The invention relates to a roller drafting device for spinning machines in which the covering for the pressure rollers consists of an outer and an inner layer and the outer layer has a thinner wall than the inner layer, as well as to a belt or casing for use as a covering for pressure rollers in such drafting devices for spinning machines in which the thinner-walled outer layer loosely surrounds the thicker inner layer so that the outer layer can move relatively to the inner layer.
During the drafting of fiber bands in drafting devices the clamping action of the roller pairs plays a decisive part for the transfer of the drafting forces onto the fiber band. The roller pairs of the drafting device therefore consist of a fluted steel cylinder, the so-called lower cylinder, and of a pressure roller, the so-called upper roller, that is pressed by load onto the steel cylinder. As a rule, this pressure roller comprises an elastic covering so that no clamping line is produced but rather a clamping surface formed by the deformation of the elastic covering which surface brings about a significantly better fiber retention. A good clamping action is exerted on the fiber structure without damaging the fibers. Experience has shown that soft roller coverings therefore yield better drafting results since the softer the covering is the greater the clamping surface is. However, soft roller coverings have the disadvantage that they wear down very rapidly and that grooves are produced in particular in the area of the fiber passage. This so-called “shrinking” is eliminated by buffing over the entire covering surface. This alters the geometry of the draffing device rollers and therewith also the covering properties, which for its part has a disadvantageous effect on the drafting conditions and thus on the yarn values. In addition, the regrinding of the roller coverings is a quite expensive measure.
The attempt has therefore already been made to counteract this disadvantage by means of a multi-layer roller covering. DE 1 815 739 U teaches a pressure roller whose elastic jacket is subdivided into at least two layers of which the outer layer is designed as an elastic casing consisting of a thin hose that can be drawn over the elastic jacket of the pressure cylinder. The designing of the outer layer as a hose makes it easy to draw a cover over the elastic jacket and also to easily remove it from the latter when this outer circumferential surface has become worn. The fixing of the elastic hose is ensured by the natural friction between rubber and rubber. This known design does make it possible to readily replace the elastic outer layer; however, it was not able to solve the problem of the rapid wear and of the shrinking.
DE 1 685 634 A1 teaches a covering for drafting device rollers of spinning machines which covering is composed of two superposed cylindrical layers of which the outer layer is harder and has a thinner wall than the inner layer. The two layers are adhered to one another. As a result thereof, very different materials can be combined with each other in order to avoid the formation of windings and electrostatic charging. However, it turned out that the problem of a good drafting ability and of wear were not able to be satisfactorily solved. In addition, as a consequence of the adhesion the changing of the outer layer is expensive.
The invention has the problem of eliminating these disadvantages and of finding a roller covering that has high wear resistance and long-lasting elasticity in the running layer and thus ensures optimal drafting conditions for a long time. This problem is solved by the characteristic features of claim 1. It surprisingly turned out that it is important in a multi-layer covering with a thin outer layer and a thicker inner layer that a relative movement can take place between the two layers. The milling motion of the soft covering and the tension forces produced thereby are then transferred only onto the inside of the outer, thin-walled layer but not on the fibers and the fluted cylinder. Practically no wear occurs any more, in particular no groove formation (shrinking), so that the outer layer has a service life that is more than three times longer.
The outer layer is advantageously adapted on its outside as a fiber contact surface to the requirements of a good fiber clamping and on its inside as a running surface to the smoothest possible, low-friction running of the pressure roller. This is achieved, e.g., in a simple manner by the selection of appropriate material compositions for the fiber contact layer and the running layer of the outer layer. This outer layer can be designed as the casing around the inner pressure roller layer as well as an endless belt. It must only be so flexible that it adapts to the deformation of the soft inner layer. It proved to be especially advantageous to design the outer layer in the direction of travel of the fiber structure, that is, transversely to the roller axis, as inelastically as possible, that is, that is, with the lowest possible extensibility. The tension forces in the clamping surface producing wear and acting negatively on the drafting are eliminated in this manner, whereas the outer layer can adapt in axial direction to the rugosities of the fiber structure. An excellent clamping is achieved in this manner. The desired reduction of the expansion of the outer layer transversely to the axis of the pressure roller is achieved quite well by a yarn insert without limiting the expandability in the direction of the roller axis. The relative motion between the outer layer and the inner layer is favored by the smoothest possible surface of the running layer of the outer layer, and as a consequence thereof the breakdown of the tension forces is furthered in an even better manner.
It is advantageous for a high delivery speed to use an outer layer designed as a belt and to run this belt through a deflection rail. In addition, this deflection rail can also comprise side rims for a more reliable guidance. It also proved to be especially advantageous at high delivery speeds for a trouble-free travel if the belt rolls off the pressure roller at an angle α>30° to the plane of the fiber structure. The belt advantageously consists of several layers and the inside is designed as a smooth travel layer and the outside as a fiber contact layer. A yarn insert is provided between the layers which prevents the belt from expanding in the direction of travel without adversely influencing a desired transverse expansion.
Further details of the invention are explained using the figures.
In
In the customary pressure roller coverings a clamping surface is formed by the soft elastic covering which surface produces a good clamping action. However, tension forces are produced in the area of the clamping surface by the pressing work of the covering that have a negative effect on the fiber structure during drafting and also cause the known high wear of the covering. However, the arrangement of an outer layer 1 that flexibly adapts to the deformation of soft and elastic covering 2 of pressure roller 3 but that causes no or only a very low pressing work on account of its lower thickness and deformability surprisingly led to the result that this outer layer 1 exhibits a significantly greater stability and also the soft inner layer 2 displays none of the customary phenomena of wear and shrinking. It turned out in extensive tests that outer layer 1 still ran without any problems even after three times the run time and did not have to be replaced. The drafting values were even able to be improved compared to new traditional coverings. It is to be assumed that this surprising result can be traced to the fact that the tension forces conditioned by the pressing work of soft and elastic inner layer 2 of pressure roller 3 can not affect the clamped fiber structure. These tension forces are degraded by the relative motion that is possible between soft inner layer 2 and smooth run layer 102 of outer layer 1. No relative movement takes place between the fibers and drafting device cylinder 5 as well as outer layer 1 so that the clamping takes place in the area of static friction. Thus, no wear caused by sliding can occur.
In the exemplary embodiment according to
It should be taken into consideration that, depending on the particular draft, drafting devices 3, 5 forming the delivery roller pair run approximately 20 to 30 times more rapidly than the roller pairs arranged in front of the main drafting field, that are customarily surrounded by fiber guide belts. These known fiber guide belts proved to be unsuitable for being used as outer layer 1 on exit roller pair 3, 5. These belts are insufficient in their properties. Thus, it turned out, e.g., that it is important that outer layer 1 or belt 10 or 100 is as inelastic as possible in the direction of travel of fiber structure F, that is, transversely to roller axis 31, so that it can not expand.
Of course, not every expansion can be eliminated in the physical sense but it should be as small as possible. This achieved in a simple manner by yarn insert 103. Furthermore, the known belts favor the sliding of the fibers during drafting, which is undesired for the exit roller pair.
Yarn insert 103 takes the elasticity from belt 100 in the direction of travel so that an expansion is practically not possible. However, the expandability remains transversely to the direction of travel, that is, in the direction of pressure roller axis 31. The belt can adapt to the rugosities of drafted fiber structure F so that a good clamping is always ensured. In spite of these multi-layers of the outer layer, the latter must naturally not be too thick in order to impart good flexibility to it for adaptation to the deformation of inner layer 2 and to fiber structure F. A total thickness of 0.8 to 1.0 mm has proven to be especially advantageous in this connection as regards the stability and also the drafting results. No groove formation (shrinkage) could be determined even after several years of run time.
The desired properties of run layer 102 and a fiber contact layer 101 can also be achieved by an appropriate physical shaping of the surfaces. However, run layer 102 and fiber contact layer 101 preferably consist of different materials that have the desired sliding properties and the necessary grip. Measurements according to DIN 53375 have shown that e.g., the above-described material for fiber contact layer. 101 has a frictional force value that is at least twice as high as the frictional force value of run layer 102 when the latter consists of a material like that used for belts for fiber guidance in the main drafting field. Run layer 102 thus has good sliding properties while fiber contact layer 101 achieves an excellent clamping of the fibers.
The manufacture of such an endless belt in accordance with
In the embodiment according to
Number | Date | Country | Kind |
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102 60 025.2 | Dec 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP03/14369 | 12/17/2003 | WO | 6/16/2005 |