公开(公告)号：US12115579B2

公开(公告)日：2024-10-15

申请号：US18550677

申请日：2022-03-15

Applicant: K.K. SUN METALON

Inventor： Kazuhiko Nishioka ,  Koji Kageyama

IPC: B22F3/16 ,  B22F1/12 ,  B22F3/00 ,  B22F3/14 ,  B22F3/24 ,  B22F5/00 ,  B22F7/02 ,  B22F9/20 ,  B22F10/10 ,  B22F10/20 ,  B22F10/22 ,  B22F10/25 ,  B22F10/66 ,  B22F12/41 ,  B22F12/50 ,  B22F12/60 ,  B22F12/70 ,  B23K1/005 ,  B33Y10/00 ,  B33Y30/00 ,  B33Y70/10 ,  B22F3/105

CPC classification number: B22F10/22 ,  B22F1/12 ,  B22F3/004 ,  B22F3/14 ,  B22F3/16 ,  B22F3/24 ,  B22F5/00 ,  B22F7/02 ,  B22F9/20 ,  B22F10/10 ,  B22F10/20 ,  B22F10/25 ,  B22F10/66 ,  B22F12/41 ,  B22F12/50 ,  B22F12/60 ,  B22F12/70 ,  B23K1/005 ,  B33Y10/00 ,  B33Y30/00 ,  B33Y70/10 ,  B22F2003/1054 ,  B22F2201/01 ,  B22F2201/10 ,  B22F2201/50 ,  B22F2202/11 ,  B22F2301/052 ,  B22F2301/35 ,  B22F2998/10 ,  B22F2999/00 ,  C04B2237/34 ,  C04B2237/363

Abstract: Provided is a method for producing a metal solid, the method being capable of easily producing a metal solid. A method for producing a metal solid, the method comprising covering at least a portion of the periphery of a metal powder with a high-melting-point material having a melting point higher than the melting point of the metal powder; and irradiating the metal powder, at least a portion of the periphery of which is covered with the high-melting-point material, with microwaves to heat the metal powder, thereby sintering or melt-solidifying the metal powder.

公开(公告)号：US12052920B1

公开(公告)日：2024-07-30

申请号：US18533907

申请日：2023-12-08

Applicant: HARBIN INSTITUTE OF TECHNOLOGY

Inventor： Jiehe Sui ,  Liangjun Xie ,  Zihang Liu ,  Fengkai Guo

IPC: H10N10/01 ,  B22F1/054 ,  B22F3/12 ,  B22F5/00 ,  B22F9/04 ,  H10N10/853

CPC classification number: H10N10/01 ,  B22F1/054 ,  B22F3/12 ,  B22F5/006 ,  B22F9/04 ,  B22F2009/043 ,  B22F2201/11 ,  B22F2201/50 ,  B22F2301/058 ,  B22F2301/10 ,  B22F2301/255 ,  B22F2304/05 ,  H10N10/853

Abstract: The present disclosure provides a preparation method of a contact material with high thermal stability and low contact resistance based on an MgAgSb-based thermoelectric material and relates to the field of the contact materials preparation. The present disclosure aims to solve the problem of failure to achieve long-term stability for the MgAgSb/Mg3Bi2 device due to the fact that a contact material used by MgAgSb is Ag and MgAgSb may easily yield Ag3Sb in an Ag-rich environment at present. The method includes: at step 1, preparing MgCuSb nano-powder; at step 2, preparing MgCu0.1Ag0.87Sb0.99 nano-powder; at step 3, preparing MgCu0.1Ag0.87Sb0.99—Mg3.2Bi1.5Sb0.5 thermoelectric generation device. The present disclosure is applied to preparation of a contact material with high thermal stability and low contact resistance based on an MgAgSb-based thermoelectric material.

公开(公告)号：US09780236B2

公开(公告)日：2017-10-03

申请号：US14553181

申请日：2014-11-25

Applicant: INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE

Inventor： Chun-Yi Chiu ,  Kuo-Chan Chiou ,  Wei-Han Hsiao

IPC: H01B1/02 ,  H01L31/0224 ,  C09D5/24 ,  C09J9/02 ,  H01B1/22 ,  H01B1/24 ,  B22F1/00 ,  C22C32/00 ,  C09J11/04 ,  C08K3/04 ,  C08K3/08

CPC classification number: H01L31/022425 ,  B22F1/0014 ,  B22F2999/00 ,  C08K3/04 ,  C08K2003/0806 ,  C08K2003/085 ,  C08K2201/001 ,  C09D5/24 ,  C09J9/02 ,  C09J11/04 ,  C22C32/0089 ,  H01B1/22 ,  H01B1/24 ,  B22F3/10 ,  B22F2201/50

Abstract: Disclosed is a conductive paste composition, including 100 parts by weight of copper powder, 40 to 150 parts by weight of silver powder, 0.1 to 3 parts by weight of carbon powder, 1 to 5 parts by weight of glass powder, and 5 to 15 parts by weight of binder. The conductive paste composition can be applied on a substrate, and then sintered under atmosphere at a high temperature to form an electrode on the substrate.

公开(公告)号：US20170218512A1

公开(公告)日：2017-08-03

申请号：US15013091

申请日：2016-02-02

Applicant: National Cheng Kung University ,  Delta Electronics Inc.

Inventor： Wen-Hsi Lee ,  Hsin-Chang Tsai

IPC: C23C16/442

CPC classification number: C23C16/442 ,  B22F1/00 ,  B22F1/0055 ,  B22F1/025 ,  B22F2998/10 ,  B22F2999/00 ,  B22F1/0088 ,  B22F2001/0092 ,  B22F9/24 ,  B22F3/1007 ,  B22F2201/50

Abstract: A thick-film copper paste is made. A displacement reaction with low cost is used to precipitate nano-silver (Ag) to be grown on copper particles. Thus, the thick-film copper paste is made of the copper powder coated with nano-Ag. The paste can be sintered in the air and is increased in overall electrical conductivity. The copper inside is not oxidized. Its resistance on electromigration is good. Furthermore, the paste can be added with frit as a sintering aid to assist sintering the nano-Ag-coated copper paste. Furthermore, even in a high-temperature heat treatment, the powder of nano-Ag-coated copper is still antioxidant and can replace the silver paste used in the current market.

公开(公告)号：US20160311167A1

公开(公告)日：2016-10-27

申请号：US15105272

申请日：2014-12-09

Applicant: VOXELJET AG

Inventor： Daniel Günther ,  Johannes Günther

IPC: B29C67/00 ,  B28B1/00 ,  B22F3/00 ,  B33Y10/00 ,  B33Y30/00

CPC classification number: B29C64/165 ,  B22F3/008 ,  B22F2003/1056 ,  B22F2201/50 ,  B28B1/001 ,  B29C64/20 ,  B33Y10/00 ,  B33Y30/00 ,  Y02P10/295

Abstract: The invention relates to a method for producing three-dimensional models by means of a layering technique, particulate build material being applied to a build space in a layer, and a binder fluid then being selectively applied to the build material, proceeding in layers, and these steps being repeated until the desired model is produced, a controlled air flow being conducted through the applied build material, as well as a device for carrying out the method and thus produced models.

Abstract translation: 本发明涉及一种通过分层技术生产三维模型的方法，将颗粒构建材料施加到层中的构建空间上，然后将粘合剂流体选择性地施加到构建材料上，并以层状方式进行，以及 重复这些步骤，直到产生期望的模型，通过所施加的构建材料进行受控气流，以及用于执行该方法并因此产生的模型的装置。

公开(公告)号：US20160236422A1

公开(公告)日：2016-08-18

申请号：US15011923

申请日：2016-02-01

Applicant: Shozo Sakura

Inventor： Shozo Sakura

IPC: B29C67/00 ,  B08B5/02 ,  B22F3/24

CPC classification number: B29C67/0096 ,  B08B5/02 ,  B22F3/1055 ,  B22F2003/1058 ,  B22F2003/247 ,  B22F2999/00 ,  B29C64/153 ,  B29C64/165 ,  B29C64/35 ,  B29K2103/00 ,  B29K2105/251 ,  B33Y30/00 ,  B33Y40/00 ,  Y02P10/295 ,  B22F2201/50 ,  B22F2201/20

Abstract: A powder removal device includes an air spray configured to blow an airflow including powder against a three-dimensional object including a plurality of fabrication layers, to remove unbonded powder from the three-dimensional object. Each of the plurality of fabrication layers includes bonded powder.

Abstract translation: 粉末去除装置包括：空气喷雾，其构造成将包括粉末的气流吹向包括多个制造层的三维物体，以从三维物体除去未结合的粉末。 多个制造层中的每一个包括粘结粉末。

公开(公告)号：US07527761B2

公开(公告)日：2009-05-05

申请号：US11014198

申请日：2004-12-15

Applicant: Ruthie Swartzlander ,  W. Grover Coors

Inventor： Ruthie Swartzlander ,  W. Grover Coors

IPC: B28B3/00

CPC classification number: C04B35/488 ,  B22F2998/10 ,  B22F2999/00 ,  C04B2235/3225 ,  C04B2235/3279 ,  C04B2235/656 ,  C04B2235/6567 ,  C04B2235/762 ,  C22C1/058 ,  C22C29/12 ,  H01M4/8885 ,  H01M8/1253 ,  H01M2008/1293 ,  H01M2300/0077 ,  Y02E60/525 ,  Y02P70/56 ,  B22F1/0003 ,  B22F2201/013 ,  B22F2201/50

Abstract: A method of making a solid electrolyte-YSZ product, where the method includes the step of providing a powdered mixture of zirconia, yttria and a metal oxide, where yttria-stabilized zirconia is not added to the mixture. The method also includes sintering the powdered mixture at about 1500° C. or less, for about 5 hours or less, to form a two-phase composite that includes cubic YSZ and the metal oxide. Also, a method of making a fuel cell electrode that includes the step of forming a green body that includes zirconia, yttria and a metal oxide, where yttria-stabilized zirconia is not added to the green body. The method also includes shaping the green body into a form of the electrode, and sintering the green body at about 1500° C. or less to form a two-phased sintered body that includes cubic yttria-stabilized zirconia and the metal oxide. The method may further include reducing the sintered body to form the electrode.

Abstract translation: 一种制备固体电解质YSZ产品的方法，其中所述方法包括提供氧化锆，氧化钇和金属氧化物的粉末混合物的步骤，其中不向混合物中加入氧化钇稳定的氧化锆。 该方法还包括在约1500℃或更低温度下烧结约5小时或更短时间的粉末混合物以形成包括立方YSZ和金属氧化物的两相复合材料。 此外，制造燃料电池电极的方法包括形成氧化锆，氧化钇和金属氧化物的生坯的步骤，其中不向生坯中添加氧化钇稳定的氧化锆。 该方法还包括将生坯成形为电极的形式，并在约1500℃或更低温度下烧结生坯以形成包括立方氧化钇稳定的氧化锆和金属氧化物的双相烧结体。 该方法还可以包括减少烧结体以形成电极。

公开(公告)号：US20080230737A1

公开(公告)日：2008-09-25

申请号：US12076336

申请日：2008-03-17

Applicant: Chio Ishihara ,  Kazuo Asaka ,  Kohei Muramatsu ,  Tsuyoshi Akao ,  Hirotake Hamamatsu

Inventor： Chio Ishihara ,  Kazuo Asaka ,  Kohei Muramatsu ,  Tsuyoshi Akao ,  Hirotake Hamamatsu

IPC: H01F1/00

CPC classification number: H01F41/0246 ,  B22F1/0062 ,  B22F3/24 ,  B22F2003/248 ,  B22F2998/10 ,  B22F2999/00 ,  C22C2202/02 ,  H01F1/24 ,  H01F1/26 ,  B22F3/02 ,  B22F2201/10 ,  B22F2201/02 ,  B22F2201/50

Abstract: A method for producing a soft magnetic powdered core comprises a mixing step for forming a raw powder by adding a thermoplastic resin powder to a soft magnetic powder and mixing them, a compacting step for forming a compact by compacting the raw powder into a predetermined shape, a melting and setting step for the resin in which the resin of the compact is melted by heating to at least the melting point of the thermoplastic resin and the melted resin is set by cooling to a room temperature, and a crystallizing step for the resin in which the set resin is heated to not less than the exothermic onset temperature and not more than the endothermic onset temperature, which are measured by DSC analysis of the thermoplastic resin, and is cooled to a room temperature.

Abstract translation: 一种软磁性粉末芯的制造方法，其特征在于，包括：将热塑性树脂粉末添加到软磁性粉末并混合而形成原料粉末的混合工序，将原料粉末压制为规定形状的压实成形工序， 将通过加热到至少热塑性树脂和熔融树脂的熔点而使压块的树脂熔化的树脂的熔融和凝固步骤通过冷却至室温来设定，并且树脂的结晶步骤 将该树脂加热至不低于通过热塑性树脂的DSC分析测定的放热起始温度和不高于吸热开始温度，并冷却至室温。

公开(公告)号：US20080226487A1

公开(公告)日：2008-09-18

申请号：US12074127

申请日：2008-02-29

Applicant: Yuji Akimoto ,  Kazuro Nagashima ,  Hidenori Ieda ,  Hitomi Yanagi

Inventor： Yuji Akimoto ,  Kazuro Nagashima ,  Hidenori Ieda ,  Hitomi Yanagi

IPC: B22F3/11 ,  C22C19/03

CPC classification number: B22F1/0088 ,  B22F2998/00 ,  B22F2998/10 ,  B22F2999/00 ,  H01G4/008 ,  H01G4/30 ,  B22F1/02 ,  B22F9/30 ,  B22F2201/50

Abstract: A nickel powder with an average particle size of 0.05 to 1.0 μm, which is composed of nickel particles having an oxidized surface layer and containing sulfur, wherein the sulfur content with respect to the total weight of the powder is 100 to 2000 ppm, and the intensity of a peak identified to sulfur bonded to nickel in surface analysis by ESCA of the nickel particles varies in a direction toward the center from the surface of the particles, and this intensity has its maximum at a location deeper than 3 nm from the particle outermost surface. This nickel powder is manufactured by bringing a nickel powder containing sulfur and dispersed in a non-oxidizing gas atmosphere into contact with an oxidizing gas at a high temperature.

Abstract translation: 平均粒径为0.05〜1.0μm的镍粉末，其由具有氧化表面层且含有硫的镍粒子组成，其中相对于粉末总重量的硫含量为100〜2000ppm， 通过镍颗粒的ESCA进行的表面分析中鉴定为硫结合的峰的强度在从颗粒表面朝向中心的方向上变化，并且该强度在距离颗粒最外侧的3nm以下的位置处具有最大值 表面。 该镍粉是通过将含硫的镍粉末分散在非氧化性气体气氛中与高温下的氧化性气体接触来制造的。

公开(公告)号：US20240165700A1

公开(公告)日：2024-05-23

申请号：US18550677

申请日：2022-03-15

Applicant: K.K. SUN METALON

Inventor： Kazuhiko NISHIOKA ,  Koji KAGEYAMA

IPC: B22F3/16 ,  B22F3/00 ,  B22F3/24 ,  B22F5/00 ,  B22F7/02 ,  B22F9/20

CPC classification number: B22F3/16 ,  B22F3/004 ,  B22F3/24 ,  B22F5/00 ,  B22F7/02 ,  B22F9/20 ,  B22F2201/01 ,  B22F2201/10 ,  B22F2201/50 ,  B22F2202/11 ,  B22F2301/052 ,  B22F2301/35 ,  B22F2998/10 ,  B22F2999/00

Abstract: Provided is a method for producing a metal solid, the method being capable of easily producing a metal solid. A method for producing a metal solid, the method comprising covering at least a portion of the periphery of a metal powder with a high-melting-point material having a melting point higher than the melting point of the metal powder; and irradiating the metal powder, at least a portion of the periphery of which is covered with the high-melting-point material, with microwaves to heat the metal powder, thereby sintering or melt-solidifying the metal powder.