Effect of Steel Fibers on Compressive Strength of Recycled Aggregate Concrete

Abdulla, N. A. (2015). Effect of recycled coarse aggregate type on concrete. Journal of Materials in Civil Engineering, 27(10), 04014273. Search in Google Scholar

Ahmad, J., Martínez-García, R., Szelag, M., de-Prado-Gil, J., Marzouki, R., Alqurashi, M., & Hussein, E. E. (2021). Effects of Steel Fibers (SF) and Ground Granulated Blast Furnace Slag (GGBS) on Recycled Aggregate Concrete. Materials, 14(24), 7497. Search in Google Scholar

Al-Luhybi, A. S. (2019). Mechanical Properties of Recycled Aggregate Concrete with Steel Fiber: A Review. Tikrit Journal of Engineering Sciences, 26(3), 37-42. Search in Google Scholar

ASTM C136/C136M-14, “Standard Test Method for Sieve Analysis of Fine and Coarse Aggregates”, American Society for Testing and Materials (ASTM), Philadelphia, PA. USA, www.astm.org Search in Google Scholar

ASTM C143, “Slump of Hydraulic Cement Concrete”, American Society for Testing and Materials (ASTM), Philadelphia, PA. USA, www.astm.org Search in Google Scholar

ASTM C150/C150M-18, “Standard Specifications for Portland Cement”, American Society for Testing and Materials (ASTM), Philadelphia, PA. USA, www.astm.org Search in Google Scholar

Awchat, G. (2021). Compressive Strength of Steel Fiber Reinforced Polymer Modified Recycled Aggregate Concrete. In Advanced Materials Research (Vol. 1166, pp. 81-94). Trans Tech Publications Ltd. Search in Google Scholar

Bhan, C., & Kaur, M. (2018). Strength characteristics of recycled concrete aggregate with addition of steel fibres. International Journal of Advance Research and Development, 3(11), 10-15. Search in Google Scholar

Chandar, S. P., Gunasekaran, K., Sandeep, N. S., & Manikandaprabhu, S. (2017). An experimental investigation on strength properties of steel fibres along with recycled aggregate in cement concrete. Rasayan Journal of Chemistry, 10(2), 528-533. Search in Google Scholar

Chen, G. M., He, Y. H., Yang, H., Chen, J. F., & Guo, Y. C. (2014). Compressive behavior of steel fiber reinforced recycled aggregate concrete after exposure to elevated temperatures. Construction and Building Materials, 71, 1-15. Search in Google Scholar

Gangaram, S., Bhikshma, V., & Janardhana, M. (2018). Development of M20 and M30 Grade of Recycled Aggregate Concrete by Replacing 100% Virgin Aggregates with Recycled Aggregates. International Journal of Advance Engineering and Research Development, 5(3), 203-209. Search in Google Scholar

Gao, D., Zhang, L., & Nokken, M. (2017). Compressive behavior of steel fiber reinforced recycled coarse aggregate concrete designed with equivalent cubic compressive strength. Construction and Building Materials, 141, 235-244. Search in Google Scholar

Hameed, R., Akmal, U., Khan, Q. S., Cheema, M. A., & Riaz, M. R. (2020). Effect of fibers on the bond behavior of deformed steel bar embedded in recycled aggregate concrete. Mehran University Research Journal Of Engineering & Technology, 39(4), 846-858. Search in Google Scholar

Kilani, A., Fapohunda, C., Adeleke, O., & Metiboba, C. (2022). Evaluating the effects of agricultural wastes on concrete and composite mechanical properties. Search in Google Scholar

Lamond, J. F., Campbell Sr, R. L., Giraldi, A., Jenkins, N. J., Campbell, T. R., Halczak, W., ... & Seabrook, P. T. (2001). Removal and reuse of hardened concrete. American Concrete Institute: Farmington Hills, MI, USA, 26. Search in Google Scholar

Li, P., Li, S., Zhu, W., & Lu, Y. (2022). Experimental research on the mechanical properties of steel fiber recycled aggregate concrete subjected to true triaxial compression. Construction and Building Materials, 339, 127579. Search in Google Scholar

Luhar, S., Chaudhary, P. S., & Luhar, I. (2018, October). Influence of steel crystal powder on performance of recycled aggregate concrete. In IOP Conference Series: Materials Science and Engineering (Vol. 431, No. 10, p. 102003). IOP Publishing. Search in Google Scholar

McKay, D. T. (2004). Sustainability in the Corps of Engineers. A paper presented at the technical session sponsored by the ACI board advisory committee on sustainable developments. Washington, DC, USA. Search in Google Scholar

Memon, B. A., & Buller, A. H. (2016). Recent development on use of demolished concrete as coarse aggregates. International Journal of Emerging Technology and Innovative Engineering, 2(1), 1-11. Search in Google Scholar

Memon, B. A., & Buller, A. H. (2016). Recent development on use of demolished concrete as coarse aggregates. International Journal of Emerging Technology and Innovative Engineering, 2(1), 1-11. Search in Google Scholar

Nazarimofrad, E., Shaikh, F. U. A., & Nili, M. (2017). Effects of steel fibre and silica fume on impact behaviour of recycled aggregate concrete. Journal of Sustainable Cement-Based Materials, 6(1), 54-68. Search in Google Scholar

Omidinasab, F., Moazami Goodarzi, S., & Sahraei Moghadam, A. (2022). Characterization and optimization of mechanical and impact properties of steel fiber reinforced recycled concrete. International Journal of Civil Engineering, 20, 41-55. Search in Google Scholar

Senaratne, S., Gerace, D., Mirza, O., Tam, V. W., & Kang, W. H. (2016). The costs and benefits of combining recycled aggregate with steel fibres as a sustainable, structural material. Journal of cleaner production, 112, 2318-2327. Search in Google Scholar

Sryh, L., & Forth, J. (2015). Experimental investigation on the effect of steel fibres on the mechanical properties of recycled aggregate concrete. In Conference Fibre Concrete (Vol. 10, p. 120488). Search in Google Scholar

Sryh, L., & Forth, J. (2016). Effect of steel fibres and recycled aggregate on drying shrinkage and creep deformations of Concrete. In The 9th International Concrete Conference Environment, Efficiency and Economic Challenges for Concrete (pp. 4-6). Search in Google Scholar

Su, Q. (2020). Strengths of recycled concrete added with steel fiber. Archives of Civil Engineering, 66(3). Search in Google Scholar

Verian, K. P., Ashraf, W., & Cao, Y. (2018). Properties of recycled concrete aggregate and their influence in new concrete production. Resources, Conservation and Recycling, 133, 30-49. Search in Google Scholar