TH3748B - Ceramic materials containing polymer components and methods of their application for this purpose. - Google Patents

Abstract

Method for the manufacture of self-adhering ceramic fuselage with polymer segments. This includes initially arranging the Cera fuselage. A self-adhering mic consisting of (i) the product of making Polycrystalline oxidation reactions that occur within under the oxidation of the molten parent metal with the oxidant; and (ii) the interconnected permeability. where at least there will be some Sections open to or accessible from one or more surfaces of the body. Polymers are placed or joined together. within the permeability that are interconnected The polymers are in The position to change and improve further to the properties of the ceramic body that happened earlier.

Claims (8)

1.Method for manufacturing self-adhesive ceramic hulls. With a piece of ceramic assembled This method will consist of The procedure is as follows: (a) the arrangement of a self-adhesive ceramic body consisting of (i) the product of polycrystalline oxidation. Ristalline formed under oxidation of primary molten metal. Liquids with oxidants and (ii) interconnected pores. With at least some parts open or accessible from the skin Face at least one side of the aforementioned ceramic body; Then (b) taking the polymer to at least part of the pores Such to make a ceramic body with a piece of poly 2. A method for producing a self-adhesive ceramic body containing a piece of polymer. By such method will It consists of the following steps: (a) the arrangement of a self-adhesive ceramic body consisting of (i) polycrystalline oxidation products. Ristalline formed under oxidation of primary molten metal. Liquids with oxidants and (ii) interconnected pores. Where at least some parts will be opened to or accessible from The surface of at least one side of the aforementioned ceramic body; And (b) the contact of one or more such surfaces of the The ceramic body contains a certain amount of polymers sufficient to fill at least part of the attached pores; And (c) permeability into at least part of the pores at Connected between them, with at least part of The amount of such polymers To make a ceramic body 3. A method for manufacturing a self-adhesive ceramic body containing a piece of polymer. By the above method will be assembled Well, the steps are as follows; (a) the provision of a self-adhesive ceramic body consisting of (i) the product of polycrystalline oxidation; Ristalline formed under oxidation of primary molten metal. Liquids with oxidants and (ii) interconnected pores. Where at least part of it is opened to or accessible from the skin Face at least one side of the aforementioned ceramic body. (B) Direct polymerization in at least part One of the aforementioned In order to produce a ceramic body that Contains a piece of polymer. 4. Method for manufacturing a self-adhesive ceramic body containing a part of the polymer. By the above method will be assembled With the steps of: (a) arrangement of a self-adhesive ceramic body consisting of (i) the product of polycrystalline oxidation. Ristalline formed under the oxidation of the parent metal at Melts with oxidants and (ii) interconnected pores where at least partially open to or accessible. From at least one surface of the aforementioned ceramic body; (b) determination of the position of the ceramic body in the reaction region; (c) Permeability at least part of the body seepage. Ceramics in the reaction area With a fluid that can be polymerized which will form a polymer under conditions Of being a polymer; And (d) the permeable ceramic body was taken in the processing area. The reaction provides a condition of polymerization in order to form a ceramic body containing a component of the polymer 5. Method as described in claim 1, or Either 2 or 3 or 4 Where the parent metal consists of At least one part of the material selected from the group consisting of aluminum, silicon, titanium, tin zirconium and hafnium 6.Methods as described in Claims 1 or 2 or 3 or 4. Any one Where the parent metal is composed of aluminum and the product of polycrystalline oxidation Ristal Line included with Alumina 7.Method as set out in any of Clause 1 or 2 or 3 or 4. Where the connected pores Between them there are 5 to 45% by the volume of the staggered body. Ramic before the ceramic body is seeped out or wet with polyurea. 8. Method as described in one of Claims 1 or 2 or 3 or 4. Where the ceramic body that holds the body By itself, will continue to be filled with a filler through the product of The polycrystalline oxidation process 9. The methods described in Clause 8 include vaporization with an additional step of filler contouring. Full of such a prototype 1 0. Self-adhesive ceramic body. Which contains products from Polycrystalline oxidation reaction occurs. Under the oxidation of the parent metal with molten and there is contact with each other. Where at least those pores This will open onto or be reached from at least the surface. One of the aforementioned ceramic body And polymers are positioned in At least part of the aforementioned 1 1. Means as specified in either Clause 1, 2, or 3 or 4. Where the ceramic body is It consists of metal parts that are connected with each other, with at least some part open to or accessible from the surface. At least one side of the aforementioned ceramic body. And by the body The ceramic is placed in the heating zone to the stage (b), causing at least part of the interconnected metal component to ion from the ceramic body 1. 2. Means as specified in Clause 1 or 2 or 3 or 4 of any of the above. Where the ceramic body is It consists of metal parts that connect with each other, with at least some of them accessible from at least the surface. One of the aforementioned ceramic body And by which the ceramic body is loud It is said to be immersed in the body before reaching the step of (b) to at least dissolve the metal. Some contact with each other from the aforementioned ceramic body 1 3.Methods of manufacturing self-adhesive ceramic components Where they contain polycrystalline materials that contain The oxidation product of the parent metal and the oxidant, whereby the ceramic component has a polymer component, the method consists of steps of (a) positioning. The parent metal is closer to the permeable mass. Of the filler material and the adoption of such parent metal and filler Come together to each other So the formation takes place of production The oxidation packaging of the parent metal takes place in Direction directed and into the mass of the said filler; (b) heating the parent metal until it reaches above point Its melt But lower than the melting point of the product from the making Its oxidation reaction To form the body of the parent metal And the reaction of the parent metal molten with the oxidant at Such temperature To form an oxidation product and at that temperature it remains a part of At a minimum, of the oxidation products come into contact and expand between the molten and oxidant metal itself. To pull the molten metal through the reaction products Sidion is headed towards the Sundance exit. And concentrate into the mass of the material of The fillers are close together, so the products from the The new oxidation reaction takes place again. Continuous within the mass of the surface fillers during oxidation Dants and products from previous oxidation reactions; (c) The continuation of the said reaction for a time when This is enough to embed at least part of the filler. Products from such oxidation reactions. In order to create a ceramic component; (d) the formation of a partial puncture, at least in the denominator Assembling the ceramics by using a one-step practice process. At least Selected from a group consisting of navigation Took the oxidation process to the end And evaporation The molten residue from the ceramic component and the leaching of the residual parent metal from the ceramic component and the leaching of the residual parent metal from the denominator. Ceramic assembly; And (e) the least part of the polymer addition. Of the created holes In order to establish himself A ceramic component containing a polymer component 1 4. The methods described in Clause 13, where the dosing of the said polymer contains a minimum One selected stage from a group consisting of one selected stage from a group consisting of The infiltration of the polymer. In the very least, part of the denominator of the ceramic component and the polymerization directly in part is The least of the ceramic components And partial seepage Is the least of the ceramic components in the area of Reacts with a polymerization fluid that forms a polymer within the term of polymerization 1. 5. Methods set out in Clause 13 or 14, whereby a parent metal is composed of a material At least chosen from the group Which contains aluminum, silicon, titanium, tin, zirconium and hafnium. 6.Method as described in any of Clause 13 or 14. Where the parent metal is composed of aluminum and is produced Packaging from the oxidation of the polycrystalline that Contains 1 alumina 7. The method described in any Clause 13 or 14 whereby the interlocking pores are approximately 5 to 45% by volume of the first ceramic component. On the ceramic component there is a polymer in it 1 8. Methods for producing self-adhesive ceramic body by oxidation of parent metal. To create a polycrystalline material Containing (i) products of oxidation Of the parent metal (Ii) The least residual parent metal contains: (a) heating the parent metal to a temperature above the melting point of It is, however, below the melting point of the product from oxidation to form a molten metal body; (b) Reaction to the molten parent metal with oxidant that Is in a vaporous condition at such a temperature To create a Oxidation products; (c) Maintaining a minimum portion of the product from Oxidation reaction In contact with and in between The parent metal is molten and oxidant thereof. To extract the parent metal Liquid through products of oxidation reaction directed towards So oxidant Oxidation products Emerging Will create a continuation at the connection area During the oxidant And products of the previous oxidation reaction; (d) The continuation of the said reaction for a time when Sufficient to manufacture such a ceramic body; (e) Creating a minimum partial permeability in the ceramic body. By taking at least one of the operating steps selected from the group, which consists of the lead process. Of the oxidation to the end of the process and evaporation of the residual parent metal from the ceramic body and leaching The residual parent metal from the ceramic body; And (f) the least part of the polymer addition. Of the created hole This is to create a component. Ceramics with polymer parts included (18 claims, 6 pages, 7 photos).