[2] Habel K, Viviani M, Denarié E, Brühwiler E. Development of the mechanical properties of an ultra-high performance fiber reinforced concrete (UHPFRC). Cement and Concrete Research. 2006 Jul 1;36(7):1362-70.
[View at Google Scholar]; [View at Publisher]
[4] Boulekbache B, Hamrat M, Chemrouk M, Amziane S. Influence of yield stress and compressive strength on direct shear behaviour of steel fibre-reinforced concrete. Construction and Building Materials. 2012 Feb 1;27(1):6-14.
[View at Google Scholar]; [View at Publisher]
[6] Sivakumar A, Santhanam M. Mechanical properties of high strength concrete reinforced with metallic and non-metallic fibres. Cement and Concrete Composites. 2007 Sep 1;29(8):603-8.
[View at Google Scholar]; [View at Publisher]
[9] Murali G, Vardhan CV, Prabu R, Khan ZM, Mohamed TA, Suresh T. Experimental investigation on fibre reinforced concrete using waste materials. International Journal of Engineering Research and Applications (IJERA) ISSN. 2012 Mar;2248(9622):278-83.
[View at Google Scholar]; [View at Publisher]
[11] Rahmani, E., Dehestani, M., Beygi, M. H. A., Allahyari, H., & Nikbin, I. M. (2013). On the mechanical properties of concrete containing waste PET particles. Construction and Building Materials, 47, 1302-1308.
[View at Google Scholar]; [View at Publisher]
[14] Ghernouti Y, Rabehi B, Bouziani T, Ghezraoui H, Makhloufi A. Fresh and hardened properties of self-compacting concrete containing plastic bag waste fibers (WFSCC). Construction and Building Materials. 2015 May 1;82:89-100.
[View at Google Scholar]; [View at Publisher]
[15] Rahnema H, Modarresi MH, Lashkari A, Hadianfard MA, Sedaghat S. Study of Properties of High Strength Concrete Reinforced with Industrial Waste Steel Fibers. InAdvanced Materials Research 2012 (Vol. 341, pp. 231-241). Trans Tech Publications Ltd.
[View at Google Scholar]; [View at Publisher]
[16] Yazdizadeh Z, Marzouk H, Hadianfard MA. Monitoring of concrete shrinkage and creep using Fiber Bragg Grating sensors. Construction and Building Materials. 2017 Apr 15;137:505-12.
[View at Google Scholar]; [View at Publisher]
[17] Yu R, Spiesz P, Brouwers HJ. Static properties and impact resistance of a green Ultra-High Performance Hybrid Fibre Reinforced Concrete (UHPHFRC): Experiments and modeling. Construction and Building Materials. 2014 Oct 15;68:158-71.
[View at Google Scholar]; [View at Publisher]
[20] Kim DJ, Park SH, Ryu GS, Koh KT. Comparative flexural behavior of hybrid ultra high performance fiber reinforced concrete with different macro fibers. Construction and Building Materials. 2011 Nov 1;25(11):4144-55.
[View at Google Scholar]; [View at Publisher]
[21] Ahmed SF, Maalej M, Paramasivam P. Flexural responses of hybrid steel–polyethylene fiber reinforced cement composites containing high volume fly ash. Construction and building materials. 2007 May 1;21(5):1088-97.
[View at Google Scholar]; [View at Publisher]
[23] Khalil W, Ahmed H, Hussein Z. Behavior of high performance artificial lightweight aggregate concrete reinforced with hybrid fibers. InMATEC Web of Conferences 2018 (Vol. 162, p. 02001). EDP Sciences.
[View at Google Scholar]; [View at Publisher]
[24] ASTM C136 / C136M-19, Standard Test Method for Sieve Analysis of Fine and Coarse Aggregates, ASTM International, West Conshohocken, PA, 2019.
[View at Publisher]
[25] ASTM A510 / A510M-20, Standard Specification for General Requirements for Wire Rods and Coarse Round Wire, Carbon Steel, and Alloy Steel, ASTM International, West Conshohocken, PA, 2020.
[View at Publisher]
[26] Ebrahimi A, Mahdikhani M. Case study of the statistical distribution of the concretes implemented at Qazvin. Journal of Structural Engineering and Geo-Techniques. 2017 Sep 30;7(2):37-50.
[View at Google Scholar]; [View at Publisher]
[27] ACI 211 (2002). Standard practice for selecting proportions for normal, heavyweight, and mass concrete. ACI Committee 211, American Concrete Institute, USA.
[View at Publisher]
[28] ASTM C192 / C192M-19, Standard Practice for Making and Curing Concrete Test Specimens in the Laboratory, ASTM International, West Conshohocken, PA, 2019.
[View at Publisher]
[29] BS EN-12390-3. Compressive strength of test specimens. British Standards Institution; 2001.
[View at Publisher]
[30] ASTM C496 / C496M-17, Standard Test Method for Splitting Tensile Strength of Cylindrical Concrete Specimens, ASTM International, West Conshohocken, PA, 2017.
[View at Publisher]