Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-28T01:54:08.074Z Has data issue: false hasContentIssue false

Performance of Repair Mortar with Natural Fibers

Published online by Cambridge University Press:  24 March 2020

A Kenai
Affiliation:
Geomaterials and civil engineering laboratory, University of Blida1, Algeria
M Rezagui
Affiliation:
Geomaterials and civil engineering laboratory, University of Blida1, Algeria
W Yahiaoui
Affiliation:
Geomaterials and civil engineering laboratory, University of Blida1, Algeria
B Menadi
Affiliation:
Geomaterials and civil engineering laboratory, University of Blida1, Algeria
S Kenai*
Affiliation:
Geomaterials and civil engineering laboratory, University of Blida1, Algeria
*
*Corresponding author [email protected]
Get access

Abstract

Concrete is the most used material in the world after water because of its good mechanical characteristics and its reasonable cost. However, reinforced concrete structures can be damaged by corrosion or other chemical attacks and require repair and maintenance. The repair materials need to satisfy some mechanical and physico-chemical characteristics. Ready-made repair mortars are widely used. However, they are quite expensive, generally imported and they frequently incorporate low volume of synthetic fibers. This paper reports an experimental investigation designing an environmental friendly repair mortar made of local mineral addition (natural pozzolan (PN) and slag (SL)) and local natural fibers. The natural fibers used are Alfa fibers and date palm tree fibers at a volume ratio of 0.75%. The physical and mechanical properties studied are compressive strength, bending strength, total shrinkage and bond strength by slant shear and pull-off tests. The durability of the mortar was assessed by water capillary absorption. The results are compared to those of a reference mortar. The results showed that the substitution of cement by slag and natural pozzolan lead to a decrease in shrinkage (at 28 days of age). The use of date palm and alfa fibers improves the bending strength but reduces compressive strength. According to the results of the pull-off tests, only mortars containing slag meet the minimum value (1.5 MPa) required by EN1504-3. The types of failures observed for most composites show that they can be successfully applied with 20 mm thick layers.

Type
Articles
Copyright
Copyright © Materials Research Society 2020

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Abdulhameed, H.A., Nassif, H., Khayat, K.H., Use of fiber-reinforced self-consolidating concrete to enhance serviceability performance of damaged beams, Transp. Res. Rec. 2672 (2018) 4555.CrossRefGoogle Scholar
Pattnaik, R.R., Investigation On ASTM C882 Test Procedure Of Slant Shear Bond Strength Of Concrete Repair Material, Inter. J. Civ. Str.Env.Infr. Eng. Res. Dev., 5 (2015) 16.Google Scholar
Kassimi, F., El-Sayed, A.K., Khayat, K.H., Performance of fiber-reinforced self-consolidating concrete for repair of reinforced concrete beams, ACI. Struct. J. 111 (2014) 12771286.CrossRefGoogle Scholar
Abdulhameed, H.A., Evaluation of Pozzolanic Repair Materials by Different Test Methods Evaluation of Pozzolanic Repair Materials by Different Test Methods, Eng. Tech. J.,(2018).Google Scholar
Mansi, A.S., Bond Strength Assessment for Different Types of Repair Materials, Eng. Tech. Journal. 28 (2010) 63256336.Google Scholar
Mehta, P., Knab, L., Spring, C., Evaluation of Test Methods for Measuring the Bond Strength of Portland Cement Based Repair Materials to Concrete, Cem. Concr. Aggr., 11 (1989) 3-14.CrossRefGoogle Scholar
ASTM, Standard Test Method for Tensile Strength of Concrete Surfaces and the Bond Strength or Tensile Strength of Concrete Repair and Overlay Materials by Direct Tension ( Pull-off Method ) 1, (2014) 37.Google Scholar
Hindo, K., In-place bond testing and surface preparation of concrete, in: Concr. Int., (1990) 1246.Google Scholar
ASTM, Standard Test Method for Bond Strength of Epoxy-Resin Systems Used With Concrete Bond Strength of Epoxy-Resin Systems Used With Concrete By Slant Shear, (2009) 2326.Google Scholar
AFNOR, NF EN 12390-3 Test for hardened concrete - Part 3: Compressive strength of specimens,33 (2019) 15.Google Scholar
ASTM, Standard Test Method for Measurement of Rate of Absorption of Water by Hydraulic-, ASTM Int. 41 (2013) 16.Google Scholar
Cao, M., Xu, L., Zhang, C., Rheological and mechanical properties of hybrid fiber reinforced cement mortar, Constr. Build. Mater. 171 (2018) 736742.CrossRefGoogle Scholar
Li, L.G., Zhao, Z.W., Zhu, J., Kwan, A.K.H., Zeng, K.L., Combined effects of water film thickness and polypropylene fiber length on fresh properties of mortar, Constr. Build. Mater. 174 (2018) 586593.CrossRefGoogle Scholar
Mokhtari, A., Kriker, A., Guemmoula, Y., Boukrioua, A., Khenfer, M.M., Formulation and characterization of date palm fibers mortar by addition of Crushed Dune Sand, Ener. Proc., 74 (2015) 344350.CrossRefGoogle Scholar
Abdelaziz, S., Guessasma, S., Bouaziz, A., Hamzaoui, R., Beaugrand, J., Abdulfatah, A., Date palm spikelet in mortar: Testing and modelling to reveal the mechanical performance, Constr. Build. Mater., 124 (2016) 228236.CrossRefGoogle Scholar
Asrial, F., Sudikno, A., Leksono, A., Indriyani, A.S.L., Palmyra Fiber as Additional Materials on Solid Concrete Brick of Aggregate, Mediterr. J. Soc. Sci. Rome-Italy. 8 (2017) 410418.Google Scholar
Krobba, B., Bouhicha, M., Kenai, S., Courard, L., Formulation of low cost eco-repair mortar based on dune sand and Stipa tenacissima microfibers plant, Constr. Build. Mater. 171 (2018) 950959.CrossRefGoogle Scholar
Campello, E., V Pereira, M., Darwish, F., The Effect of Short Metallic and Polymeric Fiber on the Fracture Behavior of Cement Mortar, Proc.Mater. Sci., 3 (2014) 19141921.CrossRefGoogle Scholar
Hadjsadok, A., Kenai, S., Courard, L., Michel, F., Khatib, J., Durability of mortar and concretes containing slag with low hydraulic activity, Cem. Concr. Compos. 34 (2012) 671677.CrossRefGoogle Scholar
Chen, H., Huang, S., Tang, C., Malek, M.A., Ean, L., Effect of curing environments on strength , porosity and chloride ingress resistance of blast furnace slag cement concretes: A construction site study, Constr. Build. Mater., 35 (2012) 10631070.CrossRefGoogle Scholar
Mirmoghtadaei, R., Mohammadi, M., Ashraf Samani, N., Mousavi, S., The impact of surface preparation on the bond strength of repaired concrete by metakaolin containing concrete, Constr. Build. Mater., 80 (2015) 7683. 8.CrossRefGoogle Scholar
Tayeh, B.A., Bakar, B.H.A., Johari, M.A.M., Ratnam, M.M., The relationship between substrate roughness parameters and bond strength of ultra-high-performance fiber concrete, J. Adhes. Sci. Technol., 27 (2013) 17901810.CrossRefGoogle Scholar
Ghafari, E., Naderi, M., Effect of Different Curing Regime and Cementitious Materials on the Bond Strength of Self Compacting Mortars, Aust. J. Basic. Appl. Sci., 5 (2011) 421428.Google Scholar
Benyahia, A., Ghrici, M., Choucha, S., Omran, A., Characterization of fiber reinforced self-consolidating mortars for use in patching damaged concrete, Lat. Am. J. Solids.Struct., 14 (2017) 11241142.CrossRefGoogle Scholar