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Research Article

Enhancing the thermal properties of cement composites through substitution of the fine aggregate using metallic material

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Article: 2144311 | Received 19 Jul 2022, Accepted 31 Oct 2022, Published online: 15 Nov 2022

Reference

  • Asadi, I., et al., 2018. Thermal conductivity of concrete – a review. Journal of Building Engineering, 20, 81–93.
  • A.S.O.T., 2015. Materials, standard specification for Portland cement, ASTM C150. American Society of Testing Materials, United States of America.
  • Astm, C., 2001. 1437, standard test method for flow of hydraulic cement mortar. West Conshohocken, PA: American Society for Testing and Materials (ASTM) International.
  • ASTM, A., 2021. C348-14 standard test method for flexural strength of hydraulic-cement mortars. West Conshohocken: ASTM Int.
  • Baghban, M.H., Hovde, P.J., and Jacobsen, S., 2013. Analytical and experimental study on thermal conductivity of hardened cement pastes. Materials and Structures, 46 (9), 1537–1546.
  • Besheli, A.E., et al., 2021. Improving concrete pavement performance in relation to combined effects of freeze–thaw cycles and de-icing salt. Construction and Building Materials, 277, 122273.
  • Bowling, R.A., 1988. A theoretical review of particle adhesion. Particles on Surfaces, 1, 129–142.
  • Camões, A., et al., 2005. Estimating compressive strength of concrete by mortar testing.
  • Chougan, M., et al., 2020. High performance cementitious nanocomposites: The effectiveness of nano-graphite (nG). Construction and Building Materials, 259, 119687.
  • Cui, X., et al., 2017. Mechanical, thermal and electromagnetic properties of nanographite platelets modified cementitious composites. Composites Part A: Applied Science and Manufacturing, 93, 49–58.
  • Feng, J., and Yin, G., 2019. Thermal analyses and responses of bridge deck hydronic snow melting system. Advances in Civil Engineering, 2019, 1–15.
  • Habibzadeh-Bigdarvish, O., et al., 2021. A novel full-scale external geothermal heating system for bridge deck de-icing. Applied Thermal Engineering, 185, 116365.
  • Haigh, S., 2012. Thermal conductivity of sands. Géotechnique, 62 (7), 617–625.
  • Jeon, I.K., et al., 2020. Investigation of sulfuric acid attack upon cement mortars containing silicon carbide powder. Powder Technology, 359, 181–189.
  • Jing, G., et al., 2020. Introducing reduced graphene oxide to enhance the thermal properties of cement composites. Cement and Concrete Composites, 109, 103559.
  • Jittabut, P., 2015. Effect of nanosilica on mechanical and thermal properties of cement composites for thermal energy storage materials. Energy Procedia, 79, 10–17.
  • Kabir, N., et al., 2019. Characteristics of different type of coarse aggregate on properties of high performance concrete. SSM, 2, 88–96.
  • Lee, J.S., and Rhee, I., 2019. Functional properties of a pitch-based carbon fiber–mortar composite as a thin overlay for concrete pavement. Materials, 12 (17), 2753.
  • Li, K., et al., 2015. Comparison of geothermal with solar and wind power generation systems. Renewable and Sustainable Energy Reviews, 42, 1464–1474.
  • Li, H., Zhang, Q., and Xiao, H., 2013. Self-deicing road system with a CNFP high-efficiency thermal source and MWCNT/cement-based high-thermal conductive composites. Cold Regions Science and Technology, 86, 22–35.
  • Liu, C., et al., 2020. Multi-scale modelling of thermal conductivity of phase change material/recycled cement paste incorporated cement-based composite material. Materials & Design, 191, 108646.
  • Malin, F., Norros, I., and Innamaa, S., 2019. Accident risk of road and weather conditions on different road types. Accident Analysis & Prevention, 122, 181–188.
  • Moosberg-Bustnes, H., Lagerblad, B., and Forssberg, E., 2004. The function of fillers in concrete. Materials and Structures, 37 (2), 74–81.
  • Nam, J.-H., 2015. Standard specification for road construction- chapter 10 revised cement concrete pavement work (draft). Journal of the Korean Road Association: Road, 17 (1), 32–38.
  • Nuijten, A.D., and Høyland, K.V., 2017. Modelling the thermal conductivity of a melting snow layer on a heated pavement. Cold Regions Science and Technology, 140, 20–29.
  • Park, R., and Paulay, T., 1991. Reinforced concrete structures. Canada: John Wiley & Sons.
  • Qin, Y., et al., 2021. Study of the effects of fine coral powder and salinity on the mechanical behaviour of coral sand-seawater cement mortar. Construction and Building Materials, 313, 125476.
  • Rainwater, K.A., et al., 2021. Side-by-side field comparison of snow and ice control chemicals for anti-icing applications. Cold Regions Science and Technology, 184, 103230.
  • Shrivastava, M., et al., 2022. Assessment of hydration behaviour of Portland cement-based materials containing brick powders as partial replacement for fine aggregates. Materials Today: Proceedings, 65, 1095–1104.
  • Song, X., et al., 2019. Study on thermal conductivity of cement with thermal conductive materials in geothermal well. Geothermics, 81, 1–11.
  • Soroka, I., and Setter, N., 1977. The effect of fillers on strength of cement mortars. Cement and Concrete Research, 7 (4), 449–456.
  • Standard, A., 2008. ASTM C109-standard test method for compressive strength of hydraulic cement mortars. West Conshohocken, PA: ASTM International.
  • Stolarska, A., and Strzałkowski, J., 2020. The thermal parameters of mortars based on different cement type and W/C ratios. Materials, 13 (19), 4258.
  • Sun, J., et al., 2021. The effect of graphite and slag on electrical and mechanical properties of electrically conductive cementitious composites. Construction and Building Materials, 281, 122606.
  • Vitali, D., et al., 2016. A new model concrete for reduced-scale model tests of energy geo-structures. Geo-Chicago, 2019, 185–194.
  • Wan, J., et al., 2019. Enhanced ice and snow melting efficiency of steel slag based ultra-thin friction courses with steel fiber. Journal of Cleaner Production, 236, 117613.
  • Woo, B.H., et al., 2020. An experimental and statistical study on rebar corrosion considering the temperature effect using Gaussian process regression. Applied Sciences, 10 (17), 5937.
  • Woo, B.H., et al., 2021a. Ice-Melting performance assessment of cement composites using silicon carbide as fine aggregate. Applied Thermal Engineering, 117113.
  • Woo, B.-H., et al., 2021b. Effects of thermal conductive materials on the freeze-thaw resistance of concrete. Materials, 14 (15), 4063.
  • Zhai, S., et al., 2021. Investigation on preparation and multifunctionality of reduced graphene oxide cement mortar. Construction and Building Materials, 275, 122119.
  • Zhao, W., et al., 2020. Snow melting on the road surface driven by a geothermal system in the severely cold region of China. Sustainable Energy Technologies and Assessments, 40, 100781.

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