公开(公告)号：US10435802B2

公开(公告)日：2019-10-08

申请号：US15910270

申请日：2018-03-02

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Sung Jong Yoo ,  Injoon Jang ,  So Young Lee ,  Jin Young Kim ,  Jong Hyun Jang ,  Hyoung-Juhn Kim ,  Jonghee Han ,  Hyun Seo Park

IPC: B01J35/00 ,  B01J23/28 ,  B01J23/72 ,  B01J23/74 ,  B01J23/881 ,  B01J23/882 ,  B01J23/883 ,  B01J23/885 ,  B01J37/08 ,  B01J37/34 ,  C25B11/04 ,  C25B1/04

Abstract: Provided are a cathode catalyst for water electrolysis devices and a method for preparing the same. More specifically, provided are a cathode catalyst for water electrolysis devices that exhibits both high activity and high electrical conductivity, compared to conventional transition metal phosphide catalysts, and a method for preparing the same.

公开(公告)号：US10276875B2

公开(公告)日：2019-04-30

申请号：US15374732

申请日：2016-12-09

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Hyung Chul Ham ,  Min-Jae Lee ,  Chang-Whan Lee ,  Seong Cheol Jang ,  Sun-Hee Choi ,  Hyun Seo Park ,  Chang Won Yoon ,  Sung Pil Yoon ,  Jonghee Han ,  Suk Woo Nam ,  Tae Hoon Lim ,  Jin Young Kim

IPC: H01M4/86 ,  H01M4/90 ,  H01M4/88 ,  H01M8/14

Abstract: An anode for a molten carbonate fuel cell (MCFC) having improved creep property by adding CeO2 and/or Cr for imparting creep resistance to nickel-aluminum alloy and nickel as materials for an anode is provided. Improved sintering property, creep property and increased mechanical strength of a molten carbonate fuel cell may be obtained accordingly.

公开(公告)号：US10245553B2

公开(公告)日：2019-04-02

申请号：US15224922

申请日：2016-08-01

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Jongsoo Jurng ,  Min Su Kim ,  Eun Seuk Park ,  Hyoun Duk Jung ,  Jin Young Kim

IPC: A61L9/00 ,  B01D53/02 ,  B03C3/00 ,  B01D53/86 ,  B01D53/04

Abstract: Disclosed is an apparatus for decomposing low-concentration volatile organic compounds, which includes: an adsorption unit configured to adsorb a volatile organic compound; a heated air supply unit configured to supply a heated air to the adsorption unit; an oxidation decomposing catalyst unit configured to decompose a volatile organic compound detached from the adsorption unit; and an ozone supply unit configured to supply an ozone to the oxidation decomposing catalyst unit. The apparatus may maximize an exchange cycle semi-permanently by adsorbing low-concentration VOC under a high-flow condition and then detaching VOC within a short time and also by recycling an adsorption filter. In addition, the apparatus may effectively decompose VOC substances detached by a low flow into carbon dioxide and water under a condition with most excellent oxidation decomposition efficiency by using an oxidation decomposing catalyst filter.

公开(公告)号：US09954240B2

公开(公告)日：2018-04-24

申请号：US15132011

申请日：2016-04-18

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY ,  Jagiellonian University

Inventor： Dirk Henkensmeier ,  Jong Hyun Jang ,  Hyoung-Juhn Kim ,  Jin Young Kim ,  Sung Pil Yoon ,  Jonghee Han ,  Suk Woo Nam ,  Ngoc My Hanh Duong ,  Artur Michalak ,  Karol Dyduch ,  Mateusz Brela

IPC: H01M8/103 ,  H01M8/1004 ,  H01M8/12 ,  H01M8/1027 ,  C08G65/40 ,  C08G65/48 ,  C08G65/00 ,  H01M8/1018

CPC classification number: C08G65/40 ,  C08G65/007 ,  C08G65/4037 ,  C08G65/48 ,  H01M8/1004 ,  H01M8/1025 ,  H01M8/1027 ,  H01M8/103 ,  H01M8/12 ,  H01M2008/1095 ,  Y02P70/56

Abstract: Disclosed are a 5-(2,6-dioxyphenyl)tetrazole-containing polymer, a method for preparing the same, a membrane containing the same and an electrochemical device, particularly a high temperature polymer electrolyte membrane fuel cell, including the membrane. The membrane containing the 5-(2,6-dioxyphenyl)tetrazole-containing polymer is capable of providing high proton conductivity and exhibiting good mechanical properties, thereby capable of providing superior fuel cell performance. Accordingly, the membrane may be usefully used in an electrochemical device, particularly a fuel cell, more particularly a high temperature polymer electrolyte membrane fuel cell.

公开(公告)号：US09941476B2

公开(公告)日：2018-04-10

申请号：US14659809

申请日：2015-03-17

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Hae Jung Son ,  Min Jae Ko ,  Bong Soo Kim ,  Doh-Kwon Lee ,  Jin Young Kim ,  Hong Gon Kim ,  Sungmin Park

IPC: H01L51/00 ,  C08G61/12 ,  H01L51/05

CPC classification number: H01L51/0036 ,  C08G61/123 ,  C08G61/124 ,  C08G61/126 ,  C08G2261/12 ,  C08G2261/1412 ,  C08G2261/146 ,  C08G2261/18 ,  C08G2261/3223 ,  C08G2261/3229 ,  C08G2261/3241 ,  C08G2261/3243 ,  C08G2261/3245 ,  C08G2261/3246 ,  C08G2261/334 ,  C08G2261/344 ,  C08G2261/364 ,  C08G2261/414 ,  C08G2261/592 ,  C08G2261/92 ,  H01L51/0035 ,  H01L51/0545 ,  H01L51/0558 ,  Y02E10/549

Abstract: The present disclosure provides an organic semiconductor compound, which has superior charge mobility, low band gap, wide light absorption area and adequate molecular energy level. The conductive organic semiconductor compound of the present disclosure can be used as a material for various organic optoelectric devices such as an organic photodiode (OPD), an organic light-emitting diode (OLED), an organic thin-film transistor (OTFT), an organic solar cell, etc. In addition, it can be prepared into a thin film via a solution process, can be advantageously used to fabricate large-area devices and can reduce the cost of device fabrication.

公开(公告)号：US20150027896A1

公开(公告)日：2015-01-29

申请号：US13975743

申请日：2013-08-26

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Jin Young Kim ,  Doh-Kwon Lee ,  Hong Gon Kim ,  Bong Soo Kim ,  Se Won Seo ,  Kee Doo Lee ,  Hae Jung Son ,  Min Jae Ko

IPC: H01L31/18

CPC classification number: H01L21/02422 ,  H01L21/02425 ,  H01L21/02491 ,  H01L21/0256 ,  H01L21/02568 ,  H01L21/02628 ,  H01L31/0326 ,  Y02E10/50

Abstract: A Cu2ZnSnS4-xSex (0≦x≦4) thin film solar cell is disclosed. The thin film solar cell includes a Cu2ZnSnS4-xSex (0≦x≦4) thin film as an absorber layer produced by forming a precursor film composed of Cu, Zn, Sn, and Se using an ionic liquid as a solvent through a constant current process and annealing the precursor film with sulfur. Also disclosed is a method for fabricating the thin film solar cell. The method uses a non-vacuum electrodeposition process that is appropriate for large-area mass production and is thus cost effective compared to a vacuum process. In addition, since the method uses an ionic liquid, the formation of by-products harmful to humans as a result of side reactions is suppressed. Furthermore, the method uses a one-step electrodeposition process, which enables the deposition of a maximum of four elements at one time, or a multi-step deposition process, and an annealing process.

Abstract translation: 公开了一种Cu2ZnSnS4-xSex（0＆nlE; x＆nlE; 4）薄膜太阳能电池。 薄膜太阳能电池包括通过使用离子液体作为溶剂通过恒定电流形成由Cu，Zn，Sn和Se构成的前体膜制成的吸收层的Cu2ZnSnS4-xSex（0＆lt; nlE; x＆nlE; 4）薄膜 用硫处理和退火前体膜。 还公开了一种制造薄膜太阳能电池的方法。 该方法使用适用于大面积批量生产的非真空电沉积工艺，因此与真空工艺相比是成本有效的。 此外，由于该方法使用离子液体，因此抑制由于副反应而对人体有害的副产物的形成。 此外，该方法使用一步电沉积工艺，其能够一次最多沉积四个元素，或多步沉积工艺和退火工艺。

公开(公告)号：US20140342467A1

公开(公告)日：2014-11-20

申请号：US13946656

申请日：2013-07-19

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Yeon Seok Kim ,  Jong Soo Jurng ,  Byoung Chan Kim ,  Hyoun Duk Jung ,  Jin Young Kim

IPC: G01N33/18

CPC classification number: G01N33/1813 ,  G01N21/6428 ,  G01N21/78 ,  G01N21/85 ,  G01N2021/773 ,  G01N2021/7786

Abstract: The present invention relates to an apparatus and method for continuously monitoring subaqueous target harmful substances. More particularly, it relates to an apparatus and method for continuously monitoring subaqueous target harmful substances by continuously measuring the concentration of the subaqueous target harmful substances. The present invention provides an apparatus and method for continuously monitoring subaqueous target harmful substances, which can continuously measure the concentration of subaqueous target harmful substances using a receptor that can selectively recognize the target harmful substances, a porous membrane fixed with the receptor, and a sensing unit that continuously measures the intensity of fluorescent signals of the target harmful substance reacting with the receptor, and can be utilized as various apparatuses and methods for continuously sensing various harmful substances necessary to continuously monitor for the management of the water quality.

Abstract translation: 本发明涉及连续监测水中靶标有害物质的装置和方法。 更具体地，涉及通过连续测量水中靶标有害物质的浓度来连续监测水中靶标有害物质的装置和方法。 本发明提供一种用于连续监测水中靶标有害物质的装置和方法，其可以使用能够选择性地识别目标有害物质的受体，用受体固定的多孔膜，连续地测量水中靶标有害物质的浓度，以及感测 能够连续地测量与受体反应的目标有害物质的荧光信号的强度的单位，并且可以用作连续检测持续监测水质管理所需的各种有害物质的各种装置和方法。

公开(公告)号：US11289711B2

公开(公告)日：2022-03-29

申请号：US16934893

申请日：2020-07-21

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Jong Hyun Jang ,  Hyun Seo Park ,  Hee-Young Park ,  Katie Heeyum Lim ,  Oh Sub Kim ,  Hyoung-Juhn Kim ,  Jin Young Kim ,  Sung Jong Yoo ,  Dirk Henkensmeir ,  So Young Lee

IPC: H01M4/92 ,  H01M4/86 ,  H01M4/88 ,  H01M4/90

Abstract: Disclosed are a catalyst electrode for a fuel cell, a method for fabricating the catalyst electrode, and a fuel cell including the catalyst electrode. The presence of an ionomer-ionomer support composite in the catalyst electrode prevents the porous structure of the catalyst electrode from collapsing due to oxidation of a carbon support to avoid an increase in resistance to gas diffusion and can stably secure proton channels. The presence of carbon materials with high conductivity is effective in preventing the electrical conductivity of the electrode from deterioration resulting from the use of a metal oxide in the ionomer-ionomer support composite and is also effective in suppressing collapse of the porous structure of the electrode to prevent an increase in resistance to gas diffusion in the electrode. Based on these effects, the fuel cell exhibits excellent performance characteristics and prevents its performance from deteriorating during continuous operation.

公开(公告)号：US11173481B2

公开(公告)日：2021-11-16

申请号：US16534216

申请日：2019-08-07

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY ,  GLOBAL FRONTIER CENTER FOR MULTISCALE ENERGY SYSTEMS

Inventor： Sung Jong Yoo ,  Injoon Jang ,  Hee-Young Park ,  So Young Lee ,  Hyun Seo Park ,  Jin Young Kim ,  Jong Hyun Jang ,  Hyoung-Juhn Kim

IPC: B01J37/34 ,  B01J23/50 ,  B01J23/52 ,  B01J37/02 ,  H01M4/90 ,  H01M4/88

Abstract: Disclosed are a metal single-atom catalyst and a method for preparing the same. The method uses a minimal amount of chemicals and is thus environmentally friendly compared to conventional chemical and/or physical methods. In addition, the method enables the preparation of a single-atom catalyst in a simple and economical manner without the need for further treatment such as acid treatment or heat treatment. Furthermore, the method is universally applicable to the preparation of single-atom catalysts irrespective of the kinds of metals and supports, unlike conventional methods that suffer from very limited choices of metal materials and supports. Therefore, the method can be widely utilized to prepare various types of metal single-atom catalysts. All metal atoms in the metal single-atom catalyst can participate in catalytic reactions. This optimal atom utilization achieves maximum reactivity per unit mass and can minimize the amount of the metal used, which is very economical.

公开(公告)号：US10854886B2

公开(公告)日：2020-12-01

申请号：US16268856

申请日：2019-02-06

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Jong Hyun Jang ,  Hee-Young Park ,  Jea-woo Jung ,  Hyoung-Juhn Kim ,  Dirk Henkensmeier ,  Sung Jong Yoo ,  Jin Young Kim ,  So Young Lee ,  Hyun Seo Park

IPC: H01M4/92

Abstract: A method for preparing a carbon-supported, platinum-cobalt alloy, nanoparticle catalyst includes mixing a solution containing, in combination, a platinum precursor, a transition metal precursor consisting of a transition metal that is cobalt, carbon, a stabilizer that is oleyl amine, and a reducing agent that is sodium borohydride to provide carbon-supported, platinum-cobalt alloy nanoparticles, and washing the carbon-supported, platinum-cobalt alloy, nanoparticles using ethanol and distilled water individually or in combination followed by drying at room temperature to obtain dried carbon-supported, platinum-cobalt alloy, nanoparticles; treating the dried carbon-supported, platinum-cobalt alloy, nanoparticles with an acetic acid solution having a concentration ranging from 1-16M to provide acetic acid-treated nanoparticles, and washing the acetic acid-treated nanoparticles using distilled water followed by drying at room temperature to obtain dried acetic acid-treated nanoparticles; and heat treating the dried acetic acid-treated nanoparticles at a temperature ranging from 600 to 1000° C. under a hydrogen-containing atmosphere.