The invention relates to a sheet forming screen made of a multi-layer fabric as it is used in the process of papermaking in the sheet forming section of a wet end of a paper machine for draining a fiber suspension.
A main process in papermaking is the forming of the sheet (=sheet forming) which is effected by draining a fiber suspension by means of filtration in the sheet forming section of the wet end of a paper machine by using a so-called sheet forming screen or paper machine screen.
In this respect, the fiber suspension is a mixture of wood or cellulose fibers, fillers and auxiliary chemical agents suspended in water.
In order to be able to produce a paper sheet as uniform as possible, it is necessary to increase or set the amount of water within the fiber suspension immediately before the sheet formation to approximately 99%. This ensures that the fibers can be distributed uniformly in the water, which is beneficial to the quality of the sheet to be formed.
The amount of water is reduced to approximately 80% by the above-mentioned filtration process within the sheet forming section, i.e. during the sheet forming process. The paper fibers and the fillers and auxiliary agents remain on the papermaking screen in a uniformly distributed manner in the form of a nonwoven fabric.
While in the past the draining process took place mainly by means of a paper machine screen applied to a Fourdrinier paper machine, mainly twin wire paper machines are being used these days, for example in the form of so-called gap formers. These twin wire paper machines are characterized in that the fiber suspension is sprayed into a gap which is formed between two paper machine screens, so that draining can take place simultaneously through both screens, whereby it is possible to significantly accelerate the filtration process and thus also the production rate of the papermaking machine. There are papermaking machines these days for types of paper having a low surface weight, which are capable of producing with speeds of more than 2,000 m/min.
These extreme requirements for the paper to be produced and the conditions existing in the papermaking machine require sheet forming screens which are designed especially for this purpose and which offer high fiber support, high openness and a high mechanical stability at the same time. In addition, a low tendency to marking of the fabric, i.e. a high uniformity of the paper forming screen is necessary especially for the domain of graphic papers.
Multi-layer paper machine screens have proven of value for these fields of application over the past years, comprising two sides formed in a different manner, which are adapted to the particular purpose of use. Screens of this type have a paper side which is formed by the upper side of an upper tissue. In habitual language use, the paper side is also referred to as the upper side of the screen, and is relevant for forming the paper sheet. In addition, these screens have a machine side which is formed by the lower side of a lower fabric. The machine side which can also be referred to as the lower side of the screen contacts the members of the papermaking machine. The respective screen side has a machine direction and a cross direction. In this respect, machine direction (also MD for “machine direction”) refers to the running direction of the paper web and therefore also to the running direction of the paper machine screen, and the cross direction (also CMD for “cross machine direction”), sometimes also referred to as cross machine direction, is the direction turned by 90° in the plane of the paper machine screen, i.e. the direction located transverse to the running direction of the paper and the screen.
Due to the very specific configuration of modern paper machine screens, usually neither the paper and machine side nor the machine and cross direction are interchangeable, as otherwise the mode of operation of the screen would not be ensured or would not be ensured sufficiently. For example, the machine direction threads (=longitudinal threads) on the machine side which realize movement/circulation of the screen, can be protected against wear by transverse threads projecting or protruding significantly. Providing a balanced relationship of longitudinal and transverse threads on the paper side can ensure a good depositing possibility for the paper fibers. With respect to the fiber support, but also with respect to the tendency to marking of the screen, the most simple and at the same time the oldest basic weave of textile engineering has proven of value for the upper fabric and thus for the paper side, namely the so-called plain weave. In this kind of weave, the repeat (=the smallest repeating unit of the weave) of which is formed exactly by two warp threads (as a general rule, the longitudinal threads/machine direction threads of the screen are formed by the warp threads) and two weft threads (as a general rule, the transverse threads of the screen are formed by the weft threads), the threads are connected to a fabric in a particularly intimate and uniform manner. Although the plain weave is very well suited for forming a paper sheet and is hence very well suited for the paper side, it is usually not suited very well for the machine side. If a paper machine screen is provided with a plain weave paper side, it can therefore be advisable to provide for a second fiber layer underneath the plain weave, forming the machine side of the screen, which gives the screen sufficient stability and wearing potential.
In this respect, the connection of the two layers (i.e. of the upper fabric forming the paper side and the lower fabric forming the machine side) is a particular challenge, amongst others due to the fact that the plain weave favorable for the paper side involves particularly unfavorable preconditions for such a layer connection.
The state of the art describes different approaches for connecting two screen fabric layers, one approach of which describes the use of additional, separate binder threads extending in a longitudinal direction or a transverse direction. According to this approach, two finished and completed fabric layers are connected to each other by separate, fabric-external binder threads, which binder threads do not contribute to/are not required for establishing the corresponding fabric layer weave. Both fabric layers consist of longitudinal threads and transverse threads which extend exclusively in the respective fabric layer and thereby generate the respective fabric layer pattern and/or the respective fabric layer weave completely. This approach is, for example, described in CA 1 115 177 A1, where separate binder weft threads are used which bind with warp threads of the upper fabric and warp threads of the lower fabric, and in DE 39 28 484 A1 in which separate warp threads are used as binder threads. Other examples can be found in DE 42 29 828 A1, WO 93/00472, and EP 0 136 284 A2. The separate binder threads are usually configured to be thinner than the threads forming the respective fabric layer (cf., for example, CA 1 115 177 A1), as the binder threads must be incorporated in the fabric structure in addition to the fabric forming threads. In this respect, little space is provided for such separate binder threads especially in a plain weave. Otherwise, the binder threads would interfere with the originally homogeneous structure of the weave, so that imperfections which cause markings in the paper would be produced especially in the plain weave provided on the paper side. However, practice has shown that the thin binder threads wear out and break rather fast especially in paper machines which process a high amount of abrasive fillers or the construction of which puts a heavy strain on the screens with bending in the machine direction, so that the two fabric layers are first displaced and then separated as a result thereof. It goes without saying that it is impossible to make high quality paper by means of a fabric/screen changed in such a manner.
As an alternative, at least two transverse threads can be used which interact as a so-called functional transverse thread pair. Either one or both of the transverse threads of a functional pair extend alternately in the upper fabric and the lower fabric. In this respect, both transverse threads of a functional pair can form a virtually uninterrupted transverse thread of a paper side plain weave, i.e. an upper interconnected transverse thread. Those thread portions of the functional pair which are currently not required for forming the virtually uninterrupted transverse thread on the paper side extend in the interior the fabric and can be used for binding the lower fabric to the upper fabric. In this respect, the thread portion binding the lower fabric can, for example, complete the lower fabric or its weave at the same time. For example, an upper transverse thread may be provided between two functional transverse thread pairs, which completes exclusively the plain weave (i.e. which extends only in the upper fabric), but has no binding function. Exemplary embodiments of this approach can be found, for example, in EP 0 097 966 A2, EP 794 283 A1, WO 99/06630 A1, WO 99/06632 A1, and WO 02/14601 A1. It is an advantage of this solution that the binder threads and the transverse threads forming the upper fabric can have the same diameter, whereby uniformity of the paper side can be increased. In addition, material usage can be limited. On the other hand, the binding strength is reduced. Moreover, this approach has not been able to avoid interior wear and layer separation connected therewith in a sufficient manner. Deflection of the screen to rollers and draining members in the paper machine leads to a bending of the screen in a longitudinal direction. In this respect, always one of the two fabric layers is compressed, whereas the other one is expanded. Friction occurs at the inner sides of the two individual layers, which leads to internal wear. Besides, the binder threads oriented in a transverse direction are slightly moved in the fabric, which leads to friction and therefore wear also between the binder threads oriented in a transverse direction and the threads incorporated exclusively in one layer.
Another alternative may be a connection of the layers by so-called functional longitudinal thread pairs. If both fabric layers are penetrated by threads extending in the main bending direction, the differences in length are balanced at very short intervals. The possibility of an internal relative movement is reduced to a degree that is not relevant anymore in practice. In this context, the solutions described in DE 100 30 650 C1 and in US 2007/0 157 988 have shown in practice that the binding of a machine side to a paper side plain weave by means of functional longitudinal thread pairs described therein does not lead to layer separation anymore. Due to the long float of the machine side cross direction threads, the number and distribution of the so-called warp change locations and the distribution of paper to machine side machine direction threads, these fabrics meet their limits with respect to markings in the paper, water content in the fabric and fiber support, and can hardly be used for light-weight graphic papers.
EP 0 069 101 and EP 093 096 also show a layer connection by means of functional longitudinal thread pairs.
EP 1 767 692 A2 discloses a multi-layer fabric, wherein a paper side plain weave is bound to a machine side 4-shaft weave. In the upper fabric, an upper longitudinal thread extending exclusively in the upper fabric and a functional pair of longitudinal threads are provided alternately. The respective upper longitudinal thread extends above two lower longitudinal threads arranged in pairs next to each other, which extend exclusively in the lower fabric. The respective functional longitudinal thread pair forms, on the one hand, an upper composite longitudinal thread in the upper fabric, and, on the other hand, binds the lower fabric to the left-hand side and to the right-hand side of a lower longitudinal thread which is arranged underneath the upper composite longitudinal thread and extends exclusively in the lower fabric. The lower fabric entirely consists of lower transverse threads and lower longitudinal threads and is bound only to the upper fabric by the thread portion of the functional longitudinal thread pairs meanwhile extending in the lower fabric (the binding thread portion acting as a separate, fabric-external binder thread). The fabric has a longitudinal thread repeat of eighteen longitudinal threads, three of which are formed as upper longitudinal threads and nine of which are formed as lower longitudinal threads, the remaining six longitudinal threads forming three functional pairs. Depending on the definition (see below), a longitudinal thread ratio of 2:3 (6:9) or 1:2 (6:12) is obtained (if one considers the lower longitudinal threads arranged in pairs next to each other as respectively one lower longitudinal thread, a ratio of 1:1 (6:6) or 2:3 (6:9) is obtained).
Similar approaches are described in WO 2004/085740 A2 and in WO 2004/085741 A1, wherein WO 2004/085740 A2 shows a fabric having a longitudinal thread repeat of 20 threads which are distributed into four upper longitudinal threads, four functional pairs and eight lower longitudinal threads. The fabric shown in WO 2004/085741 A1 has a longitudinal thread repeat of 16 threads which are distributed into four upper longitudinal threads, four functional pairs and four lower longitudinal threads, so that a longitudinal thread ratio of 2:1 (8:4) or 1:1 (8:8) is obtained. In both fabrics, the lower fabric is bound only to the upper fabric by thread portions of the functional pairs, i.e. the lower fabric is formed entirely and finally by lower longitudinal threads and lower transverse threads.
EP 1 826 316 A2 describes a fabric having a longitudinal thread repeat of four upper longitudinal threads, twelve lower longitudinal threads and four functional pairs (i.e. a longitudinal thread repeat of 24 threads). The upper warps and the functional pairs form a paper side plain weave which is bound to a complete lower side by means of the functional pairs. At least three different warp systems are required for making the fabric. The upper longitudinal threads and the functional pairs are arranged alternately, which leads to the paper side weave pattern overlying with the two different upper warp systems.
EP 1 527 229 B1 and EP 1 220 964 B1 each disclose a triplet warp thread composed of three warp threads, the warp threads of which respectively extend in the upper fabric and in the lower fabric.
The problem of the invention is to provide a sheet forming screen made of a multi-layer fabric, which is easy to produce and meets the requirements described above, i.e., for example, a high fiber support, a high mechanical stability, a low tendency to marking and a stable layer connection.
To solve this problem, the invention provides a sheet forming screen according to claim 1. Further embodiments of the screen according to the invention are described in the dependent claims.
According to the invention, the sheet forming screen is formed of a multi-layer fabric having a longitudinal thread repeat of sixteen longitudinal threads, four longitudinal threads of which are formed as upper longitudinal threads and eight longitudinal threads of which are formed as lower longitudinal threads. The remaining four longitudinal threads form two functional longitudinal thread pairs of respectively two longitudinal threads arranged next to each other.
According to a first embodiment of the invention, each of the four longitudinal threads forming the two functional longitudinal thread pairs extends both in the upper fabric layer and in the lower fabric layer, whereby the upper fabric layer is connected firmly to the lower fabric layer.
According to the first embodiment of the invention, the upper longitudinal threads partially form the weave of the upper fabric layer (this is, for example, the paper side weave) together with transverse threads extending in the upper fabric layer, the eight lower longitudinal threads partially form the weave of the lower fabric layer (this is, for example the machine side weave) together with transverse threads extending in the lower fabric layer, and the two functional longitudinal thread pairs formed by the remaining four longitudinal threads complete both the weave of the upper fabric layer and the weave of the lower fabric layer. In this respect, the longitudinal threads of the two functional pairs form two upper composite longitudinal threads and two lower composite longitudinal threads which insert in the corresponding weave pattern.
According to a second embodiment of the invention, at least one of the four longitudinal threads forming the two functional longitudinal thread pairs extends both in the upper fabric layer and in the lower fabric layer, whereby the upper fabric layer is connected to the lower fabric layer. The longitudinal threads of the two longitudinal thread pairs which do not extend in both fabric layers extend alternately in the upper layer and between the two layers, i.e. alternately in the upper layer and in the interior of the fabric. Preferably, all four longitudinal threads forming the two functional longitudinal thread pairs extend in the second embodiment of the invention as well both in the upper fabric layer and in the lower fabric layer, so that a reliable connection of the fabric layers is ensured.
According to the second embodiment of the invention, the upper longitudinal threads partially form the weave of the upper fabric layer (this is, for example, the paper side weave) together with transverse threads extending in the upper fabric layer, and the eight lower longitudinal threads already form the complete weave of the lower fabric layer (this is, for example, the machine side weave) together with transverse threads extending in the lower fabric layer. The two longitudinal threads of each longitudinal thread pair alternately complete the weave of the upper fabric layer. Thus, the longitudinal threads of the two functional pairs form two upper composite longitudinal threads which complete the weave of the upper fabric layer. In addition, the at least one longitudinal thread extending both in the lower and in the upper fabric layer binds the lower fabric layer completely formed by the lower longitudinal threads to the upper fabric layer, acting as a separate binder thread. If both longitudinal threads of a functional pair extend both in the upper fabric layer and in the lower fabric layer, the two longitudinal threads of a longitudinal thread pair alternately complete the first weave and, in addition, alternately bind the lower fabric layer completely formed by the lower longitudinal threads to the upper fabric layer. This means, in the latter case, that the thread portions of a functional pair which are currently not used for forming the upper composite longitudinal thread integrate at least a transverse thread extending in the lower fabric and acting as a separate binder thread, in order to thereby connect the lower fabric layer to the upper fabric layer. This has the advantage of an increased number of binding points and hence of a stronger layer connection. In addition, both threads of a functional pair have the same thread length in the latter case, which leads to a uniform interlace.
According to the invention, the connection of the upper layer to the lower layer is thus realized (at least in part) by functional longitudinal thread pairs which brings about the above-described advantages in comparison with a layer connection by means of separate connection threads or by means of functional transverse thread pairs. However, the invention should also include, for example, screens of a type where, for example, separate connecting threads are provided in addition to the functional longitudinal thread pairs.
Due to the fact that the fabric has a longitudinal thread repeat of 16 longitudinal threads and due to the claimed distribution of the sixteen longitudinal threads into four upper longitudinal threads, eight lower longitudinal threads and two functional pairs, the paper forming screen according to the invention can be produced by means of a weaving machine provided with a shaft package of sixteen shafts and two warp beams (if the longitudinal threads are formed by warp threads). In this respect, the sixteen longitudinal threads can be separated into two warp beam units of eight threads each, the first unit comprising the eight lower longitudinal threads of the respective repeat and the second unit comprising the remaining eight longitudinal threads of the respective repeat. A weaving machine equipped with sixteen shafts and two warp beams is required for the production of a plurality of other fabrics/screens, so that the screen according to the invention can be produced without any problems by means of an existing weaving machine. This means that it is not required to use a separate weaving machine or to rebuild an existing weaving machine (for example, by adding or by withdrawing shafts) for producing the screen according to the invention. The screen according to the invention can rather be produced during production breaks of another 16-shaft screen without a prior rebuilding of the machine being necessary.
The claimed distribution/allocation of the sixteen longitudinal threads results in a ratio of upper longitudinal threads to lower longitudinal threads of 4:8 or 1:2. For the first embodiment of the screen according to the invention, respectively two of the four longitudinal threads of the two functional pairs can be assigned to the lower and upper fabric layer, respectively, as these four longitudinal threads contribute to the formation of fabric in both layers and respectively form two composite longitudinal threads, so that a total longitudinal thread ratio of 6:10 or 3:5 is obtained. If in the second embodiment of the screen according to the invention only the two upper composite longitudinal threads are taken into consideration when calculating the longitudinal thread ratio, a longitudinal thread ratio of 6:8 or 3:4 is obtained. If the four longitudinal threads are distributed evenly to the upper fabric and to the lower fabric (although the at least one longitudinal thread in the lower fabric layer only acts as a separate binder thread), a ratio of 6:10 or 3:5 is obtained, just like in the first embodiment. The described longitudinal thread ratio of 3:5 or 3:4 and the reduced longitudinal thread number in the upper fabric layer involved, which usually forms the paper side, favors the formation of paper side cross meshes, the extension of which is greater in a screen cross direction than in a screen longitudinal direction. Such cross meshes enable a high fiber support, as the paper fibers are oriented mainly in a machine direction due to the paper machine's operation and the flow conditions in the head box thereof. This means that the screen surface has a higher fiber support ability with a constant total thread number and a comparable permeability and a comparable design. Hence, a paper side of the screen oriented in a rather transverse manner provides an improved fiber support. The comparatively large number of lower longitudinal threads balances a paper side reduction in strength and an increase in screen expansion in a machine direction going along with the formation of cross meshes, i.e. the reduction in strength and the increase in expansion of the screen in the critical machine direction caused by a reduction of paper side longitudinal threads can be compensated by a greater number of machine side longitudinal threads.
According to an embodiment of the invention, exactly two upper longitudinal threads and/or exactly four lower longitudinal threads are arranged in the fabric between two functional longitudinal thread pairs, whereby a particularly uniform paper side and machine side, respectively, can be presented.
According to another embodiment of the invention, the upper longitudinal threads and the longitudinal threads of the functional pairs substantially have the same diameter. If the longitudinal threads are formed by warp threads, the upper longitudinal threads and the longitudinal threads of the functional pairs can therefore be wound up on a common warp beam. The diameter of the lower longitudinal threads may, for example, equal the diameter of the upper longitudinal threads and the longitudinal threads of the functional pairs (especially in the first embodiment of the invention). Alternatively, the diameter of the lower longitudinal threads may be greater than the diameter of the upper longitudinal threads and of the longitudinal threads of the functional pairs (especially in the second embodiment of the invention).
According to another embodiment of the invention, all transverse threads extending in the upper fabric are formed as upper transverse threads which are arranged exclusively in the upper fabric, and/or all transverse threads extending in the lower fabric are formed as lower transverse threads which are arranged exclusively in the lower fabric.
The transverse threads extending in the lower fabric layer may, for example, be greater in diameter than the transverse threads extending in the upper fabric layer.
The ratio of transverse threads extending in the upper fabric to transverse threads extending in the lower fabric may, for example, be greater than 1, for example at least or exactly 2:1 or, for example, at least or exactly 3:2. The greater number of transverse threads extending in the upper fabric favors the formation of the above described paper side transverse meshes. However, the invention is not limited to a particular number of transverse threads extending in the lower fabric and in the upper fabric.
The first weave (=weave of the upper fabric layer) may, for example, be a plain weave, and the second weave (=weave of the lower fabric layer) may, for example, be a 5-shaft weave (especially in the first embodiment/alternative of the invention; in this respect, the four longitudinal threads of the two functional pairs form two lower composite longitudinal threads which are considered as two lower longitudinal threads for the description/evaluation of the second weave) or a 4-shaft weave (especially in the second embodiment/alternative of the invention) (in this regard, 4-shaft weave or 5-shaft weave means that the weave can be made by means of 4 or 5 shafts; in other words, the repeat of such a weave has 4 or 5 warp threads and longitudinal threads, respectively). However, the invention is not limited to a particular weave of the upper fabric or to a particular weave of the lower fabric. Upper fabrics and lower fabrics may, for example, also have the same weave, such as a plain weave.
Further variations of the screen according to the invention can be derived from the following description of exemplary embodiments.
Hereinafter, some of the terms used in this application shall be defined:
Longitudinal threads are threads of the screen/fabric which are arranged in the machine direction of the paper machine. In the flat woven screen, the longitudinal threads are formed by the warp threads of the weaving loom. Circular woven fabrics, in contrast, realize the longitudinal threads by means of wefts.
Transverse threads are threads of the screen/fabric which are arranged transverse to the machine direction of the paper machine. In the flat woven screen, the transverse threads are formed by the wefts. Circular woven fabrics, in contrast, realize the transverse threads by means of the warps of the weaving loom.
A fabric layer is a single-layer fabric consisting of transverse threads and longitudinal threads (or warps and wefts).
The upper fabric or the upper fabric layer is a fabric layer which is usually formed in a particularly fine manner, which usually forms the paper side (=the upper side of the upper fabric oriented outwards) of the screen, on which the paper fiber layer is formed. The upper layer is located on the “logical upper side” of the screen.
The lower fabric or the lower fabric layer is a fabric layer which is usually formed in a particularly robust manner, which usually forms the machine side (=the lower side of the lower fabric oriented outwards) of the screen, which enters in direct contact with the driving and draining members of the paper machine generating wear.
Upper longitudinal threads are threads which are located exclusively in the upper fabric and which are there interwoven with transverse threads extending in the upper fabric. The upper longitudinal threads never leave the upper fabric, i.e. they do not change into the lower fabric.
Upper transverse threads are threads which are located exclusively in the upper fabric and which are there interwoven with the upper longitudinal threads (as well as with the longitudinal threads of the functional pairs). The upper transverse threads never leave the upper fabric, i.e. they do not change into the lower fabric.
Lower longitudinal threads are threads which are located exclusively in the lower fabric and which are there interwoven with transverse threads extending in the lower fabric. The lower longitudinal threads never leave the lower fabric, i.e. they do not change into the upper fabric.
Lower transverse threads are threads which are located exclusively in the lower fabric and which are there interwoven with the lower longitudinal threads (in the first embodiment of the invention also with the longitudinal threads of the functional pairs). The lower transverse threads never leave the lower fabric, i.e. they do not change into the upper fabric.
A functional longitudinal thread pair consists of two longitudinal threads located directly next to each other, the position of which in the screen/fabric is not limited to one fabric layer, i.e. the longitudinal threads of a functional pair do not extend exclusively in one fabric layer. Usually, both longitudinal threads of a functional longitudinal thread pair extend both in the lower fabric and in the upper fabric, i.e. the longitudinal threads of a longitudinal thread pair change between the upper and the lower fabric layers (in the first embodiment of the invention as well as in an alternative of the second embodiment of the invention). However, one or both longitudinal threads of a functional pair may also change between one of the two layers and the interior of the fabric (according to a second alternative of the second embodiment). According to the first embodiment of the invention, the two threads of a functional pair together fulfill both the task of an upper longitudinal thread (for example of an upper warp) and of a lower longitudinal thread (for example of a lower warp), and, in addition, interconnect the different fabric layers due to their extension. An upper longitudinal thread formed in such a manner and a lower longitudinal thread formed in such a manner can also be referred to as “upper and lower composite longitudinal threads, respectively”. According to the second embodiment of the invention, the two longitudinal threads of a functional pair together fulfill the task of an upper fabric-internal longitudinal thread (“upper composite longitudinal thread”) and, if applicable, that of a lower fabric-external binder thread.
A longitudinal thread repeat is the smallest repeating unit of longitudinal threads in the fabric. If the longitudinal threads are formed by warp threads, the thread number of the longitudinal thread repeat corresponds to the number of shafts required for producing the fabric.
The invention will hereinafter be described in more detail by means of two exemplary embodiments and with reference to the drawing, in which:
a shows the weave pattern of the upper fabric, the binding locations where an upper transverse thread is bound in by an upper longitudinal thread or an upper composite longitudinal thread being marked with an “x”,
a shows the weave pattern of the lower fabric, the binding locations where a lower transverse thread is bound in by a lower longitudinal thread or a lower composite longitudinal thread being marked with an “x”,
a shows the weave pattern of the upper fabric, the binding locations where an upper transverse thread is bound in by an upper longitudinal thread or an upper composite longitudinal thread being marked with an “x”,
a shows the weave pattern of the lower fabric, the binding locations where a lower transverse thread is bound in by a lower longitudinal thread being marked with an “x”, and the binding locations where the lower fabric is bound to the upper fabric by means of a longitudinal thread of a functional longitudinal thread pair being marked with a “−”, and
Exactly one repeat of the fabric, i.e. the smallest repeating unit of the entire fabric is illustrated in
The sixteen longitudinal threads are distributed to the lower fabric layer and the upper fabric layer as follows. The four longitudinal threads 11, 12, 13 and 14 extend exclusively in the upper fabric layer (see, for example,
The remaining four longitudinal threads 21, 22, 23, and 24 of the weave repeat are formed as two so-called functional pairs. The two longitudinal threads 21 and 22 arranged directly next to each other form a first functional pair, and the two longitudinal threads 23 and 24 arranged directly next to each other form a second functional pair. The four longitudinal threads 21, 22, 23 and 24 forming the two functional pairs extend each both in the lower fabric layer and in the upper fabric layer, i.e. these four longitudinal threads 21, 22, 23, and 24 change between the upper and lower fabric layers.
As shown, for example, by
a shows the weave pattern of the upper fabric. In this respect, it can clearly be seen how the two longitudinal threads 21, 22 together form an upper composite longitudinal thread that inserts in the weave pattern of the paper side, i.e. the upper composite longitudinal thread 21, 22 replaces an upper longitudinal thread which would otherwise be required for forming the paper side plain weave. The same applies to the longitudinal threads 23, 24.
In addition, as shown, for example, by
Of the thirty transverse threads, twenty transverse threads 101 to 120 are assigned to the upper fabric layer and the paper side, respectively, and ten transverse threads 201 to 210 are assigned to the lower fabric layer and the machine side, respectively. The twenty transverse threads 101 to 120 of the upper layer are smaller in diameter than the ten transverse threads 201 to 210 of the lower layer. The twenty transverse threads 101 to 120 extend exclusively in the upper fabric layer, and the ten transverse threads 201 to 210 extend exclusively in the lower fabric layer. This means that none of the transverse threads 101 to 120 changes to the machine side and none of the transverse threads 201 to 210 changes to the paper side. Hereinafter, the transverse threads 101 to 120 will therefore be referred to as upper transverse threads and the transverse threads 201 to 210 will be referred to as lower transverse threads. It should be noted that the invention is limited neither to the shown number of upper and lower transverse threads nor to the shown ratio of upper transverse threads to lower transverse threads (here: 2:1). In addition, the diameter of the upper transverse threads may, for example, be equal to or greater than the diameter of the lower transverse threads.
As shown in
As shown by
According to the embodiment shown in
The longitudinal threads of the two functional pairs 21, 22 and 23, 24 serve as fabric-internal threads in the lower fabric and in the upper fabric and act as binder threads at the same time. Thus, according to this embodiment, the threads of the functional pairs are used both in the lower fabric and on the machine side, respectively, and in the upper fabric and on the paper side, respectively, as an essential part of the corresponding fabric. Their weaving in the respective fabric serves not only for binding the lower fabric to the upper fabric but also for forming functional binding points within the corresponding fabric.
The above-described completion of the paper side and machine side weaves by the two functional pairs is especially obvious from a combination of
As shown in
As also shown by
As also shown in
According to the embodiment shown in
The diameter of the lower longitudinal threads 31 to 38 may, for example, be equal to the diameter of the upper longitudinal threads 11 to 14 and the threads 21 to 24 of the functional pairs according to the embodiment shown in
For clarification and in a very simplified manner,
This means that the 16 longitudinal threads are separated into two units of 8 threads each, an individual warp beam X1 and X2, respectively, being assigned to each unit, and the threads being disposed in the shafts X3 of the weaving loom individually according to their function. This results in a logical allocation of the warp threads in accordance with their function which has been described above.
A plurality of different fabrics can be produced by means of the described assembly of a 16-shaft shaft package X3 in connection with two warp beams X1 and X2, especially fabrics where the connection of upper fabric and lower fabric is obtained by functional longitudinal thread pairs. Examples of such fabrics are the screen and fabric, respectively, as described, for example, in DE 100 30 650 C1 and in WO 2007/087852. Consequently, a number of fabrics/screens can be produced by means of one and the same weaving machine without having to reconstruct the weaving machine in the meantime.
The sixteen longitudinal threads are distributed to the lower fabric layer and the upper fabric layer as follows. The four longitudinal threads 11, 12, 13 and 14 are formed as upper longitudinal threads and extend exclusively in the upper fabric layer (see
As shown in
As illustrated by
Twelve transverse threads 101 to 112 of the twenty transverse threads are assigned to the upper fabric layer, and eight transverse threads 201 to 208 of the twenty transverse threads are assigned to the lower fabric layer. The twelve transverse threads 101 to 112 of the upper layer are smaller in diameter than the eight transverse threads 201 to 208 of the lower layer. The twelve transverse threads 101 to 112 are formed as upper transverse threads and extend exclusively in the upper fabric layer, and the eight transverse threads 201 to 208 are formed as lower transverse threads which extend exclusively in the lower fabric layer. This means that none of the transverse threads 101 to 112 changes to the machine side and in the lower fabric layer, respectively, and none of the transverse threads 201 to 208 changes to the paper side and into the upper fabric layer, respectively. However, it should be noted that the invention is limited neither to the shown number of upper and lower transverse threads nor to the shown ratio of upper transverse threads to lower transverse threads (here: 12:8 or 3:2). In addition, the diameter of the upper transverse threads may, for example, be equal to or greater than the diameter of the lower transverse threads.
As shown in
As shown by
According to the embodiment shown in
If the upper fabric layer shown in
Just like in the fabric according to the first embodiment, the diameter of the upper longitudinal threads 11 to 14 in the fabric according to the second embodiment can be equal to the diameter of the threads 21 to 24 of the functional pairs. Thereby, a uniform paper side can be obtained which is only slightly interfered with by the four change locations A1, A2, B1 and B2. In addition, the upper longitudinal threads 11 to 14 and the threads 21 to 24 of the functional pairs can be arranged without any difficulties on a common warp beam (for example warp beam X2 in
The diameter of the lower longitudinal threads 31 to 38 can for example, just like in the fabric according to the first embodiment, be equal to the diameter of the upper longitudinal threads 11 to 14 and the threads 21 to 24 of the functional pairs. It is, however, also possible to use threads with a greater diameter for the lower longitudinal threads, as the lower longitudinal threads can be applied to a separate warp beam (for example warp beam X1 in
The fabric according to the second embodiment can be produced by means of the weaving machine and warp thread assembly shown in
Number | Date | Country | Kind |
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10 2010 017 055.0 | May 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP11/57978 | 5/17/2011 | WO | 00 | 7/11/2012 |