Asphalt concrete, which is used as a road base material, accounts for >90% of a road pavement. A huge amount of waste concrete and waste asphalt concrete aggregates are generated. Recently, carbon neutrality is promoted across all industries for sustainability. Therefore, to achieve carbon neutrality in the asphalt concrete industry, waste asphalt concrete aggregates should be recycled. Additionally, road base materials are prepared using additives to ensure structural stability, durability, and economic efficiency. In this study, recycled asphalt concrete aggregates were used to evaluate the physical properties of road base materials according to the type of polymer additive and mixing method, and the applicability of road base each material was evaluated. Results showed that when the acrylate-based polymer additive was mixed, the uniaxial compressive strength was 30% higher. Furthermore, the compressive strength of the split mix was improved by ~29% compared to the total mix.

The asphalt concrete industry, accounting for >90% of road pavement, is a crucial contributor to construction waste. This study focuses on the recycling of asphalt concrete recycled aggregates, which currently exhibits a low rate. We investigated the application of these aggregates, combined with hardener and mixing water, in the development of ecofriendly road base materials using circular aggregates. Results revealed that the 13-mm asphalt concrete recycled aggregates met all quality standards. However, the 25-mm aggregates did not conform to the reclaimed asphalt content standard; however, they met other quality standards. Moreover, the experimental results for the hardener and mixing water indicated compliance with all quality standards.

초고성능 콘크리트(UHPC)는 낮은 물-결합재비(W/B), 고성능 감수제(SP), 혼화재 및 강섬유(Steel Fiber)의 혼입으로 일반 콘크리트보다 유동성, 강도 등에서 월등히 우수한 성능을 지닌 건설 재료이다. 본 연구에서는 진동밀로 분쇄하여 시멘트의 분말도를 6000cm2/g급 까지 높여 최적의 초고성능 모르타르를 제작하였다. 또한, UHPC의 특성상 시멘트, 혼화재뿐만 아니라 화학 혼화제 혼입량에 따라 물성에 많은 차이를 나타내기 때문에 최적의 화학 혼화제를 도출하기 위하여 고성능 혼화제에 따른 물성 평가 실험도 수행하였다. 분쇄된 시멘트를 활용한 초고성능 모르타르의 유동성, 강도 등 물성 테스트를 진행하였으며, 경제성을 고려하여 강섬유와 기타 혼화재를 혼입하지 않고 목표 물성을 달성하고자 하였다. 실험결과, 모든배합에서 플로우 값은 목표치 180±10mm를 확보하였으며, W/B 20%, SP 0.8%에서 최대 압축강도 90MPa, 휨강도 16.8MPa까지 나타났다.

Reaction degree of ground granulated blast furnace slag(GGBFS) in cement paste was measured by water-binder ratio and GGBFS replacement ratio, curing temperature with ages using selective dissolution. In result of experimental, when water-binder ratio and curing temperature were high and replace ratio of GGBFS was low, reaction degree was estimated high.

These researchers are studying on the hydration model suggestion of cement incorporating blast furnace slag in durability prediction of concrete using hydration model. So in this study it measured hydration heat according to replace ratio, water cement ratio using conduction calorimeter to acquire experiment data for experimental verification and verify hydration heat property when blast furnace slag is incorporated.

철근이 부식되면 오염된 콘크리트를 제거하고 철근방식을 하고 보수하는 방법과 방청제를 도포하는 방법으로는 철근위치에서 방청성능을 확보하기가 곤란한 실정이다. 이에 본 연구에서는 철근위치까지 방청제를 고압 침투시키기 위한 연구개발에 앞서 방청제 가압 침투 실험을 통하여 침투깊이를 측정하고 위치별 아질산이온의 양을 측정하여 물시멘트비, 압력, 가압시간에 따른 침투깊이 예측하고 우수한 방청성을 가지는 염화물이온과 아질산이온의 몰비 0.6 이상이 되는 물시멘트비와 압력, 가압시간을 산정하였다. 실험결과 물시멘트비가 방청제의 침투에 가장 큰 영향을 주며 또한 실험체의 깊이가 깊어질수록 침투시킨 방청제의 농도는 같지 않고 낮아지는 것을 알 수 있었다.