EP0528752A1 - Method and apparatus for laying a subsidiary winding with a predetermined wrap angle around the spindle shaft of a ring spinning or twisting machine - Google Patents

Abstract

By detecting the yarn length delivered from the drawing unit (5), the current wrap angle of the subsidiary winding can be calculated by the data-processing unit (20), thus making it possible to control the motors (7, 17) for the drawing unit and for the spindle shaft in such a way that a predetermined wrap angle of the subsidiary winding of especially 90 DEG to 270 DEG is maintained reliably and accurately. This makes it possible to prevent yarn residues from occurring in the sensitive spinning region during the doffing, thereby reducing the maintenance outlay for the ring spinning or twisting machine (1). <IMAGE>

Description

The invention relates to a method for creating a winding from a predetermined wrap angle and a correspondingly designed ring spinning or twisting machine.

Underwindings serve to define the machine end of the thread before doffing; when the filled bob is removed, the thread breaks between the winding and the bob. The thread end must still be secured in the underwind for spinning on a new tube; as soon as the new cop is filled, a new underwinding must be created, which means that the old underwinding must be removed.

On the one hand, the secure fixing of the thread end in the winding requires a wrap angle of several 360⁰, depending on the various influencing factors present. On the other hand, it is difficult to remove the multiple turns of the thread end reliably and in good time from the sensitive spindle area. Despite the use of devices for cleaning the spindle area with knives, blowers, etc. in conventional ring spinning or twisting machines, contamination cannot be completely avoided, which leads to increased maintenance and is undesirable.

Accordingly, machines with clamping devices for the thread end lying in the winding have been developed, which allow wrap angles to be provided in particular between 90⁰ and 270⁰. This facilitates the removal of the in the subwinding lying thread end after piecing and allows to dispense with the structurally complex fans and knives. However, it is necessary that the intended wrap angles are adhered to very precisely.

DE-OS 29 27 616 now discloses a method for spinning which allows, regardless of the properties of the respective threads and their production parameters, to always apply approximately the same backwinding and underwinding, that is to say also to maintain a specific wrap angle. The disclosure mentions the advantage that thread-specific adjustment work on the spinning machine can be avoided in this way, since an essentially generally sufficient, unchangeable wrap angle of 900⁰ to 1260⁰ is guaranteed. The method uses three necessary parameters, each of which cannot be changed; a fixed basic thread delivery speed at the beginning of the spinning, a subsequent fixed speed-time program for the thread delivery speed during the spinning and a coupled, fixed ring bench lowering speed.

This prior art has the disadvantage that, despite the fixed parameters, a wrap angle results with an inaccuracy that can be greater than the above-mentioned desired wrap angles from 90⁰ to 270⁰: the movement of the ring bench, for example, cannot be controlled precisely enough without hydraulics; hydraulics are hardly an option because of the unavoidable oil losses in connection with the downpour of down and the resulting contamination of the machine.

Accordingly, it is an object of the present invention to provide a method and a ring spinning or twisting machine, according to which windings with a wrap angle of in particular 90⁰ to 270⁰ can be placed with constant and improved accuracy.

To solve this, the method according to the invention has the features of claim 1 and a correspondingly designed machine has the features of claim 9.

These features ensure that the continuous increase in the wrap angle can be recognized via the detected winding stage and the detected thread length emitted from the drafting system, which allows the single parameter "delivery speed" of thread from the drafting system to be brought down in a controlled manner from the start of the winding, what enables a precise stop of the thread delivery and results in a corresponding accuracy of the wrap angle.

A preferred embodiment of the method according to claim 2 provides for an intermediate phase of at least reduced yarn delivery of the drafting device when a predetermined winding stage occurs, while at the same time the spindle shaft rotation is maintained. As a result, the thread reserve in the thread balloon is wound up on the bobbin until the thread between the drafting device and the bobbin is stretched. Accordingly, in the phase of the winding, the wrap angle grows exactly according to the thread length, which is output from the drafting system and recorded via the delivery speed. Inaccuracies due to the thread stored or storable in the thread balloon are eliminated, with the consequence that the desired wrap angle is achieved particularly precisely.

Preferred embodiments have features of the dependent claims.

An embodiment is explained in more detail with reference to the figures.

• Fig 1 eine schematische Darstellung einer Spinn- oder Zwirneinheit einer Maschine gemäss der vorliegenden Erfindung, wobei die Antriebssteuerung in der Art des Blockschemas dargestellt ist;
• Fig 2 ein Diagramm, in welchem die Betriebsverhältnisse vor dem Doffen dargestellt sind.

It shows:

• 1 shows a schematic illustration of a spinning or twisting unit of a machine according to the present invention, the drive control being shown in the form of the block diagram;
• Fig. 2 is a diagram in which the operating conditions are shown before doffing.

1 shows the organs of the spinning area of a ring spinning machine 1 and the associated control in a schematic arrangement.

A section of a frame 2, a spinning unit 3 arranged thereon and drive control 4 for the corresponding organs of the spinning unit 3 are shown.

The spinning unit 3 has a drafting unit 5 with front drawing cylinders 6, which are driven by a motor 7. The connection between engine 7 and cylinder 6 and the middle and rear extension cylinders are omitted to relieve the figure. Furthermore, the spinning unit 3 has a spindle shaft bearing 8 for a spindle shaft 9 with an underwind crown 10 and a clamping element 11 as well as a thread guide device arranged on a ring bank 12 with a flange ring 13, a rotor 14 running thereon and a balloon limiter 15. The spindle shaft 9 stands over a belt drive 16 with a motor 17 in connection. A cop 18 with a sleeve 18 'is attached to the spindle shaft 9. A drive for the ring bench 12 is omitted to relieve the figure.

A thread 19 runs from the drafting system 4 through the balloon limiter 15 and the rotor 14 onto the cop 18.

The drive controller 4 has a data processing unit 20 with a time measuring device 21 and a memory 22 for spinning programs to be driven, including drive programs for the motors 7, 17 and the ring bench drive. Furthermore, the data processing unit 20 has memory 22 ', 22˝, 22' '' for data relating to the delivery speed (v) of the thread 19 from the drafting device 5, the position of the ring belt 12 and for data relating to the spindle shaft speed. A sensor 23 for the speed of the drafting cylinder 6 and a sensor 24 for the position of the ring bank 12 are operatively connected to the data processing unit 20 via data lines 25, 26, as are control lines 27, 28, 29, which go from the data processing unit 20 to the motors 7, 17 and the ring bench drive.

Figures 2a to 2c schematically show the operating conditions during the phase of the winding.

In all diagrams the time (t) is plotted horizontally, while vertically in Fig. 2a the delivery speed (v) of the thread 19 from the drafting device 4, in Fig. 2b the speed (n) of the spindle shaft 9 and in Fig. 2c the position or height ( h) the ring bench 12 is specified.

The vertically solid dashed lines also mark the same time periods: HW for the phase of the rear turn, UW for the phase of the underwind, LV for the intermediate phase at least reduced thread delivery and NL for the phase of the overrun of the spindle shaft after the delivery termination LA.

In operation of the ring spinning machine 1, triggered and controlled by the drive control 4, a spinning program contained in the memory 20 is executed. Such a spinning program essentially consists of the sections "piecing", "actual spinning process" (winding the bobbin) and "parking spinning", ie creating top, bottom and bottom windings.

Specifically for the stop spinning, the top turn is created at an already reduced spindle shaft speed and this is driven down further for the back turn. These speed reductions take place in dependence on the spinning parameters in such a way that, among other things, the thread balloon is maintained, and consequently, despite the changing operating conditions, there is no fear of thread breakage. The phase of the winding, as described below, is initiated by the data processing unit 20 via an intermediate phase of reduced thread delivery of the thread delivered from the drafting device 5 as soon as a predetermined winding stage of the cop 18 is given and then completed by applying the desired wrap angle.

The predetermined winding stage for initiating the phase of the winding occurs as soon as the ring rail 12 passes the height 0 (FIG. 2c) during the downspinning on the way to the winding position UWS, which means that the thread 19 over the area of the lower edge of the sleeve 18 ' of the cop 18 runs. The height 0 of the ring bank 12 is detected by the sensor 24 and reported to the drive control via the data line 26. This now triggers the intermediate phase of reduced thread delivery (FIG. 2a) of the thread 19 delivered from the drafting device 5, which is done by a corresponding command sent to the motor 7 via the data line 27. Since the spindle shaft 9 still rotates (Fig. 2b), but continues to wind thread 19 from the thread reserve in the thread balloon on the cop 18 until the thread 19 extends between the standing front stretching cylinder 6 and the rotating cop 18 stretched. If the intermediate phase of at least reduced thread delivery then continues for a short time, this has no disadvantageous effect, since the stretched thread 19 is only twisted to an increased extent, but is essentially not exposed to an excessively increasing tensile load. Accordingly, for the intermediate phase of reduced or even stopped thread delivery, a time which is certainly sufficient for the thread balloon to be used up can be provided.

As a result of the intermediate phase of reduced or stopped thread delivery, the thread reserve in the thread balloon is thus eliminated and the thread 19 is stretched, which has the consequence that the thread length subsequently released from the drafting unit 5 corresponds exactly to the thread length further wound on the spindle shaft.

After the intermediate phase of reduced thread delivery, the drive control 4 further lowers the ring bench 12 from the height 0 for activation of the drafting device 5 or its drawing cylinder 6 until the thread reaches the downwind position UWS (FIG. 2c). The underwinding between underwind crown 10 and the clamping element 11 held in the open position or an underwind whorl is formed accordingly.

The drive control 4 now detects the thread length delivered after the intermediate phase of reduced thread delivery via the time measuring device 21 and the sensor 23 for the rotational speed of the stretching cylinder 6 and causes the delivery to be terminated as soon as the thread length required for the desired wrap angle has been delivered from the drafting device 5. Since the thread between the drafting system 5 and the spindle shaft 9 after the delivery is canceled and the free thread length of the Thread balloons stretched, the desired wrap angle is realized with the required precision and repeatability.

During this phase of underwinding, the drive control 4 proportionally reduces the spindle shaft speed and delivery speed, so that before the delivery is terminated there is only a low delivery speed, thus a precise delivery termination is supported.

For the delivery cancellation itself, only the stretching cylinder 6 is shut down by the drive control 4 via the motor 7, while the spindle shaft rotation is maintained for a short overrun time (FIG. 2b). As a result, the underwinding is applied tightly to the spindle shaft, which facilitates doffing and reinforces the thread section between the drafting device 5 and the underwind crown 10 by increased twisting, ie supports the thread breakage at the desired location, ie at the end of the underwinding.

The data processing unit 20 allows control loops to be provided for the various operations, for example as follows:

On the one hand, the thread delivery speed and also the spindle shaft speed can be reduced depending on the approach of the ring rail 12 to the height 0, which enables a precise and soft intermediate delivery stop without fear of a thread break. Furthermore, the thread delivery speed can be reduced with the same advantages as a function of the increasing wrap angle of the winding.

In a preferred embodiment, the thread delivery is only slowed down at the intermediate delivery stop until the thread balloon is dismantled and stretched out.

In a further exemplary embodiment, the phase of the underwinding is initiated independently of the top or rear windings. The intermediate delivery stop then takes place while the Overwind. It is then necessary to create a backwinding with a predetermined slope in order to ensure that during the backwinding no thread reserve similar to the thread balloon arises and falsifies the value of the thread length lying in the underwinding. A backward twist with a predetermined slope arises from the detection of the ring bank movement and corresponding control of the thread delivery speed by the data processing unit 20.

In yet another exemplary embodiment, a further control loop for the target position is created via the ring bench drive that can be controlled by the drive controller 4.

Claims (14)

Method for creating a winding of a predetermined wrap angle on a spindle shaft of a ring spinning or twisting machine with a cop, characterized in that the length of the thread (19) to be wound is detected from a predetermined winding stage of the cop (18) and the other Delivery of thread (19) is stopped by a delivery abort as soon as the thread length required for the wrap angle has been released. A method according to claim 1, characterized in that the ongoing delivery of the thread (19) is temporarily at least reduced when the predetermined winding stage occurs during an intermediate phase. A method according to claim 1 or 2, characterized in that the spindle shaft (9) is kept rotating after the delivery is canceled. Method according to one of claims 1 to 3, characterized in that the predetermined winding stage is given when the thread (19) is guided over the lower edge of a sleeve (18 ′) of the cop (18). Method according to Claim 4, characterized in that the spindle speed in a phase before the predetermined winding stage is continuously reduced from a speed value selected as a function of the spun thread (19) by a predetermined negative acceleration value. Method according to one of claims 1 to 3, characterized in that the predetermined winding stage is given in the phase of the top winding. A method according to claim 6, characterized in that a rear turn is created with a predetermined slope. Method according to one of claims 1 to 7, characterized in that the detection of the thread length via the delivery speed (v) from the drafting device, preferably by means of pulses generated depending on the angle of rotation of a delivery cylinder, and via the delivery time (t). Ring spinning or twisting machine for carrying out the method according to claim 1, with a frame (2), with spinning or twisting units (3) arranged therein, each consisting of a drafting device (5), a spindle shaft (9) and a corresponding one a ring bench (12) arranged thread guiding device (13, 14, 15) and with at least one drive (7, 17) for spindle shafts (9) and for drafting units (5), characterized in that they have means (21, 23) for detecting the Length of the processed thread (19), means (24) for detecting the predetermined winding stage and a drive control (4) operatively connected to these means (21, 23, 24) with a device (20) for controlling the spindle shaft drive (17) and the Delivery speed of the drafting units (5) has. Ring spinning or twisting machine according to claim 10, characterized in that the means for detecting the thread length include a time measuring device (21) and a sensor (23) for the delivery speed of the thread (19) delivered from the drafting device (5). Ring spinning or twisting machine according to claim 10, characterized in that the sensor (23) is designed as a speed or, in particular, angle of rotation sensor for the foremost drafting cylinder (6). Ring spinning or twisting machine according to one of Claims 9 to 11, characterized in that the means for detecting the predetermined winding stage have a sensor (24) for the position of the ring bench (12) which is preferably provided with its own drive which can be controlled by the drive controller (4) . Ring spinning or twisting machine according to one of claims 9 to 12, characterized in that the drive control (4) has a device for controlling the drafting system drive (5). Ring spinning or twisting machine according to one of Claims 9 to 13, characterized in that the drive control (4) has a time measuring device (21) and memory (22, 22 ′, 22˝) for spinning programs to be driven and for data from the sensors (23, 24 ) regarding the delivery speed (v) and the position of the ring bank (12) as well as a data processing unit (20) and to the drives (7, 17) and control lines (27, 28, 29) leading to the ring bank drive.

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