An experimental study on damaged cementitious mortars repaired by glass/epoxy composite materials

[1]. Jain S., Chellapandian M., Prakash S. S. (2017). Emergency repair of severely damaged reinforced concrete column elements under axial compression: An experimental study, Construction and Building Materials, 155 751–761.10.1016/j.conbuildmat.2017.08.127Search in Google Scholar

[2]. P. Azarsa, R. Gupta. (2018). Specimen preparation for nano-scale investigation of cementitious repair material, Construction and Building Materials, Micron, 107 43–54.10.1016/j.micron.2018.01.007Search in Google Scholar

[3]. A. Irene Ortega, Teresa M. Pellicer, Jose M. Adam, Pedro A. Calderón. (2018). An experimental study on RC columns repaired on all four sides with cementitious mortars, Construction and Building Materials, 161 53–62.10.1016/j.conbuildmat.2017.11.126Search in Google Scholar

[4]. M. Elghazy, A. El Refai, U. Ebead, A. Nanni. (2018). Post-repair flexural performance of corrosion-damaged beams rehabilitated with fabric-reinforced cementitious matrix (FRCM), Construction and Building Materials 166 732–74410.1016/j.conbuildmat.2018.01.128Search in Google Scholar

[5]. American Concrete Institute (ACI). (1995), Building Code Requirements for Reinforced Concrete. Detroit, MI.Search in Google Scholar

[6]. J. Castro and A. E. Naaman, (1981) Cement Mortar Reinforced with Natural Fibers, ACI Journal, JanuarySearch in Google Scholar

[7]. Saadatmanesh, H. & Ehsani, M.R. (1990). Fiber Composite Plates Can Strengthen Beams, Concrete International, March, pp. 65-7 1.Search in Google Scholar

[8]. Meir, U. and Kaiser, H. (1991). Strengthening Structures with CFRP Laminate, Proceedings of Advanced Composite Materials in Civil Engineering; Structures, ASCE, Las /Vegas, Nevada, pp. 224-232.Search in Google Scholar

[9]. Ross, C.A., Jerome, D.M. and Hughes, M.L. (1994). Hardening and Rehabilitation of Concrete Structures Using Carbon Fiber Reinforced Plastics (CFRPL Final Report, Wright Laboratory Armament Directorate) Eglin Air Force Base, Florida.Search in Google Scholar

[10]. Ritchie, P.A. (1988). External Reinforcement of Concrete Beams Using Fiber Reinforced Plastic, Thesis, Leigh University.Search in Google Scholar

[11]. Ghaleb, B.M. (1992). Strengthening of Damaged Reinforced Concrete Beams bv External Fiber Glass Plates, Thesis, King Fahd University of Petroleum and Minerals, Saudi Arabia.Search in Google Scholar

[12]. PCI committee on glass fiber reinforced concrete panels. (1981). Recommended practice for glass fiber reinforced concrete panels. PCI J., 26(1):25-93.Search in Google Scholar

[13]. Gonilho-Pereira C., Faria P., Fangueiro R., Vinagre P., Martins A., (2011). Cement based fiber-reinforced mortar: the fiber influence on the mortar performance, 6th Congresso Luso-Moçambicano de Engenharia CLME’2011, Maputo, 29 August - 2 September.Search in Google Scholar

[14]. Puertas, F., Amat, T., Fernandez-Jimenez A., and Vazquez, T., (2003). Mechanical and durable behaviour of alkaline cement mortars reinforced with polypropylene fibres, Cement and Concrete Research 33 pp. 2031–2036.Search in Google Scholar

[15]. Toledo, R.D., and Sanjuan, M.A., (1999). Effect of low modulus sisal and polypropylene fibers on the free and restrained shrinkage of mortars at early age, Cem. Concr Res 29 pp. 1597–1604.Search in Google Scholar

[16]. ACI 544.1R-96, (1996) State-of-the-art report on fiber rein-forced concrete, Farmington Hills, Michigan: American Concrete InstituteSearch in Google Scholar

[17]. Aydin, A.C.(2007). Self compactability of high volume hybrid fiber reinforced concrete. Const. Build. Material;21, 1149-1154.10.1016/j.conbuildmat.2006.11.017Search in Google Scholar

[18]. Shah, S. P. and Naaman, A. E. (1976). Mechanical properties of glass and steel fiber reinforced mortar. ACI Journal; 73(1), 50-53.Search in Google Scholar

[19]. Nataraja, M. C, Dhang, N. & Gupta, A. P. (1999). Stress-strain curves for steel fiber reinforced concrete under compression. Cement & Concrete Composite; 21, 383-390.10.1016/S0958-9465(99)00021-9Search in Google Scholar

[20]. Okamura, H. & Ouchi, M. (2003). Self-compacting concrete. J. Adv. Concr Technol,1(1), 1-15.10.3151/jact.1.5Search in Google Scholar

[21]. Gang, L. Wang, K &, Rudolphi, T.J. (2008). Modeling reheological behavior of highly flowable mortar using concepts of particle and fluid mechanics. Cem. & Conc. Comp. 30, 1-12.10.1016/j.cemconcomp.2007.06.002Search in Google Scholar

[22]. Domene, P. L. & Jine, J. (1999). Properties of mortar for self-compacting concrete. Proceedings of the 1st international RILEM symposium on self-compacting concrete, 109-20.Search in Google Scholar

[23]. Khayat, KH, Morin, R. (2002). Performance of self-consolidating concrete used to repair parapet wall in Montreal. Proceedings of the first North American conference on the design and use of self-consolidating concrete, 475-481.Search in Google Scholar

[24]. Zhou, F. P., Barr, B. I. G. & Lydon, F. D. (1994) Fracture mechanical properties of high strength concrete with varying silica fume content and aggregates. Cement &Concrete Research, 25(3), 543-52.Search in Google Scholar

[25]. Carlach D., Hemery Y. (2002). Etude prospective sur le collage en France, Digitp/Simap, décembre, 237 pages http://www.industrie.gouv.fr/pdf/collage.pdfSearch in Google Scholar

[26]. A. Finley. (1999). Notice technique, Les résines époxydes EPONAL (sols industriels, étanchéité, réparations, collages), éditions mars.Search in Google Scholar

[27]. Bardonnet P. (1992). Résines époxydes: composants et propriétés. Techniques de l’ingénieur, traité de Plastique et Composites,10.51257/a-v1-a3465Search in Google Scholar

[28]. Mays G., Hutchinson A.R. (1992). Adhesives in Civil Engineering, Cambridge University Press. Cambridge (UK),.Search in Google Scholar

[29]. Toutanji H., Ortiz G. (2001). The effect of surface preparation on the bond interface between FRP sheets and concrete members, Composite Structures (53), 457-462.10.1016/S0263-8223(01)00057-5Search in Google Scholar

[30]. Maugis D., Barquins M. (1986). Adhésion, collage et mécanique de la rupture, Colloque RILEM Adhesion between polymers and concrete – bonding, protection, repair, 16-19 Septembre Aix en Provence, 41-54.10.1007/978-1-4899-3454-3_5Search in Google Scholar

[31]. Pang M., Yang S., Zhang Y.. (2011). Experimental study of cement mortar-steel fiber reinforced rammed earth wall, International Symposium on Innovation & Sustainability of Structures in Civil Engineering, Xiamen University, China.10.3390/su4102630Search in Google Scholar

[32]. Mc. N. Shaw I. (1989). Interactions between organic polymers and cement hydration products,, PhD thesis of Birmingham University.Search in Google Scholar

[33]. Neves M.I., Chabut M., Perruchot C., Chehimi M.M., Benzarti K. (2004). Interfacial interactions of structural adhesive components with cement pastes: studies by inverse gas chromatography (IGC), Journal of Applied Surface Science (238),523-529..10.1016/j.apsusc.2004.05.245Search in Google Scholar

[34]. Majumdar, A. J. (1975) Properties of fibre cement composites, Fibre Reinforced Cement and Concrete, RILEM Symposium, 279-313.Search in Google Scholar

[35]. Larner, L. J., Speakman, K. and Majumdar, A. J. (1976), Chemical interaction between glass-fibres and cement, J. of Non-Crystalline Solids, 20, 43-74.10.1016/0022-3093(76)90107-1Search in Google Scholar

[36]. Bijen, J. (1983). Durability of some glass fiber reinforced cement composites. ACI journal, July-August 305-311.Search in Google Scholar

[37]. Leonard, S. and Bentur, A. (1984) Improvement of the durability of glass fiber reinforced cement using blended cement matrix. Cement and concrete research 14:717-728.10.1016/0008-8846(84)90035-8Search in Google Scholar

[38]. Bentur, A. (1986). Aging process of glass fibre reinforced cements with different cementitious matrices. RILEM symposium FRC 86, vol. 2, paper 7.3.Search in Google Scholar

[39]. Shah, S.P., Ludirdja, D., Daniel, J.I., Mobasher, B. (1988). Toughness-durability of glass fiber reinforced concrete systems. ACI materials journal, September-October 352-360.Search in Google Scholar

[40]. Li, Z. and Mobasher, B. & Shah, S.P. (1991). Evaluation of interfacial properties in fiber reinforced cementitious composites. Fracture processe in concrete, rock and ceramics, J.G.M. Van Mier, J.G. Rots, A. Bakker, RILEM, E. an F.N. Spon. Pp. 317-326,Search in Google Scholar