EP1000196A1

EP1000196A1 - Multi-layer screen for the wet area of a paper machine and product manufactured using the same

Info

Publication number: EP1000196A1
Application number: EP98943749A
Authority: EP
Inventors: Hans-Jürgen Lamb
Original assignee: SCA Hygiene Products GmbH
Current assignee: Essity Germany GmbH
Priority date: 1997-07-30
Filing date: 1998-07-21
Publication date: 2000-05-17
Anticipated expiration: 2018-07-21
Also published as: DE19732879C2; SK1122000A3; CN1272155A; JP2001512192A; DE19732879A1; CZ2000296A3; BR9811566A; AU730580B2; HRP20000043A2; ATE209270T1; ES2169546T3; PL187485B1; AR013263A1; WO1999006629A1; TR200000277T2; PL338418A1; EP1000196B1; KR20010022426A; CO5040193A1; AU9154898A

Abstract

The invention relates to a multi-layer screen (10, 11) for the wet area of a paper machine and to a tissue paper produced using the same. The inventive screen consists of threads, preferably woven threads, forming at least two layers. These layers are joined to each other by additional threads (14) which are interlaced with the layers. Together with the threads which make up the layers, the additional threads (14) form constricted points (16), said constricted points being spread across the length and breadth of the screen. A significantly less quantity of water can pass through these points than through the areas adjacent thereto. Arranged in special sequences, the additional threads are a means of influencing the drainage of water through the screen at the constricted points for producing tissue paper with alternating areas of high and low GSM substance. The invention therefore provides a simple means of producing a tissue paper with a flexible, thin, non-homogeneous, net-like structure.

Description

Multi-layer screen for the wet area of a paper machine and the product made with it

The invention relates to a multi-layer sieve for the wet area of a paper machine, in particular for tissue production, with at least two layers made from threads, preferably woven threads, which are connected to each other by additional threads intertwined with the layers and a product produced therewith.

Such a multilayer sieve is known from US Pat. No. 5,219,004.

In the production of paper and in particular tissue paper, it is known to alternately provide a high and a low basis weight in the wet area by selective selective dewatering through the screen over certain areas by differentiated deposition of the fibers. In places where the sieve is more permeable to the draining water, ie in the so-called open zones, more fibers are deposited than in the so-called closed zones. Usually, the closed and open zones are formed by arranging weft and / or warp threads of the fabric forming the screen at different distances from one another, a distinction being made according to the machine direction and the transverse direction perpendicular thereto. This makes it possible to use paper, e.g. B. silk or tissue paper, with a network-like structure in which the normally flat, homogeneous, normally inflexible structure of the dried silk or tissue paper due to the differences in basis weight generated in the sheet formation in the macroscopic area in a flat, inhomogeneous, network-like structure is transferred, which reacts flexibly when subjected to external forces. Like conventional silk or tissue paper, paper is a flat structure in which the individual fibers are firmly anchored in its structure. The integration of the fibers into the structure results in an inflexible, rigid structure with a macroscopically homogeneous basis weight. In the uncreped state, silk or tissue paper has very low elongation values, in the range <= 6%. The creping process which is usually carried out in the manufacture of tissue paper makes the tissue paper more flexible compared to the stresses caused by external forces, but predominantly in the machine direction. The higher flexibility in the machine direction that can be achieved with creping in the case of a homogeneous paper structure manifests itself in an increased working capacity with the result of greater flexibility in the machine direction.

By converting the flat, homogeneous structure into network-like, flat, inhomogeneous structure, the flexibility of the paper and thus also of a silk or tissue paper can be additionally improved, whereby this improvement is not limited to the machine direction, but can also be achieved in the cross machine direction .

As has already been stated, the network-like structure is achieved by varying the basis weight, areas of high basis weight and areas of low basis weight in the macroscopic range being one another alternate. The variation in the basis weight is achieved by varying the drainage capacity of the sieve. Where, according to the above explanations, many fibers are deposited, one speaks of a zone of high basis weight. Where few fibers are deposited, one speaks of a zone of low basis weight.

Due to the locally different drainage capacity of the screen, there are also partial flows parallel to the screen surface, which means that the fibers are more or less aligned, similar to the way real watermarks are created.

It is known to achieve zones of different drainage performance by narrowing the screen by closing zones in the screen with plastic glue or paint, etc. (e.g. WO 93/00474).

The openness of the sieve can also be varied by combining different weaving patterns. The base fabric of the structure-forming sieve can have one or more layers, but preferably two layers. As has already been mentioned in connection with US Pat. No. 5,219,004, it is already known to connect the layers to one another by means of additional threads.

It is an object of the invention to provide a multi-layer structure-giving sieve of the type mentioned at the beginning, which enables the modified dewatering properties mentioned to be set in a simple manner in order to produce an improved product.

This object is achieved in that the additional threads together with the threads forming the layers form narrowing points distributed over the width and length of the sieve, through which significantly less water can flow off than through the adjacent areas. This solution is characterized in that the additional threads used for connecting the layers of the sieve are used to form the closed zones or essentially closed zones of the sieve, the essentially open zones being formed in the regions of the sieve, where the additional threads do not close the stitches in the base fabric. Thus, a double function is achieved with the additional threads. Such a sieve can be used to produce a significantly improved paper product, in particular silk or tissue paper.

In an advantageous further development of this solution, the additional threads can form constriction z. B. run in the machine direction and appear at predetermined locations on the top of the screen or the location there and these as constriction points in

Grouping or lining up in different directions form constriction areas that appear as a pattern over the surface of the sieve. These points form macroscopic areas of low basis weight in the paper or tissue paper, ie structures with a lower deposition of fibers than in the adjacent areas, as a result of which the elongation behavior in the longitudinal and transverse directions, but especially in the transverse direction, is advantageously influenced. This is due to the fact that, with a certain orientation, the area components of low basis weight lead to a weakening in comparison with a homogeneous structure, as a result of which the above-mentioned increased flexibility of the inhomogeneous compared to the homogeneous structure is achieved. The surface weight differences which can be achieved in the aforementioned manner and which can be arranged according to a predeterminable structure in the fiber network of a paper, in particular a silk or tissue paper, accordingly lead to an increase in the labor absorption capacity in the longitudinal and transverse directions, which is particularly desirable for tissue papers. If, for example, the constriction points for the formation of longitudinal sections are lined up at an angle to the machine direction of the screen, greater flexibility is achieved across the machine direction, in addition to the flexibility in the machine direction, which improves the flexibility by creping.

In the same sense, the constriction points for the formation of longitudinal sections can also be strung together to some extent perpendicular to the machine direction and partially in the machine direction.

With regard to a further design option, the longitudinal sections can also be aligned alternately in opposite directions. However, the longitudinal sections can also be arranged in parallel within the same orientations in groups.

According to a further embodiment, the constriction points can be strung together to form zigzag or wavy courses.

The constriction points can be arranged so that closed or at least partially open, but also continuous courses are formed. The arrangement of the constriction points can also be such that discontinuous courses are available alone or together with continuous courses.

A paper product produced with such a sieve, in particular silk or tissue paper, has considerably improved properties, in particular with regard to the so-called feel or softness. There is a positive influence on dry and wet strength as well as a positive effect on the crepe process, drying, pressing and dewatering. The invention is explained in more detail below with reference to the exemplary embodiments shown purely schematically in the drawings. Show it:

Figure 1 is a plan view of a multi-layer sieve according to the invention.

Figure la is a sectional view through the screen of Figure 1 along the section line a-a.

1b shows a sectional view through the sieve according to FIG. 1 along the section line b-b;

2 to 5 plan views of different structural patterns of tissue papers, produced with multi-layer sieves similar to those of FIG. 1;

6 to 12 are schematic representations of further multi-layer sieves with different configurations of the layer arrangement of additional threads as connecting threads;

13a shows a conventional flat, homogeneous tissue paper before and after applying a stretching force (arrows); and

13b shows a flat, inhomogeneous, network-like tissue paper according to the invention, also before and after applying a stretching force (arrows).

The double-layer sieve is designed as a fabric, with an upper fabric 10 and a lower fabric 11. The machine direction of the screen is indicated by the arrow A. Depending on the weaving process selected, the threads 12a of the upper fabric (paper-touched side) can be designed as warp threads, but also as weft threads, but preferably as warp threads. same for correspondingly vice versa for the threads 12b of the upper fabric. In the same way, this applies accordingly to the threads 13a and 13b of the lower fabric.

In this exemplary embodiment, additional threads 14 run as connecting threads 14 in the same direction and parallel to the threads 12a in such a way that, as shown in FIG. 1b, the additional threads 14 run between the threads 13b and threads 13c of the lower fabric 11 and on the thread from FIG 1 visible places close stitches 15 by appearing there on the upper side of the upper fabric 10 and running above threads 12c of the upper fabric. There the additional threads 14 form constriction points 16 in the machine running direction. Lined up obliquely to the machine direction A, these constriction points 16 result in constriction regions 17 designed as longitudinal sections. Purely by way of example, two parallel constriction regions 17 and 18 are provided in each direction. Alternating such constriction areas are in z. B. mutually perpendicular directions are provided over the screen surface, so that a pattern of constriction areas is formed. These constriction areas form the previously mentioned low basis weight zones in the silk or tissue paper produced on this screen, in order to give it the desired flat, inhomogeneous, network-like structure of high flexibility under stress. Such a structure with different designs can be seen in FIGS. 2 to 5. FIG. 2 shows a product that was produced with a sieve structure according to FIG. 1. The areas marked in dark form the aforementioned network-like structure. This creates a coherent zone of high basis weight. The same applies to the product according to FIGS. 3, 4 and 5. For the products according to FIGS. 2, 3, 4 and 5, the dark areas, which mean high weight, can also be those with low weight and which are light represented area parts, which mean low basis weight, correspondingly be those with high basis weight (see the example of FIGS. 2a, 3a). Then the brightly colored areas form the aforementioned network-like structure.

Further modifications of the sieve structure can be seen schematically in FIGS. 6 to 8. In the case of a product which has been produced with a sieve structure according to FIG. 7 or 8, the parts by area having a low basis weight form the aforementioned network-like structure.

As shown in FIG. 13a in the case of conventional tissue paper, almost no change in length of the tissue paper can be determined when a stretching force is applied, but it can be seen in the case of the tissue paper in accordance with FIG. 13b.

Claims

claims

1. Multi-layer sieve for the wet area of a paper machine, made from threads, preferably woven threads with at least two layers (10, 11), which are connected to each other by additional threads (14) intertwined with the layers (10, 11), characterized in that that the additional threads (14) together with the threads (12a, 12b, 12c; 13a, 13b, 13c) forming the layers (10, 11) form constriction points (16) distributed over the width and length of the sieve, which clearly show less water can drain off than through neighboring areas.

2. Multi-layer sieve according to claim 1, characterized in that the additional threads (14) constricting parts (16) forming in the machine direction (A) and appear at predetermined locations on the top of the sieve (10) or the position there and this form constriction areas (17, 18) as constriction points in a grouping or in a row in different directions, which appear as a pattern over the surface of the sieve.

3. Multi-layer sieve according to claim 1 or 2, characterized in that the constriction points (16) to form longitudinal sections (17, 18) are lined up obliquely to the machine direction (A).

4. Multi-layer sieve according to claim 1 or 2, characterized in that the constriction points (16) to form longitudinal sections (17, 18) are strung together, partly perpendicular to the machine direction (A) and partly in the machine direction.

5. Multi-layer sieve according to claim 3 or 4, characterized in that the longitudinal sections (17, 18) are alternately aligned in opposite directions.

6. Multi-layer sieve according to claim 3 or 4, characterized in that the longitudinal sections (17, 18) are arranged in parallel within the same orientations in groups.

7. Multi-layer sieve according to at least one of claims 1 to 3, characterized in that the constriction points (16) are lined up to form zigzag or wavy courses.

8. Multi-layer sieve according to claim 1 or 2, characterized in that the constriction parts (16) are arranged in such a way that closed courses are formed.

9. Multi-layer sieve according to claim 1 or 2, characterized in that the constriction points are arranged so that partially open courses are formed.

10. Multi-layer sieve according to claim 1 or 2, characterized in that the constriction points are arranged in such a way that continuous courses are formed.

11. Multi-layer sieve according to claim 1 or 2, characterized in that the constriction points are arranged in such a way that discontinuous courses are formed.

12. Multi-layer sieve according to claim 1 or 2, characterized in that the constriction points are arranged in such a way that continuous and discontinuous courses are formed.

13. Product produced on a paper machine with a multi-layer sieve according to at least one of claims 1 to 12.

14. Product according to claim 13, characterized in that it is a tissue paper.