DE102012002579A1 - Method and device for determining the required speed of a bobbin drive roller - Google Patents

Abstract

The invention relates to a method that reduces fluctuations in the speed of cross-wound bobbins (8), in particular at the beginning of the bobbin travel, as well as a cheese-producing textile machine for carrying out the method. In the workstations (2) of a spinning machine (1) are produced in the so-called winding apparatus (4) in addition to cylindrical and conical cheeses (8), for their uniform coil structure, the supply of the thread (7) with a constant winding tension is extremely crucial. Fluctuations in the winding tension, in addition to loose thread layers, can also lead to thread breaks, which impair the continuous spinning and winding process. To avoid these effects, the invention provides that the angular momenta of the cross-wound bobbin (8) are sensory detected before a piecing or piecing process, as well as from the time sequence of the respective drive diameter is calculated to based on it in particular already at the beginning of the bobbin trip the speed of Select bobbin drive roller (10).

Description

The invention relates to a method for determining the required speed of a bobbin drive roller when driving a conical sleeve or cross-wound bobbin, which is held in the bobbin frame a job of a cheese-producing textile machine, the single-motor controlled bobbin drive roller of the job frictionally drives the conical sleeve and later cheese, and a Cheese-making textile machine for carrying out the method.

In the workstations of a spinning machine in addition to cylindrical conical coils are produced in the so-called winding apparatus, for the uniform coil structure, the supply of the yarn with a constant winding tension is extremely crucial. This tension, with which the thread is wound up, not only has a decisive effect on the quality of the coil structure, but also influences the continuous course of the spinning or winding process.

A method for controlling a traversing device driven by a single motor drive on a device for winding conical cheeses and a textile machine producing cross-cheeses are known, for example, from US Pat CH 698 687 A2 known. In order to match the coil structure as exactly as possible to the sleeve geometry, describes the Swiss patent application CH 698 687 A2 in that a so-called conicity factor is determined in advance. This Konizitätsfaktor describes the ratio of the thread laying speeds at the end faces of the cheese and is specified to the winding station computer. To control the drive, a modified Konizitätsfaktor is fixed at the beginning of the coil travel, which approaches in the course of the coil travel to the beginning of the coil assembly set value.

The DE 29 11 340 A1 describes a method for cross-winding a thread and a device for driving a bobbin on which the thread is wound. For winding a thread on a conical bobbin, a drive shaft with a concentrically arranged drive bale whose diameter is dimensioned slightly larger than the actual diameter of the roller, so that it is in the contact region, which lies in the central coil region, to a reliable frictional engagement between the drive shaft and cheese comes.

A disadvantage of the method according to the prior art proves that the manufactured conical cheeses do not always meet the required high quality standard. The Konizitätsfaktor is based on a theoretical value and can only approximate the actual tube or bobbin diameter, while the bobbin drive roller with special roller surface for conical sleeves / coils not only requires a second bobbin drive roller for the production of cylindrical coils, but also a conversion of the machine Change the format of the coils to be produced.

In addition, the bobbin frame must be aligned very accurately to the bobbin drive roller, since even bobbin drive rollers with a special roller surface prevent limited entrainment on the sleeve or coil edge. Often an adjustment of the creel is necessary. Although due to the elasticity of the winding body, the behavior is equalized from a certain thickness of lining, and cheeses not running parallel to the bobbin drive roller are less detrimental. Nevertheless, this remains a quality problem and can negatively affect subsequent processes.

Decisive for a constant winding speed of the conical sleeve or cheese is in a frictional drive the so-called driven diameter. The driven diameter is the diameter at which the peripheral speed of the cheese coincides with the peripheral speed of the drive roller; he is subject, especially at the beginning of the cross-wound coil construction slip-related fluctuations. A strong fluctuation in the position of the driven diameter in turn causes a change in the yarn speed or the yarn tension.

The actual drive point on the conical sleeve and later on the conical cheese may deviate from the geometric centerline. If the contact area of the conical sleeve with the coil drive roller, with respect to the geometric center line, on the narrower side of the bobbin, the winding tension increases; However, if this contact area lies on the wider side, the sleeve or cross-wound bobbin has a lower winding speed.

These factors are reasons for differences in the winding tension to thread breaks in the individual jobs of a cheese-producing textile machine and also have a negative effect on the emptying of the thread storage when threading or piecing. In particular, when applying to an empty conical sleeve, the pneumatic yarn storage can not be precisely controlled and it can here due to high winding tension increased yarn breaks occur, if the sleeve is driven on the narrower side, with respect to the geometric center line; respectively due to loose thread layers lower winding tension when the sleeve is driven on its wider side.

The object of the present invention is to propose a method or a device which reduces the fluctuations of the speed of cheeses, in particular at the beginning of the coil travel.

This object is achieved by the features of claim 1 for a method and by the features of claim 4 for a cheese-producing textile machine.

Advantageous embodiments of the invention are the subject of the dependent claims.

According to claim 1 it is provided that sensory angular momenta of the conical cheese are detected, that the time sequence of the angular momenta is measured, that from the respective drive diameter of the conical cheese is calculated and that the speed of the bobbin drive roller is tuned to this drive diameter. Due to the detection of the individual angular momenta as a function of time, the respective cheese diameter can be calculated exactly and the required speed of the bobbin drive roller can be controlled. This method is realized from the starting point of the coil travel and carried out in the starting phase or during the entire coil travel.

Preferably, the detection of the speed pulses already takes place before an application process, so that the respective drive diameter of the sleeve or cross-wound bobbin takes place during the application process when selecting the adapted speed range of the bobbin drive roller. This makes it possible to achieve a constant winding tension not only during but also at the beginning of the winding process (claim 2).

Furthermore, according to claim 3, by adjusting the rotational speed of the bobbin drive roller to the drive diameter of the cross-wound bobbin, this rotational speed can be controlled during the piecing process so that a pneumatic yarn store of the work station is emptied in the predetermined time. Due to the precise control of the pneumatic thread store, thread breaks due to excessive winding tension and loose thread layers due to insufficient winding tension can be avoided.

According to the method claim 4 is proposed that each job has a device that senses the pulses of rotating on the bobbin drive roller sleeve or cross-wound bobbin and forwards to a control device, from the timing of the pulses the drive diameter of the sleeve or cross-wound bobbin and from it as a result, the speed adapted to the drive diameter. the bobbin drive roller calculated.

The present invention will be explained below with reference to a schematically illustrated workstation of a textile machine producing cross-wound bobbins.

Show it

1 a schematic side view of a workstation of an open-end rotor spinning machine;

2 a perspective view of the winding device according to 1 ,

1 shows a side view of a job 2 an open-end rotor spinning machine 1 , Such an open-end rotor spinning machine 1 has on its two longitudinal sides of each machine a plurality of such juxtaposed jobs 2 , Structure and functioning of the jobs 2 are identical in each case, so that the explanation is based solely on a job 2 he follows.

1 and 2 show a job 2 that is an open-end spinning device 3 and a winding device 4 including a suction nozzle 25 having. In the open-end spinning device 3 is, as is known, in a spinning can 5 submitted sliver 6 to a thread 7 spun. The string 7 is then in the winding device 4 to a cheese 8th wound. The cheese 8th is in the winding device during the spinning / winding process 4 in a creel 9 held and is doing a bobbin drive roller 10 driven by friction. The coil frame 9 is about a pivot axis 11 pivoted.

The string 7 is by a Fadenabzieheinrichtung 12 consisting of a driven roller and a pressure roller resting on the roller, with a defined, consistent yarn delivery speed from the open-end spinning device 3 deducted. The withdrawal speed of the peeling device 12 thus determines the delivery speed of the thread 7 and thus the winding speed with which the thread 7 on the cheese 8th must be wound up.

In the thread running direction are the Fadenabzieheinrichtung 12 a thread store 13 , a waxing device 14 as well as a thread guide 15 downstream. The thread guide 15 changes in a straight line in front of the outer circumference of the cheese 8th and thus ensures simultaneous drive of the cheese 8th over the bobbin drive roller 10 for that thread 7 in intersecting layers on the cheese 8th is wound up.

The open-end rotor spinning machine 1 is an only indicated here, automatically operating control unit 22 associated with his chassis 23 on tracks 24 is guided. The rails 24 run in the superstructure of the open-end rotor spinning machine 1 on which the operating unit 22 along the open-end rotor spinning machine 1 is movable. The operating unit 22 comprises a plurality of handling devices not shown in detail for cleaning the spinning rotors or for changing the cheeses 8th ,

The workings of the jobs 2 is for example through the DE 10 2005 036 485 A1 or the DE 101 39 075 A1 so that it need not be discussed further in the context of the present description.

2 illustrates in perspective a job 2 an open-end rotor spinning machine; the string 7 leaves the open-end spinning device 3 through a so-called thread withdrawal tube 29 , In the area also a pivotally mounted Anspinnhilfsorgan 27 is arranged, which after a thread interruption by a suction nozzle 25 from the cheese 8th retrieved thread 7 takes over and prepares the thread end for thread connection.

In the area of the thread running path are also a thread monitor 30 , a pneumatic thread storage device 13 and a waxing device 14 arranged. The pneumatic thread storage device 13 is designed as a discontinuous memory, that is, the thread storage device 13 is completely emptied after each thread joining process. During operation of the open-end spinning device 3 becomes the thread storage device 13 if necessary, supplied with suction air via a vacuum source (not shown).

Furthermore, such jobs 2 , as already mentioned, via a suction nozzle 25 that by means of a stepper motor 17 defined between one in the area of the winding device 4 lying thread receiving position and one in the spinning device 3 lying thread transfer position is adjustable.

As usual, the individual stepper motors are the components of the job 2 via various control lines to a control device, in the present embodiment, to a workstation computer 19 , connected. As a result, the single-motor drives of the components of the jobs 2 independently controllable.

The inventive method will be described below with reference to the illustrated embodiments of the open-end rotor spinning machine.

The filament winding speed of a cross-wound bobbin 8th results from the speed and the diameter of the bobbin drive roller 10 and the driven diameter of the cheese 8th , To ensure a uniform bobbin construction, the yarn winding speed of the winding device must 4 with the yarn guide speed of the Fadenchangiereinrichtung 15 on the yarn delivery speed of the spinning device 3 be coordinated.

As with conical cheeses 8th the driven diameter of the cheese 8th and the diameter of the cheese 8th in the thread run-off point mostly do not match and the yarn winding speed of the winding device 4 is the speed of the coil drive roller by the measures according to the invention at the small cheese diameter under the yarn delivery speed and at the large cheese diameter above the yarn delivery speed 10 single motor 28 adapted to the respective drive diameter, so that the supply of the thread 7 occurs at constant winding tension. Thus, it can be ensured that the thread store 13 is emptied in the given time.

In a piecing process, first the sliver feed, the drives of the thread take-off roll 12 , the thread changer 15 and the bobbin drive roller 10 stopped and the cheese to be produced 8th is by means of the coil frame 9 from the bobbin drive roller 10 lifted. Subsequently, a piecing process is initiated, wherein the sliver feed, the drives of the thread take-off roll 12 , the thread changer 15 and the bobbin drive roller 10 be put back into operation synchronously with the initiation of the piecing process. The commissioning of the thread take-off roll 12 , the thread changer 15 and the bobbin drive roller 10 takes place in consideration of temporally coordinated acceleration processes of the individual drives, which should take into account, above all, the different mass moments of inertia and the traction slip of the components to be put into operation.

In particular, after a bobbin change and the subsequent application process to a conical empty tube, fluctuations of the axial position of the driven diameter occur. The string 7 especially when winding a conical empty tube through the thread guide 15 constantly between the large and small diameter of the cheese 8th oscillates. This fluctuation of the position of the driven diameter causes the winding tension of the thread 7 Also fluctuates and thus occur possible thread breaks or loose thread layers almost inevitably.

To avoid these effects, it is provided according to the invention that the angular momenta of the cross-wound bobbin are already applied prior to a piecing or piecing process 8th sensory be detected, as well as from the time sequence of the respective drive diameter is calculated, based on it already at the beginning of the coil travel, the speed of the bobbin drive roller 10 to choose.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• CH 698687 A2 [0003, 0003]
• DE 2911340 A1 [0004]
• DE 102005036485 A1 [0026]
• DE 10139075 A1 [0026]

Claims (4)

Method for determining the required speed of a bobbin drive roller ( 10 ) when driving a conical cheese ( 8th ) in the creel ( 9 ) a job ( 2 ) is mounted on a cheese-producing textile machine, wherein the thread to be wound is fed continuously by means of a thread take-off device, and wherein the single motor controlled bobbin drive roller ( 10 ) of the job ( 2 ) frictionally the conical cheese ( 8th ), characterized in that sensorically rotational pulses of the cheese ( 8th ) that the chronological sequence of the angular momenta is measured such that the respective drive diameter of the conical cross-wound bobbin (FIG. 8th ) and that the speed of the bobbin drive roller ( 10 ) is tuned to this drive diameter. A method according to claim 1, characterized in that the detection of the speed pulses before an application process on a still unstressed cheese ( 8th ) and that the calculated on the basis of the sequence of angular momentes drive diameter already during the application process of the still unsprayed cheese ( 8th ) the choice of the adapted speed of the bobbin drive roller ( 10 ). A method according to claim 2, characterized in that by means of the adaptation of the rotational speed of the bobbin drive roller ( 10 ) to the drive diameter of the cheese ( 8th ) this speed is controlled during the piecing process so that a pneumatic thread store ( 13 ) of the job ( 2 ) is emptied in the given time. Place of work ( 2 ) of a cheese-producing textile machine for carrying out the method according to claim 1, characterized in that each workstation ( 2 ) An institution ( 31 ), which sensory the pulses of the on the bobbin drive roller ( 10 ) rotating sleeve or cross-wound bobbin ( 8th ) and to a control device ( 32 ) from the chronological sequence of the pulses resulting from the drive diameter of the sleeve or cross-wound bobbin ( 8th ) and, as a result, the rotational speed of the bobbin drive roller adapted to the drive diameter ( 10 ).

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