PSI - Issue 27

Sakuri Sakuri et al. / Procedia Structural Integrity 27 (2020) 85–92 Sakuri et al. / Structural Integrity Procedia 00 (2019) 000 – 000

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elasticity increased, proportional to the alkali treatment and addition of microcrystalline cellulose. The highest flexural strength of AI 6 was 102.34 MPa, and modulus was 31% compared to before the treatment. References Aydin, M., Tozlu, H., Kemaloglu, S., Aytac, A., Ozkoc. G., 2011. Effect of alkali treatment on the properties of short flax fiber-poly (lactic acid) eco-composites. Journal of Polymers and the Environment 19(1), 11-17. Aziz, S.H., Ansell, M.P., 2004. The effect of alkalization and fibre aligment on the mechanical and thermal properties of kenaf and hemp bast fibre composites: Part 1-polyester resin matrix. Journal of Composite Science and Technology 64, 1219-1230. Azwa, Z.N., Yousif, B.F., Manalo, A.C., Karunasena, W., 2013. A review on the degradability of polymetric composites based on natural fibres. Material & Design 47, 424-442. Bae, D.M., Prabowo, A.R., Cao, B., Sohn, J.M., Zakki, A.F., Wang, Q., 2016. Numerical simulation for the collision between side structure and level ice in event of side impact scenario. Latin American Journal of Solids and Structures 13, 2991-3004. Bismarc, A., Mohanty, A.K., Aranberri-Askargorta, I., Chapla, S., Misra, M., Spingera, J., 2001. Surface characterization of natural fiber: surface properties and the water uptake behaviour of modified sisal and coir fibers. Green Chemistry 3, 100-107. Bisanda, E.T.N., 2000. The effect of alkali treatment on the adhesion characteristics of sisal fibres. Applied Composite Materials 7(5-6), 331-339. Cao, B., Bae, D.M., Sohn, J.M., Prabowo, A.R., Chen, T.H., Li, H., 2016. Numerical analysis for damage characteristics caused by ice collision on side structure. International Conference on Ocean, Offshore and Arctic Engineering 49996, V008T07A019. Cataldi, A., Berglund, L., Deflorian, F., Pegoretti A., 2015. Comparison between micro and nanocellulose – filled composite adhesives for oil paintings restoration. Nanocomposite 1, 195-203. Fisher, T., Hajaligol, M., Waymack, B., Kellogg, D., 2002. Low temperature formation of aromatic hydrocarbon from pyrolysis of cellulosic material. Fuel 80, 1799-1807. John, M.J., Anandiwala, R.D., 2008. Recent development in chemical modification and characterization of natural fiber – reinforced composites. Polymer composites 29, 187-207. Jacob, M., Thomas, S., Varugrese, K.T., 2004. Mechanical properties of sisal/oil palm hybrid fiber reinforced natural ruber composites. Composites Sciences and Technology 64, 955-965. Khalil, M.I., Motallib, M.A., Annisuzzaman, A.S.M., Sathi, Z.S., Hye, M.A., Shahjahan, M., 2001. Biomechanical analysis of different brands of unifloral honey available at the northem region of Bangladesh. Science 1, 385-388. Kabir, M.M., Wang, H., Lau, K.T., Cardona, F., 2013. Effect of chemical treatment on hemp fibre structure. Applied Surface Science 276, 13-23. Kiziltas, A., Gardner, D.J., Han, Y., Yang, H.S., 2014. Mechanical properties of microcrystalline cellulose (MCC) filled engineering composites. Journal of Polymers and the Environment 22(3), 365-372. Li, X., Tabil, L.G., Panigrahi, S., 2007. Chemical treatment of natural fiber for use in natural fiber-reinforced composites: a review. Journal of Polymers and the Environment 15, 25-33. Mohammed, M.H., Dauda, B., 2014. Unsaturated polyester resin reinforced with chemically modified natural fiber. Journal of Polymer and Textile Engineering 1, 31-38. Mostashari, S.M., Fallah, M.H., 2007. Thermogravimetric analysis of a cellulosic fabric incorporated with ammonium iron (ii)-sulfate hexahydrate as a flame retardant. Journal of Industrial Textile 37, 31-42. Palungan, M.B., Soenoko, R., Irawan, Y.S., Purnowidodo, A., 2017. The effect of fumigation treatment towards, Agave cantala Roxb fibre strength and morphology. Journal of Engineering Science and Technology 12, 1399-1414. Prabowo, A.R., Bae, D.M., Sohn, J.M., Zakki, A.F., Cao, B., Wang, Q., 2017. Analysis of structural behavior during collision event accounting for bow and side structure interaction. Theoretical and Applied Mechanics Letters 7, 6-12. Prabowo, A.R., Byeon, J.H., Cho, H.J., Sohn, J.M., Bae, D.M., Cho, J.M., 2018. Impact phenomena assessment: Part I – Structural performance of a tanker subjected to ship grounding at the Arctic. MATEC Web of Conferences 159, 02061. Prabowo, A.R., Sohn, J.M., Putranto, T., 2019. Crashworthiness performance of stiffened bottom tank structure subjected to impact loading conditions: Ship-rock interaction. Curved and Layered Structures 6, 245-258. Puvanasvaran, A.P., Sued, M.K., 2011. Investigation on the mechanical characteristics of sawdust and chipwood filled epoxy. Journal of Mechanical engineering and Technology 3(1), 71-78. Raharjo, W.W., Soenoko, R., Irawa, Y.S., Suprapto, A., 2017. Improvement in mechanical properties of cantala fiber and shot cantala/recycled high-density polyethelene composite through chemical treatment. Biomaterials, preprints . Ray, D., Sarkar, B.K., 2001. Characterization of alkali treatment jute fibers for physical and mechanical properties. Journal of Applied Polymer Science 80, 1013-1020.