Browse > Article
http://dx.doi.org/10.14190/JRCR.2020.8.2.219

A Sustainable and Viable Method to Recycle Oyster Shell Waste as an Alternative of Limestone in Limestone Calcined Clay Cement (LC3)  

Her, Sung-Wun (Department of Architectural Engineering, Hanyang University)
Suh, Heong-Won (Department of Architectural Engineering, Hanyang University)
Park, Jae-Yeon (Department of Architectural Engineering, Hanyang University)
Im, Su-Min (Department of Architectural Engineering, Hanyang University)
Bae, Sung-Chul (Department of Architectural Engineering, Hanyang University)
Publication Information
Journal of the Korean Recycled Construction Resources Institute / v.8, no.2, 2020 , pp. 219-226 More about this Journal
Abstract
Over the last decades, great efforts have been devoted to reuse industrial wastes and by-products from various industries as supplementary cementitious materials in order to reduce carbon dioxide(CO2) emission by reducing the use of Portland cement in construction. Oyster shell waste, originating from the fishery industry, is available in huge quantities in certain areas, and is generally discarded or landfilled. In this study, we aimed to reuse oyster shell as an alternative to limestone in limestone calcined clay cement(LC3). The oyster shell calcined clay cement(OC3) paste were produced and were characterized via X-ray diffraction, isothermal calorimetry, compressive strength tests, and thermogravimetry. The results revealed that OC3 pastes exhibited similar strength development and reactivities by pozzolanic reaction with LC3, which implies that oyster shell could be used as a substitute for limestone in LC3.
Keywords
Oyster shell; Limestone; Calcined clay; Pozzolanic reaction; Supplementary cementitious materials;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Antoni, M., Rossen, J., Martirena, F., Scrivener, K. (2012). Cement substitution by a combination of metakaolin and limestone, Cement and Concrete Research, 42(12), 1579-1589.   DOI
2 Avet, F., Boehm-Courjault, E., Scrivener, K. (2019). Investigation of C-A-S-H composition, morphology and density in limestone calcined clay cement($LC^3$), Cement and Concrete Research, 115, 70-79.   DOI
3 Avet, F., Scrivener, K. (2018). Investigation of the calcined kaolinite content on the hydration of limestone calcined clay cement($LC^3$), Cement and Concrete Research, 107, 124-135.   DOI
4 Bullard, J.W., Jennings, H.M., Livingston, R.A., Nonat, A., Scherer, G.W., Schweitzer, J.S., Scrivener, K.L., Thomas, J.J. (2011). Mechanisms of cement hydration, Cement and Concrete Research, 41(12), 1208-1223.   DOI
5 Liang, C.F., Wang, H.Y. (2013). Feasibility of pulverized oyster shell as a cementing material, Advanced in Materials Science and Engineering, 809247.
6 Ferreiro, S., Canut, M.M.C., Lund, J., Herfort, D. (2019). Influence of fineness of raw clay and calcination temperature on the performance of calcined clay-limestone blended cements, Applied Clay Science, 169, 81-90.   DOI
7 Her, S., Park, D., Bae, S. (2018). "A study on feasibility of clinker manufacture using oyster shell as limestone substitute," Proceedings of the Korea Concrete Institute, 30(1), 405-406. [in Korean]
8 Lertwattanaruk, P., Makul, N., Siripattarapravat, C. (2012). Utilization of ground waste seashells in cement mortars for masonry and plastering, Journal of Environmental Management, 111, 133-141.   DOI
9 Maraghechi, H., Avet, F., Wong, H., Kamyab, H., Scrivener, K. (2018). Performance of limestone calcined clay cement($LC^3$) with various kaolinite contents with respect to chloride transport, Materials and Structures, 51(5), 125.   DOI
10 Mo, K.H., Alengaram, U.J., Jumaat, M.Z., Lee, S.C., Goh, W.L., Yuen, C.W. (2018). Recycling of seashell waste in concrete: A review, Construction and Building Materials, 162, 751-764.   DOI
11 Song, H., Jeong, Y., Bae, S., Jun, Y., Yoon, S., Oh, J.E. (2018). A study of thermal decomposition of phases in cementitious systems using HT-XRD and TG, Construction and Building Materials, 169, 648-661.   DOI
12 Moon, G., Oh, S., Jung, S., Choi, Y. (2017). Effect of the fineness of limestone powder and cement on the hydration and strength development of PLC concrete, Construction and Building Materials, 135(15), 129-136.   DOI
13 Schneider, M. (2015). Process technology for efficient and sustainable cement production, Cement and Concrete Research, 78, 14-23.   DOI
14 Schneider, M., Romer, M., Tschudin, M., Bolio, H. (2011). Sustainable cement production-present and future, Cement and Concrete Research, 41(7), 642-650.   DOI
15 Scrivener, K., Martirena, F., Bishnoi, S., Maity, S. (2018). Calcined clay limestone cements($LC^3$), Cement and Concrete Research, 114, 49-56.   DOI
16 Shah, V., Joseph, A.M., Bishnoi, S. (2015). Durability characteristics of sustainable low clinker cements: A review, Calcined Clays for Sustainable Concrete, Springer, 523-530.
17 Sung, C., Kim, Y. (2010). Strength and durability properties of polymer concrete utilizing oyster shell powder as a filler, Journal of the Korean Society of Agricultural Engineers, 52(6), 125-134.   DOI
18 Yoon, G., Kim, B., Kim, B., Han, S. (2003). Chemical-mechanical characteristics of crushed oyster-shell, Waste Management, 23(9), 825-834.   DOI
19 Scrivener, K., Avet, F., Maraghechi, H., Zunino, F., Ston, J., Hanpongpun, W. (2019). Impacting factors and properties of limestone calcined clay cements($LC^3$), Green Materials, 7(1), 3-14.   DOI