109 results about "Aluminium carbide" patented technology

The invention discloses a multiple dispersion strengthening copper-base composite material produced in situ and a preparation method thereof; the reinforced phase comprises at least three of the following substances: titanium carbide, zirconium carbide, alumina, titanium boride, aluminum carbide, chromium oxide, zirconia, graphite and copper; wherein, the contents of titanium carbide, zirconium carbide, alumina, titanium boride, chromium oxide and zirconia are not less than 0.3% and not more than 5%, the content of aluminum carbide is not less than 0.1% and not more than 5%, the content of graphite is not less than 0.1% and not more than 1% and the balance is copper. The particle size of the reinforced phase is between 10nm to 10mu m. The preparation method adopts ball milling; pressing, sintering and squeezing processes and the technological parameters are optimized and controlled properly to obtain the multiple dispersion strengthening copper-base composite material. Because the in situ self-generation technology is adopted and various reinforced phase methods are combined, the material of the invention has higher high-temperature strength and better electroconductibility and anti-creep property compared with the traditional ceramic particle strengthening copper-base composite material.

The invention discloses a magnesium alloy refiner and a preparation method thereof, and relates to a grain refiner and a preparation method thereof. The method solves the problems that an overheating treatment method of the existing magnesium alloy refining method has strict condition requirement, the oxidation burning loss of magnesium is serous, a carbon-containing material treatment method has high temperature and produces harmful gases such as Cl2, HCl and the like, a ferric chloride method reduces the corrosion resistance of the magnesium alloy, an alloying method has high cost, a granular graphite or aluminium carbide granule method is easy to produce segregation on the grain boundary and a Zr element method has narrow application range. The magnesium alloy refiner is prepared from a calcium metal and a primary magnesium ingot. The preparation method comprises the following steps: heating and melting the primary magnesium ingot under atmospheric protection, then adding the calcium metal into the melted primary magnesium ingot, dissolving the calcium metal and stirring the mixture uniformly, and casting the mixture to form the magnesium alloy refiner. The magnesium alloy refiner has no burning loss, does not produce the harmful gases, has no influence on the corrosion resistance of the magnesium alloy, has low cost, is uniformly distributed in the alloy, can improve the mechanical property of the alloy, and is used for refining the magnesium alloy.

The invention discloses a titanium aluminium carbide powder and synthesis method using tin as reactive adjuvant characterized in that, using titanium (Ti), aluminium (Al) and graphite (C) as raw material, using stannum (Sn) as reaction adjuvant, proportioning by the mol ratio of Ti : Al : C : Sn = 3.0 : 1.0 : (1.8-2.0) : (0.1-0.2), mixing 2-6 hours through ball grinding, drying at 60-70 deg. C in baking oven, briquetting the dried mixture under 10-20MPa, loading into high temperature furnace, argon shielding, elevating the temperature to 1300-1550 deg. C. at the speed of 20-40 deg. C per minutes, heat preserving for 5-10 minutes, cooling with the speed of 10-15 deg. C / min.

A polycrystalline cubic boron nitride compact which comprises greater than 75 volume % and not greater than 90 volume % cubic boron nitride particles, the cubic boron nitride particles comprising particles of at least two average particle sizes, and a binder phase constituting the balance of the compact and comprising at least one titanium compound selected from titanium boride, titanium nitride, titanium carbide and titanium carbonitride and at least one aluminium compound selected from aluminium oxide, aluminium boride, aluminium nitride, aluminium carbide and aluminium carbonitride.

The invention discloses a cable sheath material containing modified PVC resins and preparation method thereof, and the cable sheath material is composed of following raw materials: modified PVC resins, polyacrylate, nanometer potter clay, sodium silicate, aluminium carbide, vulcanizing agent VA-7, antioxidant TPPD, phenyl triethoxysilane, dibenzyl thiourea, anti-oxidant DLTP, di(2-Ethylhexyl)-4,5-epoxycyclohexane-1,2-dicarboxylate and triphenylphosphine oxide; The invention employs modified PVC resin as main material, and the PVC resin is modified, and the invention has the advantages of greatly improved mechanical property, better mechanical properties, low smoke, halogen free, flame retardation, high mechanical strength and high insulation resistor, and nanometer potter clay in the raw material is used as strengthening agent, and sodium silicate and aluminium carbide are used as filling material.

The invention discloses a composite hard alloy material and a preparation method thereof. The composite hard alloy material is prepared from the following components in parts by weight: 35-40 parts of nano titanium carbide, 5-15 parts of nano titanium nitride, 7-9 parts of tungsten carbide, 5-8 parts of niobium carbide, 3-7 parts of silicon carbide, 3-5 parts of cobalt powder, 1-3 parts of yttrium oxide, 1-3 parts of aluminium carbide and 1-5 parts of titanium powder. The composite hard alloy material has high strength, good toughness and good wear resistance and thermal shock resistance.

The invention discloses an anti-corrosion heat-dissipation coating and a preparation method thereof. The coating comprises following raw materials: acrylic resin, calcium silicate powder, acetic ether, modified aluminium carbide, iron oxide, polyethylene wax powder, triethylene tetramine, anti-oxidant 264, water-soluble nano-level silica sol, dimethyl adipate, dispersant NNO, and acetone. The method adopts acrylic resin as the main material, which has the advantages of aging resistance, good adhesivity, good heat-dissipation effect, and long-term use at the temperature between 150 and 200 DEG C. Calcium silicate powder strengthens the anti-corrosion performance of the product, and alum and modified aluminium carbide strengthen the combination between the raw materials. The coating has the advantages of durability, waterproofness, damp-resistance, corrosion-resistance and very good adhesive performance.

The invention discloses a tungsten carbide coated composite hard alloy material and a preparation method thereof. The alloy material comprises a matrix and a tungsten carbide coated layer, wherein the matrix is prepared from the following components in parts by weight: 35-40 parts of nano titanium carbide, 5-15 parts of nano titanium nitride, 5-8 parts of niobium carbide, 3-7 parts of silicon carbide, 3-5 parts of cobalt powder, 1-3 parts of yttrium oxide, 1-3 parts of aluminium carbide and 1-5 parts of titanium powder. The composite hard alloy material has high strength, good toughness and good wear resistance and thermal shock resistance.

This invention relates to a synthetic method of aluminium carbide titanium ceramic powder. The invention takes TiH2 powder, Al powder and TiC powder as raw material, add Sn as accessory ingredient, dyr mix the raw materials acoording to mol ratio of TiH2:TiC:Al:Sn=1:1:1:0.1 for 10 hours, execute piece under 30 to 50 pressure, then put at high temperature furnace, under vacuum atmosphere rise the furnace temperature to 1350 to 1550 deg by rate of 15 to 40 deg per minute, holding time for 5 to 15min, execute low cost high-purity Ti3AlC2 powder.

A presensitized plate having a long press life and excellent resistance to scum and corrosive micro-stains and capable of on-press development is provided. The presensitized plate includes a photosensitive layer containing (A) a sensitizing dye, (B) a polymerization initiator, (C) a polymerizable compound, and (D) a binder polymer; and a protective layer which are formed on a support in this order. The support is prepared from an aluminum alloy plate containing intermetallic compound particles with a circle equivalent diameter of 0.2 μm or more at a surface density of 35,000 pcs / mm2 or more and aluminum carbide particles with a maximum length of 1 μm or more in an amount of up to 30,000 pcs / g.

The invention discloses a cable sheath material containing modified high density polyethylane and preparation method thereof, and the cable sheath material comprises the following raw materials: modified high density polyethylene, methyl vinyl silicone rubber, nanometer attapulgite, nanometer level titanium dioxide, aluminium carbide, isocyanate, anti-scorching agent CTP, titanate coupling agent TMC-TTS, isooctyl mercaptoacetate, 2.6-di t butyl-4-methyl phenol, chlorinated paraffin and polyurethane TPU; the invention employs modified high density polyethylane as main material, and the terpolymer EP rubber is modified, thereby the product has the characteristics of low-smoke, halogen free, flame retardation, high mechanical strength, high insulation resistor and high mechanical property, simultaneously the nanometer attapulgite in the raw material is used as strengthening agent, and nanometer level titanium dioxide and aluminium carbide are used as filling materials.

The invention belongs to the field of metal materials, and particularly relates to an aluminum oxide layer cladding type nanometer aluminum carbide particle reinforced aluminum matrix composite material and a manufacturing method of the aluminum oxide layer cladding type nanometer aluminum carbide particle reinforced aluminum matrix composite material. The aluminum oxide layer cladding type nanometer aluminum carbide particle reinforced aluminum matrix composite material is characterized in that according to the mass percentage of various chemical components, the mass percentage of aluminum ranges from 65% to 99.5%, the mass percentage of carbon ranges from 0.5% to 15.0%, and the balance is at least one of the magnesium element, the copper element, the silicon element, the zinc element, the ferrum element, the manganese element, the chromium element and the titanium element. Aluminum oxide cladding type nanometer aluminum carbide particles which are formed in an in-situ synthesis modeare distributed on an aluminum or aluminum alloy matrix. The manufacturing method of the aluminum oxide layer cladding type nanometer aluminum carbide particle reinforced aluminum matrix composite material comprises the steps that raw materials are prepared in proportion, and graphite powder and activated carbon are subjected to vacuum drying, and then are mixed and reserved; and commercial purityaluminum and at least one of magnesium, copper, silicon, zinc, ferrum, manganese, chromium and titanium are molten in a smelting furnace, after the temperature is stabilized, the mixed powder of thegraphite powder and the activated carbon are uniformly blown to the molten body in the argon atmosphere by a rotary blowing device, then the temperature is rapidly reduced until solidification is achieved, the materials are transferred to a resistance furnace to conduct a liquid-solid reaction, and therefore the nanometer aluminum carbide particle reinforced aluminum matrix composite material is obtained. The manufacturing method is low in cost, is green and environmentally friendly, and has the good industrial production prospect.

A process for preparing the sosoloid powder of tungst aluminium carbide by high-temp solid-phase reaction includes such steps as proportionally mixing W1-xAlx alloy with high-purity carbon powder, ball grinding, loading in graphite, crucible, heating to 1300-1600 deg.C in vacuum reductive atmosphere, or inertial at mosphere in solid-phase reactor, and holding the temp for 10-120 hr while ball grinding for 30-60 min at 5-10 hr of intervals. Its advantages are good crystal state, less impurity pollution, short time, and no noise.

A manufacturing method of a brake pad with a good braking effect relates to the technical field of brake pad production. The brake pad comprises a friction material and steel back. The friction material comprises the following raw materials: phenolic resin, cis-polybutadiene rubber, carbon fiber resin, talcum powder, zirconium silicide, aluminium carbide, barium sulfate, graphite, molybdenum disulfide, copper silicide, steel fibre, silicon carbide whisker, aramid fiber and molybdenum fibre. The manufacturing method comprises the following steps: burdening, mixing materials by a water method, carrying out pre-press forming and primary heat treatment to produce a friction material workblank; carrying out mild heat treatment, putting the friction material workblank into scalding hot oil to undergo scaling for 3-5 s, taking the friction material workblank out and cleaning with alcohol, and airing; carrying out steel back shot-blasting, and gluing steel back; carrying out hot press molding; and successively carrying out secondary heat-treatment, grinding, slotting chamfer, sand-blasting, and gluing silent blades. The brake pad of the invention has high strength, is oxidation resistant, and has long service life, good heat stability, high friction coefficient and good environmental protection property for production.

The invention discloses a modified terpolymer EP rubber containing cable sheath material and preparation method thereof, and the product comprises the following raw materials: modified terpolymer EP rubber, hydrogenated butadiene-acrylonitrile rubber, blast furnace slag, zeolite molecular sieve, aluminium carbide, promoter 808, promoter CZ, N-(beta-aminoethyl)-gamma-aminopropyl trimethoxysilane (triethoxysilane), barium ricinoleic acid, anti-oxidant 1010, diisobutyl phthalate and phosphate ester; the invention employs modified terpolymer EP rubber as main material, and the terpolymer EP rubber is modified, thereby the product has the characteristics of low-smoke, halogen free, flame retardation, high mechanical strength and high insulation resistor, moreover, the product has good elasticity and flexibility, simultaneously the nanometer attapulgite in the raw material is used as strengthening agent, and nanometer level titanium dioxide and aluminium carbide are used as filling materials.

The invention relates to a method for preparing aluminum carbide from aluminum oxide, which comprises the steps of: mixing industrial pure aluminum oxide as a raw material with graphite as a reducing agent; then putting the mixture at a pressure of 1-200 Pa; heating the mixture to 1450-1600 DEG C for 60-120 min; then keeping the heat for 30-120 min; and cooling the mixture to obtain the aluminum carbide, wherein purity of the aluminum carbide is more than 90% and up to 96.38%. The method disclosed by the invention is finished in a vacuum environment; the obtained aluminum carbide is pure and free from impurities; and gas generated from reaction is controlled easily. As the aluminum oxide and the graphite carbon are adopted as reactive materials, the reactive materials are obtained easily and low in cost. The method for preparing aluminum carbide from aluminum oxide disclosed by the invention is short in aluminum carbide preparation technological process, clean, free from pollution, as well as simple and convenient in operation.

The invention relates to a tungsten-cemented aluminium carbide sintered body, and the expression is(W1-xAlx)C-Co, in which x=0.1-0.86, which is alloy block-shaped material with good crystalline shape and fine texture. Proved by X-ray powder diffraction analysis and scanning electron microscope analysis, the tungsten-cemented aluminium carbide sintered body is of stable structure, improved crystallinity and higher degree of compactness. The tungsten-cemented aluminium carbide sintered body of this invention not only has glass hard and high-wearing feature of tungsten carbide, but also has lightweight, oxidation resistance and fine ductility of aluminium, which makes the alloy have high hardness, high bending strength and lower density and develop into new carbide alloy with high hardness, high strength, good workability and high oxidation-resistance temperature. The said material is hoped to be used in mechanical tool, glass-cutting, bolt die, broaching die, bowl, well drill, mine drill, cutting drill and electrical contact material.

The invention belongs to the field of medical materials and discloses a medical metal ceramic material and a preparation method thereof. The medical metal ceramic material comprises 11-15 parts of zirconium oxide, 13-17 parts of titanium dioxide, 2-4 parts of nickel, 6-11 parts of magnesium silicate, 3-7 parts of cobalt, 2-4 parts of magnesium, 3-6 parts of tungsten silicide,2-4 parts of aluminum carbonate and 4-8 parts of calcium metasilicate. The preparation method comprises the following steps: (1) respectively ball-milling the metals and a ceramic material; (2) pouring into a high-speed mixture and mixing at a high speed; and (3) sintering in vacuum at a high temperature, firstly heating the inside of a high-temperature sintering furnace to the temperature of 725-755 DEG C, heating the inside of the high-temperature sintering furnace again to the temperature of 980-1220 DEG C, sintering for 2.5-3.5 hours, and cooling the metal ceramic material inside the high-temperature sintering furnace to room temperature to obtain the medical metal ceramic material.

The invention relates to a preparation method and application of conductive paste based on two-dimensional nano titanium carbide. The preparation method comprises the steps of dissolving lithium fluoride in hydrochloric acid, adding titanium aluminum carbide, dispersing the obtained precipitate phase in absolute ethyl alcohol, performing ultrasonic treatment, dispersing in deionized water, performing ultrasonic treatment to obtain a dispersion liquid, performing centrifugal treatment to obtain an upper titanium carbide dispersion liquid, adding a settling agent, standing to obtain a precipitate product, dispersing in a base material solvent, adding a dispersing aid, and obtaining the two-dimensional nanometer titanium carbide conductive paste. A two-dimensional nano titanium carbide nanosheet is prepared by adopting an etching method, the nano titanium carbide conductive paste can be efficiently prepared through settling separation, and the nano titanium carbide conductive paste has good dispersion stability, conductivity and antistatic property, can be applied to manufacturing of conductive wires and flexible circuit printing, and realizes good conductivity and antistatic property of the base material.

The invention discloses a light tough bicycle frame material and a preparation method thereof. The bicycle frame material is prepared from the following materials in parts by weight: 12-26 parts of nano aluminium carbide, 12-28 parts of carbon fiber, 8-25 parts of nano silica, 9-18 parts of polycarbonate, 7-16 parts of polyamide, 8-20 parts of boron fiber, 18-40 parts of carbon steel fiber, 6-19 parts of polystyrene, 6-14 parts of hexamethylene diisocyanate and 7-14 parts of polyetheretherketone fiber. Compared with the prior art, the bicycle frame material provided by the invention has the advantages that (1), the bicycle frame material is light, high in toughness and long in service life; (2), the bicycle frame material is low in production cost and inexpensive.

The invention discloses a ceramic brake block, which consists of the following ingredients in the following parts: 20 to 30 parts of alumina silicate fiber, 30 to 50 parts of glass fiber, 40 to 50 parts of carbon fiber, 30 to 35 parts of bamboo charcoal fiber, 50 to 80 parts of ceramic fiber, 20 to 25 parts of asbestos fiber, 30 to 40 parts of polyester fiber, 40 to 45 parts of polyacrylonitrile fiber, 20 to 25 parts of polyvinyl alcohol fiber, 10 to 15 parts of polypropylene fiber, 15 to 25 parts of ultra to high molecular weight polyethylene fiber, 10 to 15 parts of sepiolite fiber, 20 to 25 parts of fibrilia, 15 to 18 parts of viscose, 5 to 10 parts of hollow particles, 4 to 6 parts of glass particles, 5 to 7 parts of silicon carbide, 5 to 8 parts of aluminium carbide, 2 to 5 parts of silicon dioxide, 2 to 5 parts of magnesium oxide, 3 to 6 parts of graphite, 10 to 12 parts of frictionpowder, 10 to 12 parts of reclaimed rubber, 8 to 10 parts of silicon carbide whiskers, 8 to 10 parts of magnesium borate whiskers and 6 to 8 parts of vanadium pentoxide. The ceramic brake block provided by the invention has the advantage that through the ingredient improvement matching and the composition, the technical problems of easy rustiness, higher noise, unstable high-temperature friction performance, easy locking or dragging friction, lower abrasion resistance performance and the like in the prior art are solved.

The invention discloses a cable sheath material containing modified chloroprene rubber CR322 and preparation method thereof. The cable sheath material is composed of the following components: modified chloroprene rubber CR322, polyvinyl acetate, magnesium carbonate, bauxitic clay, aluminium carbide, promoter C-15E86, antioxidant OD, isopropyl tri(dioctylpyrophosphate) titanate, zinc stearate, anti-oxidant DSTP, diphenyl isophthalate and cresyl diphenyl phosphate; the invention employs modified chloroprene rubber CR322 as main material, therefore, the cable sheath has better tensile strength, fracture elongation percentage, tensile strength conservation rate after aging and fracture stretch maintenance rate, impact brittle temperature and excellent performance, and magnesium carbonate in the material is used as strengthening agent, and bauxitic clay and aluminium carbide are used as filling materials.

The invention discloses a heat treatment method after magnesia carbon brick recovery. The heat treatment comprises the following steps: firstly, selecting magnesia carbon bricks and removing sundry bricks and impurities attached on the magnesia carbon bricks; secondly, performing watering treatment on the collected magnesia carbon bricks; thirdly, putting the watered magnesia carbon bricks into a semi-sealed device, heating to 500-800 DEG C from the room temperature at a rate of 5-20 DEG C per minute and then carrying out heat-retaining heat treatment, wherein the heat retaining time ranges from 6 to 24 hours; crushing the magnesia carbon bricks after the heat treatment and removing iron to obtain magnesia carbon powder. The heat treatment method is characterized in that the non-dried used recycled magnesia carbon bricks are subjected to semi-sealed type heat treatment, in a semi-sealed iron housing, water in the used recycled magnesia carbon bricks is heated to form water vapor which is not discharged immediately and formed into high-pressure water vapor, the high-pressure water vapor promotes hydration of aluminum carbide in the used recycled magnesia carbon bricks, and therefore, an independent water vapor treatment process is reduced and the treatment cost of the used recycled magnesia carbon bricks is reduced; meanwhile, in the meantime, the oxidization loss of graphite in the used recycled magnesia carbon bricks is reduced and the utilization rate of the used recycled magnesia carbon bricks is increased.

The invention discloses an aluminium nitride-based multi-element nano-composite ceramic die material and a preparation method thereof. The material comprises the following raw materials in parts by weight: 60-80 parts of aluminium nitride, 10-20 parts of aluminium carbide, 15-25 parts of silicon boride, 2-6 parts of scandium oxide, 4-8 parts of neodymium oxide, 2-4 parts of chromium, 1-3 parts of tungsten and 1-3 parts of nickel, wherein nanoscale powder of all the materials is adopted; the grain size of aluminium nitride is 10-100 nanometers; the grain sizes of aluminium carbide and silicon boride are 1-10 nanometers; the grain sizes of the other raw materials are 1-100 nanometers. The preparation method is characterized by using aluminium nitride as the matrix, adding aluminium carbide and silicon boride as reinforcing phases, scandium oxide and neodymium oxide as stabilizing agents and chromium, tungsten and nickel as sintering aids and carrying out hot pressed sintering on the materials, thus preparing the material. A die has strong ageing and defect resistance, good comprehensive mechanical properties and excellent antifriction and wear resistance properties.

In one embodiment, an electrode is provided. The electrode includes a current collector comprising aluminum with an aluminum carbide layer on at least one surface, on which at least one layer of carbon nanotubes (CNTs) is disposed. The electrode may comprise vertically-aligned, horizontally-aligned, or nonaligned (e.g., tangled or clustered) CNTs. The electrode may comprise compressed CNTs. The electrode may comprise single-walled, double-walled, or multiwalled CNTs. The electrode may comprise multiple layers of CNTs.

A hollow partition wall (4) is employed to feed carbon material to an underflow of a carbothermic reduction furnace used to make aluminum. The partition wall (4) divides a low temperature reaction zone (2) where aluminum oxide is reacted with carbon to form aluminum carbide and a high temperature reaction zone (3) where the aluminum carbide and remaining aluminum oxide are reacted to form aluminum and carbon monoxide.

The invention discloses a metal cutting gas, composed of fuel gas and a synergistic agent, wherein the synergistic agent is composed of aluminium carbide, ferrocene, methyl alcohol and MDPE (medium density polyethylene). The metal cutting gas disclosed by the invention has high combustion temperature and good cutting quality and can be completely combusted in the air, the combustion efficiency of the metal cutting gas in oxygen is higher, the temperature can reach about 3300 DEG C, the cutting accuracy is higher, and the grinding process is reduced, thus the product quality is improved; the environmental pollution is less, and extremely less CO or SO2 is produced, thus pollution is greatly reduced; air sources are wide, the application is safe, and the tempering rate is extremely low when the cutting gas is used, thus being very safe; the cutting gas is lighter than air and can directly enter a room to carry out welding and cutting; and the application scope is wide, the selection range of the fuel gas in the cutting gas is wide, and the requirement to the purity of each fuel gas is low.