Mobile QR Code QR CODE

Journal of the Korea Concrete Institute

ISO Journal TitleJ Korea Concr Inst.
  • SCOPUS
  • KCI Accredited Journal

Journal Search

  1. Home
  2. All Issues
  3. 2024-08 (Vol.36 No.4)
  4. 10.4334/JKCI.2024.36.4.317
Export citation EndNote
XML PDF INFO REF

References

1 
Ahmed Ali, K., Ahmad, M. I., and Yusup, Y. (2020) Issues, Impacts, and Mitigations of Carbon Dioxide Emissions in the Building Sector. Sustainability 12(18), 7427.DOI
2 
Alhorr, Y., Eliskandarani, E., and Elsarrag, E. (2014) Approaches to Reducing Carbon Dioxide Emissions in the Built Environment: Low Carbon Cities. International Journal of Sustainable Built Environment 3(2), 167-178.DOI
3 
Apostolopoulos, C. A., and Papadakis, V. (2008) Consequences of Steel Corrosion on the Ductility Properties of Reinforcement Bar. Construction and Building Materials 22(12), 2316-2324.DOI
4 
Azad, A. K., Ahmad, S., and Azher, S. A. (2007) Residual Strength of Corrosion-Damaged Reinforced Concrete Beams. ACI materials journal 104(1), 40.URL
5 
Azad, A., Ahmad, S., and Al-Gohi, B. (2010) Flexural Strength of Corroded Reinforced Concrete Beams. Magazine of Concrete Research 62(6), 405-414.DOI
6 
Belarbi, A., Zhang, L., and Hsu, T. T. (1996) Constitutive Laws of Reinforced Concrete Membrane Elements. In Sociedad Mexicana de Ingenieria Sismica in World Conference on Earthquake Engineering, Mexico 23-28 June 1996. 1-8.URL
7 
Bhargava, K., Ghosh, A., Mori, Y., and Ramanujam, S. (2007) Corrosion-induced Bond Strength Degradation in Reinforced Concrete—Analytical and Empirical Models. Nuclear Engineering and Design 237(11), 1140-1157.DOI
8 
Bosoaga, A., Masek, O., and Oakey, J. E. (2009) CO2 Capture Technologies for Cement Industry. Energy procedia 1(1), 133-140.DOI
9 
Cairns, J., Plizzari, G. A., Du, Y., Law, D. W., and Franzoni, C. (2005) Mechanical Properties of Corrosion-damaged Reinforcement. ACI Materials Journal 102(4), 256.URL
10 
Capé, M. (1999) Residual Service-life Assessment of Existing R/C Structures. Chalmers University of Technology, Goteborg (Sweden) and Milan University of Technology, Italy Erasmus Program.URL
11 
Capozucca, R., and Cerri, M. N. (2003) Influence of Reinforcement Corrosion—in the Compressive Zone—on the Behaviour of RC Beams. Engineering Structures 25(13), 1575-1583.DOI
12 
Chen, H., Ma, X., and Dai, H. (2010) Reuse of Water Purification Sludge as Raw Material in Cement Production. Cement and Concrete Composites 32(6), 436-439.DOI
13 
Choy, K. K. H., Ko, D. C. K., Cheung, W. H., Fung, J. S. C., Hui, D. C. W., Porter, J. F., and Mckay, G. (2004) Municipal Solid Waste Utilization for Integrated Cement Processing with Waste Minimization: a Pilot Scale Proposal. Process Safety and Environmental Protection 82(3), 200-207.DOI
14 
Coronelli, D., and Gambarova, P. (2004) Structural Assessment of Corroded Reinforced Concrete Beams: Modeling Guidelines. Journal of Structural Engineering 130(8), 1214-1224.DOI
15 
Deng, P., Zhang, C., Pei, S., and Jin, Z. (2018) Modeling the Impact of Corrosion on Seismic Performance of Multi-span Simply-supported Bridges. Construction and Building Materials 185, 193-205.DOI
16 
Du, Y., Clark, L. A., and Chan, A. H. (2007) Impact of Reinforcement Corrosion on Ductile Behavior of Reinforced Concrete Beams. ACI Structural Journal 104(3), 285.URL
17 
Du, Y., Clark, L., and Chan, A. (2005a) Effect of Corrosion on Ductility of Reinforcing Bars. Magazine of Concrete Research 57(7), 407-419.DOI
18 
Du, Y., Clark, L., and Chan, A. (2005b) Residual Capacity of Corroded Reinforcing Bars. Magazine of Concrete Research 57(3), 135-147.DOI
19 
González, J., Andrade, C., Alonso, C., and Feliu, S. (1995) Comparison of Rates of General Corrosion and Maximum Pitting Penetration on Concrete Embedded Steel Reinforcement. Cement and Concrete research 25(2), 257-264.DOI
20 
Gorgolewski, M. (2008) Designing with Reused Building Components: Some Challenges. Building Research and Information 36(2), 175-188.DOI
21 
Guo, Y., Trejo, D., and Yim, S. (2015) New Model for Estimating the Time-variant Seismic Performance of Corroding RC Bridge Columns. Journal of Structural Engineering 141(6), 04014158.DOI
22 
Hopkinson, P., Chen, H. M., Zhou, K., Wang, Y., and Lam, D. (2018) Recovery and Reuse of Structural Products from End-of-life Buildings. In Proceedings of the institution of civil Engineers-engineering Sustainability, Thomas Telford Ltd. 119-128.DOI
23 
Hsu, T. T. (1994) Unified Theory of Reinforced Concrete-A Summary. Structural Engineering and Mechanics: An International Journal 2(1), 1-16.URL
24 
Huang, L., Krigsvoll, G., Johansen, F., Liu, Y., and Zhang, X. (2018) Carbon Emission of Global Construction Sector. Renewable and Sustainable Energy Reviews 81, 1906-1916.DOI
25 
IEA (2023) Energy Technology Perspectives 2023. Paris: IEA. https://www.iea.org/reports/energy-technology-perspectives-2023 Accessed 17 April 2024, International Energy Agency (IEA).URL
26 
Imperatore, S., Rinaldi, Z., and Drago, C. (2017) Degradation Relationships for the Mechanical Properties of Corroded Steel Rebars. Construction and Building Materials 148, 219-230.DOI
27 
Jeong, Y. S., Lee, S. E., and Huh, J. H. (2012) Estimation of CO2 Emission of Apartment Buildings due to Major Construction Materials in the Republic of Korea. Energy and Buildings 49, 437-442.DOI
28 
KCI (2022) Durability Design Standard for Concrete Structure (KDS 14 20 40). Sejong, Korea, Ministry of Land, Infrastructure and Transport(MOLIT), Korea Concrete Institute (KCI). (In Korean)URL
29 
Kim, D. H., Lim, N. G., and Lee, S. B. (2002) The Study on Salt Injury and Carbonation of Reinforced-Concrete. Journal of the Korea Institute of Building Construction 2(2), 165-172. (In Korean)DOI
30 
Kim, J. H., Oh, K. C., and Park, S. B. (2008) A Study on Carbonation Velocity for Concrete Structures. Journal of the Korea Institute for Structural Maintenance and Inspection 12(2), 163-170. (In Korean)URL
31 
Kim, J. S., Jung, S. H., Kim, J. H., Lee, K. M., and Bae, S. H. (2006) Probability-Based Durability Analysis of Concrete Structures under Chloride Attack Environments. Journal of the Korea Concrete Institute 18(2), 239-248. (In Korean)DOI
32 
Kwon, S. J., Park, S. S., Nam, S. H., and Cho, H. J. (2007) A Study on Survey of Carbonation for Sound, Cracked, and Joint Concrete in RC Column in Metropolitan City. Journal of the Korea Institute for Structural Maintenance and Inspection 11(3), 116-122. (In Korean)URL
33 
Lee, H. S., and Cho, Y. S. (2009) Evaluation of the Mechanical Properties of Steel Reinforcement Embedded in Concrete Specimen as a Function of the Degree of Reinforcement Corrosion. International Journal of Fracture 157, 81-88.DOI
34 
Lee, H. S., Noguchi, T., and Tomosawa, F. (2002) Evaluation of the Bond Properties between Concrete and Reinforcement as a Function of the Degree of Reinforcement Corrosion. Cement and Concrete Research 32(8), 1313-1318.DOI
35 
Lee, H. W., Yoon, Y. S., Bae, S. C., and Kwon, S. J. (2023) Current Status of Chloride Conctent in Domestic Cement/ Concrete and Recommendations for Related Specifications. Journal of the Korea Concrete Institute 35(5), 495-503. (In Korean)URL
36 
Lee, J. W., Rho, Y. S., and Cho, S. H. (2022) Structural Performance of Recycled Aggregate Concrete Corroded by Accelerated Corrosion. Journal of the Korea Concrete Institute 34(5), 497-504. (In Korean)URL
37 
Li, X. (2008) Recycling and Reuse of Waste Concrete in China: Part I. Material Behaviour of Recycled Aggregate Concrete. Resources, Conservation and Recycling 53(1-2), 36-44.DOI
38 
Marinković, S., Radonjanin, V., Malešev, M., and Ignjatović, I. (2010) Comparative Environmental Assessment of Natural and Recycled Aggregate Concrete. Waste Management 30(11), 2255-2264.DOI
39 
MATLAB (2022) Version: 9.13.0 (R2022b), Natick, Massachusetts: The MathWorks Inc.URL
40 
Molina, F., Alonso, C., and Andrade, C. (1993) Cover Cracking as a Function of Rebar Corrosion: Part 2—Numerical Model. Materials and Structures 26, 532-548.DOI
41 
Niu, Y., Rasi, K., Hughes, M., Halme, M., and Fink, G. (2021) Prolonging Life Cycles of Construction Materials and Combating Climate Change by Cascading: The Case of Reusing Timber in Finland. Resources, Conservation and Recycling 170, 105555.DOI
42 
Oh, D.-Y., Noguchi, T., Kitagaki, R., and Park, W.-J. (2014) CO2 Emission Reduction by Reuse of Building Material Waste in the Japanese Cement Industry. Renewable and Sustainable Energy Reviews 38, 796-810.DOI
43 
Papadakis, V. G., Vayenas, C. G., and Fardis, M. (1989) A Reaction Engineering Approach to the Problem of Concrete Carbonation. AIChE Journal 35(10), 1639-1650.DOI
44 
Pongiglione, M., and Calderini, C. (2014) Material Savings through Structural Steel Reuse: A Case Study in Genoa. Resources, Conservation and Recycling 86, 87-92.DOI
45 
Popovics, S. (1973) A numerical approach to the Complete Stress-strain Curve of Concrete. Cement and Concrete Research 3(5), 583-599.DOI
46 
Puertas, F., García-Díaz, I., Barba, A., Gazulla, M., Palacios, M., Gómez, M., and Martínez-Ramírez, S. (2008) Ceramic Wastes as Alternative Raw Materials for Portland Cement Clinker Production. Cement and Concrete Composites 30(9), 798-805.DOI
47 
Rodriguez, J., Ortega, L., and Casal, J. (1997) Load Carrying Capacity of Concrete Structures with Corroded Reinforcement. Construction and Building Materials 11(4), 239-248.DOI
48 
Shayanfar, M. A., Barkhordari, M. A., and Ghanooni-Bagha, M. (2016) Effect of Longitudinal Rebar Corrosion on the Compressive Strength Reduction of Concrete in Reinforced Concrete Structure. Advances in Structural Engineering 19(6), 897-907.DOI
49 
Sonawane, T. R., and Pimplikar, S. S. (2013) Use of Recycled Aggregate Concrete. IOSR Journal of Mechanical and Civil Engineering 52(59).URL
50 
Syll, A. S., and Kanakubo, T. (2022) Impact of Corrosion on the Bond Strength between Concrete and Rebar: A Systematic Review. Materials 15(19), 7016.DOI
51 
Val, D. V., and Melchers, R. E. (1997) Reliability of Deteriorating RC Slab Bridges. Journal of Structural Engineering 123(12), 1638-1644.DOI
52 
Vecchio, F. J., and Collins, M. P. (1986) The Modified Compression-field Theory for Reinforced Concrete Elements Subjected to Shear. ACI Journal 83(2), 219-231.URL
53 
Vu, K. A. T., and Stewart, M. G. (2000) Structural Reliability of Concrete Bridges Including Improved Chloride-induced Corrosion Models. Structural Safety 22(4), 313-333.DOI
54 
Webster, M. D., and Costello, D. T. (2005) Designing Structural Systems for Deconstruction: How to Extend a New Building’S Useful Life and Prevent It from Going to Waste When the End Finally Comes. In Greenbuild Conference, USA: The US Green Building Council Atlanta, 1-14.URL
55 
Zhang, W., Song, X., Gu, X., and Li, S. (2012) Tensile and Fatigue Behavior of Corroded Rebars. Construction and Building Materials 34, 409-417.DOI