FI96047C - Dewatering cloth for the press section of a paper machine - Google Patents

Description

- 96047

Dewatering cloth for the press section of a paper machine

The present invention relates to dewatering fabrics for use in a press section of a paper machine, and more particularly to a woven dewatering fabric for a press section of a paper machine, wherein the machine on the opposite side, long free yarns in a monofilament warp yarn having a flattened cross-section with a width-to-thickness ratio of at least 1.5: 1, the flattened monofilament yarn having a fill factor of at least 45%, 15. wherein: (i) "a" means the number of weft yarns (4; 11; 14; 21; 30; 31) in one repeating layer of the pattern of the flattened monofilament yarn in the anti-paper surface layer 20 which weft yarns are located in under the suction and in contact with it; and (ii) "b" means the total amount of weft yarn in the anti-paper surface layer in the same repetitive tissue pattern.

Flattened monofilaments provide better dewatering and fewer marks on the paper.

30 The press section of a paper machine carries a thin, wet, self-supporting web of entangled fibers with a density ranging from 15 to 25% (i.e., a wet paper web containing about 15 to 25% fibers and other solids and about 75 to 85% water) for several through the press rolls at the same time as it is supported on a plurality of endless belts of permeable fabric. In each set of rollers, a portion of the water contained in the paper web is transferred to the fabric by the pressure of the linear compression point between the rollers of the press 96047 2. At the end of the press section, the density of the wet paper web is 30 to 50%. Two press rolls are usually used in the press section. The second roll is generally smooth and can be provided with an elastomeric surface (usually rubber). The surface of the second roll is shaped and generally also made of an elastomeric material adapted to provide a cavity into which water can pass from the press fabric. A roll having grooves on its surface located around the roll and 10 perpendicular to the axis of the roll is commonly used. The press fabric acts as an intermediary between the grooves (or other collectors such as perforations) and the wet paper web. As the paper web supported by the fabric passes to the compression point between the press rolls, water is pressed from the paper-15 web into the fabric compressed by the smooth roll and finally into the roll groove. When the fabric and the wet paper web leave a squeezing point, some of the water left in the fabric may transfer back to the wet paper web, which re-absorbs it.

20

Generally, the press fabric comprises, in combination, a base fabric to which a staple fiber fiber sheet is attached with needle pins. Some press fabrics use a single layer of cotton sheet with needle pins attached to the paper side of the base fabric. Others use two layers of batt, one on each side of the base fabric to which both are attached with needles. It is known that the batt fibers are generally in the same direction in the direction in which the batt is placed on the base fabric. If the batt is 30 transversely overlapped, i.e. substantially in the cross-machine direction, • not only are the batt fibers located parallel across the machine but there is also a transverse overlap line between successive batt strips. These joints can lead to mass gears in the press fabric, which in extreme cases can cause vibrations in the track racks, damaging the machine. In newer methods, the batt sheet can be placed substantially in the machine direction using e.g.

The method described in U.S. Pat. No. 3,508,307, which both eliminates mass variations in the cross-machine direction and provides better water removal because the batt fibers 5 are parallel in the machine direction.

The base fabrics of modern press fabrics may include a needle seam and are generally woven from synthetic, round-cut monofilaments 10, i.e., monofilament yarns, both warp and weft, as disclosed in U.S. Patent 4,601,785. so that the loops retain their shape and thus ensure that the fabric is easy to seam when installed on a paper machine. However, it is difficult to reliably attach the batt to a fabric woven from completely round monofilament yarns with needles. Needles pass round threads rather than pierce them. In this case, a cotton-side cotton sheet must be used to help secure the paper-side cotton sheet. Another disadvantage of press fabric base fabrics knitted from fully round monofilament yarns is that they tend to form visible marks at the junction of the warp and weft. Another disadvantage is that the contact area between the intersection points of the warp and the weft is limited to a certain point. Thus, the fabric is prone to diagonal distortion or rarity.

U.S. Patent No. 4,414,263 discloses the improvement of the properties of a base fabric and thus a press fabric by incorporating monofilament yarns having a flattened cut into the base fabric fabric. In that patent, a better press fabric is defined as "comprising an open-loop fabric woven from a plurality of synthetic yarns extending in both the transverse and longitudinal directions and at least one staple fiber knitted fabric attached thereto with needles. characterized in that at least some of the transversely extending yarns are monofilament yarns having a flat cut and having a longitudinal axis parallel to the plane of the fabric ". In U.S. Patent No. 4,414,263, these flattened monofilament yarns are incorporated into a conventional fabric weave. The same patent also recommends that the width-to-length ratio should vary between 1.2: 1 and 3: 1, with a value of 2: 1 being preferred for these flattened monofilaments.

U.S. Patents 4,815,499 and 4,142,557 disclose the use of corresponding flattened monofilament yarns in a paper machine forming fabric. Although such paper-15 machine forming fabrics may be similar on the upper sides to those used in the press section, they are completely different} due to the conditions in which they are used. For example, U.S. Patent No. 4,142,557 primarily discusses the improvement of a forming fabric 20 woven into a continuous length of flat fabric and seamed to provide the required loop, in which a four-niisatin satin bond is used as the fabric bond. To improve such a forming fabric, said patent discloses the use of flattened monofilament yarns having a width-to-height ratio of 1.2: 1 to 1.3: 1. Flat monofilament yarns have been proposed for use in dewatering fabrics to reduce air permeability (U.S. Patent No. 4,290,209) or to increase surface contact (U.S. Patent No. 4,302,621,663). It is also known to extrude such flat monofilament yarns on shaped surfaces (U.S. Patent 4,643,119).

Such monofilament yarns of the general type have been used in other woven fabrics. These fabrics have generally used a much higher width-to-height ratio, generally more than 10: 1, e.g. in carpet backing (UK patent li - 96047 5 1,362,684) and in geotextiles, strip fabrics and pulp containers (U.S. Pat. No. 4,643,119), a woven fabric in which a woven fabric is used. flat tape as both a warp and a weft for use as a plastic reinforcement (U.S. Patent No. 4,816,327) and sailcloth (U.S. Patent No. 4,590,121). Flattened monofilament yarn is also disclosed for use in a woven filter fabric for removing water from a slurry (EP 0 273 892).

10

It has also been suggested that water be removed from the paper web in the press section using a fabric to which a batt is not attached. Such a method is described in DE patent 3,426,264. However, it has been found that the drying fabric described in said 15 patents only works for thicker grades of paper.

A crucial feature of the press fabric of U.S. Patent No. 4,414,263 is the use of a flat monofilament thread in the base fabric. It has been found that corresponding flattened monofilament yarns can be used to provide a better dewatering press fabric, which improves web drying and leaves fewer marks on both the drying felt and the press roll grooves.

In addition, in other applications, the paper-side wadding required by U.S. Patent No. 4,414,263 may be omitted.

According to the present invention, flattened monofilaments, i.e., monofilament yarns, are used in high fill coefficients and fabric patterns that provide a long> yarn run on the paper side of the fabric. These properties of the drying fabrics of the present invention appear to provide the fabric with a relatively flat, smooth, nearly planar surface on the paper side of the fabric. This relatively flat surface appears to transfer the mechanical loads applied by the press rolls so that the 6 96047 press becomes more uniform. It is also believed that the improved paper web drying properties of the fabrics of the present invention and the ability to resist marks entering the paper are directly due to the uniform compression properties of these fabrics under the compression load.

Accordingly, the present invention in its broadest sense provides a woven dewatering fabric as defined above, characterized essentially in that for the majority of long free yarn strands: (iii) "a" is greater than 1; and (iv) "a" is greater than half of "bn.

The fill factor of the flattened monofilament yarns is preferably at least 60%. Even more preferably, the fill factor is at least Θ0%; at best it is about 85%.

The dewatering fabric is preferably a single layer, but the advantages of the present invention can also be achieved in multiple fabrics. The yarn ratio of the flattened monofilament yarns, calculated as described above, is preferably at least 5/8 and more preferably 3/4 to 7/8.

.25 The width-to-thickness ratio of the flattened monofilament yarn is preferably at least 1.6: 1 and most preferably at least about 2: 1.

If a staple fiber sheet facing the paper is used, it is preferred that it be fitted substantially perpendicular to the flattened monofilament yarns. It is also possible. the strip fits the batt layer on the side of the dewatering fabric facing the roll.

The compression dewatering fabric can be woven in many different ways. It can be woven into a closed endless loop of a desired length, which may include a needle seam. Alternatively, the fabric can be woven in a continuous flat length of 96047 7, from which a suitable length is sewn, e.g. with a needle seam, to obtain the desired endless loop.

The main difference between these methods is the control of monofilament weft-5 and weft yarns in a woven fabric loop: (a) in a fabric woven into a closed endless loop (with or without a seam), the monofilament warp yarns are located in the cross-machine direction and comprise flattened individual yarns of the present invention; and (b) in a fabric woven to a continuous length that is seamed to provide a closed endless loop, the monofilament warp yarns are located parallel to the machine and comprise the flattened monofilament yarns of the present invention.

There is also a known planar weave fabric in which monofilament warp yarns are flattened monofilament yarns. Special weaving and post-weaving treatments may be required to properly expose the yarn runs of the flattened monofilaments.

If the fabric is used in the press section with the needled batt sheet attached to either the paper side or the .25 side of the fabric, it is more advantageous to use a fabric woven into a closed endless loop. The endless loop may also include a needle seam.

If the fabric is used in a press section without a needled batt sheet attached thereto, as shown in the present invention, either of the weaving methods described above can be used. If the fabric is seamed to make it easier to install on a paper machine, it is preferable to use a needle seam.

Generally, press fabrics are made of nylon monofilament yarns in which the nylon staple fibers are in the form of a batt, although polyester and other materials have also been used. It is preferable to use nylon monofilament yarns and staple fibers in the present invention, but the invention is not limited to these materials.

5

The invention will now be described in more detail with reference to the accompanying figures, in which Figure 1 schematically shows a drying fabric according to the present invention; Fig. 2 shows the fabric of Fig. 1 provided with a paper side batt; Fig. 3 shows the fabric of Fig. 1 provided with a cotton sheet on each side; Figures 4a and 4b show cross-sections of typical flattened mono-15 filaments; Figures 5a-5d show alternative fabric designs for single and double ply fabrics (Figure 5d is outside the scope of the invention); Figures 6 and 7 show needle seam structures; and Figures 8a-8f show the tissue structures used in the examples (Figures 8a and 8e are outside the scope of the invention).

Figure 1 schematically shows one example of a dewatering fabric according to the present invention. 25 with the number 1. Arrow 2 indicates the cross direction of the machine and <arrow 3 indicates the direction of the machine. As shown, the fabric is made into a closed loop by endless weaving. For a fabric woven into a continuous flat length, arrows 2 and 3 change positions: 2 indicates the direction of the machine 30 and 3 indicates the cross direction of the machine. In this figure, the monolayer fabric comprises substantially parallel weft yarns 4 and substantially parallel flattened warp monofilaments, i.e. warp unit fiber yarns 5 (hereinafter the term "monofilament yarn" is used).

35 Weft yarns can be any of those commonly used in such a fabric, including monofilament yarns, twisted yarns, and braided yarns.

Il 96047 9

As shown in Figures 2 and 3, porous layers such as a needle punched fiberboard can be attached to a felt. The paper side batt is generally shown in 6A and the machine side batt is generally shown in 6B. It is preferred that the side plate of the paper fiber 6A arranged to be substantially perpendicular to the flattened yksikuitulankaloimiin 5 that is substantially parallel to the direction of the arrow 3.

According to Figures 4, which show cross-sections of a flattened filament, i.e. a fibrous yarn 5, these fibrous yarns have a width W and a thickness T. The width-to-length ratio of such a fibrous yarn is defined as the ratio W: T. The width-to-length ratio of the fiber yarn shown is 4: 1. To fulfill the purpose of the present invention, the width-to-length ratio should be greater than 2: 1, preferably in the size range of 2: 1 to 20: 1. If T is too small, the fibrous yarn becomes too thin and flexible to prevent the weft yarns 4 and the groove pattern or other pattern in the press roll from moving into the paper 20 at the nip between the rolls. Such marks on the surface of the paper are not desirable. A suitable lower value for T is about 0.1 mm.

The lowest value of the width-to-length ratio is 1: 1, i.e. a substantially-.25 ti square fiber yarn. In the fabrics of the present invention, the long bare yarn strands of the flattened monofilament yarn are intended to provide an almost flat surface to support the wet paper web. If the width-to-length ratio is made too small, it is difficult to form such a fabric with the machines currently in use, even with the high fill factors of flattened monofilament yarns used by the present invention. If the width-to-length ratio is less than 1.3: 1, the degree of twisting of the flattened monofilaments is too high. In view of this, a width-to-length ratio of 2: 1 or greater is preferred. The upper limit of the width-to-length ratio is determined by the weaving machine. The practical upper limit is about 100: 1.

96047 10

When the batt is attached with needle pins to the dewatering fabric, many of the needles are punctured by flattened monofilament yarns. While this naturally means that the perforated monofilament yarns are damaged, it does not appear to be relevant provided that the number of needle stitches is not huge. In addition, it has been found that the high filling factors used here result in the batt sheet adhering better to the dewatering fabric because fewer needles fail to hit the monofilament weft or weft-10 yarn. In addition, due at least in part to the high fill factor, split monofilament yarns tend to compress the cotton fiber fibers and hold them in place.

It is also possible, up to a certain point, to adjust the point 15 where the needles pierce the flattened monofilaments.

The monofilament yarn 1a shown in Fig. 4 (b) with a width-to-length ratio of 4: 1 has four flat surfaces 8 separated by three grooves 9 on each side. In practice, it has been found that in the case of such a monofilament yarn 20, the needles pass through the grooves 9 rather than the surfaces 8.

It was noted above that the orientation of flattened monofilament yarns is important in connection with needle seams. Because the cross-section of the wefts used is substantially circular, the needles do not penetrate much of the weft in the needle-stitching procedure: in most cases, the needle only moves the weft slightly to the side. For this reason, it is preferable to form the needle seam from the undamaged weft yarns. Because the wefts are located in the machine direction. in a closed loop woven fabric, it is more advantageous to use such a fabric when fitting a batt. Alternatively, if the batt is not to be used, it may be advantageous to form a needle seam from the flattened monofilament yarns.

and 96047

Figures 5 (a) to (d), 6 (b), 7 (b) and 8 show schematic sections of various possible dewatering fabric structures, three of which, Figures 5 (d), 8 (a) and 8 (e), later as will be explained in more detail, are outside the scope of the present invention and are shown for comparison.

Two of the properties of the dewatering fabric of the present invention are particularly important, one of which is shown in these diagrams. One is the "yarn ratio" and the other is the "fill factor".

The yarn strands ratio represents the portion of the flattened monofilament warp that provides a long, bare yarn strand 15 on the paper side of the fabric as indicated by reference numeral 10 in the figures. The yarn span ratio is shown as a "ratio" a / b, where a and b are integers, and (i) "a" represents the number of weft yarns on the paper-facing surface layer in the flattened monofilament yarn 20 simple repetitive fabric pattern located under and in contact with the warp; and (ii) "b" represents the amount of surface layer facing the paper, its total number of weft yarns on the surface of the fabric in a repeating pattern.

In addition, for such a bare yarn to meet the requirements of the present invention, the following two restrictions must be met with respect to the yarns 30: (iii) "a" is greater than 1; and (iv) "a" is greater than half of "b".

When these principles are first applied to Fig. 5, 35 the following wire run ratios are obtained for Figs. 5 (a), (b) and (d): 12 PfC47 Fig. 5 (a): a = 4, b = 5 and the wire run ratio is 4/5: four the weft group 11 is located under and in contact with the warp 12 and in the repeating pattern X there is an additional fabric 13; 5 - Fig. 5 (b): a = 5, b = 8 and the ratio of yarn runs is 5/8: only five wefts 14 below the warp 15 and three wefts 16 above the warp 15 are counted; although weft 17 is located above and seven wefts 18 are below, they are not located in the surface layer and are not counted in determining values a or b; Fig. 5 (c) shows a fabric model with varying yarn run ratios; Fig. 5 (d): a »3, b = 6 and the ratio of yarn runs is 15 3/6 and thus outside the scope of the present invention because the subsurface layer is not lowered.

Similarly, the yarn run ratios can be calculated for all other diagrams: Figure 6 (b): a = 5, b = 8: wire run ratio: 5/8; Figure 8 (a): a * 4, b = 8: yarn ratio: 4/8 (reference fabric); Fig. 8 (b): a * 6, b = 8: ratio of yarn runs: 6/8; . Figure 8 (c): a = 5, b = 6: yarn run ratio: 5/6; Fig. 8 (d): a = 7, b = 8: ratio of yarn runs: 7/8; Figure 8 (e): a = 3, b = 6: yarn ratio: 3/6 (reference fabric); Fig. 8 (f): a = 5, b = 8: ratio of yarn runs: 5/8.

30

There is no need to be constant for the yarn runs of a particular fabric, either along a particular flattened monofilament yarn or for all monofilament yarns in a particular fabric. In addition, the yarn-to-yarn ratio of all bare yarns does not have to comply with the constraints set for a: lie and b, although the maximum benefit is obtained if the yarn-to-yarn ratio of all flattened monofilament yarns complies with those restrictions. Figure 5 (c) shows a fabric with varying yarn run ratios: read from top to bottom, the yarn run ratios are: 7 / Θ, 5/8, 6/8, 1/8, 4/8, 6/8, 3/8 and 5 / 8. In a corresponding manner, it is also possible to change the length of the yarn run in the longitudinal direction of the warps, whereby, for example, 1/2 unit and then 5/6 unit are obtained in succession. In such a case, the entire length of the repetitive pattern should be used to determine the ratio of yarn strands: in the previous 10 examples, the ratio of yarn strands is 6/8. However, as the proportion of flattened monofilament warps which have small yarn ratios in both a and b or where a is close to half of b increases, the drying properties of the fabric deteriorates and the risk of the fabric leaving marks on the paper increases.

It is also possible to include warps other than flattened monofilament yarns in the dewatering fabric.

This is not recommended because the drying properties of the fabric are likely to suffer and the risk of marks on the paper increasing.

However, there is a limit to the coefficient of yarn runs, beyond which the structural integrity of the fabric changes. 25 is questionable. Given the large number of possible tissues, the boundary is difficult to determine accurately. In the case of the simple fabric shown in Figures 1 and 5 (a), this structural limitation is apparently encountered at a yarn coefficient of 9/10. A factor of 7/8 for yarn-30 runs seems to be a suitable practical limit.

The filling factor essentially indicates how much space the fabric is made up of by the yarns of which it is composed. It can be measured for both monofilament and weft yarns 35 as follows: 14 96047

N X W

fill factor% = _ x 100

D

5 wherein: (i) N represents the number of yarns at a given distance D; and (ii) W is the maximum lateral width of the wire.

10 In this diagram, N can also be a wire number.

In a yarn having a substantially circular cross-section, e.g. in the wefts used in Figure 1, W indicates the diameter of the yarn 15. For flattened monofilament yarns, W is the width of the monofilament yarn as shown in Fig. 4 (a).

Both D and W are measured in the same units. In the present invention, the fill factor of the flattened monofilament yarns should be greater than 45%, preferably at least 60%, and more preferably about 80%, with 85% being most preferred. As previously mentioned, these high filling factors are useful in retaining the batt when used.

-25 For other yarns, the number of yarns N determines the amount of support received for long bare threads. These must be sufficiently well supported to substantially prevent them from collapsing due to the pressure exerted on the drying fabric at the press-30 point. If the flattened monofilament yarns of the warp are relative. thick, have a high fill factor and a relatively low linear compression of the press roll, the number of weft yarns can be reduced. In general, it has been found that the number of yarns should be relatively high for yarns other than flattened monofilaments.

«Li 96047 15

The previously described advantages in the form of higher drying power are also achieved in needle-seamed fabrics woven in either closed loops or continuous lengths.

5

Figures 6 and 7 show typical needle seams having a somewhat conventional structure. In Figure 6a, the fabric is woven in a closed loop and the bare warp yarn runs 10 in the cross-machine direction. In Figure 7a, the fabric 10 is woven in a continuous flat length and the bare warp yarn runs 10 in the machine direction. The batt 6A is shown in Figure 6 (c) only for clarity. Fig. 6 (a) shows a front view of the fabric and Fig. 6 (b) a section along the lines I-1 and Fig. 6 (c) a section along the lines II-II in Fig. 6b. A fabric having a yarn run ratio of 5/8 comprises flattened warps 20, two fabric layers 21 and 22, a simple surface weft sheet 6A and a needle seam needle 23. The needle seam is obtained by making loops, as in 24, of weft yarns, where the weft loop may be a regular loop. bend (Fig. 6c) or a more or less complete loop (Fig. 6d). When preparing the fabric for installation on a paper machine, the needle is removed, the fabric is fed through the press section, and the loop is reclosed by fingering the loops at the end edge of the fabric 25 and reinserting the needle.

The fabric structure of Figures 7a and 7b is substantially the same.

The fabric bond of the fabric is substantially the same, including lithium-30 monofilament yarn stitchers 20, two weft layers 21 and 22, and a needle seam needle 23. For clarity, only one half of the seam is shown in Figure 7a. When creating the seam, essentially the same method is used, however, in this case it must be taken into account that the corrugated flattened single-fiber fibers form the loops of the needle seam. Thus, it is desirable to include a thread in those warps used to make the loops, as in step 25, and 96047 16 in those woven back into the ends of the fabric but not used to make the loops, as in step 26. In this way, the warp end 27 can be reinserted to form an overlapping connection to the tissue in a manner well known in the art because it is then corrugated to fit an existing tissue pattern.

The flattened monofilament yarns in both configurations provide a surface that provides excellent paper-side batt adhesion, possibly eliminating the need to use machine-side batt. This is because the flat monofilament yarns crack when a needle is inserted into them, trapping the batt fibers and anchoring them to the base fabric. Flattened monofilament yarns reduce marks on paper because the intersections of warps and wefts are not as protruding as those formed by universal monofilament yarns. The needle-seamed fabrics woven in accordance with the present invention also withstand more diagonal twist because the intersection of the flat and round single-fiber yarns has a larger contact area than the intersection between the two round yarns.

To determine the lower limits for yarn runs, comparative experiments were performed using single and double ply fabric with different yarn run ratios.

Changes in the composition of the paper as it passes through the press section are used to measure dewatering efficiency. "Composition" is defined as the percentage of dry paper solids (fibers, fillers, etc.) in the wet paper web. The usual composition that enters the compression section is 22%. The composition leaving the last compression point between the rolls of the compression part is generally between 3Θ and 41%.

For wire runs, the effect on dewatering was tested using a laboratory press and monitoring 35

II

96047 17 generally the method described by Jackson, Pin Journal. 72 (9), 103-107. This laboratory method gives a good relative indication of the performance of the press fabric. Table I shows the data of four single-ply fabrics 5 with the same nominal wadding structure and weft type, but different yarn run ratios. Table II shows the corresponding data for the two bilayer fabrics. Tissue models are shown schematically in Figure 8.

In these figures, the wefts 30 are 6-strand cable single-10 fiber yarns and the wefts 31 are multifilament yarns.

Table I

Weft: 0.2 mm / 2/3 wired monofilament; woven to a density of 1.1 to 15 mm

Warp: 0.2 x 0.4 mm without grooves; filling factor: 80%

No. Tissue Composition Composition of Tissue Figure 8 Tissue Composition 20 MA3 (a) 4/8 (0.5) 53.3% MA2 (b) 6/8 (0.75) 54.2% MA26 (C) 5 / 6 (0.83) 55.6% MA.1 (d) 7/8 (0.875) 55.9%

25 Table II

• · i <.

Weft: top layer (31): 350 tex multifilament filaments; woven

to a density of 1.1 mm lower layer (30): as in Figure I

30 Warp: 0.2 x 0.4 mm without grooves; filling factor: 80% •

No. Tissue of Figure 8- Lamani flushed Age of compression ratio ratio composition MA25 (e) 3/6 (0.50) 56.1% 35 MA15 (f) 5/8 (0.625) 56.9%

.. - I

96Q47 18

In each test group, the paper input composition was 35%. Data for lots MA3 and MA25 are presented for comparison. In either case, the ratio of the yarn strands is such that a is half of b, so that they are outside the scope of the present invention.

The results clearly show that as both a and b increase and a approaches b, dewatering improves. In the paper industry, a 1% increase in composition is generally considered significant.

It has been stated above that the woven dewatering fabric of the present invention does not necessarily need a batt-like porous structure on the paper side surface. If a batt is used, think about the direction in which it will be placed. If the dewatering fabric is an endless woven loop with flattened monofilament warps in the cross-machine direction, the wadding sheet should be positioned parallel to the machine using, e.g., the method of U.S. Patent No. 3,508,307. However, if the dewatering fabric is a flat woven fabric in which the wefts are flattened monofilament yarns, the batt sheet should preferably be positioned parallel to the machine, in which case the method of U.S. Patent No. 3,508,307 can also be used.

Claims (19)

96047 A woven dewatering fabric (1) for a press section of a paper machine, wherein the cross-machine direction (2) of the machine extends between opposite side edges of the fabric and the direction (3) of the machine 5 extends perpendicular to the cross-machine direction, the fabric weave pattern long free yarn strands in a monofilament warp yarn (5; 15; 20) having a flattened cross-section with a width-to-thickness ratio of 10 of at least 1.5: 1, the flattened monofilament yarn having a fill factor of at least 45%, wherein in the fabric weave pattern the flattened monofilament yarns a / b, where: (i) "a" means the number of weft yarns (4; 11; 14; 21; 30; 31) in one of the 15 repetitive fabric pattern yarns of the flattened monofilament yarn in the surface layer facing the paper, which weft yarns are under and in contact with the warp thereto; and 20 (ii) "b" means the total number of weft yarns (4; 11-13; 14-16; 21; 30; 3D) in the anti-paper surface layer in the same repetitive fabric pattern, characterized in that ..; 25 the majority of long free yarn runs (10) for: (iii) "a" is greater than 1, and (iv) "a" is greater than half of "b". 2. Awattningsduk enligt patentkrav 1, kannneteck-n ad av att den vda Duken antingen is an enskikdduk (fig. 1; 2; 3; 5a; 8b; 8c; 8d) or a teläskiktsduk (fig. 5b; 5c; 6a, 6b) , 6c, 6d; 7a, 7b; 8f). 5 Dewatering fabric according to claim 1, characterized in that the woven fabric is either a single-ply (Figs. 1; 2; 3; 5a; 8b; 8c; 8d) or a double-ply fabric (Figs. 5b; 5c; 6a, 6b , 6c, 6d; 7a, 7b; 8f). 3. An accessory according to claim 1 or 2, which is provided with a porous screw (6A) which abrades the dowel of the dowel, or if the dowel (6A; 6B) is abraded with a dowel of the dowel. 10 Dewatering gas according to claim 1 or 2, characterized in that the porous layer (6A) is attached to the paper side of the woven fabric or the porous layer (6A; 6B) is attached to each side of the woven fabric. 4. Awattningsduk enligt patentkrav 3, känneteck-n a d av att det porösa skiktet eller de böda porösa skikten är en vadd av stapelfiber. Dewatering fabric according to Claim 3, characterized in that the one or both porous layers are staple fiber wadding. 5. Awattningsduk enligt patentkrav 4, känneteck- n d av atten ena wadd or vardera wadden av stapelfiber är nälad till den vävda Duken. Dewatering fabric according to claim 4, characterized in that one or both of the staple fibers are attached to the woven fabric by needling. 6. Awattningsduk enligt patentkrav 5, känneteck-20 n a d av attatminstone en vadd (6A, 6B) av stapelfibrer ir vendad to be used to make the Duchen and to the wireframe or to be used in the present invention. Dewatering fabric according to Claim 5, characterized in that the at least one staple fiber batt 15 (6A, 6B) is attached to the woven fabric by needling and that the batt fibers are oriented substantially perpendicular to the flattened monofilament yarns. 7. Awning set according to claim 5, which comprises a flange and a guide (6A, 6B) in which a stapler is used to reduce the size of the plunger and a guide in parallel with the rigging of the plate. 30 Dewatering fabric according to claim 5, characterized in that the at least one staple fiber batt (6A, 6B) is attached to the woven fabric by needling and that the batt fibers are oriented substantially parallel to the flattened monofilament yarns. ; Dewatering gas according to Claim 1 or 2, characterized in that the yarn-to-yarn ratio of the woven fabric is between 5/8 and 9/10. 8. Awattningsduk enligt patentkrav l eller 2, kännn e-tecknad av att i den vävda Duken flotteringsvärdet är mellan 5/8 - 9/10. 9. Awattningsduk enligt patentkrav l eller 2, kännn e- tecknad av att i den vävda Duken flotteringsvärdet är mellan 3/4 - 7/8. 96047 Dewatering fabric according to Claim 1 or 2, characterized in that the ratio of the yarn runs of the woven fabric is between 3/4 and 7/8. 10. Awattningsduk enligt patentkrav 1 eller 2, kanne-tecknad av att fyllnadsfaktorn för de tillplattade enfiberträdarna är ätminstone 60%. Dewatering fabric according to Claim 1 or 2, characterized in that the flattening coefficient of the flattened monofilament yarns is at least 60%. II • · 96047 11. Awattningsduk enligt patentkrav l eller 2, kanne- tecknad av att fyllnadsfactorn för de tillplattade enfiberträdarna är ätminstone 85%. Dewatering fabric according to Claim 1 or 2, characterized in that the flattening coefficient of the flattened monofilament yarns is 85%. 12. An invention according to claim 1 or 2, comprising a bracket of a value for a plate (5; 15; 20) of 2: 1 to 10: 1. Dewatering fabric according to Claim 1 or 2, characterized in that the width-to-thickness ratio of the flattened monofilament yarns (5, 15, 20) is from 2: 1 to less than 10: 1. 13. Awattningsduk enligt patentkrav l eller 2, känn e e-15 tecknad av att den vövda Duken är en sluten ändlös slinga, i vilken de länga exponerade flotteringarna (10) av tillplattade enfibervarpträdar är orienterade i tvär-maskinr. Dewatering fabric according to Claim 1 or 2, characterized in that the woven fabric is a closed endless loop in which the long free threads of flattened monofilament warps are directed in the cross-machine direction (2). 15 14. Awattningsduk enligt patentkrav 1 eller 2, känn e e- tecknad avatt den vävda Duken är en kontinuerlig bana i vilken de länga exponerade flotteringarna av tillplattade enfibervarpträdar är maskinrikt-ningen (3). 25 • · Dewatering fabric according to Claim 1 or 2, characterized in that the woven fabric is a continuous web in which the long free yarn runs of the flattened monofilament warps are directed in the machine direction (3). 20 15. Awattningsduk enligt patentkrav 13 or 14, kän n-netecknad av att den includerar en nälsöm (23). Dewatering fabric according to Claim 13 or 14, characterized in that it comprises a needle seam (23). 16. Awattningsduk enligt patentkrav 1 eller 2, känn e e-30 tecknad av att ett flertal av de exponerade trddar-; * na head dukens papperssida utgöres av tillplattade enfiberträdar (5; 15; 20). Dewatering can according to claim 1 or 2. gas, characterized in that most of the free yarns on the paper side of the fabric are flattened monofilament yarns (5; 15; 20). 17. Awattningsduk enligt patentkrav 1 eller 2, känn e e-35 tecknad av att samtliga exponerade trädar pd dukens papperssida är tillplattade enfiberträdar. «96047 Dewatering fabric according to Claim 1 or 2, characterized in that all the free yarns on the paper side of the fabric are flattened monofilament yarns. 18. Awattningsduk enligt patentkrav l eller 2, kanne-tecknad av att läsga exponerade flotteringar (10) host tillplattade enfibervarpträdar (5; 15; 20) hartt flotteringvärde vid vilket "a" är större 5 än 1 och "a" större än halva "b". Dewatering fabric according to Claim 1 or 2, characterized in that substantially all *. the long spools (10) of flattened monofilament warps (5; 15; 20) have a yarn run ratio where a is greater than 1 and a is greater than half of b. Dewatering fabric according to Claim 1 or 2, characterized in that the ratio of yarn runs is not constant. 10 1. Awning aids (1) account for press parties with a paper mask, a lightning rod for the manufacture of paints (2) with the aid of a paper machine and a machine tool (3) with the aid of a paper dresser -15 ponerade flotteringar (10) pä papperssidan av Duken av enfibervarpträd (5; 15; 20) med tillplattat tvärsnitt med ett bredd-tjockleksförhällande pä ätminstone 1,5: 1, vilken enfibervarpträd har en fyllnadsfaktor förden tillplatt the color is reduced to 20 by the exponent of the flotation device in the form of a flotation device having the form of a / b, and the following: ; 21; 30; 31) i and 25 own monographs and that up to the envelope of the envelope, the bushings of which are in contact with the shaft; (ii) "b" is a total solution and a paperside having the same effect (4; 11-13; 14-16; 30 21; 30; 31) in the preparation; kännetecknad av att för ett flertal av de länga exponerade flotteringarna (10); (iii) "a" is paragraph 1; and 35 (iv) "a" is replaced by "b". 96047 19. Awattningsduk enligt patentkrav l eller 2, kanne-tecknad av att flotteringsvärdet icke är constant. Ill