EP4392604A1 - Reed, and process for manufacturing a reed - Google Patents

Abstract

In recent years, more and more new fields of application for woven fabrics have become available, e.g. as a filter medium. Satisfying the requirements for such applications requires very fine woven fabrics that can be manufactured only by means of reeds having an accordingly small pitch. When manufacturing such reeds, the small distances between the dents of the reeds have an influence on physical effects, e.g. capillarity, which could be disregarded until now when manufacturing reeds having larger pitches. The aim of the invention is to specify a reed having a pitch of no more than 1/8 mm and a process for manufacturing same, taking into account these specificities.

Description

Groz-Beckert KG

parkway 2

72458 Albstadt

Reed and method of making a reed

Weaving machines have been known since the 17th century. Since then, the technology of the weaving machines has developed significantly. Over time, the production of ever finer fabrics with increasing precision was made possible. However, the basic functioning of weaving machines and the weaving process remained unchanged and are not described in detail here, but are assumed to be known. The weaving reed has a major influence on the development of weaving machines. Usually, a reed consists of a plurality of teeth lined up side by side in a widthwise direction while maintaining a uniform pitch. A tooth space is formed between adjacent teeth in the machine width direction by the clearance. During weaving, the warp threads are guided in these spaces between the teeth. The reed thus has a direct influence on the positioning of the warp threads in the width direction of the weaving machine and thus also the position of the warp threads in the subsequent fabric. Irregularities in the reed therefore lead to irregularities (e.g. stripes) in the fabric produced during weaving. A characteristic of reeds is their pitch, which is the sum of the width of a tooth and the width of a tooth space. The pitch describes how densely (finely) the teeth or spaces between the teeth are lined up and correspondingly how fine the fabric to be produced with the reed will be. Although the basic structure of reeds has hardly changed for centuries, there have nevertheless been constructive changes which are often aimed at enabling more economical and/or more precise production of reeds. While the teeth of earlier reeds were still made of reeds, people quickly switched to making the teeth from a metal strip, with the teeth of the reeds having to be made from ever thinner metal strip as the fineness of the reeds increased. Today's reeds often have small pitches of 80 teeth per centimeter or more. The metal band from which the teeth are made is therefore so thin that it is very limp and can rather be described as metal foil. In the case of reeds with a coarse pitch, it is already known to tie the teeth together with a thread, for example a cotton yarn, and profile rods (usually semicircular rods) running in the width direction. On the one hand, the thread has the function of adjusting the distance between adjacent teeth so that the desired interdental space results. On the other hand, binding with the thread serves to create a sufficiently strong connection between the teeth and the profile rods for the further production steps (eg gluing the reed).

GB727546A shows such a reed bound with a cotton yarn. Semi-circular bars are arranged in the end regions of the teeth of this reed, with the teeth being enclosed between two semi-circular bars lying opposite one another in the vertical direction. The cotton yarn is spirally wound around two opposing half-round rods arranged in pairs, with one turn of the spirally wound cotton yarn running between adjacent teeth of the reed, thus ensuring spacing of adjacent teeth. At that time, the cotton yarn was usually soaked in pitch to create a firm connection between the teeth and the semi-circular rods. The pitch hardened into a solid mass after the reed was bound to create a strong bond between the reed's components.

DE2428097 shows a method for producing a reed in which the reed is bound with a nylon yarn instead of a metallic wire. The nylon yarn should not have any influence on the distance between the teeth of the reed. For this purpose, the nylon yarn should be a weakly twisted nylon yarn that offers little or no resistance to deformation in its cross section. Rather, it is provided that the teeth are precisely positioned in their final position by a suitable machine during the manufacturing process. The nylon thread is elastic and is wrapped around the profile rods (rails) of the reed under pretension so that the profile rods should clamp the teeth in their end position. This clamping is intended to prevent the teeth from slipping. The teeth are then bonded together in a known manner--usually in a U-profile. When gluing, a viscous adhesive is introduced between the teeth of the reed, with capillary forces acting on the teeth. A disadvantage of this is that the capillary forces can cause deformation and/or uneven displacement of the teeth in the area of the bond. This effect works The smaller the distances between the teeth and the thinner the teeth themselves are, the more pronounced this is - ie particularly in the case of reeds with a small pitch. The nylon yarn described in DE2428097 cannot counteract this due to its low resistance to deformation and is therefore not suitable for reeds with a small pitch.

Similar problems arise with the reed disclosed in GB693629A. The reed described there is bound with a thermoplastic yarn. However, the teeth, the yarn and the profile bars are not bonded together by casting an adhesive, but are connected to one another by softening the thermoplastic yarn and then curing it. When softening, the yarn loses its pretension and resistance and can be deformed between the teeth of the reed. It can no longer secure the position of the teeth in relation to one another. Equal distances between the individual teeth of the reed cannot be ensured in this way.

The increasing demands on the precision of the reeds and the production of ever finer reeds meant that instead of a chamois metal wire was used to bind the reeds. For example, CA2130760C shows a reed bound with a metallic wire. After binding, the ends of the teeth are inserted into the open sides of U-profiles and glued in these U-profiles with a compound or adhesive to create a strong connection between the individual components of the reed. By using thin wire instead of cotton thread, smaller distances between the teeth could be made. A disadvantage of this technique, however, is that the thickness of the wires must correspond to the required distance between the teeth. A manufacturer of reeds must therefore have the right wire available for every desired distance between the teeth of reeds. Furthermore, the manufacturing tolerances that are common today for metallic wires lead to inaccuracies, especially when manufacturing very fine reeds (more than 80 teeth/cm, or pitches of less than an eighth of a millimeter), i.e. reeds with a very small distance between the individual teeth in the reeds and consequently also in the fabric made with them. For example, a wire that is too large in diameter will result in too large a gap between adjacent teeth. These spacing errors add up over the large number of teeth on a reed, see above that the reed is ultimately too big. However, a reed that is too large cannot be used in a weaving machine. Therefore, there have already been attempts in the past to further develop this technology.

In recent years, new fields of application for tissue - for example as a filter medium - have arisen. WO2017060765 A2 describes the requirements placed on fabrics for such applications (“synthetic monofilament precision fabric”): a very uniform fabric with uniformly large thread spacing is required so that the fabric has the required properties at every point. In order to meet the requirements in these applications, fabrics with very small pitches are also required. For example, WO2020115625 describes a fabric for a diesel filter that is suitable for filtering out water from a diesel-water mixture. For this purpose, fabrics are used which are woven from a yarn with a yarn diameter of between 10 μm and 90 μm and have a lattice spacing of between 5 μm and 150 μm. In order to be able to produce such fabrics, reeds are required which have pitches of 15 μm to 240 μm. Another example of a new field of application of fine fabrics is described in WO2019025885A1. Here the fabric is used as a water- or air-permeable seal against dust (solid particles) for a loudspeaker in a smartphone. Reeds with small pitches of 20 μm to 300 μm are also required for such a fabric. Further examples are disclosed in WO2011132062A1 and EP3219837A1. However, the reeds described in the preceding paragraphs are not suitable for producing such fine fabrics while maintaining the required uniformity of the fabric. The prior art will now be discussed below, which attempts to specify suitable reeds for the production of such fine fabrics.

In sections [0002] to [0015], EP3425096A1 describes in detail the current state of the art, in particular also with regard to reeds with a small pitch. In order to be able to implement small pitches, the teeth of the reeds have a small thickness, which can be less than 0.1 mm. It is also described that such teeth have a high flexibility due to their small thickness. This flexibility of the teeth makes it difficult to produce reeds with a small pitch due to "handling problems". In addition, the previously mentioned capillary forces that act when a reed is glued between its teeth increase. Since the square of the thickness of the teeth is included in the formula for calculating the moment of resistance against bending, the thin teeth required for fine reeds are very flexible. The capillary forces between the teeth can therefore deform or shift such teeth due to their high flexibility (lower restoring force when bending). The result is irregularities in the reed.

[0009] EP3425095B1 shows a reed whose teeth are designed in such a way that, despite the capillary forces that occur when the reeds are glued together, a constant distance between adjacent teeth is ensured. For this purpose, the teeth have spacer knobs that provide a minimum distance between adjacent slats. This is to prevent the development of irregularities or deformations of the teeth due to capillary forces when the teeth are bonded. However, the spacer knobs only act on the capillary forces when the

minimum distance and thus limit irregularities. However, there can still be different distances between adjacent teeth of the reed, which lead to irregularities in the fabric during weaving.

Against the background of the present prior art, it is therefore the object of the invention to provide a reed with a fine pitch, which counteracts even small displacements of its teeth caused by capillary forces, and a method for its production.

The object is achieved by a reed with the features of claim 1 and a method with the features of claim 13. A reed for weaving machines with a maximum pitch of one eighth of a millimeter comprises at least two teeth, the teeth being predominantly in their Extend longitudinally and in its width direction, which is perpendicular to the longitudinal direction, are arranged side by side to form a tooth gap. The interdental space is the free space between adjacent teeth formed by the spacing of the teeth in their width direction. The at least two teeth each have at least two end faces, which delimit the respective tooth in its height direction, which runs perpendicular to its longitudinal direction and its width direction, and are spaced apart from one another in this height direction. The reed comprises at least two profile rods, the one Form functional pair, the at least two end faces - abut and pairs opposite in height direction - preferably flat. The profile bars extend predominantly in the width direction and have a profile cross section in a plane spanned by the longitudinal direction and the height direction, which is usually semicircular. However, any other profile cross section is also conceivable - for example a rectangular cross section. The reed preferably comprises four profile rods, which form two pairs of functions. Furthermore, the reed comprises at least one binder, which at least partially wraps around the at least two opposite profile rods, which form a functional pair, and pulls them towards each other, with the binder running at least in sections in the interdental space between the at least two teeth. Usually, the binder is spirally wound around the functional pairs of the profile bars, with the teeth lying within at least one turn of the spirally arranged binder. Several windings can be arranged between two teeth. The binder is a textile yarn comprising a plurality of filaments, the textile yarn having a greater width in the width direction at at least one point where it is in direct contact with at least one of the profile bars than in the areas that are in the height direction lie between the profile bars. If the profile bars have a semicircular cross-section, the yarn usually lies on the circumference of the semicircle and is in direct contact with the profile bar in this area. In this area, the textile yarn extends in the width direction with a greater width than the interdental space through which the textile yarn runs. It widens outside of the interdental space. This increases the contact surface between the textile yarn and the profile bar and thus prevents the yarn from slipping on the profile bar due to the increased friction surface. As a result, the position of the teeth in the width direction is also better secured by the textile yarn. In this way, therefore, reeds can be produced with a fine pitch and a precise alignment of the teeth and tooth spaces in the width direction. The textile yarn therefore has a direct influence on the position or securing the position of the teeth. Since the widening of the textile yarn occurs while maintaining the yarn volume, the height of the yarn perpendicular to the width direction decreases in the widening area. Consequently, the yarn cross-section is not circular in these areas. Surprisingly, it has been shown that reeds with a comparatively small pitch of one eighth of a millimeter or less can also be produced particularly uniformly in the aforementioned manner are. Greater uniformity of tooth spacing can be achieved than is possible with conventional reeds using metallic wire as a binder.

The textile yarn is advantageously elastic. Preferably, the textile yarn wraps around the profile bars in an elastically prestressed manner. With an elastic textile yarn, the teeth can be secured in their position before the reed is glued by applying a pretensioning force. This has the advantage that even small movements in the reed can be compensated for by stretching or contracting the textile yarn without completely losing the pretensioning force. Due to the prestressing force, which can then change minimally, the previously bonded teeth between the profile bars are prevented from loosening or shifting.

It when the textile yarn has adjacent turns that have such a large width in the width direction that the adjacent turns at least one point at which they are in direct contact with at least one of the profile bars, abut one another is particularly advantageous. There is then no distance between adjacent windings of the textile yarn, at least in sections in the width direction. Through the contact of the adjacent turns of the textile yarn, these turns mutually secure their position relative to the profile bars and thus prevent widthwise displacement of the teeth of the reed functionally connected to these turns.

Further advantages arise when the filaments of the textile yarn have a maximum diameter which corresponds at most to half the width of the interdental space in the width direction. Advantageously, the filaments have a maximum diameter of at most one third, but preferably at most one quarter of the width of the interdental space in the width direction. Such a textile yarn is compressible and can be adapted to the interdental space in its width direction, but at the same time offers a sufficiently high resistance to compression if the width of the interdental space falls below its nominal size. As a result, the textile yarn counteracts deformations and/or displacements of the teeth in the width direction, which can be caused, for example, by capillary forces during gluing, and thus improves the uniformity of the spaces between the teeth of the reed. The number of filaments in the yarn can also affect the uniformity of the reed. The reed advantageously comprises at least five filaments, but preferably at least fifteen filaments.

Advantageously, the textile yarn is compressible under application of a compressive force, the compressive force increasing progressively with increasing compression of the textile yarn. A textile yarn with these features can prevent the formation of irregular interdental spaces in the reed, in that the compression force counteracts the capillary forces acting on the teeth, especially when the reed is glued, if the width of the interdental spaces falls below the specified value.

Further advantages with regard to the uniformity of the interdental spaces arise when the textile yarn in the areas of the reed which lie between the profile rods in the height direction, rests on both sides in the width direction on at least one tooth in each case. In these areas, the textile yarn thus completely fills the entire tooth gap between adjacent teeth in the width direction, at least in sections. For this purpose, the textile yarn is advantageously compressed to the desired dimension of the interdental space during assembly of the reed. The textile yarn thus advantageously has a larger diameter than the target size of the interdental space, but can be compressed to the target size of the interdental space.

The textile yarn is advantageously twisted and has a twist coefficient a of at least 20, with the following formula for the twist coefficient a: oc= t * -

J 1000 where t = number of twists per meter of textile yarn Pt = fineness of textile yarn in tex applies.

Advantageously, however, the textile yarn has a twist coefficient of 20 to 100. The rotation coefficient is described in DIN EN ISO 2061 and is specified in this standard without a unit. The standard states as follows: "The twist coefficient describes the angle that the fibers on the surface of the yarn make to the axis of the yarn and is a measure of the hardness of the yarn caused by twisting." One twist of the yarn corresponds a rotation of 360° around the longitudinal axis of the yarn. Twisting the yarn can influence its cross-sectional shape, as well as its stretching and compression behavior. The rotation coefficient is also often referred to in the literature as the degree of rotation or rotation coefficient. It characterizes the twist hardness and is suitable for comparing the elongation and compression behavior of yarns of different counts. The twist coefficient indicates the number of twists per meter length that a comparison yarn with a fineness of 1000 tex would have with the same twist hardness. Yarns have the same twist hardness if their twist coefficient is the same. It has been shown that when tying fine reeds with a textile yarn, the elongation and compression behavior of a textile yarn with a twist coefficient in the above selection range brings advantages with regard to the uniformity of the reed. However, it is particularly advantageous if the textile yarn has a twist coefficient of 45 to 65. The textile yarn is compressible at least up to the specified size of the width of the interdental space. However, if the width of the interdental space falls below the target value, the compression force increases at least progressively with increasing compression. In this way, the increasing compression force counteracts the width of the interdental space falling below the target dimension.

Further advantages arise when the textile yarn has 500 to 2000 twists per meter. However, the textile yarn advantageously has 800 to 1800 twists per meter. With the number of twists per meter of yarn, the stretching and compression behavior of the textile yarn can be adjusted in such a way that the tooth spaces between the teeth are as uniform as possible during production of the reed.

Advantageously, the textile yarn has at least one filament containing at least one of the following materials: polyamide, polyamide 6.6, polyamide 6, polyester, polyimide, polyamideimide, polypropylene, polyurethane. Due to its material behavior, polyamide in particular is suitable for forming a textile yarn that has the required stretching and compression properties. However, the textile yarn can advantageously also consist of other materials which are not mentioned in the above list, but allow the formation of a yarn with the required stretching and compression behavior. The filaments of the textile yarn can also advantageously contain more than one material. The textile yarn can therefore go to Examples include polyamide filaments and polyester filaments, various polyamide filaments, or various polyester filaments. Advantageously, however, all filaments of the textile yarn contain polyamide.

[0020] In order to achieve a pretensioning force that is as uniform as possible and uniform spaces between the teeth, it is advantageous if the textile yarn has a maximum tensile strength of at least 20 cN/tex based on the fineness. Advantageously, the textile yarn has a maximum tensile strength related to the fineness of 100 cN/tex. However, it is particularly advantageous if the textile yarn has a maximum tensile strength of 30 cN/tex to 60 cN/tex based on the fineness. The maximum tensile strength related to the fineness can be determined according to DIN EN ISO 2062.

Further advantages arise when the textile yarn has an elongation at maximum tensile force of 10% to 80%, but preferably of 20% to 45%. The elongation at maximum tensile force can be determined according to DIN EN ISO 2062.

An advantageous embodiment of the reed does not include a spacer, the arrangement of which determines the width of the interdental space between the at least two teeth. A spacer can be, for example, a metallic (substantially incompressible) wire, metallic coil or spring. Such spacers are known from the prior art and are used in addition to the binder. In the case of reeds from the prior art, they are arranged between the teeth of a reed. In the case of reeds with small pitches of less than 0.1 mm in particular, this is often associated with very complex manual work. For example, producing a reed with more than 150 teeth per cm using spacers between the teeth can take several months. This technique is therefore not suitable for the industrial production of reeds with such small pitches.

Advantageously, at least one tooth of the reed has at least one spacer knob, which is raised on at least one side in the width direction B compared to a large part of the tooth and falls below a minimum distance from at least one adjacent tooth in the width direction B. Such spacer knobs are already known from EP3425095B1. There, for example, FIGS. 4 and 5 show teeth (#16) of a reed that have spacer knobs (#30). All embodiments of the spacer knobs disclosed in this patent specification can be advantageously combined with the present teaching according to the invention. With the spacer knobs can occur Capillary forces between adjacent teeth are counteracted. As a result, the spaces between the teeth of reeds with small pitches can also be made uniform.

A method for producing a reed with a maximum pitch of one eighth of a millimeter is described below. In a first method step, at least two teeth, which extend predominantly in their longitudinal direction, are arranged next to one another, forming a tooth gap in their width direction, which runs perpendicular to the longitudinal direction, with the at least two teeth each having two end faces that the respective tooth in its height direction, which is perpendicular to its longitudinal direction and its width direction, and are spaced from each other in this height direction. At least one binder is then wound around at least two profiled bars, which form a functional pair and are located opposite one another in pairs in the height direction, in such a way that it at least partially wraps around the at least two profiled bars and pulled towards one another in such a way that the at least two profiled bars on the at least two end faces of the at least two teeth rest. The binding agent runs at least in sections in the interdental space between the at least two teeth. A textile yarn is used as a binder, which comprises a plurality of filaments, the textile yarn being wound under pretension in such a way that at least one point at which it is in direct contact with at least one of the profile bars is compared to the width of the yarn in the areas that lie between the profile bars in the height direction, widens in the width direction. Winding the yarn under pretension means that the yarn is applied with a pretension force and stretched along its longitudinal direction for winding. The textile yarn widens outside of the interdental space, or it widens. This increases the contact surface between the textile yarn and the profile bar and thus prevents the yarn from slipping on the profile bar due to the increased friction surface. As a result, the position of the teeth in the width direction is also better secured by the textile yarn. In this way, therefore, reeds can be produced with a fine pitch and a precise alignment of the teeth and tooth spaces in the width direction. The method described is suitable for producing a reed with all the features already described in the previous sections.

Advantageously, the textile yarn is wound under tension in such a way that it is at least one point where it is in direct contact with at least one of the profile bars Contact is widened in the width direction in such a way that turns of the textile yarn lying next to one another in the width direction bear laterally against one another in the width direction. In this way, adjacent turns of the textile yarn mutually secure themselves against slippage in the width direction and also prevent slippage of the teeth of the reed during manufacture.

In an additional method step, the textile yarn is compressed between the at least two teeth in the width direction to the width of the interdental space. However, the filaments of the textile yarn are not compressed in the process. The compression of the yarn has the advantageous result that the positions of the filaments of the textile yarn are changed - that is, shifted - and the cross-sectional shape of the yarn is changed, but not the cross-sectional shape of individual filaments. The filaments are thus advantageously rearranged relative to one another.

Further advantages result if the filaments of the textile yarn are compressed when the width of the interdental space falls below the target value. In this way, the compression force increases disproportionately when the target dimension is not reached and the textile yarn or its filaments counteract the falling below the target dimension of the width of the interdental space. As a result, the width of the spaces between the teeth can be ensured as uniformly as possible during the manufacture of a reed.

FIG. 1 FIG. 1 shows a three-dimensional view of a reed with a large number of teeth (2) which are arranged next to one another in the width direction (B) to form spaces (5) between the teeth.

FIG. 2 shows a section through the reed from FIG. 1, which lies in a plane spanned by the longitudinal direction (L) and the vertical direction (H) and runs exactly between two teeth (2) through a tooth gap (5).

Fig. 3 Figure 3 shows the section A-A from Fig. 2.

Fig. 4 Figure 4 shows section B-B from Fig. 2.

FIG. 5 FIG. 5 shows detail C from FIG. 2, the textile yarn (4) having a twist.

FIG. 6 Like FIG. 3, FIG. 6 shows the section A-A from FIG. 2. In comparison to FIG. 3, however, the textile yarn (4) comprises more filaments (8).

FIG. 7 FIG. 7, like FIG. 4, shows the section BB from FIG. 2. In contrast to FIG Width direction (B) do not touch each other.

1 shows a three-dimensional view of a reed 1. The reed 1 comprises a plurality of teeth 2, which are arranged side by side in a width direction B, forming interdental spaces 5 between adjacent teeth 2. Four profile bars 3 are positioned above and below the teeth 2 in the height direction H. Two profile bars 3 each, which are mirrored in the height direction H, form a functional pair and enclose the teeth 2 in the height direction H between them. In each case one textile yarn 4 wraps around a functional pair of the profile rods 3 in a spiral, so that one turn of the textile yarn 4 runs through each tooth gap 5, and connects the profile rods 3 and the teeth 2 in this way.

2 shows a section through the reed 1 from FIG not provided with a reference number in this illustration. Only one tooth 2 is shown because it covers the other teeth 2 of the reed in this view. At the left and right ends of the teeth 2 in the illustration, two profiled rods 3, which form a functional pair, are arranged. The profile bars 3 rest on the end faces 6 of the teeth 2 and are pressed onto the end faces 6 by the textile yarn 4 wrapping around the profile bars 3 with pretension. This exerts a clamping force on the teeth 2, which is suitable for securing the position of the teeth 2 and preventing a shift in the width direction B. In the illustration, one turn of the textile chamois 4 is wound around each functional pair of the profile rods 3 . The windings each begin at the highest point of the textile yarn 4 in the height direction H, which can be seen from the fact that the textile yarn 4 is cut at this point. The cut surfaces 7 of the textile chamois 4 are shown hatched. The windings run once completely around a functional pair of the profile bars 3 and then merge into the next winding of the textile yarn 4, which runs in the interdental space 5, which lies behind the tooth 2 shown.

3 shows the section AA from FIG. 2. It can be seen how the textile yarn 4 is arranged in the spaces 5 between the teeth. In this exemplary embodiment, the textile yarn 4 consists of eleven filaments 8 and is wound around the profile rods 3 in such a way that in each interdental space 5 one turn of the textile yarn 4 runs. The textile yarn 4 is therefore shown cut once in each interdental space 5 in this representation. The textile yarn 4 is a twisted yarn and, in its original state before the profile rods 3 are wrapped around it, has a substantially circular cross-section. However, when the reed 1 is assembled, this cross-section is compressed. In FIG. 3 it can be seen, for example, that the cross section of the textile yarn 4 is compressed between the teeth 2 of the reed 1 in such a way that it is adapted to the width 9 of the spaces 5 between the teeth in the width direction B. The textile yarn 4 thus rests against a tooth 2 on both sides in the width direction B. The position of the filaments 8 can shift in relation to one another. However, individual filaments 8 are preferably not compressed. As a result, the textile yarn 4 can be compressed to the desired width 9 of the interdental spaces 5 with a defined expenditure of force. If the target value is not reached, however, the individual filaments 8 are advantageously compressed, which requires a significantly greater compression force. In this way, it is possible to counteract the width 9 of the interdental space 5 falling below the target value. This behavior of the textile yarn 4 can be achieved in that the filaments 8 have a maximum diameter 13 which corresponds at most to half the width 9 of the interdental spaces 5 . FIG. 2 also shows once again what is to be understood by the division 11 in the sense of this patent application. The pitch 11 is the sum of the width 9 of the tooth space 5 and the tooth width 10 in width direction B.

4 shows the section BB through the reed 1 from FIG. 2. A plurality of teeth 2 are shown in section. A profile bar 3 is shown above the teeth 2 in the longitudinal direction L behind the cutting plane. In the width direction B between adjacent teeth 2 there is a space 5 between each tooth. The two interdental spaces 5 on the left in the illustration are completely filled with the textile yarn 4 in the width direction B and height direction H. The textile yarn 4 can thus bring about a uniform formation of the interdental spaces 5 . For clarification, three interdental spaces 5 without textile yarn 4 are shown in the illustration. Actually, these interdental spaces 5 are also filled with the textile yarn 4 . The textile yarn 4 is rotated about its longitudinal axis by the angle of rotation 12 and exits the interdental spaces 5 in the vertical direction H at the top. With the exit from the interdental spaces 5, the textile yarn lies against the profile bar 3 and widens in the width direction B. It therefore has a greater width in the areas in which it rests on the profile bar 3 than in the areas in where it runs between the teeth 2 in the interdental spaces 5. The textile yarn 4 widens in the vertical direction H with increasing distance from the interdental spaces 5 until adjacent windings of the textile yarn 4 in the width direction B are in contact with one another. In this way, the adjacent turns of the textile yarn 4 mutually secure their position as well as the position of the teeth 2 in the width direction B. While the textile yarn 4 widens in the width direction B, its height 14 increases perpendicular to the width direction B and perpendicular to the longitudinal extension of the textile yarn 4 off This behavior of the textile yarn 4 is shown in FIG. 5, which shows detail C from FIG. How much the textile yarn 4 widens in the width direction B or contracts in its height 14 can be influenced by twisting the textile yarn 4 . With a lightly twisted yarn (small twist angle 12) or a yarn with no twist, this effect is more pronounced than with a highly twisted yarn (large twist angle 12).

FIG. 6 shows essentially the same view as FIG. 3. However, the textile yarn 4 comprises more filaments (exactly 22 filaments). The filaments have a smaller maximum diameter 13 which is less than a third of the width 9 of the interdental space 5 . Such a textile yarn 4 adapts even better to the interdental space 5 . Therefore, reeds 1 can be produced with an even greater uniformity of the interdental spaces 5.

FIG. 7 shows essentially the same view as FIG. 4. However, the textile yarn 4 has a different expansion and compression behavior. In this exemplary embodiment, too, the textile yarn 4 widens in the width direction B outside of the interdental spaces 5 . In contrast to the exemplary embodiment shown in FIG. 4, however, the textile yarn 4 does not widen to such an extent that the adjacent windings of the textile yarn 4 in the width direction B are in lateral contact with one another.

Figures 1 to 7 partially do not represent the actual proportions of the individual components of the reed 1. It is therefore not to scale drawings but basic sketches intended to show the essential features of the invention.

Claims

patent claims

1. Reed (1) for weaving machines with a pitch (11) of at most 1/8 mm with the following features a) at least two teeth (2), the teeth (2) extending predominantly in their longitudinal direction (L) and in their Width direction (B), which runs perpendicularly to the longitudinal direction (L), are arranged side by side to form an interdental space (5), b) the at least two teeth (2) each having two end faces (6), which the respective tooth (2nd ) in its height direction (H), which runs perpendicular to its longitudinal direction (L) and its width direction (B), and are spaced apart from one another in this height direction (H), c) at least two profile bars (3) which form a functional pair, which rest on the at least two end faces (6) and are opposite each other in pairs in the height direction (H), d) at least one binding agent which at least partially wraps around the at least two opposite profile bars (3), which form a functional pair, and pulls them towards one another, e) wherein the binding agent is at least partially in the interdental space

(5) between the at least two teeth (2), characterized in that f) the binder is a textile yarn (4) comprising a plurality of filaments (8), g) and that the textile yarn (4) on at least one point at which it is in direct contact with at least one of the profile bars (3), has a greater width in the width direction (B) than in the areas that lie between the profile bars (3) in the height direction (H).

2. Reed (1) according to the preceding claim characterized in that the textile yarn (4) is elastic. Reed (1) according to one of the preceding claims, characterized in that the textile yarn (4) has adjacent windings which have such a large width in the width direction (B) that the adjacent windings at least at one point where they are connected to at least one of the profile bars (3) are in direct contact, abut one another. Reed (1) according to one of the preceding claims, characterized in that the filaments (8) have a maximum diameter (13) which corresponds at most to half the width (9) of the interdental space (5). Reed (1) according to one of the preceding claims, characterized in that the textile yarn (4) can be compressed by applying a compression force, the compression force increasing progressively with increasing compression of the textile yarn (4). Reed (1) according to one of the preceding claims, characterized in that the textile yarn (4) in the regions which lie between the profile bars (3) in the height direction (H) on both sides in the width direction (B) on at least one tooth (2nd ) is present. Reed (1) according to one of the preceding claims, characterized in that the textile yarn (4) is twisted and that the textile yarn (4) has a twist coefficient a of at least 20, the following formula for the twist coefficient: 19oc= t * -

J 1000 with t = number of twists per meter of textile yarn (4) Pt = fineness of textile yarn (4) in tex. Reed (1) according to one of the preceding claims, characterized in that the textile yarn (4) has at least one filament which preferably contains at least one of the following materials: polyamide, polyamide 6.6, polyamide 6, polyester, polyimide, polyamideimide, polypropylene, polyurethane . Reed (1) according to one of the preceding claims, characterized in that the textile yarn (4) has a maximum tensile strength related to the fineness of at least 20 cN/tex. Reed (1) according to one of the preceding claims, characterized in that the textile yarn (4) has an elongation at maximum tensile force of 10 to 80%, but preferably of 20% to 45%. Reed (1) according to one of the preceding claims, characterized in that the reed (1) does not include a spacer, the arrangement of which predetermines the width of the interdental space (5) between the at least two teeth (2). Reed (1) according to one of the preceding claims, characterized in that at least one tooth (2) has at least one spacer nub that 20

Width direction (B) is raised at least on one side compared to a large part of the tooth (2) and prevents falling below a minimum distance to at least one adjacent tooth (2) in the width direction (B). Method for producing a reed (1) with a pitch (11) of a maximum of 1/8 mm with the following method steps: a) at least two teeth (2), which mainly extend in their longitudinal direction (L), are formed, forming a tooth gap ( 5) arranged next to one another in their width direction (B), which runs perpendicularly to the longitudinal direction (L), b) the at least two teeth (2) each having two end faces (6) which extend the respective tooth (2) in its height direction (H) which runs perpendicularly to its longitudinal direction (L) and its width direction (B) and are spaced apart from one another in this height direction (H), c) at least one binder is placed around at least two profiled rods (3) which form a functional pair form and are wound in pairs in the height direction (H) opposite one another in such a way that it at least partially wraps around the at least two profile bars (3) and pulls them towards one another in such a way that the at least two profile bars (3) rest on the at least two Sti rn surfaces (6) of the at least two teeth (2), d) the binding agent running at least in sections in the interdental space (5) between the at least two teeth (2), characterized in that e) that a textile yarn (4) is used as the binding agent , which comprises a plurality of filaments (8), is used, f) and that the textile yarn (4) is wound under pretension in such a way that at least one point where it is connected to at least one of the profile rods (3) in is in direct contact, widens in the width direction (B). Method for producing a reed (1) according to the preceding claim, characterized in that the textile yarn (4) is wound under pretension in such a way that it 21 at least one point where it is in direct contact with at least one of the profile bars (3), widens in the width direction (B) in such a way that in the width direction (B) adjacent turns of the textile yarn (4) lie laterally in the width direction (B). touch each other. Method for producing a reed (1) according to one of the preceding claims, characterized in that a) the textile yarn (4) is compressed between the at least two teeth (2) in the width direction (B) to the width (9) of the interdental space (5). b) and that the filaments (8) of the textile yarn (4) are not compressed in the process. Method for producing a reed (1) according to one of the preceding claims, characterized in that the filaments (8) of the textile yarn (4) are compressed when the width (9) of the interdental space (5) falls below the target value.