DE1560305C - Method and device for spinning fibers - Google Patents

Description

The invention relates to a method and a device for spinning fibers by means of a spinning turbine.

In the known spinning turbines, fibers are fed into individual fibers by means of a suitable feed element fed in dissolved sliver, collected in a collecting channel and as a thread through an in the spinning turbine axis lying stationary or rotating thread outlet tube withdrawn. With this one The process must involve the twisting of the thread in the thread outlet tube up to the fiber binding point be brought up. However, the deflection at the mouth of the thread outlet tube arises a rotation jam. It is therefore the aim to achieve this To minimize rotation jam; For example, it is known to give the yarn to be withdrawn a false twist to grant and by appropriate shaping of a drivable thread outlet tube another To achieve a reduction in the rotation congestion (German Auslegeschrift 1 178 336). Also was the Rotation propagation increased by overwinding by increasing the friction of the thread exit tube (German Auslegeschrift 1 111549). However, this type of rotation propagation does not have the desired effect Brought success.

The present invention is based on the recognition that the rotation propagation mainly due to the deflection of the thread as it exits the thread outlet tube resulting contact pressure is impaired. This contact pressure increases depending on the Centrifugal force with increasing speed of the spinning turbine. .

The invention is therefore based on the object of eliminating or at least eliminating this contact pressure largely reduced in order to improve the rotation propagation and thus the prerequisite for increased haul-off speed and higher production.

This object is achieved according to the invention in that the thread tension between the fiber binding point and take-off device is changed briefly periodically.

To carry out the method, the thread outlet tube has, for example, a spacing between them to the thread binding point on the fiber ring in the collecting channel periodically changing mouth within the Spinning turbine on. For this purpose, the thread outlet tube with its located in the spinning turbine Mouth be mounted to swing longitudinally or transversely. Also the mouth can of the thread outlet tube eccentric to the orbit of the fiber binding point surrounding the mouth be arranged, the thread outlet tube preferably in a rotatable, the Eccentricity of the orifice adjusting insert is mounted. Advantageously, they are adjustable stored thread outlet tubes of several spinning stations together by an adjusting device connected and adjustable together. But it is also possible to reduce the vibrations of the piece of thread to produce by means of a thread outlet tube, which is inclined with respect to its longitudinal axis Mündungsquerschniu or a provided on the mouth edge of the Fadenaustriüsrohres nose or Has groove. The frequency of the vibration generated by the short-period changes in thread tension can, independently of the spinning turbine speed, additionally by the rotation of such a Thread outlet tube are influenced.

One eccentric to the orbit of the fiber binding point arranged mouth of the thread outlet tube is already through the German Patents 963,400 and 1,000,267 are known. In doing so, the inclined collection tube moves on along the roll surface or the inside wall of the drum, creating new fibers in these removal parts fed and spun with a delay determined by the take-off speed will. The distance between the mouth of the sampling tube and the sampling point remains always constant, so that it is impossible to generate vibrations with this pipe.

The present invention has the advantage that by the vibration of the contact pressure on the Mouth of the thread outlet tube periodically ge changes, so that the resulting in the thread outlet tube Rotation of the thread can easily propagate. There is thus a higher take-off speed and thus a more economical production of the yarn is achieved. The thread also falls as a result of decreased Friction smoother. On the other hand, the resulting from the vibration movement can changing longitudinal tensions do not affect the yarn, as this is due to the high frequency The change in tension is always within the range of the fiber length.

Details of the invention are explained with reference to the drawings. Show it

Fig. 1 to 3 spinning turbines with centrally arranged Yarn outlet tube in longitudinal or cross-section,

F i g. 4 to 6 differently designed thread outlet tube mouths in a perspective view, Fig. 7 to 9 spinning turbines with eccentrically arranged Thread outlet tube in cross and longitudinal section,

10 to 11 a device for stepless Adjustment of the eccentricity of the. Thread outlet tube in plan view and in longitudinal section;

Fig. 12 shows a spinning turbine with angled, eccentrically opening thread outlet tube in longitudinal section;

13 to 18 show the spinning turbine according to FIG. 12 in cross section during various working phases,

19 to 21 devices in longitudinal section for imparting a vibration directly to the thread. A spinning device with a spinning turbine 2, the shaft 21 of which is mounted in a housing 1, has a cover 11 which is fastened on the housing 1 and thus opposite the spinning turbine 2 is stationary. The cover 11 also serves as a cover for the spinning turbine 2. A fiber feed tube 51 opens eccentrically into the spinning turbine 2 on the cover 11. The housing 1 is connected to a suction line 4 connected. A thread outlet tube 31 extends into the spinning turbine 2. It does not matter It matters whether this is arranged in the tubular shaft 21 or in the cover 11 or elsewhere. The spinning turbine 2 is driven via a whorl 22 seated on the end of the shaft 21 over the strap 23.

In a known manner, for example, by a feed device 5 via the fiber feed pipe 51 fibers F are fed into the spinning turbine 2, in

3 4

which is guaranteed due to the centrifugal force at the point of magnets, the excitation frequency of the largest diameter, ie in the collecting channel with the resonance frequency of the thread outlet tube 24, a fiber ring R forms. The supply of the fibers 31 are brought into agreement,
in the spinning turbine 2 is effected by a suction air as a vibration drive for the thread outlet tube A from the line 4 or by the rotation 5 31 in the spinning turbines described, each of the spinning turbines itself can be effected. Find the thread end of the suitable vibration motor application, e.g. B. finished thread G stands with the fiber ring R in electrical oscillating motors, electromagnets, crank binding and rotates with this so that this drives or cam drives.
The thread end acts like a crank arm and so the There are still further thread G in its in the thread outlet tube 31 located in the thread outlet tube 31 for the vibration distribution. For example, the thread-like thread outlet tube reaching as far as the take-off rollers 3 or only its mouth can be given an eccentric piece of rotation. Since the loose fibers of the to the orbit of the opposite to the opening around the thread ring R are arranged to form a continuously running fiber binding point £,
drawable thread tied into the thread end While in the spinning turbine 2 ″ according to FIG of the radial thread-generated rotation propagates into the thread end to the one-piece G at every moment of the spinning process binding point E on the fiber ring R. In order to remain constant, this length changes with an eccentric twist jam at the thread exit tric arrangement of the mouth 32 of the thread tube mouth To prevent this, according to the invention 20 outlet pipes 31.

which is located between the take-off rollers, 3 and the In the position according to FIG. 7 is the distance

Thread binding point £ on the fiber ring R extending between the mouth 32 and fiber binding point E on

Thread piece G given a vibratory movement. By greatest. The piece of thread G is therefore stretched and

the in rapid succession changing longitudinal tension of the stretched (G 1) and exerts on the mouth 32nd a

The thread also changes the contact pressure at the contact pressure caused by the thread tension

Thread outlet tube mouth or is thereby under-. After half a turn, however, in the direction

broke. so that the rotation about this reversal of the arrow P (Fig. 8) is the distance between

control point can propagate. The vibratory movement of mouth 32 and fiber binding point £ smallest,

can be applied to the thread in different ways. The previously stretched piece of thread is therefore loose

will. 30 and relaxed (G 2). The rotation propagation

According to Fig.l the thread outlet tube 31 is at this moment no contact pressure hindering by an oscillating motor 30 on the arm 33 in opposition, so that the rotation is displaced up to the fiber axial oscillations, whereby the end of the binding parts E is brought up. For this of the thread G each short from the Mühdung 32 of the reason, the thread withdrawal speed increases Fadenaustrittsrohres31 solves until it is through the take-off 35, without the risk of thread breakage device 3 again tensioned and thus occurs due to the low solidification of the thread. -. .. Muzzle is pulled. This process is repeated. An example of the eccentric arrangement of the thread outlet tube is shown in very rapid succession, so that no incorrect distortions. That can arise. The tension changes as a result of the thread outlet tube 310 is here in the cross section of the vibration movements of the thread G are located at 40 level of the cover 11, with its given take-off speeds and spinning mouth 325 outside the spinning turbine turbine speed consistently in the area of the length axis. .
of the individual fibers F. A further embodiment is shown in FIG

Due to the vibration movements, the hand of a hanging spinning turbine changes 2. The thread distance between the mouth 32 of the thread outlet 45 outlet tube 313 is centrally connected to the cover 115 31 and fiber binding point E. It can arrange, but it ends eccentrically to the rotation, the vibrations through longitudinal or through the axis of the spinning turbine at 326 into the spinning turbine. Transverse vibrations of the thread outlet tube 31 in order to be able to influence the vibration frequency can be transmitted to the thread G. nen, the thread outlet tube 313 can be rotated in

3 shows the vibration distribution being supported by an arm 330. The thread exit tube

transversely oscillatable thread outlet tube. That is by means of a belt 315 over a whorl

Bore of the tubular shaft 210 is driven up 314.

widened conically towards the spinning turbine 200, thereby changing the relative rotational speed with the thread of the thread outlet tube 313 arranged within the shaft opposite the spinning outlet tube 31 The vibration frequency is influenced unhindered by the turbine 2 issued to it. As well can follow. The mouth 32 of the thread with can each have an optimal result, even with The outlet pipe swings between the end positions of the different materials and the materials from these 32 ' and 32 "back and forth. The yarn outlet tube 31 dependent spinning conditions, can be achieved is at its lower end by arm 34, vibration frequency is highest when filament is preferred held in an elastic sleeve 35. 60 outlet pipe 313 and spinning turbine 2 in opposite. To distribute the vibration, an electromagnet 36 is to rotate in the set direction, and is equal to zero if seen. thread outlet tube 313 and spinning turbine 2 with

As in the example already described, rotate in the same direction at the same speed.

1, the contact pressure also changes here. The vibration distribution is shown in FIGS. 13 to 18

the mouth 32 of the thread outlet tube 31, so 65 on the basis of an eccentric, but stationary

that the rotation propagation also favors the mouth 326 of the thread outlet tube 313

will. vividly. When the spinning turbine 2 in the direction of the

In order to work properly by means of the electric arrow / ', the piece of thread G is up to

Position Γ »1 (Fig. 16) more and more tense and then suddenly relaxes (G 2 in Fig. 18). then it receives its shortest length again in the phase according to FIG. This is then repeated Occurrence.

Hine adaptation to the material to be processed, the number of the thread to be produced and the The withdrawal speed can also be adjusted by changing the eccentricity of the mouth 32 of the thread exit screw 31I can be achieved.

Figs. 10 and 11 show a device at which the eccentricity of the thread outlet tube 311 at all spinning positions I, II ... of a not shown central control point can be changed at the same time. In the cover 111 of the housing 1 is a Minsatz 112 is provided, which has a ring gear 113 at its upper end. This one stands with a rack 114 controlled by a central control point.

If the eccentricity of the thread outlet tube 311 are adjusted, the rack 114 is shifted accordingly in the longitudinal direction of the machine. Since this rack engages in the ring gear 113 of the insert 112, the position of the Thread outlet tube 311 can be adjusted continuously up to position 311 ', in which its mouth 32 is centered on the axis of the spinning turbine 2 (32 '").

Instead of a rack, suitable linkages or chain or other gears can also be used.

In a particularly simple way, vibrations can be avoided by appropriately shaping the mouth of the thread outlet tube 31 can be obtained.

Examples of such thread outlet tubes are shown in FIGS. 4 to f> shown.

The thread outlet tube 31 according to FIG. 4 has an oblique with respect to its longitudinal axis Muzzle cross-section 320. By the high side

321 of the mouth cross-section 320, the piece of thread (7 is stretched, while it is on the low side.

322 is released again.

The thread outlet tube 31 works similarly according to FIG. 5. Here, the thread end is through a on the Muzzle 32 arranged nose 323 briefly stretched and then released again.

With the thread outlet tube according to FIG. 6 is a groove 324 in the for the brief release of the thread end Mouth 32 is provided.

If the thread outlet tube 311 arranged in the insert 112 driven and with a mouth according to FIG. 4 to 6, so can, as above described, in a similar way, the frequency of the vibration independent of the spinning turbine speed to be changed.

The elements which impart a vibration can also act directly on the thread G.

A corresponding arrangement shows z. B. FIG. 19. The one emerging from the thread outlet tube 316 Thread G is deflected twice by two deflection rollers 300 and 301. The pulley 301 is attached to the machine frame, while the pulley 300 sits on an arm 331, which is in point

332 is pivotably mounted on the frame and by its own weight down against the stop

333 is pulled.

When energized, an electromagnet 360 connected to an alternating voltage attracts the arm 331, which falls down again when released.

According to FIG. 20, an electromagnet 361 attracts a plunger 37 when energized. This one sits on one Leaf spring 370, which is fastened to the thread outlet tube 316 by means of the ring 371. When the Plunger 37 through the magnet 361 springs back the plunger, so that this rhythmic movement the thread G is given a vibratory motion.

ίο The thread can also vibrate through a eccentric cam (Fig. 21) acting on one or both sides can be granted which has its own Owns drive.

Claims (9)

Patent claims: 1. A method for spinning fibers by means of a spinning turbine, in which individual fibers collected in a collecting trough and attached to a fiber binding parts located on this collecting trough be tied into a thread, which through a thread outlet tube with a pull-off device is withdrawn, characterized in that the thread tension is changed briefly periodically between the fiber binding point and the take-off device. 2. Device for performing the method according to claim 1, characterized in that that the thread outlet tube (31) their distance to the fiber binding point (E) in the Has collecting channel (24) periodically changing mouth (32) within the spinning turbine (2, 200). 3. Apparatus according to claim 2, characterized in that the thread outlet tube (31) with its mouth (32) located in the spinning turbine (2, 200) longitudinally or transversely is pivotably mounted (Fig. 1 and 2). 4. Apparatus according to claim 2, characterized in that the mouth (32, 325, 326) of the thread outlet tube (310, 311, 313) is arranged eccentrically to the orbit of the fiber binding point (E) surrounding the mouth. 5. Apparatus according to claim 4, characterized in that the thread outlet tube (311) in a rotatable insert (112) which adjusts the eccentricity of the mouth (32) is mounted (Fig. 10). 6. Device according to claims 4 and 5, characterized in that the adjustable. mounted thread outlet tubes (311) several Spinnstelleri (I. II ...) Interconnected and shared by an adjusting device (114) are adjustable (Fig. 10). 7. Device for performing the method according to claim 1, characterized in that that the thread outlet tube (31) has an opening cross section (320) which is inclined with respect to its longitudinal axis (FIG. 4). 8. Device for performing the method according to claim 1, characterized in that that the mouth edge (32) of the thread outlet tube (31) has a nose (323) or groove (324) (Figs. 5 and 6). 9. Device according to claims 2 to 8, characterized by a rotating Fadenaiistrittsrohr (311). For this purpose 2 sheets of drawings