DE10022404A1 - Textile fabric provided with ultraviolet radiation filter, useful for clothing, is obtained by depositing filter on fabric or fibers by impregnation with solution, dispersion or suspension - Google Patents

Abstract

Textile fabric is provided with an ultraviolet (UV) radiation filter. Independent claims are also included for: (i) a method of producing textile fabric with a UV filter by placing the fabric or fibers in a solution, dispersion and/or suspension of UV filter in water or a suitable liquid and leaving for long enough to deposit the filter on the fabric or fibers, then drying and processing in the usual way; (ii) textile laundry or pre- or after-treatment agents containing UV filter(s) or precursor(s) in addition to usual contents.

Description

The present invention relates to a textile fabric to which UV radiation filters have been applied and a process for its production.

The potential damage to human skin from sun exposure has been going on since Years of intensive research, especially since there is a connection between more intense Sun exposure and skin cancer formation has been noted. Responsible for the Skin damage is particularly the ultraviolet rays, which make up about 5% of the Make out solar radiation. UV rays are electromagnetic Radiation in the wavelength range from 400 nm to 10 nm. The shorter the wavelength is, um the radiation is so energetic. The UV range is usually divided into three sub-ranges classified, namely UV-A rays in the range of 400 to 320 nm, UV-B rays in the range from 320 to 290 nm and UV-C rays in the range from 290 to 10 nm.

The most harmful to human skin are the UV-C rays, which are usually caused by the ozone layer is filtered and does not reach the earth's surface. The longer wave UV-A rays lead to the so-called by converting melanin precursors Immediate pigmentation that occurs within a few hours, but is very low and doesn't last long. However, these rays penetrate deep into the dermis and lead premature skin aging. The shorter-wave but higher-energy UV-B rays penetrate the skin a few millimeters and lead to the formation of a relatively permanent Pigments that are deposited in the cells of the epidermis and cause long-term tanning. However, the UV-B rays can release oxygen molecules due to their activity lead to skin damage, what as sunburn and recurrence before especially in children and adolescents, the risk of developing melanoma in the later years of life can increase significantly. The UV-C rays are caused by the Filtered ozone layer, however, their radiation dose that reaches the earth's surface can due to the thinning of the ozone layer, also known as the ozone hole become.  

The high number of skin cancers and the risk of reducing them The ozone layer, even higher, requires protection from excessive UV radiation. Especially people who work outdoors or stay there for a long time, need to protect themselves in order to reduce the UV radiation dose that is Human life accumulated.

So far, people have been protecting themselves from too much sun exposure through so-called Sunscreens containing UV filters or absorbers. The UV absorber or UV protection filters are organic substances that are able to to absorb electromagnetic radiation in the UV range. The molecules go in here an energetically excited state. When returning to the basic state, the The energy absorbed again completely, but less or not for the skin released harmful form again, e.g. B. larger in the form of heat or light Wavelength and lower frequency.

Another way to protect yourself from the sun's rays is to cover your skin with textiles. However, it was found that the notion that the textiles could Protect skin from damaging UV rays is not correct. Depending on the Fiber density of the textiles can penetrate the UV rays through the fabric and lead to Cause damage to the skin. In the field of textiles have already been special Fiber materials developed with high UV protection factors. An example is given by M. Foessel et al., Melliand Textilber .; 78; 1997, p. 515.

The protective effect of textiles can be defined analogously to the UV protection factor of cosmetics are called UPF factor (UV protection factor). D. Knittel et al., Again Melliand Textilber .; 4/1999; P. 281, describe that tissue with a UPF factor <50 only about 1% of the allow radiation to pass through. Such fabrics can be quasi UV-impermeable can be designated because the penetrating portion of the radiation can be classified as harmless is.

The high number of skin cancers and the reduction in the ozone layer demand for further possibilities of equipping textile fabrics with UV protection agents in order to Minimize radiation dose for people who are outdoors.

The present invention was accordingly based on the object, textiles, in the form of Fibers or fabrics to provide protection against harmful UV  Offer rays, with the textiles also on conventional fibers and fabrics such as Natural textiles etc. should be used.

Surprisingly, it was found that when you make textiles, fibers or finished A UV radiation filter is applied to the fabric, and the UPF factor improves significantly leaves. Both natural and synthetic textiles can be used as textile fabrics become.

The present invention accordingly relates to a textile which is characterized by distinguishes that it is exposed to a UV radiation agent.

The term textile used here includes both fibers and finished fabrics, e.g. B. available as a substance or as an already processed product. The textile can be made from any known materials exist, such as natural and synthetic textiles, e.g. B. Cotton, linen, silk, hemp, jute, sisal, viscose, polyamide, polyester, as well as any other well-known textile materials.

Any substances known from the prior art can be used as the UV radiation filter. If the textile is to be processed for clothing, they should preferably have no harmful or allergenic effect on the skin. Examples of suitable UV radiation filters are p-aminobenzoic acid, trimonium benzylidene camphorsulfate, homosalates, benzophenone-3, 2-phenylbenzimidazole-5-sulfonic acid and its salts, terephthalate-dicamphor-sulfonic acid and its salts, butyl-methoxy dibenzoylmethane benzoic acid, ester of p-amine , Camphor derivatives, salicylic acid esters, benzophenone-4, octyltriazone, urocanic acid, 2-cyano-3,3-diphenylacrylic acid ethylhexyl ester, titanium dioxide, Al ₂ O ₃ and any mixtures thereof.

It has proven to be particularly advantageous if the UV radiation filter in solid form are present, especially if they are not water-soluble. A low water solubility or insolubility has the advantage that if the textile with water in Comes into contact, such as B. in the rain or when washing, the UV radiation filter not immediately is released again. It when the UV radiation filter is a particularly advantageous Particle size between 1 and 1,000 nm, particularly preferably between 5 and 300 nm and has in particular between 10 and 80 nm. Such a particle size is special advantageous because the UV radiation filter can be distributed virtually homogeneously on the textile, so that UV absorption takes place almost across the board down to the microscopic range  can. Another advantage is that the high surface area of the radiation filter particles becomes one leads to particularly effective UV absorption.

The special particle size also means that the feel and appearance of the fabric are not sustainable changed. Yet another advantage is that particles with a particle size in the nano range improved adhesion to the textile fabric compared to particles with less specific surface, that is, larger particle size.

Another object of the present invention is a method for producing a textile applied with a UV radiation filter, in which the textile is in a solution, Dispersion or slurry of a UV radiation filter is introduced, there over a sufficient time is left so that the UV radiation filter on the textile can settle and then dried and optionally in a manner known per se is processed.

In a further embodiment of the present invention, this can be done with a UV radiation filter loaded textile can also be produced in which the textile with a precursor of a UV Radiation filter is soaked and the precursor by chemical reaction in the UV Radiation filter is transferred.

The application of the UV radiation filter can, for. B. by targeted coagulation by pH Change or change in temperature.

The in-situ formation of the UV radiation filter on the textile is especially for such Radiation filters are suitable, which can be formed by simply reacting to their preliminary stages. Examples of this are the oxide precursors of inorganic radiation filters, such as aqueous aluminum or Ti solutions by hydrolysis or by changing the pH can be easily converted into the oxides. The UV radiation filter can be bound without additional auxiliary and binding agents are bound to the textile. Especially if the Radiation filters with a particle size in the nano range can dispense with binders become.

In a further embodiment, the UV radiation filter can be bound using Binders are supported. As a binder, for example, polymer solutions water-based dispersions or dispersions, preferably of film-forming polymers, are used, which form a film on the fiber after application and drying.  

In a preferred embodiment of the present invention, UV radiation filters or a preliminary stage of it used in agents for textile washing, pre- or post-treatment.

Another object of the present invention are accordingly means for Textile laundry, textile pretreatment or aftertreatment, containing the usual ingredients are characterized in that they have at least one UV radiation filter or a precursor thereof contain.

As other common ingredients in the agents for textile washing, pretreatment or treatment can be included, come z. B. surfactants, builders, cobuilders, acids preferred Citric acid, amidosulfonic acid or acidic salts such as hydrogen sulfate, enzymes, fragrances, Dyes Bleaching agents based on halogen or oxygen together with bleach activators or - catalysts, complexing agents, such as. B. phosphonates, including complexing Surfactants into consideration. Machine dishwashing detergents additionally contain in particular Rinse aid surfactants and corrosion inhibitors. Textile detergents usually contain in addition the components mentioned as active ingredients fluorescent agents, optical brighteners, Enema preventers, textile anti-crease agents, antimicrobial agents, germicides, Fungicides, antioxidants, antistatic agents, enzymes, ironing aids, phobing and Impregnating agents, UV absorbers and / or fragrances into consideration.

The agents according to the invention are preferably fabric softeners. The fabric softener contain in particular cationic surfactants as surfactants.

Examples Example A

UV protective equipment of blue cotton fabric with Al ₂ O ₃ / SiO ₂ , which had an SPF = 18.1 untreated.

0.68 g of aluminum sec-butoxide and 7.9 g of tetraisopropyl orthotitanate were mixed with 198 ml Isopropyl alcohol mixed. In a second round bottom flask was mixed by mixing 4.1 g Bis-2-ethylhexyl sulfosuccinate sodium salt (AOT), 4.9 g n-heptane and 3.0 g a transparent W / O microemulsion. In this The cotton fabric was soaked in microemulsion. The textile pretreated in this way was used in the Transfer the alcoholic mixture and leave it there for 19 hours. Here, the aluminum and the titanium alcoholate is hydrolyzed by the water stabilized in the microemulsion system and Nanoscale oxide formed on the textile. The latter was under running for 1 minute Rinsed water. After the textile had dried, the weight gain became 1.5% by weight. certainly. An SPF of 73.0 was determined.

Example B

UV protection of white cotton fabric by treatment with a nano-TiO ₂ suspension, which had an untreated one of SPF = 5.1.

A titanium dioxide suspension Tioveil® AQ-G (from Tioveil) was mixed with deionized water diluted to a solids concentration of 0.1% by weight. The cotton sample was in 5 h the suspension stirred, then wrung out and in the drying cabinet at 40 ° C and 50 mbar dried. The weight gain was 0.6%. The SPF was 17.3 determined.

Example C

UV protection of white cotton fabric by treatment with a nano-TiO ₂ suspension, which had an untreated one of SPF = 5.1.

A titanium dioxide suspension Tioveil® AQ-G (from Tioveil) was mixed with deionized water diluted to a solids concentration of 0.5% by weight. The cotton sample was 5 hours stirred in the suspension, then wrung out and in a drying cabinet at 40 ° C and dried 50 mbar. The weight gain was 1.2%, the SPF was 28.2 determined.

Example D

UV protection of white cotton fabric by treatment with a nano-TiO ₂ suspension, which had an untreated one of SPF = 5.1.

A titanium dioxide suspension Tioveil® AQ-G (from Tioveil) was mixed with deionized water diluted to a solids concentration of 1.0% by weight. The cotton sample was in 5 h the suspension stirred, then wrung out and in the drying cabinet at 40 ° C and 50 mbar dried. The weight gain was 3.5% and the SPF was 43.0 determined.

Example E

UV protection of white cotton fabric by treatment with a nano-TiO ₂ suspension, which had an untreated one of SPF = 5.1.

A titanium dioxide suspension Tioveil® AQ-G (from Tioveil) was mixed with deionized water diluted to a solids concentration of 2.0% by weight. The cotton sample was in 5 h the suspension stirred, then wrung out and in the drying cabinet at 40 ° C and 50 mbar dried. The weight gain was 5.5% and the SPF was 64.9 determined.

Example F

UV protection of blue cotton fabric by pulling on a TiO ₂ suspension and subsequent coagulation by raising the pH. The untreated tissue had one of SPF = 18.1.

A 1% by weight suspension was prepared by dilution using a TiO ₂ suspension Tioveil® AQ-G. The pH was adjusted to 3. The blue textile piece was soaked in the suspension, then wrung out and dried. The dried textile was then introduced into a solution with a pH of 6. The weight gain after drying was 7.6% by weight and the SPF 64.9.

Example G UV protection equipment of white tissue with the organic UV protection agent Neo Heliopan®

A 5% by weight aqueous suspension of nanoscalar Neo Heliopan® BB (10-100 nm) was diluted to 0.1% by weight with deionized water. The textile sample was in the Suspension and stirred for 5 hours. Then the textile was under running water rinsed and dried. The weight gain was 1.4% and the SPF 85.6.  

Example H

UV protection equipment of white fabric with the organic UV protection agent Neo Heliopan® (SPF value before treatment 5.1).

A 5% by weight aqueous suspension of nanoscalar Neo Heliopan® BB (10-100 nm) was diluted to 0.5% by weight with deionized water. In the suspension was the Textile sample was given and it was stirred for 5 hours. The textile was under flowing Rinsed water and dried. The weight gain was 2.4% and the SPF 227.2.

Example I

UV protection equipment of white fabric with the organic UV protection agent Neo Heliopan® (SPF of the tissue before treatment 5.1).

A 5% by weight aqueous suspension of nanoscalar Neo Heliopan® BB (10-100 nm) was diluted to 2.0% by weight with deionized water. In the suspension was the Textile sample was given and it was stirred for 5 hours. The textile was under flowing Rinsed water and dried. The weight gain was 3.6% and the SPF 562.7.

Claims (13)

1. Textile fabric, characterized in that it is loaded with a UV radiation filter. 2. Textile fabric, characterized in that the UV radiation filter in the form solid particles. 3. Textile fabric according to claim 2, characterized in that the Particle size of the UV radiation filter between 1 and 1,000 nm, preferably is between 5 and 300 nm and in particular between 10 and 80 nm. 4. Textile fabric according to one of claims 1 to 3, characterized in that the UV radiation filter is selected from p-aminobenzoic acid, trimonium benzylidene camphorsulfate, homosalates, benzophenone-3, 2-phenylbenzimidazole-5-sulfonic acid and their salts, terephthalate-dicamphor -sulfonic acid and its salts, butyl-methoxydibenzoylmethane, esters of p-aminobenzoic acid, camphor derivatives, salicylic acid esters, benzophenone-4, octyltriazone, urocanic acid, 2-cyano-3,3-diphenylacrylic acid-ethylhexyl ester, titanium dioxide, Al ₂ O ₃ and any mixtures thereof. 5. Textile fabric according to one of claims 1 to 4, characterized in that the fabric is selected from natural and synthetic fabrics, especially cotton, linen, silk, hemp, jute, sisal, virgin wool, polyamides, Polyester, viscose, as well as any mixtures of the above. 6. Process for the production of a textile with UV radiation filters Fabric, characterized in that fabric or the fibers in a solution, dispersion and / or slurry of the UV radiation filter in water or a suitable liquid agent and a sufficient Period is left so that the UV radiation filter is on the fabric or the fiber can settle, and then the fabric / textile in is dried in a known manner and further processed. 7. A process for producing a fabric to which UV protection agents have been applied Fibers, characterized in that the fabric or the fibers  are soaked with the precursor of a UV radiation filter and then the precursor is transferred into the UV radiation filter by chemical reaction. 8. The method according to any one of claims 6 or 7, characterized in that the targeted coagulation of the UV radiation filter by adjusting the pH value he follows. 9. The method according to any one of claims 6 to 8, characterized in that Binders can be used to bind the UV radiation filter. 10. Agents for textile washing, textile pretreatment or aftertreatment, containing conventional Ingredients, characterized in that there is at least one UV radiation filter or contains a precursor thereof. 11. Composition according to claim 10, characterized in that as usual ingredients Surfactants, builders, cobuilders, acids, preferably citric acid, amidosulfonic acid or acidic salts such as hydrogen sulfate, enzymes, fragrances, dyes bleach Halogen or oxygen base together with bleach activators or catalysts, Complexing agents such. B. phosphonates, including complexing surfactants in Consideration. Machine dishwashing detergents additionally contain in particular Rinse aid surfactants and corrosion inhibitors. Textile detergents usually contain in addition to the components mentioned as active ingredients fluorescent, optical Brightener, anti-shrink agent, textile finish anti-crease, antimicrobial Active ingredients, germicides, fungicides, antioxidants, antistatic agents, enzymes, ironing aids, Phobing and impregnating agents, UV absorbers and / or fragrances 12. Composition according to claim 10 or 11, characterized in that it is a Is fabric softener. 13. Composition according to claim 12, characterized in that cationic surfactants are included.