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이재엽,이상중,한인섭,Lee, Jai-Yeop,Lee, Sangjung,Han, Ihnsup Korean Society of Soil and Groundwater Environment 2013 지하수토양환경 Vol.18 No.3
Adsorption of melamine was examined using columns packed with granular activated carbon (GAC). Raw GAC was sieved with 20, 40, 60 and 80 mesh to determine the influence of adsorbent particle size on reaction and diffusion. The mass ratio of the adsorption capacity of GAC for melamine ranged from 9.19 to 11.06%, and adsorption rates increased with decreasing particle size within this range. Rate constants between 3.295 ~ 4.799 $min^{-1}$ were obtained using a pseudofirst-order equation that was used to determine adsorption kinetics. A surface diffusion model was adapted to take into account the unsteady-state equation of a spherical adsorbent by converting the surface concentration from a constant to a variable governed by a dispersion equation. The calculated values were fit with the experimental results by using the diffusion coefficients as regression parameters. The modified equation exhibited a more precise agreement with respect to the sum of the absolute error (SAE).
4차산업혁명 기술의 환경분야 적용 및 전망 - 환경정책기반공공기술개발사업 과제를 중심으로 -
김규현(Gyuhyun Kim),한인섭(Ihnsup Han) 대한환경공학회 2022 대한환경공학회지 Vol.44 No.11
목적 : 최근 국내외 전 분야에서 4차산업혁명에 대한 논의가 활발히 진행되고 있으며 환경분야에서도 관련된 연구개발이 폭넓게 진행되고 있다. 4차 산업혁명의 핵심은 초연결, 초지능 및 융복합이다. 주요기술은 인공지능(Artificial Intelligence), 사물인터넷(Internet of Things), 차세대 통신기술(Fifth Generation communication technology), 로봇, 블록체인, 드론, 3D(Three Dimension) 프린터, 빅데이터, 무인 운송수단, 바이오 공학, 신소재, 공유경제, VR/AR (Virtual Reality/Augmented Reality) 등이 있다. 4차산업혁명 기술의 환경적용 사례를 통해 발전방안을 모색하고자 한다. 방법 : 2011년에서 2020년까지 추진된 환경정책기반공공기술개발사업 과제를 중심으로 4차산업혁명기술이 적용된 사례를 분석하고 향후 전망을 도출하였다. 결과 및 토의 : 4차산업기술은 침수를 대비하게 위해 인공신경망을 이용한 유량예측시스템, 증강현실을 이용한 상하수관로 정보 제공, 드론을 이용한 환경감시 및 식생입체 구조 판별, 인공지능을 이용한 동물 울음소리 기반 개체식별 기술 등 다양한 분야에 적용되었다. 앞으로 환경분야의 설계, 운영, 유지관리, 조사, 감시, 서비스 제공 등 다양한 분야에서 4차산업혁명 기술이 적용되어 작업환경 개선, 서비스 품질 향상, 운영 효율화 등이 예상된다. 결론 : 스마트 환경기술 전환에 따라 산업 고도화 및 고부가가치 창출이 가능할 것으로 예상되며 이를 위해 정책적 지원과 기술 개발이 지속적으로 추진되어야 한다. Objectives : Recently, the Fourth Industrial Revolution has been actively discussed in all fields around the world. And the related R&D(Research and Development) has been widely conducted in the environmental field. The core of the Fourth Industrial Revolution is hyperconnectivity, superintelligence, and convergence. Major technologies related with it are AI(Artificial Intelligence), IoT(Internet of Things), 5G(Fifth Generation communication technology), robots, blockchain, drones, 3D(Three Dimension) printers, big data, unmanned transportation, biotechnology, new materials, sharing economy, and VR/AR(Virtual Reality/Augmented Reality), etc. It is intended to seek development plans through the examples of the 4th industrial revolution technology’s environmental application. Methods : In concentration of the public technology development project, based on environmental policy, conducted from 2011 to 2020, some cases of the 4th industrial revolution technology’s environmental application have been analyzed and the future prospects have been derived. Results and Discussion : The 4th Industrial Revolution technology has been applied in various fields such as design, operation, maintenance, investigation, monitoring, and service provision in the environmental field. Therefore, in the future, it is expected that there will be working environment improvement, the progress of service quality and operational efficiency. Conclusion : With the transition to smart environmental technology, it is expected that it will be possible to advance the industry and create high value-added things. To do so, government policy support and technology development should be continuously executed.
탈취제 성상에 따른 슬러지 내 황화수소 저감에 관한 연구
정회석 ( Hoesuk Jung ),이수정 ( Sujeong Lee ),선제호 ( Jeaho Seon ),요스케카츠라 ( Yousuke Katsura ),한인섭 ( Ihnsup Han ) 한국폐기물자원순환학회 2021 한국폐기물자원순환학회지 Vol.38 No.5
This study compared H<sub>2</sub>S removal efficiency of two types of deodorants (NOx deodorant ACE and Fe<sup>3+</sup> deodorant S) at high temperature versus low temperature (summer/winter). For both temperature conditions, NOx deodorant ACE removed H<sub>2</sub>S by 99% or more within 2 hours at the least dose of 2.5% (w/w), and this lasted for about 8 hours maximum. Fe<sup>3+</sup> deodorant S removed H<sub>2</sub>S by 99% or more at the dose of 5.0% (w/w), and this lasted for about 6 hours maximum. For the sludge where H<sub>2</sub>S exists at high concentration, NOx deodorant ACE was the most appropriate. For Fe<sup>3+</sup> deodorant S, additional alkaline chemicals are expected to be necessary.