• Title/Summary/Keyword: 폐 휴대폰

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Characterization of Metal Composition in Spent Printed Circuit Boards of Mobile Phones (폐휴대폰 내의 인쇄회로기판에 함유된 금속 성분의 변화)

  • Jeong, jinki;Lee, Jae-chun;Choi, Jun-chul
    • Resources Recycling
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    • v.24 no.3
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    • pp.76-80
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    • 2015
  • Mobile phone has become one of the essential items in our daily life. In Korea, it is estimated that more than 20 million cell phones are discarded each year due to advancement in technology, thus creating disposal and environmental pollution. In order to conserve the resources, their proper recycling is essential as it contains both valuable and toxic metals. The economics of the recycling will depend on the amount and value of the metals. Therefore, it is necessary to determine the composition of the metals present in the different cell phones. In the present study, a report is presented on the variation of metal content per year of waste mobile phones. A review has been made for the mobile phones manufactured during the period 2000-2009 and metal content of the printed circuit boards (PCBs) by analyzing their metals. An example of the precious metal palladium and of the heavy metal lead shows the decreasing trend.

PVA필름 제조 기술 확보 및 국산화 성공

  • Ryu, Won-Seok;Sin, Jae-Gyun
    • The monthly packaging world
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    • s.154
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    • pp.108-109
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    • 2006
  • PVA필름은 휴대폰, 카메라폰, 컴퓨터모니터, LCD TV등 편광필름이 사용되는 TFT-LCD 제품에는 반드시 필요한 핵심부품으로, 최근 인조대리석 제조용 필름, 분리필름, 내(耐)산소투과성 포장필름 등에도 활용범위를 넓혀가고 있는 신소재이다. 그러나 PVA필름은 일본이 PVA특성조절기술을 갖고 있어 그동안 일본에서 전량 수입해 사용해 온 것이 현실. 지난 1990년 설립된 이래, 국내 최초로 순수국내 기술로 고온수용성 부직포를 개발하며, 생산해 온 (주)텍스테크(대표이사 신재균)가 폐 부직포를 재활용해 LCD용 폴리비닐알코올(PVA) 필름을 제조하는 기술을 개발, 업계의 주목을 끌고 있다. 신재균 사장을 만나 폐부직포를 이용한 PVA 필름제조 기술개발 경위와 기대효과를 들어보았다.

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Lithium - A Critical Metal for Clean Energy Technologies: A Comprehensive Review on Challenges and Opportunities for Securing Lithium from Primary and Secondary Resources (리튬-청정 에너지 기술의 핵심금속: 1차 및 2차 자원으로부터 리튬 확보를 위한 도전과 기회에 대한 종합적 고찰)

  • Swain, Basudev;Kim, Min-seuk;Lee, Chan-Gi;Chung, Kyeong Woo;Lee, Jae-chun
    • Resources Recycling
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    • v.28 no.5
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    • pp.3-18
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    • 2019
  • Due to the increasing demand for clean energy, the consumption of lithium ion batteries (LIBs) is expected to grow steadily. Therefore, stable supply of lithium is becoming an important issue globally. Commercially, most of lithium is produced from the brine and minerals viz., spodumene, although various processes/technologies have been developed to recover lithium from other resources such as low grade ores, clays, seawaters and waste lithium ion batteries. In particular, commercialization of such recycling technologies for end-of-life LIBs being generated from various sources including mobile phones and electric vehicles(EVs), has a great potential. This review presents the commercial processes and also the emerging technologies for exploiting minerals and brines, besides that of newly developed lithium-recovery-processes for the waste LIBs. In addition, the future lithium-supply is discussed from the technical point of view. Amongst the emerging processes being developed for lithium recovery from low-grade ores, focus is mostly on the pyro-cum-hydrometallurgical based approaches, though only a few of such approaches have matured. Because of low recycling rate (<1%) of lithium globally compared to the consumption of lithium ion batteries (56% of lithium produced currently), processing of secondary resources could be foresighted as the grand opportunity. Considering the carbon economy, environment, and energy concerns, the hydrometallurgical process may potentially resolve the issue.

A Study on the Recycle of Carbon Material in Anode of Secondary Battery (이차전지 음극재 탄소 소재 재활용에 대한 연구)

  • Han, Gyoung-Jae;Kim, Yu-Jin;Yoon, Seong-Jin;Kang, Yu-Jin;Jang, Min-Hyeok;Jo, Hyung-Kun;Cho, Hye-Ryeong;Seo, Dong-Jin;Park, Joo-Il
    • Journal of the Korea Organic Resources Recycling Association
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    • v.30 no.4
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    • pp.59-66
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    • 2022
  • Lithium-ion batteries have greatly expanded along with the mobile phone market, and as the electric vehicle business is activated in earnest, they will attract many people's attention even afterwards. Until now, many people have attracted attention to the recovery of valuable metals inside lithium-ion batteries, but graphite, which is mainly used as an anode material, is also worth recycling. Therefore, in order to recover graphite with high purity and valuable metals, graphite that can be used as an anode material of a secondary battery may be generated again through a regeneration process of purifying and separating graphite from a waste lithium-ion battery and recovering electrical characteristics of graphite. This paper describes the process of converting waste graphite into regenerated graphite and the environmental and economic effects of regenerated graphite.