Effects of Silica Ceramic Particle Sizes on the Properties of Recycled Polyethylene Composites

J.O. Agunsoye, S. I. Talabi, V. S. Aigbodion, A. Olumuyiwa

Abstract


Particulate filled polymeric composites are becoming attractive because of their wide applications and lower production cost. To evaluate the possibility of using waste silica based ceramic materials as reinforcing filler in recycled polyethylene (PE) composite, the effect of  ceramic (PC) particle sizes on the mechanical, wear and thermal behaviours of polyethylene (PE) composites were investigated at  (2wt% filler) and grain sizes (40µm-150µm). The wear behaviour was characterized using analysis of variance (ANOVA) and linear regression to determine the main and interactive effects of the process parameters such as speed, load and time on the wear behaviour of the fabricated PE-PC composites. Test results show that the decreasing the ceramic particles 150µm-40µm improved the mechanical, wear and thermal properties of the recycled polyethylene (PE) composites. Factorial design of the experiment can be successfully employed to describe the wear behavior  of the samples and developed linear equation for predicting wear rate with in selected experimental conditions.


References


[1]Matthews, F. L., & Rawlings, R. D. (1999). Composite materials: engineering and science. Woodhead Publishing.

[2] Aigbodion, V., Hassan, S., & Agunsoye, J. (2012). Effect of bagasse ash reinforcement on dry sliding wear behaviour of polymer matrix composites. Materials & Design, 33, 322–327.

[3] Friedrich, K., Lu, Z., & Hager, A. (1995). Recent advances in polymer composites’ tribology. Wear, 190(2), 139–144.

[4] Friedrich, K. (1986). Friction and wear of polymer composites. North Holland.

[5] Olumuyiwa, A. J., Isaac, T. S., Adewunmi, O. A., & Ololade, A. I. (2012). Effects of palm kernel shell on the microstructure and mechanical properties of recycled polyethylene/palm kernel shell particulate composites. Journal of Minerals and Materials Characterization and Engineering, 11, 825–831.

[6] Sarki, J., Hassan, S., Aigbodion, V., & Oghenevweta, J. (2011). Potential of using coconut shell particle fillers in eco-composite materials. Journal of Alloys and Compounds, 509(5), 2381–2385.

[7] Hassan, S., EJ, O., & Aigbodion, V. (2012). Potentials of maize stalk ash as reinforcement in polyster composites. Journal of Minerals & Materials Characterization & Engineering, 11(4), 543–557.

[8] Atuanya, C., Ibhadode, A., & Igboanugo, A. (2011). Potential of using recycled low-density polyethylene in wood composites board. African Journal of Environmental Science and Technology, 5(5), 389– 396.

[9] Unal, H., Mimaroglu, A., Kadoglu, U., & Ekiz, H. (2005). Wear behavior of pure polytetrafluoroethylene (ptfe) and its composites. Materials and Design, 24, 239.

[10] Suresha, B., Siddaramaiah, Kishorec, Seetharamud, S., & Sampath Kumarand, P. (2011). Wear behavior of graphite filled glass epoxy composites. Wear, 267, 1405.

[11] Naga Raju, B., Ramji, K., & Prasad, V. (2011). Studies on tribological properties of zno filled polymer nanocomposites. ARPN J Eng Appl Sci, 6, 75–82.

[12] Basavarajappa, K., B amd Arun, & Paulo Davim, J. (2009). Wear studies on glass fibre reinforced epoxy composites along with fillers sic and graphite. Journal of Minerals and Materials Characterization and Engineering, 8, 379.

[13] Vishwanath, V., Varma, A., & Kumeswara Rao, C. (1991). Wear studies on both polyester and phenolic reinforced glass fibre composites. Composite Sciences and Technology, 44, 77.

[14] M´alek, J. (1992). The kinetic analysis of nonisothermal data. Thermochimica acta, 200, 257–269.

[15] M´alek, J., Mitsuhashi, T., & Criado, J. M. (2001). Kinetic analysis of solid-state processes. Journal of Materials Research, 16(6), 1862–1871.

[16] Varhegyi, G., Antal Jr, M. J., Szekely, T., & Szabo, P. (1989). Kinetics of the thermal decomposition of cellulose, hemicellulose, and sugarcane bagasse. Energy & Fuels, 3(3), 329–335.

[17] Liu, N., & Fan, W. (1998). Modelling the thermal decompositions of wood and leaves under a nitrogen atmosphere. Fire and materials, 22(3), 103–108.




DOI: http://dx.doi.org/10.3968/j.ans.1715787020130601.1630

DOI (pdf): http://dx.doi.org/10.3968/g3659

DOI (indexed/included/archived): http://dx.doi.org/10.3968/g4585

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