DE10306475A1 - Rotary thread guide for ring spinning machines, is constructed as small rotary tube with carrier for thread running through - Google Patents

Abstract

The thread guide (1) is constructed as a small rotary tube (11) with a carrier (13) for the thread running through. The carrier is a spiral (13). Its angle exceeds 360[deg], preferably being about 540[deg]. The carrier has an edge lying in a plane at right angles to the axis of rotation of the spiral. The edge (14, 15) is a curved bridge section. Upper and lower ends of the spiral are each constructed as an edge. The thread guide has a casing (2) in which the rotary tube rotates. Its thread inlet opening (21) is eccentric to the axis of tube rotation. The small rotary tube has an eccentric thread outlet bore (23). The eccentricity (e) corresponds approximately with the diameter of the carrier core. The thread guide has a push-on casing (34) at a spacing (h) from the upper end of the ring spindle (3). The ring spindle projects out at least 50 mm from the upper end of the casing. The thread guide is swung from its operational position into a servicing position, where it can be coupled with a suction unit (5), which it operates through this movement. A carrier having wear resistant surface is also claimed. Its coefficient of friction is a function of the grain size of material forming its surface.

Description

The invention relates to a rotating thread guides for ring spinning machines, the one at a distance above the upper end of the ring spindle is arranged and over a magnetic force field is coupled to the ring spindle, so that the thread guide with the same speed as the ring spindle rotates.

It is a known fact that the threads on the Ring spinning machine mainly between drafting device and thread guide break in the so-called spinning zone. In this area is that from the drafting system emerging fuses not yet solidified so that everyone Thread tension tip has grown. In addition, the conventional Thread guides, the so-called thread guide eyelet the rotation propagation partially obstructed in the spinning zone.

It has therefore already been proposed, so-called Put crowns on the ring spindle to the one on the ring revolving runner to make outgoing swirling towards the spinning triangle more effective, in order to better solidify the resulting from the To reach drafting device emerging fuse. With these spindle attachments the thread goes into the prongs of the crown and is carried along by it, however, the yarn must make the same backward movement on the crown, like the runner on the spinning ring, which corresponds to the winding and the winding speed lags behind the peripheral speed of the spindle. The thread jumps backwards from point to point according to the lag of the runner. The resulting friction leads for yarn damage and to roughen the yarn, which is undesirable. Generated additionally every jump a bump on Runner. These crown screw attachments therefore have a big one Runner wear results. With the so-called spinning finger as an attachment to the ring spindle the crown prongs avoided, the spinning finger is smooth and robs the yarn thereby less. However, the spinning finger works practically like a crown with a jag around which the yarn runs. The means that the Jump is a lot bigger namely almost a turn. The runner stops briefly at this moment of jumping and then turns accelerated again. This spinning finger solution therefore leads to large thread runs. Besides, can the spinning finger cannot be balanced, which is why special spindle bearings are necessary are able to endure this imbalance.

To avoid these disadvantages it has been proposed to provide a rotating thread guide. This rotating thread guide consists of a ball-bearing thread guide tube, which expediently Ceramic is made, which over the upper part of the spindle Ring spindle independent of this is mounted on the machine frame, and in the spindle head and arranged in the thread guide tube Permanent magnets magnetically coupled to the ring spindle and at Rotation of the same is taken. The spindle speed will be like this transmitted synchronously to the thread guide tube by this magnetic coupling. This known device gives the thread in the spinning zone Wrong rotation due to the touch of the thread as it passes through the swirl tube and the edge of the upper part of the spindle. However, it has been shown that the Effect of this rotating thread guide is unsatisfactory because the thread at the touch is exposed to considerable slip, so that the false wire production is unstable and therefore unsatisfactory. Add to that the intermittent Mode of operation, since the thread only during the fraction of one Balloon or rotor revolution on the friction body Completely is applied and experiences a torque. Moreover the effect of the known device is strongly dependent on the course of the thread dependent. A really significant reduction in thread tension and / or of thread breaks has not shown. Apart from the threading problems, there is the thread break problem not on the ring spinning machine due to the rotating thread guide generally solve to let. A disadvantage has also been found in that magnetic coupling of spindle and thread guide to a controlled thread guide movement must be dispensed with from the outset (International Textile Practice 1982, January, pages 19 and 20).

The object of the invention is this Avoid disadvantages of the prior art and a device to create that is capable of better and more defined rotation propagation to ensure up to the spinning triangle.

This task is due to the characteristics of claim 1 solved.

By designing the thread guide as a rotating tube with a take-away for the thread running through, the thread is given a real twist in the critical area between the thread guide and the drafting device, precisely at the spindle speed. The inevitable entrainment of the thread eliminates slippage and unpredictability of the entrainment of friction and thus also the influences of the entry angle in the thread guide. The driver is expediently designed as a spiral, since the spiral prescribes a defined wrap around the thread due to its helix. This looping is important because it acts like a brake and thus dampens tension peaks from the rotor and balloon, so that they cannot affect the sensitive area between the thread guide and the drafting system. The spiral of the spiral is expediently greater than 360 °, preferably approximately 420 °, in order to optimally achieve this damping effect. For a good take of the thread without roughening it, the upper and lower ends of the spiral 13 formed as an edge that lies in a plane perpendicular to the axis of rotation of the spiral and is appropriately rounded. The rotating tube is expediently arranged rotatably in a housing net. This encapsulation not only protects the rotating tube and the thread run, but also prevents winding or knotting of the thread if the thread breaks. In addition, this encapsulation enables automatic threading using suction air, which leads to savings in operating times when removing threads.

The eccentric arrangement of the thread inlet bore has surprisingly meant that none Ballooning between thread guide and drafting system is created. The eccentricity suitably depends on the diameter of the core of the driver. To avoid excessive thread tension it has proven to be useful that thread guides at a certain distance from the top of the ring spindle attached sleeve centric over the end of the ring spindle. There is a distance of at least 50 millimeters has been found to be cheap, with the Diameter of the spinning ring and the balloon produced thereby Role play.

The swiveling of the thread guide from one Operating position in an operating position not only enables a problem-free manual or mechanical deduction of the cops, but also serves for maintenance and keeping the thread guide clean. Is expedient the thread guide can be coupled with a suction device in the operating position the thread guide can simultaneously operate by moving into the operating position. In this way, the thread guide cleaned of flight and by the suction device the thread for re-spinning in the thread guide threaded.

Further details of the invention are described ^un gen reference to the Drawing.

Show it

1 the thread guide arrangement according to the invention in connection with the ring spindle and a suction device;

2 according to the driver designed as a spiral 1 ;

3 a plan view of the driver according 2 ;

4 a plan view of the housing according to 1 ;

5 another embodiment of the thread guide according to the invention.

In 1 is an embodiment of a rotating thread guide 1 shown in section. It consists of a housing 2 with an eccentrically arranged yarn inlet opening 21 in a ball bearing 16 rotatable rotating tube 11 with a centrally arranged thread outlet opening 22 , In the rotating tube 11 is the driver 13 stored and rotatably connected to this, so that this driver 13 with the rotating tube 11 turns together. The housing 2 is stationary on the bearing ring 17 put on, to accommodate the ball bearing 16 serves. The bearing ring 17 is by a holder 18 added to a hinge 19 is pivotable. This allows the thread guide 1 in the operating position shown in dashed lines 1' be swung up so that the head of the spindle 3 free and for removing the cops and reattaching sleeves 4 is accessible.

Another suction device is located on the ring spinning machine parallel to the usual sliver suction arranged under the drafting rollers 5 arranged in the form of a tubular profile. Every spinning station is on this tube 5 a suction opening 51 assigned to which the thread inlet opening 21 the thread guide 1 in the operating position 1' creates so that by the suction device 5 Suction air through the thread guide 1 is sucked through. On the one hand, this suction pull serves to keep the thread guide clean 1 of flight and similar loose deposits. On the other hand, the spindle can 3 raised thread in front of the central thread outlet opening 22 be placed so that this in the thread guide 1 is sucked in and thus threaded. The thread guide is used for re-spinning 1 from its operating position 1' folded down into the operating position. Which emerges from the thread inlet opening 21 into the suction opening 51 extending thread is picked up for the start of the spinning process and placed on the drafting device in a known manner.

The suction opening is expedient 51 by the movement of the thread guide 1 Can be opened and closed to avoid unnecessary air consumption in the operating position. This can be done in a simple manner in that at the thread inlet opening 21 the thread guide 1 a cam is arranged which closes the suction opening 51 presses or operated in another way, so that the suction device 5 is activated when the thread guide 1 in the operating position 1' to the suction opening 51 creates, and the suction opening 51 is closed again when the thread guide 1 is pivoted back into its operating position ..

That of the spindle 3 facing part of the rotating tube 11 is designed as a magnet and forms with the head 31 the spindle 3 , which is also equipped with permanent magnets, a magnetic coupling, so that the rotating tube 11 at the same speed as the spindle 3 circulates. The distance of the spindle head 31 from the rotating tube 11 is determined in a known manner by the magnetic field which is necessary to ensure that the rotary tube is carried along with the spindle. As a rule, this distance is about 5 to 10 mm.

In the simplest version, the driver is like 5 shows, designed as a cross or T and consists of the core 12 ' and an edge 14 that act as crossbars in the core 12 ' is anchored. That edge 14 takes the through the thread inlet 24 entering thread and gives it the rotation analogous to the spindle speed. Via an eccentrically arranged thread outlet opening 23 in the rotary tube 10 the thread leaves the thread guide 100 , Here too is the rotating tube 10 in a ball bearing 16 rotatable in the bearing ring 17 on the holder 18 stored. The magnetic coupling between the spindle head described above is used to carry the device 31 and the rotating tube 10 ,

To prevent the full tension of the balloon from spreading between the thread guides 100 and drafting system output, the thread is around the core 12 ' of the driver 12 wound. Depending on the friction value of the surface of this core 12 ' of the driver 12 is looped once or twice to get the desired damping. According to this simple version 5 For such a wrap, an increased period of manual threading by the operator is required. The housing 20 must also be removable for this purpose. In addition, only whole or half loops are possible. A finer gradation would only be given if a further crossbar, for example offset by 90 ° to the edge 14 would be provided.

When running in 1 is therefore the driver 13 formed as a spiral, as in 2 shown in detail. The spiral 13 has an edge on both its upper and lower ends 15 on which the thread goes into the spiral 13 runs in or out of the spiral. The helix α makes the loop around the core 13 ' automatically determined. As described above, the thread is sucked in and automatically lies in the spiral 13 and the desired wrap is made. This edge is used to ensure a gentle thread run during operation and easy threading 15 preferably designed as a rounded web.

Due to the heavy strain caused by the thread, it is advisable to use this spiral 13 Made of ceramic or metal with a wear-resistant sinter coating. Via the sintered coating or the surface of the ceramic part, it is possible to give a certain friction value μ of the surface and thus to determine the desired damping in addition to the wrapping. Experiments have shown that the desired damping is achieved with a helix α of at least 360 °. A helix of α = 540 ° (about 1 1/2 loops) has proven to be optimal. The damping works in the following way: Due to the friction of the thread as a result of the looping on the driver 13 respectively. 14 a stronger pull from the thread balloon is required, which has the consequence that the balloon becomes smaller. On the other hand, the tension in the spinning zone between the thread guide and the drafting system is significantly reduced, since this is held back by the friction. In particular, tension peaks, which are formed by runners and balloons and which have often led to thread breaks, are eliminated from the spinning zone.

The thread guide works as follows: The thread running out of the drafting system runs through the thread inlet opening 21 respectively. 24 in the housing 2 the thread leader 1 or the housing 20 the thread guide 100 and leaves through the yarn outlet 22 respectively. 23 the thread guide. The one with the driver 13 peripheral edge 15 or driver 12 with edge 14 detects the thread extending through the housing and gives it rotation with the spindle speed by the entrainment. The rotating tube 10 respectively. 11 runs over the thread balloon in usually under the runner rotating on the spinning ring for winding onto the sleeve 4 , Since the rotor lags behind the angular velocity of the spindle by the winding, the real rotation that the thread has received in the spinning zone is reduced again by this amount. It is advantageous, however, that for the solidification of the fuse emerging from the drafting device in the spinning zone, a higher one and by the driver 12 respectively. 13 rotation is given that corresponds exactly to the spindle speed and continues without problems along this short distance into the spinning triangle. This leads to an exact and constant rotation. Jumping over crown prongs or the like is eliminated, as are the imponderables of swirling due to friction.

Compensating the difference between the angular speed of the spindle 3 and the angular velocity of the rotor takes place after the thread passes the rotating tube 11 respectively. 10 has left. The thread can be in the space between the spindle head 31 and the rotating tube 10 respectively. 11 move freely so that this compensation takes place continuously in contrast to the measures known from the prior art for the propagation of rotation. The thread should move as freely as possible here, it may be the spindle head 31 touch, but should not rub against it in such a way that a torque occurs in the direction of rotation. There is therefore a distance h between the top edge of the sleeve 4 and the thread guide 1 respectively. 100 to be observed so that a sufficiently large balloon is created even in the uppermost position of the ring bench and thus the spindle head 31 if possible not touched at all or only slightly. On the other hand, the magnetic coupling to the thread guide 1 respectively. 100 a small distance of about 5 to 10 millimeters between the spindle head and the rotating tube 10 respectively. 11 to guarantee the transport. It is therefore necessary to place the spindle at least 50 millimeters above the end of the sleeve 4 to extend. Depending on the spinning ring diameter and the resulting thread balloon, the extension should correspond at least to the spinning ring diameter.

When running in 5 is a central thread inlet hole 24 shown while executing in 1 the thread inlet bore 21 is arranged eccentrically. It has surprisingly been found that the eccentric thread inlet drilling 21 more advantageous than a central thread inlet bore 24 there is a balloon formation between thread guide 1 respectively. 100 and drafting system exit through the eccentric arrangement of the thread inlet bore 21 is avoided. The eccentricity e of this thread inlet bore 21 to the axis of rotation of the driver 13 supposed to be about the diameter of the core 13 ' the spiral 13 correspond ( 4 ). In order to form a balloon even when running 5 to avoid the thread inlet bore 24 around the diameter of the core 12 ' eccentric to the axis of rotation of the driver 12 to be ordered.

1,100

thread guides

1'

operating position thread guides

10.11

rotary tube

12

takeaway

12 '

core of the driver

13

driver, spiral

13 '

core the spiral

14.15

edge

16

ball-bearing

17

bearing ring

18

holder

19

hinge

2.20

casing

21.24

Yarn inlet hole

22.23

Fadenauslaßbohrung

3

ring spindle

31

Magnetic attachment, spindle head

4

shell

5

suction

51

suction opening

Claims (20)

Rotating thread guide for ring spinning machines, which is arranged at a distance above the upper end of the ring spindle and is coupled to the ring spindle via a magnetic force field, so that the thread guide rotates at the same speed as the ring spindle, characterized in that the thread guide ( 1 . 100 ) as a rotating tube ( 10 . 11 ) with a carrier ( 12 . 13 ) is designed for the continuous thread. Device according to claim 1, characterized in that the driver as a spiral ( 13 ) is trained. Device according to claim 2, characterized in that the helix (α) of the spiral ( 13 ) is greater than 360 °, preferably about 540 °. Device according to one of claims 2 or 3, characterized in that the driver ( 12 . 13 ) an edge ( 14 . 15 ), which lies in a plane perpendicular to the axis of rotation of the spiral. Device according to claim 4, characterized in that the edge ( 14 . 15 ) is designed as a rounded web. Device according to one of claims 4 or 5, characterized in that the upper and lower ends of the helix act as an edge ( 15 ) is trained. Device according to one or more of claims 1 to 6, characterized in that the thread guide ( 1 . 100 ) a housing ( 2 . 20 ) in which the rotating tube ( 10 . 11 ) is rotatably arranged. Device according to claim 7, characterized in that the housing ( 2 ) a thread inlet bore ( 21 ) which is eccentric to the axis of rotation of the rotating tube ( 11 ) is arranged. Device according to one of claims 7 or 8, characterized in that the rotating tube ( 10 ) a thread outlet bore ( 23 ) which is arranged eccentrically. Device according to one of claims 8 or 9, characterized in that the eccentricity (e) approximately the diameter of the core ( 12 ' . 13 ' ) of the driver ( 12 . 13 ) corresponds. Device according to one or more of claims 1 to 10, characterized in that the thread guide ( 1 . 100 ) at a certain distance (h) to the upper end of the ring spindle ( 3 ) attached sleeve ( 4 ) centered over the end ( 31 ) the ring spindle ( 3 ) is arranged. Device according to claim 11, characterized in that the ring spindle ( 3 ) at least 50 mm above the upper end of the sleeve ( 4 ) protrudes. Device according to one of claims 11 or 12, characterized in that the ring spindle ( 3 ) at least by the diameter of the spinning ring over the upper end of the sleeve ( 4 ) protrudes. Device according to one or more of claims 1 to 13, characterized in that the thread guide ( 1 . 100 ) from its operating position to an operating position ( 1' ) is pivotable. Device according to claim 14, characterized in that the thread guide ( 1 . 100 ) in the operating position ( 1' ) with a suction device ( 5 ) can be coupled. Device according to one of claims 14 or 15, characterized in that the thread guide ( 1 . 100 ) by its movement into the operating position ( 1' ) the suction device ( 5 ) operated. Driver for a rotating thread guide for ring spinning machines according to one or more of claims 1 to 16, characterized in that the driver ( 12 . 13 ) consists of wear-resistant material. Driver according to claim 17, characterized in that the driver ( 12 . 13 ) has a wear-resistant coating. Driver according to one of claims 17 or 18, characterized in that the driver ( 12 . 13 ) is designed as a spiral. Carrier according to one or more of claims 17 to 19, characterized in that, due to the grain of the material, the coefficient of friction μ of the surface of the carrier ( 12 . 13 ) is determined.