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Journal of the Korea Concrete Institute

J Korea Inst. Struct. Maint. Insp.
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  • Korea Citation Index (KCI)

References

1 
AASHTO (2015), Standard method of test for surface resistivity indication of concrete's ability to resist chloride ion penetration, Washigton, DC: AASHTOGoogle Search
2 
Cho, Y.C., Song, Y.S., Kim, K.S. (2011), Investigation and analysis of ground deformation at a coal waste depot in dogye, Journal of Engineering Geology, 21(3), 199-212.DOI
3 
Gao, S., Zhang, S., Guo, L. (2021), Application of coal gangue as a coarse aggregate in green concrete production: A Review, Materials, 14(22), 6803DOI
4 
Hama, S.M., Ali, Z.M., Zayen, H.S., Mahmoud, A.S. (2023), Structural behavior of reinforced concrete incorporating glass waste as coarse aggregate, Journal of Structural Integrity and Maintenance, 8(1), 59-66.DOI
5 
Kim, I.S., Choi, S.Y., Yang, E.I. (2018), Evaluation of durability of concrete substituted heavyweight waste glass as fine aggregate, Construction and Building Materials, 184, 269-277.DOI
6 
Kim, I.S., Choi, Y.S., Choi, S.Y., Yang, E.I. (2019), Evaluation of durability and radiation shielding property of heavyweight filling material for application in radioactive disposal facilities, Annals of Nuclear Energy, 133, 750-761.DOI
7 
Kim, Y.J., Jeong, S.Y., Gang, Y.S. (2025), Basic characteristics analysis of coal refuse for application as concrete aggregates, Journal of the Korean Recycled Construction Resources Institute, 13(2), 125-131.Google Search
8 
Lee, W.G., Song, M.S., Kim, K.N. (2024), Review of using coal refuse as raw materials for calcined clay cement, Journal of the Korean Society for Environmental Technology, 25(6), 363-368.DOI
9 
Li, Y., Liu, S., Guan, X. (2021), Multitechnique investigation of concrete with coal gangue, Construction and Building Materials, 301, 124114DOI
10 
Lim, T.Y., Ku, H.W., Hwang, J.H., Kim, J.H., Kim, J.K. (2011), A study on the fabrication of foamed glass by using refused coal ore and its physical properties, Journal of the Korean Crystal Growth and Crystal Technology, 21(6), 266-273.DOI
11 
NT Build 492 (1999), Concrete, mortar and cement-based repair materials: chloride migration coefficient from non-steady-state migration experiments, Espoo, Finland: NordTestGoogle Search
12 
Yang, I.H., Jeong, S.T., Park, G.W., Choi, G.M. (2024b), Characteristics of concrete using Coal-By-product as fine aggregate, Journal of the Korean Recycled Construction Resources Institute, 12(1), 53-62.Google Search
13 
Yang, Y.S., Kim, B.K., Lee, B.J., Kim, Y.Y. (2024a), Compressive strength and durability of cement mortar mixed with industrial By-products for OPC replacement, Journal of the Korea Institute for Structural Maintenance and Inspection, 28(6), 198-204.Google Search
14 
Yu, L., Xia, J., Xia, Z., Chen, M., Wang, J., Zhang, Y. (2022), Study on the mechanical behavior and micro-mechanism of concrete with coal gangue fine and coarse aggregate, Construction and Building Materials, 338, 127626DOI
15 
Zhang, T., Wen, Q., Gao, S., Tang, J. (2023), Comparative study on mechanical and environmental properties of coal gangue sand concrete, Construction and Building Materials, 400, 132646DOI
16 
Zhang, T., Wang, H., Tang, J.P., Gao, S. (2024), Mechanical and environmental performance of structural concrete with coal gangue fine aggregate, Journal of Building Engineering, 84, 108488DOI
17 
Zhou, M., Dou, Y., Zhang, Y.Z., Zhang, Y.Q., Zhang, B. (2019), Effects of the variety and content of coal gangue coarse aggregate on the mechanical properties of concrete, Construction and Building Materials, 220, 386-395.DOI