公开(公告)号：US08192714B2

公开(公告)日：2012-06-05

申请号：US12534262

申请日：2009-08-03

申请人： Kazuchika Ohta ,  Ick-Soo Kim ,  Byoung-Suhk Kim ,  Jongchul Park

发明人： Kazuchika Ohta ,  Ick-Soo Kim ,  Byoung-Suhk Kim ,  Jongchul Park

IPC分类号： D01F9/12 ,  B01J19/08

CPC分类号： B82Y40/00 ,  B82Y30/00 ,  C01B32/162 ,  Y10S977/842 ,  Y10S977/844

摘要： A method for manufacturing carbon nanotubes of the present invention includes the steps of: preparing at least one metal selected from a group consisting of iron, cobalt and nickel and an organic compound: and forming carbon nanotubes by using the organic compound as a carbon source, wherein the metal and the organic compound are put into a heating vessel having a substance capable of converting electromagnetic energy into heat, and the organic compound is brought into contact with the metal in a state where the inside of the heating vessel is heated at a temperature of 600° C. to 900° C. by applying the electromagnetic energy to the heating vessel so as to form the carbon nanotubes.

摘要翻译： 本发明的制造碳纳米管的方法包括以下步骤：制备选自铁，钴和镍中的至少一种金属和有机化合物，并通过使用有机化合物作为碳源形成碳纳米管， 其中将金属和有机化合物放入具有能够将电磁能转换成热的物质的加热容器中，并且在加热容器的内部被加热的状态下使有机化合物与金属接触 通过将电磁能施加到加热容器以形成碳纳米管，其温度为600℃至900℃。

公开(公告)号：US08333947B2

公开(公告)日：2012-12-18

申请号：US12534252

申请日：2009-08-03

申请人： Kazuchika Ohta ,  Ick-Soo Kim ,  Byoung-Suhk Kim ,  Jongchul Park

发明人： Kazuchika Ohta ,  Ick-Soo Kim ,  Byoung-Suhk Kim ,  Jongchul Park

IPC分类号： D01F9/12 ,  B01J19/08

CPC分类号： B82Y40/00 ,  B82Y30/00 ,  C01B32/15

摘要： A method for manufacturing carbon nanotubes includes the steps of: preparing metal-containing-nanofibers which include nanofibers made of organic polymer and metal which possesses a catalytic function in forming carbon nanotubes; and forming carbon nanotubes which contain metal therein by using the nanofibers as a carbon source, wherein the carbon nanotubes are formed by putting the metal-containing-nanofibers into a heating vessel which has a substance capable of converting electromagnetic energy into heat, and by heating the metal-containing-nanofibers using heat which is generated by the heating vessel when electromagnetic energy is applied to the heating vessel.

摘要翻译： 制造碳纳米管的方法包括以下步骤：制备含有纳米纤维的纳米纤维，所述纳米纤维包括由有机聚合物制成的纳米纤维和在形成碳纳米管时具有催化功能的金属; 并且通过使用纳米纤维作为碳源形成含有金属的碳纳米管，其中，通过将含金属的纳米纤维放入具有能够将电磁能转化为热的物质的加热容器中，并且通过加热形成碳纳米管 含有电子的纳米纤维，当电磁能被施加到加热容器时，使用由加热容器产生的热量。

公开(公告)号：US08202504B2

公开(公告)日：2012-06-19

申请号：US12534268

申请日：2009-08-03

申请人： Kazuchika Ohta ,  Ick-Soo Kim ,  Byoung-Suhk Kim ,  Jongchul Park

发明人： Kazuchika Ohta ,  Ick-Soo Kim ,  Byoung-Suhk Kim ,  Jongchul Park

IPC分类号： D01F9/12 ,  B01J19/08

CPC分类号： B82Y40/00 ,  B01J31/04 ,  B01J2531/847 ,  B82Y30/00 ,  C01B32/162 ,  Y10S977/842 ,  Y10S977/844

摘要： A method for manufacturing carbon nanotubes of the present invention includes the steps of: preparing a metal complex which contains at least one metal selected from a group consisting of iron, cobalt and nickel and an organic compound: and forming carbon nanotubes which contain metal therein by using the organic compound as a carbon source, wherein the carbon nanotubes are formed by putting the metal complex into a heating vessel which has a substance capable of converting electromagnetic energy into heat, and by heating the metal complex using heat which is generated by the heating vessel when electromagnetic energy is applied to the heating vessel. As the metal complex used in a method for manufacturing carbon nanotubes of the present invention, nickel stearate or nickel benzoate can be named, for example. According to the method for manufacturing carbon nanotubes of the present invention, it is possible to manufacture carbon nanotubes using an inexpensive heating device within a short time.

摘要翻译： 本发明的制造碳纳米管的方法包括以下步骤：制备含有选自铁，钴和镍中的至少一种金属和有机化合物的金属络合物，并通过以下方法形成含有金属的碳纳米管： 使用有机化合物作为碳源，其中通过将金属络合物放入具有能够将电磁能转化成热的物质的加热容器中，并且通过加热产生的加热金属络合物来形成碳纳米管 当电磁能被施加到加热容器时的容器。 作为本发明的碳纳米管制造方法中使用的金属络合物，例如可以列举硬脂酸镍或苯甲酸镍。 根据本发明的碳纳米管的制造方法，可以在短时间内使用便宜的加热装置制造碳纳米管。

公开(公告)号：US09177729B2

公开(公告)日：2015-11-03

申请号：US13977711

申请日：2012-02-06

申请人： Ick-soo Kim ,  Byoung-Suhk Kim ,  Kei Watanabe ,  Naotaka Kimura ,  Kyu-oh Kim ,  Jae-hwan Lee

发明人： Ick-soo Kim ,  Byoung-Suhk Kim ,  Kei Watanabe ,  Naotaka Kimura ,  Kyu-oh Kim ,  Jae-hwan Lee

IPC分类号： H01G9/02 ,  H01M2/14 ,  H01M2/16

CPC分类号： H01G9/02 ,  H01M2/145 ,  H01M2/162 ,  H01M2/1686

摘要： The present invention provides a separator and a method for manufacturing the separator. The separator includes a first nanofiber layer (20) which has a lattice shape when viewed from a plan view, a second nanofiber layer (30) which is provided on a first surface of the first nanofiber layer (20) and is thinner than the first nanofiber layer, and a third nanofiber layer (40) which is provided on a second surface of the first nanofiber layer and is thinner than the first nanofiber layer. The thickness of the first nanofiber layer ranges from 7 μm to 30 μm. The thickness of each of the second and third nanofiber layers ranges from 1 μm to 5 μm. The present invention can provide a separator which has high insulation, high dendrite resistance, high ion conductivity and high mechanical strength.

摘要翻译： 本发明提供一种分离器及其制造方法。 所述隔板包括从平面观察时具有格子状的第一纳米纤维层（20），设置在所述第一纳米纤维层（20）的第一面上且比所述第一纳米纤维层薄 纳米纤维层和设置在第一纳米纤维层的第二表面上并且比第一纳米纤维层薄的第三纳米纤维层（40）。 第一纳米纤维层的厚度为7μm〜30μm。 第二和第三纳米纤维层的厚度范围为1μm至5μm。 本发明可以提供绝缘性高，耐枝晶性高，离子电导率高，机械强度高的隔膜。

公开(公告)号：US20140004405A1

公开(公告)日：2014-01-02

申请号：US13977711

申请日：2012-02-06

申请人： Ick-soo Kim ,  Byoung-Suhk Kim ,  Kei Watanabe ,  Naotaka Kimura ,  Kyu-oh Kim ,  Jae-hwan Lee

发明人： Ick-soo Kim ,  Byoung-Suhk Kim ,  Kei Watanabe ,  Naotaka Kimura ,  Kyu-oh Kim ,  Jae-hwan Lee

IPC分类号： H01G9/02 ,  H01M2/14 ,  H01M2/16

CPC分类号： H01G9/02 ,  H01M2/145 ,  H01M2/162 ,  H01M2/1686

摘要： The present invention provides a separator and a method for manufacturing the separator. The separator includes a first nanofiber layer (20) which has a lattice shape when viewed from a plan view, a second nanofiber layer (30) which is provided on a first surface of the first nanofiber layer (20) and is thinner than the first nanofiber layer, and a third nanofiber layer (40) which is provided on a second surface of the first nanofiber layer and is thinner than the first nanofiber layer. The thickness of the first nanofiber layer ranges from 7 μm to 30 μm. The thickness of each of the second and third nanofiber layers ranges from 1 μm to 5 μm. The present invention can provide a separator which has high insulation, high dendrite resistance, high ion conductivity and high mechanical strength.

摘要翻译： 本发明提供一种分离器及其制造方法。 所述隔板包括从平面观察时具有格子状的第一纳米纤维层（20），设置在所述第一纳米纤维层（20）的第一面上且比所述第一纳米纤维层薄 纳米纤维层和设置在第一纳米纤维层的第二表面上并且比第一纳米纤维层薄的第三纳米纤维层（40）。 第一纳米纤维层的厚度为7μm〜30μm。 第二和第三纳米纤维层中的每一个的厚度范围为1μm至5μm。 本发明可以提供绝缘性高，耐枝晶性高，离子电导率高，机械强度高的隔膜。

公开(公告)号：US07067606B2

公开(公告)日：2006-06-27

申请号：US10620644

申请日：2003-07-16

申请人： Patrick T. Mather ,  Byoung-Suhk Kim ,  Qing Ge ,  Changdeng Liu

发明人： Patrick T. Mather ,  Byoung-Suhk Kim ,  Qing Ge ,  Changdeng Liu

IPC分类号： C08G77/04

CPC分类号： C08G18/3893 ,  C08G18/4833 ,  C08G18/718 ,  C08G65/336 ,  C08L71/02 ,  C08L2205/05 ,  C08L83/00

摘要： Amphiphilic telechelics incorporating polyhedraloligosilsesquioxane (POSS) synthesized by direct urethane linkage between the diol end groups of polyethylene glycol (PEG) homopolymers and the monoisocyanate group of POSS macromers. The hydrophobicity of the amphiphilic telechelics can be varied by using PEG homopolymers of increasing MW, providing for control over molecular architecture by hydrophilic/hydrophobic balance. Methods for synthesizing the amphiphilic telechelics and their use as surfactants, thickening agents, additives to plastic such as PMMA′(Plexiglass), epoxyadhesives for improving their properties are also disclosed.

摘要翻译： 通过在聚乙二醇（PEG）均聚物的二醇端基与POSS大单体的单异氰酸酯基团之间通过直接氨基甲酸酯键合成的多面体聚二甲基倍半硅氧烷（POSS）的两亲电视电影。 通过使用增加MW的PEG均聚物可以改变两亲性电视电泳的疏水性，通过亲水/疏水平衡提供对分子结构的控制。 还公开了合成两亲电视电影的方法及其作为表面活性剂，增稠剂，塑料添加剂如PMMA（有机玻璃）的用途，用于改善其性能的环氧树脂粘合剂。