Open Access

Experimental Research on the Thermal Instability of Fiber Polypropylene Concrete at 250 °C


[1] Kheddache, L., Chahour, K. and Safi, B. “Effet de la répartition des fibres sur le comportement mécanique en flexion des mortiers autoplaçants” Articles scientifiques sélectionnés - Journal of Civil Engineering, vol.15, no.1, 2020, pp.129-148. Search in Google Scholar

[2] Lakhal, R. (2011) Elaboration des bétons à hautes performances a base des sous-produit locaux formulation et caractérisation physico-mécanique.» Mémoire de magister, Université Badji Mokhtar,Annaba.. Search in Google Scholar

[3] Kalifa, P., Menneteau, F-D., Quenard, D. (2000) Spalling and pore pressure in HPC at high temperatures. Cement and Concrete Research. 30 (12), 1915-1927. Search in Google Scholar

[4] Noumowé, A. (1995) Effect of high temperatures (20-600°C) on concrete. Special case of high concrete. PhD thesis. France. National Institute of Applied Sciences of Lyon. Search in Google Scholar

[5] Hager, I. (2004) High temperature behavior of high performance concretes - evolution of the main ones. PhD Thesis. France. National School of Bridges and Roads and the School. Search in Google Scholar

[6] Mindeguia, J. (2009) Experimental contribution to understanding the risks of thermal instability in concretes. PhD thesis. France. University of Pau and the Adour countries. Search in Google Scholar

[7] Aidoud, A., Benouis, A.H. (2018) Investigation of the Evolving Relationship Between the Properties of Ordinary Concrete and High Performance Concrete at High Temperatures. Journal of Materials and Environmental Sciences 9 (4), 1335-1342. Search in Google Scholar

[8] Kalifa, P., Chéné, G., Gallé, C. (2001) High-temperature behaviour of HPC with polypropylene fibres - From. Cement and Concrete Research. 30 (10), 1487-1499. Search in Google Scholar

[9] Yermak, N., Pliya, P., Beaucour, A-L., Simon, A., Noumowé, A. (2017) Influence of steel and/or polypropylene fibres on the behaviour of concrete at high temperature: Spalling, transfer and mechanical properties. Construction and Building Materials. 132, 240–250. Search in Google Scholar

[10] Yagoub, M. (2009) Assessment of the quality of fiber concrete in situ case of self-placing concrete with mixed fibers. Masters thesis. Algeria. Mohamed Khider University - Biskra. Search in Google Scholar

[11] Hager, I. (2013) Behaviour of cement concrete at high temperature. Bulletin of the Polish Academy of Sciences 61 (1), 145-154. Search in Google Scholar

[12] Technical manual (MEDAPLAST- SP 40 (GRANITEX)), available at: Search in Google Scholar

[13] EN (2003) European Standard 12309-3.Tests for hardened concrete - part 3: Resistance to compression of test pieces. CEN. 02. Search in Google Scholar

[14] NF (2005) EN standar. NF 12504-4. Sonic auscultation test. AFNOR. Search in Google Scholar

[15] CONTROLS (2002) Instruction Manual: Ultrasonic Pulse Velocity tester. Mod. 58-E0048. Search in Google Scholar

[16] Search in Google Scholar

[17] Eurocode 2 (2001) (ENV 1992-1-2): Design of concrete structures, Part 1-2: General rules - calculation of fire behavior. February. Search in Google Scholar

[18] BAEL 91 rules (DTU P 18-702) (revised February 99, 2000) Technical rules for the design and calculation of reinforced concrete structures and structures using the limit states method Fascicle 62, title 1 of the CCTG - Works section 1: reinforced concrete 1. Search in Google Scholar

[19] Chouiter, Y (2016) Study of the behavior of a high performance concrete (HPC) with glass fibers subjected to high temperature. Master memory. Algeria. Materials. M’sila: Mohamed Boudiaf University. Search in Google Scholar

[20] Sideris, KK; Manita, P; Chaniotakis, E (2009) Performance of thermally damaged fiber reinforced concretes. Construction and Building Materials 23 (3), 1232-1239. Search in Google Scholar

[21] Pimienta, P; Mindeguia, JC; Simon, A; Behloul, M; Felicetti, R; Bamonte, R; Gambarova, PG (2012) Performance of concrete subjected to high temperature, from material to structure. Symposium Cergy-Pontoise University. France. 23 October. Search in Google Scholar

[22] Khaliq. W; Kodur.V (2011) Thermal and Mechanical Properties of Fiber Reinforced HighPerformance Self-Consolidating Concrete at Elevated Temperatures. Cement and Concrete Research. 41 (11), 1112-1122. Search in Google Scholar

[23] Behnood, A; Ghandehari, M (2009) Comparison of compressive and splitting tensile strength of high-strength concrete with and without polypropylene fibers heated to high temperature. Fire Safety Journal. 44 (8), 1015-1022. Search in Google Scholar

[24] Pliya, P (2010) Contribution of polypropylene and metallic fibers to improving the behavior of concrete subjected to high temperature. PhD thesis. France. University of Cergy Pontoise. Search in Google Scholar

Publication timeframe:
2 times per year
Journal Subjects:
Engineering, Introductions and Overviews, other