The present invention concerns a paper machine clothing comprising a substrate with an upper side, a lower side, two lateral edges and an usable region between the two lateral edges, wherein the usable region comprises a plurality of through-channels extending through the substrate and connecting the upper side with the lower side, wherein the through-channels are non-cylindrical with a cross sectional area becoming smaller when going in a thickness direction of the substrate from the upper side to a middle region of the substrate between the upper side and the lower side. Another aspect of the present invention concerns a method of producing such a paper machine clothing.
In the sense of the present invention the term “paper machine clothing”, abbreviated “PMC”, refers to any kind of a rotating clothing used to transport a nascent or already formed fiber web in a machine that is designed to continuously produce and/or finish a fiber web, such as paper, tissue or board material. For historical reasons, PMC is sometimes also called wire, felt or fabric. In particular, PMC can be a forming wire or a dryer fabric or a press felt, depending upon its intended use in the corresponding machine. Furthermore, in the sense of the present invention the term PMC may also refer to any kind of clothing used in wet and/or dry production of fibrous nonwovens.
The term “substrate” in the sense of the present invention refers to some kind of foil material made of plastic. The substrate itself is usually impermeable to water, so that through-channels are needed to obtain a desired permeability, e.g. for dewatering the nascent fiber web or further drying the already formed fiber web. The substrate can be formed monolithic or comprise several layers that might be co-extruded or produced separately and laminated together afterwards. After joining the longitudinal ends of the substrate to each other, e.g. by laser welding, to obtain some kind of an endless belt, the perforated substrate may already represent the final product, for example a forming wire. For other applications, further steps might be necessary to produce the final PMC, such as permanently attaching fibers thereto to form a press felt. Furthermore, the substrate may comprise a reinforcing structure, such as yarns, that may be imbedded therein. After joining the longitudinal ends of the substrate to each other, the “upper side” of the substrate shall be the radially outer side, sometimes also referred to as “paper side”, whereas the “lower side” of the substrate shall be the radially inner side, sometimes also referred to as “machine side”. The substrate is preferably laser-drilled to provide the through-channels.
The idea of producing a PMC from a substrate that is perforated, especially by using a laser, is already known for quite a long time in the prior art and described e.g. in the 1980's and 1990's in the documents U.S. Pat. Nos. 4,541,895A and 5,837,102, respectively, the content of which is hereby incorporated by reference.
In the sense of the present invention the term “usable region” refers to a region of the PMC that is actually used for the production and/or finishing of the fiber web. The usable region may span the complete width of the PMC, i.e. may reach from one lateral edge to the other lateral edge thereof. Alternatively, the usable region may refer only to a region that is located between the two lateral edges and is spaced apart from the two lateral edges. In the latter case, the PMC may have another configuration, such as permeability and thickness, outside the usable region compared to the usable region.
The term “cross sectional area” of a through-channel in the sense of the present invention refers to an area of the through-channel that is obtained by cutting the through-channel with a plane that is perpendicular to the thickness direction of the substrate.
The term “non-cylindrical” in the sense of the present invention means that there are at least two different cross sectional areas of a through-channel. For example, in the case of a non-cylindrical through channel that is substantially conical, a cross sectional area taken at a first plane perpendicular to the thickness direction of the substrate may be substantially circular having a first radius, whereas another cross sectional area taken at a second plane perpendicular to the thickness direction of the substrate may be also substantially circular but having a second radius that differs from the first radius.
A paper machine clothing according to the preamble part of claim 1 is known for example from the disclosure of documents U.S. Pat. No. 4,446,187 A and DE 10 2010 040 089 A1, the content of which is hereby incorporated by reference.
Fiber retention, permeability and the degree of marking are characteristic parameters of a PMC that are important in view of the quality of the fiber web that is to be produced and/or finished on the PMC. With the paper machine clothing known from the prior art there is still room for improvement.
Thus, it is an object of the present invention to provide a paper machine clothing with improved characteristics compared to the known paper machine clothing, thereby allowing to produce a fiber web of very high quality.
This object is achieved by a paper machine clothing according to the features of independent claim 1, as well as by a method of producing the same according to the features of independent claim 13. Advantageous embodiments are the subject-matter of the dependent claims.
Thus, according to the invention, a paper machine clothing as initially described and as recited in the preamble part of claim 1 is provided wherein a shape of the cross sectional area of at least one through-channel, preferably of all through-channels, of the plurality of through-channels changes when going in the thickness direction of the substrate from the upper side to the lower side.
That the shape of the cross sectional area changes does not mean that the same shape, e.g. circular, is just scaled in size but means that the shape itself changes, e.g. from elliptical to circular. For example, the through-channels of the prior art embodiments shown in
Advantageously, the shape of the cross sectional area is substantially more elliptical in an upper region of the through-channel than in a lower region of the through-channel. In mathematics, an ellipse is a curve in a plane surrounding two focal points such that the sum of the distances to the two focal points is constant for every point on the curve. As such, it is a generalization of a circle, which is a special type of an ellipse having both focal points at the same location. The shape of an ellipse (how “elongated” it is) is represented by its eccentricity, which for an ellipse can be any number from 0 (the limiting case of a circle) to arbitrarily close to but less than 1. Consequently, “the cross sectional area being substantially more elliptical in an upper region of the through-channel than in a lower region of the through-channel” means that the shape of the cross sectional area changes as the eccentricity of the substantially elliptically shaped cross sectional area in the upper region of the through-channel is larger than the eccentricity of the substantially elliptically shaped cross sectional area in the lower region of the through-channel, wherein the latter one might be even 0 (corresponding to a circle). Thereby, the value of the eccentricity may diminish continuously in thickness direction.
Of course, the terms “elliptical” and “circular” when used in view of the cross sectional areas of the through-channels must not be understood in a strict mathematical way but some deviations, e.g. due to manufacturing tolerances, are allowed. Therefore, the term “elliptical” may be rather understood as “oval” as also described in previously mentioned prior art documents WO 91/02642 A1 and WO 2010/088283 A1.
In view of the through-channels 30′ described with respect to
According to the present invention it is possible to impart anisotropic properties to the substrate in a beneficial way. For example, it is proposed that the shape of the cross sectional area in the upper region of the through-channel has a first dimension extending in cross-machine direction and a second dimension extending in machine direction, wherein the first dimension is smaller than the second dimension. Thus, the “first direction” can correspond to the minor axis of a substantially elliptical shaped cross sectional area, whereas the “second direction” can correspond to the major axis of the substantially elliptical shaped cross sectional area. With such a configuration of the through-channels the substrate, and thus the final paper machine clothing, can stand higher stress in the machine direction compared to the cross machine direction, wherein stresses that act on the paper machine clothing are usually in fact much higher in the machine direction than in the cross machine direction. As it is clear to those skilled in the art, the term “machine direction” refers to the longitudinal direction of the PMC, i.e. the direction of transportation of the fiber web or the fibrous nonwoven when the PMC is installed in a corresponding machine, whereas the term “cross machine direction” refers to a direction within the plane of the PMC that is perpendicular to the machine direction.
In an alternative embodiment it is proposed that the shape of the cross sectional area in the upper region of the through-channel has a first dimension extending in cross-machine direction and a second dimension extending in machine direction, wherein the first dimension is larger than the second dimension. Thus, the “first direction” can correspond to the major axis of a substantially elliptical shaped cross sectional area, whereas the “second direction” can correspond to the minor axis of the substantially elliptical shaped cross sectional area. Such a form of the through-channels is particularly beneficial if the fiber retention on the paper machine clothing, in particular a forming fabric, shall be enhanced.
The first dimension and the second dimension preferably differ from each other by at least 5%, more preferably by at least 10%, and even more preferably by at least 15%, of the respective smaller dimension.
Preferably, on the lower side of the substrate the shape of the cross sectional area is substantially circular.
Preferably an upper rim of at least one of the plurality of through-channels directly contacts an upper rim of at least one other neighboring through-channel of the plurality of through-channels. More preferably this applies substantially to all through-channels and to all their neighboring through-channels formed within the usable region of the substrate. In the sense of the present invention the term “neighboring” could be replaced by the term “adjacent”, meaning that there is no other through-channel placed between two neighboring or adjacent through-channels. Furthermore, in the sense of the present invention the term “upper rim” of a through-channel refers to the rim of the through-channel on the upper side of the substrate. The rim itself may be defined as a closed line where the sidewall of the through-channel ends. In view of the previously described examples of the prior art, the upper rim can be easily identified, always being completely surrounded by the first surface 22′. To be more specific, in these examples, the upper rim is always a circular line lying within the plane of the first surface 22′ of the substrate 20′. In contrast, according to the present invention, the upper rim of a through-channel may not lie within a plane. This is particularly true when two neighboring through-channels partially “intersect” or “overlap” each other on the upper side of the substrate. The upper rim may then partially be surrounded or defined by portions of the still existing first surface of the substrate and partially by the sidewall of at least one neighboring through-channel. In an alternative embodiment of the present invention, the upper rim of a through-channel may be even completely surrounded or defined by the respective upper rims of the neighboring through-channels. In the latter case, the original first surface of the substrate, i.e. the surface that was substantially plane and parallel to the second surface of the substrate before the perforation of the substrate, may have been completely lost in the usable region of the substrate. The topography of the substrate after the perforation process may somehow resemble the topography of an egg box.
In the known prior art, the through-channels are always formed as discrete holes being clearly spaced apart from one another with the respective upper rims of the through-channels being fully surrounded or defined by the first surface of the substrate. Such a configuration was believed mandatory to maintain the required structural integrity of the substrate.
It is the merit of the inventors to have overcome this prejudice of the prior art by decreasing the distance of non-cylindrical through-channels to such an extent that the neighboring through-channels “overlap” each other on the upper side of the substrate. It was surprisingly found out that it is possible to do so without reducing the structural integrity of the substrate in an undue manner. With the present invention it is thus possible to increase the open area of the upper side of the substrate. It is a further merit of the inventors to have found out that by doing so the quality of the fiber web to be produced and/or finished on the PMC can be significantly improved.
In a preferred embodiment of the present invention at least 90%, preferably all, of the through-channels in the usable region of the substrate have an upper rim that directly contacts an upper rim of at least one other neighboring through-channel, preferably of all other neighboring through-channels, of the plurality of through-channels in the usable region of the substrate.
Furthermore, it is advantageous if less than 20%, preferably less than 10%, and more preferably less than 5%, of a surface on the upper side of the substrate is flat and substantially orthogonal to the thickness direction of the substrate. In other words, it is preferred if hardly any portion of the original first surface of the substrate, that was existing before the perforation process, is left after the perforation process.
In contrast to the first surface, with respect to the second surface of the substrate, it is advantageous, if between 70% and 90%, preferably between 75% and 85%, and more preferably about 80%, of a surface on the lower side of the substrate is flat and substantially orthogonal to the thickness direction of the substrate. Such a result can be achieved if the cross sectional area of the through-channels is smaller on the lower side of the substrate compared to the upper side of the substrate. For example, the through-channels may be substantially funnel-shaped tapering to the lower side of the substrate.
According to one embodiment of the present invention, the cross sectional area of at least one through-channel, preferably of all through-channels, of the plurality of through-channels in the usable region of the substrate may continuously decreases when going in the thickness direction of the substrate from the upper side to the lower side of the substrate.
According to an alternative embodiment of the present invention, the cross sectional area of at least one through-channel, preferably of all through-channels, of the plurality of through-channels in the usable region of the substrate continuously increases again when going in the thickness direction of the substrate from the middle region of the substrate between the upper side and the lower side to the lower side of the substrate. With such a configuration, the respective through-channel resembles the through-channel shown in
It is also possible to have in the same substrate a mixture of through-channels according to the two previously described embodiments.
In order to increase the density of through-channels in the usable region of the substrate, and thus, to enhance the dewatering capability of the paper machine clothing, it is suggested that at least 90% of all through-channels in the usable region of the substrate are arranged in a non-checkered pattern. Arranging the through-channels in a checkered pattern would mean that the through-channels are evenly distributed in the usable region of the PMC like the fields of a classic chess-board. In contrast to this, arranging the through-channels in a non-checkered pattern means that the through-channels are distributed differently.
According to another aspect, the present invention also refers to a method of producing the paper machine clothing as previously described comprising the following steps: providing a substrate having a first surface and a second surface, wherein the first surface and the second surface are preferably planar and parallel to each other; and forming a plurality of non-cylindrical through holes into a usable region of the substrate, wherein the plurality of through holes is formed into the substrate by using a laser and wherein preferably cold air is blown onto the substrate during the step of forming the through holes into the substrate. The cold air inhibits overheating and damaging of the substrate material, which is particularly important for the material region between two neighboring through holes when the laser is advancing form the first of the two through holes to the second one.
Preferably, at least some, more preferably all, of the plurality of through holes that are neighboring each other are formed at such a close distance that they partially overlap each other.
The term “through hole” in the sense of the present invention refers to the form of a hole that is formed in the substrate neglecting the neighboring through holes that may partially overlap. In contrast, the term “through-channel” refers to the geometric form of the channels in the finally drilled substrate. Due to the fact that neighboring through holes may overlap each other according to the present invention, its form, especially in view of its upper rim, can differ from the form of the through-channels.
According to one embodiment of the present invention it is proposed that, when all the through holes have been formed into the usable region of the substrate, at least one of the first surface and the second surface in the usable region has disappeared by at least 90%, preferably by 100%. As result the finally drilled substrate has none or hardly any opposite surface portions that are planar and parallel to each other. Preferably the substrate, before it is perforated, has a caliper in its usable region between 0.5 mm and 1.5 mm and even more preferable between 0.8 mm and 1.2 mm. After perforating the substrate in its usable region, the caliper thereof may be different. In some embodiments the caliper of the perforated substrate may be smaller compared to the substrate before perforation. This may be particularly true when at least one of the first surface and the second surface in the usable region has completely disappeared. However, in other embodiments, the caliper of the perforated substrate may be even greater compared to the substrate before perforation. This can happen if part of the material that is evaporated e.g. by means of a laser condensates again, thereby forming some kind of hills or ridges. Anyway, as previously mentioned, the topography of the substrate after the perforation process may somehow resemble the topography of an egg box.
In the following, the invention will be explained with respect to some schematic drawings that are not true to scale, wherein:
G-G in
A single through hole 31 of a first type not forming part of the present invention is provided in the center of the section of the substrate 20.
The through hole 31 has a circular upper rim 34 where a side wall of the through hole 31 ends and the flat first surface 22 begins. The circular upper rim 34 has a diameter A, as shown in
A single through hole 32 of a second type according to the present invention is provided in the center of the section of the substrate 20.
Thus, the through hole 32 has an elliptical upper rim 35 where a side wall of the through hole 32 ends and the flat first surface 22 begins. The elliptical upper rim 35 has a first diameter A and a second diameter B measured orthogonally thereto, as indicated in
According to an advantageous embodiment of the present invention, several of such non-cylindrical through holes are arranged in such a close relationship that they partially overlap each other in the substrate. Examples of such arrangements for the through holes 31 of the first type and the through holes 32 of the second type are shown in
In
These anisotropic properties can be used in a beneficial way. For example, the substrate that is perforated in a way as shown in
Finally,
In contrast, in the examples shown in
Number | Date | Country | Kind |
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18168641.1 | Apr 2018 | EP | regional |
18180071.5 | Jun 2018 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/059753 | 4/16/2019 | WO | 00 |