• 한국지반공학회논문집
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• 제27권2호
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• pp.5-15
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• 2011

일본에서 개발된 원추형 팽이기초(Top-Base Foundation)와 국내에서 개발된 부양형 팽이기초(Floating Top-Base Foundation)를 대상으로 대표 점토질 연약지반인 저압축성점토, 점토질 실트, 점토질 모래에 타설하여 실내모형실험을 수행하였다. 본 실험을 통해 하중-침하량, 기초측면 히빙량, 지중응력분포 등을 측정하여 두 가지 팽이기초의 성능을 비교 평가하였다. 또한, 단변길이 증가에 따른 침하량 변화를 분석하였다. 실내모형실험 결과 부양형 팽이기초가 지지력 증진, 침하량 저감, 응력분산효과, 측방구속력에 대해서 좀 더 우수한 성능을 발휘하는 것으로 나타났으며, 기초폭증가에 따른 침하량은 팽이기초 $5{\times}5$배열을 기점으로 수렴하였다.

• 한국구조물진단유지관리공학회 논문집
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• 제14권2호
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• pp.137-144
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• 2010

팽이기초에 대한 일본과 국내에서 현재까지 공통적으로 연구되고 있는 것은 팽이기초의 현장재하실험에 대한 지지력과 침하량에 주목되어 있다. 그러나 팽이기초에서 선행되어야할 연구는 공법 자체가 상재하중을 하부에 어떠한 원리로 전달되는 지에 대한 분석이 수행되어야 한다. 이에 본 연구에서는 일본에서 개발된 Top-Base Foundation과 국내에서 개발된 부양형 팽이기초의 응력전달 메커니즘을 수치해석 및 실내모형실험을 통하여 분석하였다. 팽이기초의 하중전달 메커니즘을 분석한 결과 상재하중에 대한 팽이기초 자체의 하중저감 분담률은 주로 팽이기초와 쇄석사이에서 발생하는 주면마찰력이 가장 크게 나타났다. 또한, 팽이기초의 내부응력분산효과를 포함한 Top-Base Foundation의 총 응력분산각은 $41.8^{\circ}$이며, 부양형 팽이기초의 총 응력분산각은 $44.5^{\circ}$로 산정되었다.

• 한국지반공학회:학술대회논문집
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• 한국지반공학회 2009년도 세계 도시지반공학 심포지엄
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• pp.430-440
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• 2009

Top-Base Foundation(TBF) was developed in Japan as a factory made concrete product. It is actively used in 6,000 sites by the end of 1980s in Japan and applied for a domestic patent in 1985. It is a shallow foundation whose effectiveness is proven by many relevant researchers and engineers. TBF was introduced to Korea in 1991 and has been applied mainly to architectural structures to date. Currently, the effectiveness in bearing capacity and settlement of TBF is being underestimated for civil engineering structures. Characteristics of Top-Base Foundation studied in Japan and Korea is known as follows: (1) as concrete part and crushed stone behave together, they perform the function of rigid mat; (2) the conical part and pile part of TBF disperses load by interaction with the crushed stone; (3) by preventing lateral strain and differential settlement on lower ground, it improves bearing capacity and constrains settlement at the same time. In Korea, it is used mostly in clayey soft grounds. The formula of bearing capacity and settlement of TBF suggested in Japan give the values of the underestimated. bearing capacity while its settlement is overestimated in comparison with the values measured from the field loading test. Therefore, in this study, the stress delivery mechanism of Top-Base Foundation developed in Japan and Floating Top Base developed in Korea is investigated through numerical analysis and laboratory model test.

• 한국진공학회:학술대회논문집
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• 한국진공학회 2011년도 제40회 동계학술대회 초록집
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• pp.482-483
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• 2011

Graphene is a good candidate for the future nano-electronic materials because it has excellent conductivity, mobility, transparency, flexibility and others. Until now, most graphene researches are focused on the nano electronic device applications, however, biological application of graphene has been relatively less reported. We have fabricated a deoxyribonucleic acid (DNA) conjugated graphene field-effect transistor (FET) and measured the electrical transport characteristics. We have used graphene sheets grown on Ni substrates by chemical vapour deposition. The Raman spectra of graphene sheets indicate high quality and only a few number of layers. The synthesized graphene is transferred on top of the substrate with pre-patterned electrodes by the floating-and-scooping method [1]. Then we applied adhesive tapes on the surface of the graphene to define graphene flakes of a few micron sizes near the electrodes. The current-voltage characteristic of the graphene layer before stripping shows linear zero gate bias conductance and no gate operation. After stripping, the zero gate bias conductance of the device is reduced and clear gate operation is observed. The change of FET characteristics before and after stripping is due to the formation of a micron size graphene flake. After combined with 30 base pairs single-stranded poly(dT) DNA molecules, the conductance and gate operation of the graphene flake FETs become slightly smaller than that of the pristine ones. It is considered that DNA is to be stably binding to the graphene layer due to the ${\pi}-{\pi}$ stacking interaction between nucleic bases and the surface of graphene. And this binding can modulate the electrical transport properties of graphene FETs. We also calculate the field-effect mobility of pristine and DNA conjugated graphene FET devices.