A synopsis about the effect of basalt and natural fibers on geopolymer properties
Vol 1, Issue 1, 2018
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Abstract
Currently, the introducing of basalt and natural fibers into different geopolymer swift growth of geopolymers. Despite of geopolymers have good properties such as fire resistance, flame resistance, higher compressive strength and higher durability, they suffer from low tensile strength and flexural strength. Different types of fibers were used to increase flexural strength, tensile strength, fracture toughness and ductility of geopolymers. The current article goals to brief the available earlier studies focused on the effect of basalt fibers and different natural fibers on the properties of geopolymers.
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1. Rashad AM. An investigation on very high volume slag pastes subjected to elvated temperatures. Construction and Building Materials 2015; 74: 249-258.
2. Rashad AM, Sadek DM. An investigation on Portland cement replaced by high-volume GGBS pastes modified with micro-sized metakoalin subjected to elevated temperature. International Journal of Sustainable Built Environment 2017; 6: 91-100.
3. Rashad AM, El-Nouhy H, Zeedan SR. An investigation on HVS paste modified with nano-SiO2 imperiled to elevated temperature. Arabian Journal for Science and Engineering 2017, https://doi.org/10.1007/s13369-017-2985-1.
4. Rashad AM. A brief on blast-furnace slag and copper slag as fine aggregate in mortar and concrete based on Portland cement. Reviews on Advanced Materials Science 2015; 4: 278-306.
5. Rashad AM. Alkali-activated metakaolin: A short guide for civil Engineer – An overview. Construction and Building Materials 2013; 41: 751-765.
6. Rashad AM. A comprehensive overview about the influence of different additives on the properties of alkali-activated slag – A guide for Civil Engineer. Construction and Building Materials 2013; 47: 29-55.
7. Rashad AM. A comprehensive overview about the influence of different admixtures and additives on the properties of alkali-activated fly ash. Materials and Design 2014; 53: 1005-1025.
8. Fiore V, Scalici T, Bella G. Di, et al. A review on basalt fibre and its composites. Composites Part B 2015; 74: 74-94.
9. Dhand V, Mittal G, Rhee KY, et al. A short review on basalt fiber reinforced polymer composites. Composites: Part B 2015; 73: 166-180.
10. Bhat T, Chevali V, Liu X, et al. Fire structural resistance of basalt fibre composite. Composites: Part A 2015; 71: 107-115.
11. Saba N, Jawaid M, Alothman OY, et al. A review on dynamic mechanical properties of natural fibre reinforced polymer composites. Construction and Building Materials 2016; 106: 149-159.
12. Malkapuram R, Kumar V, Yuvraj SN. Recent development in natural fibre reinforced polypropylene composites. Journal of Reinforced Plastics and Composites 2008; 28: 1169-1189.
13. Abiola OS, Kupolati WK, Sadiku ER, et al. Utilisation of natural fibre as modifier in bituminous mixes: A review. Construction and Building Materials 2014; 54: 305-312.
14. Oda S, Jr José Leomar, Ildefonso JS. Analysis of use of natural fibers and asphalt rubber binder in discontinuous asphalt mixtures. Construction and Building Materials 2012; 26: 13-20.
15. Punyamurthy R, Sampathkumar D, Bennehalli B, et al.Abaca Fiber Reinforced Epoxy Composites: Evaluation of Impact Strength. International Journal of Sciences: Basic and Applied Research (IJSBAR), 2014; 18(2): 305-317.
16. Odera RS., Onukwuli OU, Atuanya CU. Characterization of the Thermo-Microstructural Analysis of Raffia Palm Fibers Proposed for Roofing Sheet Production. Journal of Minerals and Materials Characterization and Engineering 2015; 3: 335-343.
17. Li WM, Xu JY. Impact characterization of basalt fiber reinforced geopolymeric concrete using a 100-mm-diameter split Hopkinson pressure bar. Materials Science and Engineering A 513-514 2009; 145-153.
18. Li WM, Xu JY. Mechanical properties of basalt fiber reinforced geopolymeric concrete under impact loading. Materials Science and Engineering A 2009; 505: 178-186.
19. Masi G, Rickard William DA, Bignozzi MC. The effect of organic and inorganic fibres on the mechanical and thermal properties of aluminate activated geopolymers. Composites Part B 2016; 76: 218-228.
20. Dias DP, Thaumaturgo C. Fracture toughness of geopolymeric concretes reinforced with basalt fibers. Cement & Concrete Composites 2005; 27: 49-54.
21. Zhang HY, Kodur V, Qi SL, et al. Characterizing the bond strength of geopolymers at ambient and elevated temperatures. Cement & Concrete Composites 2015; 58: 40-49.
22. Kumutha R, Fathima IS, Vijai K. Experimental investigation on properties of basalt fiber reinforced geopolymer concrete. IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE) 2017; 14(3): 105-109.
23. Arunagiri K, Elanchezhiyan P, Marimuthu V, et al. Mechanical properties of basalt fiber based geopolymer concrete. International Journal of Science, Engineering and technology Research (IJSETR), 2017; 6(4): 551-556.
24. Ronad A, Karikatti VB, Dyavanal SS. A study on mechanical properties of geopolymer concrete reinforced with basalt fiber. International Journal of Research in Engineering and Technology (IJRET), 2016; 5(7): 474-478.
25. Timakul P, Rattanaprasit W, Aungkavattana P. Improving compressive strength of fly ash-based geopolymer composites by basalt fibers addition. Ceramics International 2016; 42: 6288-6295.
26. Malenab Roy Alvin J, Ngo Janne Pauline S, Promentilla Michael Angelo B. Chemical treatment of waste abaca for natural fiber-reinforced geopolymer composite. Materials 2017; 10(579): 1-19. DOI:10.3390/ma10060579.
27. Chen R, Ahmari S, Zhang LY. Utilization of sweet sorghum fiber to reinforce fly ash-based geopolymer J Mater Sci 2014; 49: 2548-2558.
28. Koniejenko K, Fraczek E, Pytlak E, et al. Mechanical properties of geopolymer composites reinforced with natural fibers. Procedia Engineering 2016; 151: 388-393.
29. Alomayri T, Shaikh FUA, Low IM. Characterisation of cotton fibre-reinforced geopolymer composites. Composites: Part B 2013; 50: 1-6.
30. Alomayri T, Low IM. Synthesis and characterization of mechanical properties in cotton fiber-reinforced geopolymer composites. Journal of Asian Ceramic Societies 2013;1: 30-34.
31. Patel R, Joshi R. Analysis of development of porous fly ash-based geopolymer with low thermal conductivity. International Advanced Research Journal in Science, Engineering and Technology 2016; 3(12): 171-178.
32. Kumar H. Teja Kiran. Experimental study on coir fibre reinforced flyash based geopolymer concrete with 12M molar activator. International Journal of Civil Engineering and Technology (IJCIET) 2017; 8(1): 438-443.
33. Bhavsar G, Goliya SS, Dhakre OS. Optimizing the strength of rigid pavement by replacing Class F Flyash in geopolymer concrete by coconut fiber ash. International Journal of Engineering Development and Research (IJEDR) 2016; 4(3): 465-472.
34. Alzeer M, MacKenzi K. Synthesis and mechanical properties of novel composites of inorganic polymers (geopolymers) with unidirectional natural flax fibres (phormium tenax). Applied Clay Science 75-76-2013; 148-152.
35. Alzeer M, MacKenzie Kenneth JD. Synthesis and mechanical properties of new fibre-reinforced composites of inorganic polymers with natural wool fibres. J Mater Sci 2012; 47: 6958-6965.
DOI: https://doi.org/10.24294/nrcr.v1i2.752
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