TH29656B - Can and dry antimicrobial coatings - Google Patents

Abstract

The disclosures are pyrithione-containing coatings that exhibit a combination of preservation. In a can that resists microbial attack Combined with the anti-microbial efficiency of the film Dryness resulting from applying the coating component on the substrate. Also disclosed is a process. For efficacy against microorganisms in the can And dry film to the elements Acquias Patent Drug Coating

Claims (8)

1. Composition Acquyte coatings that include: (a) water, (b) basic intermediates, (c) selected zinc compounds from the group containing zinc oxide, zinc hydroxide, salt of Sync And their combination, and (d) non-zinc pyrithione pyrithione salts, alone or in conjunction with zinc pyrithione where the pyrithione salts are Was selected from a group consisting of sodium pyrithione, tercia rebutylamine pyrithione, aluminum pyrithione, calcium pyrithione, potassium pyrithione. , Magnesium pyrithione, barium pyrithione, and combinations thereof, where such zinc compounds are present in the composition in amounts between 0.001% and 10% with respect to the weight of the elements. And where pyrithione salts are present in the composition, in the molar ratio of the pyrithione salts to the said zinc compounds between approximately 1:10 and approximately 10: 1. 2. The coating component of claim 1, where the base medium is polymer-latex. 3. Method for providing anti-microbial efficacy of coating elements. The actuase consists of the procedure of: (a) exposure to the component with sodium pyrithione, in the amount of sodium. Such pyrithione is between 0.1% and 2% by weight as compared to the weight of the element. And (b) exposure to the component with zinc oxide, in amounts between 1% and 10% by weight, relative to the weight of the coating component. And reacts at least part of the zinc oxide with at least part of the sodium Such pyrithione, therefore, is Conversion of Sodium Pyrithione to Zinc Pyrithione 4.Process for coating the substrate with a coating element to obtain a coating. Showing anti-microbial efficacy on that substrate This includes the steps of: (a) the inclusion of the coating component. Between approximately 0.01% and approximately 0.5% by wt, relative to the weight of the coating composition, of soluble pyrithione salts. That solubility at 20 ํ at least 4,000 parts per million. (B) the inclusion of a compound containing metal ions into the coating element in amounts between 0.001% and 10% wt, relative to the weight of that coating element, to make at least a fraction of the Compounds containing such metal ions Transcended with at least part One of the aforementioned soluble pyrithione salts, thus creating a metallic coating component. Pyrithione is formed, which pyrithione metal is soluble in the substance. Less than 100 ppm of such coatings, (c) the contact of the substrate with the coating composition containing the pyrithione metal to form a pyrithione-based coating on the substrate. Said, and (d) drying the coatings containing the pyrithione metal on the said substrate to create The dry film on the substrate, in which the dry film has an effective anti-microbial and leak-proof content of the pyrithione metal. 5. Process of claim 4, where compounds containing such metal ions are selected from A group containing metal salts, metal oxides, metal hydroxides. And the combination of these 6. Process of claim 4 where the compound containing the aforementioned metal ions is made up of metal ions chosen from groups containing zinc, coper, titanium and aggregation. Together of all these 7. Process of claim 4, where such soluble pyrithione salts are selected from the group containing sodium pyrithione, tertia, butylamine, pyrithione, Luminum pyrithione, calcium pyrithione, potassium pyrithione, magnesium pyrithione, barium pyrithione, and their incorporation. 8. Process of claim 4, where the molar ratio of the aforementioned soluble pyrithione salts to compounds containing such metal ions is between approximately 1:10 and approximately 10: 1.