Evaluation of composites made from blends of cotton burs, cotton stalks, kenaf, flax, and southern pine: Heat treatments to improve physical and mechanical properties and rot resistance

Authors: Holt, Gregory; Wanjura, John; Pelletier, Mathew; CHOW, P - University Of Illinois; WEDEGAERTNER, T - Cotton, Inc

Submitted to: National Cotton Council Beltwide Cotton Conference
Publication Type: Abstract Only
Publication Acceptance Date: 11/17/2012
Publication Date: 1/7/2013
Citation: Holt, G.A., Wanjura, J.D., Pelletier, M.G., Chow, P., Wedegaertner, T.C. 2013. Evaluation of composites made from blends of cotton burs, cotton stalks, kenaf, flax, and southern pine: Heat treatments to improve physical and mechanical properties and rot resistance. National Cotton Council Beltwide Cotton Conference. 2013 Beltwide Cotton Conferences, San Antonio, Texas, January 7-10, 2013. Pg. 746.

Interpretive Summary:

Technical Abstract: Experiments were conducted on composite board blends of cotton burs (B), cotton stalks (S), kenaf (K), flax, (F), and southern yellow pine (P). The composite boards were subjected to heat treatments and rot resistance testing. Heat treatments consisted of heating fibers either pre- or post-board fabrication using an oven at 365 deg F for 30 minutes. Board construction was accomplished using a 100-ton capacity oil-heated hydraulic press.Composite boards were produced using the following blend of fibers: 100% B, 50B/50K, 50B/50S, 50B/50F, 50B/50P, 100P, 100H, 100F, 100S, and 100K. Three specimens from each board were subjected to water absorption, thickness swelling, internal bond, and static bending stresses (modulus of rupture [MOR] and modulus of elasticity [MOE]). The testing was performed in accordance with methods described in Part B of the American Society for Testing and Materials (ASTM) D 1037-06a. For the rot resistance testing, three common rot fungi were used on heat treated and untreated boards made from blends of the biomasses previously listed, using ASTM D 2017. Results indicate heat-treating the fibers post-fabrication improved water absorption in all boards compared to untreated specimens. Heat treating had mixed effects on MOE, MOR, and internal bond with some fiber composites having improved values while others had lower values. Composites with flax fibers exhibited water resistance equivalent to the 100% P and H composites. For rot resistance testing, there were no significant weight loss differences due to heat treating. Wood blend composites had, on average, less weight loss than other blends for two of the three fungal species evaluated.