TH7286A - Method for constructing metal matrix constituents By using finely ground polycrystalline oxidation products as a filler and the resulting product - Google Patents

Abstract

The invention involves a new method to create a metal matrix composite material. And a new material containing the metal matrix produced by this Especially then Polycrystalline oxidation products of the parent metal and oxidant are produced first. And after that, the polycrystalline oxidation product is fineed to the ideal size as a filler material. Which can then be placed into a suitable container Or make it a pre-formed one The filler material, or the pre-formed form of the microscopic polycrystalline oxidation product, is exposed to the metal matrix alloy in the Of the seepage enhancer and / or the seepage enhancer and / or the seepage atmosphere, at least At some point during the process, where the metal matrix alloy will naturally penetrate, the filler material or the pre-formed form. As a result of the application of microscopic polycrystalline oxidation products. Therefore having to help enhance the natural infiltration (The rate of supplementation or quantity) can be increased. A new metal matrix object was also created in this way.

Claims (4)

1. Methods of forming a metal matrix component containing: - Providing the permeable mass of the filler. Containing products of oxidation reactions; And - natural infiltration The least Part of the molten matrix metal permeable mass 2. The method specified in Clause 1, which follows the process of providing a descriptive state for seepage, contact with The least One of the permeable mass And matrix metal for The least Part of the seepage range 3. Methods outlined in claim 2, where the seepage atmosphere consists of one environment selected from the group. These consist of oxygen and nitrogen. 4. Methods stated in Clause 2, which continue with the process of feeding or dispensing. The least One of the main seepage enhancer and seepage enhancer, at least One of a matrix metal, passable mass And atmospheric conditions of seepage 5. Methods set out in Clause 4, which at the very least One of the main auxiliary agents of seepage And an aid to enhance the seepage Is provided in a matrix metal body, permeable mass And atmospheric conditions of seepage 6.Methods outlined in claim 4, where matrix metals Contains aluminum, the main seepage enhancer contains zinc, and the seepage atmosphere contains oxygen. 7. Methods outlined in claim 4, where the matrix metal Contains aluminum, the main seepage enhancer contains magnesium and the infiltration atmosphere contains nitrogen 8. Methods outlined in Clause 4, where the main seepage enhancer. include The selected materials are from the group that includes Magnesium, strontium and calcium 9. Methods outlined in claim 4, where matrix metals Contains aluminum, the main seepage enhancer contains strontium, and the infiltration atmosphere contains nitrogen 1 0. Methods outlined in claim 4, where the matrix metal Contains aluminum, the main seepage enhancer contains calcium and the infiltration atmosphere contains nitrogen 1 1. Methods stated in Clause 1, which further follows the process of feeding or dispensing. The least One of the main auxiliary agents of seepage And an aid to enhance the seepage At the very least One of the matrix metal and permeable mass 1 2. The method specified in Clause 4 or 11. Where at least One of the main auxiliary agents of seepage And the seepage enhancer is fed from an external source 1. 3. The method specified in claim 1, where at least One of the auxiliary agents And the main auxiliary agent of seepage Is provided at the boundary between permeable masses And the matrix metal 1 4. Methods outlined in Clause 11, where at least One of the main auxiliary agents of seepage And an aid to enhance the seepage Will be provided in a metal matrix 1 5. Method specified in Clause 1,4 or 11, whereby such fine oxidation products contain products from Reaction of primary molten metal And at the very least A vapor oxidant material, a liquid oxidant And solid oxidants 1 6. Methods outlined in Clause 15, which follows the procedure for the reduction of the parent mixtures of the reaction product. The fine layer preceding the natural infiltration, permeable mass with such molten matrix metals 1 7. Methods specified in Clause 1,4 or 11. one Where such fine oxidation products consist of the reaction products of the molten metal And oxidant Containing The materials selected were from a group consisting of oxygen, nitrogen, halogens, sulfur, phosphorus, arcenic, carbon, boron, selenium, tellerium and their combinations. Specified in either Clause 1,4 or 11 Where the products of such oxidation contain at least One selected from a group consisting of oxides, nitrides, carbides, borides and oxenitrides 1. 9. Methods specified in any Clause 1,4 or 11. One where the oxidation products contain at least the One material selected from the group consisting of aluminum oxide, aluminum nitride, silicon carbide, silicon boride, aluminum boride, titanium nitride, zirconium nitride, titanium boride. The methods specified in Clause 1, where the product from being made, has been identified in claim 1, where the product is made from, zirconium boride, titanium carbide. Such fine oxidation reactions Will contain a latent form as well The least Any one of the seepage enhancers And the main auxiliary agent of seepage. 2 1. Methods outlined in Clause 1, where it follows the exposure procedure. The least Part of the mass that is permeable with the least One of the main seepage enhancers And an aid to reinforce the seepage during At least part of the infiltration range 2 2. Methods outlined in claim 1, where the permeable mass is It consists of a pre-formed pattern 2. 3. Methods outlined in claim 1 where the permeable mass consists of at least the One additional material selected from the group consisting of powder, flakes, sheets, substructures, tapered strands, sponges, fibers, particle pellets, long fibers, cut fibers, stacked sheets, tubes and resistant felt. Fire 2 4. V, as specified in Clause 23, where at least The added material has a limited solubility in molten matrix metal 2 5. Methods outlined in claim 1, where the main seepage enhancer is alloyed into the metal. 2 6. The method specified in claim 1, where the matrix metal is Aluminum And at the very least One alloy selected from a group Which consists of Silicon, iron, copper, manganis, chromium, zinc, calcium, magnesium and strontium 2 7. Method covered in claim 1 where the temperature during seepage Naturally, it is higher than the melting point of the matrix metal. But below the temperature of the matrix metal evaporation and the melting point of the non-metallic part of the permeable mass 2 8. Methods stated in claim 1, where the temperature during natural infiltration is It is within the range of 750 C to 850 C 2 9. The method stated in claim 1, where the matrix metal is Aluminum And the permeable mass is further composed of materials selected from the group These include oxides, carbides, borides and nitrides 3 0. Methods outlined in claim 1, where the fine oxidation products are polycrystalline. 3 1. Methods stated in claim 1, wherein the microscopic oxidation products contain constituent materials 3 2. Methods identified in claim 1, where Products from such oxidation reactions It is made to be small to size between approximately 200 mesh and approximately 500 mesh. 3. 3. Method for constructing metal matrix components. Containing: - Providing a filler permeable mass to be filled Containing products from oxidation reactions Polycrystalline; - contact of molten metal matrix with such permeable mass; - Providing atmospheric conditions of infiltration with exposure to at least part of the permeable mass; - At the very least Adopting the selected materials from the group that includes Auxiliary enhancer And the main auxiliary agent of seepage The least The selected materials are from the group that includes The matrix metal and the permeable mass in sufficient amounts of the cause of the natural infiltration of the molten matrix metal into the resulting permeable mass; And - natural infiltration, permeable liquid 3 4. One of the methods specified in Clause 33 or 4. Where the seepage enhancer is produced by reacting the main seepage enhancer and, at the very least, One of the materials selected from the group consisting of permeate atmospheres, fine oxidation products. 3. Methods specified in Clause 34, where, during seepage, the main seepage enhancer evaporates. 3. 6. Methods specified in claim. Article 35, where the main evaporative seepage enhancer reacts to form a reaction product in At least partially of the permeable mass. 3 7. Methods specified in Clause 36, whereby the reaction products are Will be reduced at least partially 3 8. Methods specified in Clause 37, where the reaction products are coated at least partially of the permeable mass. As set out in claim 36, where the reaction product contains: Magnesium Nitride 4 0. Methods specified in Clause 1, which comprise the procedure for determining the surface boundaries of permeable masses with a barrier. Where the matrix metal naturally penetrates the barrier 4. 1. Methods outlined in Clause 40, where the barrier Contains a selection of materials from the group consisting of carbon, graphite and titanium diboride 4. 2. Methods outlined in claim 40, where such barriers are not completely wet with such a matrix metal 4. 3.The methods set out in claim 40, where such barriers consist of: The least A material that provides a connection between the permeability atmospheres. And at the very least Any one of the matrix mode, permeable mass, permeation enhancer. And the main auxiliary agent of seepage 4 4.How to make a metal matrix composite Containing: - Providing a filler permeable mass to be filled Containing alumina oxidation products formed from a parent metal containing aluminum; - Contact of molten metal Containing Aluminum with such permeable; - the provision of atmospheric conditions of infiltration by contact with such permeable mass; - The introduction of materials containing magnesium The least One of such permeable mass and matrix metal; And - the natural infiltration of the permeable mass with such liquid matrix metal.