EP1587978B1 - Textile fabric and method for the production and use thereof - Google Patents

Abstract

The invention relates to a voluminous, textile, multi-layered fabric, especially a unilaterally mesh-layered non-woven fabric comprising pile fibres and/or pile fibre loops (24, 25) and at least one pile fibre layer (22), said pile fibres having essentially the same length and with respect to the cross-section thereof, are anchored and protrude from the cross-section thereof (21) in a predominately vertical to diagonal manner. The free ends of the pile fibres and/or pile fibre loops are clamped in a fixed manner in a closed functional layer (26). The functional layer (26) is arranged at a distance from the fabric cross-section (21). The invention also relates to a method for the production of fabric in addition to the use thereof.

Description

The invention relates to a textile fabric according to the preamble of claim 1, and a method for producing the sheet and its use.

In the course of the following description and claim of the invention, naturalized brand names are also used for mechanical web bonding processes such as Maliwatt, Malivlies, Kunit, Multiknit, Struto, which are described in the textbook "Nonwovens", Raw Materials, Manufacture, Use, Properties, Testing. Albrecht, H. Fuchs, W. Kittelmann, Wilay-VCH-Verlag GmbH, D-69469 Weinheim, 2000, in particular on page 305 are explained.

Voluminous nonwoven fabrics which have on one or both sides a consolidating fiber mesh layer are, for example, from DE 198 12 499 A1 known. The unilaterally mesh-coated nonwoven fabric has a mesh layer as a base fabric and a plush-like surface formed of protruding fibers. The one-sided mesh-coated nonwoven fabric is produced by the production of a double-meshed, voluminous nonwoven fabric and central separation in a surface plane.

The DE 42 39 469 A1 deals with a method for solidifying cross-oriented fiber webs, in which also a single-side mesh-coated, so-called nonwoven knitted fabric is produced.

Another technology for producing a meshed bulky nonwoven fabric is known from EP 1 149 882 A1 known. This nonwoven fabric is designed as a textile carrier of an adhesive tape and has a velorized surface produced by a needle method, which is suitable, inter alia, for the function of reducing compressive forces. The velorized surface is formed of a plurality of parallel, arranged substantially perpendicular to the nonwoven web, substantially equal length fiber parts whose foot is anchored in the nonwoven web. On the velor surface opposite surface of the nonwoven web, the adhesive of the adhesive tape is provided. Since unwanted fibers from the anchoring solidified nonwoven web may be torn when unrolling an as-rolled tape in which the suede surface is in contact with the adhesive, it is proposed to consolidate the nonwoven fabric into the nonwoven web in the nonwoven web or during the velor-needling needling The velorized surface of the nonwoven fabric to arrange a thin, non-textile web.

Voluminous single-sided or double-sided stitch-bonded nonwovens are also used as pressure elastic upholstery fabrics. The upholstery fabrics are arranged between a coating material, for example consisting of a wool fabric, and a foam core, for example consisting of polyurethane. They should in particular ensure compressive elasticity and be moisture-storing and moisture-permeable ( EP 0 126 798 B1 ).

From the DE 44 24 636 C2 For example, a multilayer bulky laminating fabric to be used as a upholstery fabric is known, in which two stitchbonded nonwoven fabrics are connected by vertical fiber pleats consisting of the fiber parts of the outer fibrous mesh layers and extending to the middle of the respective opposite fibrous layer. This is to be generated by a denser fiber arrangement in the respective fiber layer, a pressure-elastic zone.

The from the DE 41 27 337 A1 Known upholstery includes a nonwoven fabric containing a superabsorbent hydrogel as the functional fabric. On the one hand, the hydrophilic hydrogel should absorb large quantities of moisture and steam and on the other hand be easily regenerable, in particular desorbable. About the type of nonwoven fabric no statement is made.

From the WO 00/64311 For example, there is known a cushion of a seat or reclining furniture which has a desorbing moisture reservoir in the form of a hydrophilic layer for reversibly absorbing body moisture. The hydrophilic layer consists inter alia of a nonwoven fabric as a carrier material and a superabsorber grafted onto the nonwoven fabric, wherein the fibers of the nonwoven fabric are at least partially coated by the superabsorber. The superabsorbent is sprayed onto the nonwoven fabric prior to its polymerization or applied by the dip-bath process. About the nature of the nonwoven fabric, no information is given in this document.

When spraying, the superabsorbent penetrates inhomogeneously deep into the nonwoven fabric and is also distributed inhomogeneously on the surface. The result is an extreme surface roughness and unwanted stiffening of the nonwoven fabric. In addition, it is also not possible to apply defined amounts of superabsorber, so that the absorption capacity is not controllable.

The object of the invention is to provide a pressure-elastic, in particular as upholstery fabric usable fabric, in particular of a nonwoven, which may contain defined amounts of functional agent in particular homogeneously distributed, wherein defined nonwoven properties such as suppleness and / or flexibility (elastic bending stiffness) and / or softness and / or elasticity can be ensured.

This object is solved by the features of claims 1, 41 and 46. Advantageous developments of the invention are characterized in the subclaims.

The invention relates in particular to pressure-elastic nonwoven fabrics with a three-dimensional fiber arrangement.

In the context of the invention, compressive elasticity is understood to be the property of a voluminous textile fabric to absorb the compressive force by elastic deformations of structural elements in the volume structure of the textile under pressure or pressure on a surface of the textile, and to ensure, during relief, that the deformed structural elements elastic spring back. The pressure-elastic behavior of the textile fabrics is determined by the method known for elastic foams.

The textile fabrics according to the invention, in particular in the form of a nonwoven fabric, have a fiber pile layer with high compressive elasticity and, in particular, also with further functional utility properties and are used e.g. as a polyurethane foam substitute in vehicle interior trim, in the upholstered furniture industry as well as a pressure-elastic, functional textile material in the clothing, medical and insulation sectors.

It is generally known that nonwovens with a three-dimensional fiber arrangement by a structurally determined proportion of fiber parts vertical to diagonal arrangement to nonwoven cross section pressure loads higher resistance than conventional nonwovens with extensive horizontal fiber arrangement in the nonwoven cross section. Such nonwoven fabrics with a three-dimensional arrangement are known in the art as struto, as a laid in longitudinal fold batt, solidified by binding fibers as dilourisierte nonwovens with subsequent ejection of vertical fiber parts of the nonwoven cross section through piercing barb needles, as Kunit as a solidified by fiber stitching, longitudinally compressed batt. At high compressive stress, as they occur, for example, when using such nonwovens as polyurethane foam substitute in the upholstery area in upholstered furniture or vehicle seats and interior trim parts in cars, the soft vertical to diagonal protruding fiber parts, put on by the compressive stress and form in this horizontal arrangement parallel to the nonwoven fabric cross-section no or little recovery forces to return to the starting position after elimination of the pressure load; they thus show a low compressive elastic behavior.

To improve the compressive elasticity of such three-dimensionally oriented nonwoven fabrics, for example, in the DE 202 09 709 U1 the use of thermoplastic binder fibers proposed. These binder fibers form small bonding surfaces with and between the fiber parts during thermal treatment, as well as the fiber parts projecting vertically to obliquely from the nonwoven fabric cross-section, and thus make it difficult to put it over under pressure loads. However, as a result of the uniform distribution of the binder fibers within the entire binder skeleton in the nonwoven fabric, these bonding binding points are evenly distributed in the nonwoven fabric and, if the proportion is too high, an excessively large number of such bond points harden and stiffen the nonwoven fabric. Moreover, for economic and / or functional reasons, such nonwoven fabrics with three-dimensional fiber orientation often do not require the use of such binder fibers, for example, when use or processing temperatures which are above the melting range of the binder fibers occur.

From the DE 101 39 843 A1 is a nonwoven fabric with three-dimensional fiber orientation is known, which consists of a non-woven fabric bonded by thread meshes and having on one side a Faserpolschicht formed from vertically to the non-woven fabric cross-section protruding fiber parts, which over the entire surface have a high density, parallelism and uniform height, wherein one or both ends of the fiber parts are mechanically incorporated in the nonwoven cross section. Disadvantage of these nonwovens is in addition to the low compressive elasticity that only a maximum Faserpolhöhe of 6 mm is achieved and the fiber parts in the Faserpolschicht are not connected to each other supporting.

In the DE 100 47 824 C1 there is described a fibrous non-woven fabric without additional threads for use as a cushioning material having a bulky pile structure of fiber parts having a spatial-diagonal arrangement covered on one side with stitches to improve the transverse strength of the nonwoven fabric. The disadvantage is that there is a large difference between the pile fiber heights in these nonwoven fabrics, which causes a very uneven surface of the pile fiber layer, and also adversely affects the compressive elasticity of the nonwoven fabric.

Corresponding DE 42 35 858 A1 For example, the pile fiber surface of a fiber stitched Kunit nonwoven fabric may also be used to form fiber stitches. The resulting multi-knit nonwoven fabric then has two fiber mesh surfaces with certain thickness uniformity, but has between these two fiber mesh layers diagonally oriented fiber parts whose height is too low for good compressive elasticity effects.

According to a particular embodiment of the invention, a one-sided mesh-strengthened, voluminous nonwoven fabric is selected and changed such that during manufacture ensures a predetermined compressive elasticity and possibly also a predetermined amount of functional agent attached to pile fibers or Polfaserschlingen and / or introduced into cavities between the pile fibers.

According to one embodiment of the invention, a new structure of the nonwoven fabric is provided in the form of a voluminous, one-side mesh-coated or nonwoven web having pile fibers extending perpendicularly to the surface plane or to the nonwoven fabric cross-section and / or pile fiber loops which are at least three in the plane of the fabric has different structural levels, of which an inner structural layer, for example, forms an indentation barrier for a functional agent and an outer structural layer predetermined Cavities for receiving functional agents and predetermined Polfaseroberflächen for the addition of functional agents provides.

The void volume, the void distribution and / or the size of the attachment surfaces of the fibers can be predetermined in the preparation of the new nonwoven fabric, so that the nonwoven fabrics according to the invention are easily adaptable to predetermined requirements.

Based on FIGS. 1 to 6 the drawing, the invention is explained in more detail below by way of example. The FIGS. 1 to 6 show schematically in cross section the structure of inventive voluminous fabrics.

The textile fabric after Fig. 1 consists of a bulky nonwoven fabric 1 and has a three-layered structure. At the bottom is a base layer 2 - the so-called nonwoven fabric cross-section - arranged with substantially aligned in the surface plane fiber parts 3. It contains on the underside the fibrous and / or thread meshes 4 which act in the surface plane and anchor in the base layer 2 anchoring regions 5, 6 of first longer pole fibers 7 and second shorter pole fibers 8 projecting mainly perpendicularly from the base layer 2 , wherein the pile fibers 7 are arranged at a lateral distance from the pile fibers 8.

The pile fibers 7 have at least predominantly the same pole tip height H of the pole tips 9, measured from the lower surface 10 of the textile fabric, or the pole tips 9 of the pile fibers 7 are at least predominantly in a plane plane 12. Similarly, the pole tips 11 of the pile fibers 8 at least predominantly same pole tip height h, measured from the lower surface 10, on or lie the pole tips 11 of the pile fibers 8 at least predominantly in a plane plane 13. The plane 12 of the Polfaserspitzen 9 is - viewed from the lower surface 10 of the mesh plane 14 - above the plane 13 of the Polfaserspitzen eleventh

By this structure of the new nonwoven fabric, relatively wide upwardly open cavities 15 are formed between the long pile fibers 7 and relatively narrow spaces 16 remain between the long and short pile fibers 7, 8. According to the invention, the spatial distribution of the short fibers 8 e.g. chosen so close that e.g. almost no functional agent, e.g. in the form of an adsorbent in the pile fiber structure of the pile fibers 8 and in the cavities 16 can penetrate when a functional agent is introduced into the cavities 15, wherein the pole tips 11 blocking act against the ingress of functional agent. As a result, the nonwoven fabric properties in the nonwoven fabric area 17, which consists of the short fiber layer area and the area of the base layer 2, are retained. This layer structure ensures in particular the desired for many applications compressive elasticity and flexibility and softness of the nonwoven fabric. The long fiber layer region 18 provided over the short fiber layer provides the cavities 15 e.g. for the reception of functional agents and the functional means accessible attachment surfaces of the long pile fibers 7 available.

According to the invention, a functional layer 19 is applied to the nonwoven fabric on the side of the plane 12, whose thickness is selectable and which can reach to the tips 11 of the short pile fibers 8, and solidified, wherein the cavities 15 at least partially filled and the long Pol fibers 7 are involved in this area.

The closed functional layer has essentially the functional task to fix the free end portions of the pile fibers or Polfaserschlingen the pile fibers 7 position or integrate stationary, so that the pile fibers or Polfaserschlingen are clamped on both sides, namely once in the base layer 2 and the other in the functional layer 19. This clamping causes in a surprising way a high compressive elasticity of the nonwoven fabric. The pile fibers can only bend or buckle under the pressure load, but elastically spring back to their starting position when pressure is released. Even with long-lasting pressure loads the double-clamped pile fibers do not lose their elasticity, so that the nonwoven fabric has excellent resilience with high dimensional stability. In this case, the short pile fibers 8 can increase the resistance to the pressure load when the functional layer 19 strikes the pile fiber tips 11 of the pile fibers 8 when the functional layer 19 is arranged above the pile fiber tips 11. In the event that the functional layer 19 is seated on the pile fiber tips 11, the short pile fibers 8 increase the resistance to pressure loads and support the elastic springback.

However, the functional layer can also take on an additional task, namely if it contains functional agents, such as e.g. Contains moisture or liquid absorbent, or consists of a functional agent.

Preferably, the functional layer is applied by spraying. The application can also be done with a dip process.

Advantageously, the nonwoven fabric according to the invention is sprayed with a superabsorbent polymer, a so-called superabsorber. Superabsorbents are electrolyte networks that can absorb, store and desorb large amounts of fluid.

It is within the scope of the invention to provide nonwovens with more than two levels of pile fiber tips and the correspondingly different void volumes. It is also within the scope of the invention to provide instead of pile fibers Polfaserschlingen or pile fibers in combination with Polfaserschlingen, for example, in one layer of pile fibers and in another layer Polfaserschlingen be generated.

• Verdichtung des Faserflors 1:4 bis 1:10
• Schwinghub der Bürste 80 bis 70 mm
• Flächenmasse des Vliesstoffes 100 bis 800 g/m²

A textile fabric according to the invention can be produced, for example, by the so-called Kunit process. In this case, a nonwoven fabric with Faserpolstruktur on one side and with a fiber mesh structure on the other surface side is formed from a batt with longitudinally oriented or transversely oriented fibers. General data of the meshing of the batt inserted into the needle by a brush are:

• Compaction of the batt 1: 4 to 1:10
• Swing stroke of the brush 80 to 70 mm
• Basis weight of the nonwoven 100 to 800 g / m ²

By special adjustment of the compression and the swing stroke, the inventive structure of the nonwoven fabric for the spray application of functional agents can be achieved.

A further possibility for producing a nonwoven fabric according to the invention is a two-step process with production of a nonwoven consolidated by fiber or thread stitches with predominant transverse orientation of the fibers by cross-plating the card pile before mechanical consolidation by meshing (Malivlies) or over stitching (Maliwatt). Subsequently, in this nonwoven fabric having barb needles piercing perpendicular to the nonwoven fabric surface, the fiber pile layers or fiber pile structures are formed by discharging protruding fiber parts from the nonwoven fabric cross section. With this method it is also possible to use a longitudinally oriented batt.

The different heights and the different number of protruding fiber parts for forming the structure of the nonwoven fabric according to the invention is achieved by the number of needles and the type of needles, especially the distance of the needle tip to the first barb.

High compressive elasticity is achieved solely by the adhesive effect of the functional agents introduced into the receiving spaces 15 (Layer 19) on the long pile fiber threads in the area of the pole tips 9 achieved.

During a pressure load on the surface of the sheet, the structure deforms, whereby the short-pole fibers 8 sideways elastically, support each other due to a correspondingly high number per square centimeter and elastically spring back upon release of the compressive load. The long pole fibers 7 provide a considerable additional support because they are integrated into the base layer 2 and into the functional layer 19 and oppose a lateral pressure exerted by the short pole fibers 8.

The short-pole fibers 8 thus ensure a synergistic effect in that on the one hand they form a barrier against the penetration of functional agents and on the other hand form the cavity 15 for functional agents in combination with the long fibers and ensure compressive elasticity or pressure resistance of the fabric.

Likewise, the functional layer 19 can provide a synergistic effect. It ensures, on the one hand, the desired function, e.g. the desorption or desorption or odor binding or the like, and on the other hand, it forms by the integration of Langpolfasern 7 an elastic membrane-like surface, which ensures Drukkelastizität.

In addition, the surface of the functional layer 19 is relatively smooth so that the sheet is e.g. when used as upholstery fabric, can be pulled without additional lubricant on a cushion core. With conventional upholstery fabrics, an additional slip coating often has to be applied for this purpose.

The relatively smooth surface of the mesh layer of the base layer 2 is particularly well suited for lamination with a upholstery fabric.

Example 1:

For the fiber pile formation, a fiber blend of 60% polyester fibers with a fiber fineness of 3.6 dtex and a fiber length of 60 mm and 40% polyester fibers with a fiber count of 4.4 dtex and a fiber length of 36 mm is used. A double pile with a mass of 36 g / m ^{2 is} formed and meshed on a stitchbonding machine Kunit with a compression of 1: 8 and a swing stroke of the brush of 48 mm at a mesh fineness of 18 F.

The result is a voluminous nonwoven fabric with a basis weight of 280 g / m ² and a total thickness of 4.8 mm.

• Von der je Flächeneinheit im Vliesstoff enthaltenen Fasermenge sind 50% in den Fasermaschen angeordnet.
• Die der Vliesstoffdicke von 4,8 mm entsprechende Höhe H zuzuordnende Höhe h der Polspitzen 11 beträgt 3,2 mm. Damit ergibt sich ein Verhältnis der Höhe H zur Höhe h von 1,5 zu 1.
• Die Querschnittsfläche der für die Funktionsmittelanlagerung vorgesehenen Aufnahmeräume 15 errechnet sich bei einer mittleren Anzahl von langen Polfasern 7 von 7000 je cm² Vliessstofffläche zu 0,98875 cm² pro cm². Für die Querschnittsfläche der Zwischenräume 16 ergibt sich bei einer mittleren Anzahl kurzer Polfasern 8 von 9000 je cm² Vliesstofffläche ein Wert von 0,96085 cm² pro cm² Vliesstoff. Damit ist das Verhältnis der Querschnittsflächen der Aufnahmeräume 15 zu der Querschnittsfläche der Zwischenräume 16 1,021 zu 1.

Structurally, this nonwoven fabric is characterized by the following data:

• Of the per unit area contained in the nonwoven fiber amount 50% are arranged in the fiber meshes.
• The height h of the pole tips 11 corresponding to the nonwoven fabric thickness of 4.8 mm corresponding to height H is 3.2 mm. This results in a ratio of the height H to the height h of 1.5 to 1.
• The cross-sectional area of the receiving spaces 15 provided for the functional agent attachment is calculated to be 0.988875 cm ² per cm ² for an average number of long pile fibers 7 of 7000 per cm ^{2 of} non-woven fabric surface. For the cross-sectional area of the interspaces 16, with a mean number of short pile fibers 8 of 9000 per cm ^{2 of} nonwoven fabric surface, this results in a value of 0.96085 cm ² per cm ^{2 of} nonwoven fabric. Thus, the ratio of the cross-sectional areas of the receiving spaces 15 to the cross-sectional area of the spaces 16 is 1.021 to 1.

The pile fibers 7 are firmly embedded in a functional layer 19 of a superabsorber, which has a thickness of 1.2 mm. Before applying the functional layer 19, the permanent set was 40.5%. It lowered by the functional layer to 25%.

Example 2:

In another embodiment, the bulky nonwoven fabric consists of a cross-web nonwoven consolidated by fiber stitching which is then treated with long and short pile fibers with barb needles vertically piercing through the nonwoven cross section to achieve the particular pile fiber structure. In this case, also referred to as Malivlies nonwoven fabric consists of a fiber mesh bottom and in the nonwoven fabric cross section horizontally arranged fibers of polyester fibers with a fiber thickness of 3.3 dtex, the fiber length of 50 mm and he has a basis weight of 240 g / m ² , a thickness of 1.8 mm and a mesh size of 14 courses of 25 mm each and a mesh length of 1,6 mm. This Malivlies is then needled on two structuring needle machines with the following parameters: Machine 1: injection site
Needle type
penetration depth
stitch density Fiber mesh side
Crown needle 15 x 18 x 42 S 111
6 mm
600 stitches per cm ² Machine 2: injection site
Needle type
penetration depth
stitch density Fiber mesh side
Crown needle 15 x 18 x 42 S 111
11 mm
400 stitches per cm ²

This results in a voluminous nonwoven fabric having a lower-side base layer (2), which already had the Malivlies, and formed by needling a pile fiber layer of the short pile fibers (8) and from the long pile fibers (7). These pile fibers are arranged vertically by the vertical expulsion from the original web cross-section and vertically have a high height uniformity due to the selected needle.

The total thickness and thus height H is 3.6 mm, the height h is 2.4 mm and the thickness of the fiber mesh layer is 1.2 mm.

In the first needling passage, the short pile fibers (8) are arranged exclusively from the horizontally arranged fibers, with a density corresponding to the needle type and stitch density of 7200 pieces of fiber per cm ² . In the second needle passage, the expulsion of the long pile fibers (7) takes place in a density of 4000 fiber parts per cm ^{2 of} nonwoven fabric.

With the obtained heights, the ratio of H to h is calculated with a value of 1.5 to 1.

Cross-sectional area of receiving spaces = 0.9908 cm ² / cm ² material

Cross-sectional area Interspaces = 0.97424 cm ² / cm ² Material This results in a ratio of the two surfaces of 1.017 to 1.

Also in this example, the long pile fibers 7 are firmly embedded in a functional layer 19 of a superabsorber. The thickness of the layer 19 is 1.4 mm. Before application, the nonwoven fabric exhibited a permanent set of 38%. It was lowered by the functional layer to 26%.

The object of the invention is achieved by the non-textile functional layer 19, e.g. itself does not have to have elastic properties.

However, the functional layer preferably also has its own spring or rubber-like elasticity, which supports the elasticity of the elastic structure of the textile fabric.

According to a particular embodiment of the invention, the functional layer not only fulfills the fiber-binding function and not only may have inherent elasticity, but rather consists of a material which acts as a so-called functional agent. For example, the functional layer may have good seat climatic and / or clothing physiological properties, such as e.g. Water storage and / or water vapor absorption and / or water vapor permeability and / or air permeability and / or odor retention and / or odor formation (perfume) and / or heat conduction and / or thermal insulation.

As a rule, the functional layer 19 has thicknesses of between 1 and 4 mm, in particular between 1.1 and 3 mm.

The object of the invention is achieved not only by the use of a voluminous textile fabric, in particular in the form of a nonwoven fabric with different pile fiber lengths according to Fig. 1 , but also with fabrics, in particular in the form of nonwovens with a uniform Faserpolschicht. Appropriately, a Faserpolschicht should be present with a predominant share in it vertically to diagonally protruding from the base layer equal length fiber parts, which are held together in the upper part of the base layer farthest by the flat, connecting acting non-textile functional layer 19 with each other so that Although compression and compression of the nonwoven fabric in the area of the Faserpolschicht but not flipping the fiber parts of the Faserpolschicht with little repetitive effect occurs.

The high compressive elastic effect of such a flat fiber binding in the upper part of the Faserpolschicht results from the relatively thin, non-textile functional layer. Important for the good compressive elasticity is the fate of a certain free movable height of the individual fiber parts of the Faserpolschicht in the area between the base layer cross-section and underside of the non-textile Functional layer. In addition, it is favorable to attribute to this non-textile functional layer incorporating fiber subregions, due to a material selection, further processing and use-related properties, as described above.

The following examples illustrate the invention with reference to FIG FIGS. 2 to 6 when using bulky nonwovens with a high proportion of vertically to diagonally protruding Polfaseranteilen.

The Indian Fig. 2 The pressure elastic nonwoven fabric shown consists of the base layer 21 and the pile fiber layer 22. The pile fiber layer 22 has the vertical to diagonal protruding from the base layer 21 fiber parts 23 in the farthest from the base layer 21 area fiber ends 24 or fiber slices 25. The non-textile functional layer 26 arranged in this area of the fiber ends 24 or the fiber-part loops 25 binds them in such a way that the fiber parts 23 are not pressed into a horizontal position when compressive stresses occur but that they are pressed into the elastic structural part region 27 the Faserpolschicht 22 elastically absorb these compressive forces and after the elimination of the pressure load the Faserpolschicht 22 and the structural region 27 revert back to the starting position. The channel-like cavities 28, for example, in the elastic subregion 27 of the fiber pole layer 22 provide space for forwarding and / or storing gaseous or liquid media and space for storing non-textile, solid, particulate functional agents (not shown).

Example 3:

The in FIG. 3 A compressionally elastic nonwoven fabric shown schematically in cross-section consists of a Kunit nonwoven fabric of polyester fibers of fineness 3.3 dtex and with a fiber length of 90 mm. It has a mass of 380 g / m ² and a total thickness of 5.6 mm. In the Faserpolschicht 22 280 g / m ² fiber mass are included, with a thickness of the base layer 21 forming fiber mesh layer 29 of 1.2 mm, the Faserpolschicht 22 has a thickness of 4.4 mm. On top of the Faserpolschicht 22, a superabsorbent was sprayed, which thus forms the non-textile functional layer 26 and has a mass of 100 g / m ² and a thickness of 1.4 mm. In this non-textile functional layer, 80% of the free fiber dividend ends 24 and fiber dividing loops 25 contained in the fiber pole layer 22 are firmly bound. As a result of this incorporation according to the invention of fiber parts 23 of the fiber pole layer 22 into the non-textile functional layer 26, the pressure-elastic properties of the pressure-elastic nonwoven fabric with respect to the known Kunit nonwoven material change as follows: property Kunit nonwoven Inventive Druckelästischer nonwoven fabric Thickness (mm) 5.4 5.6 Compression hardness (kPa) 1.2 5.7 Pressure-elastic behavior as a30 - 5H% 21.0 45.5 as a30 - 5E3% 80.1 94.3 permanent deformation % 39.5 28.3

In addition to a significant improvement of the compressive elastic behavior by the flat surrounding the fiber parts 23 of the Faserpolschicht 22 contrary integration of the fiber parts 23 in the non-functional functional layer 26 results in nonwoven fabric construction according to the invention by the type and amount of non-textile functional layer 26, a substantial increase in water vapor absorption and moisture storage capacity than important functional properties for the use of the nonwoven fabric according to the invention as a climatically excellent padding component for vehicle seats. The corresponding test values are listed below: property Kunit nonwoven pressure-elastic nonwoven fabric according to the invention Water vapor transmission resistance (g / m ² Pa h) 0.11 0.16 Water absorption (%) 842 1890

Example 4:

The pressure-elastic nonwoven fabric according to the invention consists, as in Example 3, of a Kunit nonwoven fabric of polyester fibers with a fineness of 4.0 dtex and a length of 70 mm. It has a mass of 290 g / m ² and a thickness of 4.4 mm. In the Faserpolschicht 22 200 g / m ² fiber mass are included and this Faserpolschicht 22 has a thickness of 3.7 mm. The upper side of the Faserpolschicht 22 was bonded to a thermoplastic adhesive nonwoven polyolefin having a mass of 40 g / m ² , the resulting non-functional functional layer 26 binds at a thickness of 0.8 mm 2/3 of all free fiber ends 24 and fiber slices 25 firmly in itself and forms the pressure-elastic nonwoven fabric according to the invention. An increase in the elasticity characterizing values is achieved as follows compared with the known Kunit nonwoven fabric without a non-textile functional layer: property Kunit nonwoven pressure-elastic nonwoven fabric according to the invention Thickness (mm) 4.4 4.3 Compression hardness (kPa) 1.2 4.6 Pressure-elastic behavior as a30 - 5H% 23.2 30.1 as a30 - 5E3% 75.6 95.1 permanent deformation % 44.2 27.6

For this significant improvement of the compressive elastic behavior by the inventive construction of the pressure-elastic nonwoven fabric compared to a comparable Kunit nonwoven fabric comes through the thermoplastic sheet polymer layer of non-textile functional layer 26 formed of a special non-woven fabric, the possibility in the application of the non-textile functional layer 26 or in a subsequent operation Decorative textile or another textile or non-textile surface to stick. Thus, a separation force of 17.6 N / 5 cm width can be achieved.

Example 5:

The in FIG. 4 A compressively elastic nonwoven fabric shown schematically in cross-section consists of a nonwoven fabric, solidified by fiber stitching, having a basis weight of 155 g / m ² of polyester fibers of fineness 3.6 dtex and a length of 60 mm. By post-needling on a needle machine having vertically piercing fork needles, the fiber pole layer 22 has been formed with the fiber bundles 31 each containing free fiber dividend ends 24 and fiber dividing loops 25. The mass fraction of the Faserpolschicht 22 is 105 g / m ² and it has a thickness of 2.1 mm. Between the individual tufts 31 granular activated carbon particles 32 are embedded with a mass of 30 g / m ² . In a further operation, the non-textile functional layer 26 was applied, which is a water vapor-permeable polyurethane film with a basis weight of 80 g / m ² and a thickness of 0.7 mm. The pressure-elastic nonwoven fabric with the illustrated structure with the embedded functional particles of activated carbon 32 and the tufts 31 firmly integrating waterproof elastic non-textile functional layer 26 forms an excellent pressure-elastic and clothing climatic active component in the protective clothing manufacturing.

Example 6:

The in FIG. 5 A compressionally elastic nonwoven fabric shown schematically in cross-section consists of a Kunit nonwoven fabric of 60% polyester fibers with a fineness of 3.6 dtex and a length of 60 mm and 40% viscose fibers of fineness 4.2 dtex and a length of 80 mm. The nonwoven fabric has a basis weight of 510 g / m ² and a thickness of 6.2 mm. In the Faserpolschicht 22 360 g / m ² fiber mass are included, the Faserpolschicht 22 has a thickness of 5.4 mm. On top of the Faserpolschicht 22, a superabsorbent in liquid form was applied so that it forms on the one hand the non-textile functional layer 26 with a basis weight of 130 g / m ² and a thickness of 2.0 mm and on the other hand some of the upper part of the Faserpolschicht 22 protrude from the surface of the non-textile functional layer 26 at a height of 0.5 mm.

The viscose fibers which contribute to a proportion of 40% of the free fiber ends 24 and fiber part loops 25 projecting from the surface of the non-textile functional layer 26 form an additional vertical line for moisture towards or away from the non-textile functional layer 26. Depending on the position and function of the pressure-elastic nonwoven fabric introduced, for example, into a vehicle seat, this effect supports its climatic behavior in a very positive manner. The property improvements with regard to compressive elasticity and moisture transport that occur as a result of the nonwoven fabric construction according to the invention are detectable on the basis of the following determined property values: property Kunit nonwoven pressure-elastic nonwoven fabric according to the invention Thickness (mm) 6.2 6.4 Compression hardness (kPa) 3.2 6.5 Pressure-elastic behavior as a30 - 5H% 28.1 46.1 as a30 - 5E3% 86.7 94.7 permanent deformation (%) 39.5 28.4 Water vapor resistance (g / m ² Pa h) 0.10 0.16 Water absorption (%) 712 1383

The textile fabric according to the invention may be a nonwoven fabric made of fibers or filaments which has a pile surface of fibers or filament parts or fiber or filament loops protruding vertically or obliquely from the base layer. Such nonwoven fabrics are generally known, for example, as Struto, a non-woven fabric, as a Kunit stitch-bonded nonwoven fabric, or as needled, stitchbonded, or spun-bonded nonwoven velor needle-punched fabrics. However, a textile fabric according to the invention may also be a textile fabric of filament and / or fiber yarns as a pile fabric, pile knit or pile knitted fabric, all of which have a pile surface of vertically or obliquely extending from the base layer, substantially equal length yarn or fiber parts and / or yarn - or fiber loops. It may also be woven, knitted or knitted fabrics which have received this pile surface through an equipment process called roughing or velorizing by needling. The pressure-elastic textile fabric according to the invention can also be a flock material with a pile surface formed by flock fibers. Likewise, it may be called a tufting textile fabric whose pole surface of loops or cut Slings is incorporated into a textile or non-textile carrier from tufted fiber or filament yarns.

The following examples describe such textile fabrics of the invention.

Example 7:

This in FIG. 6 In the cross-section schematically illustrated pressure-elastic textile fabric consists of a 250 g / m ² heavy designated as Webvelour pile fabric 21a of polyester filament yarns. The pole layer 22 is formed by special weaving loops, which are formed by subsequent cutting to the vertically projecting filament parts 23. The thickness of the pile fabric referred to as Webvelour is 3.8 mm, while the pile layer has a thickness of 2.9 mm. The upper side of the pole layer 22 is then sprayed with a non-textile functional agent, for example of superabsorbent polymer, so that the free filament dividend ends 24 are firmly bound into the non-textile functional layer 26. This non-textile functional layer 26 has a thickness of 1.1 mm and a mass of 110 g / m ² . This inventive construction of a textile fabric with Polschicht 22 and applied non-functional functional layer 26 results in addition to the caused by the superabsorber of the functional layer 26 high moisture transport and high moisture storage a reduction of the original existing in textile fabric permanent deformation after close to normal pressure load by 65%.

Example 8:

The pressure-elastic textile fabric according to the invention consists of a polyamide filament yarn knitted fabric called Wirkvelour and has a basis weight of 190 g / m ² and a thickness of 3.0 mm. In the pile layer 22 formed from filament parts 23 are 120 g / m ² Filamentgarnmasse included and the Pol layer 22 has a thickness of 2.3 mm. The surface of the pole layer 22 is bonded with a polyamide adhesive film having a basis weight of 50 g / m ² so that this adhesive film with a thickness of 0.7 mm forms the non-textile functional layer 26 and thereby 85% of all free filament dividend ends 24 of Pol layer 22 firmly binds. This integration according to the invention in combination with the textile construction results in a high compressive elasticity and low permanent deformation in view of the use of the pressure-elastic textile fabric as a seat cushion component.

Claims (46)

1. Lofty, textile, multilayered fabric, in particular formed from a one-sidedly stitch bonded nonwoven, having a ground layer (2, 21) and at least one pile fibre layer (22) having first pile fibres and/or pile fibre loops (7, 24, 25) of essentially equal length which are anchored in the ground layer (2, 21) and project therefrom overwhelmingly perpendicularly to diagonally, characterized in that the first pile fibres and/or pile fibre loops (7, 24, 25) are bound in the region of their free end regions fixedly into an uninterrupted, non-textile functional layer (19, 26) or an adhesive fibrous sheet, the functional layer (19, 26) being spaced apart from the ground layer (2, 21).
2. Fabric according to Claim 1, characterized in that the functional layer (19, 26) contains a functional agent.
3. Fabric according to Claim 1 and/or 2, characterized in that the functional layer (19, 26) consists of a functional agent.
4. Fabric according to one or more of Claims 1 to 3, characterized in that the functional agent is a conventional absorbent of liquid.
5. Fabric according to Claim 4, characterized in that the functional agent is a conventional superabsorbent polymer in the form of an electrolyte network.
6. Fabric according to one or more of Claims 1 to 5, characterized in that the textile fabric is a nonwoven produced by the Kunit or Malivlies or Maliwatt process and comprising on one surface side of the ground layer (21) a fibre stitchbond structure (29) and on the other side a fibre pile structure layer (22) having fibres or fibre loops (23) erected from a fibrous web having longitudinally oriented and/or transversely oriented fibres.
7. Fabric according to one or more of Claims 1 to 6, characterized in that the functional agent is a conventional odour-binding agent.
8. Fabric according to one or more of Claims 1 to 7, characterized in that the functional agent is a conventional scent.
9. Fabric according to one or more of Claims 1 to 8, characterized in that the functional agent is a conventional heat-conducting agent.
10. Fabric according to one or more of Claims 1 to 8, characterized in that the functional agent is a conventional heat-insulating agent.
11. Fabric according to one or more of Claims 1 to 10, characterized in that the functional agent is a foam material.
12. Fabric according to one or more of Claims 1 to 11, characterized in that the functional agent is an elastic material.
13. Fabric according to one or more of Claims 1 to 12, characterized in that a granular functional agent is incorporated between the pile fibres and/or pile fibre loops (7, 8, 23).
14. Fabric according to one or more of Claims 1 to 13, characterized in that it has a multilayered construction and comprises a bottom-side ground layer (2), thereabove a pile fibre layer having second short pile fibres or pile fibre loops (8) and thereabove a pile fibre layer having the first longer pile fibres or pile fibre loops (7).
15. Fabric according to one or more of Claims 1 to 14, characterized in that the ground layer (2, 21) has a subface region (10) formed from areally consolidating fibres and/or thread stitches (4, 29).
16. Fabric according to one or more of Claims 1 to 15, characterized in that the ground layer (2, 21) comprises essentially fabric plane aligned fibres and/or fibre sublengths (2).
17. Fabric according to one or more of Claims 1 to 16, characterized in that the pile fibres and/or pile fibre loops (7, 8, 24, 25) are retained in the ground layer (2, 21) by anchoring regions (5, 6) and protrude from the cross section.
18. Fabric according to one or more of Claims 1 to 17, characterized in that the pile fibres and/or pile fibre loops (7, 8, 24, 25) project essentially perpendicularly and/or obliquely from the ground layer (2, 21).
19. Fabric according to one or more of Claims 1 to 18, characterized in that the pile fibres or pile fibre loops (7, 8, 24, 25) are laterally spaced apart.
20. Fabric according to one or more of Claims 1 to 19, characterized in that the first pile fibres (7, 24, 25) have at least overwhelmingly an identical pile tip height H for the pile tips (9), measured from the subface (10).
21. Fabric according to Claim 20, characterized in that the pile tips (9) lie in one face plane (12).
22. Fabric according to one or more of Claims 14 to 21, characterized in that the second pile fibres (8) have at least overwhelmingly an identical pile tip height h for the pile tips (11), measured from the subface (10).
23. Fabric according to Claim 22, characterized in that the pile tips (11) lie in one face plane (13).
24. Fabric according to one or more of Claims 20 to 23, characterized in that the ratio of the height H of the first pile fibres or pile fibre loops (7) to the height h of the second pile fibres or pile fibre loops (8) is between 1.2 and 1.
25. Fabric according to one or more of Claims 1 to 24, characterized in that reception cavities (15, 28) are formed between the first pile fibres (7, 24, 25).
26. Fabric according to one or more of Claims 1 to 25, characterized in that the fabric is 3 to 20 mm and especially 5 to 12 mm in thickness.
27. Fabric according to one or more of Claims 1 to 26, characterized in that at least 200 first pile fibres (7, 24, 25) stand upright in the pile fibre layer per square centimetre of nonwoven surface.
28. Fabric according to one or more of Claims 1 to 27, characterized in that the nonwoven contains up to 25% by mass of thermoplastic bonding fibres.
29. Fabric according to one or more of Claims 1 to 28, characterized in that the nonwoven mass is 100 to 800, especially 200 to 600 g/m².
30. Fabric according to one or more of Claims 1 to 29, characterized in that the fibre pile layer (22) contains a fibre mass of 250 to 350, especially 270 to 320 g/m².
31. Fabric according to one or more of Claims 1 to 30, characterized in that the functional layer (26) has a mass of 80 to 120, especially 90 to 110 g/m².
32. Fabric according to one or more of Claims 1 to 31, characterized in that at least 80% of the free fibre subends (24) and/or fibre subloops (25) contained in the fibre pile layer (22) are firmly bound into the functional layer (26).
33. Fabric according to one or more of Claims 1 to 32, characterized in that the pile layer (22) contains 40 to 50% of the textile mass contained in the entire textile fabric.
34. Textile fabric according to one or more of Claims 1 to 33, characterized in that the thickness of the non-textile functional layer (19, 26) is not more than 50% of the thickness of the pile layer (22).
35. Fabric according to one or more of Claims 1 to 34, characterized in that at least 50% of the free fibre subends (24) and/or fibre subloops (25) contained in the fibre pile layer (22) are bound into the non-textile functional layer (26).
36. Fabric according to one or more of Claims 1 to 35, characterized in that the non-textile functional layer (26) consists of a thermoplastic polymer or a thermoset polymer or of polyvinyl chloride having a fibre surface binding effect.
37. Fabric according to one or more of Claims 1 to 36, characterized in that the free fibre subends (24) and/or the free fibre subloops (25) of the fibre pile layer (22) protrude from that surface side of the non-textile functional layer (26) which is remote from the ground layer (21), preferably to a height of not more than one third of the height of the fibre pile layer (22).
38. Fabric according to one or more of Claims 1 to 37, characterized in that it consists of a nonwoven composed of fibres which has a pile surface composed of pile fibre portions or pile fibre loops projecting vertically to obliquely from the ground layer, and preferably is a vertically lapped nonwoven or a stitch-knitted nonwoven or a postneedling-velourized needled, stitch-knitted or spunbonded nonwoven.
39. Fabric according to one or more of Claims 1 to 38, characterized in that it is a woven or knitted pile fabric having a pile surface composed of yarn or fibre portions and/or yarn or fibre loops projecting vertically to obliquely from the fabric cross-section.
40. Fabric according to one or more of Claims 1 to 38, characterized in that it is a flocked fabric, having a pile surface formed by flock fibres, or is a tufted fabric whose pile surface is formed from pile fibre loops or cut pile fibre loops which has fibrous or filamentous yarns tufted into a textile or non-textile backing.
41. Process for producing a textile fabric according to one or more of Claims 1 to 38, characterized in that a fibrous web comprising longitudinally oriented and/or transversely oriented fibres is used to form a nonwoven having a fibre pile structure on one top side and a fibre stitchbond structure on the other top side, by using a brush to sweep fibre material into a sliding-tongue needle for stitchbonding and to effect a densification of the fibrous web in the range from 1:4 to 1:10, wherein the first pile fibres and/or pile fibre loops (7, 24, 25) are bound in the region of their free end regions fixedly into an uninterrupted, non-textile functional layer (19, 26) or an adhesive fibrous sheet, the functional layer (19, 26) being spaced apart from the ground layer (2, 21).
42. Process according to Claim 41, characterized in that a nonwoven having a basis weight of 100 to 800, in particular 200 to 600 g/m² is produced.
43. Process according to Claim 41 and/or 42, characterized by a two-step process whereby a nonwoven consolidated by fibre or thread stitches and having predominantly transversal or longitudinal orientation of the fibres of the card web before mechanical consolidation is produced and subsequently is treated with barbed needles perpendicularly to the nonwoven surface to form the different fibre pile layers by ejecting projecting fibre portions from the nonwoven, the different heights and also the different numbers of projecting fibres to form the novel nonwoven structure being created by the number and type of ejecting needles, which is preferably achieved by a predetermined distance from the needle tip to a first barb.
44. Process according to one or more of Claims 41 to 43, characterized in that at least one functional agent is sprayed onto and/or into the pile fibre layer comprising the pile fibres (7, 24) or pile loops (25) and consolidated.
45. Process according to Claim 44, characterized in that a superabsorbent solution is applied by spraying and polymerized.
46. Use of a textile fabric according to one or more of Claims 1 to 40 as cushion fabric.

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