TH20344B - Mixture for dimensional control, brilliance, coated steel products and methods. - Google Patents

Abstract

DC60 (25/06/47) Method for coating steel products such as large sheets. And sheet using alloy coating Aluminum-Zinc Including improvement of bath, coating with particle components in Effective amount to control the shiny face size of glaze products, improve the properties of Against the rust from stress, warping, improving the appearance of the coated surface. When brushed, and the paintability of the coating Ingredients include various borides. Such as titanium boride and aluminum boride, carbides such as titanium carbide, and aluminide such as titanium aluminide.This method yields coated steel products that No need to iron and smooth for painting. How to coat steel products like large sheets And sheet using alloy coating Aluminum-Zinc Including improvement of bath, coating with particle components in Effective amount to control the luster of the coating product, improve the Against the rust from stress, warping, improving the appearance of the coated surface. When brushed, and the paintability of the coating Ingredients include various borides. Such as titanium boride and aluminum boride, carbides such as titanium carbide, and aluminide. Such as titanium, aluminide, this method produces coated steel products that do not need to be smoothed for painting.

Claims (5)

1. Method of iron products using bath (bath) molten aluminum-zinc alloy, the modification of the composition by changing the composition of the aluminum-zinc alloy by adding the resulting quantity of one or more of the compound components. As a spangle that results in a spangle coated on a substrate equal to between about 400 and 500 microns, the particle compound that makes the pattern smaller was selected from a group consisting of: Boride compounds, the amount between approximately 0.0008 to less than 0.0012% by weight, and containing either titanium and aluminum 2. Method of claim 1, where the particle constituents are TiB2, AlB2. , And either AlB12 3. Method of claim 1, where the particle size of the particle compound component It is in the range between approximately 0.01 microns and about 25 microns. 4. Method of claim 2, where the particle size of the compound particle component is The range is between approximately 0.01 microns and about 25 microns. 5. Method of claim 1, which is also included in the metal bath process. The main mixture of aluminum And adding a certain amount of the particle compound component to it, and then adding the main alloy bath to the bath, the aluminum-zinc coating was applied. In proportion to do To obtain effective quantities of the constituent particles. 6. Coated steel products containing iron substrate. And aluminum-zinc coating on it, the improvement consists of aluminum-zinc coating Was modified by the quantity that yielded Of one or more of the particle compound components selected from the composite group With either titanium and aluminum boride compounds, the coating characteristics Aluminum - such a zinc The luster size is between approximately 400 and 500 microns. 7. Product of Claim 6, where the aluminum-zinc coating. Was tampered with Such boride compounds 7. Product of claim 7, where the particle size of Clause 7 is TiB2, AlB2 and AlB12. 9. Product of claim 7, where the particle size of Claim 7. Compound that is The coating particles ranged from approximately 0.01 microns and approximately 25 microns. 1 0. Aluminum-zinc coatings mixtures. A steel substrate was coated with a luster size of between about 400 to 500 microns, an improved aluminum-zinc alloy composite. That includes the resulting quantity of one or more of Particle component selected from a group containing Boride compounds in Dosage between approximately 0.0008 and less than 0.0012% by weight, and with either titanium and aluminum 1 1. Mixture of claim 10, where the constituent constituents are either TiB2, AlB2, and AiB12 1 2. Mixture of claim 10, where the particle size of the compound component is The coating particles range between approximately 0.01 microns and approximately 25 microns. 3. Mixture of claim 10, where the constituent particle is the boride compound. And the amount of particle compounds in the bath The alloy ranges between approximately 0.0008 and 0.0012% by weight, of boron 1. 4. Method of claim 1 which, also consists of painting coated steel products. Without using coated steel products to adjust the surface 1 5. Product of Claim 7, which continues to include the surface painted on enameled steel products.