Damping Properties of Novel Organic Hybrids of Textile Reclaimed Rubber and Hindered Phenol

Xiao Ou Zhou; Sheng Jiang; Xiong Yan; Xue Ting Liu; Li Li

doi:10.4028/www.scientific.net/AMR.834-836.195

Paper Titles

Study on Natural Rubber Quality of Micro-Cut Tapping with Gas-Stimulation
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Research on Insulator Detection by Nuclear Magnetic Resonance
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Preparation and Electromagnetic Properties of CIP/SiO₂/PANI Composites
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Research of the Stability of Stiffened Composite Panel
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Damping Properties of Novel Organic Hybrids of Textile Reclaimed Rubber and Hindered Phenol
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The Property of Waterborne UV-Curable Polyurethane Based on Alkali Lignin of Wheat Straw
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Co-Extrusion of Wood Flour/PP Composites with PP-Based Cap Layer Reinforced with Macro-and Micro-Sized Cellulosic Fibres
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Preparation of Porous Titanium with High Porous Titanium and Surface Modification with High Concentration Alkaline Treatment
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Effect of 1-(9-Ethyl-9H-carbazol-3-yl)-4,4,4-trifluorobutane-1,3-dione on Properties of Luminescent Europium (III) Complexes
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Damping Properties of Novel Organic Hybrids of Textile Reclaimed Rubber and Hindered Phenol

Abstract:

A series of thin, low-cost and environment-friendly organic hybrid composites consisting of reclaimed rubber (R-Rubber) which is a waste product of roller processing of textile mill filled with organic hindered phenol compound 2, 2-methylenebis (6-tert-butyl-4-methyl-phenol) (AO2246) were fabricated. In this study the damping property of the R-Rubber composites were tested in the dynamic mechanical analysis (DMA). The study concluded that R-Rubber/AO2246 composites exhibited an exceptional damping performance with a broad temperature range. Meanwhile, by addition of AO2246, the tan δ peak maximum (tan δ _max) of R-Rubber/AO2246 composite was remarkably increased up to 1.5. Furthermore, with increasing the AO2246 content, storage modulus (E') and loss modulus (E") increases up to R-Rubber/AO2246 (100/80) and then becomes smaller. There is critical value on E and E" increasing which is caused by the excessive crystallization. The Interaction of AO2246 crystallizing, hybridized state and Molecular hydrogen bond led not only to control Tan δ _max of R-Rubber, but also to regulate glass transition temperature and improve the storage modulus, which make R-Rubber have potential applications in fields of engineering.