EP2893064A2

EP2893064A2 - Spinning machine having a twisting element

Info

Publication number: EP2893064A2
Application number: EP13779909.4A
Authority: EP
Inventors: Christian Griesshammer; Ludek Malina; Petr Blazek; Vaclav Kubovy; Jarmila Steklikova; Radek Zarecky; Petr Haska
Original assignee: Maschinenfabrik Rieter AG
Current assignee: Maschinenfabrik Rieter AG
Priority date: 2012-09-04
Filing date: 2013-08-16
Publication date: 2015-07-15
Also published as: CH706909A1; CN104603340A; WO2014037773A3; WO2014037773A2

Abstract

The invention relates to a spinning machine (1), comprising a multi-cylinder drawing frame (2) for processing a fiber sliver (4), wherein the multi-cylinder drawing frame (2) comprises an intake roller pair (6) and at least two additional roller pairs (10, 12) arranged after the intake roller pair (6), which form a preliminary draft zone (7) and at least one main draft zone (8). In order to avoid faulty drafts in the multi-cylinder drawing frame (2), the multi-cylinder drawing frame (2) has a mechanical twist-producing means (9) in the preliminary draft zone (7).

Description

Spinning machine with swirl element

The invention relates to a spinning machine with a multi-cylinder drafting system for processing a fiber structure, wherein the multi-cylinder drafting system consists of an inlet roller pair and at least two other pair of rollers arranged below the pair of inlet rollers, which form a Vorverzugszone and at least one main drafting zone.

Spinning machines of this type are currently suitable for processing a fiber structure in the form of a roving or a sliver, in which the fibers are screwed approximately uniformly, and are fed to the multi-cylinder drafting system via a flyer spool. The term fiber structure means a collection of staple fibers which are combined in a sliver. In a first draft zone, the pre-draft zone, the fibers are largely parallelized in the twisted state by means of a delay and prepared for the subsequent main delay.

In the recent past, more and more fiber assemblies are used, in which not all fibers are screwed in evenly, such. As slightly twisted bands, partially twisted bands or fine bands with predominantly parallel fiber layer. A major problem in the processing of such fiber composites with multi-cylinder drafting of current spinning machines is that due to the lack of stability in the fiber structure in the pre-draft zone often misalignments occur, which adversely affect the subsequent yarn quality.

From the field of spinning machines for processing long staple fibers by the 2-cylinder method has long been known that the fiber structure in the drafting, which consists of a single draft zone, for stabilization a false twist is imposed, so that an optimal drafting process can be realized. The term false twist here means that the fiber structure in the current process in front of the false twist element in sections, or temporarily rotation and thus given a certain strength, and that the fiber structure returns to the false twist element back to the initial state, so that the fiber structure despite imposed rotation remains undistorted in the result. So z. B. the company BEFAMA for the drafting system of 2-cylinder carded-ring spinning a fixed wire screw before, which additionally applied to the fiber structure in the single draft zone of the drafting system, for controlling so-called floating fibers, with a false twist.

For such a measure, to apply the fiber structure in the drafting system for stabilization with a false twist to avoid false warping, was in the field of processing short staple fibers so far not necessary, since mainly uniformly twisted fiber composites were processed.

The invention is therefore based on the object to perform a spinning machine with a multi-cylinder drafting system with at least one Vorverzugs- and a main drafting zone for processing a fiber structure of short staple fibers so that false distortions in the processing of unevenly twisted fiber composites are avoided.

According to the invention, this object is achieved in that the multi-cylinder drafting system in the Vorverzugszone has a mechanical swirl generating means. Experiments have shown that the introduction of a false twist on the swirl-producing agent in a non-uniformly twisted fiber structure of the fiber composite can be consolidated or stabilized in total so that, for example located in the fiber structure thin points can not adversely affect the drawing process in the drafting zone. That is, by the swirl-producing agent, for. B. an interruption or further thinning of the fiber structure in the region of the thin areas during the drawing process in the pre-drawn zone can be avoided. By the proposed swirl generating means is also achieved that the entire warping process is self-regulating, so that the distortion force can be kept in a defined frame. It can thereby be limited to the forces acting on the center cylinder of the multi-cylinder drafting forces. The number of order ^¬ schlingungen in the swirl generating means may, for example between 0.75 and 5, preferably to between 1.5 and 2.5. The permissible distortion force is limited to about a force that occurs when processing a uniformly twisted roving in a conventional multi-cylinder drafting system. Moreover, it is advantageous that through the use of the proposed swirl generating means the Distances of the clamping points of a conventional multi-cylinder drafting system can be maintained.

In order to achieve an exact guidance of the fiber structure in the swirl-generating means, it has moreover proven to be advantageous if the swirl-generating means is designed as a guide element which is stationary relative to the conveying direction of the fiber structure and shows its longitudinal direction in the conveying direction of the fiber structure. Does it come during the spinning process to an interruption of the fiber flow, z. As in a bobbin change, the Luntenenden are securely connected to each other by the proposed guide element, so that the connected Luntenenden can safely pass through the drafting system.

Experiments have also shown that different embodiments of the guide element lead to Falschdrallbeaufschlagung the fiber structure. In a proposed embodiment, the guide element has a core running in the conveying direction of the fiber structure, so that the fiber structure undergoes a helical deflection by the guide element. This embodiment of the guide element proves to be advantageous because of its simplicity. In a further proposed embodiment, the guide element has an inwardly extending helical guide surface. The advantage of this embodiment is that over this type of guide surface the fiber structure a precisely defined false twist is imposed, so that it is reproducible. Operating errors of the operating personnel can thus be avoided. For easier insertion or threading of the fiber structure into the guide element, the guide element has at one end an insertion channel running in the conveying direction of the fiber structure, which is surrounded by an insertion cam which is raised on one side. In addition, the guide element at the opposite end to the insertion channel an outlet cam, which is also increased on one side. Both the insertion cam and the outlet cam have the advantage that jumping out of the fiber dressing from the guide element can be prevented. In a further embodiment, it is proposed to design the guide element as a spiral with a clear diameter, wherein the clear diameter is smaller than the diameter of the fiber structure and may be between 0.2 and 10 mm, preferably 0.5 to 5 mm. In the case of the withdrawal movement of the fiber structure, the guide element is thereby impressed spirally in the sheath of the fiber structure. A significant advantage of this embodiment is that the fiber structure in the guide element retains its original conveying direction and undergoes only a small additional deflection, so that the self-regulation of the delay takes place in a simple manner. In addition, it is advantageous that incorrect filing of the fiber structure can be avoided.

For introducing the fiber structure in the guide element, it has also proven to be advantageous if the guide element is movably mounted. The operating personnel is thereby made possible to move the guide element during an insertion process of the fiber structure from the Vorverzugszone, thereby simplifying the insertion or threading of the fiber structure in the guide element.

For a simple insertion or threading of the fiber structure in the guide element, it is advantageous if, as further proposed, the guide element is mounted pivotably about an axis arranged parallel to the axes of the pair of inlet rollers, wherein the free end of the guide element points in the direction of the main draft zone.

The fiber strand is often imposed a traversing movement transversely to the conveying direction of the fiber structure when entering the drafting system, whereby the clamping point along the nip line of the roller pairs is changed continuously. As a result, premature wear of the coated pressure rollers of the roller pairs can be counteracted. So that the guide element can follow the traversing movement, it is proposed that the guide element is mounted movably parallel to the axes of the inlet roller pairs. It can thereby be avoided that the fiber in the pre-draft zone additional deflections in the region of the guide element is exposed, which lead to stresses in the fiber structure.

So that the guide element can follow the traversing movement, it is proposed to mount the guide element so as to be pivotable about an axis arranged parallel to the conveying direction of the fiber structure.

The attachment of the guide elements on the spinning machine can be done in various ways. In one embodiment, it is proposed to arrange a plurality of guide elements next to one another on a carrier, which is mounted detachably on the spinning machine parallel to the axes of the inlet roller pairs. This type of fastening has the advantage that the tensile forces acting on the guide element from the fiber structure can be absorbed directly by the carrier. In addition, the carrier on the spinning machine is easy to install, so that a subsequent attachment of the carrier to the spinning machine can be carried out quickly.

Furthermore, it is proposed to move or drive the carrier via a drive element connected to the carrier parallel to the axes of the inlet roller pair.

If the spinning machine has a traversing device which sets the fiber structure in a traversing movement, it is proposed in another embodiment to fix the carrier with the guide elements directly to the traversing device so that the guide elements can follow the traversing movement of the traversing device directly.

The invention will be shown and described in more detail with reference to subsequent embodiments. 1 shows a cross section of a conventional two-stage multi-cylinder drafting system, in which a swirl-producing agent according to the invention is integrated, Figure 2 is a perspective partial section of Figure 1, showing the essential elements in the vicinity of the swirl-generating means with various forms of the traversing device and

Figure 3 is a schematic representation of a swirl generating means in three different embodiments (9a-9c).

The spinning machine 1 according to Figure 1, a conventional two-stage multi-cylinder drafting unit 2, which further have a pair of feed rollers 6 and two of the inlet roller pair 6 are disposed downstream roller ^pairs' 10, 12 a main drafting zone 8 is divided into a Vorverzugszone 7 and. From a flyer bobbin 3, a fiber strand 4, for example, a sliver or a roving, via the inlet roller pair 6 of the pre-draft zone 7 is fed. A traversing device 5, which is connected upstream of the inlet roller pair 6, sets the fiber structure 4 before entering the pre-draft zone 7 in a traversing movement, so that the clamping point along the nip of the pairs of rollers 6,10,12 changed continuously.

In the Vorverzugszone 7, a mechanical swirl generating means 9 is arranged, which acts on the fiber structure 4 with a false twist. The swirl generating means 9 is designed as a guide element which is stationary relative to the conveying direction F of the fiber structure 4 and whose longitudinal direction is aligned in the conveying direction F of the fiber structure 4. The main drafting zone 8 has to guide the fiber structure 4 a Doppelriemchen 1 1, which is attached to the middle pair of rollers 10 and driven by this. About a take-off roller pair 12 of fiber structure 4 is removed from the main drafting zone 8. Subsequently, the fiber structure 4 is screwed by means of a spin-forming device 13, for example a ring spinning device, and wound onto a yarn package 14.

FIG. 2 shows a perspective partial detail from FIG. 1, with a representation of the essential elements in the vicinity of the swirl-generating means 9 or of the guide element.

In one possible embodiment in the front part of FIG. 2, the swirl-generating means 9 in the pre-draft zone 7 is pivotable about a swivel axis 18 on a prebending zone 7. nem holding element 15 stored. The pivot axis 18 is arranged parallel to the axes A1, A2 of the inlet roller pair 6, so that the free end of the swirl-generating means 9 points in the direction of the main draft zone 8, not shown. The holding element 15 is (as indicated by a double arrow) via a guide pin 21 movably mounted on a support 16 which is mounted parallel to the axes A1, A2 of the inlet roller pair 6 removable on a machine frame 17. Also, an embodiment is possible, wherein the holding element 15 is fixedly connected to the carrier 16, and the carrier is movably mounted on the machine frame 17. Due to the movable mounting of the holding element 15 on the carrier 16 and the carrier 16 on the machine frame 17, the swirl generating means 9 is able to follow the traversing movement of the traversing device 5.

During the spinning process, the longitudinal direction of the swirl-generating means 9 is aligned in the conveying direction F of the fiber structure 4. The fiber structure 4, which is supplied via the inlet roller pair 6 to the swirl-generating means 9, undergoes a false twist in the swirl-generating means 9, which causes the fiber structure 4 in the pre-drawn zone 7 to be stabilized in such a way that mis-distortions are avoided.

Does it come during the spinning process to an interruption of the fiber flow, z. B. because the flyer bobbin 3 is empty, the swirl generating means 9 is pivoted out of the Vorverzugszone 7 about the pivot axis 18 and it is introduced or threaded a new fiber structure 4 in the swirl generating means 9. After introduction of the new fiber composite 4, the swirl-generating means 9 is pivoted back into the pre-draft zone 7. An embodiment is also possible, wherein the swirl-generating means 9 is movably mounted on the holding element 15 via guides, not shown, so that the swirl-generating means 9 can be moved out of the pre-draft zone 7 in the event of an interruption of the fiber flow.

So that the swirl generating means 9 can follow the traversing movement of the traversing device 5, in a further embodiment, which is shown in the middle part of Figure 2, the holding member 15 is pivotally mounted on the carrier 16 about a parallel to the conveying direction F of the fiber structure 4 arranged axis 20. According to a further embodiment in the rear part of Figure 2, the swirl generating means 9 is pivotally mounted on a holding element 15 similar to the previous embodiments. The holding element 15 in turn is movably mounted on a carrier 16 via a guide pin 21. In contrast to the preceding exemplary embodiments, the retaining element 15 is connected directly to the traversing device 5 via a connecting element 19, so that the traversing movement of the traversing device 5 can be transmitted directly to the swirl-generating means 9.

In the aforementioned exemplary embodiments, a plurality of twist generating means 9 are preferably arranged side by side on the carrier 16 so that a plurality of spinning stations 13 not shown in FIG. 2 can be provided with a swirl generating means 9 by a carrier 16. In addition, it is possible to line up a plurality of carriers 16 along the spinning machine 1 in order to provide the entire spinning stations 13, which extend along the spinning machine 1, with a swirl-generating means 9.

Figure 3 shows three different embodiments of the swirl generating means or the guide element (9a-9c). In a first embodiment, the guide element 9a has a core 22 extending in the conveying direction F of the fiber structure 4, via which the fiber structure 4 undergoes a helical deflection. This form of embodiment can be realized by means of a simple wire hook.

In a further embodiment, the guide element 9b has an inwardly extending helical guide surface 23, via which the fiber structure 4 is deflected helically. About the number of turns, the guide element 9b shows, the fiber structure 4 a precisely defined number of rotations can be imposed. For easier insertion or threading of the fiber structure 4 in the guide element 9b, the guide element 9b at one end in the conveying direction F of the fiber structure 4 extending insertion channel 24 which is surrounded by a one-sided increased introduction cam 26. In addition, the guide member 9b faces on the opposite to the insertion channel 24 End of a spout cam 27, which is also raised on one side. Both the insertion cam 26 and the outlet cam 27 prevents the fiber dressing 4 from jumping out of the guide element 9b. In addition, below the insertion channel 24 transversely to the longitudinal direction of the guide element 9b, a through hole 25 is arranged, via which the guide element 9b can be pivotally mounted on the holding element 15.

In a further embodiment, the guide element 9c is designed corkscrew-shaped as a spiral with a clear diameter d, wherein the clear diameter d is smaller than the diameter of the fiber structure 4 and can be between 0.2- 10 mm, preferably 0.5- 5 mm. In the case of the withdrawal movement of the fiber structure 4, the guide element 9c is thereby impressed spirally in the jacket of the fiber structure 4.

Claims

Patent claims

1. Spinning machine (1) with a multi-cylinder drafting system (2) for processing a fiber structure (4), with a pair of inlet rollers (6) and at least two further pairs of rollers (0, 12) arranged downstream of the inlet roller pair (6), which one Pre-draft zone (7) and at least one main draft zone (8), characterized by a mechanical twist generating means (9) arranged in the pre-draft zone (7).

2. Spinning machine according to the previous claim, characterized in that

Swirl generating means (9) is designed as a guide element which is stationary relative to the conveying direction of the fiber structure (4) and whose longitudinal direction is aligned in the conveying direction of the fiber structure (4).

3. Spinning machine according to the previous claim, characterized in that

Guide element (9a) has a core (22) running in the conveying direction of the fiber structure (4), so that the fiber structure (4) experiences a helical deflection through the guide element (9a).

4. Spinning machine according to one or more of claims 1-2, characterized in that the guide element (9b) has an internally extending helical guide surface (23).

5. Spinning machine according to one or more of claims 1-2, characterized in that the guide element (9c) is designed as a spiral with a clear

Diameter (d) is carried out, the clear diameter (d) being smaller than the diameter of the fiber structure (4).

6 spinning machine according to one or more of the preceding claims

characterized in that the guide element (9) is movable.

7. Spinning machine according to the preceding claim, characterized in that the guide element (9) is pivotally mounted about an axis (18) arranged parallel to the axes of the pair of inlet rollers (6), the free end of the guide element (9) pointing in the direction of the main draft zone (8 ) shows.

8. Spinning machine according to one or more of the preceding claims

characterized in that the guide element (9) is movably mounted parallel to the axes of the inlet roller pair (6).

9. Spinning machine according to one or more of claims 1-6, characterized in that the guide element (9) can be pivoted about an axis (20) arranged parallel to the conveying direction of the fiber structure (4).

10. Spinning machine according to one or more of the preceding claims

characterized in that a plurality of guide elements (9) are arranged next to one another on a removable support (16).

11. Spinning machine according to the preceding claim, characterized in that the carrier (16) is arranged parallel to the axes (A1, A2) of the inlet roller pair (6) via a drive element (AT) connected to the carrier (16).

12. Spinning machine with a traversing device (5) arranged in front of the pair of feed rollers (6), characterized in that the guide elements (9) are attached to the traversing device (5).

13. Twist generating means for a spinning machine (1) according to one or more of the preceding claims.