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    • 2. 发明专利
    • All solid-state secondary battery
    • 所有固态二次电池
    • JP2010245024A
    • 2010-10-28
    • JP2009276698
    • 2009-12-04
    • Toyota Motor Corpトヨタ自動車株式会社
    • YOSHIDA SATOSHIDOI KOKICHIUENO YUKIYOSHINISHINO NORIAKITSUCHIDA YASUSHI
    • H01M10/0562H01M4/13H01M4/62H01M10/0565
    • H01M10/0525H01M4/02H01M4/043H01M4/139H01M2004/021Y02E60/122
    • PROBLEM TO BE SOLVED: To provide an all solid-state secondary battery capable of suppressing overvoltage and the expansion/contraction of an electrode active material layer, and preventing the discontinuation of a conductive path and a metallic ion conductive path. SOLUTION: In the all solid-state secondary battery, in an electrode active material layer of at least one of a positive electrode and a negative electrode, a total content ratio represented by a ratio (W e /W a ) which is represented by a ratio of a mass (W e ) of an electrolyte contained in the electrode active material layer to the mass (W a ) of an active material contained in the electrode active material layer is larger than 1 (1 e /W a ); and a local content ratio represented by a ratio [W e (partial)/W a (partial)] of mass [W e (partial)] of an active material contained in the same electrode active material, to a mass [W a (partial)] of an active material contained in a portion of the electrode active material is increased, from a solid-state electrolyte interface toward a current collector interface in the thickness direction of the electrode active material layer. COPYRIGHT: (C)2011,JPO&INPIT
    • 要解决的问题:提供能够抑制电极活性物质层的过电压和膨胀/收缩的全固体二次电池,并且防止导电路径和金属离子传导路径的中断。 解决方案:在所有固态二次电池中,在正极和负极中的至少一个的电极活性材料层中,以比例(W e e )与质量之比(W a )表示, 包含在电极活性物质层中的活性物质的比例大于1(1 / W a )。 和由[W e (部分))的比例[部分] / W(SB)a (部分)]表示的局部含量比 )包含在相同电极活性材料中的活性材料与包含在电极活性材料的一部分中的活性材料的质量[W SB SB a(SB))(部分))从固体 在电极活性物质层的厚度方向上朝向集电器界面的状态电解质界面。 版权所有(C)2011,JPO&INPIT
    • 3. 发明专利
    • Organic-inorganic hybrid electrolyte and method of manufacturing the same
    • 有机无机混合电解质及其制造方法
    • JP2009043682A
    • 2009-02-26
    • JP2007210372
    • 2007-08-10
    • Tokyo Institute Of TechnologyToyota Motor CorpUniv Of Tokyoトヨタ自動車株式会社国立大学法人 東京大学国立大学法人東京工業大学
    • YOSHIDA SATOSHIKAWAI HIROYUKIYAMAGUCHI TAKEHISAITO DAICHILEE JU MYEUNGFUJII KEITARO
    • H01B13/00H01B1/06H01M8/02H01M8/10
    • Y02P70/56
    • PROBLEM TO BE SOLVED: To provide a method of manufacturing an organic-inorganic hybrid electrolyte which has a wide range of selections in materials and mixing conditions. SOLUTION: The method has a process in which a reformed inorganic material is made by introducing into an inorganic material a modification group having a mutual electrostatic operation with an ion conductive group held by an organic polymer material and then the same is mixed/dispersed in an organic polymer material. By introducing the modification group, affinity between the organic polymer material and the reformed organic material can be raised very high, and even under the condition that mixture/dispersion cannot be conducted conventionally, an organic-inorganic hybrid electrolyte can be manufactured. Specifically, the method has a mixing process in which the organic polymer material having the ion conductive group, a polarorganic solvent having affinity with the organic polymer material, a surface reforming agent introducing an organic material having affinity with the polarorganic solvent, and a reformed inorganic material which can be obtained by making a surface modification agent, which introduces a modification group having cation which generates an attraction force against the ion conductive group, contact with an inorganic material precursor are mixed. COPYRIGHT: (C)2009,JPO&INPIT
    • 要解决的问题:提供在材料和混合条件下具有广泛选择范围的有机 - 无机混合电解质的制造方法。 解决方案:该方法具有这样的方法,其中通过将与有机聚合物材料保持的离子导电基团相互静电操作的改性基团引入到无机材料中,然后将其混合/ 分散在有机聚合物材料中。 通过引入改性基团,有机聚合物材料与改性有机材料之间的亲和性可以提高很高,并且即使在常规地不能进行混合/分散的条件下,也可以制造有机 - 无机混合电解质。 具体地说,该方法具有混合方法,其中具有离子导电基团的有机聚合物材料,与有机聚合物材料具有亲和性的极性有机溶剂,引入与极性有机溶剂具有亲和性的有机材料的表面改性剂,以及重整无机物 将通过制造表面改性剂获得的材料与引入与离子导电基团产生吸引力的阳离子的改性基团混合,与无机材料前体接触。 版权所有(C)2009,JPO&INPIT
    • 4. 发明专利
    • Manufacturing method for composite positive electrode active material
    • 复合阳极电极活性材料的制备方法
    • JP2011146284A
    • 2011-07-28
    • JP2010006903
    • 2010-01-15
    • Toyota Motor Corpトヨタ自動車株式会社
    • YOSHIDA SATOSHIKUBO HIRONORIIWASAKI MASAHIRO
    • H01M4/58H01M4/36
    • H01M4/625B82Y30/00B82Y40/00C01B25/45C01B32/174H01M4/36H01M4/5825H01M10/052
    • PROBLEM TO BE SOLVED: To provide a manufacturing method for a composite positive electrode active material capable of restraining condensation of carbon nanotubes and attaining the composite positive electrode active material which is excellent on output characteristics by compounding by improving dispersibility of the positive electrode active material and carbon nanotubes. SOLUTION: In the manufacturing method for a composite positive electrode active material wherein the positive electrode active material and carbon nanotubes are compounded, the manufacturing method for a composite positive electrode active material includes a preparation process of preparing a material solution of a positive electrode active material containing a raw material of the positive electrode active material, carbon nanotubes, and a carbon nanotube soluble solution containing a soluble material made from water-soluble polymer wherein a solubility maintenance rate of the carbon nanotube is not reduced along with temperature rise, and a hydrothermal synthesis method of synthesizing a positive electrode active material-carbon nanotube compound by hydrothermally synthesizing by mixing the material solution of a positive electrode active material and the carbon nanotube soluble solution. COPYRIGHT: (C)2011,JPO&INPIT
    • 解决问题的方案为了提供一种复合正极活性物质的制造方法,所述复合正极活性物质能够抑制碳纳米管的缩合,从而通过提高正极的分散性,得到复合正极活性物质,其具有优异的输出特性 活性材料和碳纳米管。 解决方案:在正极活性物质和碳纳米管复合的复合正极活性物质的制造方法中,复合正极活性物质的制造方法包括制备正极活性物质和碳纳米管的材料溶液的制备方法 含有正极活性物质的原料的电极活性物质,碳纳米管和含有由水溶性聚合物制成的可溶性材料的碳纳米管可溶解液,其中碳纳米管的溶解维持率随温度升高而不降低, 以及通过将正极活性物质的材料溶液与碳纳米管可溶解混合而进行水热合成来合成正极活性物质 - 碳纳米管化合物的水热合成方法。 版权所有(C)2011,JPO&INPIT
    • 6. 发明专利
    • Cooling device
    • 冷却装置
    • JP2005259636A
    • 2005-09-22
    • JP2004072532
    • 2004-03-15
    • Toyota Motor Corpトヨタ自動車株式会社
    • YOSHIDA SATOSHI
    • F01P11/00B01D53/22F25D9/00F25D17/02H01M8/04
    • Y02E60/50
    • PROBLEM TO BE SOLVED: To provide a cooling device in which deterioration of a cooling medium by oxygen can be prevented by a simple constitution. SOLUTION: This is the cooling device (10) to cool an exothermic part (20) by the cooling medium, and provided with cooling circuits (11 to 18) to supply the cooling medium to the exothermic part (20) and a reservoir tank (100) to store the cooling medium to supplement the cooling circuits. Regulating means (110, 120) to prevent an oxygen component from flowing in while alleviating differences between the inner and outer atmospheric pressures occurring in reducing the inner atmospheric pressure accompanied by supplementation of the cooling medium into the cooling circuits are installed in the reservoir tank (100). Because the regulating means (110, 120) alleviate the increase and decrease of this pressure while flowing-in of the oxygen component is prevented even if the inner pressure becomes low, it is possible to evade that the cooling medium is deteriorated by the oxygen component. COPYRIGHT: (C)2005,JPO&NCIPI
    • 要解决的问题:提供一种可以通过简单的结构防止冷却介质被氧气劣化的冷却装置。 解决方案:这是通过冷却介质冷却放热部件(20)的冷却装置(10),并且设置有冷却回路(11至18)以将冷却介质供应到放热部件(20)和 储存罐(100)以存储冷却介质以补充冷却回路。 调节装置(110,120),用于防止氧成分流入,同时减轻伴随着将冷却介质添加到冷却回路中的内部大气压降低而产生的内外大气压之间的差异。 100)。 由于调节装置(110,120)即使在内部压力变低的情况下也能够防止氧成分的流入而减轻该压力的增加和减少,因此可以避免冷却介质被氧成分 。 版权所有(C)2005,JPO&NCIPI
    • 9. 发明专利
    • Arc vapor-deposition apparatus
    • ARC蒸气沉积装置
    • JP2009275264A
    • 2009-11-26
    • JP2008128264
    • 2008-05-15
    • Toyota Motor Corpトヨタ自動車株式会社
    • YOSHIDA SATOSHIISHIMARU YOICHI
    • C23C14/24B01J23/42B01J37/02H01M4/88H01M8/10
    • Y02E60/521
    • PROBLEM TO BE SOLVED: To provide an arc vapor-deposition apparatus that can effectively inhibit a short circuit across between a cathode and a trigger electrode and can extend a period in which the apparatus can be used in a maintenance-free state to a longer period of time (or increase the number of times of use). SOLUTION: The arc vapor-deposition apparatus 100 has an arc vapor-deposition source 10 including a pressure-reduced vessel 8 that accommodates a cylindrical anode 6 which accommodates one unit body formed of the cathode 1, an insulator 4 surrounding the cathode 1, a C ring 3 provided on the outer perimeter of the insulator 4, and the trigger electrode 2 provided on the outer perimeter of the C ring 3; and also has a first feeding means 9A for moving the cathode 1 relatively against the insulator 4 according to a consumed amount of the vapor-deposition material constituting the cathode 1, and a second feeding means 9B for making at least the insulator 4 protrude from the end of the C ring 3. The gap width of a groove 31 of the C ring 3 becomes gradually wider toward a direction of the cathode 1 from a trigger electrode 2 side. COPYRIGHT: (C)2010,JPO&INPIT
    • 解决的问题:提供一种电弧蒸镀装置,其能够有效地抑制阴极和触发电极之间的短路,并且能够将该装置在免维护状态下使用的期间延长至 更长的一段时间(或增加使用次数)。 电弧蒸镀装置100具有电弧蒸镀源10,该电弧蒸镀源10包含减压容器8,压缩容器8容纳容纳由阴极1形成的一个单位体的圆筒状阳极6,围绕阴极的绝缘体4 如图1所示,设置在绝缘体4的外周上的C环3和设置在C环3的外周上的触发电极2; 并且还具有用于根据构成阴极1的蒸镀材料的消耗量使阴极1相对于绝缘体4移动的第一供给单元9A,以及至少使绝缘子4从 C环3的槽31的间隙宽度从触发电极2侧向阴极1的方向逐渐变宽。 版权所有(C)2010,JPO&INPIT
    • 10. 发明专利
    • Electrocatalyst manufacturing method
    • 电动汽车制造方法
    • JP2009259417A
    • 2009-11-05
    • JP2008103841
    • 2008-04-11
    • Toyota Motor Corpトヨタ自動車株式会社
    • YOSHIDA SATOSHIISHIMARU YOICHI
    • H01M4/88B01J23/42B01J37/02C23C14/32
    • H01M4/92C23C4/067C23C4/134H01M4/926
    • PROBLEM TO BE SOLVED: To provide an electrocatalyst manufacturing method for increasing the effective area of a catalyst metal to achieve the high support of the catalyst metal by using a combination of wet process and drive process.
      SOLUTION: The electrocatalyst manufacturing method includes a first step (the wet process) of dispersing and agitating a carrier C such as carbon and a catalyst material or a catalyst material precursor S1' in solvent Y to produce an intermediate T1 of an electrocatalyst having the catalyst material S1 deposited on the surface of the carrier C, and a second step (the drive process) of further depositing a catalyst material S2 on the surface of the intermediate T1 under dry conditions to produce catalyst supporting carrier particles T2.
      COPYRIGHT: (C)2010,JPO&INPIT
    • 要解决的问题:提供一种电催化剂制造方法,用于通过使用湿法和驱动方法的组合来增加催化剂金属的有效面积以实现催化剂金属的高支撑。 电解催化剂的制造方法包括:在溶剂Y中分散并搅拌载体C如碳和催化剂材料或催化剂材料前体S1'以产生电催化剂的中间体T1的第一步骤(湿法) 将催化剂材料S1沉积在载体C的表面上,以及在干燥条件下进一步在中间体T1的表面上沉积催化剂材料S2以产生催化剂载体颗粒T2的第二步骤(驱动方法)。 版权所有(C)2010,JPO&INPIT