• 한국정밀공학회지
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• 제26권7호
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• pp.99-104
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• 2009

Creep characteristic is an important failure mechanism when evaluating engineering materials that are soft as polymers or used as mechanical elements at high temperatures. One of the popular thermo-elastic plastics, Polyethylene(PE) which is used broadly for engineering purposes, as it has good properties and merits compared to other plastics, was studied for creep characteristic at various level of stresses and temperatures. From the experimental results, the creep limit of PE at room temperature is 75% of tensile strength. Also the creep limits decreased exponentially as the temperatures increased, up to 50% of the melting point. Also the secondary stage among the three creep stages was nonexistent nor was there any rupture failure which occurred for many metals.

• 한국정밀공학회지
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• 제27권9호
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• pp.78-85
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• 2010

Creep characteristic is an important failure mechanism when evaluating engineering materials that are soft material as polymers or used as mechanical elements at high temperatures. One of the popular thermo-elastic polymers, Polycarbonate(PC) which is used broadly for engineering polymer, as it has excellent mechanical and thermal properties compared to other polymers, was studied for creep characteristic at various level of stresses and temperatures. From the experimental results, the creep limit of PC at room temperature is 85 % of tensile strength. which is higher than PE (75%)at room temperature. Also the creep limits decreased exponentially as the temperatures increased, up to 50 % of the melting point($267^{\circ}C$). Also the first and third stage among the three creep stages was non-existent nor was there any rupture failure which occurred for many metals.

• 한국정밀공학회지
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• 제28권12호
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• pp.1403-1410
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• 2011

Creep characteristic is an important failure mechanism when evaluating engineering materials that are soft material as polymers or used as mechanical elements at high temperatures. One of the popular thermo-elastic polymers, Polymethyl methacrylate(PMMA) which is used broadly for engineering polymer, as it has excellent mechanical and thermal properties compared to other polymers, was studied for creep characteristic at various level of stresses and temperatures. From the experimental results, the creep limit of PMMA at room temperature is 85 % of tensile strength. which is higher than that of PE (75%)at room temperature. Also the creep limits decreased to nil linearly as the temperatures increased, up to $120^{\circ}C$ of the melting point($267^{\circ}C$). Also the first and third stage among the three creep stages were non-existent nor were there any rupture failure which occurred for many metals at high temperatures.

• 한국정밀공학회지
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• 제29권10호
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• pp.1137-1143
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• 2012

Creep characteristic is an important failure mechanism when evaluating engineering materials that are soft material as polymers or used as mechanical elements at high temperatures. One of the popular thermo-plastic polymers, Acrylonitrile Butadiene Styrene (ABS) which is used broadly for machine elements material, as it has excellent mechanical properties such as impact resistance, toughness and stiffness compared to other polymers, was studied for creep characteristic at different levels of stress and temperatures. From the experimental results, the creep limit of ABS at room temperature is 80 % of tensile strength which is higher than PE and lower than PC or PMMA. Also the creep limits decreased to linearly as the temperatures increased, up to $80^{\circ}C$ which is the softening temperature of Butadiene ($82^{\circ}C$). Also the secondary stage of creep among the three creep stages for different levels of stress and temperature was non-existent which occurred for many metals by strain hardening effect.

• 콘크리트학회논문집
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• 제15권2호
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• pp.280-287
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• 2003

산업폐기물 중 하나인 굴패각(Oyster Shell, OS)에 대한 건설재료로써의 활용성을 검토하기 위해 굴패각을 혼합한 콘크리트의 장기역학적 특성과 내구성을 실험적으로 평가하였다. 실험결과에 따르면 굴패각을 10% 대체한 콘크리트의 장기강도는 굴패각을 대체하지 않은 콘크리트와 유사한 결과를 보였으나, 굴패각을 20% 대체한 콘크리트의 장기강도는 감소하는 것을 보였다. 즉, 일정 한도 이상의 굴패각 대체는 콘크리트의 장기재령 강도에 열화요인으로 작용할 수 있는 것으로 나타났고, 굴패각의 대체에 따른 탄성계수 저하는 대체율에 거의 비례적으로 저하하였으며 굴패각의 대체율 20%에서 약 10∼15% 저하하였다. 굴패각의 대체율이 증가할수록 건조수축 발생량은 증가하였으며 기존의 건조수축과 크리프 모델식은 굴패각의 증가에 따른 영향을 잘 반영하지 못하였고 이에 대한 예측식의 보정이 필요하다. 잔골재의 일부를 굴패각으로 대체하여도 콘크리트의 동결융해 저항성, 탄산화 저항성, 및 화학침식 저항성에는 나쁜 영향을 미치지 않으며, 투수 저항성은 오히려 크게 개선되었다.