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WO/2022/223147A1 |
A solder material for use in electronic assembly, the solder material comprising: solder layers; and a core layer comprising a core material, the core layer being sandwiched between the solder layers, wherein: the thermal conductivity of...
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WO/2022/222225A1 |
The present application relates to the technical field of high-temperature alloys, and in particular to a high-temperature alloy having low stacking fault energy, a structural member and an application thereof. The high-temperature alloy...
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WO/2022/220242A1 |
Provided is a high Ni alloy exhibiting excellent high welding temperature cracking resistance and comprising, in terms of mass%, Cr: 16-30%, Ni: 18-50%, Al: 0.01-1.0%, and Ti: 0.01-1.5%. In a first invention, a relationship between the n...
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WO/2022/215635A1 |
This steel sheet for hot stamping is characteristically provided with the following in the indicated sequence: a base steel sheet; an Al-Si alloy plating layer that has an Al content of at least 75 mass% and an Si content of at least 3 m...
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WO/2022/210217A1 |
In this production method for forming Ni-based conductive metal particles by mixing a first aqueous solution comprising Ni and NaOH with a second aqueous solution comprising P to prepare a third aqueous solution with a pH greater than 7 ...
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WO/2022/209497A1 |
[Problem] To provide a soft magnetic powder used to fabricate a magnetic core that has high relative permeability and high DC superimposition characteristics. [Solution] The present invention is a soft magnetic powder that includes Fe an...
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WO/2022/208004A1 |
The invention relates to a nickel-based superalloy comprising in weight percentages: 5.5 to 7.5% of aluminum, 1.0 to 4.0% of tantalum, 0.50 to 3.0% of titanium, 3.0 to 7.0% of cobalt, 8.0 to 12.0% of chromium, 0 to 2.5% of molybdenum, 0 ...
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WO/2022/213084A1 |
A nickel-based alloy is provided. The nickel-based alloy includes the following elements in a weight percentage, carbon (C): 0.05% – 0.09%, chromium (Cr): 9.6% – 10.5%, cobalt (Co): 14.7% - 15.3%, molybdenum (Mo): 2.8% – 3.2%, tita...
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WO/2022/199828A1 |
Aspects of the present invention relate to a composition for use in laser cladding a surface of a machined or cast aluminium part (100a), the composition comprising a matrix material and a hardener, wherein the hardener is present in an ...
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WO/2022/198344A1 |
The present invention relates to the field of magnetocaloric materials of importance for magnetic refrigeration. It specifically provides a method for manufacturing a TbCo2 magnetocaloric alloy in ribbon form that can be used as a magnet...
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WO/2022/200175A1 |
A nickel-based alloy composition is specified, comprising nickel as main constituent and the following further constituents in weight per cent (wt%): 0.04 to 0.10% carbon (C), 8 to 13% tantalum (Ta), 12 to 20% chromium (Cr), 3 to 25% cob...
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WO/2022/196775A1 |
The problem of the present invention is to obtain an alloy having low thermal expansion characteristics or negative thermal expansion characteristics in the vicinity of 600 to 800˚C. This thermal expansion-controlled alloy contains, by ...
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WO/2022/191142A1 |
In a manufacturing method according to one embodiment, a first partially sintered body (2A) formed from a powder comprising a first Ni-based alloy is prepared, and a second partially sintered body (3A) formed from a powder comprising a s...
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WO/2022/185092A1 |
The invention relates to an iron-nickel alloy having the following composition in percent by weight: 36.5% ≤ Ni ≤ 38.5%; 0.50% ≤ Mn ≤ 1.25%; 0.001% ≤ Cu ≤ 0.85%; 0.040% ≤ C ≤ 0.150%; 0.10% ≤ Si ≤ 0.35%, the remainder ...
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WO/2022/184695A1 |
The invention relates to an iron-nickel alloy having the following composition in percent by weight: 36.5% ≤ Ni ≤ 38.5%; 0.50% ≤ Mn ≤ 1.25%; 0.001% ≤ Cu ≤ 0.85%; 0.040% ≤ C ≤ 0.150%; 0.10% ≤ Si ≤ 0.35%, the remainder ...
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WO/2022/178541A1 |
This disclosure generally relates to coating compositions comprising chromium and aluminum and coatings formed using the same, and more particularly to bond coat compositions and coatings for use in various gas turbine applications. In o...
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WO/2022/176842A1 |
This FeNi ordered alloy structural body (1) has a structure in which particles (3) each including an L10-type FeNi ordered alloy phase are arranged on a support body (2) with intervals (5) therebetween. In such a FeNi ordered alloy struc...
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WO/2022/173082A1 |
The present invention relates to: a heat treatment method for improving the strength and ductility of a superalloy manufactured by additive manufacturing (AM); and a nickel-based superalloy heat-treated by the heat treatment method, the ...
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WO/2022/171473A1 |
The invention relates to a nickel-based alloy, comprising or in particular consisting of (in wt.%): carbon (C): 0.09% – 0.13%; chromium (Cr): 19.0% – 21.5%; cobalt (Co): 18.0% – 20.0%; molybdenum (Mo): 0.5% – 1.5%; tungsten (W): ...
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WO/2022/173081A1 |
The present invention relates to a homogenization heat-treatment method for a super heat-resistant alloy ingot, the method comprising a step of subjecting a nickel-based super heat-resistant alloy ingot composed of Inconel 718 to homogen...
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WO/2022/167363A1 |
The invention relates to a nickel-based alloy comprising cobalt (Co): 7.7% – 9.3%; chromium (Cr): 15.5% – 16.6%; molybdenum (Mo): 1.3% – 2.2%; tungsten (W): 2.1% – 3.1%; aluminum (Al): 3.7% – 4.7%; titanium (Ti): 1.5% – 2.0%;...
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WO/2022/167042A1 |
The invention relates to the use of an alloy having the composition (in mass per cent) C max. 0.02%, S max. 0.01%, N max. 0.03%, Cr 20.0 - 23.0%, Ni 39.0 - 44.0%, Mn 0.4 - < 1.0%, Si 0.1 - < 0.5%, Mo > 4.0 - < 7.0%, Nb max. 0.15%, Cu > 1...
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WO/2022/168914A1 |
Provided are a Ni-based alloy powder for lamination molding, a lamination molded article, and a manufacturing method therefor, all of which prevent development of cracks. The Ni-based alloy powder for lamination molding contains, in ma...
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WO/2022/159363A1 |
A superalloy powder mixture is provided for use with additive manufacturing or welding metal components or portions thereof. The superalloy powder mixture includes at least 51% by weight a high melt superalloy powder and at least 5% by w...
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WO/2022/155345A1 |
An alloy includes a composition, in weight percent, of aluminum from about 1.3% to about 1.8%, cobalt from about 1.5% to about 4.0%, chromium from about 18.0% to about 22.0%, iron from about 4.0% to about 10.0%, molybdenum from about 1.0...
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WO/2022/149539A1 |
An alloy powder for deposition modeling according to one embodiment of the present invention is configured from a nickel-based alloy and contains 15.0% by mass to 25.0% by mass of cobalt, 10.0% by mass to 25.0% by mass of chromium, 0.0% ...
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WO/2022/148426A1 |
The present invention provides a high-aluminum austenitic alloy and a high-aluminum austenitic centrifugal casting pipe. The high-aluminum austenitic alloy and the high-aluminum austenitic centrifugal casting pipe have excellent anti-cor...
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WO/2022/149178A1 |
Apparatus (10) for heating steel products (200), in particular billets, comprising a heating chamber (13), a plane of advance (P) defined inside said heating chamber (13) and feed and extraction means (18, 20) for said steel products.
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WO/2022/145067A1 |
Provided is a steel material with a predetermined chemical composition satisfying 0.40[Pr] + 0.37[Sm] + 0.37[Eu] + 0.36[Gd] + 0.35[Tb] + 0.34[Dy] + 0.34[Ho] + 0.33[Er] + 0.33[Tm] + 0.32[Yb] + 0.32[Lu] + 1.24[Sc] - 2.33[O] - 3.99[N] - 1.7...
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WO/2022/145062A1 |
Provided is a steel material having a prescribed chemical composition that satisfies 0.40[Pr]+0.37[Sm]+0.37[Eu]+0.36[Gd]+0.35[Tb]+0.34[Dy]+0.34[H
o]+0.33[Er]+0.33[Tm]+0.32[Yb]+0.32[Lu]+1.24[Sc]-2.33[O]-3.99
[N]-1.74[S]≧0.0003 (in the f...
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WO/2022/145068A1 |
Provided is a steel material having a predetermined chemical composition satisfying 0.40 [La] + 0.40 [Ce] + 0.39 [Nd] + 0.63 [Y] – 2.33 [O] – 1.74 [S] – 1.80 [P] ≥ 0.0003 (in the expression, [La], [Ce], [Nd], [Y], [O], [S], and [...
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WO/2022/145071A1 |
Provided is a steel material having a predetermined chemical composition satisfying 0.61[Zr]+0.31[Hf]-1.75[O]-3.99[N]-1.74[S]≥0.0003 (in the expression, [Zr], [Hf], [O], [N], and [S] are each the content [mass%] of an element), the ste...
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WO/2022/145065A1 |
Provided is a steel material that has a specific chemical composition satisfying 0.61 [Zr] + 0.31 [Hf] − 1.75 [O] − 3.99 [N] − 1.74 [S] ≥ 0.0003 (where [Zr], [Hf], [O], [N], and [S] are the contents [mass%] of the respective elem...
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WO/2022/145070A1 |
Provided is a steel material that has a specific chemical composition satisfying 0.40 [La] + 0.40 [Ce] + 0.39 [Nd] + 0.63 [Y] − 2.33 [O] − 1.74 [S] − 1.80 [P] ≥ 0.0003 (where [La], [Ce], [Nd], [Y], [O], [S], and [P] are the conte...
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WO/2022/145061A1 |
Provided is a steel material that has a specific chemical composition satisfying 0.40[Pr]+0.37[Sm]+0.
37[Eu]+0.36[Gd]+0.35
[Tb]+0.34[D...
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WO/2022/145066A1 |
Provided is a steel material having a prescribed chemical composition which satisfies Z≥0.0003 and 1.80×[P]-Z<0.010 (In the formulas, Z=0.61[Zr]+0.31[Hf]-1.75[O]-3.99[N]-1.74[S], and [Zr], [Hf], [O], [N], [S] and [P] represent the con...
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WO/2022/145063A1 |
Provided is a steel material having a predetermined chemical composition satisfying X ≥ 0.0003 and 1.80 x [P] – X < 0.010 (in the expressions: X = 0.40 [Pr] + 0.37 [Sm] + 0.37 [Eu] + 0.36 [Gd] + 0.35 [Tb] + 0.34 [Dy] + 0.34 [Ho] + 0....
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WO/2022/145069A1 |
Provided is a steel material having a predetermined chemical composition satisfying 0.61 [Zr] + 0.31 [Hf] – 1.75 [O] – 3.99 [N] – 1.74 [S] ≥ 0.0003 (in the expression, [Zr], [Hf], [O], [N], [C], and [S] represent the content [mas...
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WO/2022/145064A1 |
Provided is a steel material which has a predetermined chemical composition and which contains inclusions containing at least one kind from among Pr, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, and Sc and one or two kinds from S and O, where...
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WO/2022/145290A1 |
Provided is a plating structure including a substrate configured from Cu or a Cu alloy, an Ni electrolytic plating film formed on the substrate, a Pd plating film formed on the Ni electrolytic plating film, and an Au plating film formed ...
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WO/2022/136552A1 |
Non-magnetic part comprising an austenitic alloy, the austenitic alloy comprising between 50 and 85 wt % of iron, one or more gammagene elements the weight percentage or the total weight percentages of which amount to between 15 and 35 w...
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WO/2022/137691A1 |
The present invention pertains to a nickel powder or an aggregate of nickel particles having a 50%-particle diameter D50 of 100 nm or less in a number distribution obtained through measurement performed with scanning electron microscope ...
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WO/2022/139339A1 |
Present embodiments suggest deployable solar panels which are mounted on a moving body capable of moving, the panels comprising: solar panels which are mounted on the exterior of the moving body to convert light energy into electric ener...
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WO/2022/138645A1 |
The present invention provides: a nickel-based alloy which has excellent alkali corrosion resistance and excellent weldability; and a heat treatment furnace component which is formed of this Ni-based alloy. This Ni-based alloy, which h...
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WO/2022/131194A1 |
A coating device that comprises one or more coating heads, each of which has edge members facing each other, wherein the amount of a coating liquid to be applied is controlled by controlling the distance between the edge members. This co...
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WO/2022/132928A1 |
Nickel alloys, methods of making nickel alloys, articles including the nickel alloys, uses of the alloys, and methods of treating nickel alloys are described. The inventive heat resistant structural materials are suitable for application...
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WO/2022/122639A1 |
This disclosure relates to a friction stir welding (FSW) tool holder comprising a nickel-chromium based alloy.
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WO/2022/123297A1 |
The invention relates to a substantially equiatomic FeCo-alloy cold-rolled strip or sheet, and to a magnetic part cut from same, as well as to a method for fabricating a FeCo-alloy cold-rolled strip or sheet. A fully recrystallised hot-r...
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WO/2022/123830A1 |
Provided is a turbine component production method, and the like, with which it is possible to obtain a single-crystal structure more simply and produce a favorable turbine component. In a seed crystal placement step, a seed crystal is pl...
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WO/2022/124344A1 |
Provided are: a permanent magnet having a high coercive force; a method for manufacturing same; and a device using said permanent magnet. This permanent magnet has a composition represented by formula (1). Formula (1): (R1-xZrx)a(T1-...
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