correct method or pivoting of the individual handling elements 14, 15, 16, 17, 18, 19, 20, 21, 22 or assemblies. In the present case, sensors are shown in the suction nozzle 14 and in the pneumatic handling element 15. In a conventional manner, an additional sensor S is arranged at the spinning station 2 in the yarn path, in order to monitor the presence of the yarn G and, if applicable, the quality of the yarn G.

[0040] If a thread breakage occurs or a clearer cut is carried out, the end of the yarn G accumulates on the coil 6 and this still rotating and, for spinning in, must initially be searched for on the surface of the coil 6 (work step of thread search). For this purpose, according to the present example, the coil 6 is driven by a roller 4 of an auxiliary drive 22 in the direction opposite to the regular draw-off direction (solid arrow). Meanwhile, the suction nozzle 14 is pivoted in the direction of the coil 6 (dashed line), in order to search for and detect the yarn end G. If the suction nozzle 14 has detected the yarn end G, it is pivoted into the position shown by the solid line, whereas the yarn G is fed to a pneumatic handling element 15. From the position shown by the solid line, the yarn end G can now be detected by the yarn catcher 16 and, through pivoting the yarn catcher 16, can be fed into the position of the feed unit 17 shown by the dashed line. At the same time, the yarn end G is inserted into the pair of auxiliary rollers 21, by means of which a temporary draw-off of the yarn F from the open-end spinning device 7 takes place after spinning in.

[0041] In the work step of yarn end preparation, the yarn end G is initially clamped in the clamping device 18 and is separated by a separating device 20. This results in a new yarn end G, which is now prepared in the yarn preparation unit 19 for spinning back in.

[0042] Meanwhile, in the spinning unit 7, the work step of cleaning of spinning element 8 can be carried out.

[0043] After the yarn end G has been prepared, the work step of feeding the prepared yarn end G to the spinning unit 7 is now carried out. For this purpose, the movably supported feed unit 17 is moved from its drawn-off preparation position into a feed position shown by a dashed line, and the yarn end G is thereby placed in front of the draw-off element 10.

[0044] Subsequently, the work step of returning the yarn end G into the spinning unit 7 or into the spinning element 8 takes place. For this purpose, the pair of auxiliary rollers 21 and/or an additional pair of auxiliary rollers 21 (not shown), which is arranged on the feed unit 17, is driven in the direction opposite to the regular draw-off direction, such that the yarn end G finally reaches the effective area of the spinning element 8.

[0045] In the state of the art, the individual work steps for all applications were always carried out with a fixed cycle time or time period, such that, overall, a chronologically constant cycle sequence arose. As a rule, the time period of the individual work step was specified in such a manner that, even with more difficult yarns G, a good success rate of the relevant work step was achieved.

[0046] By contrast, it is now provided that, at least with individual work steps, the cycle time of this work step must be adjusted to the yarn characteristic GC of the yarn G currently being produced, in order to achieve a saving of time and an associated increase in machine efficiency. Likewise, the cycle time of a certain work step can also be prolonged, if this appears to be required for a more difficult application based on lower success rate of the relevant work step.

[0047] In the case of the spinning machine 1 shown here, an adjustment to the time period of the cleaning of the spinning element 8, or an adjustment to the time period of the yarn end preparation, comes into question. Likewise, a time period for the thread search, for the transfer of the yarn G by the yarn catcher 16, for the feeding of the yarn end G to the spinning unit 7 and for the return of the yarn end G into the spinning unit 7 can be predetermined.

[0048] In order to enable a comfortable setting of the time period of a work step, in the present case, an information memory device unit 13 is provided, which is in operative connection with a control unit 12 of the spinning machine 1. Different yarn characteristics GC1, GC2, . . . , GCn are stored in the information memory device 13, to each of which at least one suitable value W1, W2, . . . , Wn of the time period for the respective work step is allocated. Thus, it is possible to obtain, after inputting the yarn characteristic GC of the respective current application by means of the information memory device 13, a value W suitable for this yarn characteristic GC. The stored values W are based on the experiences of prior setting processes and, according to a first version, are permanently stored in the information memory device 13. Thereby, the selection of a suitable value W for the current yarn characteristic GC can be carried out by an operator. In this case, the control unit 12 merely proposes a certain, suitable value W for the current yarn characteristic GC; however, this still must be confirmed by the operator. Only then is this value W adopted by the control device 12, in order to control the setting device 5 or its handling elements 14, 15, 16, 17, 18, 19, 20, 21 accordingly. However, it is particularly advantageous if the selection and adoption of a suitable value W takes place automatically by means of the control unit 12.

[0049] According to a particularly advantageous version, the control unit 12 is designed as a self-learning control unit 12, such that the values W stored in the information memory device 13 for certain yarn characteristics GC can be varied. In doing so, it is particularly advantageous if the initially selected value W of the time period of a work step can be automatically adjusted for a certain yarn characteristic GC, even during the spinning process or during a production batch. A corresponding procedure for adjusting the time period of a certain work step is shown schematically in FIG. 2.

[0050] While, for some work steps, the appropriate time period can be directly stored as the value W, in some other work steps, the time period for a certain work step arises from certain setting values for carrying out this work step. Such setting values can be, for example, the traversing speed of handling elements 14, 15, 16, 17, as the suction nozzle 14, the pneumatic handling element 15, the yarn catcher 16 and in particular the feed unit 17. The setting values can also be the rewinding speed of the yarn G or certain rotational speeds, for example the rotational speed of the pair of auxiliary rollers 21 or the roller 4 for driving the coil 6, or other parameters. In this case, the corresponding time periods are not stored as value W, but are stored as suitable values for such speeds or rotational speeds.

[0051] In the present case, the procedure is described using the example of the work step of thread search or the return of the yarn end G into the spinning unit 7. In both cases, certain values W of the rewinding speed of the yarn G are stored as setting values. As described in FIG. 1, at least one suitable value W1, W2, . . . , Wn of the rewinding speed is stored in the information memory device 13 for each yarn characteristic GC1, GC2, . . . GCn. At the beginning of the spinning process, in particular at the beginning of a certain production batch, the operator enters the yarn characteristic GC of the current application by means of the control unit 12. Furthermore, it is possible for the operator to enter a certain desired minimum success rate for the relevant work step. However, in contrast to the illustration shown, such a minimum success rate can also be permanently stored in the control unit 12. From the information memory device 13, for the entered yarn characteristic GC arising from the stored values W1, W2, . . . , Wn, the value W suitable for this yarn characteristic GC can now be selected and can be output by means of the control unit 12 as the initial value SW. This initial value SW can now be predetermined, either automatically or by the operator, as a suitable value W for carrying out the relevant work step.

[0052] After preferably multiple setting processes have been carried out with this predetermined value W, there can be an examination of whether the desired, previously entered minimum success rate or the permanently stored minimum success rate has been achieved. If this is the case, the predetermined value W is also used as a working value AW for future setting processes, and a further adjustment to the value W is not required. However, if the minimum success rate is not achieved, the predetermined value W is reduced by means of the control unit 12, and this reduced value W is once again predetermined for carrying out the relevant work step. The correction of the value W, in this case the reduction of the value W of the rewinding speed, is carried out until the predetermined minimum success rate is achieved. As soon as this is the case, the value W determined in this manner is once again predetermined as the working value AW for future setting processes, and a further adjustment is not required. In addition, the working value AW determined in this manner can be stored in the information memory device 13, in order to be able to serve as the initial value SW for future production batches from the outset.

[0053] However, an alternative or in addition to the above-described change to the time period as a function of a success rate of the relevant work step, by means of a multiple number of setting processes, the time period can also be varied within a single setting process as a function of a success of the individual work step. This is the case if a work step has been unsuccessful and has to be repeated.

[0054] For example, the rewinding speed upon searching for a yarn end G that has accumulated on a coil 6 (thread search) can be varied in order to improve the chances of success for the thread search. A value W of the rewinding speed is selected for the thread search and initially the thread search is started using a selected value W as the initial value SW of the rewinding speed of 1 m/s, for example. The time period for the work step of searching for the yarn end G is, for example, specified at a search time of 5 s as the initial value SW, and the work step is carried out at a regular negative pressure level.

[0055] If this work step is successful, the initial value SW of the rewinding speed is adopted as the working value AW for the subsequent setting processes at other work stations. Likewise, the time period for the work step and the negative pressure level for the subsequent setting processes remain unchanged.

[0056] If the work step fails, the selected initial value SW is changed, and the relevant work step, in this case the thread search, is repeated with the changed value W. For example, the rewinding speed is now reduced to 0.5 m/s. In doing so, the time period and the negative pressure level remain unchanged. If the thread search is now successful, the reduced rewinding speed of 0.5 m/s is now adopted as the working value AW for the subsequent setting processes.

[0057] In the event of a further failure of the work step within the same setting process, the reduced rewinding speed of 0.5 m/s can also be adopted as the working value AW for the repetition of the work step and for the subsequent setting processes. However, an adjustment to additional values W is now carried out, and the relevant work step is now repeated with the adjusted values W. The negative pressure level can now be increased (for example). If the work step fails again, the time period for the thread search can be further increased starting from the initial value SW, here 5 s. However, if the relevant work step is successful, the values W for future setting processes are reset to the initial values SW.

[0058] Only if the relevant work step frequently fails in the various setting processes with the initial values, and thus the success rate of the relevant work step is low, will the changed values W, in this case the reduced rewinding speed, as described above, be permanently adopted or at least adopted for the respective part, as values W, in the control unit.

[0059] In the present case, the determination of suitable values W was described on the basis of the rewinding speed of the yarn G. In a similar manner, of course, suitable values W can also be determined for other setting values as described above. In doing so, of course, it not always necessary to start with a relatively high initial value SW and to reduce this successively. If more difficult applications, which require slower cycle times, are frequently required, starting with a low rewinding speed or a low value W, and successively increasing this until an acceptable success rate is achieved, can also be provided. In doing so, the success rate of a work step can be monitored, for example by means of sensors S, as described for FIG. 1.

[0060] Furthermore, the described procedure can also be used with the determination of suitable values W for certain setting values by means of an information memory device 13, in an analogous manner with other textile machines. For a winding machine, for example, an adjustment to the time period for yarn preparation, for the yarn search, for the transfer of the yarn G by a working element of the textile machine, for the feeding the yarn end G into the splicing chamber and, if applicable, for the returning of the yarn end G into the work station can be predetermined.

[0061] Thus, for each individual step and for each yarn characteristic GC, the cycle time can be optimized such that an optimum efficiency arises for the particular application. In particular, if such an optimization of the cycle time is carried out for a multiple number of work steps of the setting process, this results in considerable time savings and thus increases in efficiency.

LIST OF REFERENCE SIGNS

[0062] 1 Spinning machine [0063] 2 Spinning station [0064] 3 Maintenance device [0065] 4 Roller for driving the coil [0066] 5 Setting device [0067] 6 Coil [0068] 7 Spinning unit [0069] 8 Spinning element [0070] 10 Draw-off element [0071] 11 Draw-off device [0072] 12 Control unit [0073] 13 Information memory device [0074] 14 Suction nozzle [0075] 15 Pneumatic handling element [0076] 16 Yarn catcher [0077] 17 Feed unit [0078] 18 Clamping device [0079] 19 Yarn preparation unit [0080] 20 Separating device [0081] 21 Auxiliary pair of rollers [0082] 22 Auxiliary drive [0083] G Yarn [0084] G Yarn end [0085] S Sensor [0086] W Value [0087] SW Initial value [0088] AW Working value [0089] GC Yarn characteristic