EP4043625A1 - Yarn forming element - Google Patents

Abstract

The invention relates to a yarn-forming element for an air spinning nozzle, comprising a spinning cone with a cone tip forming a first end face with an inlet opening, a channel body forming a second end face with an outlet opening, the channel body and the spinning cone being connected to one another, and a passage which connects the channel body and passes through the spinning cone to connect the inlet port to the outlet port. In order to provide a yarn-forming element that is particularly inexpensive and easy to produce, it is provided that the spinning cone has a truncated cone-like partial segment, which extends in the direction of the second end face with an increasing distance from its inner surface side to an outer surface side of the channel body radially delimiting the passage, forming a space extends.

Description

The invention relates to a yarn-forming element, an air spinning nozzle comprising such a yarn-forming element and a method for producing such a yarn-forming element.

Yarn-forming elements for spinning devices, in particular for air-jet spinning devices, are known in a variety of configurations from the prior art. Yarn-forming elements are used to produce an air-spun yarn from a fiber sliver coming from a drafting system, which is fed in a controlled manner into a spinneret that includes the yarn-forming element, by means of spinning compressed air fed into the spinneret to generate a turbulent air flow. The air-spun thread is discharged from the spinneret via the yarn-forming element.

A yarn formation element is, for example, from the references EP 3 293 294 A1 , WO 2010/034416 A1 and EP 2 573 218 A2 known, in which the Garnbildungselement is formed of several composite components. Due to the fluid flows used for spinning, on the one hand to spin the sliver into a thread using spinning compressed air and on the other hand to discharge the air-spun thread, a particularly precise and tight connection between the individual components must be produced, which means that a particularly complex and cost-intensive production with very little tolerances is necessary.

In addition to the problem that the components have to be connected particularly tightly, the yarn-forming elements of the prior art also have the disadvantage that fibers definitely get caught at the separation points or seams of the individual components and are thereby detached from the thread, which impairs the strength of the thread and on the other hand leads to an accumulation of detached fibers at the separation points, which can also impair the spinning result.

The invention is therefore based on the object of providing a yarn-forming element which can be produced at least in a cost-effective manner and, in particular, is also of simple construction. Furthermore, preferably, the yarn-forming element proposed with the invention should enable a spinning process with improved accuracy and efficiency, in particular the Contamination by detached fibers can be reduced during spinning and the piecing process.

The object is achieved by a yarn-forming element according to claim 1, an air spinning nozzle according to claim 12 and a method according to claim 13. Advantageous developments of the invention are specified in the dependent claims.

The yarn-forming element for an air spinning nozzle according to the present invention comprises a spinning cone with a cone tip forming a first end face with an inlet opening for receiving a yarn. Furthermore, a channel body is provided which has a second end face with an outlet opening for discharging a thread from the yarn-forming element, the channel body and the spinning cone being connected to one another. A passage passes through the channel body and the spinning cone to connect the inlet opening with the outlet opening for passage of the thread. The thread taken up by the inlet opening can consequently be guided via the passage to the outlet opening and be discharged out of the yarn-forming element through the outlet opening.

The yarn-forming element is characterized in that the spinning cone has a truncated cone-like partial segment which extends in the direction of the second end face with an increasing distance between its inner surface side and an outer surface side of the channel body radially delimiting the passage, forming an intermediate space. As a result, the yarn-forming element can at least be designed to save material and consequently be more cost-effective. The truncated cone-shaped sub-segment can be arranged in a preferred manner directly or via at least one further sub-segment lying in between adjoining a sub-segment forming the cone tip. This allows the cone-shaped area of the spinning cone to be designed as required in a direction pointing from the inlet opening to the outlet opening, for example taking into account a fiber length to be spun, whether short, medium or long staple fibers.

According to a preferred embodiment of the present invention, the spinning cone has a cylindrical sub-segment into which the truncated cone-like sub-segment merges on its side facing away from the cone tip, with an inner surface side of the cylindrical Sub-segment is spaced to the outer surface side of the channel body while continuing the gap formed. The yarn-forming element can thus also be provided with a horizontal, outer stop surface to save material, via which the yarn-forming element can be positioned appropriately and very precisely within the spinneret to a sliver feed of the spinneret, via which the sliver is fed to the yarn-forming element.

The intermediate space is preferably accessible or open from a direction running from the outlet opening to the inlet opening. In other words, the end of the spinning cone facing the second end face is spaced apart from the outer surface side of the channel body in such a way that the external space bordered by the spinning cone can communicate with an area surrounding the spinning cone. As a result, a stabilization element suitable for stabilizing the position of the yarn-forming element can engage in the intermediate space.

According to a further preferred embodiment of the present invention, the channel body protrudes beyond the spinning cone in the direction of the second end face. The channel body consequently has such a length along the passage that the second end face or the outlet opening projects towards the end of the spinning cone facing this second end face or the outlet opening, forming a distance. This makes it possible for the end segment of the channel body, which has the outlet opening, to be received by a cover element which delimits the spinneret at the end and closes it off in a sealing manner, in order to reliably discharge the thread from the spinneret. The length of the channel body can be aligned with an outer surface side of the cover element or spaced therefrom as required.

The cylindrical sub-segment preferably has a first sub-segment and a second sub-segment, with an outside diameter of the first sub-segment being different from an outside diameter of the second sub-segment. More preferably, the first sub-segment and the second sub-segment are connected to one another via a step-like increase in their outer diameter. In other words, the outer surface sides of the first and second partial segments merge into one another in a stepped manner. Thereby For example, a stop acting along the passage can be provided for a fastening element engaging on the outside of the yarn-forming element, in order to be able to reliably position the yarn-forming element within the spinneret in the direction of passage.

The first sub-segment is particularly preferably arranged along the channel body closer to the tip of the cone than the second sub-segment, with the outer diameter of the second sub-segment being larger than the outer diameter of the first sub-segment. As a result, the section of the second sub-segment that protrudes radially beyond the first sub-segment provides a stop, as described above, on a side of the second sub-segment that faces the inlet opening, and a further stop on a side of the second sub-segment that faces the outlet opening, over which the second sub-segment and thus the Garnbildungselement can be clamped or locked in position via clamping or fastening means of the spinneret. This allows easy and safe assembly of the yarn-forming element within the spinneret.

According to a further preferred embodiment of the present invention, the cylindrical sub-segment has a first sub-segment and a second sub-segment, with an inside diameter of the first sub-segment being equal to an inside diameter of the second sub-segment. The cylindrical sub-segment is formed with its inner surface side equidistant to the outer surface side of the channel body over its extension length running along the channel body. Thereby a deeper engagement can be provided for engagement elements of the spinneret in order to be able to achieve a more stable positioning of the yarn-forming element within the spinneret.

According to another preferred embodiment of the present invention, the yarn-forming element has a three-segmented passage. The passage preferably comprises at least three segments, each with different internal diameters, with two consecutive segments merging seamlessly into one another with the interposition of a transition area. The transition area consequently connects a segment of the passage with a diameter that is different from a diameter of the following segment along the passage. Such transition areas favor fluid flows within the passageway. In a particularly preferred manner, a first passage segment, which adjoins the inlet opening, has the smallest inner diameter and a third passage segment, which adjoins the outlet opening, has the largest inner diameter. An intermediate second passage segment includes an inner diameter that is greater than the inner diameter of the first passage segment but less than the inner diameter of the third inner diameter. The passage consequently widens from the inlet opening to the outlet opening. As a result, particularly with regard to a piecing process in which the thread for piecing is preferably introduced into the yarn-forming element via the outlet opening, it can be reliably initiated and discharged to the inlet opening and via this into the turbulence chamber of the spinneret.

Although the yarn-forming element can consist of any material, according to a preferred embodiment, the yarn-forming element is formed in one piece from one piece, whereby particularly good guidance of the fibers or the thread and a particularly seamless surface that is free of severing and connection points can be designed in a simple manner can. For example, the yarn-forming element can be formed using an additive manufacturing process, which can be used to reliably avoid separation and connection points. Possible additive manufacturing processes can be, for example, 3D printing, Selective Laser Melting (SLM), Electron Beam Melting (EBM), Binder Jetting (BJ) and/or Fused Deposition Modeling (FDM). In addition, subsequently or alternatively, the workpiece can also be sintered, in particular if the yarn-forming element is to be formed completely from a ceramic material. alternatively or additionally, the stereolithography process (SLA) can also be used to form the yarn-forming element from the ceramic material.

Furthermore, the yarn-forming element can preferably have a ceramic coating on at least all fiber-guiding surface sections in order to provide a particularly smooth, stable and also resistant surface. Particularly preferably, at least the outer surface side of the spinning cone and/or the inner surface sides of the passage has a ceramic coating.

According to a further preferred embodiment, the yarn-forming element is formed rotationally symmetrically and/or mirror-symmetrically to a central longitudinal axis of the passage. The latter configuration is preferred in particular when the channel body is not to be shaped in a rotationally symmetrical manner. In any case, the symmetrical design of the yarn-forming element favors the production of the same.

According to a further aspect of the present invention, an air spinning nozzle is proposed which has a yarn-forming element as described above.

Further features and advantages of the invention result from the following description of a preferred exemplary embodiment, with reference to the figures and drawings that show details that are essential to the invention, and from the patent claims. In a preferred embodiment of the invention, the individual features can each be implemented individually or together in any desired combination.

Fig. 1

eine schematische Seitenansicht eines Garnbildungselements nach einem Ausführungsbeispiel, und

Fig. 2

eine schematische Schnittansicht des in Figur 1 gezeigten Garnbildungselements entlang der Schnittlinie A-A.

The invention is explained in more detail below with reference to an exemplary embodiment illustrated in the drawings.

1

a schematic side view of a yarn-forming element according to an embodiment, and

2

a schematic sectional view of the in figure 1 shown yarn-forming element along section line AA.

Figures 1 and 2 12 show, in a schematic side and sectional view, a yarn-forming element 1 molded in one piece from a ceramic material according to an exemplary embodiment of the present invention.

The yarn-forming element 1 comprises a spinning cone 2 with a cone tip 3, which forms a first end face 4 with an inlet opening 5 for the yarn-forming element 1. The yarn-forming element 1 also includes a channel body 6 which forms a second end face 7 with an outlet opening 8 for the yarn-forming element 1 . The channel body 6 is seamless due to the formation of the Garnbildungselements 1 in one piece spinning cone 2 over.

The channel body 6 and the spinning cone 2 are passed by a passage 9, via which the inlet opening 5 and the outlet opening 8 are communicatively connected to one another for the passage of a thread. The passage 9 is divided into three segments 18, 19, 20, each with a different inner diameter, with two consecutive segments 18, 19, 20 merging into one another seamlessly or without any separation or connection points with the interposition of a transition region 21, 22. A first passage segment 18, which adjoins the inlet opening 5, has the smallest inner diameter and a third passage segment 20, which adjoins the outlet opening 8, has the largest inner diameter. An intermediate second passage segment 19, bordered by a first 21 and second transition region 22, via which the first 18 and second passage segment 20 connect, has an inner diameter that is larger than the inner diameter of the first passage segment 18, but smaller than the inner diameter of the third Inner diameter is 20. The passage 9 consequently widens from the inlet opening 5 to the outlet opening 8 .

The spinning cone 2 has a truncated cone-shaped partial segment 10 which extends in the direction of the second end face 7 with an increasing distance from its inner surface side 11 to an outer surface side 12 of the channel body 6 radially delimiting the passage 9 , forming an intermediate space 13 . The truncated cone-shaped sub-segment 10 is adjoined by a cylindrical sub-segment 14 assigned to the spinning cone 2, into which the truncated cone-shaped sub-segment 10 merges seamlessly on its side facing away from the cone tip 3 due to the formation of the yarn-forming element 1 from one piece, i.e. without any separation or connection points. The cylindrical sub-segment 14 comprises a first sub-segment 16 and a second sub-segment 17 , an inside diameter of the first sub-segment 16 being equal to an inside diameter of the second sub-segment 17 . In contrast, the outside diameter of the first sub-segment 16 is smaller than the outside diameter of the second sub-segment 17 . The second sub-segment 17 is consequently formed with a greater material thickness than the first sub-segment 16 . The first 16 and second sub-segment 17 merge into one another in a step-like manner on the outside, creating a stop both in the direction of the inlet opening 5 and a stop in the direction of the outlet opening 8 is trained pointing.

The intermediate space 13 delimited on the outside by the truncated cone-shaped sub-segment 10 and the cylindrical sub-segment 14 is accessible from a direction running from the outlet opening 8 to the inlet opening 5, with the channel body 6 protruding beyond the spinning cone 2 in the direction of the second end face 7 or the outlet opening 8.

The yarn-forming element 1 is formed rotationally symmetrically with respect to a central longitudinal axis M of the passage 9 .

The yarn-forming element 1 is suitable for an air spinning nozzle, by means of which an air-spun thread can be produced. The air spinning nozzle has appropriate fastening means for receiving the yarn-forming element 1 in order to be able to position the yarn-forming element 1 opposite a sliver feed with the cone tip 3 exactly and as required. For this purpose, according to an exemplary embodiment not shown, the air spinneret can comprise engagement elements which come into contact with the radial outer surface side of the first partial segment 16 and with the stop and with the surface side of the second partial segment 17 pointing towards the outlet opening 8 . As a result, the yarn-forming element 1 can be positioned reliably and stably within the air spinning nozzle, which also allows the yarn-forming element 1 to be exchanged without difficulty.

Reference List

1

yarn forming element

2

spinning cone

3

cone tip

4

first face

5

intake port

6

channel body

7

second face

8th

exhaust port

9

passage

10

truncated cone segment

11

inner surface side of the frustoconical sub-segment

12

outer surface side of the channel body

13

space

14

cylindrical segment

15

inner surface side of the cylindrical sub-segment

16

first segment

17

second segment

18

first segment

19

second segment

20

third segment

21

first transition area

22

second transition area

M

central longitudinal axis of the passage

Claims (13)

Yarn forming element (1) for an air spinning nozzle comprising
a spinning cone (2) with a cone tip (3) forming a first end face (4) with an inlet opening (5),
a channel body (6) forming a second end face (7) with an outlet opening (8), the channel body (6) and the spinning cone (2) being connected to one another, and a passage (9) which connects the channel body (6) and the Spinning cone (2) for connecting the inlet opening (5) with the outlet opening (8) passes,
characterized in that
the spinning cone (2) has a truncated cone-shaped partial segment (10) which extends in the direction of the second end face (7) with an increasing distance between its inner surface side (11) and an outer surface side (12) of the channel body (6 ) to form a gap (13). Yarn-forming element (1) according to Claim 1, characterized in that the spinning cone (2) has a cylindrical partial segment (14) into which the frustoconical partial segment (10) merges on its side facing away from the cone tip (3), an inner surface side (15 ) of the cylindrical sub-segment (14) to the outer surface side (12) of the channel body (6) while continuing the formed gap (13) is spaced. Yarn-forming element (1) according to Claim 1 or 2, characterized in that the intermediate space (13) is designed to be accessible from a direction running from the outlet opening (8) to the inlet opening (5). Yarn-forming element (1) according to at least one of the preceding claims, characterized in that the channel body (6) protrudes beyond the spinning cone (2) in the direction of the second end face (7). Yarn forming element (1) according to at least one of the preceding claims, characterized in that the cylindrical sub-segment (14) has a first sub-segment (16) and a second sub-segment (17), an outer diameter of the first sub-segment (16) being different from an outer diameter of the second sub-segment (17). Yarn-forming element (1) according to Claim 5, characterized in that the first sub-segment (16) is arranged along the channel body (6) closer to the cone tip (3) than the second sub-segment (17), the outer diameter of the second sub-segment (17) is larger than the outer diameter of the first sub-segment (16). Yarn-forming element (1) according to at least one of the preceding claims, characterized in that the cylindrical sub-segment (14) has a first sub-segment (16) and a second sub-segment (17), an inner diameter of the first sub-segment (16) being equal to an inner diameter of the second Sub-segment (17) is. Yarn-forming element (1) according to at least one of the preceding claims, characterized in that the passage (9) has at least three segments (18, 19, 20), each with different internal diameters, with two consecutive segments (18, 19, 20) under Interposition of a transition region (21, 22) merge seamlessly. Yarn-forming element (1) according to one of the preceding claims, characterized in that the yarn-forming element (1) has a ceramic coating on at least all fiber-guiding surface sections. Yarn-forming element (1) according to at least one of the preceding claims, characterized in that the yarn-forming element (1) is formed in one piece from one piece, in particular from a ceramic material. Yarn-forming element (1) according to at least one of the preceding claims, characterized in that the yarn-forming element (1) is rotationally symmetrical and/or mirror-symmetrical to the central longitudinal axis (M) of the passage (9). is. Air spinning nozzle for an air spinning device of an air spinning machine, characterized by a yarn forming element (1) according to at least one of the preceding claims. Method for producing a yarn-forming element (1), characterized in that the yarn-forming element (1) is a yarn-forming element (1) according to one of Claims 1 to 11, the yarn-forming element (1) being made in one piece from ceramic, in particular by means of a sintering process or a stereolithography process , is trained.

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