A Review on Utilization of Light Weight Fly Ash Cenosphere as Filler in both Polymer and Alloy-Based Composites

[1] ASM International Engineered Materials Handbook, Desk Edition, www.asm-intl.org 1995.

[2] L Mohammed , M N M Ansari, G Pua, J Mohammad, IM Saiful, “A Review on Natural Fiber Reinforced Polymer Composite and Its Applications,” International Journal of Polymer Science Volume 2015.

[3] KY Lee, A Yvonne , AB Lars, O Kristiina, B Alexander, “On the use of nanocellulose as reinforcement in polymer matrix composites,” Composites Science and Technology 105, pp 15-27, 2014.

[4] Bryan Harris Engineering composite materials. The Institute of Materials, London 1999.

[5] PH Holloway and ‎P N Vaidyanathan, “Characterization of Metals and Alloys,” Momentum Press, New York 1993.

[6] K Friedrich, S Fakirov, Z Zhang, “Polymer Composites: From Nano- to Macro-Scale,” Springer, America 2005.

[7] Parker Jacob, “Fly Ash: Properties, Analysis and Performance,” Nova Science Publishers, UK 2017.

[8] S Firat, G S Yılmaz, T Comert, M Sumer, “Utilization of marble dust, fly ash and waste sand (Silt-Quartz) in road subbase filling materials,” KSCE Journal of Civil Engineering, 16(7), 2012.

[9] BI Oza and A S Amin, “Effect of untreated Cenosphere on Mechanical properties of Nylon-6,” International Journal on Recent and Innovation Trends in Computing and Communication, 3(2321-8169), 2015.

[10] S Anandhan, “Recent Trends in Fly Ash Utilization in Polymer Composites,” Int J Waste Resources, 4 (3), 2014.

[11] Syntactic Foam Oxford English Dictionary citation of science: News Let. 2 Apr. 213/3.

[12] ASTM International, “Engineering Materials Handbook,” www.astm.org 1995.

[13] A H Landrock, “Handbook of Plastic Foams: Types, Properties, Manufacture and Applications,” Edited Noyes Publications, New Jersey, 147-163, 1995.

[14] J Rahul and T Hareesh, “Processing, compression response and finite element modeling of syntactic foam based interpenetrating phase composite (IPC),” Materials Science and Engineering A, 499, pp 507–517, 2009.

[15] N Gupta, B S Brar, B S Woldesenbet, “Effect of filler Addition on the Compressive and Impact Properties of Glass Fibre Reinforced Epoxy,” Bulletin of Materials Science, 2, pp 219-223, 2001.

[16] K V Joseph, F Finjin, C Joyson, P Das, G Hebbar, “FLY Ash Cenosphere Waste Formation in Coal Fired Power Plants And Its Application as A Structural Material- A Review, International Journal of Engineering Research & Technology, 2(8), 2013.

[17] N Ranjbar and C Kunzel, “Cenospheres: A review,” Fuel, 207, pp 1-12, 2017.

[18] B R Manjunath, P Sadasivamurthy, P V Reddy, R H Karickal, “Studies on cenosphere as fillers for PVC compounds for application in electrical cables” Journal of the American Institute of Chemists Volume, 86(1), 2013.

[19] K R Pradeep, G Nikhil, F S Benjamin, D L Dung, “The synthesis, compressive properties, and applications of metal matrix syntactic foams,” The Journal of the Minerals, Metals & Materials Society, 63(2), pp 36–42, 2011.

[20] Johann Thim, “Performing plastics – How plastics set out to conquer the world of sports,” European Chemical Industry Council 2005, Retrieved 2009-08-07.

[21] A Das and B K Satapathy, “Structural, thermal, mechanical and dynamic mechanical properties of cenosphere filled polypropylene composites,” Materials and Design, 32, pp1477–1484, 2011.

[22] M Labella, E S Zeltmann, V C Shunmugasamy, N Gupta, R K Pradeep, “ Mechanical and thermal properties of fly ash/vinyl ester syntactic foams,” Fuel, 121, pp 240–249, 2014.

[23] N Chand, P Sharma, M Fahim, “Correlation of mechanical and tribological properties of organosilane modified cenosphere filled high density polyethylene,” Materials Science and Engineering A, 527, pp 5873–5878, 2010.

[24] T Morimoto, T Suzuki, H Iizuka, “Wear rate and fracture toughness of porous particle-filled phenol composites,” Composites Part B, 77, pp 19-26, 2015.

[25] N Guptaa, E Woldesenbet, P Mensah, “Compression properties of syntactic foams: effect of cenosphere radius ratio and specimen aspect ratio,” Composites: Part A, 35, pp 103–111, 2004.

[26] S R Chauhan and S Thakur, “Effects of particle size, particle loading and sliding distance on the friction and wear properties of cenosphere particulate filled vinylester composites” Materials and Design, 51, pp 398–408, 2013.

[27] P Sampathkumaran, Kishore, S Seetharamu, V V Pattanashetti, V V Kumar, S M Kumar, H B Niranjan, “Fly ash cenospheres as reinforcement in different polymer composites – a comparative study of physical and mechanical properties,” Indian Journal of Engineering & Material Sciences, 22, pp 354-362, 2015.

[28] V C Divya, M K Ameen, R B Nageshwar, R R Sailaja, “High density polyethylene/cenosphere composites reinforced with multi-walled carbon nanotubes: Mechanical, thermal and fire retardancy studies,” Materials and Design, 65, pp 377–386, 2015.

[29] H B Jalageri, G U Raju, K G Kodancha, “Experimental Investigations on Mechanical Properties of Cenosphere/MWCNT Reinforced Polymer Nanocomposites,” American Journal of Materials Science, 5(3C), pp 101-106, 2015.

[30] S Ren, X Tao, X Ma, J Liu, “Fabrication of fly ash cenospheres-hollow glass microspheres/borosilicate glass composites for high temperature application,” Ceramics International, 44(1), 2017.

[31] R Balaji, M Sasikumar, A Elayaperumal, “Thermal, thermo oxidative and ablative behavior of cenosphere filled ceramic/phenolic composites,” Polymer Degradation and Stability, 114, pp 125-132, 2015.

[32] M R Wang, D C Jia, P G He, Yu Zhou, “Microstructural and mechanical characterization of fly ash cenosphere/metakaolin-based geopolymeric composites,” Ceramics International, 37, pp 1661–1666, 2011.

[33] P J Bora, M Porwal, K J Vinoy, Kishore, P C Ramamurthy, M Giridhar, “Industrial waste fly ash cenosphere composites based broad band microwave absorber,” Composites Part B: Engineering, 134(1), pp 151-163, 2018.

[34] R Balaji and M Sasikumar, “A study on the effect of cenosphere on thermal and ablative behavior of cenosphere loaded ceramic/phenolic composites," Polymer, 55, pp 6634-6639, 2014.

[35] P Sambyal, G Ruhi, Bhandari Hema, K D Sundeep, “Advanced anti corrosive properties of poly (aniline-co-o-toluidine)/ flyash composite coatings,” Surface & Coatings Technology, 272, pp 129–140, 2015.

[36] J Sharma, N Chand, M N Bapat, “Effect of cenosphere on dielectric properties of low density polyethylene,” Results in Physics, 2, pp 26–33, 2012.

[37] J Gu, G Wu, X Zhao, “Damping properties of fly ash/epoxy composites. Journal of University of Science and Technology Beijing” 15(4),pp 509, 2008. [38] S B Angadi, R Melinamani, V Gaitonde, M Doddamani, S R Karnik, “Experimental Investigations on Drilling Characteristics of Cenosphere Reinforced Epoxy Composites,” Applied Mechanics and Materials, 766-767, 801-811, 2015.

[38] V Chandel, O S Bhatia, M S Sethi, “Fabrication and Characterization of Al 7075-Cenosphere Composite & Its Comparison with Pure Al 7075: A Review,” International Journal of Research Studies in Science, Engineering and Technology, 2(3), pp 7-20, 2015.

[39] C Vikrant and S B Onkar, “Fabrication and Characterization of Al 7075-Cenosphere Composite & its comparison with pure Al 7075,” International Journal of Engineering Trends and Technology, 29(3), 2015.

[40] M D Goel, D P Mondal, M S Yadav, S K Gupta, “Effect of strain rate and relative density on compressive deformation behavior of aluminum cenosphere syntactic foam,”. Materials Science & Engineering A, 590, pp 406–415, 2014.

[41] S Birla, D P Mondal, S Das, D K Kashyap, “Effect of cenosphere content on the compressive deformation behaviour of aluminum-cenosphere hybrid foam,” Materials Science & Engineering A, 685, pp 213–226, 2017.

[42] P K Rohatgi, A Daoud, B F Schultz, T Puri, “Microstructure and mechanical behavior of die casting AZ91D-Fly ash cenosphere composites,” Composites: Part A, 40, pp 883–896, 2009.

[43] S P Kumarasamy, Vijayananth Kavimani, T Thankachan, G P Muthukutti, “Investigations on mechanical and machinability behavior of aluminum/ flyash cenosphere /Gr hybrid composites processed through compocasting,” Journal of Applied Research and Technology, 15(5), pp 430-441, 2017.

[44] Z Huang and S Yu, “Microstructure characterization on the formation of in situ Mg2Si and MgO reinforcements in AZ91D/Flyash composites,” Journal of Alloys and Compounds, 509, pp 311–315, 2011.

[45] A Vishwakarma, D P Mondal, S Birla, S Das, “Effect of cenosphere size on the dry sliding wear behaviour LM13- cenosphere syntactic foam,” Tribology International, 110, pp 8–22, 2017.

[46] W A Uju and I N Oguocha, “A study of thermal expansion of Al–Mg alloy composites containing fly ash” Materials and Design, 33, pp 503–509, 2012.

[47] V Saravanan, P R Thyla, S R Balakrishnan, “A low cost, light weight cenosphere–aluminium composite for brake disc application,” Bull. Mater. Sci., 39 (1), pp 299–305, 2016.

[48] D D Luong, N Gupta, A Daoud, P K Rohatgi, “High strain rate compressive characterization of aluminum alloy/ Fly ash cenosphere composites,” JOM, 63(2), 2011.