TH3816B - Method for making molded ceramic components using cross-sections - Google Patents

Abstract

This invention relates to a method of producing ceramic pieces that are self-stable by oxidation of parent metal. formed a polycrystalline ceramic material composed of Importantly, it is the product of the oxidation reaction of the parent metal. as with oxidant that is a vapor-type oxidant and on the other hand If one is one or more metallic elements, the method consists in the process of having at least a portion of the parent metal thereof with at least a portion of the barrier. Stay away from such Parent Metals to make it at a minimum. One surface of the ceramic piece heat the raft Such metal at a temperature higher than its melting point, but lower than the melting point of oxidation products to resulting in molten metal At that temperature, the molten metal reacts with oxidants to form products of oxidation reaction At least part of the oxidation product remains Maintains contact and is between molten metal and oxidant to move the molten metal through the oxidation product to the barrier and come into contact with the oxidant so that the product from Oxidation reactions continue during The surface between the oxidant and the product of the oxidation reaction either pre-existing or allowing the metal to be dispersed throughout the polycrystalline material. This reaction continues up to the barrier to produce A ceramic element with a face set up by a barrier. The component is made by stacking the barrier on a filter material. such as the main frame and infiltrate the filler with matt The polycrystalline ceramic rix that is raised on the cross section is

Claims (6)

1. A method for producing self-resisting ceramic pieces by oxidation of parent metal to form polycrystalline materials. Ristalline, which contains the product of oxidation of Parent metal with the least oxidant type. One which includes oxidant in a vapor state Such method Consists of the steps of (a) given to at least the section One of the parents The metal has a barrier, at least some of which is placed. Away from the said parent metal to at least cause Is one side surface of a ceramic piece (b) heats Such metal until the temperature is higher than its melting point, but Below the melting point of the products from the oxidation reaction to Resulting in melted parent metal pieces (c) react The metal is melted at this temperature with the oxidant. Said to make (D) maintains at least part of the oxidation effect. To touch and be between the parent metal melting and The said oxidant It moves parent metal, melts through the produce. From oxidation reaction to the said barrier and to To come into contact with the oxidant to yield the reaction The resulting oxidation continues at the interface between the oxidant and the products of a pre-existing oxidation reaction, and (e) continues the reaction until the reaction is produced. out Such sidation is in contact with such a barrier to produce Such a layer of ceramic with such a surface formed by 2. Method for manufacturing a stable ceramic component structure by On its own that contains the mass of the inserted filler material. Absorbed by the oxidation-derived ceramics of parent metal to Resulting in a polycrystalline material. Polycrystalline material It contains the products of the oxidation reaction of Such metal with at least one kind of oxidant. Which includes oxidants in a vaporized state Such method It consists of the process of (a) heating the parent metal to a high temperature. Than its melting point, but lower than its melting point, but low Than the melting point of the products from the oxidation reaction to make To occur parent metal melting (b) in contact with an area of the mass of With such a parent metal piece, the mass of such a filler material is at least one surface bounded by a least partial barrier. To be placed away from The contact area to produce the effect of the reaction. Such oxidation can occur within the mass of the filler material. And in the direction directed to the said barrier. Can be formed within the mass of the filler material and in the The direct path to the barrier (c) reacts Such metal at this temperature with the oxidant. Said to make (D) Maintain at least part of the oxidation effect. As mentioned above, touch and be in between the Parent Metals. With the aforementioned oxidant moving parent metal further melting by Through the products of the oxidation reaction to the oxidant so that The product of the new oxidation reaction occurs continuously. Continually at the boundary between the said oxidant and the products of Oxidation reaction The predecessor, which penetrates the mass of the filler material. And (e) continued such reaction until The products of this oxidation reaction come into contact with the cross section. Such barriers to produce such a structural ceramic component. 3. A method for producing ceramic components with a required shape consisting of at least a stabilized main frame. By itself, a piece of which is infiltrated with a ceramic matt. Rix obtained from the oxidation of parent metal to make Polycrystalline materials were formed. Such polycrystalline materials. Contains the product of parent metal oxidation reaction. Such as with at least one type of oxidant which includes This method consists of the procedure of (a) heating the parent metal to a temperature above the melting point of the It's, but below the melting point of the products of the oxidation reaction. To make this happen, parent metal melting (b) requires at least Most of the main frame pieces are self-stabilized and shaped. The figure is then at least one piece, having at least a surface. One that is scoped by a barrier. At the very least, one such main frame would result in infiltration. Production of such an oxidation reaction (c) touches an area of At the very least, one such main frame with a The aforementioned silver metal on the surface of at least that One of the main frame pieces, which is placed away from the area. Touch it to produce the effects of the reaction. Such zidation can occur internally, at least. One such main frame and in a direct direction towards the surface (d) reacts such parent metal at The temperature with the said oxidant to cause As a result of this oxidation reaction (e) remains at least at Most of the products from the said oxidation give Touch and lie between the Parent metal melting and the Ox The dant moved to the parent metal forging further through production. The result of the oxidation reaction The release goes to oxidant to produce a product of the reaction. The emerging oxidation continues at the junction. Between the said oxidant and the products of the reaction Pre-existing zidation that has penetrated at least One such main frame and (f) reacts as Continue to say until the product of the said oxidation reaction penetrates At least one such main frame And contact with the said barrier to produce components The aforementioned ceramics and traces of at least the frame pieces. One such main piece and the surface that arose from 4. Method for claim 1, 2 or 3, any one of the above Which such barrier cannot be wet with Crust metal forged 5. Any method of claim 1, 2 or 3 that Which the above barrier will react with parent metal melting Such as in contact with the above mentioned parent metal to make Resulting in, at the very least, the product of a reaction which will Block the movement of the melted parant metal through production. 6. Any one of claim 1, 2 or 3 method that Which the above barrier consists of at least the type One can be selected from the group containing calcium sulfate. Calcium silicate Fortland Cement Tri Calcium Phosphate, and Mixtures of these substances; 7.Method of claim 6, where the barrier is It also contains at least one volatile material. Which will evaporate when heated and at lower temperatures The melting point of the products of the said oxidation reaction. To help the barrier to allow the permeation. Obtained oxidant in such a vapor state. 8. Method according to claim 6, where the barrier is It contains at least one type of filler material. 9. Method according to claim 8, where the barrier is It contains at least the filler material in powder form. One type of fine grain mixed with such a barrier. Filler material Most of the above powder form has coefficient of expansion. Is equal to that of the filler material or the main frame that is embedded in it. In a ceramic matrix 1 0. Method according to claim 8, where the barrier is It consists of filler material containing alumina 1. 1. Method of claim 1, 2 or 3. Where the barrier contains calcium sulfate and At least one type of material can be chosen from that group. Contains silica and calcium carbonate 1. 2. Method of claim 1, 2 or 3, either. Where the parent metal is composed of aluminum 1. 3. Method of claim 1, 2 or 3, any one Where at least that barrier consists of One type of steel or ceramic. Fold 1 4. Method of claim 1, 2 or 3, either. Where the parent metal consists of the metal selected from Groups that embrace silicon, titanium, tin, zirconium and hafnium 1 5. Any method of claim 2 or 3 that The said oxidant consists of at least material type. One to choose from: Solid Oxidant, Liquid Oxidant, and Liquid Oxidant Mixture Coexistence with the filler material or the aforementioned structural parts 1 6. Method of claim 15 where the oxidant is Contains selectable oxidants from silica, boron and reducingable boride groups 1 7. Methods of claim 1, 2 or 3. Where the oxidant in such a vapor state consists of oxid Selectable dants from groups containing oxygen-containing gases, containing nitrogen, halogens, sulfur, phosphorus, arsenic, carbon, boron, selenium and their mixtures 1 8. Method of claim 17, where Loud oxidant It consists of 1 9. Method for claim 17, where the oxidant as The said filler 2 0. Method for claim 2 and claim 3 where the filler material or the said main frame is assembled. With the materials selected from the group consisting of hollow objects, granules, fiber objects, fibers, steel wool, sheets, rods, pellets, tubes, high-temperature canvas and a mixture of such materials 2 1. Method of claim 2 and claim 3rd right where such filler material or the said main frame is assembled With at least one type of single metal oxide of metal Selectable from groups consisting of aluminum, cerium, hafnium, lanthanum, neodymium, praziodium, samarium, standium, thorium, uranium, lutrium and zirconium. In pursuance of claim 2 and claim 3, where such filler material or the said main frame is assembled. With at least one type of aluminum oxide, silicon carbide, silicone, aluminum oxenitride, zirconium oxide, barium titanate, boron nitride, silicon nitride. Magnesium aluminate, iron-chromium-aluminum alloy Aluminum and its mixtures 2 3. Method of claim 3 where the main structural elements are It contains at least one material that can be chosen. From the silica-containing group Silicon carbide and alumina 2 4. Method according to claim 23, where at least One such material consists of particles ranging in size from approximately 10m2 to approximately 1,000m2. 5. Method of claim 3 where the main frame is It consists of carbon fiber that is coated 2. 6. Method according to claim 25, where carbon fiber is It will be coated with alumina 2. 7. Method of claim 1, 2 or 3, any one It also contains the use of sources of at least the accelerator type. One in conjunction with the aforementioned Parent Metal 2 8. Method of claim 27, where at least One such type of accelerator will be alloyed in Pratt Metal 2. 9. Method according to claim 27, where at least One such catalyst source is applied as a layer on the skin. The face of the parent metal and it also contains making The effect of most oxidation is next to the thickness. Of the prepared layer of the source of the accelerator 3 0. Method for claim 27, where at least One such source of accelerator will be assigned at least Some of the most extreme is within the said filler material or the main frame piece 3 1. Approach according to claim 27, where the source of the catalyst is found. It contains at least two sources of substances that Select from a group containing magnesium, zinc, silicon, germanium, tin, lead, boron, sodium, lithium, calcium, phosphorus, and atrium 3. 2. Method according to claim 31, where the polycrystalline material is considered to be a The aforementioned Ristal Calline contains Pins' initial skin. Pine, which is formed as a product of the oxidation reaction of the Such metal The source of the catalyst and the aforementioned issue 3 3. Method of claim 32, where such accelerator Contains magnesium or a source of magnesium and The abovementioned metal consists of aluminum 3. 4. Method according to claim 27, where parent metal It contains aluminum, and it also contains at least One source of accelerators that are alloyed with Such metal and, at the very least, the source of the catalyst. One will be directed on the surface of the parent metal. 3. 5. Method of claim 1, 2 or 3, either. Where the parent contains aluminum that is used in conjunction with The source of such oxidant catalyst consists of air, the heating process is between 850 ° C and 1450 ° C and produces such an oxidation effect. It will consist of 3 alumina 6. Method of claim 1, 2 or 3, any one Where the vapor oxidant contains the oxidant Selectable from a group containing H2H2O mixtures, methane, ethane, propane, acetylene, ethylene, pyrpropylene, silica, Co / Co2 mixtures and mixtures thereof. Right 2 and Claim 3 where the filler material or the said main frame will It consists of a selectable material from a group consisting of spherical powders, bubbles, wire, round rods, plates, round tubes and mixtures thereof. 3 8. Method according to claim 31, where the catalyst source It also contains a source of at least the metal. A kind of rare earth 3 9. Method according to claim 27, where the source of the catalyst It also contains sources of at least two substances. The selection was made from a group consisting of magnesium, zinc, silicon, germanium, tin, lead, boron, sothium, lithium, calcium, phosphorus, and rare-earth metals. One such rare-earth metal can be selected from the group that Contains lanthanum, cerium, prazodium, neodymium and samarium 4 1. Method according to claim 1, 2 or 3, any one Where at least part of the barrier will Permits oxidant permeability in such vapor conditions 4 2. Method according to claim 1, 2 or 3, any one Where the aforementioned barrier will dissolve in and dilute Crust Metal forged in contact with Parent Metal forged Said to inhibit further increase in reaction products. Oxidation 4 3. Method according to claim 1, 2 or 3, any one Where the products of the said oxidation reaction consist of Materials to choose from from the Parent Metal Oxide-containing group Boride of Parent Metal And carbide of Parent Metal 4 4. Method according to claim 1, 2 or 3, any one Where at least that barrier consists of One material selected from the alumina-containing group. Solid ramic or zirconia ceramic 4 5. Method according to claim 3, where the main structure pieces are Said, and the parent will be combined into a set, and that set will Is defined as having all surface obstructions that are exposed to oxidation Dan in such a vapor state 4 6. How to use the barrier Which the above barrier Contains at least one kind of material which will stop or crumple. Hinder the increase in the product of the oxidation reaction of the Bent metal, melted with the least oxidant, which Including oxidant in a vapor state How to do it With the steps of (a) laying such a barrier, touch With parental metal pieces to make space between raft pieces The rents and the barrier (b) react Such parent metal at temperatures above the melting point of the Such metallic, but below the melting point of the produce (46 claims, 8 pages, 14 photos).