DE2810184A1 - Open=end spinning unit - has ridges round mantles of the two sieve drums - Google Patents

Abstract

The open-end spinning unit to clad a spun core with spun fibres, using two sieve drums rotating in the same direction, has raised projections on the drums, running around their circumference. Viewed axially, these projections form a wave pattern, such as a sine curve line. The lines formed round the mantles mesh together at the point where the gap is narrowest, without touching each other. The hyperboloid angle can be reduced to give an equal advance action so that the spinning advance action can be increased.

Description

OPEN - END - SPINNING DEVICE

Bag. 1059 Addendum to patent application P 26 13 263.8 By the German patent application P 26 13 263.8 (dar. 978) is a spinning device known, which consists of two air-permeable sieve drums, which between two adjacent surface lines form a narrowest gap. Be in this narrowest gap supplied individual fibers are spun into a thread.

By the German patent application P 26 56 787.3 (Baq 1012) this is Spinning device developed in such a way that hyperboloid rollers are related. Through this a conveying effect is created on the thread. After registration P 27 39 410.1 (Bag. 1042) the hyperboloid rollers are designed and assigned in such a way that the smallest diameter of the hyperboloids is at the thread exit.

Object of the solution characterized by claim 1 of this application is to achieve a conveying effect of the spinning device or the conveying effect the spinning device to increase or a decrease in the hyperboloid angle to enable the same promotional effect.

The specified solution has the advantage that the thread formation line assumes such a stable position that the thread being formed passes through the impulse fluctuations of the yarn forming line flowing at high speed Single fiber cloud suffers no quality fluctuations.

Here you have to keep in mind that the individual fibers with a speed of e.g. 50 m / sec. and more.

The elevations or grooves with which the screening drums are provided, lie in one embodiment of the invention in normal planes to the axes of rotation Drums. These can be cylinders, truncated cones, or truncated hyperbolids. The sieve drums are in each case arranged so that the elevations comb each other.

For the height and the mutual spacing of the elevations preferred values from claim 2.

While one in the submission of tow that is inadequately prepared and are therefore uneven, observe the spinning devices according to the preamble can that the emerging open thread end under the impulse of on the fiber cloud impinging on this thread end as a result of the non-uniform distribution the fibers in the fiber cloud move back and forth, which leads to corresponding irregularities the thread quality leads, can also with the spinning device according to the invention such quality fluctuations if insufficiently balanced tow is presented of the thread can be avoided.

However, the invention also offers particular advantages in that it it allows a conveying effect on the emerging thread end in the withdrawal direction to evoke.

For this purpose, the screen drums are shaped according to the invention with elevations equipped with opposing thread webs, Since the elevations mesh with each other, If the screen drums are designed as cylinders or truncated cones, it is necessary to shape the elevations in a special way so that the elevations do not touch. This type of Formsebuncr results from geometrical considerations, but it can also can be determined empirically by using pre-made drums with bumps runs together until the surveys have been processed so far, that the elevations comb without touching each other. These sieve drums can then be used as a production sample.

The pitch of the thread-shaped elevations can exceed the length of the Screen drums be constant or grow in the direction of the thread take-off to one to achieve a constant conveying effect or an increasing conveying effect. In these In cases it is particularly useful to determine the number of turns of the thread-shaped elevations to design stepped multi-thread, so that the distances between the individual elevations stay constant.

If there are thread-shaped elevations in hyperboloids or hyperboloid stumps are applied, the pitch angle can be appropriately chosen so that it the largest intersection angle projected onto a plane between the generatrix corresponds to the hyperboloids and their axis of rotation. This makes it possible that the Comb elevations with one another without touching one another and without a special one Shaping is required.

In the following, embodiments of the invention are based on the Drawing explained.

1 shows the schematic representation of an open-end spinning device with cylindrical screen drums as well as elevations lying in normal planes; Fig. 2 an open-end spinning device with hyperboloid sieve drums and in normal ends lying elevations; Fig. 3 shows the section through two matching drums (hyperboloid, cylindrical, frustoconical) along the narrowest gap; Fig. 4 the section through two matching drums with thread-shaped Elevations along the line IV in Fig. 3, namely Fig. 4a with cylindrical screen drums FIG. 4b with hyperboloid sieve drums and constant pitch angle, FIG. 4c with hyperboloid sieve drums and constant pitch.

In Fig. 1, the cylindrical screen rollers 1, 2 are shown, in which Inside there are air extractors with extraction nozzles 3, 4. The screen rollers are driven in the same direction by motor 5 and belt 6. The thread 7 is in The area of the narrowest gap between the two screen rollers is formed from individual fibers and withdrawn by the trigger mechanism 8. The supply of the individual fibers and the forming Thread ends are not shown for the sake of clarity. The screen rollers show Elevations 9, which are essentially in the circumferential direction - in the illustrated Case in each case in a normal plane -stretch and mesh with one another in such a way that the narrowest gap has a sinuous, wavy shape, which the dem Individual fibers fed to the area of the narrowest gap or the fiber sliver formed therefrom customize in some way. This stabilizes the thread formation line achieved.

In Fig-. 2 hyperbolically designed screen rollers 11, 12 are shown, in the interior of which there are Luftabsauqungen with the suction nozzle 13, 14. the Screen rollers 11, 12 are driven by motors 15. The thread 17 is through the trigger mechanism 18 withdrawn. The thread formation line lies essentially parallel to the two surface lines of the screening drums 11, 12, which between them form the narrowest gap. The supply of the individual fibers 21 is also shown in the gusset or gap formed between the two rollers. The sliver 20 is drawn into the opener housing by the feed roller 22 and by the opening roller 23, which has a toothing on its circumference, broken down into individual fibers. As a result the centrifugal effect and as a result of air currents, the generation of which is not here is shown in detail, the individual fibers 21 fly through the fiber guide channel 24 in the area of the narrowest gap. It cannot be avoided that the tow (Sliver) sometimes has irregular spots. Also the resolution of the tow is Subject to uncontrollable disruptive factors. For this reason it is made from the individual fibers 21 existing fiber cloud not homogeneous. The through the individual fibers on the in formation The momentum exerted on the perceived thread end is therefore not constant. One can observe that the end of the thread depends on the presence and the size of disruptive factors changed its position. These changes in position affect the evenness the thread quality. The elevations 19 now bring about a substantial stabilization the thread formation line, as well as in the device according to FIG. 1. In addition but also cause the elevations in the spinning device according to FIG. 2 to intensify the conveying effect of the spinning rollers by the fact that the fibers are attached to the g-wound adjust the narrowest gap in a certain way despite their rigidity.

In Fig. 3 is the tortuous shape of the narrowest gap according to this invention recognizable. According to this invention, the distance between the elevations t is approximately 3 to 10 mm. The height h of the elevations is between 0.5 and 3 mm. The distance between the screen rollers is a few hundredths of a mm.

Part of the side wall of a screen roller is shown in FIG. 3 31 and the associated screen roller 32. The elevations run essentially sinusoidal. The elevations can run in normal planes or else in the form of a thread be trained.

In Fig. 4a a section along the line IV of FIG. 3 is shown. The lines 33 represent the crest of the elevations of the screen roller. 31. Dar. With 34, on the other hand, are the cut surfaces along line IV through the elevations of the roller 32 designated. From Fig.

4a shows that with a thread-like configuration of the elevations in the case of cylindrical screen drums, the shape of the elevations so chosen must be that the elevations of the intersecting in the area of the narrowest gap Roller 31 on the one hand and 32 on the other hand do not touch. The shape of the bumps is particularly dependent on the diameter of the screening drums, the distance or the pitch t of the elevations and the height h of the elevations.

When using cylindrical and frustoconical screen drums thread-shaped elevations have the additional positive effect that they do not only stabilizes the thread formation line but also has a conveying effect on the open thread end can be exercised in that the open thread end approximates the turns of the narrowest gap and the thread-shaped elevations consequently receive a partially form-fitting contact with the thread.

FIG. 4b again shows a section along the line IV according to FIG. 3 represents. Here, however, the representation is applied to a hyperbolic sieve drum, which has the thread-shaped elevations. The angle of incline is constant, so that the pitch or the distance t of the elevations from thick to thin End of the hyperboloids diminished. Because the pitch angle of the thread corresponds exactly to the angle at which the generating surface line 38 of the hyperboloids the axis of rotation 31 crosses, it can be ensured that the elevations of the other screen roller, the cut surfaces of which are denoted by 37, not with the elevations the screen roller 31 cross. This allows the elevations even with thread-shaped Comb course even with great immersion depth without the risk of mutual contact is given.

The changing distance between the elevations can thereby be compensated for be that the thread designed increasingly multi-thread from the thin to the thick end will.

FIG. 4c again shows a section along the line IV in FIG. 3 shown, also with a hyperbolic screen roller. Here is however, the pitch of the elevations is chosen to be constant. It can be seen that the elevations of the other screen roller with their cut surfaces 39 only in one adjust certain area of the direction of the elevations (combs 40) of the screen roller. In the remaining areas where the bumps move from the thin to the thick end increasingly cross, the form of the survey must be adapted.

When choosing a constant pitch or an even increasing pitch lets you increase the conveying effect in the direction of the thread take-off.

Claims (10)

Smells 1. Open-end spinning device for spinning a thread from and around a core thread with staple fibers consisting of two in the same direction driven self-drums, which between them one by two essentially parallel Surface lines form limited narrowest gap, in the area of which the individual fibers collected and twisted on the thread formation line, and from suction devices inside the sieve drum for generating the surfaces of the sieve drums in The air streams penetrating the narrowest gap to collect the staple fibers on the thread formation line, especially nacg. 978) P 26 13 263.8, characterized in that because the screen drums (1, 2; 11, 12; 31, 32) have elevations (9, 19, 33, 34), which run essentially in the circumferential direction and which - in axial section seen - form a wavy line e.g. a sinusoidal wavy line and in the area Comb the ttantellines forming the narrowest gap without touching each other. 2. Spinning device according to claim 1, characterized in that the Height (h) of the elevations (9, 19, 33, 34) are between 0.5 and 3 mm and that the Distance (t) of the elevations (pitch) 3 to 10 mm. 3. Spinning device according to claim 1 or claim 2, characterized in that that the elevations are threaded in opposite directions, 4. Spinning device according to claim 3, characterized in that the elevations are multi-threaded are trained. 5. Spinning device according to one of the preceding claims, characterized characterized in that the screen drums (1, 2) are cylindrical. 6. Spinnvorrichtunq according to claim 5, characterized in that the threaded elevations of the cylindrical screen drums so adapted to each other are that the elevations mesh with each other without touching. 7. Spinning device according to one of claims 1 to 4, characterized in that that the sieve drums (11, 12) have the shape of hyperboloids. 8. Spinning device according to claim 7, characterized in that the The pitch angle of the thread-like elevations is constant and the largest intersection angle corresponds to the generatrix with the axis of the hyperboloids. 9. Spinning device according to one of claims 1 to 4, characterized; that the sieve drums are designed to be frustoconical. 10. Spinning device according to claim 7 or claim 9, characterized in that that the pitch of the thread-shaped elevations is constant or in the thread running direction seen is increasing.