• Patent21
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• s.55
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• pp.2-8
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• 2004

21세기를 접어들어, 우리나라 및 세계 각국은 새로운 기술분야를 개척하기 위해 부단한 노력을 하고 있다. 특히 IT, BT, NT 기술분야는 현대 내ㆍ외국 모두 21세기의 새로운 발전 동력의 근간이 되는 기술로 각 국가 모두 사활을 걸고 있는 분야이다. 이에 우리나라도 국가경쟁력을 높이기 위해 각 부처에서는 10대 차세대 성장동력산업을 정부의 산업정책으로 이끌어 가기 위한 노력을 하고 있다. 정부에서 발표한 차세대 성장동력산업은 디지털 TV, 차세대 이동통신, 차세대 반도체 등의 IT 분야와 바이오 신약/장기 등의 BT 분야로 나눌 수 있다.

• Electronics and Telecommunications Trends
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• v.27 no.5
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• pp.64-72
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• 2012

물질의 상태를 알기 위해 사용되는 센서 기술은 전기적 신호와 정보 등을 감지하는 전자 기술뿐만 아니라 생물학을 포함한 바이오 기술과 나노 기술과의 융합을 통해 진화하고 있다. 이러한 진화는 아이폰을 시작으로 하는 IT 산업의 변화를 이끌 뿐만 아니라, 헬스케어 분야를 중심으로 빠르게 적용되고 있는 기술로써 첨단기술의 상징으로 자리매김하고 있다. 이미 많은 사람들이 알고 있는 유비쿼터스 사회에서 꼭 필요한 스마트 센서로써의 현주소를 파악하기 위해서 산업동향과 국 내외 주요 연구결과물들을 살펴보고, 향후 발전방향을 예측해 보고자 한다.

• Ceramist
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• v.7 no.3
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• pp.48-54
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• 2004

반도체 집적화 공정 기술을 바탕으로 기계적 구조물(Micromachined mechanical structure)구현을 가능하게 한 Microelectromechanical systems (MEMS) 기술은 최근 들어 새로운 연구분야로서 크게 각광받고 있다. 이러한 MEMS 기술은 자동차, 산업, 의공학, 정보과학 등에 폭넓게 응용되고 있으며 실리콘 가공 기술 및 미세전기소자 (Microelectronics) 기술이 융합되어 전기$.$기계적인 미세소자를 제작하는데 널리 이용되고 있다. (중략)

• Journal of the Korean Institute of Intelligent Systems
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• v.14 no.4
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• pp.411-417
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• 2004

Recently, instruments and systems related on biological technology have been enormously developed. Particularly, many researches for biological cell injection have been carried out. Usually, excessive contact force occurring when the end-effector and a biological cell contact might make a damage on the cell. Unfortunately, the excessive force could easily destroy the membrane and tissue of the cell. In order to overcome the problem, we proposed a new injection system for biological cell manipulation. The proposed injection system can measure the contact force between a pipette and a cell by using a force sensor. Also, we used vision technology to correctly guide the tip of the pipette to the cell. Consequently, the proposed injection system could safely manipulate the biological cells without any damage. This paper presents the introduction of our new injection system and design concepts of the new micro end-effector. Through a series of experiments the proposed injection system shows the possibility of application for precision biological cell manipulation such as DNA operation.

• Journal of Digital Convergence
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• v.18 no.2
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• pp.83-93
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• 2020

As the importance of the biohealth industry has recently increased, innovative government support is required. However due to the limitation in the support framework, a complementary support system for commercialization is needed. This study examines the concept of TRL which the existing support being following, and investigates domestic support system and overseas support cases. It points out that the current TRL-based government support policy has limitations for the commercialization of the biohealth industry, which requires a lot of time and investment. The new concept of the support system reflecting the characteristics of the bio-industry and solving the problems of late R&D stage was proposed and connected with the policy direction. It is meaningful that the role as a guideline for overcoming the gap between research and industry for the commercialization of the biohealth.

• The Microorganisms and Industry
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• v.20 no.1
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• pp.34-37
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• 1994

본고에서는 광범위하고 앞으로의 전망이 밝은 식품신소재중 효소 또는 미생물에 의해서 전환 또는 합성되는 몇가지 분야에 대해서 기술해 보고자 한다. 기술분야는 기능성 올리고당, 식이섬유, 당알콜을 포함하는 탄수화물소재, 신감미료, 단백분해 peptide 등을 포함한 단백, 펩타이드 소재 및 지질계 소재에 대해서 한정적인 범위에서 기술하고저 한다.

• Asia-Pacific Journal of Business Venturing and Entrepreneurship
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• v.11 no.1
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• pp.85-95
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• 2016

Generally a venture capital aims at investment and support Venture businesses that signifies a start-up which has high technologies but frailty of the economy so that raise fund from financial agencies at high risk rate, it has high risk but when the venture businesses launch into general orbit, the venture capital guarantee high-rate profits. Venture capital do not just provide risk capital but also takes a role as a mentor for continuous growth with total consulting service at business and technical management. Also it offers in-depth support to reform the supported enterprise in order to enhance the competitive. Venture capital receives attention for years as a principal agent to be promoted strategically at national level. Bio venture, a major concern of venture capital and one of core industries in Korea, is different from other industries because it needs long-term and large scale of investment. these factors bring about difficulties in an investment and growth. Therefore, it is very important to identify growth and profitability of start-ups and small and venture businesses with long-term appreciation above all other industries. This research analyze management results of bio venture businesses empirically by investment from venture capital. according to the results, bio venture businesses need huge capital and a long gap of time, henceforth, formation of model for growth is necessary with angel investing as well as venture capital. Since, there are not many listed bio venture businesses, significant statistical result would be limited. This research studied at only economic focus but further study need to examine a question from various angles.

• Clean Technology
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• v.24 no.4
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• pp.357-364
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• 2018

Studies on the production of biogas from third generation biomass, such as micro- and macroalgae, have been conducted through experiments of various scales. In this paper, we investigated the feasibility of commercialization of integrated combined heat and power (CHP) production using biogas derived from macroalgae, i.e., seaweed biomass. For this purpose, an integrated CHP plant of industrial scale, consisting of solid oxide fuel cells, gas turbine and organic Rankine cycle, was designed and simulated using a commercial process simulator. The cost of each equipment in the plant was estimated through the calculated heat and mass balances from simulation and then the techno-economic analysis was performed. The designed integrated CHP process produces 68.4 MW of power using $36ton\;h^{-1}$ of biogas from $62.5ton\;h^{-1}$ (dry basis) of brown algae. Based on these results, various scenarios were evaluated economically and the levelized electricity cost (LEC) was calculated. When the lifetime of SOFC is 5 years and its stack price is $$225kW^{-1}$, the LEC was 12.26 ¢ $kWh^{-1}$, which is comparable to the conventional fixed power generation.

• Journal of Energy Engineering
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• v.22 no.2
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• pp.184-196
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• 2013

We need to develop new renewable energy that could fundamentally replace fossil fuel, since the volume of economy and industry of our time becomes uncontrollably enormous. One of the alternative is to develop energy based on marine biomass, which would meet environment and energy needs at the same time. The marine bio-energy productions is supposed to occupy 50% to 500 million TOE in bio-energy production that is based on the Korean 3rd new renewable energy technology development, utilization, supply plan until 2030. This study attempts to apply input-output analysis to investigating the economic impacts of marine bio-energy development project in the Korean national economy. More specifically, this study shows what national economy effect of production-inducing effect, value-added inducing effect, employment-inducing effect, and R&D-inducing effect are explored with demand-driven model. Furthermore, this study attempts to define and classify the marine bio-energy development project sector from I-O table. Also, this study pays particular attention to marine bio-energy development project by taking the industry as exogenous specification and then investigating its economic impacts. The Marine bio-energy development project case 223 billion won, production-inducing effect, value-added inducing effect, and employment-inducing effect are 312 billion won, 87 billion won, 1,151 persons, and 5 billion won respectively. These quantitative information can be usefully utilized in the policy-making for the industrialization of marine bio-energy development project.

• Textile Coloration and Finishing
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• v.7 no.2
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• pp.77-85
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• 1995

섬유와 인류의 관계는 실로 5,000년이 넘는다. $\ulcorner$섬유$\lrcorner$라고 하면 많은 사람들이 $\ulcorner$의복$\lrcorner$만을 연상한다. 따라서 의복이 왜 그렇게 대단한 기술이며 과학이겠는가 하고 반문하는 사람도 있다. 이는 의복이라는 단순한 개념의 섬유만을 상상하기 때문이다. 장구한 의복의 역사가 곧 섬유의 역사라고 생각하는 것 또한 무리는 아니다. 그런데 최근 우리의 경제부흥에 가장 큰 공헌을 한 산업이 섬유산업이라는 데는 이의가 있을 수 없다. 지금 세계의 섬유산업은 내실 크나큰 변화를 일으키고 있다. 이는 장구한 세월동안 축적되어 온 섬유기술이 새로운 첨단산업을 탄생시키고 새로운 산업분야를 형성시키고 있기 때문이다. 지금 섬유산업은 르네상스를 맞이하고 있다는 것이 현실이며, 섬유기술은 고차원적인 첨단기술시대를 열어가고 있다. 선진 제국들은 중요한 테크놀로지의 하나로 신소재공학 기술을 열어가고 있다. 그 예로서 항공, 우주, 해양, 원자력, 토목, 건축 분야 등에서 요구하고 있는 고강도 고탄성의 섬유, 내열, 방염, 내부식성인 즉 내환경성의 섬유, 일렉트로닉스 분야의 도전성, 압전성, 광전성, 방사선 차단성, 흡진성, 도광성의 특수기능섬유, 라이프사이언스분야의 생체적합성, 혈액적합성, 고분리기능성 등과 같은 바이오섬유, 이 모든 것들은 21세기 각 분야의 첨단공학을 실현시키는데 필요불가결한 것들이다.