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NTIS 바로가기Advances in civil engineering, v.2019, 2019년, pp.1 - 9
Kwon, Seung-Jun (Department of Civil and Environmental Engineering, Hannam University, Daejeon-Si, Republic of Korea) , Wang, Xiao-Yong (Department of Architectural Engineering, Kangwon National University, Chuncheon-Si, Republic of Korea)
As abundant CO2 is released by high-strength concrete due to its high binder content, the reduction of CO2 emissions has become increasingly important. This study proposed a general procedure to optimize the mixture design of low-CO2 high-strength concrete containing silica fume. First, the equation...
Papadakis, Vagelis G. Effect of supplementary cementing materials on concrete resistance against carbonation and chloride ingress. Cement and concrete research, vol.30, no.2, 291-299.
Concrete International 23 61 2001
Larsen, Ingrid Lande, Granseth Aasbakken, Ida, O’Born, Reyn, Vertes, Katalin, Thorstensen, Rein Terje. Determining the Environmental Benefits of Ultra High Performance Concrete as a Bridge Construction Material. IOP conference series. Materials science and engineering, vol.245, 052096-.
Voo, Yen Lei, Foster, Stephen J.. Characteristics of ultra-high performance ‘ductile’ concrete and its impact on sustainable construction. The IES journal. Part A, Civil and structural engineering, vol.3, no.3, 168-187.
Yu, R., Spiesz, P., Brouwers, H.J.H.. Development of an eco-friendly Ultra-High Performance Concrete (UHPC) with efficient cement and mineral admixtures uses. Cement & concrete composites, vol.55, 383-394.
Park, Junghoon, Tae, Sungho, Kim, Taehyung. Life cycle CO2 assessment of concrete by compressive strength on construction site in Korea. Renewable & sustainable energy reviews, vol.16, no.5, 2940-2946.
Kim, Tae, Chae, Chang, Kim, Gil, Jang, Hyoung. Analysis of CO2 Emission Characteristics of Concrete Used at Construction Sites. Sustainability, vol.8, no.4, 348-.
Latawiec, Rafal, Woyciechowski, Piotr, Kowalski, Karol. Sustainable Concrete Performance-CO2-Emission. Environments, vol.5, no.2, 27-.
Yeh, I.C.. Computer-aided design for optimum concrete mixtures. Cement & concrete composites, vol.29, no.3, 193-202.
Mosaberpanah, Mohammad Ali, Eren, Ozgur. CO2-full factorial optimization of an ultra-high performance concrete mix design. European journal of environmental and civil engineering = Revue Européenne de génie civil, vol.22, no.4, 450-463.
Yang, Keun-Hyeok, Tae, Sung-Ho, Choi, Dong-Uk. Mixture Proportioning Approach for Low-CO2Concrete Using Supplementary Cementitious Materials. ACI materials journal, vol.113, no.4,
Tapali, Julia G., Demis, Sotiris, Papadakis, Vagelis G.. Sustainable concrete mix design for a target strength and service life. Computers & concrete, vol.12, no.6, 755-774.
Khan, Asaduzzaman, Do, Jeongyun, Kim, Dookie. Cost effective optimal mix proportioning of high strength self compacting concrete using response surface methodology. Computers & concrete, vol.17, no.5, 629-638.
Ji, Tao, Yang, Yu, Fu, Mao-yuan, Chen, Bao-chun, Wu, Hwai-Chung. Optimum Design of Reactive Powder Concrete Mixture Proportion Based on Artificial Neural and Harmony Search Algorithm. ACI materials journal, vol.114, no.1,
Lee, Han-Seung, Wang, Xiao-Yong. Evaluation of the Carbon Dioxide Uptake of Slag-Blended Concrete Structures, Considering the Effect of Carbonation. Sustainability, vol.8, no.4, 312-.
Lim, Chul-Hyun, Yoon, Young-Soo, Kim, Joong-Hoon. Genetic algorithm in mix proportioning of high-performance concrete. Cement and concrete research, vol.34, no.3, 409-420.
Wu, Z., Shi, C., Khayat, K.H., Wan, S.. Effects of different nanomaterials on hardening and performance of ultra-high strength concrete (UHSC). Cement & concrete composites, vol.70, 24-34.
Shi, C., Wang, D., Wu, L., Wu, Z.. The hydration and microstructure of ultra high-strength concrete with cement-silica fume-slag binder. Cement & concrete composites, vol.61, 44-52.
DeRousseau, M.A., Kasprzyk, J.R., Srubar III, W.V.. Computational design optimization of concrete mixtures: A review. Cement and concrete research, vol.109, 42-53.
Yepes, V., Marti, J.V., Garcia-Segura, T., Gonzalez-Vidosa, F.. Heuristics in optimal detailed design of precast road bridges. Archives of Civil and Mechanical Engineering, vol.17, no.4, 738-749.
Behnood, Ali, Behnood, Venous, Modiri Gharehveran, Mahsa, Alyamac, Kursat Esat. Prediction of the compressive strength of normal and high-performance concretes using M5P model tree algorithm. Construction & building materials, vol.142, 199-207.
Duan, Z.H., Kou, S.C., Poon, C.S.. Prediction of compressive strength of recycled aggregate concrete using artificial neural networks. Construction & building materials, vol.40, 1200-1206.
Mechtcherine, V., Shyshko, S.. Simulating the behaviour of fresh concrete with the Distinct Element Method - Deriving model parameters related to the yield stress. Cement & concrete composites, vol.55, 81-90.
Chou, J.S., Tsai, C.F., Pham, A.D., Lu, Y.H.. Machine learning in concrete strength simulations: Multi-nation data analytics. Construction & building materials, vol.73, 771-780.
Wang, Xiao-Yong, Luan, Yao. Modeling of Hydration, Strength Development, and Optimum Combinations of Cement-Slag-Limestone Ternary Concrete. International journal of concrete structures and materials, vol.12, no.1, 12-.
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