A rapid urbanization has increased the portion of paved layer that results in the change of water circulation system. This change leads to frequent events of flooding, drought, and urban heat island. To resolve these issues, permeable pavement system based on Low Impact Development (LID) concept is being applied to international urban areas. Therefore it is necessary to establish a rational design procedure for the permeable pavement system that reflects our environmental conditions. iDue to inherent characteristics of permeable pavement system, water infiltrates thorough the layers so it may reduce the bearing capacity of sub-layers. In this study, an effort was made to investigate the effectiveness of geogrid reinforced crushed stone subbase layer based on field experimental program along with a limited numerical analysis. It reveals that geogrid reinforced sections improve the bearing capacity by close to 20%. In addition, a light weight deflectomenter (LWDT) appears to be promising for the compaction quality control of crushed stone subbase layer in order to construct qualified permeable pavement systems.
본 연구는 고성능콘크리트의 강도조절과 수화열 저감을 위하여 쇄석 쇄사 생산시 발생되는 쇄석미분말을 사용하여 고성능콘리트의 강도, 유동성 내구성능 및 건조수축 특성을 검토한 것이다. 실험결과 쇄석미분말은 치환율 10% 증가시마다 무치환시의 압축강도를 약 10~15%씩 감소시키며, 변형계수와 물구속비를 감소시켜 고성능콘크리트의 유동성 향상에 효과적이다. 또한, 고성능콘크리트에서 쇄식미분말 10% 치환시 마다 단위시멘트량 감소에 따른 최고 단열온도상승량을 약 4℃씩 감소시켰다. 반면 건조수축랑은 10% 치환시마다 약 5% 증가시키는 것으로 나타났다. 한편 고성능콘크리트의 내구성은 단위분체량과 유동성향상에 따른 조직의 치밀화로 쇄석미분말의 치환에 관계없이 상대동탄성계수 100%이상으로 우수하게 나타났다. 이와 같이 문제로서 쇄석미분말의 사용은 치환량에 따른 고성능콘크리트의 강도조절이 가능하며 수차 발열량을 저감시킬 수 있다.
Waste stone sludge generated during the collection of crushed aggregate is difficult to use due to high moisture content. Production of 1 ton aggregate generates approximately 0.25 tons of waste stone sludge. Considering the total crushed aggregate collection in 2012 of about 100 million tons, it can be estimated that 25 million tons of waste stone sludge is generated annually. Recycling of waste stone sludge is made difficult by the high moisture content of 30%. Therefore, to make recycling this process must be a drying process, which makes a fine powder of even better quality that can use as an additive. The purpose of this study is to analyze the changes in physical properties caused by the use of dried waste stone sludge as an additive in the extrusion of cement. A test specimen was made, substituting 50% of the silica with waste stone sludge, and physical performance evaluation was performed. Results showed that 50% substitution of silica resulted in no difference in moldability, but a slight increase in the water content required for the same workability was found. Flexural strength and drying shrinkage were found to be 97% of normal levels, but satisfied the specified performance in the KS F 4735 standard.