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시멘트풀 속에서의 순환굵은골재 부착모르타르의 성상변화에 관한 연구
문대중,최재진,Moon, Dae-Joong,Choi, Jae-Jin 한국건설순환자원학회 2011 한국건설순환자원학회지 Vol.6 No.1
순환굵은골재 콘크리트에서 혼합전의 순환굵은골재에 부착되어 있었던 모르타르의 성상변화를 조사하기 위한 방법으로, 시멘트풀 속에 순환굵은골재를 투입하여 경화시킨 다음 순환굵은골재에 부착된 모르타르의 비캇경도와 공극분포를 검토하였다. 이때 순환굵은골재는 모재콘크리트의 압축강도를 3수준(25.5MPa, 41.7MPa, 60.1MPa)으로 변화시켜 제조한 것을 파쇄시킨 다음 표면건조포화상태 및 절대건조상태에서 사용되었다. 실험결과 순환굵은골재에 부착된 모르타르의 비캇경도는 순환굵은골재의 모재콘크리트의 강도가 클수록 크며, 재령이 증가할수록 크게 되는 것으로 나타났다. 또한, 시멘트풀 속에서 부착모르타르의 공극분포는 $100nm{\sim}10{\mu}m$ 크기의 공극이 감소되며, 6nm~100nm 크기의 작은 공극이 증가하는 것으로 나타났다. Vicker's hardness and pore size distribution of mortar adhered to the recycled coarse aggregate were tested according to the strength level of original concrete of recycled coarse aggregate to find the change of mortar adhered to the recycled coarse aggregate in cement paste. The strength levels of original concrete of recycled coarse aggregate were 25.5MPa, 41.7MPa and 60.1MPa and the aggregates were used at the state of saturated surface dry condition and oven dry condition. The results of this experimentation indicated that the mean value of Vicker's hardness was increased according to age and strength of original concrete of recycled aggregate. Porosity of $100nm{\sim}10{\mu}m$ size was reduced and porosity of 6nm~100nm size was increased in cement paste.
재생(再生)잔골재(骨材)를 프리캐스트 콘크리트용(用) 골재(骨材)로 활용(活用)하기 위한 실험적(實驗的) 연구(硏究)
문대중,문한영,김양배,임남웅,Moon, Dae-Joong,Moon, Han-Young,Kim, Yang-Bae,Lim, Nam-Woong 한국자원리싸이클링학회 2006 資源 리싸이클링 Vol.15 No.2
폐콘크리트 파쇄시 발생하는 재생잔골재의 품질을 검토하였으며, 재생잔골재를 활용한 모르타르의 압축강도, 휨강도 및 흡수율을 검토하였다. 또한, 프리캐스트 콘크리트 제품용 골재로서의 적용성에 대하여 평가하였다. 재생잔골재의 밀도 및 흡수율은 각각 $2.31\;g/cm^3$ 및 8.07%로 KS F 2573의 2종에 해당되는 품질이었다. 혼합시멘트 MRS1, MRS2 및 MRS3 사용 모르타르의 재령 28일 압축강도는 물-시멘트비 35%, 양생온도 $40^{\circ}C$의 조건에서 각각 15.8, 27.4 및 48.7MPa로 최대값을 발현하였다. 모르타르의 최대휨강도는 혼합시멘트 MRS1 및 MRS2 사용시 물-시멘트비 35.0%, 양생온도 $40^{\circ}C$, 혼합시멘트 MRS3사용시 물-시멘트비 37.5%, 양생온도 $40^{\circ}C$의 조건에서 발현하였다. 혼합시멘트 MRS1, MRS2 및 MRS3를 사용한 모르타르의 흡수율의 범위는 각각 $8.3{\sim}7.3%,\;6.5{\sim}8.5%$ 및 $3.5{\sim}6%$의 범위로 나타났다. 그러므로 혼합시멘트와 재생잔골재의 비율을 적절히 조절함으로써 MRS1는 저강도용, MRS2는 보통강도용, MRS3는 고강도용으로 다양한 프리캐스트 콘크리트 제품에 적용될 수 있을 것으로 기대된다. The duality of recycled fine aggregate (RS) which was produced at the waste concrete crushing was investigated. The compressive strength, flexural strength and absorption of mortar utilized with RS were examined. It was evaluated on the application of RS as precast concrete aggregate. The density and absorption of RS were $2.31g/cm^3$ and 8.07% respectively, the quality of RS was satisfied with the criterion of KS F 2573 type 2. The maximum 28days compressive strength of mortar mixed with blended cement MRS1, MRS2 and MRS3 were developed with 15.8, 27.4 and 48.7MPa respectively, in condition to curing temperature $40^{\circ}C$ and water-cement ratio 37.5%. When blended cement MRS1 and MRS2 were used, the maximum flexural strength of mortar was developed at curing temperature $40^{\circ}C$ and water-cement ratio 35.0%. When blended cement MRS3 was used, the maximum flexural strength of mortar was developed at curing temperature $40^{\circ}C$ and water-cement ratio 37.5%. The absorption of mortar mixed with blended cement MRS1, MRS2 and MRS3 were indicated the range of $8.3{\sim}7.3%,\;6.5{\sim}8.5%$ and $3.5{\sim}6%$ respectively. Therefore, when the ratio of blended cement and RS is appropriately centre]led, it would be expected that MRS1, MRS2 and MRS3 will be able to apply the variable low strength, medium strength and high strength precaste concrete.
문대중,문한영,김양배 한국콘크리트학회 2004 콘크리트학회논문집 Vol.16 No.6
The quality of recycled aggregate is affected by original concrete strength and the manufacturing process of recycled aggregates. In this study, the porosity of old and new mortar, and the compressive strength of concrete were investigated to examine the influence of recycled aggregate on the concrete. Six kinds of recycled coarse aggregates were produced from concrete blocks of differing strength levels (A:60.1MPa, B:41.7MPa, C:25.5MPa).Original concrete strength and the bond mortar of recycled aggregate influences the pore structures of both old and new mortar. The pore size distribution of old mortar was found to be greatly affected by age, and the reduction of the porosity of bond mortar on low strength recycled aggregate increased at a greater rate than that of bond mortar on high strength recycled aggregate. The pore size distribution of new mortar in recycled aggregate concrete changed in comparison with that of new mortar in virgin aggregate concrete. The total porosity of new mortar using B level recycled aggregates was smaller than that of new mortar with A, and C level recycled aggregates. Moreover, the compressive strength of recycled aggregate concrete was found to have been affected by original concrete strength. The compressive strength of concrete only changed slightly in the porosity of new mortar over 15%, but increased rapidly in the porosity of new mortar fewer than 15%.