Journal of Engineering and Applied Sciences
Year:
2018
Volume:
13
Issue:
5
Page No.
1210 - 1218
References
Al-Hadithi, A.I. and M.F.A. Alani, 2015. Mechanical properties of high performance concrete containing waste plastic as aggregate. J. Eng., 21: 100-115.
Al-Hadithi, A.I. and N.N. Hilal, 2016. The possibility of enhancing some properties of self-compacting concrete by adding waste plastic fibers. J. Build. Eng., 8: 20-28.
Direct Link | Al-Hadithi, A.I., 2008. Some properties of concrete using waste plastic fiber with a very small percentages. Proceedings of the 1st International Conference on Engineering Sciences (IESC’08), November 2-4, 2008, University of Aleppo, Aleppo, Syria, pp: 1-8.
Al-Hadithi, A.I., 2013. Improving impact and mechanical properties of gap-graded concrete by adding waste plastic fibers. Intl. J. Civ. Eng. Technol. India, 4: 118-131.
Al-Hadithi, A.I., A.T. Noaman and G.S. Jamil, 2013. Behaviour of waste plastic fiber concrete slabs under low velocity impact. Iraqi J. Civ. Eng., 9: 135-148.
Direct Link | Al-Obaidi, Z., 2013. The possibility of enhancing the impact strength property of ferro cement panels by using waste plastic fibers. MSc Thesis, University of Anbar, Ramadi, Iraq.
Al-Rawi, M.I., 2011. Flexural behavior of reinforced concrete beams enhancement with waste plastic fibers. MSc Thesis, University of Tikrit, Tikrit, Iraq.
Anonymous, 1984. Specification for aggregate from natural sources for concrete and building construction. Iraqi Standard Specifications/45, Baghdad, Iraq.
Anonymous, 1984. Sulphate resistant cement. Iraqi Standard Specifications, Baghdad, Iraq.
Anonymous, 1996. ASTM A820/A820M-16 standard specification for steel fibers for fiber-reinforced concrete. ASTM International, Pennsylvania, USA. https://www.astm.org/Standards/A820.htm.
Anonymous, 2002. ASTM C78-02 standard test method for flexural strength of concrete (using simple beam with third-point loading). ASTM International, Pennsylvania, USA. https://www.astm.org/DATABASE.CART/HISTORICAL/C78-02.htm.
Anonymous, 2009. Converting waste plastics into a resource. United Nations Environment Programme, International Environmental Technology Center, Nairobi, Kenya.
Anonymous, 2009. Converting waste plastics into a resource. United Nations Environment Programme, UN Environment International Environmental Technology Center, Osaka, Japan. http://www.unep.or.jp/Ietc/Publications/spc/WastePlasticsEST_AssessmentGuidelines.pdf.
Baldenebro-Lopez, F., J. Castorena-Gonzalez, J. Velazquez-Dimas, J. Ledezma-Sillas and C. Gomez-Esparza
et al., 2014. Influence of continuous plastic fibers reinforcement arrangement in concrete strengthened. IOSR. J. Eng., 4: 15-23.
Direct Link | Batayneh, M., I. Marie and I.M. Asi, 2007. Use of selected waste materials in concrete mixes. J. Waste Manage., 27: 1870-1876.
Direct Link | Chavan, S. and P. Rao, 2016. Utilization of waste PET bottle fibers in concrete as an innovation in building materials-[a review paper]. Intl. J. Eng. Res., 5: 304-307.
Direct Link | Daud, M.A.M., H.M. Desa, N. Wahidudin and K. Mohamed, 2012. Influence of polymer waste (Polyethylene Terephthal ate) in composites structure materials. Eur. Intl. J. Sci. Technol., 1: 15-22.
Direct Link | Daud, M.A.M., M.Z. Selamat and A. Rivai, 2013. Effect Pf thermoplastic polymer waste (PET) in lightweight concrete. Adv. Mater. Res., 795: 324-328.
CrossRef | Direct Link | Ghernouti, Y., B. Rabehi, T. Bouziani, H. Ghezraoui and A. Makhloufi, 2015. Fresh and hardened properties of self-compacting concrete containing plastic bag waste fibers (WFSCC). Constr. Build. Mater., 82: 89-100.
CrossRef | Direct Link | Hannawi, K., W. Prince and S. Kamali-Bernard, 2010. Effect of thermoplastic aggregates incorporation on physical, mechanical and transfer behavior of cementitious materials. Waste Biomass Valorization, 1: 251-259.
CrossRef | Hannawi, K., W. Prince and S.K. Bernard, 2012. Strain capacity and cracking resistance improvement in mortars by adding plastic particles. J. Mater. Civ. Eng., 25: 1602-1610.
Direct Link | Kandasamy, R. and R. Murugesan, 2011. Fibre reinforced concrete using domestic waste plastics as fibres. ARPN J. Eng. Applied Sci., 6: 75-82.
Direct Link | Mark, J.E., 1999. Polymer Data Handbook. Oxford University Press, Oxford, England, UK., ISBN:9780195107890, Pages: 1018.
Marzouk, O.Y., R.M. Dheilly and M. Queneudec, 2007. Valorization of post-consumer waste plastic in cementitious concrete composites. Waste Manage., 27: 310-318.
CrossRef | Mesbah, H.A. and F. Buyle-Bodin, 1999. Efficiency of polypropylene and metallic fibres on control of shrinkage and cracking of recycled aggregate mortars. Constr. Build. Mater., 13: 439-447.
Direct Link | Neville, A.M., 1981. Properties of Concrete. 3rd Edn., Pitman Publishing, London, England, UK., ISBN:9780273016427, Pages: 779.
Nibudey, R.N., P.B. Nagarnaik, D.K. Parbat and A.M. Pande, 2013. A model for compressive strength of PET fiber reinforced concrete. Am. J. Eng. Res., 2: 367-372.
Pandya, J. and B.M. Purohit, 2013. Experimental study on the mechanical properties of concrete incorporating PET fibers. Intl. J. Sci. Res. Dev., 2: 43-45.
Direct Link | Prahallada, M.C. and K.B. Parkash, 2013. Effect of different aspect ratio of waste plastic fibers on the properties of fiber reinforced concrete e an experimental investigation. Intl. J. Adv. Eng. Res. Technol., 2: 1-13.
Rebeiz, K.S., D.W. Fowler and D.R. Paul, 1993. Recycling plastics in polymer concrete for construction applications. J. Mater. Civ. Eng., 5: 237-248.
Direct Link | Remadnia, A., R.M. Dheilly, B. Laidoudi and M. Queneudec, 2009. Use of animal proteins as foaming agent in cementitious concrete composites manufactured with recycled PET aggregates. Constr. Build. Mater., 23: 3118-3123.
Direct Link | Safi, B., M. Saidi, D. Aboutaleb and M. Maallem, 2013. The use of plastic waste as fine aggregate in the self-compacting mortars: Effect on physical and mechanical properties. Constr. Build. Mater., 43: 436-442.
Direct Link | Saikia, N. and J. de Brito, 2012. Use of plastic waste as aggregate in cement mortar and concrete preparation: A review. Constr. Build. Mater., 34: 385-401.
CrossRef | Direct Link | Sikalidis, C.A., A.A. Zabaniotou and S.P. Famellos, 2002. Utilisation of municipal solid wastes for mortar production. Resour. Conserv. Recycle., 36: 155-167.
Direct Link | Venu, M. and P.N. Rao, 2010. Effect of non bio degradable waste in Concrete slabs. Int. J. Civil Struct. Eng., 1: 449-457.
Direct Link | Verdolotti, L., F. Iucolano, I. Capasso, M. Lavorgna and S. Iannace
et al., 2014. Recycling and recovery of PE‐PP‐PET‐based fiber polymeric wastes as aggregate replacement in lightweight mortar: Evaluation of environmental friendly application. Environ. Prog. Sustainable Energy, 33: 1445-1451.
CrossRef | Direct Link |