DE102004008931A1 - Porous glass or glass ceramic powders, used in cosmetic, biocide or health care applications, e.g. for release of cosmetic, medicinal, veterinary or pesticidal active agents, as odor absorbers or as biocides - Google Patents

Abstract

Use of porous glass or glass ceramic powders (I), having an average pore diameter of 0.0005-500 Microm, an average particle size of 0.5-500 Microm and pore diameter to particles size ratio less than 0.2, with or without filling, is claimed in cosmetics, in (or as) biocide or in the health care sector. ACTIVITY : Fungicide; Antibacterial; Virucide; Insecticide; Algicide; Herbicide. MECHANISM OF ACTION : None given.

Description

The invention relates to the use of porous glass and glass ceramics as carrier or absorber material in cosmetics, in biocidal formulations and in health care

Micro and nanoporous glass is used as a filter material in different areas such as the Pharmaceutical, food processing or water treatment well.

The known from the prior art nanoporous Material is infiltrated with an active substance. The active substance is then released at a certain rate. If the porous material The porous powder can not be infiltrated with an active substance can be used for example as adsorber material.

The use of microglass TSG in silica flakes with a TiO ₂ layer on the surface for UV protection has become known from the field of cosmetics.

The use of a porous and not porous antimicrobial and anti-inflammatory sol-gel glass is described in WO 01/72262.

The US 6132744 describes the combination of porous powders with Talc in cosmetic formulations. Even with the from the US 6132744 described combination, only one absorber material is disclosed with a storage capacity in cosmetic formulation.

The use of porous polymer powder in the field of makeup cosmetics is known for. B. in JP04041412 and JP 62215638 described. JP9183617 describes the production of a porous calcium carbonate, which can also be used in cosmetics.

A glass powder as a preservative for cosmetics is described in PCT / DE00 / 02231.

In the US 5290544 describes water-soluble glasses for use in cosmetic products with very low SiO ₂ and very high B ₂ O ₃ or high P ₂ O ₅ contents. The glasses have silver concentrations greater than 0.5% by weight. These glasses have an extremely low hydrolytic resistance and tend to completely dissolve in water. The released Ag and / or Cu ions have an antibacterial effect. In the US 5290544 the SiO ₂ content is 38% by weight.

The use of borosilicate glasses in The cosmetic is always in platelet form described.

Inorganic biocides in the form of non-porous glasses are used in the JP-A-200302478 , the JP-A-2001247335 . JP-A-2000327364 described.

Non-porous antimicrobial borosilicate glasses are in the JP-A-200302478 described. These are water-soluble glasses with a maximum SiO ₂ content of 50%. Non-porous antimicrobial phosphate glasses are in the applications JP 2001247335 . JP 2000327364 described.

The JP-A-10337469 describes ceramic sintered bodies that contain biocide ions such as Ag, Zn or Cu.

The object of the invention is a Fabric available to provide in the element ions as well as organic in aqueous solutions Components can be added and / or delivered. such porous glasses, Glass powder, glass ceramics or glass ceramic powder are used in the fields of cosmetics, Biocides and can be used in the medical field without that the effectiveness of the active ingredients is influenced.

The task is through use of porous glasses, which has a high hydrolytic resistance, infiltrates with / or without cosmetic or biocidal active ingredients and other organic compounds in the field of cosmetics or of biocides or in the field of medical application use find, solved.

The porous glass according to the invention can be anti-microbial be, but it is not mandatory. If the porous glass itself is an antimicrobial Has effect, the antimicrobial effect is possibly by biocides introduced synergistically enhanced.

The glass or the glass ceramic is usually used used as a powder, with a dry or wet grinding process Particle sizes smaller 500 µm can be obtained. Particle sizes of <50 μm or <20 μm have proven to be expedient. Particle sizes <10 μm and smaller than 5 μm are particularly suitable. As a whole Particle sizes of <1 μm have been found to be particularly suitable. The grinding process can be carried out both dry and in non-aqueous grinding media.

The porous glasses can be made from glass compositions exist that are inert or reactive to aqueous or non-aqueous Systems are.

Mixtures of different glass powders from the composition range with different compositions and grain sizes are possible in order to achieve different release rates. To this It is possible to achieve long-term release.

The admission and delivery behavior of substances can by the pore shape, the number of pores and the Pore volume can be influenced and adjusted. Particularly preferred is a controlled slow delivery or acceptance. Prefers is the average size of the pores, the so-called average pore size is preferred less than 10 μm, particularly preferably less than 1 μm, preferred less than 500 nm, very preferably less than 100 nm. A very special one preferred embodiment has smaller pore sizes 60 nm, so that a slow release of, for example, biocidal ions is achieved.

The pore size distribution can be very narrow or be wide.

For an even release of active substances is the pore size distribution preferably narrow. For In particular applications, the pore size distribution can also be wide. This is particularly preferred when e.g. high at the beginning Release rate of an active ingredient combined with a long-term effect achieved shall be. The large pores have a strong effect at the beginning of the reaction, the small pores achieve the long-term effect.

The pore diameter to particle size ratio is <0.2, particularly preferably <0.05 and 0.01, most preferably <0.005 and 0.002.

In addition to the average pore size a different pore shape can also be advantageous. Conceivable is a big one Pore with porous Shell or pores with neck rejuvenation. Even pore penetration is advantageous.

The powders can be surface modified e.g. through silanization etc. to special properties such as hydrophilic or hydrophobic properties or molecular binding properties achieve.

This can be done through surface modifications Absorption behavior of the fillers and thus control their dispensing behavior.

The porous glass can, for example, have a Sol-gel process or phase separation with subsequent removal of one Phase as well as be produced by a sintering process.

If the porous glasses are produced by phase separation with a subsequent removal of a phase, removal in an acid bath is appropriate, for example. Examples of acids that can be used in an acid bath are: HF, NH ₄ F-HF, HCl, HCl / KCl, HNO ₃ , H ₂ SiF ₆ , H ₂ SO ₄ , H ₃ PO ₄ .

The average pore diameters can vary according to manufacturing parameters and method between 0.1 nm and 100 μm. Pore sizes between 0.1 and 1 μm are preferably about Segregation and or over Sol gel route manufactured. Pore sizes> 1 μm are preferably about the sinter route and or the sol-gel route.

The active filling of porous glass powders with active substances e.g. by capillary force infiltration, pressure infiltration or vacuum infiltration.

fillers can the pores in solid, liquid or gaseous Fill the mold. For solids, the material must be filled in liquid or gaseous form be introduced if a high degree of penetration is achieved shall be.

Also filling the pores with nanopowders as a solid e.g. by applying high electrical fields is possible. Electromigration then takes place into the um pores of the nanopowders.

The delivery of active ingredients can by the pore size of the porous glass be determined. For example, there is a strong short-term levy and low long term delivery possible.

Under Health Care, these are Registration applications in the medical field, especially as Depot for the release of medicinal substances, preparations, the general well-being of people and pets, as well contribute to the general improvement of human health, Roger that.

As previously stated, the present application is not on glasses limited, but also includes glass ceramics, ceramics and silicates. The glasses can be sol-gel glasses or melting glasses his.

Glass fibers are also called glass powder Glass granulate, glass balls, glass blocks, and glass panes understood.

The pH of the glass in contact with water can be defined by varying the glass composition be adjustable.

Mixtures of differently filled porous powders, which can also be produced in different ways possible to combine different properties.

The glass according to the invention, the glass ceramic according to the invention as well as the glass or glass ceramic powder in one embodiment of the invention as a biocidal porous Jar for pesticides, Herbicides or fungicides are used which are lower and higher Killing organisms or have an anti-reproductive effect. Such are particularly preferred Compositions against organisms such as e.g. Bacteria, fungi, yeast Viruses, and insects, especially unwanted pests.

In a further preferred embodiment, for example for biocides, the porous glass matrix contains Even ions such as Ag, Zn, Te, I, Cu, Cr, Ge, especially heavy metals, which should not be used in direct contact with humans. These materials are used in particular to achieve a strong biocidal effect, for example in polymers, paints and varnishes.

Another application of the porous glasses according to the invention or Glass ceramics with an antimicrobial effect is the area cosmetics and health care.

In a preferred embodiment shows the material has a biocidal but at least a biostatic effect, is, however, skin-friendly in contact with humans, toxicologically harmless and in particular also be suitable for consumption. For this Application is preferably largely free of toxicological glass questionable heavy metals such as As, Sb, Cr, Pb, Hg, Ba, Ni.

For certain applications such as in cosmetics are also used special requirements are placed on the purity of the glass powder, thus the toxicological harmlessness of the glass powder as well their suitability for consumption is guaranteed is. The exposure to heavy metals should be possible for this be small. Desirable maximum concentrations in the area of cosmetic Products are e.g. Pb <20 ppm, Cd <5 ppm, As <5 ppm Sb <10 ppm, Hg <1 ppm, Ni <10 ppm.

For contains this application the porous Glass matrix prefers antimicrobial ions such as zinc or silver for humans or higher Organisms not harmful to health or are toxic.

In a particularly preferred embodiment of the invention in the field of cosmetics and health care the porous Glass or the porous Glass ceramic an active ingredient depot.

For this preferred embodiment is the glass matrix, which is preferred from the group of non-heavy metals composed, non-toxic to humans.

The glass surface is preferably modified so that no negative interactions of the glass matrix with the one to be released Active ingredient occur, or so modified, the active ingredient to be released on the surface are fixed according to their application.

Another preferred application the porous described here glasses represents the adsorption of substances. These can be applications that odors absorb from the air, or body fluids, or generally absorb foreign substances or pollutants from aqueous media. On Such glass is particularly for the cosmetics and Health care as porous Glass adsorption of substances suitable.

A preferred embodiment represents continue to be used as the adsorbent medium described here porous glasses as a composite material with activated carbon.

The porous glass can be used for cosmetic Applications as an adsorbant for Fabrics etc. For hydrophilic or hydrophobic substances such as water or oils, fats be used.

A preferred application for this is Absorption of smells, especially body odors. A Another application is the antiperspirant or sweat-reducing Effect by absorption of watery or greasy or oily Body substances.

The porous glass can for example for cosmetic Applications antimicrobial, anti-inflammatory, skin care, fragrance, moisturizing or antiperspirant, deodorant, skin regenerating, anti-wrinkle, self-tanning, stimulating, circulation-promoting, soothing, aging-reducing, irritation-reducing have sebum-regulating properties. Also filling the Pores with coloring agents, flavoring agents, preservatives, vitamins, coloring agents, Radical scavengers, Thickeners, esters, inorganic and organic light stabilizers, Radical scavengers, Pigments, thickeners, softening substances, moisturizing Substances, film formers, electrolytes, polar and non-polar oils, polymer, Copolymer, emulsifiers, wax stabilizers, herbal active ingredients, anti-inflammatory natural Active ingredients, antioxidants are possible.

In the field of cosmetics is one Use in make-up, eye cosmetics, hair masks, hair shampoos, Hair rinses, Lipsticks, cleansing milk, body lotions, Body powder, Shower oils, Bath oils, shower gels, Deodorant formulations, antiperspirant formulations, day cream, Night cream, sun cream, sun gels, aftersun products, perfume formulations, Masks, in particular face masks, gels, eye shadows, compact products, such as compact powder, blush, primers possible.

The porous glass powder can be in all appropriate compositions for the above uses be introduced. All cosmetic ones are only exemplary here Sunscreen preparations for Skin and hair as well as for decorative cosmetics such as makeup, foundations, lipsticks, the Called UVA and UVB absorption or reflection.

In the health care sector, they can porous glasses are filled with nourishing, healing or therapeutic substances, such as aloe vera, retinol, lanolin, glycerin, serine, hyauluraunic acid, triclosan, Witch hazel, silica, polyethylene, vinyl, vitamin (such as A, c, e, f), DHA, erythrulose, AHA, salicilic acid, beta-hydroxy fruit acid, ceramides, Millet, such as soybean oil, Avocado oil, Almond oil, Olive oil, Karite, keratin brewer's yeast, citric acid, lactic acid, zinc, gluconate, UVB blocker of organic UVA and / or, farnesol, enzyme and perfume oils.

The introduction of one or more of the following substances into the porous glass powder is also conceivable:
Acetate: salts of acetic acid;
Acetone:
Acetylted Lanolin Alcohol:
Acrylate copolymer: active ingredients in an oil-absorbing gel, such as Clinac OC
Acrylates / Octylpropenamid
Alcohol SD-40
Algae / seaweed extract:
allantoin:
Alpha hydroxy acids such as citric acid, amino acetic acid, lactic acid and the less common alpha hydroxy acids used in the cosmetics field, such as malic and tartaric acid.
Alpha lipid acid
Aluminum stearate
Ascorbic Acid: Vitamin C; L-form of ascorbic acid
Ascorbyl palmitate:
beeswax
Benzoyl peroxide:
Beta-hydroxy acid: salicylic acid,
boric acid:
caffeine:
Fighter
Carbomers (934, 940, 941, 980, 981
Carmine:
Caviar:
cellulose:
ceramides,
Ceteareth
Cetyl alcohol
Collagen Cyclic acids
Hyaluronic acid cyclomethicone
dimethicone
EDTA
elastin
Ellagic acid
Ethyl alcohol
glycerin
glycine
glycogen
Glycolisäure
Alpha-hydroxy acid
Glycol stearate: extract of grape seed extract of green tea
Hyaluroni acid
hydroquinone
Isopropyl alcohol
isopropyl
isopropyl palmitate
Isostearic acid
Kaolin (china clay)
Kojic acid
lactic acid
lanolin
lecithin
L-Ergothioneine
Licorice extract

linoleic acid
Vitamin F
lysine
Aminooctyl methoxycinnamate
octyl palmitate,
Octyl salicylate,
oxybenzone,
PABA (para-aminobenzoic acid),
Panthenol: a B vitamin (B5)
Parabens
polybutene:
Hydroxyl polyacid,

proline
Propylene Glycol: Resveratrol: Antioxidant that supports and protects collagen.

Resin oil: Retinyl palmitate: (also known as vitamin apalmitate);

Retinyl palmitate polypeptide
Rose hip
Salicyli acid
silica
Silkon
silk powder

page proteins
Sodium bicarbonate,
Sodium borate,
Sodium hyaluronate,
Sodium laurel sulfate,
sorbic acid,
sorbitol,
stearic acid,
Sulfur,
Titanium dioxide
triclosan,
tyrosine,
Vitamin A,
Vitamin B,
Vitamin C,
Witch hazel
Xanthan gum

In the field of cosmetics and / or health care, the active ingredients can include one or more of the following substances: humectants, such as:
Glycerin (glycerin), propylene glycol, sorbitol, hyaluronic acid, lecithin, urea, DNA, milk acid +, carboxyl-containing acid of pyrrolidone (NA-PCA), phospholipids, collagen, elastin, ceramide hyaluronic acid or hyaluronan ascorbic acid (vitamin C), butylated hydroxyl ), butylated hydroxytoluene (BHT), EDTA and tocopherol (vitamin E). ALMOND OIL, ALOE VERA, AVOCADO OIL, BEE WAX, RIZINUS OIL, COCOA BUTTER, COCONUT OIL, GLYCERIN, GRAPE GRAIN OIL, HAZELNUT OIL, BUXACEE OIL, KUKUI NUT OIL, OIL OIL OIL, MACADAM , OLIVE OIL, PALM OIL, PALM SEED OIL, PEANUT OIL, ROSE HIP SEED OIL, SAFLOR OIL, SCHIBAUM BUTTER, SOYA OIL, WITCH HAZELNUT, WHEAT MICROBE OIL
Dextran (and) -acetyl-hexapeptide-2
Dextran (and) acetyl hexapeptide-1
Tetra Peptide-1
Tripeptide-1
Glucose (and) citric acid (and) sorbitol
Yeast extract
Dextran (and) acetyl tetrapeptide-2

Botanical active substances, such as:
Mineral oil (and) chamazulene
Caprilic / Caprin-Amber Triglyceride (and) Chamazulene
PEG 40 hydrogenated castor oil (and) PPG2 ceteareth 9 (and) azulenes (and) chamazulenes
Grain of oil
Propylene glycol (and) glycosphingolipids
Propylene Glycol (and) Lemon (Citrus Medica Limonum) Extract (and) Citric Acid (and) Lactic Acid (and) Mandelic Acid (and) Salicylic Acid
glycogen
Dog Rose Oil (Rosa Canina)
Hip Oil
Sorbitol (and) Papaya (Carica Papaya) extract (and) Lemon (Citrus Medica Limonum) extract
Hexyles Decanol (and) Apple (Pyrus Malus) extract
Propylene Glycol (and) Horse Chestnut (Aesculus Hippocastanum) Extract Propylene Glycol (and) Cucumber (Cucumis Sativus) Extract

Biological and hemisynthetic active substances such as:
10-hydroxydecanoic acid
Inositol triphosphate
Natriumbetasitosterin sulfate

Mineral oil and chamazulen, PEG 40 hydrogenated castor oil (and) PPG-2-ceteareth-9 and cholesterol oleic acid (and) palmitic acid (and) retinyl palmitate (and) stearic acid (and) linoleic acid (and) arachidonic acid ( and)
tocopherol
Soluble collagen
Hydrolyzed collagen
Hydrolyzed elastin
Hydrolyzed keratin
Marinetechnologiesubtanzen
Porphyridium / zinc edge of the fermenter
Artemia extract

Marine active substances
Hydrolyzed glycosaminoglycans
Salmon-extract
Cell dye C
Hexyldecanol (and) phospholipids (and) sphingolipids (and) acidic (and) eicosapentaenoic acidic (and) arachidonic acid (and) docosahexane cholesterol (and) tocopherol
Hydrolyzed collagen (and) hydrolyzed glycosaminoglycans
Soluble collagen
Hydrolyzed elastin
Hydrolyzed fish protein (and) urea (and) PCA-Na (and) soluble native collagen (and) hydrolyzed collagen
hydrolyzed elastin (and) hydrolyzed collagen (and) hydrolyzed silk propylene glycol (and) Fucus Vesiculosus propylene glycol (and) algae extract

Glycyrrhizinate, such as:
Glycyrrhizic acid
Ammonium glycyrrhizate
Dipotassium glycyrrhizate
Thermotropic cholesteric liquid crystals (TCLC), such as:

Cholesterolesters
Gelatin (and) gum arabic (and) aqua (and) butyrospermum parkii (and) water (and) gelatin (and) gum arabic
Aqua (and) calcium alginate (and) sodium chloride (and) mica (and) titanium dioxide (and) potassium sorbate (and) xanthan gums

- Castor (Ricinus communis) oil
hydrogenated castor oil
Glycerol hydroxystearate
Propylene glycol hydroxystearate
Cetyl ricinoleate
Glycerine Triacetylricinoleate-
Methyl-Acetylricinoleate-
Propylene Glykolricinoleate
Undecylenic acid
Hydrocotyl (Centella Asiatica) extract

Active operating lipid extract from natural waxes: rose, mimosa, jamin, soybean natural blu me waxes: lavender, chamomile, sunflower or sage wax

Dimethicone
Dimethicone copolyol
Perfluoropolymethyl isopropyl ether
Lauroyl lysine
Magnesium myristate
polyethylene
lecithin
Highly polymerized methyl siloxanes (Methicone)
Magnesium silicates
Natriumkaliumaluminiumsilicate
Polymethyl methacrylate
PMMA and micronized TiO ₂ or zinc oxide or silicates
iron oxide

Hyaluronic acid / Dihydroxyacetone:
sodium hyaluronate
Dihydroxyacetone
Protection, food, viscosity substances

Triticum- vulgare (wheat) gluten extract (and) water
Candida Bombicola / Glucose / Methyl Rapeseedate Ferment
Galactaric acid
hydrolyzed wheat proteins
Oat flour

Substances from the field of surfactants / complexing agents / specialties such as:
Cetearyl Wheat Straw Glycosides (and) Cetearyl ALCOHOL
Cetearyl wheat bran glycosides, (and) cetearyl ALCOHOL,
vegetable acid
Calophyllum Inophyllum Seed Oil;

synthetic wax,
polyethylene,
Carnauba palm, polyethylene, or carnauba / synthetic wax, or carnauba palm

Polyethylene / PTFE / synthetic wax
PTFE
polyethylene
Carnauba / Beeswax / Jojoba
bisabolol
allantoin
Cetearyl ALCOHOL
Seesalz-
squalane
sodium hyaluronate
Corylus Avellana
Persea gratissima
Prunus armeniaca
Triticum vulgare
Prunus dulcis
Vitis Vinifera
Triticum vulgare
Sesamum indicum

Olea europaea
2-bromo-2-nitropropane -1,3-diol, 5-bromo-5-nitro-1,3-dioxane, aluminum stearate, aluminum chlorohydrates, ammonium lauryl sulfate, BHT, benzyl alcohol, bronopol,
Butylene Glycol, Butyl Paraben, Carbomer, Cera-Microcristallina, Cetyl-Isononanoate,
Chloroacetamide, Ci 15985 yellow orange = E 119, Ci 42090 patent blue, Ci 42170 green No. 3,

Ci 47005 quinoline yellow = E 104, Ci 60730 c.-extr. Violet 21, Ci 77891 titanium dioxide, Cocamide MEA (mono-ethanol sub), dibromo-dicyanobutane = Euxyl K 400 R, diazolidinyl urea, dihydrobutidine, dimethicone, dichlorophenyl-imidazole dioxolane, disodium laureth sulfosuccinate, DMux-phthalate, diethyl EDTA, ethyl alcohol, ethyl paraben, glycerin, glycerol stearate, glycine, hexamidine diisethionate, hydrogenated castor oil, hydroxyethyl ethyl cellulose, imidazolidinyl urea, isohexadecane, isopropyl alcohol, isopropyl myristate, isopropyl palmitate, iodopropamyl lauryl (iodopropyl) lauryl butyl amide, iodopropyl lauryl butyl , Laureth-2; Laureth-3, MEALauryl sulfate, methyldibromo glutaronitrile, methylgluceth, methylchloroisothiazolinone, methylparaben, microcrystalline wax see Cera Microcristallina, mineral oil (= petroleum), nitromusus compounds, octoxyglycerol, octyl palmitate, octyl methoxycinnamate (paraffins), parabens, parabens, parabens, parabens , PEG = poly ethylene glycols, petroleum jelly (= petroleum), phenoxyethanol, polyglyceryl-3 oleate, polysorbate 20-85, potassium sorbate, propylene glycol, propyl paraben, PVP, sodium benzoate, sodium cetearyl sulfate, sodium lauryl sulfate, sodium laureth sulfate, sodium myreth sulfate surfactant , Squalane lipid, steareth - triclosan, triethanolamine, urea

Substances that act as UV blockers
4-aminobenzoic, N, N, acid
N-trimethyl-4- (2-oxoborn-3-ylidenemethyl) anilium methyl sulfate,
Homosalates (INN), Oxybenzone (INN),
2-phenylbenzimidazole-5-sulfonic acid and its potassium, sodium and triethanolamine salts,
3,3 '- (1,4-phenylenedimethylene) bis (7,7-dimethyl-2-oxobicyclo [2,2,1] heptylmethanesulfonic) acid and its salts,
1- (4-tert-butylphenyl) -3- (4-methoxyphenyl) propane-1,3-dione,
Alpha- (2-oxoborn-3-ylidene) toluene-4-sulphonic acid and its salts,
2-cyano-3,3-diphenylacrylic acid, 2-ethylhexyl ester (octocrylene)
Polymer of N - {(2 and 4) - [(2-oxoborn-3-ylidenes) methyl] benzyl} acrylamide, octyl methoxycinnamate 10% S 3 13 ethoxylated ethyl 1-aminobenzoate (PEG-25 PABA),
Isopentyl-4-methoxycinnamate (isoamyl-p-methoxycinnamate),
2,4,6-trianilino- (p-carbo-2'-ethylhexyl-1'-oxy) -1,3,5-triazine (octyl triazone), phenol,
2-2 (2H-benzotriazol-2-yl) -4-methyl-6- (2-methyl-3- (1,3,3, 3-tetramethyl-1- (trimethylsilyl) oxy) disiloxanyl) propyl (drometriazole Trisiloxanes), benzoic acid,
4.4 - ((6 - (((1,1-dimethylethyl) amino) carbonyl) phenyl) amino) -1.3.5-triazines-2,4-diyl) diimino) bis, bis (2-ethylhexyl) ester)
3- (4'-methylbenzylidenes) -d-1 camphor (4-methylbenzylidenes camphor), camphor 3-benzylidenes (3-benzylidenes camphor (octyl dimethyl PABA),
2-hydroxy-4-methoxybenzo-phenone-5-sulfonic acid (benzophenone-5) and its sodium salt,
2,2'-methylene-bis-6- (2H-benzotriazol-2-yl) -4- (tetramethyl-butyl) -1,1,3,3-phenol,
Monosodium- from the 2-2'-bis (1,4-phenylene) 1Hbenzimidazole-4,6-disulphonic acid, (1,3,5) -triazine-2,4-bis ((4- (2-ethyl -hexyloxy) -2-hydroxy) -phenyl) -6- (4-methoxyphenyl), glycerin, 1,4-aminobenzoate, menthyl anthranilate, ulisobenzone dioxybene zone, digalloyl trioleates, TiO2 (nanoparticles), ZnO (nanoparticles), Fe203 ZrO2, MnO

If the porous glasses or glass ceramics are used in the cosmetics sector, the following substances from the cosmetics sector or fragrances can be added:
The following substances from the cosmetics sector are according to the "The International Nomenclature of Cosmetic Ingredients", chapter Cosmetic Products other than Frangrances Published in Section I of the Annex to Commission Decision 96/335 / EC in accordance with Council Directive 93/35 / EEC 8art 5a.1) and the following fragrances after the chapter Frangrances Ingredients Published in Section Ilof the Annex to Commission Decision 96/335 / EC in accordance with Council Directive 93/35 / EEC Bart 5a.1).

Possible substances are:
2,6-DIMETHYL-7-Octene-2-OL
2-HEPTYLCYCLOPENTANONE
2-T-BUTYLCYCLOHEXYL AZETATE
2 T-BUTYLCYCLOHEXYLOXYBUTANOL
3-hexenal
ACETYL HEXAMETHYLES INDAN
ACETYL HEXAMETHYLES TETRALINE
ALLYL caproate
ALPHA DAMASCONE
AMYL ACETATE
AMYL BENZOAT
AMYL CINNAMAL
AMYL SALIZYLATE
ANETHUM GRAVEOLENS
ASPERULA ODORATA
BENZALDEHYDE
BENZYL ACETATE
BENZYL
BENZYL BENZOATE
BENZYL-ZIMTAMAT
BENZYL salicylate
BIXA ORELLANA
BORNELONE
BOSWELIA SERRATA
BOUGANVILLA GLABRA
BRASSICA ALBA
BRASSICA BROTRYTIS
BRASSICA CAPITATA

BRASSICA JUNCEA
BRASSICA NIGRA
BRASSICA RAPA
BROMOCINNAMAL
Butyl acetate
butylbenzoate
BUXUS SEMPERVIRENS
CAKILE MARITIMA
CALLITRIS QUADRIVALVIS
CALLUNA COMMON
CAMELIA OLEIFERA
CAMELINA SATIVA
FIGHTER
CANANGA ODORATA
CAPPARIS SPINOSA
CAPSICUM FRUTESCENS
CARBENIA BENEDICTA
CARUM CARVI
CARUM PETROSELINUM
CARVON / KASSIE AURICULATA

KASSIE ITALICA
CINNAMAL
CINNAMOMUM-KASSIE
CINNAMOMUM LOUREIRII
CINNAMOMUM ZEYLANICUM
Cinnamyl ACETATE
Cinnamyl ALCOHOL
CITTUS LABDANIFERUS
citral
CITRONELLAL
citronellol
CITRONELLYL AZETATE
CITRUS AMARA
CITRUS AURANTIFOLIA
CITRUS BERGAMIA
CITRUS DULCIS
CITRUS GRANDIS
CITRUS LIME
CITRUS NOBILIS
CLEMATIS VITALBA
COCOS NUCIFERA
COPAIFERA OFFICINALIS
CORIANDRUM SATIVUM-
CORYLUS AVELLANA
CORYLUS ROSTRATA
COUMARIN
CUPRESSUS SEMPERVIRENS
CYCLAMEN ALDEHYDE
DAMAR
decanal
DELTA decalactone
DIACETONALKOHO
dihydrocoumarin
DIHYDROJASMONATE DIMETHYL HEXAHYDRONAPHTHYL
DIHYDROXYMETHYL ACETAL
DIMETHYL OCTYNEDIOL
DIMETHYLOCTAHYDRO-2-naphthaldehyde
DIRECT BLACK 51
DIRECT RED 80
DIRECT VIOLET 48
ethylbutyl
valerolactones
ETHYLZIMTAMAT
Ethylphenethyl-ACETAL
ÄTHYLPHENYLACETATE
ethyl vanillin
eucalyptol
EUCALYPTUS GLOBULUS
EUGENOL
FARNESYL ACETATE
FOENICULUM VULGAR
GAMMA nonalactone
Gamma undecalactone
GARDENIA FLORIDA
GERANIOL
GERANIUM
GERANYLAZETAT
heliotropin
HEXAHYDROHEXAMETHYL CYCLOPENTABENZOPYRANE
HEXYLES
ALCOHOL
hoplostethus
Hydroxycitronellal
isoamyl acetate
ISOBUTYLAZETAT
Isobutyric ACID
isoeugenol
ISOLONGIFOLEN KETONE EPOXY
ISOLONGIFOLEN EXO
ISOPENTYLCYCLOHEXANON
isopropyl acetate
ISOPROPYLPHENYLBUTANAL
LINALOOL
LINALYL ACETATE
MENTHOL ACETATE
MENTHYL LACTATE
Methoxy
Methyl 3-METHYLRESORCYLAT
METHYL ACETATE
Methyl EUGENOL
methyldihydrojasmonate
MIXED, IONONE
MIXED TERPENES
MUSK KETON
MYROXYLON PEREIRAE
MYROXYLON TOLUIFERUM
N-butyl-ALCOHOL
NONYL ACETATE
NOPYL ACETATE
o-cymene-5-ol
p-cymene
p-methyl-acetophenone
PERFUME
PENTADECALACTONE
Phenethyl ZETAT
phenethyl alcohol
PHENYLISOHEXANOL
PROPYL ACETATE
PROPYL-benzoate
STYRAX-BENZOIN
TERPINEOL
TERPINEOL ACETATE
trimethylhexanol
TURPENTINE
VANILLA
PLANIFOLIA
VANILLIN

If porous glasses are used in the field of medicine, ie in the field of health care, the following active ingredients can be added:
acetazolamide,
acetylcysteine,
Aspirin / codeine,
acyclovir,
acitretin,
adenosine,
ajmalin,
albendazole,
alendronate,
allopurinol,
amantadine
amikacin
amiodarone
amitriptyline
amoxicillin
Amoxicillin / clavulanic acid
Amphotericin B
ampicillin
apraclonidine
atenolol
Atenolol / chlorthalidone
Atenolol / nifedipine
atropine
azathioprine
azlocillin
Baclofen
beclomethasone
benperidol
Benserazide / levodopa
benzbromarone
Beta-acetydigoxin
betamethasone
biperiden
brinzolamide
bromocriptine
budesonide
butylscopolamine
calcipotriol
calcitonin
Calcium carbonate / etidronic
Calcium / calcium gluconate / sodium fluorophosphate
Captopril / hydrochlorothiazide
carbamazepine
Carbidopa / levodopa
carvedilol
Cefaclor
cefuroximaxetil
certoparin
quinidine
quinine
chloramphenicol
chlormadinone
chloroquine
chlorthalidone
cyclosporine
cinchocaine
cinnarizine
ciprofloxacin
clarithromycin
clindamycin
Clobetasol
clomipramine
clonazepam
clopidogrel
clotrimazole
clozapine
codeine
Codeine / acetaminophen
colchicine
cholestyramine
Cyproterone / ethinyl estradiol
dexamethasone
diazepam
diclofenac
digitoxin
digoxin
Dihydralazin
dihydrocodeine
diltiazem
Doxepin
doxycycline

enalapril
Enalapril / hydrochlorothiazide
ergotamine
erythromycin
estradiol
Estradiol / estriol / levonorgestrel
Estradiol / levonorgestrel
Estradiol / medroxyprogesterone
Estradiol / norethindrone
Estradiol / norgestrel
estriol
ethambutol
Ethambutol / Isozianid
ethinylestradiol
Ethinyl estradiol / levonorgestrel
Ethinyl estradiol / norethindrone
ethosuximide
etidronic
fentanyl
fexofenadine
Finasteride
flecainide
flucloxacillin
fluconazole
flunarizine
fluoxetine
formoterol
fosfomycin
fusidic
gemfibrozil
gentamicin
glyburide
glyceryl trinitrate
goserelin
halofantrine
haloperidol
hydrochlorothiazide
Hydrochlorothiazide / losartan
Hydrochlorothiazide / metoprolol
Hydrochlorothiazide / triamterene
Hydrochlorothiazide / verapamil
hydrocortisone
ibuprofen
Idoxuridine, ointment
imipramine
indomethacin
Insulin (human)
Insulin (pig)
Interferon alpha 2a
Interferon alpha 2b
isoniazid
Isoniazid / pyridoxine
Isoniazid / rifampicin
isosorbide dinitrate
Isotretinoin
itraconazole
Conjugated estrogens
Conjugated estrogens / medrogestone
Conjugated estrogens / medroxyprogesterone
lamotrigine
latanoprost
leuprolide
levocabastine
levomepromazine
Methadone
levonorgestrel
levothyroxine
lidocaine
Lisinopril
lithium
loperamide
lormetazepam
losartan
lovastatin
mebendazole
mebeverine
meclizine
medroxyprogesterone
mefloquine
melperone
mesalazine
metformin
methotrexate
metoclopramide
metoprolol
metronidazole
mezlocillin
mifepristone
moclobemide
molsidomine
morphine
mycophenolate
naftifine
Naloxone / Tilidin
naproxen
natamycin
sodium aurothiomalate
sodium fluoride
nifedipine
nitrendipine
norethindrone
norfloxacin
nortriptyline
omeprazole
ondansetron
oxazepam
Oxybutynin
penicillamine
Penicillin-G (benzylpenicillin)
Penicillin-V (phenoxymethylpenicillin)
perphenazine
phenobarbital
phenprocoumon
phenytoin
pilocarpine
piperacillin
pravastatin
praziquantel
prednicarbat
prednisolone
proguanil
propafenone
propranolol
protionamide
pyrantel
pyrazinamide
pyrimethamine
ranitidine
rifampicin
salbutamol
scopolamine
selegiline
simvastatin
sotalol
streptomycin
sucralfate
Sulfamethoxazole / trimethoprim
sulfasalazine
Sumatriptan
tacrolimus
temazepam
terazosin
terbutaline
testosterone
theophylline
thiamazole
thioridazine
timolol
tretinoin
triamterene
trimethoprim
trimipramine
urapidil
ursodeoxycholic acid
valproic acid
vancomycin
verapamil
vigabatrin
zolpidem
zopiclone

In the field of dental care (oral care) the following substances can be added to the porous glass, which are embedded in the pores of the porous glass:
2-methyl-4-hydroxypyrrolidines
CUMARIN 6-METHYL
ALLANTOIN
ALUMINUM FLUORIDE
AMMONIUM FLUORIDE
AMMONIUM FLUOR SILIKAT
Ammonium monofluorophosphate
AMMONIUM PHOSPHATE
BORIC ACID
CALCIUM CARBONATE
CALCIUM FLUORIDE
KALZIUMGLYZEROPHOSPHAT
KALZIUMMONOFLUOROPHOSPHAT
CALCIUM PHOSPHATE
KALZIUMSACCHARIN
CETYLAMINE HYDROFLUORIDE
CHLOROTHYMOL
DEQUALINIUM CHLORINE COMPOUND
Diammonium Phosphate
di-calcium phosphate
Dicalcium DIHYDRATE
Hydroxyapatite
MAGNESIUM FLUORIDE
MAGNESIUM FLUOR SILIKAT
NICOMETHANOL HYDROFLUORIDE
OCTADECENYL AMMONIUM FLUORIDE
PALMITYL TRIHYDROXYETHYL PROPYLENEDIAMINE DIHYDROFLUORID
PHENOLPHTHALEIN
POTASSIUM ACESULFAM
POTASSIUM FLUORIDE
POTASSIUM SILICATE FLUOR
potassium monofluorophosphate
PVM / MA COPOLYMER
SACCHARIN
SODIUM FLUORIDE
SODIUM FLUOR SILIKAT
sodium metaphosphate
sodium monofluorophosphate
sodium
tin fluoride
pyrophosphate
STEARYL- TRIHYDROXYETHYL PROPYLENEEDIAMINE DIHYDROFLUORIDE
Stevioside
STRONTIUM ACETATE
STRONTIUM CHLORIDE
Tricalcium PHOSPHATE
ZINC CHLORIDE
ZINC SULFATE

Another use of the porous glass powder is the use as a biocide. For this the porous glass matrix doped with biocidally active ions such as Ag, Zn, Cu, I, Te, Ce, Cr. Furthermore, the porous glass powder as an adsorbent for unwanted substances et al For Hydrophilic or hydrophobic substances are used at the same time antimicrobial effect. In this preferred embodiment the pores of the glass are not filled with an active ingredient. The biocidal effect is caused by a surface reaction, in particular caused an ion exchange with water, preferably sufficient already air humidity.

The porous glass can be filled with biocidal active substances that e.g. fungicidal, bactericidal, insecticides, algicidal, herbicidal, possess properties. In particular, too Mixtures of these biocides possible. By Different active ingredients can be introduced into the pores the strenght the biocidal or biostatic effect can be controlled.

This embodiment is preferred an even release rate of the biocidally active ingredients a long period of time.

A further preferred embodiment is the porous material which has been infiltrated organically and inorganically, for example AgNO ₃ , with a biocidal substance during the grinding step. A subsequent tempering step, for example in order to achieve better adhesion of the biocidal active substance and a cleaning step in order to remove non-firmly adhering active substance, can be carried out. In particular, a diffusion of ion exchange into the glass matrix can take place through the subsequent step. This is particularly preferred.

The following are biocidal substances specified that particularly for the use described here in porous glass powders as biocides are suitable. Examples of this are: triclosan, Ag, Zn, Cu compounds.

Chloro-4-nitrobenzene benzene, 2-chlorophenol, chlorothalonil, 2-chlorotoluene, alpha-chlorotoluene, chlorpyrifos, Coumaphos, cypermethrin, DDT, dichlofluanide, dichloroaniline, 1,2-benzenedichlorobenzene, 1,3-dichlorobenzene, 1,4-dichlorobenzene, 1,4-dichlorobenzene, 1,4-dichlorobenzene , Dichloronitrobenzene (all isomers), ganohalogen, 2,4-dichlorophenol, 1,3-dichloropropen, dichlorprop, dicofol, dieldrin, diuron, endosulfan, endrin, heptachlor, hexachlorobenzene, hexachlorobutadiene (HCBD), hexachlorocycloethanone, hexachloroblorone -Iodo-2-propynyl n-butyl carbamate (IPBC), linuron, pentachlorobenzene, pentachloroethane, pentachlorophenol (PCP), 6-5 permethrin, propanil, simazine, tetrachlorobenzene (all isomers), tetrachloroethylene1,2,4-trichloro-benzene, trichlorobenzene, Trichlorophenol (all isomer), trifluralin, 1,1,1-trichloroethane, 1,1,2,2, -tetrachloroethane, 1,1,2-trichloroethane, 1,1,2-trichlorotrifluoroethane, 1,1-dichloroethane, 1 , 1-dichloroethene, 1,2-dibromoethane, 1,2-dichloroethane, 1,2-dichloroethene, 1,2-dichloropropane, 1,3-dichloro-2-propanol, 1,3-dichloropropene, 1,6-dichlorohexane, 1-chlorohexane, 1-fluoro-4-isocyanatobenzene, 2,2- dichloropropanoic acid, 2,3-dichlorophenol, 2,3-dichloropropen, (2,4,5-trichlorophenoxy) acetic acid, (2,4,5-trichlorophenoxy) propionic acid, 2,4,6-trichloro-1,3 , 5-triazine, 2,4-dichlorophenoxybutyric acid, 2,4-dichlorophenoxy-4-aniline, 2,6-dichlorophenol, 2-amino-4-chlorophenol, 2-benzyl-4-chlorophenol, 2-chloro-1, 3-butadiene, 2-chloroanthraquinone, 2-chloroethanol, 2-chlorophenol, 3-chloroaniline, 3-chlorophenol, 3-chloropropene, 3-chlorotoluene, 4-chloro-2-methylphenol, 4-chloro-2-nitroaniline, 4- chloroaniline, 4-chlorophenol, 4-chlorotoluene, 5-chloro-2-methyl-4-isothiazolin-3-one, alachlor, alpha, alpha-dichlorotoluene, alpha-cypermethrin, alpha-trifluoro-2-nitrotoluene, alpha-trifluoro- 3-nitro-4-chlorotoluene, alpha-rifluoro-3-nitrotoluene, alpha-trifluoro-4-nitrotoluene, anilazine, benazolin, benodanil, bifenox, bifenthrin, bis (2-chloroiso propyl) ether, bromacil, captan, carbon te tetrachloride, chlorbufam, chloridazon, Chloroacetic acid, Chloroaminotoluol, Chlorodinitrobenzol, chloroethylene, chloroform, Chloronaphthalen, Chloronitrotoluol, chloropicrin, chlorotoluron, chloroxuron, chlorpropham, chlorthal-dimethyl, clofentezine, clopyralid, cyanazine, cyproconazole, Dalapon, Deltamethrin, dichlobenil, dichlorobenzidine, dichloromethane , dichlorophen, diclobutrazol, diclofop-methyl, dicloran, dienochlor, difenoconazole, diflubenzuron, diflufenican, dimethomorph dioxin diphenyl chloroarsin, Drazoxolon, epichlorohydrin, epoxiconazole, esfenvalerate, ethyl dichloroarsin, etridiazole, fenarimol, fenoxaprop-P-ethyl, fenpiclonil, fenoxaprop ethyl, fenvalerate, flamprop-M-isopropyl, fluazinam, flucythrinate, flumethrin, fluroglycofen-ethyl, fluroxypyr, flusilazole, flutriafol, fomesafen, Gama-HCH, hexachloronaphthalene, imazalil, imidacloprid, loxionine, iodine, iodine, iodine, iodine, iodine, iodine, iodine, iodine, iodine, 4 (4-chloro-2-methylphenoxy) butyric acid, metazachlor, metoxuron, monochlorobenzene, mono linuron, myclobutanil, N- (4-bromophenyl) methyl-1,2-ethanediamine, Nuarimol, Ofurace, Oxadiazon, Paclobutrazol, PCBs, Penconazol, Pentanochlor, Prochloraz, Propachlor, Propaquizafop, Propiconazol, Propyzamid, Prosulfurzen, Pyrenoxen, Pyrenoxen , Quizalofop-ethyl, TCA (trichloroethane), tebuconazole, teflubenzuron, tefluthrin, terbacil, terbuthylazine, tetrabromoethane, tetradifon, triadimefon, triadimenol, triallate, triasulfuron, triazoxide, trichloriclopyrin, trichloroacyloric acid -bromo-1-propyl) phosphate, vinclozolin
Organophosphorus
Demeton, Diazinon, Dichlorvos, Dimethoat, Fenitrothion, Fenthion, Malathion, Mevinphos, Oxydemeton-Methyl-, Parathion, Parathion-Methyl, Triazophos, Tributyl-Phosphat, Trichlorfon, Triphenyltin Oxid (TPTO), Triphenyl-Phosphat, Cresylatiphenyl -S-methyl-sulfone, disulfoton, ethoprophos, fenchlorphos, fonofos, heptenophos, mephosfolan, methamidophos, methidathione, omethoate, phorat, phosalon, pirimiphos-methyl-, propetamphos, pyrazophos, quinalphos, tetrachlorvinphos, trofosyl-phos, thofosyl-thofomyl-thofomyl -Phosphate, trioctyl-phosphate, trixylenyl-phosphate, vamidothione organotin dibutyl bis (oxylauroyi) tin, tetrabutyltin, tributyltin oxides (TBTO), triphenyltin oxides (TPTO), dibutyltin oxides, dibutyltin salt, fentinididatin, fenbutinatin
(3,4-dichloronitrobenzol)
(1,4-dichloro-2-nitrobenzene)
(1,2-dichloro-3nitrobenzol)
1,2,3,4-tetrachlorobenzol)
(1,2,3,5-tetrachlorobenzol)
(1,2,4,5-tetrachlorobenzol)
(2,4,5-trichlorophenol)
(2,4,6-trichlorophenol)

Mercury and its compounds
Mercury compounds, mercury oxides,
Phenyl-mercuric acetate

hydrocarbon
1,2,4-trimethylbenzene, benzene, bitumen, ethylbenzene, fluoranthenene, mineral oil, petroleum oil, styrene, tar acids, tar oil,
TolueneToluene, xylene
CMT
Amitrol, benomyl, carbendazim, thiophanate methyl, thiram, ziram
CMT / hydrocarbon benzo (a) pyrene

The following organic and inorganic biocides can also be added to the porous glass powder according to the invention:
(2-naphthyloxy) acetic acid, (alkylaryl) trimethylammonium chloride, 1-naphthylacetic acid, 4-indol-3-ylbutyric, aldicarb, alkyl benzalkonium chloride, alloxydim sodium, amidosulfuron, amitraz, ammonium carbonate, anthraquinone, asryamam
Thuringiensis, Benalaxyl, Bendiocarb, Benfuracarb, Bentazon, Bitertanol, Bordeaux Mixture (Copper Mixture), Bupirimate, Carbaryl, Carbetamide, Kohlfuran, Carbosulfan, Carboxin, Cetrimid, Chlorine, Cresylic Acid, Cycloxydim, Cymoxanil, Daminozidate, Dazomidide, Dazomidide, Dazomidide , Dikegulac, Dinocap, Diphenamid, Diquat, Dithianon, Dodemorph, Dodin, Ethirimol, Ethofumesat, Fenpropathrin, Fenpropidin, Fenpropimorph, Fenuron, Fluazifop-Pbutyl, Formaldehyde, Fosetyl-Aluminum, Fuberidazole, Hexalicone, Gibbon Acid, Gibonic Acid, Gibbon Acid, Guralaxylibibine, Guralaxylibibine, Guralaxylibibine, Guralaxylibibin hymexazol,
Imazamethabenz-methyl, imazaquin, iodine, isoproturon, isoxaben, lenacil, malignant hydrazide, maneb, mepiquat, metalaxyl, metaldehyde, metamitron, metam-sodium,
Methabenzthiazuron, Methiocarb, Metribuzin, Metsulfuron-Methyl-, Nabam, Napropamide, Nicotine, Nitrothal-Isopropyl, Octhilinon, Oryzalin, Oxadixyl, Oxamyl, Oxycarboxin, Paraquat, Pendimethalin, Peracetic Acid, Phenmedipynic, Phosphoric Acid, Phosphoric Acid, Phosphorous Acid, Phosphoric Acid, Phosphoric Acid, Phosphoric Acid, Phosphoric Acid, Phosphoric Acid, Phosphoric Acid, Phosphoric Acid, Phosphorous Acid Propamo carb hydrochloride, propham, propoxur, pyrethrin, quinomethionate, resmethrin, Rotenon, sethoxydim, sodium sodium chlorate, sodium sodium hypochlorite, sodium sodium monochloroacetate, sodium tetraborate, tebutam, terbutryn, thiabendazole, trifluorosulfuronidomethyl, trifluorosulfuronimethyl-methyl-trifluoromethyl , Verticillium lecanii, Zineb, Zineb-ethylenethiuram disulfide
Ammonia and nitrites
ammonia
Low TPB
4-chloro-2-methylphenoxy acetic acid, dicamba, chlormequat chloride, clodinafop-propargyl, 2,4-dichlorophenoxyacetic acid, 2-chloroethylphosphonic
acid
Taste and odor
methyl tertiary butyl ether

Biocide / Metal
Oxine copper, Mancozeb, Ferbam, Cufraneb, copper ammonium carbonate,
copper hydroxide, copper oxychloride, copper sulfate,
Aluminum ammonium sulfate, aluminum sulfate,
Isopropanol, potassium metasilicate,
Sodium carbonate, sodium metasilicate, sodium silicate

The invention is intended to be explained below of the embodiments to be discribed.

A glass was melted from the raw materials, which was then formed into ribbons or glass bands about 1 mm thick. These ribbons were annealed from 500 ° C to 750 ° C for 5 to 48 hours depending on the glass composition and the desired pore size and pore volume in order to generate the segregation. The annealed ribbons were further processed by dry grinding to powder with a particle size d50 = 4.20 or 100 μm. Powder particles were etched between 10 minutes and 1 hour in an acidic solution such as HCl or HNO ₃ or HF at a temperature ranging from room temperature to 100 ° C. The duration of the etching and the temperature were chosen depending on the desired pore size and the pore volume. The glass is then washed with water, the powder is heated and then dried.

In Table 1 are compositions indicated by porous glasses according to the invention, the after etching with acidic solution the desired Pore size distribution exhibit.

Table 1: Compositions (synthesis values in% by weight on an oxide basis and properties of glasses according to the invention.

In Table 2 below, the annealing time for a 1 mm thick is for the exemplary embodiment 1.1 Glass ribbons at different temperatures and the pore size for different dissolving times in, an 18.3 GeW% HCl (34Mol%) + 17.2 GeW% KCl + 64.5 GeW% H ₂ O - acidic solution.

Table 2 Treatments of the glasses according to working example 1.1

Depending on the duration of treatment different porosities, as indicated in Table 2: Table 3 is for those prepared according to Table 2 glasses, the BET surface, the Langmuir surface, the average pore density and the micropore volume are given.

To characterize a specific special surface of a material can different theories are used. A first option is the Langmuir theory, another is the Brunauer, Emmet, Teller (BET) Theory.

The Langmuir theory means that the gas molecules and the adsorbed molecules are in a dynamic equilibrium, on the so-called Langmuir isotherm. It is believed that the adsorbed molecules are not interact with each other, and that the surface is a comprises monomolecular layer.

The BET theory generalizes the Langmuir theory on the adsorption of multilayer BET isotherms The exact method for determining the surface according to BET is in DIN 66131 described.

The average size of the micropores is preferred smaller than 300 nm and larger than 2 nm.

The pore volume of the micropore area is the sorbed volume at the end point of the isotherm p / p0 = 1 (p: Gas pressure, pressure of the sorptive, p0 saturation vapor pressure of the sorptive).

Table 3: Porosity of the glasses according to Table 2

From Table 3 it follows that it is possible with the glasses according to the invention to heat the desired specific surface, the porosity and the size of the micropores by means of appropriate etching processes and adjust the porous volume, which is determined by the number of micropores, of the porous glass according to the invention.

The tempering step generates phase segregation in two main phases: a SiO ₂ -rich and a B ₂ O ₃ -rich phase. The two phases are linked. The volume and size of the phase segregation depend on the tempering conditions such as temperature and time.

The 1a to 3a show SEM images of the exemplary embodiments A1 ( 1a - 1b ), B1 ( 2a - 2 B ) and C1 ( 3a - 3b ) from tables 2 to 3.

As you can see on the figures, can depending on the temperature and etching process get different porous surfaces become.

On the 1a for example, you can see the particles and their shape. On the 1b you can see the surface of the resulting particles. 1b is an enlarged section of 1a , The pores in 2a are larger than the pores according to the embodiment 1a , because the tempering time of the glass is longer, ie the boron-containing phase in the separated glass is larger.

The pores according to the embodiment 3a are larger than the pores according to the embodiment 1a , because the tempering temperature is higher, ie the boron-containing phase in the unmixed glass is larger.

The porous borosilicate glass according to the 1a To 4b can be filled with active substances as described in the previous sections, which can then be released slowly. It is also possible to absorb substances, for example sweat, in deodorant applications.

Below is an embodiment one about the sol-gel route made glass.

Pretreatment of the used glassware and - vessels were made by rinsing with 2 N HCl, subsequent Wash with demineralized water and dry at 100 ° C. The Sol-Gel process The glass produced was powdered with a dry grinding Particle size in the Range 3–15 μm processed. In the sol-gel process, the desired organometallic compounds, such as metal alcoholates or metal salts, glasses (e.g. carbides, nitrides) manufactured. While Drying process, which can be compared to an etching process can the porosity of the glass set.

Suitable in addition to the borosilicate glasses also largely water-insoluble silicate glasses as starting material for porous Glasses. The pore size distribution will in these glasses by etching with acids like manufactured as described above.

The parameters around the porosity of glasses over the Sol-gel route are produced: the amount of water in the organometallic compounds in the sol, and the drying process of the Gels, i.e. the temperature and time of drying are in Table 4 the compositions and properties of glasses according to the invention are given.

Table 4: Compositions (synthesis values in% by weight based on oxide) and properties of glasses according to the invention.

4 shows the surface of a spray-dried sol-gel glass according to Table 4. 5a and 5b show the surface of a glass particle that can be wet ground in 4 glass powder shown was obtained.

In addition to the borosilicate glasses, the silicate glasses produced by the sol-gel process silicate sintered glasses also have a porosity according to the invention. A composition of such a sintered glass is given in Table 5 as a further exemplary embodiment of a porous sintered glass.

Table 5: Glass with the composition in% by weight on an oxide basis

For the production of the porous sintered glass according to the embodiment 3-1 in Table 5 shows the starting substances in an attritor mill in water to an average grain size of approx. 1 µm ground and then in uniaxial fittings pressed and in the oven at 620 ° C Sintered for 20 min. The average pore size of the glass thus obtained was about 0.5 µm. The compact was then cut to a grain size of approx. 15 um ground up again.

To get a biocidal jar, in which the pores of the sintered glass are infiltrated, a Silver nitrate solution ground together with the glass powder in a drum mill. After subsequent drying the silver nitrate is in the pores.

Claims (37)

Use of porous glass powders with an average Pore diameter from 0.0005 μm - 500 μm and with an average particle size of 500 nm to 500 μm and one Pore diameter to particle size ratio of <0.2 with and without filling in cosmetics. Use of porous glass ceramic powders with an average pore diameter of 0.0005 μm - 500 μm and with an average particle size of 500 nm to 500 μm and one Pore diameter to particle size ratio of <0.2 with and without filling in cosmetics. Use of porous glass powders with an average Pore diameter from 0.0005 μm - 500 μm and with an average particle size of 500 nm to 500 μm and one Pore diameter to particle size ratio of <0.2 with and without filling in or as biocides. Use of porous glass ceramic powders with an average pore diameter of 0.0005 μm - 500 μm and with an average particle size of 500 nm to 500 μm and one Pore diameter to particle size ratio of <0.2 with and without filling in or as biocides. Use of porous glass powders with an average Pore diameter from 0.0005 μm - 500 μm and with an average particle size of 500 nm to 500 μm and one Pore diameter to particle size ratio of <0.2 with and without filling in the area of health care. Use of porous glass ceramic powders with an average pore diameter of 0.0005 μm - 500 μm and with an average particle size of 500 nm to 500 μm and one Pore diameter to particle size ratio of <0.2 with and without filling in the area of health care. Uses of porous glass powders / glass ceramic powders according to any one of claims 1-6, wherein the glass powder / glass ceramic powder via phase separation after tempering the glass and subsequent Ent removal of at least one phase with an acidic solution. Use of porous glass powders / glass ceramic powders according to one of the claims 1-6, where the glass powder / glass ceramic powder from a sintering process Glass powders or glass ceramic powder are produced. Use of porous glass powders / glass ceramic powders according to one of the claims 1-6, where the glass powder / glass ceramic powder over an organometallic or inorganic sol-gel process. Use of powders according to claims 1-9, wherein the pore sizes in the range of 0.0005 μm - 500 μm. Use of powders according to claims 1-9, wherein the pore sizes in the range of 0.001 μm - 10 μm. Use of powders according to claims 1-9, wherein the pore sizes in the range of 0.001 μm - 1 μm. Use of porous powder according to claim 1 to 12, the particle sizes being <1 mm. Use of porous powder according to claim 1 to 12, the particle sizes being <500 μm. Use of porous powder according to claim 1 to 12, the particle sizes being <50 μm. Use of porous powder according to claim 1 to 12, the particle sizes being <10 μm. Use of porous powder according to claim 1 to 12, the particle sizes being <5 μm. Use of porous powder according to claim 1 to 12, the particle sizes being <1 μm. Use of porous powder according to claim 1 to 12, the particle sizes being <0.5 μm. Use of porous powder according to claim 1 to 12, the particle sizes being <0.1 μm. Use of powders according to any one of claims 1-20, wherein the composition of the glasses in the following range is in wt .-% on an oxide basis SiO ₂ 50-100 wt .-% B ₂ O ₃ 0–40 wt .-% Na ₂ O 0 -20% by weight Al ₂ O ₃ 0-5% by weight Use according to claim 21, wherein the glass composition has SiO ₂ between 53 and 72% by weight. Use according to one of claims 21 to 22, wherein the glass composition B ₂ O _{3 has} between 20 and 35 wt .-%. Use according to one of claims 21 to 23, wherein the glass composition Na ₂ O has between 4 and 12% by weight. Use of powders according to any one of claims 1 to 20, wherein the composition of the glasses in the following range in wt .-% on an oxide basis SiO ₂ 53-72 B ₂ O ₃ 20-35 Na ₂ O 4-12 Al ₂ O ₃ 0 -5. Use of powders according to any one of claims 1 to 20, wherein the composition of the glasses is in the following range SiO ₂ 40-90 B ₂ O ₃ 0-10 P ₂ O ₅ 0-20 Na ₂ O 0-20 K ₂ O 0-10 CaO 4-45 MgO 0-5. Use of powders according to one of claims 1 to 6 and 8, the composition of the glasses being in the following range SiO ₂ 40-90 B ₂ O ₃ 0-10 P ₂ O ₅ 2-20 Na ₂ O 0-20 K ₂ O. 0-10 CaO 4-45 MgO 0-5. Use of porous glass powders / glass ceramic powders according to one of the claims 1-27 in Paints and varnishes. Use of porous glass powders / glass ceramic powders according to one of the claims 1-27 in Plasters, cements and concrete. Use of porous glass powders / glass ceramic powders according to one of the claims 1-27 in Anti-fouling products. Use of porous glass powders / glass ceramic powders according to one of the claims 1-27 in cosmetic products. Use of porous glass powders / glass ceramic powders according to one of the claims 1-27 in Deodorant products. Use of porous glass powders / glass ceramic powders according to one of the claims 1–27 in Oral hygiene, dental care, oral care. Use of porous glass powders / glass ceramic powders according to one of the claims 1–27 in Polymers division. Use of porous glass powders / glass ceramic powders according to one of the claims 1–27 herbicide. Use of porous glass powders / glass ceramic powders according to one of the claims 1-27 in Fungicides. Use of porous glass powders / glass ceramic powders according to one of the claims 1-27 in Pesticides.