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http://dx.doi.org/10.12989/acc.2017.5.1.001

Elaboration and characterization of fiber-reinforced self-consolidating repair mortar containing natural perlite powder  

Benyahia, A. (Geomaterials Laboratory, Hassiba Benbouali University of Chlef)
Ghrici, M. (Geomaterials Laboratory, Hassiba Benbouali University of Chlef)
Mansour, M. Said (Geomaterials Laboratory, Hassiba Benbouali University of Chlef)
Omran, A. (Department of Civil Engineering, University of Sherbrooke)
Publication Information
Advances in concrete construction / v.5, no.1, 2017 , pp. 1-15 More about this Journal
Abstract
This research project aimed at evaluating experimentally the effect of natural perlite powder as an alternative supplementary cementing material (SCM) on the performance of fiber reinforced self-consolidating repair mortars (FR-SCRMs). For this purpose, four FR-SCRMs mixes incorporating 0%, 10%, 20%, and 30% of natural perlite powder as cement replacements were prepared. The evaluation was based on fresh (slump flow, flow time, and unit weight), hardened (air-dry unit weight, compressive and flexural strengths, dynamic modulus of elasticity), and durability (water absorption test) performances. The results reveal that structural repair mortars confronting the performance requirements of class R4 materials (European Standard EN 1504-3) could be designed using 10%, 20%, and 30% of perlite powder as cement substitutions. Bonding results between repair mortars containing perlite powder and old concrete substrate investigated by the slant shear test showed good interlocking justifying the effectiveness of these produced mortars.
Keywords
fiber reinforced self-consolidating repair mortar (FR-SCRM); flowability; mechanical properties; perlite powder; slant shear;
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  • Reference
1 ACI Committee 232 (2000), Use of Raw or Processed Natural Pozzolansin Concrete, ACI 232.1R-00 Committee Report.
2 ACI Committee 546 (2004), Concrete Repair Guide, Farmington Hills, Michigan, U.S.A.
3 Asik, M. (2006), "Structural lightweight concrete with natural perlite aggregate and perlite powder", M.S. Dissertation, Middle East Technical University, Ankara, Turkey.
4 ASTM C39 (2003), Standard Test Method for Compressive Strength of Cylindrical Concrete Specimens.
5 ASTM C618 (2012), International Standard Specification for Coal Fly Ash and Raw or Calcined Natural Pozzolan for Use in Concrete, West Conshohocken, Pennsylvania, U.S.A.
6 ASTM C882 (1999), Standard Test Method for Bond Strength of Epoxy-Resin Systems Used with Concrete by Slant Shear.
7 Benjeddou, O., Ben Quezdo, M. and Bedday, A. (2007), "Damaged RC beams repaired by bonding of CFRP laminates", Contr. Build. Mater., 21(6),1301-1310.   DOI
8 Bogas, J.A., Gomes, M.G. and Real, S. (2014), "Bonding of steel reinforcement in structural expanded clay lightweight aggregate concrete: The influence of failure mechanism and concrete composition", Constr. Build. Mater., 65, 350-359.   DOI
9 Burak, I. (2015), "Characterization of lightweight ferrocement panels containing expanded perlite-based mortar", Constr. Build. Mater., 31, 15-23.
10 Chi, M., Huang, R. and Yang, C.C. (2003), "Effect of aggregate properties on the strength and stiffness of lightweight concrete", Cement Concrete Compos., 25(2), 197-205.   DOI
11 Climaco, J. and Regan, P. (1989), "Evaluation of bond strength between old and new concrete", Technics Press, 1, 115-122.
12 Courard, L., Darimont, A., Willem, X., Geers, C. and Degeimbre, R. (2002), "Repairing concretes with self-compacting concrete: Testing methodology assessment", Proceedings of the 1st North American Conference on the Design and Use of Self-Consolidating Concrete, 267-274.
13 Cyr, M., Legrand, C. and Mouret, M. (2000), "Study of the shear thickening effect of superplasticizers on the rheological behavior of cement paste containing or not mineral admixtures", Cement Concrete Res., 30, 1477-1483.   DOI
14 Demirboga, R., Orung, I. and Gul, R. (2001), "Effects of expanded perlite aggregate and mineral admixtures on the compressive strength of low-density concretes", Cement Concrete Res., 31(11), 1627-1632.   DOI
15 EFNARC (2005), The European Guidelines for Self-Compacting Concrete: Specification, Production and Use, European Federation for Specialist Construction Chemicals and Concrete Systems.
16 EN 12190-6 (1999), Products and Systems for the Protection and Repair of Concrete Structures-Test Methods-Determination of Compressive Strength of Repair Mortar.
17 EN 1015-10 (1999), Methods of Test for Mortar for Masonry, Part 10: Determination of Dry Bulk Density of Hardened Mortar, European Committee for Standardization CEN, Brussels, Belgium.
18 EN 1015-18 (2002), Methods of Test for Mortar for Masonry, Determination of Water Absorption Coefficient.
19 EN 1015-6 (1998), Methods of Test for Mortar for Masonry, Part 6: Determination of Bulk Density of Fresh Mortar, European Committee for Standardization CEN, Brussels, Belgium.
20 EN 12504-4 (2005), Testing Concrete-Part 4: Determination of Ultrasonic Pulse Velocity, Requirements, Quality Control and Evaluation of Conformity, Structural and Non-Structural Repair Due to Capillary Action of Hardened Mortar.
21 EN 1504-3 (2006), Products and Systems for the Protection and Repair of Concrete Structures, Definitions.
22 EN 197-1 (2000), Cement, Composition, Specifications and Conformity Criteria for Common Cements.
23 EN 934-2 (2009), Admixtures for Concrete, Mortar and Grout-Part 2: Concrete Admixtures-Definitions, Requirements, Conformity, Marking and Labeling.
24 Ennis, D.J. (2011), "Perlite mining and reclamation in the no aqua peaks", Proceedings of the 62nd Field Conference, Geology of the Tusas Mountains-Ojo Caliente.
25 Jummat, M., Kabir, M. and Obaydollah, M. (2006), "A review of the repair of reinforced concrete beams", J. Appl. Sci. Res., 2(6), 317-326.
26 Erdem, T.K., Meral, C., Tokyay, M. and Erdogan, T.Y. (2007), "Use of perlite as a pozzolanic addition in producing blended cements", Cement Concrete Compos., 29(1), 13-21.   DOI
27 Erdogan, T.Y. (1997), "Admixture for concrete", METU Press, Ankara, Turkey.
28 Ferraris, C., Brower, L., Ozyildirim, C. and Daczko, J. (2000), "Workability of self-compacting concrete", Proceedings of the International Symposium on High Performance Concrete, Orlando, Florida, U.S.A.
29 Hasan, O., Recep, Y. and Abdullah, A. (2015), "Mechanical and thermophysical properties of lightweigh aggregate concretes", Constr. Build. Mater., 96, 217-225.   DOI
30 Hunger, M. (2010), "An integral design concept for ecological self-compacting concrete", Ph.D. Dissertation, Eindhoven University of Technology, Eindhoven, The Netherlands.
31 Khayat, K.H. and Morin, R. (2002), "Performance of self-consolidating concrete used to repair parapet wall in Montreal", Proceedings of the 1st North American Conference on the Design and Use of Self-Consolidating Concrete.
32 Khonsari, V., Eslami, E. and Anvari, A. (2010), "Effects of expanded perlite aggregate (EPA) on the mechanical behavior of lightweight concrete", Spec. Load. Struct. Appl., 1354-1361.
33 Kimball, S.M. (2016), "Menial commodity summaries", Department of the Interior, U.S. Geological Survey, 1202.
34 Knab, L. and Spring, C. (1989), "Evaluation of test methods for measuring the bond strength of portland cement based repair material to concrete", Cement Concrete Aggr., 11(1), 3-14.   DOI
35 Kuder, K.G., Ozyurt, N., Mu, E.B. and Shah S.P. (2007), "Rheology of fibre-reinforced cementitious materials", Cement Concrete Res., 37(2), 191-199.   DOI
36 Okamura, H. and Ouchi, M. (2003), "Self-compacting concrete", J. Adv. Concrete Technol., 1(1), 5-15.   DOI
37 Eser, H. (2014), "High performance structural lightweight concrete", M.S. Dissertation, Middle East Technical University, Ankara, Turkey.
38 Lanzon, M. and Garcia-Ruiz, P.A. (2008), "Lightweight cement mortars: Advantages and inconveniences of expanded perlite and its influence on fresh and hardened state and durability", Constr. Build. Mater., 22(8), 1798-1806.   DOI
39 Mo, X. and Fournier, B. (2007), "Investigation of structural properties associated with alkali silica reaction by means of macro-and microstructural analysis", Mater. Char., 58(2), 179-189.   DOI
40 Sahmaran, M., Christianto, H.A. and Yaman, I.O. (2006), "The effect of chemical admixtures and mineral additives on the properties of self-compacting mortars", Cement Concrete Compos., 28(5), 432-440.   DOI
41 Sanjuan, M.A., Andrade, C. and Bentur, A. (1997), "Effect of crack control in mortars containing polyethylene fibers on the corrosion of steel in acementitious matrix", ACI Mater. J., 94(2), 134-141.
42 Smith, K. and Atkinson, T. (2010), "PP fibres to resist fire induced concrete spalling", Propex Concrete Syst.
43 Turanli, L., Uzal, B. and Bektas, F. (2005), "Effect of large amounts of natural pozzolan addition on properties of blended cements", Cement Concrete Res., 35(6), 1106-1111.   DOI
44 Urhan, S. (1987), "Alkali silica and pozzolanic reactions in concrete, part 2: Observations on expanded perlite aggregate concretes", Cement Concrete Res., 17(3), 465-477.   DOI
45 Uzal, B., Turanli, L. and Mehta, P.K. (2007), "High-volume natural pozzolan concrete for structural applications", ACI Mater. J., 104(5), 535-538.
46 Yu, L.H., Ou, H. and Lee, L. (2003), "Investigation on pozzolanic effect of perlite powder in concrete", Cement Concrete Res., 33(1), 73-76.   DOI
47 Yahia, A., Tanimura, M. and Shimoyama, Y. (2005), "Rheological properties of highly flowable mortar containing limestone filler-effect of powder content and w/c ratio", Cement Concrete Res., 35(3), 532-539.   DOI