CS215122B2 - Appliance for spinning the vibres in the yearn - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a device for spinning fibers in a yarn, consisting of two air-permeable movable surfaces moving in opposite directions to each other, formed by perforated sheaths of rotating bodies between which yarn is formed, further from air suction devices.

In one spinning principle described in Melliand Textilberichte 1975, workbook 9, p. 690 et seq., The strands of the carding machine consisting of staple fibers are dislodged by means of a rapidly rotating combing roller and then fed to a rotating roller sieve drum. It has a suction neck on its inside, which runs along the surface of the inner surface of the sieve drum. The sucked air stream presses the staple fibers onto the outer surface of the sieve drum and is furthermore to hold onto the outer surface of the sieve drum, delimiting on one side the suction branch.

As a result of the rotation of the sieve drum, torque is applied to the spun fleece, which forms the individual fibers in the yarn forming line into the fiber bundle and twists in the yarn with a right twist.

This device has the drawback that the persistence of the individual fibers on said surface line of the sheath is labile. The individual fibers leave the surface line and the spinning process ceases when the speed of rotation of the sieve drum, the suction air flow and the yarn titer of the spun yarn are not properly matched to each other. if their values fluctuate. In addition, the intake air flow inhibits the twisting of the forming fiber bundle on the surface line of the housing, since the intake air flow is directed against the twisting on one side of the fiber bundle. The same principle is shown in DE-OS 2 361 313, and here too the air flow must be created by means of suction, which has a strong flow component against the direction of movement of the movable surface but which is directed against the twisting forces causing twisting of the fiber bundle.

DE-OS 2 449 583 discloses a method of spinning textile fibers in which the fibers are twisted into a bundle of fibers in a wedge-shaped space between two rollers of the same rotation which are parallel to one another. Air extraction devices are provided in each sieve drum, the mouths of which are directed against the wedge-shaped space in which the yarns are formed.

The fibers are suppressed by corresponding air streams in this wedge-shaped space on the sieve drum walls.

This method has the drawback that both one of these sieve drums and the airflow associated therewith, created by suction, counteract the desired twisting of the fiber bundle.

Here, too, stable operation is difficult to achieve, and only if the fiber bundle or the bundle of fibers is stable. the yarn is maintained on the line in which the yarn is formed by the discharge rollers arranged transversely to the wedge-shaped space.

SUMMARY OF THE INVENTION It is an object of the invention to provide a device in which the above-mentioned drawbacks are overcome. In particular, it is intended to prevent the fiber bundle from being subjected to mutually opposing torsional forces under the action of moving surfaces or air flow. Furthermore, it should be ensured that even without special yarn guides, stable operation is achieved regardless of the setting of the instantaneous operating parameters.

0.425 X ΙΟ ³ X - ^X - ^Va You X sin a

The solution to this object is that the movable surfaces are designed as skins of rotary hyperboloids whose axes are intersected with each other, so that the rotary hyperboloids form a narrow gap, which is bounded by a single forming line.

It is also a feature of the invention that the axis distance and / or the axis position of the rotary hyperboloids is adjustable.

The development of the invention is also characterized in that the moving surfaces are designed as shells of sections of rotational hyperbolids that are asymmetrical in the axial direction.

Another feature of the invention is that the peripheral velocity U of the hyperboloid shells at the yarn exit is in the range <U <0.95 X-cos and

It is also a feature of the invention that the obloidoid velocity U of the hyperboloid mantle is in the range

0.425 X 10-3 x - x sin «XV _and Vr where ··· '··' o and _m denotes the twisting coefficient

V _a denotes the pulling speed γ denotes the specific weight of the spun fibers axes denotes the half angle between the motion vectors of both rotary hyperboloids.

It is also a feature of the invention that at least one rotary hyperboloid is provided along a gap formed between rotary hyperboloids, a suction device whose suction mouth is directed along the gap formed between rotary hyperboloids against the inner wall of the perforated sheath of the rotary hyperboloid.

Another feature of the invention is that each rotary hyperboloid is associated with an air suction device upstream of the yarn forming line as viewed in the direction of movement of its surface.

The development of the invention consists in that the suction means with their orifices are arranged above a portion of the inner periphery of the rotary hyperboloids in the direction of the yarn forming line, the orifices overlapping a width of up to ten times the diameter of the yarn.

In a preferred embodiment of the invention, the extent of the overlap of the mouth of the suction means, when viewed in the direction of the fiber feed, is arranged in front of the gap formed between the rotating hyperboloids, preferably at a distance of 1 to 10 times the yarn diameter.

The advantage of the solution according to the invention is, inter alia, that it can produce effect yarns with different core and outer fiber properties when the core fibers at + cos and XV _and <U <0.85 X- cos are fed to a line in which yarn is formed, spatially in front of the outer fibers.

1 shows a spinning hyperboloid spinning device; FIG. 2 shows a solution similar to FIG. 1 with a false twisting device.

The rotary hyperboloids 31, 32 are driven by drive motors 18, 19, with motion vectors 11, 12 of the circumferential velocities of the skins of these hyperboloids. The rotary hyperboloids 31, 32 are arranged such that their axes lie in mutually parallel planes, or each of which has a forming line that is parallel to the yarn forming line 9.

This means that when projecting both s and on a plane, the angle between them is twice as large as the angle β below which each forming line intersects its axis of hyperboloid. The motion vectors 11, 12 of the circumferential velocities of the skins of the rotary hyperboloids 31, 32 intersect at the narrowest gap between the parallel generating lines at an angle 2 α.

The hyperboloids are further arranged such that the gap formed by adjacent generating lines is substantially rectangular. Since the hyperboloid 31 is displaceably and pivotably rotatable about the support 22 by its bearing 21, it is possible to adjust the width of the gap and / or to incline the rotary hyperboloid 31 so that the gap taperes towards the yarn exit.

This achieves that the frictional forces exerted by the sieve drums on the fiber bundle densifying in the yarn increase with its densification. In this case, it is to be avoided that the fiber bundle is not subjected to excessive torques or high torques. pulling forces that would tear the bundle. Further, by tapering the gap in the direction of the yarn exit, it should be ensured that the yarns leaving the device can be subjected to such high torques that sufficient shortening occurs. The gap dimensions are set so that in the area of the fiber feed 20 it is twice as large and in the area of the yarn exit is smaller than the diameter of the yarn.

Within the rotary hyperboloids 31, 32 forming the sieve drums there are suction devices 13, 14 whose mouths extend over a portion of the inner surface of the sieve drums formed by the rotary hyperboloids 31, 32 and terminate shortly before or after the yarn forming line 9. Again, a slight overlap is preferred, the overlap region being located on the supply side of the fibers 20.

The yarn feeder shown in FIG. 1 consists of a channel with a slotted orifice extending into the gap between the sieve drums formed by the rotating hyperboloids 31, 32, the orifices extending over at least part of the length of the gap. The finished yarn is drawn off by the winding device 23, optionally provided with a feeding device, at a draw-off speed V _a .

In operation, the peripheral speed of the rotary hyperboloids 31, 32 is carefully matched to both the twist to be adjusted and the pulling speed V _{and the} yarn, taking into account the permissible tensile force with which the yarn is subjected. In particular, the draw-off speed V _a is limited in that the yarn must not be subjected to excessively high tensile forces and, on the other hand, must not be too tight. The quantity _m results from the use of yarn.

Experiments with the spinning device according to the invention in two suction devices with a slight overlap gave the following results:

Two hyperboloids maximum diameter 85 mm Gap width 0.3 mm Extraction system overlap 0.9 mm Angle of motion vectors 2 and 140 ° yarn: cotton, stapl 28 mm specific weight is 1.54 £ —J metric Nm 24 cr _m shortening coefficient 120 αι, _η is essentially the coefficient by which the twist of the yarn can be calculated according to the formula T = 0É _{r and} VNm, where T is the number of twists per m of yarn.

The value of the coefficient a _m is given by the use of the yarn and its size is, according to experience, 100 to 150.

Towing speed V _a - 300 m / min.

The rotational heperboloids were measured in such a way that both hyperboloids always had the same peripheral velocity U at the yarn exit point. The yarn pulling force P was measured with which the yarn was withdrawn from the spinning device, as well as for the yarn actually achieved m and the length strength R in kilometers, which indicates the length of the yarn to be broken by its own weight, while the yarn is loosely suspended. It was calculated in the optimum ranges found according to the following formulas

4.25 X ΙΟ- ³ X —i

Vz X sin <U <0.95 X -5cos a as in a wider range a

4,25 X ΙΟ- ³ X «m X v _and X sin a

Vz

-j- V _and X cos and <U <0.85 X cos and as in the narrower range.

It has been shown that favorable values for the peripheral velocity U were achievable in the following ranges

Wider range: 132 m / min <U <835 m / min Narrow range: 220 m / min <U <746 m / min

The following table shows the results of the experiments.

U [m / min] 100

P [N] 0.54

T [1 / m] 375

Strength R [km] 5.7

Shortening coefficient «m 76,5

200

0.31

505

9.2

103 where

U circumferential speed T number of twists per m P yarn pulling force R longitudinal strength in km and _m twisting coefficient, determined empirically

400 600 800 900 0.27 0.22 0.19 0.15 830 680 730 795 11.8 11.2 10.2 8.4 128.6 138 149 162 results attempts can be recognized that too

high circumferential velocities U cause too much torsion and lower strength. Both are disadvantageous for further processing. In the lower limits, a twist was caused so little that sufficient strength could not be achieved. Hyperboloid shells may be, for example

215 7 in normal planes cut along line 36, 37 and as a result can be made asymmetrical. Such a design would be advantageous if no tensile forces should be applied to the yarn being formed.

FIG. 2 shows a spinning device similar to the spinning device of FIG.

1. In the spinning device shown in FIG. 2, the rotational hyperboloid-shaped faces on the outlet side of the sieve drum are mounted on the outlet side, respectively. thickened surfaces 34 and 35, which cause the fiber bundles formed therein to be clamped. The rotary hyperboloid-shaped sieve drums have a movement component in the yarn-forming line region which causes the twist and another movement component which causes the fiber bundle and the individual fibers to be transported. The conveying effect is further enhanced by the reinforcements 34 and 35 of the faces.

Such an additional torque increase can be advantageous if, in the case of coarse fibers or very high shortening, a high torque must be applied in order to achieve the necessary twisting. In these cases, a false twist device 33 may be provided which is arranged downstream of the spinning device.

The fiber supply can be effected by means of a feed device adapted to feed from each side of the yarn forming line. If the fiber supply is carried out in the manner just described, it is also possible according to the invention to produce a yarn from a mixture of fibers, the fibers of one kind being fed through the feed device from one side of the yarn forming line and the other of the other. Thus, the device according to the invention can be used simultaneously for mixing and spinning. In this case, the feed devices can be arranged offset in relation to one another in the direction of the line in which the yarn is formed or other feed devices can be arranged downstream of the fiber feed devices. This makes it possible to spin yarns whose core differs from the outer fibers in terms of the origin and structure of the individual fibers. This makes it possible to produce, for example, effect yarns in which the effect consists in a different core and sheath, for example yarns with a chemical fiber core for high strength and with a fiber yarn sheath to improve appearance, feel, moisture absorption, etc.

The yarn core can also be fed as a continuous filament to the yarn forming line 9 from above and between the surfaces. In this way, a yarn can be produced whose core consists of continuous filaments and whose sheath consists of staple fibers. The continuous filament may advantageously be a shaped, crimped fiber with three-dimensional shaping, such as is formed, for example, by false twist shaping in blown air shaping.

In the case of thick yarns, in particular thick yarns with a strong twist, unevenness of twist occurs in the cross-section of the yarn. Indeed, it has been found that the fibers lying within the fiber bundle have fewer twists per meter than the fibers present on the surface of the fiber bundle. These drawbacks are overcome by the device according to the invention.

Claims (9)

SUBJECT An apparatus for spinning fibers in a yarn, comprising two air-permeable movable surfaces moving against each other, formed by apertured skins of rotating bodies between which a yarn is formed, further comprising air suction means, characterized in that the movable surfaces are The rotational hyperboloids (31, 32) have a narrow gap which is bounded by a single forming line. 4.25 X ΙΟ ³ χ - ^Χ Υ · You X sin where the axis _m is the twisting coefficient whose value is determined empirically, V _a is the draw speed, ce is the half-angle of the motion vectors ynAlez Device according to claim 1, characterized in that the distance and / or position of the axes of the rotary hyperboloids (31, 32) is adjustable. Device according to claim 1, characterized in that the movable surfaces are designed as shells of sections of rotary hyperboloids (31, 32) asymmetrical in the axial direction. Device according to claim 1, characterized in that the peripheral velocity (U) of the sheaths of the hyperboloids (31, 32) at the yarn exit is in the range of ^ ^ <U <0.95 X- _x cos and the peripheral velocity of the rotary hyperboloids, γ is the specific weight of the yarn. Device according to claim 4, characterized in that the peripheral velocity (Uj of the skins of the rotary hyperboloids (31, 32 J) is in the range of ³ 0,426X1O- XV _and XX frog Vr. where is the learning coefficient, the value of which is determined empirically, V _a is the draw speed, ce is the half angle of the motion vectors of the peripheral speed of the rotating hyperboloids, y is the yarn specific gravity. Device according to one of Claims 1 to 4, characterized in that a suction device (13, 14) is provided in at least one rotary hyperboloid (31, 32), the mouth of which is directed along a gap formed between the rotary hyperboloids (31, 32). ) against the inside of the perforated sheath of the rotary hyperboloid (31, 32). Apparatus according to any one of claims 1 to 6, characterized in that each rotary hyperboloid (31, 32) is associated with an aspirator and a XV _{and a} <U <0.85 X- ⁵ -cos and a cleaning device (13). 14), arranged, as viewed in the direction of movement of these rotary hyperboloids (31, 32), upstream of the yarn forming line (9). Apparatus according to claim 7, characterized in that the suction means (13, 14) extend through their orifices over a portion of the inner periphery of the rotary hyperboloids (31, 32) in the direction of the yarn forming line (9). up to ten times the yarn diameter. Apparatus according to claim 8, characterized in that the extent of the overlap of the mouth of the suction device (13, 14) is arranged, viewed in the direction of the fiber feed (20), before the gap formed between the rotating hyperboloids (31, 32) at a distance of one. - up to ten times the diameter of the yarn.