EP1771619A1

EP1771619A1 - Dressings which can be applied several times to textile fibres and textile fabrics

Info

Publication number: EP1771619A1
Application number: EP05759681A
Authority: EP
Inventors: Oliver Marte; Walter Marte; Stefan Angehrn; Martin Meyer; Ulrich Meyer; Urs Von Arx; Ruth Weber; Oliver KÜNZI; Cédric CLIVAZ; Martin Hochstrasser
Original assignee: Schoeller Textil AG
Current assignee: Schoeller Textil AG
Priority date: 2004-07-20
Filing date: 2005-07-18
Publication date: 2007-04-11
Also published as: TWI279226B; KR20070035090A; US20080044580A1; JP2008506865A; WO2006007753A1; TW200612871A

Abstract

The invention relates to formulations for dressing, dressing layers, dressed textile fibres and textile fabrics and method for dressing textile fibres and textile fabrics. The textiles produced according to said invention can receive, a plurality of times, active substances, or active ingredients, and, according to the applicational function, can be deposited in an isotropic manner to the surrounding medium or in an anisotropic manner in a directly adjacent layer by means of a locally oriented material flow. The dressing layers are characterised by the swellability thereof and their capability of receiving active substances. The polymer layers form nano pockets during swelling which can receive one or several guest molecules. The active substances are released and desorbed whilst carrying the dressed tissue, are assisted by body heat, humidity, friction and movement. Counter to known intelligent biotextiles' based on cyclodextrine, it is possible, according to the invention, to apply an essentially wider spectrum of active substances to the textile surfaces a plurality of times. Said active substances can be deposited when the loaded textiles are carried and can be absorbed by the skin of the carrier, cutaneously or percutaneously, and they produce the desired effect on the destination point.

Description

Reloading equipment on textile fibers and

fabrics

The present invention relates to finishing formulations and reloadable finishes on textile fibers and fabrics, and to a method of finishing textile fibers and fabrics having such functional layers. Likewise, the present invention relates to the textile fibers and sheets treated by the method according to the invention with repeatedly loadable equipment.

The market for coated or finished textiles is arguably the fastest growing market within the textile sector today. The functionality of coated or finished textiles is becoming ever more stringent, but at the same time, stricter environmental and consumer protection requirements are increasingly limiting the range of chemicals available. Suppliers are thus required to create new products that offer new and / or improved functionality with a limited range of precursors. Numerous coatings are known from the literature and practice which influence and improve the surface properties of textile fabrics in terms of dirt repellency, water and / or oil repellency, UV resistance, abrasion resistance and chemical resistance. In all these functions, the emphasis is on protecting the wearer of the textile product from one or the other external influence, ie to keep substances away from the body of the wearer. The term "intelligent textiles" is already known today for body-worn textiles with coatings / finishes which allow clothing to be provided with therapeutic or cosmetic active substances which are released to the skin of the wearer when being worn or released from the equipment commercially interesting active ingredients is widely available, ranging from cortisone in ointments for eczema patients via nicotine for the withdrawal of smokers to anti-wrinkle creams in skin creams The continuous supply of the skin with painkillers, hormones, vitamins or sunscreen over such intelligent bio-equipment has already been It is also known that the production of unpleasant-smelling sweat odor can be prevented by antibacterial substances in textiles such as underwear, socks, sportswear or shoes.

Active substances and active substances are to be understood below, where not specified, as pharmaceuticals and wellness substances. The former, as defined in the Pharmaceuticals Act, are substances and compositions of substances which, through applications on or in the human or animal body, serve to heal, alleviate, prevent or detect diseases, ailments, bodily injuries or pathological complaints. Wellness substances are substances that serve to increase the complete overall well-being in all physical and mental areas of life and to bring body, mind and soul into harmony with nature. Wellness substances are to be understood below as cosmetics. Some pharmaceutically active substances, both from "natural medicine" and from conventional medicine, which according to the above classification belong to the medicinal products and their respective field of application are listed below:

Motion sickness: scopolamine, cinnarizine, meclozin; Smoking Weaning: Nicotine; Venous problems: heparin;

Hay fever: antihistamines such as cetirizine; Muscle / Joint Pain: Diclofenac; and angina pectoris: glycerol trinitrate.

Textile finishing essentially knows two different ways to make smart equipment. On the one hand, loadable cage molecules, such as cyclodextrins or dendrimers, are applied to the surfaces to be coated, or polymeric binder systems mixed with the respective active compounds (for example polyacrylates or polymethanes) are applied to the textile substrate. The layers functionalized with cage molecules are repeatedly loadable, in contrast to the layers whose coating compositions are applied as ready-made mixtures of polymer binders and active substances in the context of fabric finishing as a finishing agent.

Both said production methods show disadvantages, which mainly relate to the purpose of the application, namely the functionality of the finishing layers to be produced.

The range of application of the layers produced with cage molecules is severely limited by the molecular size and geometry as well as by the limited selectable affinity for the substances to be stored. The cyclodextrins, for example, are oligosaccarides of 6 to 8 glucose units having a hollow body structure with the polar OH groups on the outside and hydrophobic inside. It follows that only small lipophilic active substances can be stored and Thus, the objective and universality of cyclodextrin-containing equipment are severely limited. As a result, cage molecules already loaded with active substances are usually added to the finishing liquors and applied to the fabric by the textile finisher. Due to the predetermined functionality and the predetermined intended use of tissue equipped in this way, only very limited quantities are produced in order to minimize the sales risk. This makes the products very expensive and the range of products remains small. The advantage of layers made with "cage molecules" over polymeric binder systems is their reloadability, depending in part on the equipment used, after any washing operations of the garment concerned. Such a reloadability is not given in the application of directly mixed with active substances polymeric binder systems. Here, the functionality-determining chemicals or active ingredients are applied to the fabric during the finishing process and then usually thermally fixed. Already during this fixing process, a large part of the desired function is lost. Among other things, the active ingredients are thermally decomposed or altered, bound or decomposed by reaction with the fixing agents or they evaporate and are removed with the heating medium (for example with the exhaust air). The remaining active substance on the fabric determines the functionality for only a limited period of use of the garment in question, since so produced wellness layers are not washable and not reloadable. Due to the disadvantages described in this way functionalized fabrics find only a very limited market and hold a high sales risk for the textile finisher in itself. The object of the invention is to provide equipment formulations, reloadable finishes, finished textile fibers and fabrics, and processes for finishing textile fibers and fabrics which do not have the disadvantages of the products and processes available on the textile market.

This task is being solved by new finishing formulations, new finishing techniques, new equipment and textile fibers and fabrics provided with the new finishes. Specially selected chemicals, some of which are unusual for the textile industry, allow, inter alia, the following to be achieved: i) the new equipment can be loaded several times, for example after prolonged use or after washing a corresponding garment, with different substances and the combination of two separately controllable ones Functionalities in a textile fabric equipped according to the invention are made possible; ii) functional surfaces (guest / host systems) are realized on textile fabrics which make it possible to take up predominantly lipophilically dominated active substances as guest substances and to apply them isotropically to the surrounding medium or anisotropically by a locally directed material flow into an immediately adjacent one Shift again.

For the realization of the inventive equipment, both existing and new processes for textile finishing are applicable, such as, for example, the UV curing of the finish formulations applied to the textiles.

The inventive equipments can be used as drug delivery coatings, ie as so-called "drug delivery Systems ", and / or designed as pollutant uptake coatings and used.

An essential feature of the invention is the application of equipment or finishing layers to textile fibers or fabrics which, following the guest / host principle, represent a host system which is as widely applicable as possible and which can be temporarily loaded several times with the most varied active substances or guest molecules. The host layer applied by the textile refiner is the carrier of the guest molecules, which can be applied, for example, by the customer himself. The customer (for example, the clothing manufacturer, the chemical cleaner or the carrier) can therefore determine the functionality of the respective textile or garment itself usually. This is made possible by the use of crosslinkable polymer binders in combination with crosslinkable spacer substances, the use of a surfactant (emulsifier, dispersant or mixtures thereof) and a general, multifunctional crosslinker, as well as the use of any catalysts. A finishing layer consisting of such chemicals forms after fixation on the fiber or the tissue surface the host system necessary for the absorption of the active substances. Essential to the understanding of the present invention is the swellability of the equipment produced. The use of preferably lipophilically modified polymer compounds and crosslinkable "tentacle" or spacer molecules results in a polymer layer which can be swelled by polar protic and / or polar aprotic substances. Upon swelling of this polymer layer, stochastic nanotubes (spatial dimensions depending on molecular sizes, depending on the spacers used) form in the finish layer. These nano pockets can be one or more Include guest molecules, since they are adaptable in their spatial structure and their polarity to the molecular sizes of the guests to be recorded. The nanotags preferably have a size of at most 500 nanometers. The one or more guest substances, ie the ingested active substances, are released and desorbed again during the wearing of the tissue thus treated, supported by body heat, moisture, friction and movement. Depending on the type of active substance, they can be absorbed by the skin of the wearer, for example, cutaneously or percutaneously and develop the desired effect at the destination.

The simultaneous use of crosslinkable surface-active substances achieves a spatial, thermodynamically induced self-organization of the finishing components, which on the one hand determines the affinity of the layer for the majority of lipophilic active substances and, on the other hand, the physiological behavior of the finishing layer relative to human skin.

Immediately after making the finish layer, the nano pockets in the non-swollen finish layer are in a so-called collapsed form. The formation of the nanotags which are potentially present after fixing the equipment takes place only in contact with moisture and the substances to be sorbed, or the substance mixture to be absorbed, which in a preferred embodiment may be an aqueous emulsion of the active substance to be sorbed or of a mixture of active substances. Both the proportions and the choice of the polymer layer forming chemicals are control parameters of the active substance absorption and Abgäbe by the finishing layer. In addition to the nano pockets, the finishing layers according to the invention can be provided with micropores and / or mesopores as further structures. For this purpose, during the preparation of the finishing formulation, for example, CO ₂ or N ₂ -releasing substances are added and / or non-reactive, evaporable solvents are added. The release of gas or the escape of the non-reactive solvents gives rise to micro or meso capillarity (percolation clusters) during drying and / or fixation in the finishing layer, the size of the micro- and mesopores being in the range from 1 to 25 μm. The highly enlarged active surface in this way considerably influences the sorption or desorption behavior of the active substances to be applied.

Another essential feature of the functional equipment produced in this way is the repeatedly feasible loading of the finishing layer and its dynamic, adapted to the active substances, formation of the nanotags. This function is primarily determined by the type and concentration of spacer substances present in the finishing layer.

An additional functionality of the equipment according to the invention is achievable by admixing cage molecules for equipment formulation or by the separate application of the cage molecules to the textile already provided with a novel, reloadable textile provided with nanopockets in the polymer layer. In addition to the known cyclodextrins, the β-glucan and zeolites are specifically mentioned. Ss-glucan is a polysaccharide structural polymer, which is produced as a waste product in yeast processing. After purification of the glucan product from fat and protein substances, the glucan should be used as a cage molecule. Zeolites are hydrous framework silicates which on the one hand can accommodate various cations in their lattice structure and, on the other hand, guest molecules in the interstices of the zeolite particles.

The differentiation of the two host systems (dynamic formation of nano pockets and cage molecules) with respect to the uptake of different active substances takes place on the one hand by the component ratio of the finishing layer forming the nano pockets and on the other hand by the functional and constitutional properties of the cage molecules used and their interaction with the finishing components. For example, the charge dominance (anionic, nonionic, cationic) of the cage molecules, in interaction with the equipment used, influences their receptivity to active substances. These parameters determine the sorption or desorption properties that are more important for the guest molecules, such as polarity, affinity, geometric and spatial structures, etc.

Essential to the formation of the nano-pocket structure of the host system are the proper choice of finishing chemicals and their mixing ratio, as well as the drying and fixing conditions directed to the host-forming chemicals. The chemicals that form the host are mixed in a first step into a finishing liquor or finish formulation. For this purpose, a polymer compound is presented as a main component at least, which is preferably emulsified in water acrylic, epoxy or urethane polymer of a crosslinkable modified fat (C ₂ to C _8). Then be Chemicals as a spacer mixed, on the one hand contain molecular "tentacles" with at least one terminal reactive group and on the other hand take on spacer functions. The chemical constitution of the molecular "tentacles" or spacers includes, for example, polyether chains, preferably polyoxyethylene, polyoxypropylene, block polymers, and / or C ₂ to Cia chains with, for example, terminal hydroxyl, amino, carbonyl, carboxyl, acid amide, Isocyanate, N-methylol or methoxy-N-methylol functions (α-aminoalkylation products).

As a further component, the finishing liquor is preferably added with at least one multifunctional synthetic resin compound as crosslinker (α-aminoalkylation products such as, for example, methoxylated ethyleneurea or melamine compounds), which decisively determines the washing resistance, swellability and nano-pocket structure of the finishing layer.

As the crosslinking of the ingredients, catalyzing substances are added to catalysts, e.g. Magnesium chloride, mono- and polycarboxylic acids or esters as acid-releasing compounds.

To control the affinity and physiological behavior of the finish layer, a surfactant or mixture of surfactants is incorporated into the liquor. As surface-active substances are typically anionic and non-ionic substances such as glyceryl citrates, glyceryl laurates, fat-modified sorbitan derivatives (for example Span and Tween series emulsifiers), cetaryl glucosides, polyglyceryl oleates, polyglyceryl stearates and siloxane poly glycol ethers and / or Siloxanpoly-Glucoside used whose HLB (Hydrophilic Lipophilic Balance) in the range of 3 to 15 are.

The use of gas-releasing (CO ₂ and N ₂ as propellant gases) and acting on the finishing layer, non-reactive substances is facultative and targeted, for example, when high host loadings and high Abgabegeschwindgkeiten are required. This objective is closely related to the sorption and desorption of undesirable odor substances. In order to obtain a desired microporous / mesoporous percolation structure of the finishing layer, organic CO ₂ and N ₂ releasing propellant gas substances (for example acetoacetic acid, 2,2'-azobisisobutyronitrile, 2,2'-azobis (2-methylpropane), inorganic CO ₂ releasing substances (eg sodium bicarbonate in combination with acid-releasing catalysts) and polar, non-reactive, propellant solvents (eg ethyl acetate, methyl glycol acetate, diglycol dimethyl ether) whose boiling point is between 60 and 200 ⁰ C, preferably at 120 ⁰ C, added.

In a second process step, the finishing liquors containing the host chemicals are applied to the textile material using industry-standard application techniques such as padding, coating or spraying. In order to increase the washing permanence of the HostSystem, reactive-group-containing adhesive layers, also called primer layers, can be applied beforehand, especially with synthetic fiber materials. Such primer layers are known, for example, from WO 01/75216. The application of primer layers is a process stage upstream of the application of the host layer. Depending on the intended use of the host layer-bearing tissue can by applying applicator systems such as patting two different acting host layers are applied, which differ, for example, by their affinity (more or less lipophilic).

The third important for the formation of the nano-pocket structure process step is the drying of the impregnated fabric (residual water content up to 30%), and subsequent fixing of the finishing layer, both according to one Trockenfixierverfahren (at 120 to 180 ⁰ C) and for a Feuchtfixierverfahren (at 15 to 40 ⁰ C) can be performed. The drying of the finished fabrics is carried out at temperatures between 50 and 150 ⁰ C for 30 to 180 seconds in industry-standard units such as tenter or Hotflue. When fixing the finishing layer, it is preferred to use thermal and / or UV-emitting reactors, depending on the polymer / crosslinker system used. The thermal fixation is carried out at temperatures between 120 and 200 ⁰ C, preferably at 140 to 160 ⁰ C and reaction times of 1 to 5 minutes. When using UV-curing polymers reaction times of 0.5 to 60 seconds, preferably from 1 to 3 seconds are necessary depending on the polymer type and radiation power of the reaction unit. The big advantage of the use of UV-curing polymers is the wash-resistant layer fixation on the textile substrate which can be carried out at low temperatures. As a result, an active substance loading of the functional layer in combination with the application of the layer-forming chemicals is made possible even without the usual thermal decomposition reactions and / or the evaporation of the guest substances.

The following examples illustrate, by means of selected examples, preferred finishing formulation, production the nanosheet-forming finish layers according to the invention and their efficiency with respect to the desired functionality.

Example 1: Equipment layer for formation of nanostructured percolation clusters

A pre-cleaned and bleached cotton blended fabric (75% Co, 25% PES) with a grammage of 210 g / m ² is impregnated with a finishing liquor whose components form nanosheets, that is nanostructured percolation clusters, during the drying phase of the fabric. The nano-pockets containing tissue coating can be used both as a reloadable drug delivery system and as a pure sorbent layer, for example, for undesirable odors.

The finishing formulation applied to the fabric surface has a mass fraction based on tissue dry weight of 11%. After impregnation of the fabric with the liquor containing the equipment components, fabric drying is carried out at 120 ^° C. for 120 seconds.

The finish formulation contains the following components:

Table 1: finish formulation according to Example 1

Dicrylan AS is an aqueous 40% acrylic dispersion sold by the company ERBA and, in combination with the other formulation components, gives a soft, skin-friendly coating. Glucan P20 is a cross-linkable propoxylated glucose and serves as a spacer for the formation of the nanoparticles which forms the host system for the later-to-be-applied active agents (guests). Lyofix CHN is a resin crosslinking component (partially etherified hexamethylol melamine resin) which, in combination with the other formulation components and the catalyst (MgCl ₂ ), gives a wash-permanent fabric coating. The fixation of the layer takes place at 150 ⁰ C for 3 minutes.

The layer produced in this way is able, when immersed in an aqueous emulsion containing the active substance or the active substances, to form the nanostructured percolation clusters loaded with active substance (s).

Example 2: Nano pockets with dynamic adaptation to the guest substances

On a boiled and bleached blended fabric, consisting of 30% cotton and 70% polyamide, weighing 165 g / m2, an impregnation is applied to a finishing formulation, hereafter referred to as coating material, which the host system applies to the fabric after fabricating Guest substances (ie the active substances) represents. The fixed on the Faser¬ surface equipment has a mass fraction of 8% based on the dry weight of the untreated fabric. After impregnation of the mixed fabric with the coating mass containing finishing liquor, the fabric for 60 seconds at 130 ⁰ C dried and the forming during drying, fixes the nano equipment bags containing layer at 150 ⁰ C during 180 seconds. The impregnation liquor contains the following components:

Table 2: Equipment formulation according to Example 2

Subitol ES (Bezema AG) is a wetting and padding aid based on anionic surfactants.

DICRYLAN AS is a chemically / thermally crosslinkable nonionic polyacrylate dispersion for the aqueous coating of textile fiber materials. Pluriol P 600 (BASF) is a polypropylene glycol with an average molecular weight of about 600 g / mol and is used both for foam damping and the solubility, the polarity change and the consistency change. LYOFIX MLF (ERBA) is a non-ionic, relatively low-formaldehyde, partially etherified hexamethylol melamine resin for dimensionally stable equipment on cellulose and its blends with synthetic fibers. Compared to conventional melamine-based crosslinkers, it has a lower formaldehyde content and a high buffer effect and leads to good washing and ironing shrinkage values, good primary effects and very good permanences. The finishing layer resulting from the use of this equipment liquor, after exposure to an aqueous emulsion containing 20% isooctanol for twelve hours as a model substance for lipophilic wellness substances, shows an octanol uptake of up to 16% based on the layer composition. After three times loading and extraction of the finish layer with a 50% water / ethanol solution, the originally observed 16% octanol uptake could be reproduced again.

This experiment has shown that the repeated loading of the finishing layer with lipophilic substances, which can even be carried out by the end user, allows them to choose the functionality of the finishing layer according to their needs.

Example 3: Functionalized Nano-pocket Equipment for Eczema Patients

An existing polyester and Lycra knit with a weight per square meter of 230 g is freed of fiber preparations before dyeing by a chemical cleaning process and then dyed. On the dyed and dried knit is by a single-application application system

(Tatting technique) applied on the back of the knitted fabric and later garment a coating mass, which as

Host system is capable of lipophilic active substances such as

Example Phenolkarbonsäuren an oregano or

Velvety root extract, farnesol or gamma-linolenic acid

(Evening primrose oil) as a guest record. The functionality of the finishing layer is determined only by the wearer of the garment by the choice of the applied agent. In the case of the oregano and velvet root extract, it is the fungicidal and bacteriostatic, in farnesol it is only the bacteriostatic effect, while in the case of evening primrose oil, the itching on the skin caused by atopic dermatitis is alleviated. The production of the nano pockets containing coating layer is carried out by the Gewirkimpprägnierung with the equipment described below, drying at 120 ⁰ C for 80 seconds and the subsequent fixation at 160 ⁰ C for 180 seconds. The weight of the applied finish layer is 12% based on the dry weight of the fabric. The layer components and their concentrations are listed below. Table 3: Equipment formulation according to Example 3

Invadin PBN (ERBA) is a surface-active preparation of ethoxylated fatty alcohol and aliphatic ether alcohol and serves as a special wetting agent for water- and oil-repellent equipment.

Perapret HVN is an anionic thermally crosslinkable polyacrylate dispersion offered by BASF for the finishing of woven or knitted fabrics made of cellulose fibers and their blends with synthetic fibers.

Pluronic PE 3100 is a BASF product made by the copolymerization of propylene oxide and ethylene oxide and is used as a low-foaming surfactant. Drapal GE 202 (Akzo Chemie) is a partially esterified, branched carboxylic acid copolymer with hydrophobic alkyl and hydrophilic ether groups with emulsifying properties. LYOFIX MLF (ERBA) is a non-ionic, relatively low-formaldehyde, partially etherified hexamethylol melamine resin for dimensionally stable equipment on cellulose and its blends with synthetic fibers. Compared to conventional melamine-based crosslinkers, it has a lower formaldehyde content and a high buffer effect and leads to good washing and ironing shrinkage values, good primary effects and very good permanences. The loading of the finish layer prepared according to the above specification with an aqueous emulsion containing oregano or velvetroot and farnesol was carried out by spraying the fabric side bearing the coating layer on one side. After twelve hours of exposure, a knit section was subjected to delicates and dried. Subsequently, one each containing the active ingredients and washed and an untreated knitted section was placed on a fungus-infected agar gel and left for three days in a climatic chamber at 30 ⁰ C.

The untreated knit section was largely overgrown by the fungal culture after three days, while the knitted fabric section carrying the equipment and loaded with velvetroot extract and farnesol completely stopped fungal growth on the agar layer covered by the test piece by the desorption of the active substances.

This example demonstrates the loading of the host layer and the desorption of the fungicidally and bacteriostatically effective guest substances in this case.

Example 4: Equipment with Odor Absorbing Effect

A blended fabric consisting of 30% cotton and 70% polyester is dyed and dried after it has been pre-cleaned. The functionalization of the tissue surface is effected by the application of a finishing layer of the composition listed below: Table 4: Equipment formulation according to Example 4

Subitol LS-N is an anionic low foaming wetting agent based on a synergistic surfactant mixture and will be marketed by CHT in Tübingen.

Methocell 311 is a cellulose ether from DOW Europe

S.A.

Knittex FPC (ERBA) is a nonionic reactant crosslinker based on a modified glyoxal crosslinker for the low-formaldehyde, cook-wash-resistant easy-care finish of cellulosic articles and blends thereof.

Knittex catalyst MOF (ERBA) is a liquid magnesium salt-based acid donor, which is preferably used for the refining of cellulose articles.

Azobisisobutyronitrile is used as the N ₂ -splitting propellant.

The chemicals contained in the equipment fleet on the one hand, the formation of a for the absorption of lipophilic

Suitable nano pocket structure and polarity, and on the other hand, for rapid sorption and desorption of the

Sorbents necessary layer porosity ensured. to

To produce the functional layer, the fabric is impregnated with the equipment liquor described above (liquor pick-up 80

%) and dried at 110 ⁰ C for 180 seconds. The Layer fixation is carried out by the subsequent at 150 ⁰ C and 3 minutes lasting condensation on a tenter. To prevent the usual bacteriological infestation of the sorbed substances, the finishing layer is loaded with a little farnesol (about 2% by weight of the finishing layer).

The equipment described in Example 4 is used after loading with farnesol the sorption of odor-intensive substances, such as occur for example in restaurants or restaurant kitchens. The workwear provided by the equipment according to Example 4 for restaurant personnel or such ladies' or men's outerwear shows no odor nuisance even after three days of use. The described properties of the odorant sorption by the farnesol are retained even after repeated washing of the garments, the garment or the finish layer having to be loaded again with farnesol after each wash.

Example 5: Bi-component kit with nanopockets and cage molecules

An existing 100% polyamide knit fabric is dyed and dried after the removal of Faseravivagen. Subsequently, in a first step, the impregnation of the knitted fabric with the chemicals forming the nanosheets and the drying of the knitted fabric at 120 ⁰ C for 2 minutes. In a second method step, a suspension containing an anionic carboxylated glucan (cage molecule) is applied by unilateral patting, the cage molecule being previously loaded with a silver complex has been. This was followed by drying and chemical fixation of the two host systems (nano pockets and cage molecules), whose functionalities differ due to the different charge dominance (non-ionogenic nano pocket host and anionic cage molecule host). The applied to the knit nano-pockets forming composition is 10% and that of the loaded glucan 1% based on the untreated knitted fabric. The ingredients of the seasoning liquor, which is applied in a first process step with a residual moisture content of 72%, are listed below:

Table 5: first finish formulation according to Example 5

BERMOCOLL E 230 FQ (Akzo Nobel) is a nonionic water-soluble cellulose ether (low viscosity grade of ethyl hydroxyethyl cellulose) that increases the consistency and stability of waterborne products. Pluronic P 3500 (BASF) is a block polymer of polypropylene glycol and ethylene oxide and is mainly used as a nonionic surfactant.

The glucan suspension, which is applied in the second process step on one side on the later support side of the garment by patting is composed as follows: Table 6: glucan-containing second finish formulation according to Example 5

The present equipment corresponds to a multifunctional layer for close-up clothing items whose wearers have dry, flaky or slightly infective skin. It has the pronounced bactericidal function of the silver-loaded glucan cage molecules and, in addition, via the active ingredient loading of the nanotags, the skin is greased and moistened and a bacteriostatic effect is achieved. For this purpose, the functional layer containing the nano pockets was loaded with an aqueous emulsion containing linseed oil, urea, gamma-linolenic acid and farnesol for twelve hours and the release was examined for several days on a gel simulating the human skin. After a four-day desorption of the mentioned active substances in a Franz diffusion cell, only about 17% of the active substance mass originally present in the nanosheet structure could be detected. The remaining 83% of the active substance mass was, as expected, in the diffusion gel simulating the human skin. Due to the described multifunctionality of the finishing layer, their use for close-up clothing of atopic dermatitis patients is almost ideally suited. Example 6: Further bi-component equipment with nanopockets and cage molecules

An existing 100% polyamide fabric is dyed after its pre-cleaning, rinsed and subjected to an after treatment with tannin. The dried knit fabric is equipped in a first step analogous to Example 5 with the nanoparticles forming chemicals. In a subsequent process step, a suspension of a silver zeolite is sprayed on. The following drying and condensation fix the two host systems (nano pockets and silver zeolites) on the fabric. The order quantities were selected analogously to the quantities given in Example 5. The chemicals applied in the first step were applied with a residual moisture content of 75%. The liquor containing silver zeolite sprayed onto the knit fabric is composed as follows:

Table 7: Silver zeolite-containing finish formulation according to Example 6

The functionality of the equipment layer consisting of two host systems can be supplied analogously to the purpose mentioned in Example 5. By using non-loaded or other substances (instead of silver) loaded zeolites can be generated additional functionalities.

In the case of thermal and / or UV or blue light-curing equipment, the host system for receiving active ingredients and active substances (guests or drugs) from thermal and / or UV or blue light-curing prepolymers or monomers and at least one component with spacer function and a surfactant. A host system constructed in this way is swellable by aqueous emulsions containing the active substances and active substances and capable of sorbing and releasing the active substances and active substance contained in the emulsions.

Reactive group-containing monomers and / or polymers whose HLB value is between 3 and 16, preferably between 8 and 12, are used as surface-active substances. Typical representatives are sorbitan laurate or stearate, mono- and diglycerides, ethoxylated and / or propoxylated C ₈ - C ₂ o

Compounds or vinyl or allyl ether alkoxylates having 10 to 30 EO units which form addition or condensation products with predominantly nucleophilic reactive groups such as, for example, amino and hydroxyl functions.

The spacers co-determining the swelling of the finish layer are of the general type: RG-RS-RG. RG corresponds to a UV- or blue-light-curing reactive group or a functional group crosslinking with such a reactive group and RS corresponds to a spacer substance characterizing radical such as, for example, a polyether, polyester or vinylogous chain: [-CH ₂ -CH ₂ -O-] _n ,

[-CH (CH ₃ ) -CH ₂ -O] _n ,

[-CH ₂ -CO-O- (CH ₂ ) _x -O-] _n ,

[-CH (CO-O- (CH ₂ ), -CH ₃ ) -CH ₂ -J _n , or

[-CH (N-CO- (CHz) ₃ ) -CH ₂ -] _n

The chain length of the residual hydrophilicity RS determining the hydrophilicity or hydrophobicity of the spacer substance is defined by n and x, where n is preferably greater than 5 and less than 30 and x is preferably between 2 and 4.

Example 7: UV cured bacteriostatic equipment

A fabric made of cotton and polyester with a

Square weight of 170 g will be after its pretreatment

(Desizing and bleaching) dyed and dried.

Subsequently, the impregnation of the fabric with wellness active ingredients and the "micro-pockets" forming coating components, the chemical fixation takes place after drying of the fabric by UV curing. By using UV-curing, nanotube-forming equipment components, it is possible to use wellness active substances already in the production of the finishing layer, without having to fear their chemical change or thermally induced loss of substance.

Such an example shows the following formulation for equipment having a bacteriostatic effect: Table 8: UV curable, bacteriostatic finishing formulation according to Example 7

The finishing liquor is applied to the fabric by means of a padder with a squeeze effect of 75% and dried at 110 ^° C. for 2 minutes in the tenter. Immediately after the tenter passage, UV curing of the finish layer takes place. The layer hardening takes 2.5 seconds in the UV channel under protective atmosphere. The tissue treated in this way is characterized by a slightly hydrophobic and bacteriostatic effect. The bacteriostatic effect is again loaded with farnesol after washing a corresponding piece of clothing.

Example 8: UV-curable reloadable finish layer

A pre-cleaned, dyed polyamide fabric having a grammage of 180 g / m 2 is impregnated with a solution of 5 g / l Rewin RT (BEZEMA AG) to improve color fastness. The pretreated and dried fabric is impregnated in a second step on a tenter frame with a finish formulation in the form of an aqueous emulsion. Preparation and composition of the emulsion is described below. The emulsion is prepared with the following components: Table 9: UV curable finish formulation according to Example 8

OTA 480 is a propoxylated trimethylolpropane triacrylate and is offered by UCB.

Superonic PE / F 108 is a Vinyletheralkoxylat (about 14 ^Λ 000 g / mol) by the company Unicema.

UVR 6105 refers to an epoxy resin from Dow.

Water and Superonic PE / F 108 are mixed with good stirring. To this mixture is added the mixture of OTA 480, UVR 6105, Pluronic PE 6200, ethyl hydroxyethyl cellulose, sorbitan monolaurate and 2-hydroxy-2-methyl-1-phenyl-1-propanone in small portions.

The fabric impregnated on the tenter frame with a liquor application of 80% based on the dry weight of the textile material is then dried at 120 ^° C. for 2 minutes and, after drying, passes through a UV channel for fixing the finishing layer. The reaction time in the UV channel is 2.5 seconds at one specific radiant power of 5.5 kW / m2. The UV channel is preferably purged with a protective gas such as nitrogen, CO ₂ or argon, on the one hand to avoid any unwanted oxidation processes in the radical curing of acrylates and on the other hand, the ozone formation.

The tissue equipment produced in this way is characterized by excellent host properties, which in turn is characterized by the good swellability of the host layer and the high affinity for lipophilic substances. The layer prepared in the manner described shows a specific substance uptake of 23 mg isooctanol (model substance for therapeutic and / or cosmetic active substances) per gram of host layer. Another essential criterion of the host property is the reloading of the host layer after a completed wash of the garment in question. The reloadability of the finish layer after five washes is still 82% of the original sorption capacity for isooctanol.

In addition to the properties that characterize the functionality of the UV-curable finishing layers, their cost-effective production should be mentioned since the usual high-temperature fixation to be performed is eliminated. By using the UV-curing equipment components, it is possible to use or add the desired active substances already in the production of the finishing layer, without having to fear their chemical change or thermally induced loss of substance.

Claims

claims

A finishing formulation for making finishes on textile fibers and fabrics comprising a crosslinkable polymer binder, a surfactant and a general multifunctional crosslinker, characterized in that the composition comprises crosslinkable spacer substances and in that, in cooperation with the preferably lipophilic modified polymer binder, one characterized by polar Protective and / or polar aprotic substances swellable polymeric finishing layer can be produced with nano pockets, which is repeatedly loaded with active substances.

2. Equipment formulation according to claim 1, characterized in that the polymer binder from the group of crosslinkable fat-modified, emulsified in water, C ₂ to Ci ₈ acrylic, epoxy, vinyl acetate, vinylpyrolidone polymers and their Blockpolimerisaten or urethane polymers is selected.

3. finishing formulation according to claim 1 or 2, characterized in that the polymer binder in a proportion of 40 to 80%, preferably 50 to 65%, based on the dry matter content of the finished finish layer, is present.

4. Equipment formulation according to one of claims 1 to 3, characterized in that as crosslinking agent multifunctional synthetic resin compounds, preferably α- aminoalkylation products such as methylolated and / or methoxylated ethylene urea or melamine compounds are added.

5. Equipment formulation according to one of claims 1 to 4, characterized in that the crosslinking agent in a proportion of 5 to 40%, preferably 10 to 20%, based on the dry matter content of the finished finish layer, is present.

6. Equipment formulation according to any one of claims 1 to 5, characterized in that the spacer substances are selected from the group consisting of polyether chains, preferably polyoxyethylene, polyoxypropylene block polymers and / or C ₂ to C ₈ chains preferably terminated by hydroxyl, amino, Carbonyl, carboxyl, acid amide, isocyanate, N-methylol or methoxy-N-methylol functions.

7. finishing formulation according to any one of claims 1 to 6, characterized in that the spacer substances in a proportion of 5 to 40%, preferably 10 to 25%, based on the dry matter content of the finishing layer to be produced, are present.

8. finishing formulation according to one of claims 1 to 7, characterized in that as crosslinking catalysts, substances from the following group are added: magnesium chloride, mono- and polycarboxylic acids or esters as acid-releasing compounds.

9. finishing formulation according to any one of claims 1 to 8, characterized in that the crosslinking catalysts in a proportion of 1 to 8%, preferably 2 to 4%, based on the dry matter content of the finishing layer to be produced.

10. Equipment formulation according to one of claims 1 to 9, characterized in that anionic and nonionic

Substances whose HLB values are in the range from 3 to 15 are added as surface-active substances, these being selected from the following group:

Glyceryl citrates, glyceryl laurates, fat-modified sorbitan derivatives, preferably emulsifiers of the Span- and

Tweenreihe, Cetaryl-Glucoside, Polyglyceryl-Oleate,

Polyglyceryl stearates and siloxane poly glycol ethers and / or siloxane polyglucosides.

11. Equipment formulation according to one of claims 1 to 10, characterized in that the surface-active substances in a proportion of 2 to 25%, preferably 5 to 8%, based on the dry matter content of the finishing layer to be produced, are present.

12. Equipment formulation according to one of claims 1 to 11, characterized in that for controlling the generation and the spatial extent of percolation structures in the finish-fiber composite CO ₂ - and / or N ₂ - releasing and / or non-reactive in producing the finishing layer impulsive substances are added.

13. Equipment formulation according to claim 12, characterized in that the CO ₂ - and / or N ₂ -abspaltende

Propellant substances organic substances from the group acetoacetic acid, 2,2'-azobisisobutyronitrile and 2,2'-azobis- (2-methylpropane), and / or inorganic CO ₂ - Cleaving sodium bicarbonate in combination with acid-releasing catalysts include.

14. Equipment formulation according to claim 12, characterized in that as the polar, non-reactive, propellant solvent preferably ethyl acetate, methyl glycol acetate and / or diglycol dimethyl ether whose boiling point between 60 and 200 ⁰ C, preferably at 120 ⁰ C, are mixed.

15. Equipment formulation according to one of claims 1 to 14, characterized in that the driving substances in a proportion of 1 to 15%, preferably 2 to 5%, based on the dry matter content of the finishing layer to be produced, are present.

16. A formulation according to any one of claims 1 to 15, characterized in that it comprises cage molecules from the group cyclodextrins, dendrimers and / or glucans.

17. A formulation according to any one of claims 1 to 16, characterized in that the cage molecules in a proportion of 1 to 20%, preferably 8 to 15%, based on the dry matter content of the finishing layer to be produced, are present.

18. Equipment formulation according to one of the preceding claims, characterized in that it is crosslinkable by light in the UV range of 100 nm to 400 nm or in the visible range of 400 nm to 800 nm.

19. A formulation according to claim 18, characterized in that it is thermally and / or UV or Blue light-curing prepolymers or monomers and at least one component with spacer function and a surface-active substance.

20. Equipment for textile fibers and fabrics, characterized in that it is prepared using finishing formulation according to one of the preceding claims and swellable by polar protic and / or polar aprotic substances and that it has swollen state nanotapes containing active substances are repeatedly loadable.

21. Equipment according to claim 20, characterized in that the nanotags have a stochastic distribution in terms of their spatial extent.

22. Equipment according to claim 20, characterized in that the upper limit of the size of the nanotags is 500 nm.

23. Equipment according to claim 20, characterized in that it has a micro or Mesokapillarität, wherein the size of the micro and mesopores in a range of 1 to 25 microns.

24. Equipment according to one of claims 20 to 23, characterized in that it comprises cage molecules from the group: cyclodextrins, dendrimers or glucans or mixtures thereof.

Equipment according to any one of claims 20 to 24, characterized in that it comprises silver zeolite.

26. A method for producing finishes on textile fibers and fabrics according to any one of claims 20 to 25, characterized in that at least one finish formulation according to any one of claims 1 to 19 is used.

27. A method for producing equipment on textile fibers and fabrics according to claim 26, characterized in that the finishing formulation with industry-standard application techniques such as

Foulardieren, coating or spraying on the textile

Fibers and fabrics applied and subsequently dried and fixed.

28. A method for producing equipment on textile fibers and fabrics according to claim 27, characterized in that the drying of the finished fibers and fabrics at temperatures between 50 and 150 ⁰ C for 30 to 180 seconds in industry-standard units such as tenter or Hotflue takes place ,

29. A method for producing finishes on textile fibers and fabrics according to claim 27 or 28, characterized in that are used in the fixation of the finishing layer, depending on the polymer / crosslinker system used preferably thermal and / or UV or blue light-emitting reactors.

30. A method for producing equipment on textile fibers and fabrics according to claim 29, characterized in that the thermal fixation at Temperatures between 120 and 200 ⁰ C, preferably at 140 to 160 ⁰ C.

31. A process for producing finishes on textile fibers and fabrics according to claim 29, characterized in that the chemical fixation according to the

Drying of the fabric by UV or blue light curing takes place.

32. A method for producing finishes on textile fibers and fabrics according to claim 31, characterized in that for fixing light in the UV range of 100 nm to 400 nm or in the visible range of 400 nm to 800 nm is used.

33. The method according to claim 31 or 32, characterized in that the fixing of acrylate-based finishing layers takes place under a protective atmosphere.

34. The method according to any one of claims 31 to 33, characterized in that the equipment components are added before the fixation, the active substances.

35. A method for producing equipment on textile fibers and fabrics according to one of claims 26 to 34, characterized in that the

Finishing layer application an application of

Primer layers upstream, wherein reactive group-containing primer layers to increase the washing permanence of the host system, especially in synthetic

Fiber materials are applied.

36. A method for producing finishes on textile fibers and fabrics according to one of claims 26 to 35, characterized in that in addition cage molecules are applied to the textile to be finished.

37. A method for producing finishes on textile fibers and fabrics according to one of claims 26 to 36, characterized in that the finished fixed finish layer is swollen by polar protic and / or polar aprotic substances, preferably aqueous emulsions of the active substances, and thereby Mikro¬ pockets are loaded in the finishing layer with the active substances.

38. A textile article comprising a carrier material selected from a group comprising textile fibers and fabrics, and a mounted on the substrate equipment according to any one of claims 20 to 25.

39. Textile article according to claim 38, characterized in that it is designed as a textile fabric and at least one first side is provided with an equipment according to one of the preceding claims 20 to 25.

40. Textile article according to claim 39, characterized in that a second side is provided with equipment comprising cage molecules from the group of cyclodextrins, dendrimers or glucans or mixtures thereof.

41. Textile article according to claim 40, characterized in that a second side is provided with equipment comprising silver zeolite.

42. Textile article according to one of claims 38 to 41, characterized in that it is repeatedly loaded with at least one, preferably lipophilic, active substance.

43. Textile article according to one of claims 38 to 42, characterized in that it is loaded with at least one, preferably lipophilic, active substance.

44. Textile article according to claim 42 or 43, characterized in that the at least one active substance from the group phenolic acids of an oregano or Velcro root extract, farnesol or gamma-linolenic acid (evening primrose oil), lipophilic analgesics, hormones or vitamins, scopolamine, cinnarizine, meclocine, Nicotine, heparin, antihistamine, diclofenac, glycerol trinitrate.

45. Textile article according to one of the preceding claims, characterized in that the mass of the applied finish layer is between 1 to 10%, preferably 2 to 4%, based on the dry weight of the textile.