公开(公告)号：US20150179355A1

公开(公告)日：2015-06-25

申请号：US14335035

申请日：2014-07-18

申请人： Korea Institute of Energy Research

发明人： Sun-Hwa Yeon ,  Kyoung-Hee Shin ,  Jae-Deok Jeon ,  Se-Kook Park ,  Dae Wi Kim ,  Jung Joon Yoo ,  Hana Yoon ,  Sun-Dong Kim ,  Hyunuk Kim

IPC分类号： H01G11/28 ,  H02J7/00 ,  H01G11/68 ,  H01G11/52 ,  H01G11/32

CPC分类号： H01G11/28 ,  H01G11/12 ,  H01G11/52 ,  H01G11/62 ,  H01G11/68 ,  H01M10/049 ,  H02J7/0022 ,  H02J7/0052 ,  Y02E10/766 ,  Y02E60/13

摘要： Disclosed herein is stack-type flow energy storage system. More particularly, the system includes a stack-type electrode cell composed of fluidic electrode material mixed with an electrolyte and storage tank for the electrode material, thereby remarkably improving stability, output and energy density. The stack-type flow energy storage system is advantageous in that unit cells, each consisting of a cathode, a separation membrane and an anode, are connected in parallel or in series to each other to make a stack cell, thus remarkably increasing output power. Further, the stack-type flow energy storage system is advantageous in that the sizes of slurry storage tanks connected to an electrode cell are adjusted, thus determining the required specification of energy density.

摘要翻译： 这里公开了堆叠式流动能量存储系统。 更具体地说，该系统包括由与电解质混合的流体电极材料和用于电极材料的储罐组成的堆叠型电极池，从而显着提高稳定性，输出和能量密度。 堆叠型流动能量存储系统的优点在于，由阴极，分离膜和阳极组成的单电池彼此并联或串联连接以形成堆叠电池，从而显着增加输出功率。 此外，堆叠式流动能量存储系统的优点在于，调节与电极单元连接的浆料储罐的尺寸，从而确定所需的能量密度规格。

公开(公告)号：US20150132654A1

公开(公告)日：2015-05-14

申请号：US14539269

申请日：2014-11-12

申请人： Korea Institute of Energy Research

发明人： Sun-Hwa Yeon ,  Kyoung-Hee Shin ,  Chang-Soo Jin ,  Kyu-Nam Jung ,  Jae-Deok Jeon ,  Joonmok Shim ,  Jung-Hoon Yang ,  Bum-Suk Lee ,  Myung Seok Jeon ,  Wook Ahn

IPC分类号： H01M4/587 ,  H01M4/62 ,  H01M10/0525 ,  C01B31/04

CPC分类号： H01M4/587 ,  C01B32/184 ,  C01P2006/40 ,  H01M4/623

摘要： Disclosed herein is a method of preparing porous graphene from porous graphite, including 1) thermochemically reacting a highly crystalline carbide compound with a halogen element-containing gas to give a porous carbide-derived carbon; 2) treating the carbide-derived carbon with an acid, thus preparing a carbide-derived carbon oxide; and 3) reducing the carbide-derived carbon oxide. An anode mixture for a secondary battery including the graphene and an anode for a secondary battery including the anode mixture are also provided.

摘要翻译： 本文公开了一种从多孔石墨制备多孔石墨烯的方法，包括1）使高结晶碳化物与含卤素元素的气体热化学反应，得到多孔碳源衍生的碳; 2）用酸处理碳化物衍生的碳，从而制备碳化物衍生的碳氧化物; 和3）还原碳化物衍生的碳氧化物。 还提供了包括石墨烯的二次电池的阳极混合物和包括阳极混合物的二次电池的阳极。

公开(公告)号：US09738523B2

公开(公告)日：2017-08-22

申请号：US14539286

申请日：2014-11-12

申请人： Korea Institute of Energy Research

发明人： Sun-Hwa Yeon ,  Kyoung-Hee Shin ,  Chang-Soo Jin ,  Kyu-Nam Jung ,  Sukeun Yoon ,  Jae-Deok Jeon ,  Joonmok Shim ,  Jung-Hoon Yang ,  Bum-Suk Lee ,  Myung Seok Jeon ,  Wook Ahn

IPC分类号： C01B31/02 ,  H01M4/587 ,  H01G11/32 ,  C01B31/00 ,  C01B21/082 ,  H01G11/86

CPC分类号： C01B32/05 ,  C01B21/0828 ,  C01B32/00 ,  C01P2002/74 ,  C01P2006/12 ,  C01P2006/40 ,  H01G11/32 ,  H01G11/86 ,  H01M4/587 ,  Y02E60/13

摘要： Disclosed is a method of preparing a carbide-derived carbon having high ion mobility for use in a lithium battery anode material, a lithium air battery electrode, a supercapacitor electrode, and a flow capacitor electrode, including thermally treating a carbide compound in a vacuum, thus obtaining a vacuum-treated carbide compound; and thermochemically reacting the vacuum-treated carbide compound with a halogen element-containing gas, thus extracting the element other than carbon from the vacuum-treated carbide compound, wherein annealing can be further performed after thermochemical reaction. This carbide-derived carbon has a small pore distribution, dense graphite fringe, and a large lattice spacing and thus high ion mobility, compared to conventional carbide-derived carbon obtained only by thermochemical reaction with a halogen element-containing gas.

公开(公告)号：US09634329B2

公开(公告)日：2017-04-25

申请号：US14539269

申请日：2014-11-12

申请人： Korea Institute of Energy Research

发明人： Sun-Hwa Yeon ,  Kyoung-Hee Shin ,  Chang-Soo Jin ,  Kyu-Nam Jung ,  Jae-Deok Jeon ,  Joonmok Shim ,  Jung-Hoon Yang ,  Bum-Suk Lee ,  Myung Seok Jeon ,  Wook Ahn

IPC分类号： C01B31/04 ,  H01M4/587 ,  H01M4/62 ,  H01M10/0525

CPC分类号： H01M4/587 ,  C01B32/184 ,  C01P2006/40 ,  H01M4/623

摘要： Disclosed herein is a method of preparing porous graphene from porous graphite, including 1) thermochemically reacting a highly crystalline carbide compound with a halogen element-containing gas to give a porous carbide-derived carbon; 2) treating the carbide-derived carbon with an acid, thus preparing a carbide-derived carbon oxide; and 3) reducing the carbide-derived carbon oxide. An anode mixture for a secondary battery including the graphene and an anode for a secondary battery including the anode mixture are also provided.

公开(公告)号：US20160130146A1

公开(公告)日：2016-05-12

申请号：US14539286

申请日：2014-11-12

申请人： Korea Institute of Energy Research

发明人： Sun-Hwa Yeon ,  Kyoung-Hee Shin ,  Chang-Soo Jin ,  Kyu-Nam Jung ,  Sukeun Yoon ,  Jae-Deok Jeon ,  Joonmok Shim ,  Jung-Hoon Yang ,  Bum-Suk Lee ,  Myung Seok Jeon ,  Wook Ahn

IPC分类号： C01B31/02 ,  C01B31/00 ,  H01G11/32 ,  H01G9/042 ,  H01M4/587 ,  H01M4/04

CPC分类号： C01B32/05 ,  C01B21/0828 ,  C01B32/00 ,  C01P2002/74 ,  C01P2006/12 ,  C01P2006/40 ,  H01G11/32 ,  H01G11/86 ,  H01M4/587 ,  Y02E60/13

摘要： Disclosed is a method of preparing a carbide-derived carbon having high ion mobility for use in a lithium battery anode material, a lithium air battery electrode, a supercapacitor electrode, and a flow capacitor electrode, including thermally treating a carbide compound in a vacuum, thus obtaining a vacuum-treated carbide compound; and thermochemically reacting the vacuum-treated carbide compound with a halogen element-containing gas, thus extracting the element other than carbon from the vacuum-treated carbide compound, wherein annealing can be further performed after thermochemical reaction. This carbide-derived carbon has a small pore distribution, dense graphite fringe, and a large lattice spacing and thus high ion mobility, compared to conventional carbide-derived carbon obtained only by thermochemical reaction with a halogen element-containing gas.

摘要翻译： 公开了一种制备用于锂电池负极材料，锂空气电池电极，超级电容器电极和流动电容器电极的具有高离子迁移率的碳化物衍生碳的方法，包括在真空中热处理碳化物， 从而获得真空处理的碳化物; 并将真空处理的碳化物与含卤素元素的气体热化学反应，从而从真空处理的碳化物中提取碳以外的元素，其中可以在热化学反应之后进一步进行退火。 与通过与含卤素气体的热化学反应获得的常规碳化物衍生碳相比，该碳化物衍生的碳具有小的孔分布，致密的石墨条纹和大的晶格间距，因此具有高的离子迁移率。

公开(公告)号：US09761379B2

公开(公告)日：2017-09-12

申请号：US14335035

申请日：2014-07-18

申请人： Korea Institute of Energy Research

发明人： Sun-Hwa Yeon ,  Kyoung-Hee Shin ,  Jae-Deok Jeon ,  Se-Kook Park ,  Dae Wi Kim ,  Jung Joon Yoo ,  Hana Yoon ,  Sun-Dong Kim ,  Hyunuk Kim

IPC分类号： H01G11/28 ,  H02J7/00 ,  H01G11/68 ,  H01G11/12 ,  H01G11/62 ,  H01G11/52 ,  H01M10/04

CPC分类号： H01G11/28 ,  H01G11/12 ,  H01G11/52 ,  H01G11/62 ,  H01G11/68 ,  H01M10/049 ,  H02J7/0022 ,  H02J7/0052 ,  Y02E10/766 ,  Y02E60/13

摘要： Disclosed herein is stack-type flow energy storage system. More particularly, the system includes a stack-type electrode cell composed of fluidic electrode material mixed with an electrolyte and storage tank for the electrode material, thereby remarkably improving stability, output and energy density. The stack-type flow energy storage system is advantageous in that unit cells, each consisting of a cathode, a separation membrane and an anode, are connected in parallel or in series to each other to make a stack cell, thus remarkably increasing output power. Further, the stack-type flow energy storage system is advantageous in that the sizes of slurry storage tanks connected to an electrode cell are adjusted, thus determining the required specification of energy density.

公开(公告)号：US20150221959A1

公开(公告)日：2015-08-06

申请号：US14426511

申请日：2013-01-30

申请人： KOREA INSTITUTE OF ENERGY RESEARCH

发明人： Chang-Soo Jin ,  Jae-Deok Jeon ,  Bum-Suk Lee ,  Joonmok Shim ,  Kyoung-Hee Shin ,  Sea-Couk Park ,  Myung Seok Jeon ,  Kyu-Nam Jung ,  Sun-Hwa Yeon ,  Sukeun Yoon

IPC分类号： H01M8/02 ,  H01M8/20 ,  H01M8/18

摘要： A laminated structure of a redox flow cell, an integrated complex electrode cell, and a redox flow cell comprising same, wherein the integrated complex cell can reduce stack lamination process time and lamination cost and increase lamination efficiency by integrating a manifold and a bipolar plate in order to facilitate lamination. The integrated complex electrode cell having an inner seal structure, which inhibits the overflow of electrolytes, is characterized in that it inhibits the overflow of electrolytes of positive and negative poles by forming a structure in which an integrated part of the manifold and the bipolar plate can be sealed.

摘要翻译： 氧化还原流通池，集成复合电极池和包含其的氧化还原流通池的层压结构，其中集成复合电池可以通过将歧管和双极板集成在一起而减少堆叠层叠处理时间和层压成本并提高层压效率 以便于层压。 具有抑制电解质溢出的内部密封结构的集成复合电极单元的特征在于，通过形成其中集成部分和双极板的一体化部分可以抑制正极和负极的电解质的溢出 密封。

公开(公告)号：US20150180074A1

公开(公告)日：2015-06-25

申请号：US14417895

申请日：2013-01-25

申请人： KOREA INSTITUTE OF ENERGY RESEARCH

发明人： Chang-Soo Jin ,  Jae-Deok Jeon ,  Bum-Suk Lee ,  Joonmok Shim ,  Kyoung-Hee Shin ,  Sea-Couk Park ,  Myung Seok Jeon ,  Kyu-Nam Jung ,  Sun-Hwa Yeon ,  Sukeun Yoon

IPC分类号： H01M8/18 ,  H01M8/20

CPC分类号： H01M8/188 ,  H01M8/0258 ,  H01M8/026 ,  H01M8/20 ,  H01M8/241 ,  H01M8/2483 ,  H01M8/2484 ,  Y02E60/528

摘要： A manifold for a redox flow battery capable of effectively suppressing a shunt current has a supply flow pathway and an exhaust flow pathway respectively formed at a left side and a right side of an anode or cathode electrode electrolyte reaction unit so as to include a U-shaped curved portion, and the U-shaped curved portion is formed to be positioned on the upper part of the top or the lower part of the bottom of the first electrode electrolyte reaction unit. When the manifold is applied to a redox flow battery, the supply flow pathway and the exhaust flow pathway having the U-shaped curved portion are formed on the upper part of the top or the lower part of the bottom of the electrode electrolyte reaction unit to prevent an electrolyte existing in the inside of a stack and a pipe from passing through the U-shaped curved portion.

摘要翻译： 能够有效地抑制分流电流的氧化还原液流电池的歧管具有分别形成在阳极或阴极电解质反应单元的左侧和右侧的供给流路和排气流路， U形弯曲部形成为位于第一电极电解质反应部的底部的上部或下部的上部。 当歧管施加到氧化还原液流电池时，具有U形弯曲部分的供应流动路径和排气流动路径形成在电极电解质反应单元的底部的顶部或下部的上部，以 防止存在于堆叠和管道内部的电解质通过U形弯曲部分。

公开(公告)号：US10593982B2

公开(公告)日：2020-03-17

申请号：US15099742

申请日：2016-04-15

申请人： KOREA INSTITUTE OF ENERGY RESEARCH

发明人： Sun-Hwa Yeon ,  Kyoung-Hee Shin ,  Jae-Deok Jeon ,  Jung Joon Yoo ,  Hana Yoon ,  Chang-Soo Jin ,  Joon-Mok Shim ,  Jung-Hoon Yang ,  Kyu-Nam Jung ,  Dong-Ha Kim ,  Se-Kook Park

IPC分类号： H01M8/18 ,  H01M8/04082 ,  H01G11/54 ,  H01G11/74 ,  H01G11/02 ,  H01G11/08 ,  H01G11/14 ,  H01G11/22

摘要： Disclosed is a flow-type energy storage device having an improved flow of fluid. The flow-type energy storage device stores electricity using a fluidic material, and includes a reaction region in which charge-discharge reaction of electricity is performed by the fluidic material, wherein the reaction region has an octagonal cross-section. The shape of the reaction region is controlled to thus improve the flowability of the fluidic material, thereby providing a flow-type energy storage device that has almost constant electrical properties even when a charging and discharging cycle is repeatedly performed. Further, the structures of an inlet and an outlet are not complicated and a separate part for controlling the flow of fluid is not used in the device, and accordingly, additional costs are not incurred during a process of manufacturing the flow-type energy storage device.

公开(公告)号：US09653746B2

公开(公告)日：2017-05-16

申请号：US14417895

申请日：2013-01-25

申请人： KOREA INSTITUTE OF ENERGY RESEARCH

发明人： Chang-Soo Jin ,  Jae-Deok Jeon ,  Bum-Suk Lee ,  Joonmok Shim ,  Kyoung-Hee Shin ,  Sea-Couk Park ,  Myung Seok Jeon ,  Kyu-Nam Jung ,  Sun-Hwa Yeon ,  Sukeun Yoon

IPC分类号： H01M8/18 ,  H01M8/0258 ,  H01M8/026 ,  H01M8/20

CPC分类号： H01M8/188 ,  H01M8/0258 ,  H01M8/026 ,  H01M8/20 ,  H01M8/241 ,  H01M8/2483 ,  H01M8/2484 ,  Y02E60/528

摘要： A manifold for a redox flow battery capable of effectively suppressing a shunt current has a supply flow pathway and an exhaust flow pathway respectively formed at a left side and a right side of an anode or cathode electrode electrolyte reaction unit so as to include a U-shaped curved portion, and the U-shaped curved portion is formed to be positioned on the upper part of the top or the lower part of the bottom of the first electrode electrolyte reaction unit. When the manifold is applied to a redox flow battery, the supply flow pathway and the exhaust flow pathway having the U-shaped curved portion are formed on the upper part of the top or the lower part of the bottom of the electrode electrolyte reaction unit to prevent an electrolyte existing in the inside of a stack and a pipe from passing through the U-shaped curved portion.