급속공사 현장에 사용되는 속경성 보수모르타르의 내구성능 증진을 위해 사용재료의 물리적 성능을 평가하였다. 이를 위해 염화물 확산 억제 성능을 보유한 페로니켈 수쇄슬래그 잔골재와 급결제, EVA계 폴리머를 모르타르에 치환시켜 급결성능과 기초적 성능을 평가하였다. 그 결과 FNS잔골재 및 RS잔골재 사용에 따른 압축강도, 휨강도, 부착강도가 증가되었다. 속경성 폴리머 모르타르의 염화물 이온 촉진시험의 결과 FNS를 50%이하 사용 시 재령 7일에서 재령 28일간 염화물 억제 성능이 유지되었으며, FNS잔골재 및 RS잔골재 사용에 따른 내구성 저하는 발견되지 않았으나, 건축 및 토목용 대체골재로 사용하는데 경제성 및 장기 내구성에 대한 추가 검토가 필요할 것으로 판단된다.

This study evaluated the fluidity and compressive strength of concrete by replacement ratio of blast furnace slag fine aggregate and ferronickel slag fine aggregate to investigate the possibility of replacing natural fine aggregate with steel slag for fine aggregate. Test results show that the use of steel slag fine aggregate improves the fluidity of concrete and compressive strength of concrete was higher than plain concrete.

In this paper, the mechanical properties of GGBFS concrete according to the replacement ratio of electric arc furnace oxidizing slag fine aggregate was evaluated. As the replacement rate of EOS fine aggregate increased, the amount of slump and air content decreased. In addition, EOS concrete increased the initial compressive strength, but, it tended to decrease at 28 days.

This study investigated the properties of lightweight foamed concrete by using surfactant and synthetic foaming agent, lightweight aggregate. The effects of foaming agent types and replacing ratio of lightweight aggregate on the compressive strength, density and pore structure of the concrete were investigated. This study showed the improvement of important properties of lightweight foamed concrete. Lower pore distribution and correspondingly higher compressive strength values were reached. Also, synthetic foaming agent had more positive effect on the strength of foamed concrete.

This study was conducted examine the mechanical properties of LEFC in relation to the type of light weight aggregate and replacement ratio. For the specimen, different replacement ratio was used for recycled waste ALC and the bottom ash light weight aggregate respectively. The tests revealed that 60% of the waste ALC light weight aggregate is suitable for securing the optimal strength and light weight of the LEFC.

This study was conducted examine the mechanical properties of LEFC in relation to the type of light weight aggregate and replacement ratio. For the specimen, different replacement ratio was used for recycled waste ALC and the bottom ash light weight aggregate respectively. The tests revealed that 60% of the waste ALC light weight aggregate is suitable for securing the optimal strength and light weight of the LEFC.

In construction industry, large scales of construction waste has been produced with consumption of natural resources, but its efficient reutilization has not been sufficient yet. Therefore, this study has a main objective of using high volume of recycled aggregate by investigate the effect of replacement ratio of natural coarse aggregate by recycled one on the strength of concrete.

The use of recycled aggregate has been highly recommended for the environmental protection of nature and absolute shortage of natural aggregate's resource, but experimental methods adequate for each recycled product have not been established and also the data have not been enough to ensure the control of concrete quality. Thus, this study has an aim of applying high volume of recycled aggregate to the fabrication of concrete by investigating that production methods of recycled aggregate and its replacement ratio have effects on the performance of concrete.

This study evaluates the material performance of slump value and compressive strength of the concrete which was made by recycled sand and blast furnace slag powder(BFSP). The main variables are replacement ratio of BFSP. As a result, it was evaluated that more detailed evaluation is needed in long-term strength development and the compensation of slump value to the replacement ratio of BFSP.

So far, various experiments were carried out and published on recycled aggregates. But the structural use of recycled aggregates were very limited. To use a recycled coarse aggregate as structural materials, evaluation of compressive strength and splitting tensile strength were proceed according to replacement ratio of recycled coarse aggregate.

In this study, four reinforced concrete beams, replacing recycled coarse aggregate with PVA fiber(BSPG-R series), were constructed and tested under monotonic loading. Experimental programs were carried out to improve and evaluate the structural performance of such test specimens, such as the load-displacement, the failure mode and the maximum load carrying capacity. all the specimens were modeled in 1/2 scale-down size.

In this study, the experiments were carried out in order that flexural behavior evaluated High-strength Concrete Beams reinfrced with FRP plates according ro replacement ration of recycled aggregate. As a result, maximum load was higher than existiong of unreinforced when the reinforced with FRP plates and no decrease in load about increased fo replacement ration of recycled aggregate. Some specimens was greater than ACI 440-2R referemce value.