Cure Characteristics and Physical Properties of Imperata cylindrica Activated Carbon Filled SMR L Compounding

• Published in: Applied Mechanics and Materials Vol. 815; no. Design and Development of Sustainable Manufacturing Systems; pp. 44 - 48
• Main Authors: Ting, Sam Sung, Salihin, M.Z., Husin, Kamarudin, Munirah, N.R., Noriman, N.Z., Hanafi, Ismail, Mustafa Al Bakri, A.M., Fatin, M.H.
• Format: Journal Article
• Language: English
• Published: Zurich Trans Tech Publications Ltd 01.11.2015
• Subjects: Activated carbon; Crosslinking; Cures; Elastomers; Fillers; Natural rubber; Physical properties; Resilience; Rigidity; Rubber; Torque; Vulcanization; Vulcanizing; Cure Characteristics; Standard Malaysian Rubber L (SMR L); Physical Properties; Imperata Cylindrica Activated Carbon
• ISBN: 303835676X; 9783038356769
• ISSN: 1660-9336; 1662-7482; 1662-7482
• DOI: 10.4028/www.scientific.net/AMM.815.44

The potential of activated carbon as a filler in rubber compound has been reviewed .Cure characteristics and physical properties of Imperata Cylindrica activated carbon filled natural rubber of Standard Malaysian Rubber (SMR L) were studied. SMR L was used as the elastomer and the composition of filler loading were varied from 0-50 parts per hundred rubber (phr). A semi-efficient vulcanization system was used throughout the study. The cure characteristics of the rubber compound was determined by using rheometer. The samples of hardness and resilience were measured by durometer shore A and Wallace Dunlop Tripsometer. Cure characteristics showed that cure time, t90 and scorch time,t2 increased as increased filler loading which indicate poor interaction between rubber and filler which slow down the vulcanization time. Minimum torque,ML and maximum torque,MH increased as increased filler loading due to the low processability of the SMR L compounds. Crosslink density and hardness exhibit increment as increased filler loading due to increase rigidity of the SMR L compounds. The resilience will decrease correspondingly as increased in rigidity of the compounds.