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WO/2017/018512A1 |
This titanium material 1 for use in hot rolling comprises a base material 1b comprising an industrial pure titanium or titanium alloy, and a surface layer 1a formed on at least one rolled surface of the base material 1b and having a chem...
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WO/2017/018518A1 |
Provided is a titanium composite material 1 that has a first surface layer 2, an inner layer 4, and a second surface layer 3, wherein the first surface layer 2 and the second surface layer 3 are made from a titanium alloy, the inner laye...
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WO/2017/018523A1 |
A titanium material 1 for hot rolling comprising: a base material 1b comprising a pure titanium for industrial use or a titanium alloy; and a surface layer 1a formed on at least one rolled surface of the base material 1b and having a dif...
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WO/2017/018510A1 |
A titanium composite material 1 is provided with a first surface layer section 2, an inner layer section 4, and a second surface layer section 3. The first surface layer section 2 and the second surface layer section 3 comprise a titaniu...
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WO/2017/018515A1 |
Provided is a titanium material for hot rolling that has a base metal 1b made from an industrial pure titanium or a titanium alloy, and a surface layer 1a that is formed on at least one rolling surface of the base metal 1b and has a chem...
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WO/2017/018517A1 |
A titanium material 1 for hot rolling is provided with a titanium cast piece 3 and titanium plates 4 welded to the surfaces of the titanium cast piece 3 that are brought into contact with rolling surfaces 3a. The titanium cast piece 3 an...
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WO/2017/018521A1 |
Provided is a titanium material 1 for hot rolling that has a base metal 1b made from an industrial pure titanium or a titanium alloy, and a surface layer 1a that is formed on at least one rolling surface of the base metal 1b and has a ch...
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WO/2017/012185A1 |
A method for preparing titanium or titanium aluminum alloy and a byproduct- titanium-free cryolite through two-stage aluminothermic reduction comprises the following steps: (1) using sodium fluoride and sodium fluotitanate as raw materia...
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WO/2017/002851A1 |
The purpose of the present invention is to provide a sintered alloy having high mechanical strength (particularly high toughness suitable for a sputtering target material) and a sputtering target material which includes the sintered allo...
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WO/2017/002884A1 |
A titanium material according to the present invention serves as a separator in a polymer electrolyte fuel cell. The titanium material is provided with a base material composed of titanium or a titanium alloy and a passive film formed on...
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WO/2017/003192A1 |
The present invention relates to a TiNi-based medical alloy and a method for producing same. The TiNi-based medical alloy consisting of 44-48 wt% of Ti, 0.2-3.0 wt% of Mo, 0.1-2.0 wt% of Fe, 0.2-1.0 wt% of Al and the remainder of Ni has ...
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WO/2016/205781A1 |
Disclosed herein is a shape memory alloy comprising 45 to 50 atomic percent nickel; and 1 to 30 atomic percent of at least one metalloid selected from the group consisting of germanium, antimony, zinc, gallium, tin, and a combination of ...
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WO/2016/185115A1 |
The invention concerns a composition (10) intended to be sintered in order to manufacture a part comprising an alloy made from titanium aluminide, the composition comprising an alloy powder made from titanium aluminide (11), and an addit...
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WO/2016/179163A1 |
A cold rollable beta titanium alloy is provided by the present disclosure that exhibits excellent tensile strength, and creep and oxidation resistance at elevated temperatures. In one form, the beta titanium alloy includes molybdenum in ...
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WO/2016/172601A1 |
Various systems, devices, and methods for improved bone fixation are disclosed. The system includes a bone plate and a plurality of variable angle screws. The bone plate comprises titanium and the variable angle screws comprise a TiMo al...
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WO/2016/167214A1 |
Provided are: a steam turbine rotor blade that is both wear resistant and reliable; and a method for manufacturing a steam turbine rotor blade capable of obtaining such a steam turbine rotor blade. The steam turbine rotor blade according...
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WO/2015/119927A9 |
The invention relates to a TiAl alloy comprising the elements C, Si, B, Al and Ti, wherein a C fraction is ≤0.5 wt%, an Si fraction is 0.05-2.5 wt%, a B fraction is ≤0.4 wt% and an Al fraction is 25-43 wt%, in each case in relation t...
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WO/2016/152678A1 |
An aspect of the present invention is a method for manufacturing a rolled sheet for cold-rolling, the method being characterized in: being provided with a hot-rolling step for forming a rolled sheet by hot-rolling a pure titanium materia...
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WO/2016/152663A1 |
Provided is an α-β titanium alloy which has high strength and excellent hot workability equivalent to those of a typical α-β titanium alloy such as Ti-6Al-4V, while having more excellent machinability than Ti-6Al-4V. This α-β titan...
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WO/2016/152935A1 |
Provided are a titanium plate endowed with excellent strength and moldability, as well as a plate for a heat exchanger and a separator for a fuel cell in which said plate is used. A titanium plate containing Fe and O, and including an α...
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WO/2016/152780A1 |
A starting material powder comprising particles of W, or a starting material powder blended from a powder of W particles and one or more powders of alloy component particles selected from the group consisting of Ti, Zr, Hf, V, Nb, Ta, Cr...
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WO/2016/147858A1 |
Provided is a titanium alloy containing a total of 0.01-0.15 mass% of at least one platinum group element, the remainder comprising titanium, oxygen, and impurities, wherein the titanium alloy includes particles of a compound composed of...
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WO/2016/140231A1 |
A thin titanium sheet having a chemical composition that comprises, in mass%, Cu: 0.1-1.0%, Ni: 0.01-0.20%, Fe: 0.01-0.10%, O: 0.01-0.10%, Cr: 0-0.20%, and the balance: Ti and unavoidable impurities, and satisfies 0.04 ≤ 0.3 Cu+Ni ≤ ...
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WO/2016/140833A1 |
Generally planar sputter targets having a reverse bow surface (i.e., convexity) facing the magnets in a magnetron assembly is provided. Methods of making Cu and Cu alloy targets are provided including an annealing step performed at tempe...
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WO/2016/134029A1 |
A method of forming a golf club head assembly includes aligning a faceplate with a recess of a club head; welding the faceplate to the club head; then, after welding the faceplate, heating the club head and the faceplate to at least a so...
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WO/2016/130470A1 |
A method of producing an article selected from a titanium article and a titanium alloy article comprises melting feed materials with a source of hydrogen to form a molten heat of titanium or a titanium alloy, and casting at least a porti...
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WO/2016/129449A1 |
Provided are: a Cr-Ti alloy sputtering target material, which is capable of suppressing the generation of fine particles during sputtering; and a method for producing this Cr-Ti alloy sputtering target material. A Cr-Ti alloy sputtering ...
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WO/2016/114956A1 |
An alpha-beta titanium alloy comprises, in weight percentages: an aluminum equivalency in the range of 2.0 to 10.0; a molybdenum equivalency in the range of 0 to 20.0; 0.3 to 5.0 cobalt; and titanium. In certain embodiments, the alpha-be...
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WO/2016/107755A1 |
A lightweight precious alloy made from titanium and gold, comprising at least 750‰ by weight of gold, characterised in that said alloy has a composition of formula: Tia Aub Mc Td in which a, b, c, d are atomic proportions and such that...
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WO/2016/107752A1 |
An external component (1) for a timepiece or jewellery item, made from lightweight precious alloy comprising titanium and palladium, in the atomic composition TiaPdbMcTd, in which a, b, c and d are atomic fractions of the total, such tha...
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WO/2016/102806A1 |
The invention relates to an intermetallic alloy based on titanium, comprising, in atomic percentages, between 16% and 26% of Al, between 18% and 28% of Nb, between 0% and 3% of a metal M selected from Mo, W, Hf, and V, between 0% and 0.8...
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WO/2016/097630A1 |
The present invention seeks to provide a flexible pipe comprising an internal carcass that is lightweight, but also able to withstand highly corrosive environments, having high resistance to crashing, yet which can be manufactured and in...
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WO/2016/084243A1 |
A hot-rolled α+β titanium alloy sheet obtained from, in mass%, Al: 4.7-5.5%, Fe: 0.5-1.4%, N: not more than 0.03%, Si: 0.15-0.40% with a Si/O ratio of 0.80-2.80, [O]eq in equation (1) being 0.13% to less than 0.25%, and the balance fro...
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WO/2016/083724A1 |
The invention relates to a process for manufacturing a sintered three-dimensional part comprising an alloy based on titanium, the process comprising the following steps: the preparation of an injection composition (step E10) comprising a...
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WO/2016/084980A1 |
The titanium alloy member has a base material part, and a surface hardening layer formed on the surface layer of the base material part, the cross-sectional hardness of the base material part being 330 HV to less than 400 HV, and the cro...
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WO/2016/076466A1 |
Disclosed is a shape memory alloy. The shape memory alloy comprises Ti, Ni and Si, wherein Si is contained in an amount of 0.1 to 0.3 at.%.
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WO/2016/066955A1 |
The invention relates to a turbomachine part comprising an alloy based on titanium, for example Ti-8.5Cr-1.5Al or Ti-8.5Cr-1.5Sn, exhibiting a high level of strain hardening, high tensile strength, and good ductility.
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WO/2016/063768A1 |
The present invention provides a superelastic alloy containing: 8.0-20.0 mass% of essential additive elements of Au and at least one of Cr and Mo, and an optional additive element of Ta; and, as the remaining portion, Ti and unavoidable ...
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WO/2016/064985A1 |
BCC metal hydride alloys historically have limited electrochemical capabilities. Provided are a new examples of these alloys useful as electrode active materials. BCC metal hydride alloys provided include a pressure plateau in the desorp...
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WO/2016/063839A1 |
To improve the erosion resistance of a processing member for low-melting-point molten metals such as aluminum having a low melting point by suppressing the occurrence of cracks in a surface protective layer or separation of a coating lay...
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WO/2016/055013A1 |
A TiAl intermetallic compound single crystal material and a preparation method therefor. The alloy components of the material consist of TiaAlbNbc(C, Si)d, in respect of which 43≤b≤49, 2≤c≤10, a+b+c=100, 0≤d≤1 (at.%).
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WO/2016/056607A1 |
A titanium encapsulation structure which is a titanium material provided with a packaging material formed from a pure titanium material, and a filler packed into the packaging material, the internal pressure of the packaging material bei...
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WO/2016/055842A1 |
The present invention comprises a ternary material of titanium, nickel and nitrogen, rich in nitrogen in relation to titanium. Specifically, in the material of the invention the proportion of atoms of nitrogen is at least 1.5 in relation...
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WO/2016/052941A1 |
The present invention relates to a titanium alloy which is capable of nonlinear elastic deformation and simultaneously has super-high strength, super-low elastic modulus and stable super-elastic properties. The titanium alloy according t...
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WO/2016/051502A1 |
A melted and resolidified layer, which has a depth of at least 1 mm and is obtained by adding, melting, and resolidifying at least one β-phase-stabilizing element, is provided to the surface to be rolled of a titanium slab comprising a ...
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WO/2016/052789A1 |
The present invention relates to a titanium alloy exhibiting nonlinear elastic deformation and having super-high strength, ultra-low elastic modulus, and stable superelasticity, said titanium alloy comprising: niobium (Nb); zirconium (Zr...
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WO/2016/052371A1 |
Provided is a master alloy for a sputtering target, such master alloy being characterized in that, if the elements constituting the master alloy are X1, X2, Y1, Y2, and Y3 as defined hereinafter, the master alloy comprises any one combin...
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WO/2016/051503A1 |
A cast titanium slab comprising industrial pure titanium, wherein: an α-phase stabilizing element, a neutral element, or one or more types of elements selected therefrom are added to a surface serving as a rolling surface; a melted-reso...
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WO/2016/051505A1 |
A cast titanium slab comprising a titanium alloy, wherein: an α-phase stabilizing element, a neutral element, or one or more types of elements selected therefrom are added to a surface serving as a rolling surface; a melted-resolidified...
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WO/2016/051499A1 |
A melted and resolidified layer which has a depth of at least 1 mm, and which is obtained by adding, melting, and resolidifying at least one β-phase-stabilizing element is provided to the surface to be rolled of a titanium slab comprisi...
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