公开(公告)号：US11684762B2

公开(公告)日：2023-06-27

申请号：US16651605

申请日：2018-02-02

Applicant: KOREA INSTITUTE OF ENERGY RESEARCH

Inventor： Nam-Jo Jeong ,  Ji Yeon Choi ,  Han-Ki Kim ,  Seung Cheol Yang ,  Kyo Sik Hwang ,  Ji-Hyung Han ,  Joo-Youn Nam ,  Eun-Jin Jwa ,  Soon-Chul Park ,  Yong-Seog Seo ,  Moon-Seok Jang

IPC: A61M37/00 ,  A61L31/14 ,  A61L31/02 ,  H01M8/22 ,  A61B5/0531 ,  A61N1/30

CPC classification number: A61M37/00 ,  A61L31/026 ,  A61L31/146 ,  H01M8/227 ,  A61B5/0531 ,  A61M2037/0007 ,  A61M2230/65 ,  A61N1/30 ,  H01M2250/30

Abstract: Disclosed is an energy self-sufficient real time bio-signal monitoring and nutrient and/or drug delivery system based on salinity gradient power generation. The energy self-sufficient real time bio-signal monitoring and/or nutrient delivery system based on salinity gradient power generation includes: an electricity generation and nutrient and/or drug delivery module including a reverse electrodialysis device which generates electricity by using a nutrient and/or drug solution and discharge a diluted nutrient solution; and a bio-signal measuring unit inserted into the electricity generation and nutrient and/or drug delivery module and configured to receive electricity from the electricity generation and nutrient and/or drug delivery module and measure a bio-signal.

公开(公告)号：US10427982B2

公开(公告)日：2019-10-01

申请号：US15267307

申请日：2016-09-16

Applicant: KOREA INSTITUTE OF ENERGY RESEARCH

Inventor： Namjo Jeong ,  Chan-Soo Kim ,  Ji Yeon Choi ,  Joo-youn Nam ,  Soon-chul Park ,  Moon seok Jang ,  Kangmin Chon ,  Ji-Hyung Han ,  Han-Ki Kim ,  Eun-Jin Jwa

IPC: C04B35/00 ,  C04B35/628 ,  B22F1/00 ,  C01B33/02 ,  C01B32/05

Abstract: A method includes: supplying sources or nanoparticles of any one or two or more combinations selected from a group which consists of a carbon source, a doping source, a doped element containing carbon source, and a waste plastic source into a high-temperature and high-pressure closed autoclave, completely closing the high-temperature and high-pressure closed autoclave, and forming a nanoparticle-carbon core-shell structure by a single process by coating a carbon layer on the surface of the nanoparticles or forming a core-shell structure of nanoparticle-doped carbon by the single process by coating a carbon layer doped with the doped element on the surface of the nanoparticles under pressure self-generated in the autoclave and a reaction temperature in the range of 500 to 850° C. by heating the autoclave.

公开(公告)号：US20170232431A1

公开(公告)日：2017-08-17

申请号：US15435386

申请日：2017-02-17

Applicant: KOREA INSTITUTE OF ENERGY RESEARCH

Inventor： Namjo Jeong ,  Chan-Soo Kim ,  Eun-Jin Jwa ,  Ji Yeon Choi ,  Joo-Youn Nam ,  Soon-Chul Park ,  Moon-Seok Jang ,  Yong Seok Seo ,  Kyo Sik Hwang ,  Han Ki Kim ,  Ji Hyung Han ,  Tae Young Kim ,  Young Gi Yoon

IPC: B01J37/02 ,  B01J21/18 ,  B01J23/42 ,  B01J27/24 ,  B01J27/051 ,  B01J21/06 ,  B01J23/06 ,  B01J35/04 ,  B01J35/00 ,  B01J23/75

CPC classification number: B01J37/0238 ,  B01J21/18 ,  B01J21/185 ,  B01J23/42 ,  B01J23/462 ,  B01J23/468 ,  B01J23/62 ,  B01J23/626 ,  B01J23/6562 ,  B01J23/745 ,  B01J23/75 ,  B01J23/755 ,  B01J23/8892 ,  B01J23/8906 ,  B01J23/8913 ,  B01J23/892 ,  B01J23/8926 ,  B01J23/894 ,  B01J23/8966 ,  B01J23/8993 ,  B01J27/24 ,  B01J35/0006 ,  B01J35/0013 ,  B01J35/002 ,  B01J35/006 ,  B01J35/08 ,  B01J37/08

Abstract: Disclosed is a direct synthesis method of nanostructured catalyst particles on surfaces of various supports. In the disclosed synthesis method of a catalyst structure having a plurality of nanostructured catalyst particles dispersed in a support by a one-step process using a high-temperature high-pressure closed reactor, the one-step process includes supplying the support and a catalyst source into the high-temperature high-pressure closed reactor; supplying an atmosphere forming gas of the reactor into the reactor; perfectly sealing the high-temperature high-pressure closed reactor and heating the reactor to produce the catalyst structure in the reactor under self-generated pressure and synthesis temperature conditions, the catalyst structure including the plurality of nanostructured catalyst particles dispersed in the support; removing internal gases of the reactor to allow the reactor to be in a high-temperature, atmospheric pressure state and supplying an inert gas into the reactor to remove unreacted materials and byproducts remaining in the reactor; and cooling the reactor to room temperature while supplying the inert gas to synthesize the catalyst structure.

公开(公告)号：US20170081248A1

公开(公告)日：2017-03-23

申请号：US15267307

申请日：2016-09-16

Applicant: KOREA INSTITUTE OF ENERGY RESEARCH

Inventor： Namjo Jeong ,  Chan-Soo Kim ,  Ji Yeon Choi ,  Joo-Youn Nam ,  Soon-Chul Park ,  Moon Seok Jang ,  Kangmin Chon ,  Ji-Hyung Han ,  Han-Ki Kim ,  Eun-Jin Jwa

IPC: C04B35/628

CPC classification number: C04B35/62839 ,  B22F1/0018 ,  B22F1/02 ,  B22F9/22 ,  B22F2998/10 ,  B22F2999/00 ,  C01B32/05 ,  C01B33/02 ,  C04B35/62884 ,  C04B35/62886 ,  C04B2235/52 ,  B22F2201/013

Abstract: A method includes: supplying sources or nanoparticles of any one or two or more combinations selected from a group which consists of a carbon source, a doping source, a doped element containing carbon source, and a waste plastic source into a high-temperature and high-pressure closed autoclave, completely closing the high-temperature and high-pressure closed autoclave, and forming a nanoparticle-carbon core-shell structure by a single process by coating a carbon layer on the surface of the nanoparticles or forming a core-shell structure of nanoparticle-doped carbon by the single process by coating a carbon layer doped with the doped element on the surface of the nanoparticles under pressure self-generated in the autoclave and a reaction temperature in the range of 500 to 850° C. by heating the autoclave.

公开(公告)号：US10522849B2

公开(公告)日：2019-12-31

申请号：US15694159

申请日：2017-09-01

Applicant: KOREA INSTITUTE OF ENERGY RESEARCH

Inventor： Dong-Kook Kim ,  Sung-Il Jeon ,  Ko-Yeon Choo ,  Younghyun Cho ,  Jeong-Gu Yeo ,  Jong-Soo Park ,  SeungCheol Yang ,  Ji Yeon Choi ,  Hong Ran Park ,  Ki Sook Lee ,  Young Jik Youn ,  Jung Hyun Lee ,  Hee-Yeon Kim

IPC: H01M8/02 ,  H01M8/0258 ,  H01M8/18 ,  C02F1/46 ,  C02F1/469 ,  C02F1/461

Abstract: The present invention relates to an electrochemical cell having a channel-type flow-electrode unit.The channel-type flow-electrode structure according to the present invention, which has at least two channel-type flow-electrode units, can significantly reduce manufacturing costs and installation space by reducing the number of parts while extending the electrode capacity to be suitable for large-scale plants for electricity generation, energy storage, desalination, etc. In addition, the channel-type flow-electrode structure can be applied not only to a capacitive flow-electrode device and/or a redox flow battery device, but also to all of the devices for electricity generation, energy storage, and desalination while moving ions or protons.

公开(公告)号：US10384201B2

公开(公告)日：2019-08-20

申请号：US15435386

申请日：2017-02-17

Applicant: KOREA INSTITUTE OF ENERGY RESEARCH

Inventor： Namjo Jeong ,  Chan-Soo Kim ,  Eun-Jin Jwa ,  Ji Yeon Choi ,  Joo-Youn Nam ,  Soon-Chul Park ,  Moon-Seok Jang ,  Yong Seok Seo ,  Kyo Sik Hwang ,  Han Ki Kim ,  Ji Hyung Han ,  Tae Young Kim ,  Young Gi Yoon

IPC: B01J21/06 ,  B01J23/06 ,  B01J27/051 ,  B01J35/04 ,  B01J37/02 ,  B01J35/00 ,  B01J21/18 ,  B01J23/42 ,  B01J23/75 ,  B01J27/24 ,  B01J37/08 ,  B01J23/889 ,  B01J23/46 ,  B01J23/62 ,  B01J23/656 ,  B01J23/745 ,  B01J23/755 ,  B01J23/89 ,  B01J35/08

Abstract: Disclosed is a direct synthesis method of nanostructured catalyst particles on surfaces of various supports. In the disclosed synthesis method of a catalyst structure having a plurality of nanostructured catalyst particles dispersed in a support by a one-step process using a high-temperature high-pressure closed reactor, the one-step process includes supplying the support and a catalyst source into the high-temperature high-pressure closed reactor; supplying an atmosphere forming gas of the reactor into the reactor; perfectly sealing the high-temperature high-pressure closed reactor and heating the reactor to produce the catalyst structure in the reactor under self-generated pressure and synthesis temperature conditions, the catalyst structure including the plurality of nanostructured catalyst particles dispersed in the support; removing internal gases of the reactor to allow the reactor to be in a high-temperature, atmospheric pressure state and supplying an inert gas into the reactor to remove unreacted materials and byproducts remaining in the reactor; and cooling the reactor to room temperature while supplying the inert gas to synthesize the catalyst structure.