Evaluation on the Mechanical Performance of Low-Quality Recycled Aggregate Through Interface Enhancement Between Cement Matrix and Coarse Aggregate by Surface Modification Technology |
Choi, Heesup
(Kitami Institute of Technology)
Choi, Hyeonggil (Muroran Institute of Technology) Lim, Myungkwan (Hankyong National University) Inoue, Masumi (Kitami Institute of Technology) Kitagaki, Ryoma (The University of Tokyo) Noguchi, Takafumi (The University of Tokyo) |
1 | Choi, H. S., Kitagaki, R., & Noguchi, T. (2012). A study on the completely recovery of surface modification aggregate using microwave and effective utilization. In Proceedings of the 5th ACF international conference, Pattaya, Thailand, October 2012, Session 1-2, ACF2012-0093 (pp. 41-46). |
2 | Choi, H. S., Kitagaki, R., & Noguchi, T. (2014a). Effective recycling of surface modification aggregate using microwave heating. Journal of Advanced Concrete Technology, 12, 34-45. DOI |
3 | Choi, H. S., Kitagaki, R., & Noguchi, T. (2014b). Using microwave heating to completely recycle concrete. Journal of Environmental Protection, 5, 583-596. DOI |
4 | Hendriks, C. H. F., & Janssen, G. M. T. (2001). Construction and demolition waste-General process. HERON, 46, 79-88. |
5 | Hilsdorf, H. K., & Kropp, J. (1995). Performance criteria for durability, RILEM Report 12, London, UK, pp. 166-178. |
6 | Jacobsen, S. (1996). Effect of cracking and healing on chloride transport in OPC concrete. Cement and Concrete Research, 26(6), 869-881. DOI |
7 | Khatri, R. P., & Sirivivatnanon, V. (1997). Role of permeability in sulfate attack. Cement and Concrete Research, 27(8), 1179-1189. DOI |
8 | Kumar Mehta, P., & Moneiro, P. J. M. (2006). Concrete-Microstructure, Properties and Materials. New York, NY: McGraw-Hill Companies. |
9 | Nagataki, S., Gokce, A., & Saeki, T. (2000). Effects of recycled aggregate characteristics on performance parameters of recycled aggregate concrete. American Concrete Institute, ACI Special Publication, 52, 462-467. |
10 | Noguchi, T. (2008). Resource recycling in concrete: Present and future. Stock Management for Sustainable Urban Regeneration, 4, 255-274. |
11 | Noguchi, T., & Tamura, M. (2001). Concrete design towards complete recycling. Structural Concrete Journal of the fib, 2, 155-167. DOI |
12 | Tsujino, M., Noguchi, T., Kitagaki, R., & Nagai, H. (2010). Completely recyclable concrete of aggregate-recovery type by a new technique using aggregate coating. Architectural Institute of Japan, 75(647), 17-24. (in Japanese). |
13 | Shima, H., Tateyashiki, H., Matsuhashi, R., & Yoshida, Y. (2005). An advanced concrete recycling technology and its applicability assessment through input-output analysis. Journal of Advanced Concrete Technology, 3, 53-67. DOI |
14 | Tazawa, E. (2002). Concrete engineering (p. 127). Tokyo, Japan: Asakura Publication. |
15 | Tsujino, M., Noguchi, T., Tamura, M., Kanematsu, M., & Maruyama, I. (2007). Application of conventionally recycled coarse aggregate to concrete structure by surface modification treatment. Journal of Advanced Concrete Technology, 5, 13-25. doi:10.3151/jact.5.13. DOI |
16 | Tsujino, M., Noguchi, T., Kitagaki, R., & Nagai, H. (2011). Completely recyclable concrete of aggregate-recovery type by using microwave heating. Architectural Institute of Japan, 76(660), 223-229. (in Japanese). |
17 | Xiao, J. (2013). Properties of interfacial transition zones in recycled aggregate concrete tested by nanoindentation. Cement and Concrete Research, 37(3), 276-292. DOI |
18 | Um, T. S., & Choi, S. H. (1997). The effect of the mineralogical features of aggregates in the bonding force and workability of the concrete. Journal of the Korea Concrete Institute, 9(5), 207-216. (in Korean). |
19 | Wang, K., Jansen, D. C., & Shah, S. P. (1997). Permeability study of cracked concrete. Cement and Concrete Research, 27(3), 381-393. DOI |