• 기계와재료
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• v.23 no.2
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• pp.68-79
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• 2011

전고체 리튬 이차전지는 기존 리튬 이차전지의 구성요소 가운데 액체 전해질을 고체 전해질로 대체한 것을 말한다. 전지의 폭발이나 화재의 위험성이 업소 제조공정이 단순화되며 고 에너지 밀도화 가능성에서 기존 리튬 이차전지보다 유리한 전고체 리튬이차전지는 차세대 이차전지로 주목받고 있다. 본고에서는 전고체 리튬 이차전지의 핵심 요소기술인 세라믹 고체 전해질과 용량 및 에너지 밀도 향상을 위한 전고체 이차전지 구조 등에 대해 연구개발 현황을 조사하였다.

• Journal of the Korean Electrochemical Society
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• v.10 no.1
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• pp.31-35
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• 2007

In this review article, we are going to explain the recent development of lithium secondary batteries for a cellular phone. There are three kinds of rechargeable batteries for cellular phones such as nickel-cadmium, nickel-metal hydride, and lithium ion or lithium ion polymer. The lithium secondary battery is one of the most excellent battery in the point of view of energy density. It means very small and light one among same capacity batteries is the lithium secondary battery. The market volume of lithium secondary batteries increases steeply about 15% annually. The trend of R&D is focused on novel cathode materials including $LiFePO_4$, novel anode materials such as lithium titanate, silicon, and tin, elecrolytes, and safety insurance.

• Resources Recycling
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• v.31 no.3
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• pp.27-39
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• 2022

The global demand for lithium-ion batteries (LIBs) has been continuously increasing since the 1990s along with the growth of the portable electronic device market. Of late, the rapid growth of the electric vehicle market has further accelerated the demand for LIBs. The demand for the LIBs is expected to surpass the supply of lithium from natural resources in the near future, posing a risk to the global lithium supply chain. Moreover, the continuous accumulation of end-of-life LIBs is expected to cause serious environmental problems. To solve these problems, recycling the spent LIBs must be viewed as a critical technological challenge that must be urgently addressed. In this study, recycling LIBs using pyrometallurgical processes and post-processes for efficient lithium recovery are briefly reviewed along with the major accomplishments in the field and current challenges.

• Proceedings of the Korean Society of Computer Information Conference
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• 2022.07a
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• pp.149-152
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• 2022

최근 전기차의 기술 발전이 급속도로 증가함에 따라 이차전지의 수요가 증가하게 되었다. 그로인해 다량의 고품질 전지를 생산하기 위해 제조 공장이 가동되고 있지만 생산된 전지의 품질의 핵심이 되는 화성공정의 에이징 과정 진행 중 온도 관리에 실패할 경우, 전지의 폭발 및 화재의 위험이 있다. 본 논문은 이차전지를 생산하는 에이징 공정의 효율적인 온도 관리를 위해 목업 모형을 만들어 온도 센서를 통한 온도 수집 및 모니터링 시스템을 개발하고, 공조기 바람을 통해 전지의 온도가 변화하는 속도를 계산하고, 이상온도에 도달해 고온의 상태가 되었을 경우 주변 전지로 전달되는 열을 시뮬레이션 통한 효율적인 공조 대책을 제시하여 이차전지 생산의 품질 향상과 화재 예방을 통해 전기차 생산에 따른 리튬이온 전지의 수요 해결에 기여한다.

• Membrane Journal
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• v.26 no.4
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• pp.310-317
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• 2016

Lithium ion secondary battery (LISB) is an energy conversion system operated via charging-discharging cycle based on Lithium ion migration. LISB has a lot of advantages such as high energy density, low self-discharge rate, and a relatively high lifetime. Recently, increasing demands of electric vehicles have been encouraging the development of LISB with high capacity. Unfortunately, it causes some critical safety issues. It includes dendrite formation on negative electrode, resulting in electric shortage problems and battery explosion. Also, the elevated temperatures occurred during the LISB operation induces thermal shrinkage of polyolefin (e.g., polyethylene and polypropylene) separators. Consequently, the low thermal stability leads to decay of LISB performances and the reduction of lifetime. In this study, sulfonated poly (arylene ether sulfone) (SPAES) random copolymers were used as key materials to prepare polyolefin pore-filling separator. The resulting separators were evaluated in the term of metal ion chelation capability associated with dendrite formation, $Li^+$ ion conductivity and thermal durability.

• Transactions of the Korean Society of Mechanical Engineers B
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• v.37 no.7
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• pp.665-667
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• 2013

Metal ions show various transitions in the cathode of a lithium-ion battery. The diffusion process of lithiumions and the phase transition in the cathode need to be thoroughly understood for the advanced design of an improved lithium-ion battery. Here, we employ a phase field model to simulate the diffusion of lithiumions and to study the phase transition in the cathode.

• Proceedings of the Korean Institute of Surface Engineering Conference
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• 2012.11a
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• pp.130-130
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• 2012

리튬이차전지의 음극재로 적용하기 위해, 텅스텐 산화물을 구리 기재 위에 전해 도금하였다. 이를 위해 텅스텐 산화물 염이 포함된 도금 조 내에서 다양한 도금 조건을 사용하여 산화물을 구리 기재 위에 박막 형태로 형성시켰다. 형성된 박막 산화물의 조성 및 구조적 특성을 분석하였고, 특히, 리튬 염을 포함하는 유기 용매 하에서 순환 전위 실험을 수행하여, 텅스텐 산화물 전해 도금 박막이 리튬이차전지의 음극재로서 리튬과 가역적으로 반응하는지 분석하였다.

• Electronics and Telecommunications Trends
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• v.25 no.5
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• pp.11-19
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• 2010

유비쿼터스 시대의 모바일 전력원으로서 가장 유용한 리튬이차전지의 충전방식은 1991년 리튬이온전지의 상용화 이후 정전류-정전압 방식의 충전법이 고수되어 왔다. 그러나 압전, 열전 등 신재생에너지에 의한 에너지 하베스팅으로 생성되는 전력의 성질이 전압과 전류의 범위가 매우 다양하므로 효율적으로 저장할 수 있는 에너지 매니지먼트 체계가 필요하다. 이에 대한 기반연구로서 리튬이차전지의 고효율 충전을 위한 다양한 방식이 고려되어 왔으며, 본 동향분석서에서는 이러한 충전방식에 따라 리튬이차전지 내부 소재가 받는 영향과 여러 충전방식의 장단점을 분석하고, 최적 충전방식의 기준을 정리한다.

• Journal of the Korean Electrochemical Society
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• v.11 no.3
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• pp.211-222
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• 2008

Li secondary batteries, which have been in successful commercialization, are becoming important technology as power sources in non-IT application like HEV(Hybrid Electric Vehicle) as well as in portable electronics. It is not the overstatement that the commercialization of Li secondary battery was a result of the development of carbonaceous anode material and safety mechanisms. The R&D of electrode materials of Li secondary batteries is one of the core technologies in the development and it has enormous influences on various fields as well as on the battery industry. Here, the current research of anode materials is described and the underlying problems associated with development, advantages and drawbacks is analyzed.

• Journal of the Korean Electrochemical Society
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• v.10 no.1
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• pp.20-24
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• 2007

Lithium ion secondary battery has been applied widely to portable devices, and has been studied for application to high power electric cell system such as power tool or hybrid electronic vehicle. The structure change of the electrodes materials occur when lithium ions move between electrodes. Neutron or X-rays can analyze the structure of electrode. The advantage of X-rays is convenient in test. However X-rays is scattered by electron cloud in atoms. Therefore, The elucidation for correct position of lithium is difficult with X-rays because lithium has small atomic weight. Neutron analysis techniques could solve this problem. In this review, We wish to discuss about structure analysis and the principle of structural characterization method using neutron beam source.