CS269142B1 - Device for friction spinning with open end - Google Patents

Abstract

Device designed for frlkčnlho an open end spin comprising outer and inner cylindrical friction carriers surfaces, allows optimal control the orientation of the fibers when bound to open end of the formed yarn. No county bearing friction surface, opposed to the exhaust system a braking surface arranged in the track path a portion of the fiber web opposite the tow device, for temporary hold the front ends of the fibers by the braking force which is changed than the axial force of the fibers induced the back ends of the fibers into produced yarn.

Description

The invention relates to a device for friction spinning with an open end, comprising on the one hand an cylindrical wear and an inner cylindrical wear on friction surfaces which define a wedge-shaped intercession in which the friction surfaces move in opposite directions. perforated frtktll fence in the wedge-shaped area of the suction field, and on the one hand the unifying device with the transport channel, which enters the outer wear Hkmo against the yarn extraction set from the wedge-shaped inner part Which expresses the width of the flow of fibers / moving after the impact of the front ends of the fibers on the support surface in the fiber web along the path and carried by the support surface into the wedge-shaped web.

A device of this type is disclosed in OE-OS i. 3,540,640. according to -Ε-OS No. 2,919,316, which contains a basic concept of friction spinning with an open end between a concave and a convex surface.

In an expedient geometric arrangement of the conveying channel, the single fibers are fed to a circulating support surface which is in a broadly oriented appearance to the yarns being discharged from the wedge-shaped web, so that the fiber is wound at an acute angle to the open end of the formed yarn. Thus, the fiber is fed to the open end of the yarn obliquely opposite the yarn take-off at a speed substantially corresponding to the circumferential speed of the support surface.

Due to the fact that a considerable slippage occurs between the friction surfaces and the formed yarn, the circumferential speed of the twisted yarn is an order of magnitude lower than the circumferential speed of the supporting friction surface. Thus, there is also an order of magnitude difference between the respective component of the feed speed of the fiber and the circumferential speed of the yarn, which causes a certain deformation of the fiber at the moment of its connection to the open end of the yarn due to the sharp changes in momentum in the circumferential direction.

The fibers fed to the supporting friction surface vs the axis of rotation of its axis at an acute angle move relatively quickly. Usually, this component of the velocity is also an order of magnitude more than the rate of withdrawal of the yarn being formed, so that even in the axial direction the fibers are braked and deformed when caught on the open end of the yarn.

As a result of these deformations, the position of the fibers in the internal structure of the yarn is not favorable, which is reflected in the lower appearance of the yarn made of a heavy fiber substance by conventional ring spinning.

Therefore, in the development of open-ended friction spinning technology, an effort has been made to ensure by suitable means the advantageous position and upright orientation of the fibers on the support of the friction pad when they are tied to the yarn being formed.

There are a number of known solutions to this goal. Example according to European Pat. With 165 398, the fibers are mechanically inspected in the path from the combed strand to the catch by the open end of the yarn. The practical embodiment consists in immediately attaching the end clean of the stretching device or the combing roller to the wedge-shaped insert.

European Pat. application 175 862 addressed this problem by feeding substantially straight fibers, positionally oriented obliquely to the direction of yarn withdrawal from the wedge-shaped slot, through a support friction surface into the wedge-shaped slot, by a specific profile of the feed channel mouth mounted close to the wedge-shaped slot, and several times the air velocity. projecting from the mouth of the conveying channel to the circumferential speed of the supporting frikini surface.

According to OE-OS i. 3 517 829, this problem is solved on a device for frikini spinning with an open end, his! the concept is based on a pair of juxtaposed and counter-rotating rollers, at least one of which is perforated and provided with a suction field in the region of the wedge-shaped gap.

The united fibers are fed to a non-supporting frikini surface, the movement of which is directed into the wedge-shaped interline, a pair of continuously moving conveyor belts, which drive the fibers caught by their front ends between the straps. After being released from the conveyor belts, the fibers are deposited on the supporting frikini surface so that they are aligned substantially in the direction of the yarn take-off and, in this position, are wrapped on the open end of the yarn to be formed. The essence of the solution according to ΡΕ-OS δ. U.S. Pat. No. 3,517,829 is that the fibers are twisted by conveyor straps which move substantially against the direction of yarn withdrawal from the wedge-shaped web, and that the fibers orient in longitudinal flow during transport so that their rear ends reach the noon frikini surface earlier than their front ends, thereby creating the conditions for inspecting the fibers before they are tied to the yarn in order to achieve the desired straightening of the fibers while maintaining their parallel arrangement. This fire-complex and space-consuming solution cannot be applied to an open-ended frikini spinning device according to DE-OS i. 3 540 640, partly due to the structural difference between the two basic device concepts transport · fiber straps. , the known devices for said purpose are not sufficiently efficient and the conceptual arrangement of the spinning unit for frikini spinning and open end, comprising outer and inner carriers of friction surfaces, according to -Ε-OS i. 2 919 316.

The object of the invention is therefore to ensure, by simple means, in the open-ended frikini spinning device cited in the first paragraph of the description, the control of the optimum orientation of the fibers during their insertion into the open end of the yarn to be formed.

Said podeinka is at least predominantly fulfilled by the device according to the invention in that a static braking surface arranged in the path of the edge part of the fiber strip opposite the pulling device for temporarily holding the front ends of the fibers by a braking force than the axial force of the fibers caused by the tying of the rear ends of the fibers into the yarn being formed.

To ensure this effect, it is desirable that the greatest distance between the mouth of the wedge-shaped slot and the edge of the static braking surface remote from it be aenii than the average length of the staple of the spun fibers. The interaction of the direction and speed of deposition of the twisted fibers on the support frikini surface, the position of the static braking surface and the circumferential speed of the support frikini surface ensures that the fibers the surfaces are effectively tensioned when tied to the yarn.

In order to achieve sufficient yarn quality, it is expedient to influence the orientation of only those fibers which form the core component of the yarn, while for other fibers forming the yarn wrapping component it is not necessary because these fibers contribute to the specific properties of yarns open end in terms of their oak and the ability to release the ends of the fibers when sanding the fabric made from these yarns.

The purpose of the static braking surface is to retain the front end of the fiber until the rear end of the fiber is fed through the support frikini surface into a wedge-shaped slot in which the fiber is connected to the rotating open end of the yarn. The fiber spun into the yarn gradually overcomes the resistance of the braking force until the entire length of the fiber is pulled out of the braking area.

CS 269142 Bl

The braking of the front ends of the fibers contained in the part of the fiber web carried by the support friction surface into the wedge gap can be induced by a static braking surface in the form of a rough surface, a protrusion whose surface is at least partially formed by a rough surface ·, Or an electrode whose electric charge has the opposite polarity to the polarity # of the fiber charge.

The static braking surface is preferably circumferentially adjustable in position to control the optimum effect on the type and fineness of the fibers to be processed. The position of the static braking surface also adjusts the width of the part of the fiber strip which will be subjected to the braking effect on the path to the wedge gap.

The yarn produced on the apparatus of the present invention increased the strength and uniformity of appearance of the yarn produced on the spinning unit operating without the apparatus of the present invention.

The open-ended friction spinning device according to the invention is schematically shown in the drawings, in which FIG. 1 shows a spinning work unit, without a separating device, in a three-dimensional view, FIG. FIG. a support friction surface, an adjacent wedge-shaped slot, developed in the plane of the drawing, showing a transport channel and a variant of the static braking surface.

Spinning unit / fig. 1 / comprises a separating device of the illustrated part of the conveying channel 1, a spinning device 6 and a drawing device 6, behind which a winding device (not shown) is cut. The separating device of the conventional type is formed by a feed roller * with a pressure * thumb, attached * to the combing roller, housed in a recess which passes into the conveying channel 1.

The spinning device 6 is formed by an outer cylindrical carrier 4 with an inner supporting friction surface 1, to which the outer perforated friction surface 4 of the inner cylindrical carrier Z is contacted without contact. wedge slot 11.

It is clear from Fig. 1. that the supporting friction surface 6 moves in the snow into the wedge-shaped slot 11. A set of nozzles 12 is fixed in the cavity of the inner cylindrical carrier Z, connected to a vacuum source (not shown), the mouth 13 of which extends on the perforated friction slot field 14 /fig..2/.

Transport channel 1 enters into the outer cylindrical substrate 4 * <Kao dreaming against withdrawal of the yarn 15 from klinovlté štěnbíny 11, shown by arrow 16, wherein the longitudinal orifice ⁷ and the transport channel 1 is aligned in terms of rotation frikčnl bearing surface 5, which is shown by an arrow g.

The mounting and drive of the functional parts of the spinning unit are not explained or illustrated in more detail, as these are commonly known arrangements of open-end frequency spinning spinning units.

In the axial extension of the smallest surface 10 of the wedge-shaped slot 11, a guide eye 18 for draining the yarn is fixed at the edge of the outer cylindrical carrier 6.

CS 269142 B1 χ wedge of the slot 11 · upstream of the extraction device 3 * formed by »a pair of extraction rollers 19, 20 rotating in the upek 21, 22 / fig. 1 /

In the unifying device, which continuously feeds the powder, the fibers are unified and accelerated, since the flow 23 of fibers 24 of the conveying channel 1, formed by its longitudinal growth 17, is deposited on the supporting friction surface and in the fiber web 23, the trajectories of which The movement of the individual fibers deposited on the support friction surface 2 is the result of both the effects of inertial forces acting in the orientation of the transport channel 1 and the effects caused by the movement of the support friction surface 3 in the cone J It follows from the above that the fibers a * move on the supporting friction surface 3 to move the movement of this surface into the wedge-shaped slot 11.

According to the invention continues smoothly to the region 25 of reduced length of the carrier frictional surfaces 5 Appearance · the length of the perforated frlkSnl area Y of the opposed exhaust válečkůmlýj 20 _P static braking surface 26 uaistěná path Sástl fiber strip 24 on nos1S1 27 which extends into the inner circumferential recess 28 of the outer cylindrical carrier 6, and mounted by means of an adjustable circumferential means in said section 29, 30 on a spinning unit (not shown). It follows from the above that the length of the support friction surface 5 is not equal to the length of the circumferential recess 28 than the length of the outer perforated friction surface i.

The purpose of the static braking surface 26 is to brake the front ends of the fibers of the edge portion of the belt of fibers moving inertia along the supporting friction surface 3 carried by this surface until their rear ends carried by the supporting friction surface are caught in the open end 31 of the yarn 15. formed in the wedge-shaped slot 11. It is therefore necessary that the greatest radial distance & aesia open ends 31 at the beginning of the static braking surface 26, in the said movement of the support friction surface 3 shown by arrow 3 . The end of the static braking surface 26 extends up to the wedge-shaped slot 11.

According to an exemplary embodiment, the static braking surface 26 is formed by a rough surface 32 / FIG. 3 / appearance · to a smooth supporting friction surface 3> The rough surface 32 extends up to the wedge-shaped slot 11. Roughening can be achieved in various ways! processes, eg raking, felting or etching, or gluing a suitable material, for example the back of the leather or an aolitan sponge, to the circumferential recess 28 of the outer cylindrical carrier 6.

According to another exemplary embodiment, the static braking surface 26 is formed by the surface of the protrusion 33 / FIG. 2 /, which can be or. partially roughened.

According to another exemplary embodiment, the static braking surface 26 is a locally driven suction field 34, formed by connecting the outer perforated surface of the suction pipe carrier 27 to a vacuum source (not shown) / FIG. 4 /.

According to another exemplary embodiment, the static braking surface 26 is formed by an electrode 36 mounted on a carrier 27 and carrying a hub 37, the polarity of which is opposite to the polarity of the hub of the fibers / FIG. 5 /.

From the trajectory of the fibers emerging from the longitudinal mouth 17 of the conveying channel J shown in Fig. 3, it can be seen that the fibers projecting from the part of the longitudinal mouth 17 of the conveying channel 1 closer to the pulling device 3 perform conventional _{fiber trajectories T Q} , such as on a known spinning unit for friction spinning with open ends with outer and inner friction surface carriers and attaching the spinning end to the surface layer of the open end 31 of the yarn 15 formed in the wedge-shaped slot 11 at an acute angle. The fibers emerging from the part of the longitudinal mouth 17 of the conveying channel j adjacent to the static braking surface 26 move first along the trajectory T *, but after arriving at the static barrier surface 26 the fiber orientation changes so that is attached to the open end 31 of the yarn in blunt Ohio £.

This process will be explained in more detail on a single fiber 24 with a marked beginning 2 * of the end g, in three successive positions yj, X ₂ , X3 f ^ br. 3 /.

The fiber, which occupies, for example, the instantaneous position y on the trajectory, follows the same trajectory on the static braking surface 26 formed in the exemplary embodiment by a rough surface 32 which retains the beginning of the fiber J, while its end g is essentially the friction bearing surface. in the sense of arrow J. Current position £? is one of the positions that the fiber travels during this phase. In this process, there may be some reduction in the straightness of the fiber with respect to the inhibition of the beginning of the fiber, which is not detrimental to the spinning process, as a slight wrinkling of the fiber is subsequently completely compensated by further displacing the fiber end together with the supporting friction surface. It is important that the displacement of the end g of the fiber to the coil of the beginning 2 is not limited, the fiber would not be oriented completely around the circumference of the surface i. yarn in which the fiber assumes an instantaneous position y $, oriented with respect to the longitudinal axis of the yarn at an obtuse angle θ.

When the fiber is attached to the open end of the yarn, the cohesive forces of the tinto fiber and yarn end fibers begin to act along with the forces causing the open yarn end to rotate, so the fiber is gradually spun into the open yarn end while tensioning while overcoming the to the beginning 2 of the fiber by an impulse force, which is due to the change in momentum of the originally front part of the fiber with momentum approaching the zero state, to the momentum corresponding to the speed of the drawn yarn, which moves the section of the fiber adjacent to its end g. of each fiber which is attached to the open end of the yarn, these fibers forming a yarn support component which is able to overcome the increased axial load of the yarn.

In other words, the same process can be expressed in such a way that those fibers which are deposited on the supporting friction surface 6 in its part facing the area where the open end 31 of the yarn 15 is formed in the single-slit slot 11 begin before they are connected to the open end. the braking force acting on their section located closer to the wedge slot, while their distal sections are moved by the frictional effect of the supporting friction surface 6 from a position furthest from the wedge slot 11 to a new position closer to this slot, and therefore these originally more distant sections are joined earlier to the end of the yarn, with the spun fibers overcoming the braking effect of the static braking surface 26, which is more than the axial tension of the spun fibers, until their release from the braking effect.

Giant. 6 shows four typical positions up to y of the fiber subjected to the braking effect of the protrusion 33 arranged on the carrier 27. The position y 1 shows the fiber straightened and oriented in the trajectory direction and the position y _{2 of the} deformed inertia fiber by contact with the protrusion 33 arranged on the support 27. At this stage, the beginning Z of the fiber can also be moved above the level of the trajectory T1, the end g of the fiber being carried by the supporting friction surface in the direction of the arrow. The position y ₄ shows the fiber already in the orientation defined by the obtuse angle θ, while the beginning 2 of the fiber is still braked by the edge of the projection 33.

While in the case of contact of the fiber and the rough surface 32, the beginning of the fiber is in the positions and Yj / fig. 3 / in essentially the same place # the beginning J of the thread is moved in positions X ₂ up to the protrusion 33 # as explained above.

The fiber behaves in the same way when in contact with the static braking surface 26 formed by the locally defined suction field 34 or in contact with the electrostatic forces of the charge on the surface of the electrode 36.

The fibers from the portion of the fiber web # fed to the open end of the yarn at an obtuse angle form an inner component of the formed yarn # which is overlaid by the fibers wrapped at the open end of the yarn at an acute angle g # which forms the characteristic looser surface structure of the fiber yarn. and the straightforwardness which is common in conventional yarns produced by the principle of friction spinning with an open end, it is essentially achieved that the yarn has the usual advantageous surface properties with higher strength and higher utility value for processing yarns of this kind.

From the explanation of the controlled movements of the fibers of the fiber web on the supporting friction surface 2 during the spinning process, an important factor 1 of the radial adjustment of the surface of the static braking surface 26 relative to the apex # resp. the smallest addition 10 of the two friction surfaces 2 # 2 in the array of Arrows 29 # 30 so as to achieve the optimum obtuse angle ε for the resulting fiber winding effect. The width of the fiber web which comes into contact with the static braking surface 26 can be adjusted, for example, by displacing the surface of the longitudinal mouth 17 of the conveyor channel 1 parallel to the longitudinal axis of the outer cylindrical carrier 6 or the sounded position of the braking element. by replacing the carrier 27, etc.

packed options is inaccessible. blinding the respective perforation holes of the suction field 34 of the carrier 27 in order to achieve the desired shape of the suction field 34, which affects the structure of the spun yarn. It is also possible to create the desired braking effect of the static braking surface 26 for the purpose of the electrode assembly 36 # or. with the possibility of variable adjustment of the electrodes to the voltage source.

The wrapping of the fibers at the open end 31 at angles ga? winding device (not shown) on the spool.

The spun yarn, while maintaining the characteristic features of the surface structure of the yarns spun by the principle of friction spinning with an open end between the two friction surfaces, has a higher strength.

Claims (8)

1. An open-ended friction spinning device comprising on the one hand an outer cylindrical carrier and an inner cylindrical friction surface carrier defining a wedge-shaped screen in which the friction surfaces move in opposite directions, a nozzle being located in the inner carrier forming on its perforated friction surface. a suction field in the region of the wedge-shaped slot, and a unit of the separating device with the conveying channel, which enters the outer carrier obliquely against the direction of yarn withdrawal from the wedge-shaped slot of the suction field. the width of the flow of fibers moving after the impact of the front ends of the fibers on the supporting friction surface in the fiber web along the path and carried by the supporting friction surface into the wedge-shaped web characterized by the edge (25) of the supporting friction surface (5) opposite / 3 /, a static braking surface / 26 /, arranged in the groove · edge part of the fiber strip, opposite the towing device / 3 /, is continuously connected for temporarily holding the front ends of the fibers with a braking force which is more than the axial force of the fibers caused by the binding of the rear ends of the fibers to the yarn to be formed. 2. The device according to point 1, characterized in! It is known that the greatest distance (*) between the mouth of the wedge-shaped interlock (11) and the front edge of the static braking surface (26), in terms of movement of the support friction surface (5), is aenii than the mean staple length of the spun fibers. 3. Device according to claim 1, characterized in that the static braking surface (26) is formed by a rough surface (32). 4. The device according to item 1, characterized in that the static braking surface (26) is formed by the surface of the protrusion (33). 5. The device according to item 4, characterized in! in that at least a part of the surface of the protrusion (33) is formed by a rough surface. 6. Furnished! according to point 1, characterized by! with tia that static brakes! surface / 26 / A set of fields / 34 / is formed, locally mounted on the perforated surface of the carrier / 27 / of the static braking surface / 26 /. 7. Furnished! according to claim 1, characterized in that the static braking surface (26) is formed by an electrode (36), the electric charge of which and the polarity opposite to the polarity of the charge of the fibers. 8. The device according to claim 1, characterized in that the static braking surface IZbl is arranged on a carrier (27) position-adjustable in the inner circumferential recess (28) of the outer cylindrical carrier tkl. .