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International Journal of Pavement Engineering Volume 24, 2023 - Issue 2
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Research Article

The assessment of durability, coefficient of thermal expansion, and bonding strength of latex modified mixtures in repairing restrained concrete pavements

Benyamin Mehria School of Civil Engineering, Iran University of Science and Technology, Narmak, Iran
,
Ali Akbar Shirzadi Javida School of Civil Engineering, Iran University of Science and Technology, Narmak, IranCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-6105-5991
ORCID Icon,
Shahram Asayesha School of Civil Engineering, Iran University of Science and Technology, Narmak, Iran
&
Mohammad Ali Ghanbarib Islamic Azad University- Science and Research Branch, School of Chemical Engineering, Tehran, Iran
Article: 2048301 | Received 22 Oct 2021, Accepted 25 Feb 2022, Published online: 13 Mar 2022

References

  • 12390-3. E. Testing hardened concrete. Compressive strength of test specimens.
  • Ababneh, A. N., et al., 2017. Assessment of shrinkage-induced cracks in restrained and unrestrained cement-based slabs. Construction and Building Materials, 131, 371–380.
  • Al-Ostaz, A., et al., 2010. Deterioration of bond integrity between repair material and concrete due to thermal and mechanical incompatibilities. Journal of Materials in Civil Engineering, 22 (2), 136–144.
  • Allahvirdizadeh, R., et al., 2011. Application of polymer concrete in repair of concrete structures: A literature review. Concrete Solutions, 435–444.
  • Assaad, J. J., and Issa, C. A., 2017. Mixture optimisation of polymer-modified lightweight SCC. Magazine of Concrete Research, 69 (14), 745–756.
  • Bahranifard, Z., Tabrizi, F. F., and Vosoughi, A. R., 2019. An investigation on the effect of styrene-butyl acrylate copolymer latex to improve the properties of polymer modified concrete. Construction and Building Materials, 205, 175–185.
  • Banthia, N., and Gupta, R., 2009. Plastic shrinkage cracking in cementitious repairs and overlays. Materials and Structures, 42 (5), 567–579.
  • Barluenga, G., and Hernández-Olivares, F., 2004. SBR latex modified mortar rheology and mechanical behaviour. Cement and Concrete Research, 34 (3), 527–535.
  • Beushausen, H., and Chilwesa, M., 2013. Assessment and prediction of drying shrinkage cracking in bonded mortar overlays. Cement and Concrete Research, 53, 256–266.
  • C138, A, 2017. ASTM c138/standard test method for density (unit weight), yield, and air content (gravimetric) of concrete. West Conshohocken: ASTM International.
  • C143M-15a, A. C, 2015. Standard test method for slump of hydraulic-cement concrete. West Conshohocken: ASTM International.
  • C157M-17, A. C., 2017. Standard test method for Length change of hardened hydraulic-cement mortar and concrete. West Conshohocken: ASTM International.
  • C162-04, 2004. Standard Terminology of Glass and Glass Products.
  • C496M-17, A. C, 2017. Standard test method for splitting tensile strength of cylindrical concrete specimens. West Conshohocken: ASTM International.
  • C642-13, A., 2013. Standard test method for density, absorption, and voids in hardened concrete. West Conshohocken: ASTM International.
  • C672M-12, A. C, 2012. Standard test method for scaling resistance of concrete surfaces exposed to deicing chemicals. West Conshohocken: ASTM International.
  • C78M-18, A. C, 2018. Standard test method for flexural strength of concrete (using simple beam with third-point loading). West Conshohocken: ASTM International.
  • Choi, P., and Yun, K.-K., 2014. Experimental analysis of latex-solid content effect on early-age and autogenous shrinkage of very-early strength latex-modified concrete. Construction and Building Materials, 65, 396–404.
  • D7234-19, A, 2019. Standard test method for pull-Off adhesion strength of coatings on concrete using portable pull-off adhesion testers. West Conshohocken: ASTM International.
  • Deredas, K., Kępczak, N., and Urbaniak, M., 2021. Influence of doping with styrene-butadiene rubber on dynamic and mechanical properties of polymer concrete. Composite Structures, 268, 113998.
  • Doğan, M., and Bideci, A., 2016. Effect of Styrene Butadiene Copolymer (SBR) admixture on high strength concrete. Construction and Building Materials, 112, 378–385.
  • Etebari Ghasbeh, M. A., Ghoddousi, P., and Shirzadi Javid, A. A., 2021. Modeling concrete thermal expansion based on packing density theory. Scientia Iranica, 28 (4), 2087–2100.
  • Ghoddousi, P., and Javid, A. A. S., 2012. Effect of reinforcement on plastic shrinkage and settlement of self-consolidating concrete as repair material. Materials and Structures, 45 (1), 41–52.
  • Guo, T., Xie, Y., and Weng, X., 2018. Evaluation of the bond strength of a novel concrete for rapid patch repair of pavements. Construction and Building Materials, 186, 790–800.
  • Hayashi, S., Kawamura, C., and Takayama, M., 1970. Color reactions of poly vinyl acetate and its derivatives with iodine. Bulletin of the Chemical Society of Japan, 43 (2), 537–542.
  • Heath, A. C., and Roesler, J. R., 1999. Shrinkage and thermal cracking of fast setting hydraulic cement concrete pavements in Palmdale, California, Pavement Research Center, Institute of Transportation Studies, University of … .
  • Hwang, E.-H., and Ko, Y. S., 2008. Comparison of mechanical and physical properties of SBR-polymer modified mortars using recycled waste materials. Journal of Industrial and Engineering Chemistry, 14 (5), 644–650.
  • Institute, D. T., and Technology, B., 1994. TI-B101(94)/Concrete, Thermal Expansion Coefficient: 5.
  • International, A., 2018. ASTM c33 / C33M-18-Standard Specification for Concrete Aggregates. West Conshohocken, PA.
  • International, A., 2020. ASTM c150 / C150M-20 standard specification for portland cement. West Conshohocken.
  • International, A., 2020. ASTM c1583 / C1583M-20-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). West Conshohocken.
  • Jamshidi, M., Pakravan, H. R., and Zojaji, K., 2013. Correlation between water permeability of latex-modified concrete (LMC) and water diffusion coefficient of latex film. Iranian Polymer Journal, 22 (11), 799–809.
  • Jeong, J.-H., et al., 2012. Age and moisture effects on thermal expansion of concrete pavement slabs. Journal of Materials in Civil Engineering, 24 (1), 8–15.
  • Kawano, T., 1981. Studies on the mechanism of reducing drying shrinkage of cement mortar modified by rubber latex. In: Proceedings of the third international congress on polymers in concrete.
  • Li, G., et al., 2016. Properties of rubberized concrete modified by using silane coupling agent and carboxylated SBR. Journal of Cleaner Production, 112, 797–807.
  • Liu, Y., et al., 2016. Compatibility of repair materials with substrate low-modulus cement and asphalt mortar (CA mortar). Construction and Building Materials, 126, 304–312.
  • Mallela, J., et al., 2005. Measurement and significance of the coefficient of thermal expansion of concrete in rigid pavement design. Transportation Research Record: Journal of the Transportation Research Board, 1919 (1), 38–46.
  • Mehta, P. K, 1999. Advancements in concrete technology. Concrete International, 21 (6), 69–76.
  • Mei, Y.-j., et al., 2009. Effect and mechanism of styrene-butadiene rubber latex on the long term shrinking performance of mortar. Journal of Civil, Architectural & Environmental Engineering, 3.
  • Morgan, D, 1996. Compatibility of concrete repair materials and systems. Construction and Building Materials, 10 (1), 57–67.
  • Naik, T. R., Kraus, R. N., and Kumar, R., 2011. Influence of types of coarse aggregates on the coefficient of thermal expansion of concrete. Journal of Materials in Civil Engineering, 23 (4), 467–472.
  • Nakayama, M., and Beaudoin, J. J., 1987. Bond strength development between latex-modified cement paste and steel. Cement and Concrete Research, 17 (4), 562–572.
  • Ohama, Y, 1995. Handbook of polymer-modified concrete and mortars: properties and process technology. William Andrew.
  • Ohama, Y., and Kan, S., 1982. Effects of specimen size on strength and drying shrinkage of polymer-modified concrete. International Journal of Cement Composites and Lightweight Concrete, 4 (4), 229–233.
  • Qin, R., et al., 2019. Effect of shrinkage reducing admixture on new-to-old concrete interface. Composites Part B: Engineering, 167, 346–355.
  • Ramachandran, V. S, 1996. Concrete admixtures handbook: properties, science and technology, William Andrew.
  • Rith, M., et al., 2016. Analysis of in situ bond strength of bonded concrete overlay. Construction and Building Materials, 111, 111–118.
  • Shadmani, A., et al., 2018. Durability and microstructure properties of SBR-modified concrete containing recycled asphalt pavement. Construction and Building Materials, 185, 380–390.
  • Shaker, F., El-Dieb, A., and Reda, M., 1997. Durability of styrene-butadiene latex modified concrete. Cement and Concrete Research, 27 (5), 711–720.
  • Shin, H.-C., and Lange, D. A., 2004. Effects of shrinkage and temperature in bonded concrete overlays. Materials Journal, 101 (5), 358–364.
  • Shui, Z.-h., et al., 2010. Effects of mineral admixtures on the thermal expansion properties of hardened cement paste. Construction and Building Materials, 24 (9), 1761–1767.
  • Soni, E. K., and Joshi, Y., 2014. Performance analysis of styrene butadiene rubber-latex on cement concrete mixes. Journal of Engineering Research and Applications, 3 (1), 838–844.
  • Sprinkel, MM, and Ozyildirim, C, 2000. Evaluation of high performance concrete overlays placed on Route 60 over Lynnhaven Inlet in Virginia. Virginia Transportation Research Council.
  • Wyrzykowski, M., and Lura, P., 2013. Moisture dependence of thermal expansion in cement-based materials at early ages. Cement and Concrete Research, 53, 25–35.
  • Zhou, C., Shu, X., and Huang, B., 2014. Predicting concrete coefficient of thermal expansion with an improved micromechanical model. Construction and Building Materials, 68, 10–16.
  • Zhu, X. B., et al., 2013. Influence and mechanisms of in situ toughening telechelic polymer on the microstructure of concrete. Key Engineering Materials, Trans Tech Publ.

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