| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 用于逐层构造模型的方法 | CN201280030829.5 | 2012-06-20 | CN103702958A | 2014-04-02 | 英戈·格努奇特尔; 丹尼尔·巩特尔; 英戈·埃德雷尔; 克里斯蒂安·勒斯蒂格; 埃德加·马勒 |
| 本发明说明了一种用于逐层构造模型的方法,其中在一个构造区域中逐层地施加一种颗粒状材料并且将其选择性地硬化。重复这个步骤,直到获得所希望的模型。该材料在此包括一种颗粒状的构造材料和一种喷雾干燥的碱性硅酸盐溶液。选择性地启动硬化是借助于一种包括水的溶液来进行的。 | ||||||
| 2 | 用于逐层构造模型的方法 | CN201280030829.5 | 2012-06-20 | CN103702958B | 2016-05-04 | 英戈·格努奇特尔; 丹尼尔·巩特尔; 英戈·埃德雷尔; 克里斯蒂安·勒斯蒂格; 埃德加·马勒 |
| 在此说明了一种用于逐层构造模型的方法,其中在一个构造区域中逐层地施加一种颗粒状材料并且将其选择性地硬化。重复这个步骤,直到获得所希望的模型。该材料在此包括一种颗粒状的构造材料和一种喷雾干燥的碱性硅酸盐溶液。选择性地启动硬化是借助于一种包括水的溶液来进行的。 | ||||||
| 3 | 成型组合物及用其形成用于金属铸造过程中置换件的方法 | CN200980107320.4 | 2009-02-02 | CN102026937A | 2011-04-20 | D·A·洛赫巴克尔 |
| 一种形成用于金属铸造过程中的置换件的方法,其中该方法提供多个陶瓷颗粒和树脂颗粒。该方法研磨多个陶瓷颗粒直到这些陶瓷颗粒包含小于150微米的直径,研磨多个树脂颗粒直到这些树脂颗粒包含小于100微米的直径,并形成包含多个研磨的陶瓷颗粒和多个研磨的树脂颗粒的粉末混合物。然后该方法将所述粉末混合物放置于包含空腔的模具中,该空腔限定所需的置换件。该方法进一步致密化混合物,并固化所述树脂以形成置换件。 | ||||||
| 4 | 成型组合物及用其形成用于金属铸造过程中置换件的方法 | CN200980107320.4 | 2009-02-02 | CN102026937B | 2015-02-25 | D·A·洛赫巴克尔 |
| 一种形成用于金属铸造过程中的置换件的方法,其中该方法提供多个陶瓷颗粒和树脂颗粒。该方法研磨多个陶瓷颗粒直到这些陶瓷颗粒包含小于150微米的直径,研磨多个树脂颗粒直到这些树脂颗粒包含小于100微米的直径,并形成包含多个研磨的陶瓷颗粒和多个研磨的树脂颗粒的粉末混合物。然后该方法将所述粉末混合物放置于包含空腔的模具中,该空腔限定所需的置换件。该方法进一步致密化混合物,并固化所述树脂以形成置换件。 | ||||||
| 5 | 粘合铝-硼-碳复合材料的改进方法 | CN200780038633.X | 2007-10-17 | CN101528407B | 2012-01-04 | 亚历山大·皮茨克; 罗伯特·纽曼 |
| 通过形成由微粒构成的多孔体,使得在所述多孔体的表面上具有二硼化钛粉末的微粒层,制备出铝-硼-碳(ABC)陶瓷-金属复合材料,所述的(ABC)复合材料与不同于ABC复合材料的金属或金属-陶瓷复合材料粘合,所述微粒由硼-碳化合物构成。所述多孔体渗入有铝或其合金,并且同时产生TiB2层的渗入,其中该层的铝金属含量比所述(ABC)复合材料大至少约10个百分点。然后,ABC复合材料经由渗入的二硼化钛层与金属或金属-陶瓷体熔合,其中所述金属-陶瓷体是不同于铝-硼-碳复合材料的复合材料。 | ||||||
| 6 | 粘合铝-硼-碳复合材料的改进方法 | CN200780038633.X | 2007-10-17 | CN101528407A | 2009-09-09 | 亚历山大·皮茨克; 罗伯特·纽曼 |
| 通过形成由微粒构成的多孔体,使得在所述多孔体的表面上具有二硼化钛粉末的微粒层,制备出铝-硼-碳(ABC)陶瓷-金属复合材料,所述的(ABC)复合材料与不同于ABC复合材料的金属或金属-陶瓷复合材料粘合,所述微粒由硼-碳化合物构成。所述多孔体渗入有铝或其合金,并且同时产生TiB2层的渗入,其中该层的铝金属含量比所述(ABC)复合材料大至少约10个百分点。然后,ABC复合材料经由渗入的二硼化钛层与金属或金属-陶瓷体熔合,其中所述金属-陶瓷体是不同于铝-硼-碳复合材料的复合材料。 | ||||||
| 7 | Method for producing electrode assembly | US14172006 | 2014-02-04 | US09350013B2 | 2016-05-24 | Tsutomu Teraoka; Sukenori Ichikawa; Hirofumi Hokari; Tomofumi Yokoyama |
| A method for producing an electrode assembly includes: obtaining a porous active material molded body by molding a constituent material containing a lithium multiple oxide in the form of particles by compression, and then performing a heat treatment at a temperature of 850° C. or higher and lower than the melting point of the used lithium multiple oxide; forming a solid electrolyte layer by applying a liquid containing a constituent material of an inorganic solid electrolyte to the surface of the active material molded body including the inside of each pore of the active material molded body, and then performing a heat treatment; and bonding a current collector to the active material molded body exposed from the solid electrolyte layer. | ||||||
| 8 | METHOD FOR PRODUCING ELECTRODE ASSEMBLY | US14172006 | 2014-02-04 | US20140216631A1 | 2014-08-07 | Tsutomu TERAOKA; Sukenori ICHIKAWA; Hirofumi HOKARI; Tomofumi YOKOYAMA |
| A method for producing an electrode assembly includes: obtaining a porous active material molded body by molding a constituent material containing a lithium multiple oxide in the form of particles by compression, and then performing a heat treatment at a temperature of 850° C. or higher and lower than the melting point of the used lithium multiple oxide; forming a solid electrolyte layer by applying a liquid containing a constituent material of an inorganic solid electrolyte to the surface of the active material molded body including the inside of each pore of the active material molded body, and then performing a heat treatment; and bonding a current collector to the active material molded body exposed from the solid electrolyte layer. | ||||||
| 9 | Method of bonding aluminum-boron-carbon composites | US11873837 | 2007-10-17 | US08186565B1 | 2012-05-29 | Aleksander J. Pyzik; Robert A. Newman |
| An aluminum-boron-carbon (ABC) ceramic-metal composite bonded to a metal or metal-ceramic composite other than ABC composite is made by forming a porous body comprised of particulates being comprised of a boron-carbon compound that has a particulate layer of titanium diboride powder on the surface of the porous body. The porous body is infiltrated with aluminum or alloy thereof resulting in the simultaneous infiltration of the TiB2 layer, where the layer has an aluminum metal content that is at least about 10 percentage points greater by volume than the (ABC) composite. The ABC composite is then fused to a metal or metal-ceramic body through the infiltrated layer of titanium diboride, wherein the metal-ceramic body is a composite other than an aluminum-boron-carbon composite. | ||||||
| 10 | Manufacturing method of prefrom for composite material of automobile | US558260 | 1995-11-13 | US5693274A | 1997-12-02 | Jun-Su Kim |
| The present invention relates to a manufacturing method of preform for composite material of automobile, in particular, to an economical and easy mass-production manufacturing method of preform including the steps of manufacturing a wet sheet by pouring a suspension prepared by adding inorganic binder, organic binder and cohesion agent to reinforced fiber, into vacuum suction equipment, and forming the sheet into a cylindrical shape with cylindrical press and deforming the sheet form before drying. | ||||||
| 11 | Method of producing a composite material for the preform of vehicle | JP31399495 | 1995-12-01 | JP2765653B2 | 1998-06-18 | JUNNSU KIMU |
| 12 | MASS PREPARATION FOR THE MANUFACTURE OF TECHNICAL CONCRETES FOR SHIELDING AGAINST RADIATION AND METHOD TO OBTAIN SAID PREPARATION | US15160407 | 2016-05-20 | US20160343460A1 | 2016-11-24 | Juan Manuel CARUNCHO RODADO |
| Mass preparation for the manufacture of technical concretes for shielding against radiation, of the type comprising a mixture of cement, aggregates and water; wherein the cement comprises aluminous cement and/or Portland type cement, while the aggregates comprise slag from metallurgy foundry castings. The method for obtaining said preparation includes the analysis and selection of suitable slag, its filtering and classification, plotting of the Bolomey curve depending on the intended use of the finished concrete, as well as the mixture of elements and their vibration. | ||||||
| 13 | PROCESS FOR THE MANUFACTURING OF DENSE SILICON CARBIDE | US12880751 | 2010-09-13 | US20110059240A1 | 2011-03-10 | Abuagela H. Rashed; Rex G. Sheppard; Donald J. Bray |
| A method of producing a densified SiC article is provided. Near-net shape porous silicon carbide articles are produced and densified using the developed method. A substantial number of pores within the porous near-net shape silicon carbide article are filled (impregnated) with a carbon precursor, a silicon carbide precursor, or a mixture of both. The carbon precursor can be liquid or gas. The filled SiC preform is heated to convert the carbon or silicon carbide precursor to porous carbon or SiC preform inside the pores of the net-shape silicon carbide article. The impregnation/pyrolysis cycle is repeated until the desired amount of carbon and/or silicon carbide is achieved. In case of a carbon or a mixture of silicon carbide/carbon precursor is used, the pyrolyzed near-net shape silicon carbide article is then contacted with silicon in an inert atmosphere. The silicon diffuses through the pyrolyzed near-net shape silicon carbide article and reacts with the carbon contained within the pores of the porous SiC preform producing a new phase of silicon carbide within the pores of the near-net shape silicon carbide article. The produced silicon carbide is a near-net dense silicon carbide article. | ||||||
| 14 | Process for the manufacturing of dense silicon carbide | US11170199 | 2005-06-29 | US07799375B2 | 2010-09-21 | Abuagela H. Rashed; Rex G. Sheppard; Donald J. Bray |
| A method of producing a densified SiC article is provided. Near-net shape porous silicon carbide articles are produced and densified using the developed method. A substantial number of pores within the porous near-net shape silicon carbide article are filled (impregnated) with a carbon precursor, a silicon carbide precursor, or a mixture of both. The carbon precursor can be liquid or gas. The filled SiC preform is heated to convert the carbon or silicon carbide precursor to porous carbon or SiC preform inside the pores of the net-shape silicon carbide article. The impregnation/pyrolysis cycle is repeated until the desired amount of carbon and/or silicon carbide is achieved. In case of a carbon or a mixture of silicon carbide/carbon precursor is used, the pyrolyzed near-net shape silicon carbide article is then contacted with silicon in an inert atmosphere. The silicon diffuses through the pyrolyzed near-net shape silicon carbide article and reacts with the carbon contained within the pores of the porous SiC preform producing a new phase of silicon carbide within the pores of the near-net shape silicon carbide article. The produced silicon carbide is a near-net dense silicon carbide article. | ||||||
| 15 | Process for the manufacturing of dense silicon carbide | US11170199 | 2005-06-29 | US20060003098A1 | 2006-01-05 | Abuagela Rashed; Rex Sheppard; Donald Bray |
| A method of producing a densified SiC article is provided. Near-net shape porous silicon carbide articles are produced and densified using the developed method. A substantial number of pores within the porous near-net shape silicon carbide article are filled (impregnated) with a carbon precursor, a silicon carbide precursor, or a mixture of both. The carbon precursor can be liquid or gas. The filled SiC preform is heated to convert the carbon or silicon carbide precursor to porous carbon or SiC preform inside the pores of the net-shape silicon carbide article. The impregnation/pyrolysis cycle is repeated until the desired amount of carbon and/or silicon carbide is achieved. In case of a carbon or a mixture of silicon carbide/carbon precursor is used, the pyrolyzed near-net shape silicon carbide article is then contacted with silicon in an inert atmosphere. The silicon diffuses through the pyrolyzed near-net shape silicon carbide article and reacts with the carbon contained within the pores of the porous SiC preform producing a new phase of silicon carbide within the pores of the near-net shape silicon carbide article. The produced silicon carbide is a near-net dense silicon carbide article. | ||||||
| 16 | Process for forming a high temperature resistant, flexible, pliable elements curable by false-melt technique | US956511 | 1997-10-23 | US5863481A | 1999-01-26 | Jill E. Crumpacker; Kurt C. Kelley |
| A process for forming pliable elements curable by hot pressing to form high temperature resistant elements is disclosed. In this process, a metal, a metal compound, or a mixture thereof, which has some water of hydration, is mixed with orthophosphoric acid in an amount sufficient to form a resultant mixture having a pH value no greater than 0.85. A refractory material is added to the mixture and a resultant pliable curable material is formed. An element of a preselected configuration is formed from the pliable curable material. The element is dried at a temperature less than about 100.degree. C. for a period of time sufficient to form a pliable curable element having a stable unitary mass. The pliable element is cured by "false melt" processing techniques. | ||||||
| 17 | Method for the layerwise construction of models | US14126933 | 2012-06-20 | US09358701B2 | 2016-06-07 | Ingo Gnüchtel; Daniel Günther; Ingo Ederer; Christian Lustig; Edgar Müller |
| A method is described here for the layerwise construction of models, wherein, in a building region, a particulate material is applied layerwise and selectively cured. These steps are repeated until a desired model is obtained. The material comprises in this case a particulate building material and a spray-dried alkali metal silicate solution. Selective activation of the curing proceeds using a water-comprising solution. | ||||||
| 18 | METHOD FOR THE LAYERWISE CONSTRUCTION OF MODELS | US14126933 | 2012-06-20 | US20140212677A1 | 2014-07-31 | Ingo Gnüchtel; Daniel Günther; Ingo Ederer; Christian Lustig; Edgar Müller |
| A method is described here for the layerwise construction of models, wherein, in a building region, a particulate material is applied layerwise and selectively cured. These steps are repeated until a desired model is obtained. The material comprises in this case a particulate building material and a spray-dried alkali metal silicate solution. Selective activation of the curing proceeds using a water-comprising solution. | ||||||
| 19 | Molding composition and method using same to form displacements for use in a metal casting process | US12364135 | 2009-02-02 | US08506861B2 | 2013-08-13 | David A. Rohrbacker |
| A method to form a displacement for use in a metal casting process, wherein the method provides a plurality of ceramic particles and a plurality of resin particles. The method grinds the plurality of ceramic particles until those ceramic particles comprise diameters less than 150 microns, and grinds the plurality of resin particles until those resin particles comprise diameters less than 100 microns, and forms a powder blend comprising the plurality of ground ceramic particles and the plurality of ground resin particles. The method then disposes the powder blend into a mold comprising a cavity defining the desired displacement. The method further densifies the blend, and cures the resin to form the displacement. | ||||||
| 20 | Process for the manufacturing of dense silicon carbide | US12880751 | 2010-09-13 | US08142845B2 | 2012-03-27 | Abuagela H. Rashed; Rex G. Sheppard; Donald J. Bray |
| A method of producing a densified SiC article is provided. Near-net shape porous silicon carbide articles are produced and densified using the developed method. A substantial number of pores within the porous near-net shape silicon carbide article are filled (impregnated) with a carbon precursor, a silicon carbide precursor, or a mixture of both. The carbon precursor can be liquid or gas. The filled SiC preform is heated to convert the carbon or silicon carbide precursor to porous carbon or SiC preform inside the pores of the net-shape silicon carbide article. The impregnation/pyrolysis cycle is repeated until the desired amount of carbon and/or silicon carbide is achieved. In case of a carbon or a mixture of silicon carbide/carbon precursor is used, the pyrolyzed near-net shape silicon carbide article is then contacted with silicon in an inert atmosphere. The silicon diffuses through the pyrolyzed near-net shape silicon carbide article and reacts with the carbon contained within the pores of the porous SiC preform producing a new phase of silicon carbide within the pores of the near-net shape silicon carbide article. The produced silicon carbide is a near-net dense silicon carbide article. | ||||||
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