| Document |
Document Title |
|
WO/2019/217319A1 |
New aluminum casting (foundry) alloys are disclosed. The new aluminum casting alloys generally include from 2.5 to 5.0 wt. % Mg, from 0.70 to 2.5 wt. % Si, wherein the ratio of Mg/Si (in weight percent) is from 1.7 to 3.6, from 0.40 to 1...
|
|
WO/2019/211546A1 |
The invention relates to a manufacturing method in which an alloy is prepared that comprises 3.5 to 4.7 wt% of Cu; 0.6 to 1.2 wt% of Li; 0.2 to 0.8 wt% of Mg; 0.1 to 0.2 wt% of Zr; 0.0 to 0.3 wt% of Ag; 0.0 to 0.8 wt% of Zn; 0.0 to 0.5 w...
|
|
WO/2019/211547A1 |
The invention relates to a product based on an aluminium alloy comprising, as percentages by weight, 4.0 to 4.6% by weight of Cu, 0.7 to 1.2% by weight of Li, 0.5 to 0.65% by weight of Mg, 0.10 to 0.20% by weight of Zr, 0.15 to 0.30% by ...
|
|
WO/2019/206826A1 |
The invention relates to an extruded product made of 6xxx a!uminium alloy comprising 0.40 - 0.80 wt % Si, 0.40 - 0.80 wt. % Wig, 0.40 - 0.70 wt. % Cu, up to 0.4 wt. % Fe, up to 0.30 wt. % Mn, up to 0.2 wt. % Cr, up to 0.2 wt. % V, up to ...
|
|
WO/2019/209015A1 |
One embodiment of the present invention provides a heat treatment method for Al-Mg-Si alloy to provide Al-Mg-Si alloy sheets suitable for use as the exterior covering material for vehicles, the method comprising the steps of: determining...
|
|
WO/2019/201994A1 |
Fastener for securing at least a first component and a second component together, the fastener comprising: - a securing portion (12) adapted to be secured to the first and/or the second component, and - a guiding portion (14) adapted to ...
|
|
WO/2019/201750A1 |
The present invention deals with a brazing sheet comprising: - a core layer made of a AA3xxx alloy comprising, in weight percentages: up to 0.70% Si, up to 0.70% Fe, 0.20 to 1.10% Cu, 0.70 to 1.80% Mn, up to 0.40% Mg, up to 0.30% Zn, up ...
|
|
WO/2019/196779A1 |
The present utility model relates to a brazed aluminum alloy composite bottom plate and a heating coil. An aluminum alloy composite bottom plate uses 1000, 3000 or 6000 series aluminum alloy as a substrate, and then a 4000 series aluminu...
|
|
WO/2019/193985A1 |
Provided is a compressor part for a transport aircraft, the compressor part having excellent mechanical properties at high temperature. This compressor part for a transport aircraft contains: 5.0-9.0 mass% of Fe; 0.1-3.0 mass% of V; 0.1-...
|
|
WO/2019/195612A1 |
A senes of alloys of Co, Ni, Al, W, Ta, and Cr, wherein the alloy comprises a solid solution of gamma and gamma prime alloy phases, the Ni content is greater than 25% at.%, the Al content is greater than 10 at, %, the Cr content is great...
|
|
WO/2019/195656A1 |
The present disclosure relates to methods for welding aluminum alloy products, and products made from the same. The new welded aluminum alloy products may be produced by abutting a first aluminum alloy component against a second aluminum...
|
|
WO/2019/189427A1 |
Provided is an aluminum alloy heat exchanger for exhaust gas recirculation system obtained by brazing a fin material to a tube material. The fin material comprises: a core material containing 0.05-1.50% by mass Si and 0.40-2.00% by mass ...
|
|
WO/2019/189517A1 |
Provided are: an aluminum alloy sheet for an automotive structural member, said aluminum alloy sheet having an excellent balance between strength, formability, crush properties, and corrosion resistance; an automotive structural member, ...
|
|
WO/2019/189521A1 |
Provided are an aluminum alloy having excellent strength in particular without a decrease in forming properties in T4 tempering, and an aluminum alloy sheet and an aluminum alloy member in which the aluminum alloy is used. A high-strengt...
|
|
WO/2019/189428A1 |
Provided is an aluminum alloy heat exchanger for exhaust gas recirculation system, the heat exchanger being installed in an exhaust gas recirculation system of an internal combustion engine, and being for cooling exhaust gas, and being c...
|
|
WO/2019/188452A1 |
The purpose of the present invention is to provide an aluminum alloy material having sufficient strength and workability to replace iron-based or copper-based metal materials. This aluminum alloy material contains at least one among 0.2-...
|
|
WO/2019/186739A1 |
Provided is a production method for an Al–Si–Mg-based aluminum alloy casting material. This production method for an Al–Si–Mg-based aluminum alloy for casting applies a heat treatment to an Al–Si–Mg-based aluminum alloy casti...
|
|
WO/2019/189002A1 |
This aluminum alloy has a compositional makeup containing, in mass%, 0.025-0.500% of Fe, 0-0.070% of Si, 0-0.050% of Zr, 0-0.100% of Ti, and at least one of 0.010-0.150% of B and 0.005-0.100% of Sr, the remaining portion being 99.5% or m...
|
|
WO/2019/188451A1 |
This aluminum alloy material contains at least one among 0.05-1.50 mass% of Fe, 0.01-0.15 mass% of Si, 0.01-0.3 mass% of Cu, and 0.01-1.5 mass% of Mg, with the remainder comprising Al and inevitable impurities, and has a fibrous metal st...
|
|
WO/2019/186645A1 |
Provided is a hot-dip Al-plated steel sheet production method in which fine spangles are stably formed on a surface of a plating layer. The hot-dip Al-plated steel sheet production method includes a composition adjustment step for adjust...
|
|
WO/2019/189426A1 |
Provided is an aluminum alloy heat exchanger for exhaust gas recirculation system, obtained by brazing a fin material onto a tube material. The fin material comprises: an aluminum alloy core material containing 0.10-1.50% Si and 0.40-2.0...
|
|
WO/2019/186740A1 |
Provided is an Al–Si–Mg-based aluminum alloy. This Al–Si–Mg-based aluminum alloy includes 5%–10% by mass Si, 0.2%–1.0% by mass Mg, 0.03%–0.5% by mass Sb, and 0.0004%–0.0026% by mass Be, with the remainder being Al and una...
|
|
WO/2019/180853A1 |
A hot stamp molded body which is provided with a steel base material and a metal layer that is formed on the surface of the steel base material, and which is configured such that the metal layer comprises: an interface layer which is pos...
|
|
WO/2019/180852A1 |
This hot stamped molded article is provided with a steel base and a metal layer formed on the surface of the steel base. The metal layer contains 30.0 to 36.0 mass% of Al, and has a thickness of 100 nm to 5µm. The metal layer also inclu...
|
|
WO/2019/181132A1 |
In order to improve the fatigue resistance of an alloy overlay layer in sliding contact with a counterpart member in a sliding member, this sliding member is equipped with a base material layer and an alloy overlay layer formed on the ba...
|
|
WO/2019/182021A1 |
The present invention provides a surface-treated aluminum alloy material which has a configuration that enables an oxide coating layer to have reliably improved adhesion and bondability to a resin layer, said oxide coating layer being pr...
|
|
WO/2019/178934A1 |
A method for manufacturing a lightweight, high-strength, and fatigue-resistant in-situ nano-reinforced aluminum alloy hub for a new energy automobile. The method achieves nano-particle combined reinforcement by means of Orowan strengthen...
|
|
WO/2019/181925A1 |
Provided is an aluminum alloy substrate for a magnetic disk, with which high flattening of the entire aluminum alloy substrate is achieved, and with which it is possible for floating stability of a magnetic head to be improved further. I...
|
|
WO/2019/181768A1 |
This aluminum alloy fin material for a heat exchanger is characterized by comprising an aluminum alloy containing 1.00-1.60 mass% of Mn, 0.70-1.20 mass% of Si, 0.05-0.50 mass% of Fe, 0.05-0.35 mass% of Cu, and 1.00-1.80 mass% of Zn, the ...
|
|
WO/2019/178200A1 |
Provided herein are continuously cast aluminum alloy products exhibiting uniform surface characteristics. The aluminum alloy products have a first surface comprising a width, wherein the first surface comprises an average of 50 exudates ...
|
|
WO/2019/178537A1 |
Disclosed methods relate to producing an aluminum-scandium (Al-Sc) alloy. A method can include providing an electrolyte bath comprising a first portion of at least one of ScF3 or A1F3 and a first portion of at least one of LiF, NaF, or K...
|
|
WO/2019/175065A1 |
According to this method, an external prestress is produced on at least one side of a component surface of a component (1) made of steel, metal or an alloy. For this purpose, at least one SMA plate (2) is placed as tension element on the...
|
|
WO/2019/174870A1 |
The invention relates to a method of manufacturing an AlMgSi(Cu)alloy sheet product particularly suitable for use in the production of automotive body parts, the method comprising the steps of (a) providing a rolled aluminium alloy sheet...
|
|
WO/2019/172257A1 |
Provided is an aluminum alloy brazing sheet for flux-free brazing, the sheet comprising: a core member that comprises an aluminum alloy containing 0.50-0.90% by mass of Si, 0.30-2.50% by mass of Cu, and 1.40-1.80% by mass of Mn, the Mg c...
|
|
WO/2019/171818A1 |
Provided is an Al-Mg-Si-based alloy hollow extruded material which is high strength and which exhibits excellent bending crash resistance and corrosion resistance. This aluminum alloy hollow extruded material contains 0.80-1.25 mass% of ...
|
|
WO/2019/171675A1 |
This magnetic disk substrate is provided with an aluminum alloy substrate and a base plating layer formed on a surface of the aluminum alloy substrate. For a boundary region formed between the base plating layer and the aluminum alloy su...
|
|
WO/2019/165736A1 |
Provided is a method for preparing a nano-particle reinforced composite material by multi-dimensional vibration-assisted synthesis, comprising the following steps: (1) preheating and drying a reaction salt, and melting metal melt to a sy...
|
|
WO/2019/167469A1 |
The present invention provides an Al-Mg-Si system aluminum alloy material which has both high strength and good corrosion resistance at the same time. This Al-Mg-Si system aluminum alloy material contains from 0.1% by mass to 2.0% by mas...
|
|
WO/2019/165136A1 |
The present disclosure relates to additively manufactured products and methods for making the same. Broadly, the additively manufactured products comprise a plurality of grains, where the plurality of grains comprise large equiaxed grain...
|
|
WO/2019/163239A1 |
Provided are a magnetic disc and a production method therefor, said magnetic disc being characterized in that: the magnetic disc is provided with an electroless Ni-P plating layer formed, through a compound removal process, on a surface ...
|
|
WO/2019/160106A1 |
[Problem] To provide: an Fe-Al plated hot-stamped member which exhibits more excellent corrosion resistance in molded parts and more excellent corrosion resistance after coating; and a method for producing an Fe-Al plated hot-stamped mem...
|
|
WO/2019/159795A1 |
Provided are an aluminum-alloy substrate for a magnetic disk, a manufacturing method for said aluminum-alloy substrate, and a magnetic disk employing the aluminum-alloy substrate for a magnetic disk, the aluminum-alloy substrate comprisi...
|
|
WO/2019/159810A1 |
The purpose of the present invention is to provide a method for manufacturing an aluminum alloy member, in particular, an Al-Zn-Mg-Cu-based aluminum alloy member, wherein a stable solution treatment and a quenching treatment can be appli...
|
|
WO/2019/161137A1 |
The present disclosure relates to new aluminum alloy products. In one embodiment, an aluminum alloy product comprises at least one of (i) equiaxed grains, (ii) an average grain size of not greater than 50 micrometers, (iii) at least 10 v...
|
|
WO/2019/153768A1 |
A high-resistance heat conductive alloy, comprising the following chemical components in percentage by weight: 10.0-13.0 wt.% magnesium (Mg), 3.0-5.0 wt.% yttrium (Y), 2.0-4.0 wt.% tantalum (Ta), 5.0-8.0 wt.% molybdenum (Mo), 6.0-10.0 wt...
|
|
WO/2019/155165A1 |
The invention relates to a process for manufacturing a part, comprising the formation of successive solid metal layers (201 …20n) that are stacked on one another, each layer describing a pattern defined from a numerical model (M)), eac...
|
|
WO/2019/156658A1 |
An additive manufacturing method of producing a metal alloy article may involve: Providing a supply of a metal alloy in powder form; providing a supply of a nucleant material, thenucleant material lowering the nucleation energy required ...
|
|
WO/2019/155180A1 |
The invention relates to a process for manufacturing parts (20), the process including the formation of successive, superimposed solid metal layers (201...20n), each layer describing a pattern defined on the basis of a numerical model (M...
|
|
WO/2019/150822A1 |
Provided are: an aluminum alloy fin material for heat exchangers, which is free from brazing failure associated with fin deformation during brazing, and which has excellent strength, conductivity, corrosion resistance and brazability; an...
|
|
WO/2019/152664A1 |
A method is disclosed, which includes the step of preparing an aluminum alloy body for solutionizing. The aluminum alloy body may include not greater than 0.06 wt. % Fe, where at least some Fe is present. The aluminum body may include no...
|
