TH3750B - The process of manufacturing a ceramic substrate with a filler material that is porous in it. - Google Patents

Abstract

The manufacturing process of ceramic based objects using a perforated base or pre-defined part of the filler material. filled with molten metal in a state of vaporized oxidant use To have effect and permeability on the inclusion of Po matrix. Li-crystalline of the oxidation product of metal to the base of the filler or predetermined by at the base of the filler material or the defining part Before there was a system of the first opening of the contact permeable hole. between the rough and the system of the second compartment of the welded permeability More granular interactions, where parts of the filler material remain permanently structured in the arrangement. Pre-determined preparation during permeation

Claims (5)

1.Method of manufacturing ceramics It consists of a filler material that acts as an inert compound. In the ceramic matrix of the oxidation products, which includes the steps of: (a) the body conductivity of the parent metal and the permeable mass of the material. The fillers relate to each other. For filtering through Of the products of the oxidation reaction into the permeable mass; (b) in the state of the use of vapor oxidant Melting of the body of the parent metal and the reaction of the molten metal with oxidant. To form as a product of oxidation By heating to a set temperature and that temperature will maintain At least part of the product from the said oxidation reaction. Keep in touch with and stay Between the bodies of the molten metal And the oxidant thereof in order to draw The metal quickly melts through the product of the reaction. Oxidation to the exit, the oxidant and the filler material, therefore, the oxidation reaction takes place continuously within The mass of the filler material, so the reaction is removed Oxidation occurs continuously within the mass of the material being Fill in such At the surface area between the oxidant and the fruit It is produced as a result of a previous oxidation reaction and will allow that reaction to continue for a sufficient time. That permeability is at least part of the said mass of the filler material 2. Method as specified in claim 1, where the permeable mass consists of a group of fillers material. Is in Particle model Which in itself is a crystal light that has Of the latent pores included permanently The second channel system is also defined. And between the crystals containing the underlying active ingredients With the inside of each group And the system of the first cavity consists of a cavity defined between the next groups within the permeable mass 3. Method as specified in claim 2, whereby the group It consists of large proportions by their weight and small proportion. The weight of the particles is less than the non- 4. The method specified in claim 3, whereby the aforementioned group In such permeable mass There is a space between them. And where the fraction of the aforementioned smaller particles is in Where the smaller particles fill all the gaps 5. Method according to claim 2, whereby the group It is said to be a predetermined part of a self-adhesive body. This consists of arresting the said group together. 6. Method as stated in Clause 2, whereby the group It is the uncrolled porous particles of Alpha Alumina produced by the alumina calcination. Tri-hydrate and each The body contains a large number of alpha alumina crystals. 7. Method as described in Clause 6, where the material is aluminum. Such a border is oxygen. The nodules are in the atmosphere and the products of the reaction are alpha alumina 9. Methods specified in claim 2, whereby the nodules It is spray-dried or blown-dried or nodized and some are sintered particles that will act inert under the process conditions of the aforementioned methods. 1 0. Methods as specified in Clause 2, where the nodules are spray-dried or dehydrated, or to form metal powder particles. Which will be captured by doing Reaction by Nitration or Oxidation Method 1 1. Method as described in Clause 2 in which the nodules are to be formed with the drying carbothermic retention. Or nodular particles of the original metal oxide 1 2. The method identified in claim 1, where the permeable mass is a prototype that is assembled from the bundle. Or a row of fibers By the first system It consists of gaps or holes between adjacent bundles or rows, and the puncture system is made up of spaces between adjacent fibers in each bundle or row 1. 3. Methods specified in Clause 12, whereby the fibers are not inert. Under the conditions of the aforementioned methods, but is coated to be inert under process conditions Method of the aforementioned 1 4. Method as specified in claim 1, where the permeable mass is structurally spongy, a ceramic sponge that is branched out, where the gap between the branches of the ceramic lies. Next together is the first seepage system. With very small holes Connections spread throughout the branches of the ceramics. To make up Second seepage system 1 5. Method of Creating Ceramic Objects Containing Body Material Inert fill is integrated in the ceramic matrix of the manufacture. Oxidation products That includes the steps of: (a) the conductivity of the parent metal and the permeable mass of the body material. Complement each other To penetrate the product from the making Oxidation reaction into permeable mass: (b) In a vapor oxidant atmosphere. Will melt the body The parent metal and molten metal reacts with oxidants to form a product of oxidation by heating it to a specified temperature. And at that temperature will Heal part At least Of products from making Oxidation reactions are in contact with and between the molten metal. Liquid and oxidant thereof In order to pull the molten metal Liquid passes through the oxidation products directed towards the oxidant and the filler material. Therefore, the products from the Oxidation reactions continue to build up within the mass. Of such filler material At the surface of the connection between Oxidants and products from oxidation reactions that Happened earlier And the reaction is continuous as Sufficient time to permeate a part At least Of the mass of such filler material Where enhancement consists of: (c) permeable mass Consisting of the first seepage system They form the pores between the material distributed throughout the mass, and the second system of the pores is the permeation between the diffused materials. All over the mass as well Where both systems of the pores are defined internally Or between sections Of the filler material And, at the very least, the different parts of the filler material define the second seepage system. Which has a stable structure during the penetration of products from This permeable mass consists of a material or object chosen from a group consisting of: (1) a nod of filler material is a particle in which It itself is a nodular with a structurally stable crystallite pore and a secondary pore system defined between the body. The constituent ristallite within each nodule and the first puncture system consists of a space defined between the nodules. Adjacent to each other within the permeable mass, (2) a pre-formed model of the bundle or row of fibers by the first penetrating system consists of a gap between the bundle or row. Adjoining And the second seepage system Will contain spaces Between the chicfaced fibers in each bundle or row, and (3) the spongy structure of the ceramic branch Where the gap Between the branches of the ceramics that are adjacent Constitutes a perforation system One where there is a small pores connected to each other within Branch of ceramics To make up the second seepage system (15 claims, 5 pages, 5 photos)