公开(公告)号：US20180051382A1

公开(公告)日：2018-02-22

申请号：US15537279

申请日：2015-12-15

Applicant: UNIVERSITÉ LAVAL

Inventor： Marc-André FORTIN ,  Mathieu BOUCHARD ,  Christian SARRA-BOURNET ,  Stéphane TURGEON

IPC: C25C7/06 ,  B22F1/00 ,  B22F9/16 ,  C25C1/20 ,  C25C5/02 ,  C25C7/02 ,  H05H1/24

CPC classification number: C25C7/06 ,  B22F1/0014 ,  B22F1/0018 ,  B22F9/12 ,  B22F9/16 ,  B22F2301/255 ,  B22F2999/00 ,  C25C1/20 ,  C25C5/02 ,  C25C7/00 ,  C25C7/02 ,  H05H1/00 ,  H05H1/2406 ,  H05H2001/2412 ,  H05H2242/10 ,  H05H2245/124 ,  B22F9/24 ,  B22F2202/13 ,  B22F2201/013 ,  B22F2201/02 ,  B22F2201/03 ,  B22F2201/04 ,  B22F2201/05 ,  B22F2201/10 ,  B22F2201/50

Abstract: A dielectric barrier discharge (DBD) plasma apparatus for synthesizing metal particles is provided. The DBD plasma apparatus includes an electrolyte vessel for receiving an electrolyte solution comprising metal ions; an electrode spaced-apart from the electrolyte vessel; a dielectric barrier interposed between the electrolyte vessel and the electrode such that, when the electrolyte solution is present in the electrolyte vessel, the dielectric barrier and an upper surface of the electrolyte solution are spaced-apart from each other and define a discharge area therebetween; and gas inlet and outlet ports in fluid communication with the discharge area such that supplying gas in the discharge area while applying an electrical potential difference between the electrode and the electrolyte solution cause a plasma to be produced onto the electrolyte solution, the plasma interacting with the metal ions and synthesizing metal particles. A method for synthesizing metal particles using a DBD plasma apparatus is also provided.

公开(公告)号：US20170305808A1

公开(公告)日：2017-10-26

申请号：US15731136

申请日：2017-04-24

Applicant: Iowa State University Research Foundation, Inc.

Inventor： Iver E. Anderson ,  Andrew D. Steinmetz ,  David J. Byrd

IPC: C06B45/30 ,  B22F1/00 ,  B22F9/16 ,  B22F9/08

CPC classification number: C06B45/30 ,  B22F1/0088 ,  B22F9/082 ,  B22F9/16 ,  B22F2009/0844 ,  B22F2999/00 ,  B22F2201/03 ,  B22F2201/00 ,  B22F2201/10

Abstract: A method for gas atomization of oxygen-reactive reactive metals and alloys wherein the atomized particles are exposed as they solidify and cool in a very short time to multiple gaseous reactive agents for the in-situ formation of a protective reaction film on the atomized particles. The present invention is especially useful for making highly pyrophoric reactive metal or alloy atomized powders, such as atomized magnesium and magnesium alloy powders. The gaseous reactive species (agents) are introduced into the atomization spray chamber at locations downstream of a gas atomizing nozzle as determined by the desired powder or particle temperature for the reactions and the desired thickness of the reaction film.

公开(公告)号：US20170129009A1

公开(公告)日：2017-05-11

申请号：US14936428

申请日：2015-11-09

Applicant: Delavan Inc

Inventor： Vijay Jagdale ,  Tahany I. El-Wardany ,  Wayde R. Schmidt

IPC: B22F3/10 ,  B22F3/105 ,  B22F7/02

CPC classification number: B22F3/1003 ,  B22F3/1055 ,  B22F7/02 ,  B22F7/06 ,  B22F2202/11 ,  B22F2301/052 ,  B22F2301/10 ,  B22F2301/25 ,  B22F2302/40 ,  B22F2998/10 ,  B29C64/153 ,  B33Y10/00 ,  B33Y70/00 ,  B33Y80/00 ,  C22C26/00 ,  C22C32/0084 ,  Y02P10/295 ,  B22F3/1007 ,  B22F2201/03 ,  B22F2201/01

Abstract: A method of additive manufacturing includes depositing a layer of absorptive material onto a workpiece, depositing a layer of additive manufacturing stock powder onto the workpiece, and fusing the stock powder to the workpiece using a focused energy source at a wavelength wherein the absorptive material has a higher absorptivity at the wavelength of the focused energy source than the absorptivity of the stock powder at that wavelength. The focused energy source can be a laser, e.g., with a 1064 nm wavelength, for example.

公开(公告)号：US09637824B2

公开(公告)日：2017-05-02

申请号：US14507945

申请日：2014-10-07

Applicant: United Technologies Corporation

Inventor： Michael J. Birnkrant

IPC: B22F3/11 ,  C23C18/12 ,  C22C1/08 ,  B22F1/00 ,  C22C32/00

CPC classification number: C23C18/1254 ,  B22F1/0018 ,  B22F1/0022 ,  B22F1/0059 ,  B22F3/1125 ,  B22F3/1143 ,  B22F2201/03 ,  B22F2201/04 ,  B22F2302/40 ,  B22F2302/45 ,  C22C1/08 ,  C22C32/0084 ,  C22C2200/02 ,  C23C18/1216 ,  C23C18/1283 ,  Y10T428/249921

Abstract: A method of fabricating a metal cellular structure includes providing a sol-gel that is a colloid dispersed in a solvent, the colloid including metal-containing regions bound together by polymeric ligands, removing the solvent from the gel using supercritical drying to produce a dry gel of the metal-containing regions bound together by the polymeric ligands, and thermally converting the dry gel to a cellular structure with a coating in at least one step using phase separation of at least two insoluble elements. Also disclosed is a metal cellular structure including interconnected metal ligaments having a cellular structure and a carbon-containing coating around the metal ligaments.

公开(公告)号：US09556072B2

公开(公告)日：2017-01-31

申请号：US13379894

申请日：2010-06-22

Applicant: Johan ter Maat ,  Hans Wohlfromm ,  Martin Bloemacher ,  Arnd Thom ,  Andreas Kern

Inventor： Johan ter Maat ,  Hans Wohlfromm ,  Martin Bloemacher ,  Arnd Thom ,  Andreas Kern

IPC: B22F3/12 ,  C04B35/56 ,  B22F3/10 ,  C04B35/111 ,  C04B35/14 ,  C04B35/46 ,  C04B35/478 ,  C04B35/486 ,  C04B35/505 ,  C04B35/563 ,  C04B35/565 ,  C04B35/58 ,  C04B35/581 ,  C04B35/583 ,  C04B35/584 ,  C04B35/634 ,  C04B35/638

CPC classification number: C04B35/5626 ,  B22F3/1021 ,  B22F2998/00 ,  B22F2999/00 ,  C04B35/111 ,  C04B35/14 ,  C04B35/46 ,  C04B35/478 ,  C04B35/486 ,  C04B35/505 ,  C04B35/5607 ,  C04B35/5611 ,  C04B35/563 ,  C04B35/565 ,  C04B35/58014 ,  C04B35/581 ,  C04B35/583 ,  C04B35/584 ,  C04B35/63488 ,  C04B35/638 ,  C04B2235/6021 ,  C04B2235/6022 ,  C04B2235/6562 ,  C04B2235/6567 ,  C04B2235/6582 ,  C04B2235/6586 ,  C04B2235/661 ,  B22F3/225 ,  B22F3/20 ,  B22F3/02 ,  B22F2201/03 ,  B22F2201/01

Abstract: The invention relates to a process for the continuous thermal removal of binder from a metallic and/or ceramic shaped body which has been produced by injection molding, extrusion or pressing using a thermoplastic composition and comprises at least one polyoxymethylene homopolymer or copolymer as binder in a binder removal oven, which comprises the steps (a) removal of binder from the shaped body in a binder removal oven at a temperature which is from 5 to 20° C. below, preferably from 10 to 15° C. below, the temperature of a second temperature stage over a period of from 4 to 12 hours in a first temperature stage in an oxygen-comprising atmosphere, (b) removal of binder from the shaped body at a temperature in the range >160 to 200° C. over a period of from 4 to 12 hours in an oxygen-comprising atmosphere in a second temperature stage and (c) removal of binder from the shaped body at a temperature in the range from 200 to 600° C. over a period of from 2 to 8 hours in a third temperature stage in an oxygen-comprising or neutral or reducing atmosphere, with the shaped bodies being transported through the binder removal oven during process steps (a) and (b).

Abstract translation: 本发明涉及一种从金属和/或陶瓷成型体连续热去除粘合剂的方法，其通过使用热塑性组合物的注射成型，挤出或压制制备，并且包含至少一种聚甲醛均聚物或共聚物作为粘合剂 粘合剂去除炉，其包括以下步骤：（a）在粘合剂去除烘箱中，在低于，优选10至15℃的温度下，在低于，优选10至15℃的温度下，从成形体中去除粘合剂，温度为 在含氧气氛中的第一温度阶段中在4至12小时的时间段内的第二温度段，（b）在> 160至200℃的温度范围内从成形体上除去粘合剂， 在第二温度阶段的含氧气氛中的时间为4至12小时，和（c）在200至600℃的温度范围内从2至8的时间内从成形体中除去粘合剂 小时在第三脾气 在含氧或中性或还原性气氛中的成型阶段，其中成型体在工艺步骤（a）和（b）期间被输送通过粘合剂去除炉。

公开(公告)号：US20160303653A1

公开(公告)日：2016-10-20

申请号：US14686313

申请日：2015-04-14

Applicant: HONEYWELL INTERNATIONAL INC.

Inventor： Don Mittendorf ,  Vladimir K. Tolpygo

IPC: B22F1/00 ,  B22F1/02 ,  B22F9/16

CPC classification number: B22F1/0081 ,  B22F1/0003 ,  B22F1/0085 ,  B22F1/02 ,  B22F9/04 ,  B22F9/082 ,  B22F9/16 ,  B22F2999/00 ,  C22C1/0425 ,  C22C1/0433 ,  C22C1/056 ,  C22C1/1036 ,  C22C1/1068 ,  C22C1/1084 ,  C22C32/0026 ,  B22F2201/03 ,  B22F2202/15 ,  C22C1/1078

Abstract: Methods of forming dispersoid hardened metallic materials are provided. In an exemplary embodiment, a method of producing dispersoid hardened metallic materials includes forming a starting composition with a base metal component and a dispersoid forming component. The starting composition includes the base metal component in an amount from about 50 to about 99.999 weight percent and the dispersoid forming component in an amount from about 0.001 to about 1 weight percent, based on the total weight of the starting composition. A starting powder is formed from the starting composition, and the starting powder is fluidized with a fluidizing gas for a period of time sufficient to oxidize the dispersoid forming component to form the dispersoid hardened metallic material. The dispersoid forming component is oxidized while the starting powder is a solid.

Abstract translation: 提供了形成分散硬化金属材料的方法。 在一个示例性实施方案中，生产分散硬化的金属材料的方法包括用贱金属组分和分散质形成组分形成起始组合物。 起始组合物包含约50至约99.999重量％的量的贱金属组分和基于起始组合物总重量的约0.001至约1重量％的分散质形成组分。 起始粉末由起始组合物形成，起始粉末用流化气体流化一段足以氧化分散质形成组分的时间以形成分散固化的金属材料。 分散质形成组分被氧化，而起始粉末是固体。

公开(公告)号：US20160181624A1

公开(公告)日：2016-06-23

申请号：US15057546

申请日：2016-03-01

Applicant: PLANSEE SE

Inventor： MARCO BRANDNER ,  MICHAEL O'SULLIVAN ,  THOMAS LEITER ,  OLIVER HIRSCH ,  WOLFGANG KRAUSSLER

IPC: H01M8/0202 ,  B22F3/16 ,  B22F3/24 ,  B22F5/00 ,  H01M8/1246 ,  C22C32/00 ,  C23C8/10 ,  C23C8/02 ,  C23C8/80 ,  B22F1/00 ,  C22C27/06

CPC classification number: H01M8/0202 ,  B22F1/0003 ,  B22F3/16 ,  B22F3/24 ,  B22F5/006 ,  B22F9/20 ,  B22F2003/242 ,  B22F2005/005 ,  B22F2201/03 ,  B22F2301/20 ,  B22F2998/10 ,  B22F2999/00 ,  C22C1/045 ,  C22C1/08 ,  C22C1/1078 ,  C22C27/06 ,  C22C32/0026 ,  C23C8/02 ,  C23C8/10 ,  C23C8/80 ,  H01M8/0206 ,  H01M8/0247 ,  H01M8/0258 ,  H01M8/026 ,  H01M8/1246 ,  H01M2008/1293 ,  B22F9/04 ,  B22F3/02 ,  B22F3/1007 ,  B22F2201/013

Abstract: A powder metallurgical molding forms an interconnector or an end plate for an electrochemical cell. The molding has a chromium content of at least 80% by weight, a basic shape of a plate and one or more flow fields with structuring formed on one or both of the main faces of the molding. A ratio of a maximum diameter Dmax of the molding, measured along the main face, to a minimum thickness dmin of a core region of the molding which extends along the flow field or fields and is not affected by the structuring lies in a range of 140≦Dmax/dmin≦350.

Abstract translation: 粉末冶金模制形成用于电化学电池的互连器或端板。 该成型体具有至少80重量％的铬含量，板的基本形状和在成型体的一个或两个主面上形成的结构化的一个或多个流场。 沿着主面测量的模制品的最大直径Dmax与沿着流场或场延伸并且不受结构化影响的模制品的芯区域的最小厚度dmin的比率在140＆lt; 1E ; Dmax / dmin＆nlE; 350。

公开(公告)号：US20160114394A1

公开(公告)日：2016-04-28

申请号：US14881955

申请日：2015-10-13

Applicant: DOW GLOBAL TECHNOLOGIES LLC

Inventor： Patrick T. McGough ,  George L. Athens

IPC: B22F9/18 ,  B22F1/00

CPC classification number: B22F9/18 ,  B22F1/0025 ,  B22F9/24 ,  B22F2201/03 ,  B22F2301/255 ,  B22F2304/05 ,  B82Y40/00

Abstract: A process for manufacturing high aspect ration silver nanowires is provided, wherein the total glycol concentration is

Abstract translation: 提供了制造高倍数银纳米线的方法，其中总二醇浓度在该过程中始终为<0.001重量％。

公开(公告)号：US09314845B2

公开(公告)日：2016-04-19

申请号：US14328106

申请日：2014-07-10

Applicant: TANAKA KIKINZOKU KOGYO K.K.

Inventor： Takanobu Miyashita ,  Yasuyuki Goto ,  Takamichi Yamamoto ,  Ryousuke Kushibiki ,  Masahiro Aono ,  Masahiro Nishiura

IPC: C23C14/24 ,  B22F3/12 ,  B22F9/08 ,  C23C14/34 ,  C22C1/05 ,  C22C5/04 ,  C22C32/00 ,  G11B5/851 ,  B22F9/04 ,  C22C1/04 ,  C22C1/10 ,  H01J37/34 ,  C23C14/06 ,  C22C38/00 ,  C22C38/16

CPC classification number: B22F3/12 ,  B22F9/04 ,  B22F9/08 ,  B22F9/082 ,  B22F2201/03 ,  B22F2999/00 ,  C22C1/0466 ,  C22C1/05 ,  C22C1/10 ,  C22C5/04 ,  C22C32/00 ,  C22C38/002 ,  C22C38/16 ,  C23C14/0635 ,  C23C14/34 ,  C23C14/3414 ,  G11B5/851 ,  H01J37/3429 ,  H01J37/3491 ,  H01J2237/3322 ,  H01J2237/3323

Abstract: A process for producing an FePt-based sputtering target includes adding C powder containing unavoidable impurities and metal oxide powder containing unavoidable impurities to FePt-based alloy powder containing Pt in an amount of 40 at % or more and 60 at % or less with the balance being Fe and unavoidable impurities so that the C powder and the metal oxide powder are contained to satisfy: 0

Abstract translation: 制造FePt系溅射靶的方法包括将含有不可避免的杂质的C粉末和含有不可避免的杂质的金属氧化物粉末添加至含有40质量％以上且60原子％以下的Pt的FePt系合金粉末，余量 是Fe和不可避免的杂质，因此含有C粉末和金属氧化物粉末以满足：0 <α＆nlE; 20; 10＆nlE;＆bgr; <40; 和20＆nlE;α+＆bgr;＆nlE; 40，其中α和＆bgr; 基于FePt系合金粉末，C粉末和金属氧化物粉末的总量，分别以体积％表示C粉末和金属氧化物粉末的含量，然后将FePt系合金粉末， C粉末和金属氧化物粉末以产生粉末混合物。

公开(公告)号：US20160001371A1

公开(公告)日：2016-01-07

申请号：US14850109

申请日：2015-09-10

Applicant: DOWA Electronics Materials Co., Ltd.

Inventor： Kazumasa IKARI ,  Masahiro GOTOH ,  Takayuki YOSHIDA

IPC: B22F9/26 ,  H01F1/20 ,  B22F1/02

CPC classification number: B22F9/26 ,  B22F1/0018 ,  B22F1/02 ,  B22F9/24 ,  B22F2201/03 ,  B22F2301/35 ,  B22F2302/25 ,  B22F2303/01 ,  C22C2202/02 ,  H01F1/20 ,  H01F1/26 ,  H01F17/045 ,  H01F27/255 ,  H01F27/292 ,  H01Q1/364 ,  Y10T428/12014

Abstract: A soft magnetic metal powder is manufactured. An aqueous solution of at least one of aluminum, silicon, a rare-earth element (including Y), and magnesium is added into a solution containing an iron ion while blowing a gas containing oxygen thereinto, to form a precursor containing at least one of aluminum, silicon, a rare-earth element (including Y), and magnesium. The precursor is reduced to obtain a metal powder. The metal powder is further slowly oxidized with oxygen to form an oxidized film on the surface of the metal powder.

Abstract translation: 制造软磁性金属粉末。 将含有铝，硅，稀土元素（包括Y）和镁中的至少一种的水溶液加入含铁离子的溶液中，同时吹入含氧气体，形成含有至少一种 铝，硅，稀土元素（包括Y）和镁。 将前体还原以获得金属粉末。 金属粉末被氧气进一步缓慢氧化，以在金属粉末的表面上形成氧化膜。