EP0289009A1 - Method and device for controlling and maintaining a predetermined yarn quality - Google Patents

Abstract

To control the yarn quality of a yarn produced by a textile machine, particularly a false-twist jet spinning apparatus, there is provided at the end of the spinning operation, however, upstream of the pair of withdrawal rolls for the outfeed of the produced yarn, a yarn tension measuring device. Upon falling outside of a predeterminate yarn tension tolerance or tension range the yarn tension measuring device controls operation of the false-twist jet spinning apparatus such that, as required, there is accomplished an appropriate increase or decrease of the yarn tension of the yarn produced by the false-twist jet spinning apparatus. Alteration of the yarn tension can be achieved, for instance, by varying the blowing intensity or energy of the air utilized for the spinning operation as well as by varying the angle at which there is blown in the air used for the spinning operation or by varying the rotational speed of the delivery rolls which deliver the formed yarn or by selected combinations of these measures.

Description

The invention relates to a method for monitoring and maintaining a predetermined yarn quality of a yarn produced by means of a friction spinning device, in which a fiber tube is formed from the fibers delivered to a suction drum or suction disk, from which the yarn is formed, and a spinning device for carrying out the method .

In the production of yarn, the uniformity of the yarn quality per spinning station and in the comparison of the individual spinning stations with one another plays an important role.

From the German laid-open specification DE 3517763 A1, a method and a device for maintaining a predetermined yarn twist is known, in order thereby to obtain control over the uniformity of this yarn quality aspect.

Here, since a direct measurement of the yarn twist is not possible when the spinning process is running, a yarn diameter measurement must be used to infer the yarn twist, which is to be measured contactlessly between the two the yarn and the measuring device, ie can only be measured indirectly.

From DE-OS 34 02 367 and DE-OS 34 24 709 friction spinning processes and devices are known in which two aspirated drums are used, so that an air flow is passed through the two perforated drums. The yarn quality is monitored by means of a yarn tension sensor and, if necessary, corrected by appropriate settings of the device. The devices described are classic friction spinning devices in which a yarn end is formed between the two suction drums and this yarn end is rotated directly with the aid of the surface roughness of the suction drums, with a slippage of approximately 80% of the peripheral speed of the suction drums. I.e. that the peripheral speed of the yarn end corresponds to only about 1/5 of the peripheral speed of the suction drum. This theory is among others DE-OS 36 01 358 can be seen, which is the same method for forming the yarn end.

In contrast to this, the present invention relates to a yarn manufacturing process in which a fiber tube is formed between the two drums, for which purpose it is essential that only one drum is perforated. No slippage occurs between the fiber tube and the drums.

The present invention has for its object to provide in an friction spinning process, in which a fiber tube is formed during the formation of the yarn, with economical means for optimal monitoring of the yarn quality and, in the event of fluctuations thereof, for rapid correction.

Furthermore, a method or a device is aimed at, in which or at least the draw-off rollers of a friction spinning machine having a plurality of spinning positions can be driven together, and the settings required for maintaining the yarn quality can be carried out on individual spinning positions in such a way that the Production speed of the other spinning stations is not required.

In procedural terms, this object is achieved in that the yarn quality is determined by measuring the mechanical tension of the running yarn and the value of this measurement is compared with a predetermined tension value, and in that, if the tension tolerance falls below or is exceeded, the spinning device is acted on accordingly in order to increase or decrease the tension .

In terms of the device, the solution to the problem is characterized in that a thread tension measuring element which emits a measuring signal is provided after the spinning position, as seen in the thread running direction, and in that a means is also provided which changes the thread tension by the means moving the suction nozzle in such a way that that the suction slot is displaceable in the direction of movement of the suction drum or the suction disc and opposite thereto.

In this case, display means for displaying the thread tension or control means can be provided in order to actuate the means for changing the thread tension on the basis of the measurement signal mentioned.

Further advantageous embodiments are defined in the subclaims.

• Fig. 1 einen Querschnitt durch eine Friktions-Spinn­vorrichtung, halbschematisch dargestellt,
• Fig. 2 eine Draufsicht der Vorrichtung von Fig. 1, jedoch unter Weglassung gewisser Elemente zur besseren Darstellung und unter Zufügung anderer Elemente zur Vervollständigung der Vorrichtung von Fig. 1,
• Fig. 3 ein Querschnitt durch die Vorrichtung von Fig. 1, gemäß den Linien I (Fig. 1), leicht vergrößert und halbschematisch dargestellt, und
• Fig. 3A und 3B je ein vergrößerter Ausschnitt der Fig. 3.

The invention is explained in more detail below with the aid of drawings which only show execution routes. It shows:

• 1 shows a cross section through a friction spinning device, shown semi-schematically,
• 2 is a top view of the device of FIG. 1, but omitting certain elements for better illustration and adding other elements to complete the device of FIG. 1,
• Fig. 3 shows a cross section through the device of Fig. 1, along lines I (Fig. 1), slightly enlarged and shown semi-schematically, and
• 3A and 3B each an enlarged section of FIG. 3rd

A friction spinning device comprises, in a manner known per se, an opening roller 1 with a fiber conveying channel 2 connected to it, the outlet mouth 3 of which adjoins contactlessly but close to a suction drum 4 (see also FIG. 3). The suction drum has, as partially indicated by 5, a perforation. In addition, the suction drum 4 has a suction nozzle 6 inside, which is contactless, but is close to the inner wall 7 of the suction drum 4. With the help of this suction nozzle 6, which is connected to a vacuum source (not shown), air is conveyed through the fiber conveying channel 2 and through the perforation 5 of the suction drum 4.

The suction nozzle 6 comprises an upper wall 8 and a lower wall 9, as seen in the direction of FIG. 3, and lateral end walls 10 (shown in FIG. 2 with dashed lines). The suction nozzle 6 is further connected to a connection channel 11.

The walls 8, 9 and 10 define a suction slot with the width B (FIGS. 1 and 3) and the length L (FIG. 2) adapted to the inner wall 7.

The connection channel 11 is rotatably mounted in a rotary bearing 12 (shown in section), which is fixedly received in a fixed housing part 13 (shown in section).

For rotating the connection channel 11 in order to pivot the suction nozzle 6 about the axis of rotation 14 of the connection channel 11, a guide element 15 is attached to the connection channel 11, which lies on a cam 17 with an associated sliding surface 16. This cam 17 is pivotally mounted on the one hand in a pivot bearing 19 which is fixedly connected to a fixed housing part 18 (indicated by hatching) and on the other hand is connected to a servomotor 21 by means of a joint 20. The servomotor in turn is firmly connected to a fixed housing part 22. Such servomotors are known per se and can be of electromagnetic type, for example.

On the end opposite the connection duct 11, the suction drum 4 is rotatably mounted in a rotary bearing 25 which is fixedly connected to a fixed housing part 26.

A counter drum 24 is provided parallel to the suction drum 4 and, unlike the suction drum 4, is not perforated. This counter drum 24 is rotatably mounted in a rotary bearing 23 which is movable as a whole in the directions C in a fixed sliding guide (not shown), but is not lifted off the sliding guide.

The suction drum 4 is driven by a motor 27 attached to the housing part 26.

The counter drum 24 is driven by means of an elastic belt 28 stretched around the suction drum 4 and around the counter drum 24.

In order to carry out the movements of the counter drum 24 in the directions C, a guide element 29 is fastened on the one hand to the rotary bearing 23, which lies on a cam 31 with a sliding surface 30. The cam 31 is pivotably mounted in a fixed pivot bearing 32 and connected to a fixed servomotor 34 by means of a joint 33.

On the other hand, on the side of the rotary bearing 23 opposite the cam 31, a compression spring 35 is fixedly arranged between the rotary bearing 23 and a fixed housing part 36.

A yarn 37 produced by the friction spinning device is drawn off in the direction D by a pair of take-off rollers 38.

A thread tension measuring device 39 is provided in front of the pair of draw-off rollers 38, viewed in the thread running direction D. Such devices are known per se and are available on the market, for example, under the brand name Electronic Tensiometer R-1192 from Rothschild, Traubenstrasse 3, CH-8002 Zurich.

A measurement signal 40 generated by the thread tension measuring device 39 is received by a controller 41, which is not the subject of the invention, and processed into output signals described later.

In operation, a sliver (not shown) is fed into the opening roller 1 and dissolved into individual fibers by this and conveyed onto the surface of the suction drum 4 by means of the fiber conveying channel 2.

This process is explained in more detail with the aid of FIGS. 3a and 3b.

The air flow emerging from the fiber feed channel 2 is designated M and the air flow passing through the narrowest gap F is designated N. These two air flows are created by the suction effect of the suction nozzle 6 in the width B and length L of this suction nozzle.

A fiber 42 (FIG. 3A) deposited by the air flow M on the surface of the suction drum 4 is transported in accordance with the direction of rotation E on this surface against the narrowest gap F until the front fiber end 43 (FIG. 3A) is bent back and back by the lower air flow N. is brought to the named surface in order to be transported again in the direction of E.

If one now thinks of this process not only for a single fiber, but for all delivered fibers, it can be imagined that this cycle creates a so-called fiber tube 44, which due to the direction of rotation E of the suction roller and the direction of rotation K of the counter roller 24 in Direction of rotation H (Fig. 3B) rotates at a peripheral speed which is essentially the peripheral speed of the drums 4 and. 24 corresponds to. The yarn 37 condenses in the running direction D from this fiber tube 44.

This process was first described in German in German Offenlegungsschrift No. 2919316 published.

If the suction nozzle 6 is now shifted in the direction of rotation P (FIG. 3B), the fiber tube 44 also shifts in the same direction and becomes smaller in cross section up to a minimal cross section in the area of the narrowest gap F. It has now been found that this reduction in cross-section and the increased wedge effect of the fiber tube 44 located in the wedge gap of the two rollers 4 and 24 result in a higher thread tension and a greater twist on the yarn 37. The yarn 37 is the yarn part in front of the draw-off roller pair 38, viewed in the thread running direction D.

Another variable for changing the tension in the yarn 37 is to change the narrowest gap F. As the gap F narrows, the cross section of the fiber tube also decreases and the thread tension in the yarn 37 also increases.

The controller 41 now determines whether the respectively measured thread tension (also called thread tension) lies within a predetermined tolerance range and, if this is not the case, causes a change in the gap width F within a predetermined tolerance range and / or a swiveling of the suction nozzle 6 within a specified tolerance range.

The size of the change in the gap width F including the predetermined tolerance range or the size of the pivoting of the suction nozzle 6 including the predetermined tolerance range must be determined empirically depending on the concept of the device, with the concept of the diameter of the drum 4 or. 24, the surface roughness of this drum, the amount of air sucked in etc. It is also possible to change the speed of rotation of the drums.

Which of the three above-mentioned steps is to be carried out or, if two or three of the above-mentioned steps are combined, the choice of the step or the sequence of the mentioned steps must be determined empirically, for example that first the position of the suction slit 6 and then the gap width F is changed.

If the voltage tolerance is undershot, the gap width F is reduced and / or the suction slit 6 in Movement direction E shifted, respectively. if the voltage tolerance is exceeded, the two aforementioned measures are carried out in the opposite direction.

The control 41 shown for the friction spinning device of FIGS. 1 and 1A is intended as an individual control per so-called spinning station (a plurality of spinning stations result in a spinning machine). However, it is understood that such a solution is expensive and is not absolutely necessary due to the usually slow voltage changes.

It is therefore known from the rotor-open-end spinning process that so-called traveling devices carry out control and operation functions on respective spinning units, as a result of which an optimization in terms of cost and frequency of the operations to be carried out per spinning station can be achieved.

It is therefore understood that a whole series of variations can be provided in connection with traveling devices, for example that all servomotors provided for the adjustment of the elements are provided per spinning station and that only the thread tension measurement and the control of the traveling device are assigned, which mechanically represents the simplest solution.

Another variant is that a traveling device only measures the thread tension and displays it by display means (not shown) and that the elements to be adjusted in order to change the thread tension are operated manually until the thread tension is again within the given tolerance range.

Another application of the thread tension measurement consists in the simple monitoring of the spinning position by means of the thread tension measurement, that is to say that none of the measures mentioned for changing the thread tension are carried out and it is decided on the basis of the given thread tension tolerances to shut down the spinning position in order to remedy corresponding defects .

It is therefore understood that the inventive idea of using the thread tension in order to keep the corresponding spinning device at a yarn quality level which corresponds to the desired yarn quality is not restricted to the examples shown and described.

Claims (14)

1. A method for monitoring and maintaining a predetermined yarn quality of a yarn (37) produced by means of a friction spinning device, in which a fiber tube (44) is formed from the fibers delivered to a suction drum or suction disk, from which the yarn is formed,
characterized in that the yarn quality is determined by measuring the mechanical tension of the running yarn (37; 81) and the value of this measurement is compared with a predetermined tension value,
and that if the voltage falls below or exceeds a predefined tension tolerance, the spinning device is acted on accordingly in a tension-increasing or tension-reducing manner. 2. The method according to claim 1,
characterized,
that the thread tension is continuously monitored. 3. The method according to claim 1,
characterized,
that the thread tension is monitored intermittently. 4. The method according to claim 2 or 3,
characterized,
that the spinning device is acted upon immediately after falling below or exceeding the specified tension tolerance. 5. The method according to claim 2,
characterized,
that after falling below or exceeding the specified voltage tolerance, the spinning device is shut down until a point in time at which it can be acted on accordingly. 6. The method according to claim 4 or 5,
characterized,
that after unsuccessful action on the spinning device, it is stopped for troubleshooting. 7. friction spinning device for carrying out the method according to the preceding claims,
- wherein the spinning device comprises a spinning station (4, 24),
- And the spinning position is defined by a suction zone (B, L) on the outer surface of a suction drum (4) or suction disc (not shown) and
that this suction zone is provided by a suction slot (B) provided in a suction nozzle (6), which adjoins the inner surface of the suction drum or suction disc opposite the outer surface mentioned and sucks air through the suction zone,
- That the suction drum (4) or the suction disc is assigned a counter drum (24; not shown), which is arranged with a narrowest gap between the suction drum or suction disc and counter drum, given distance (F) from the suction drum or suction disc ,
- characterized,
that a thread tension measuring element (39) which emits a measuring signal is provided after the spinning station, viewed in the direction of the thread, and
- That furthermore a means (21) is provided which changes the thread tension by the means moving the suction nozzle (6) in such a way that the suction slot can be displaced in the direction of movement of the suction drum or the suction disc and in the opposite direction. 8. The device according to claim 7,
characterized,
that display means (not shown) are present for displaying the thread tension based on the measurement signal. 9. The device according to claim 8,
characterized,
that the means for changing the thread tension can be actuated manually on the basis of the display on the thread tension display means. 10. The device according to claim 7,
characterized,
- That control means (41; 70) are provided to automatically actuate the means for changing the thread tension on the basis of the measurement signal mentioned. 11. The device according to claim 7,
characterized,
- That another means (34) changes the thread tension by the further means the suction current mel resp. Suction disc or counter drum moved such that the distance (F) between them can be changed. 12. Use of the device according to claims 7 and 11,
characterized,
that if the voltage tolerance is undershot
- said distance (F) is reduced and / or
- The suction slot in the direction of movement of the suction drum, respectively. the suction disc is moved,
- resp. if the voltage tolerance is exceeded, the two aforementioned measures are carried out in the opposite direction. 13. The apparatus according to claim 7,
characterized,
that the thread tension measuring element (39; 68) is provided per spinning station. 14. The apparatus according to claim 7,
characterized,
that the thread tension measuring element (39; 68) is slidable from spinning station to spinning station.

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