The hot pressing process parameters were optimized to prepare flax fiber reinforced polyethylene (PE) thermoplastic composite by the Taguchi method. The optimal hot pressing process parameters were determined to increase the tensile strength of the composite. The optimal parameters of the design include the following sections: hot pressing temperature, pressure, hot pressing time and coupling agent modification time. An L9 (3*4) orthogonal matrix based on the Taguchi method was created. By means of analysis of signal-to-noise ratio and analysis of variance, the optimal hot pressing process parameters combination was found, compared to the average tensile strength in the nine design experiments, and the tensile strength was improved nearly 10%.

flax fiber; hot pressing process; optimization; Taguchi method; ANOVA

Witik RA, Payet J, Michaud V, et al. Assessing the life cycle costs and environmental performance of lightweight materials in automobile applications. Composite Part A: Applied Science and Manufacturing 2011; 42(11): 1700–1709.

Oksman K, Skrifvars M, Selin JF, et al. Natural fibers as reinforcement in polylactic acid (PLA) composite. Composite Science and Technology 2003; 63(9): 1317–1324.

Joshi SV, Drzal LT, Mohanty AK, et al. Are natural fiber composites environmentally superior to glass fiber reinforced composites? Composites Part A: Applied Science and Manufacturing. 2004; 35(3): 370–376.

4 Snoeck D, Belie ND. Mechanical and self-healing properties of cementitious composite reinforced with flax and cottonised flax, and compared with polyvinyl alcohol fibers. Biosystems Engineering 2012; 111: 325–350.

Charlet K, Beakou A. Mechanical properties of interfaces within a flax bundle – Part I: Experimental analysis. International Journal of Adhesion and Adhesives 2011; 31: 875–890.

Shah DU, Porter D, Vollrath F, et al. Can silk become an effective reinforcing fibers? A property comparison with flax and glass reinforced composite. Composite Science and Technology 2014; 101: 173–183.

GARKHAIL SK, HEIJENRATH RWH, PEIJS T. Mechanical Properties of Natural-Fibre-Mat-Reinforced Thermoplastics based on Flax Fibres and Polypropylene. Applied Composite Materials 2000; 7: 351–372.

Woigk W, Fuentes CA, Rion J, et al. Interface properties and their effect on the mechanical performance of flax fiber thermoplastic composite. Composite Part A: Applied Science and Manufacturing 2019; 122: 8–17.

Dicker MPM, Duckworth PF, Baker AB, et al. Green composite: a review of material attributes and complementary applications. Composite Part A: Applied Science and Manufacturing 2014; 56: 280–291.

Duc F, Bourban PE, Plummer CJG, et al. Damping of thermoset and thermoplastic flax fiber composite. Composite Part A: Applied Science and Manufacturing 2014; 64: 115–230.

Zhang W, Huang S. Hemp fiber reinforced thermoplastic composite material and its development and application. FRP/composite 2010; 2(03): 81–83.

Fu CL, Wang XL, Cui P, et al. Performance comparison of three kinds of plant fiber/polypropylene composite. Journal of Textile Science and Engineering 2018; 35(03): 110–112.

Oksman K, Skrifvars M, Selin JF. Natural fibers as reinforcement in polylactic acid (PLA) composites. Composites Science and Technology 2003; 63: 1317–1324.

Yang B, Wang JY, Yan BJ, et al. Preparation and Mechanical Properties Analysis of Jute Fiber/ES Fiber Composite. Shanghai Textile Technology 2017; 45(06): 26–29.

Yan TH. Research on molding process and properties of

flax thermoplastic reinforced composite. Shanghai: Dong hua University, 2009. 50–86.

Liu TS. Research on Dry Hot Pressing Process Optimization and Molding Equipment for Plant Fiber Tableware. China Academy of Agricultural Mechanization Sciences 2009; 40: 200–218.

Arbelaiz A, Ferna´ndez B, Ramos JA, et al. Mechanical properties of short flax fibre bundle/polypropylene composites: Influence of matrix/fibre modification, fibre content, water uptake and recycling. Composites Science and Technology 2005; 65: 1582–1592.

Mo ZC, Hu CY, Guo CC, et al. Intercalation of ramie short fiber between carbon fiber/epoxy matrix composite. Journal of Composite Materials 2017; 34(06): 1237–1244.

Wang YJ, Meng JG, Zhang YF, et al. Performance Test of Aramid Modified by Silane Coupling Agent. Synthetic fiber 2017; 46(04): 43–46.

Ma W. Preparation and properties of thermoplastic natural bamboo fiber composite. Hangzhou: Zhejiang Agriculture and Forestry University, 2012. 47–68.

Li X, Panigrahi S, Tabil LG. A study on flax fiber reinforced polyethylene biocomposites. Applied Engineering in Agriculture 2009; 25(4): 525–531.

Ku H, Wang H, Pattarachaiyakoop N, et al. A review on the tensile properties of natural fiber reinforced polymer composites. Composites: Part B 2011; 42: 856–873.

Wang YQ, Afsar AM, Song JI. Optimization of brazing conditions for OFHC Cu and ASTM A501 low carbon steel by Taguchi method. International Journal of Precision Engineering and Manufacturing 2009; 10: 97–104.

Wang YQ, Byun JH, Kim BS, et al. The use of Taguchi optimization in determining optimum electrophoretic conditions for the deposition of carbon nanofiber on carbon fibers for use in carbon/epoxy composite. Carbon 2012; 50: 2853–2859.

Taguchi G. Introduction to quality engineering. New York: McGraw-Hill; 1990.

Roberts MJ, Russo R. A student’s guide to analysis of variance. London: Routledge, 2009. 92–109.

Montgomery DC. Design and analysis of experiments (5th ed.). New York: John Wiley Sons, 2001. 65–72.