Browse > Article
http://dx.doi.org/10.5764/TCF.2021.33.4.327

Study on the Mechanical Properties of Rubber Composite Materials Contained PBO, Aramid Chopped Fiber  

Lee, Jun Hee (Korea Textile Development Institute)
Lee, Kwang-Woo (School of Textile and Fashion Design, Kyungpook National University)
Publication Information
Textile Coloration and Finishing / v.33, no.4, 2021 , pp. 327-337 More about this Journal
Abstract
The uniformly dispersed Aramid and Poly (phenylene benzobisoxazole) (PBO) in a variety of rubber was investigated. The mechanical properties of rubber were characterized by hardness, tensile strength, elongation at break, heat resistance, oil resistance, cold resistance, ozone resistance measurements. The 3mm Aramid chopped fiber better tensile strength than the other Chopped fiber. The Aramid of 3mm chopped fiber showed excellent reinforcing in rubber composite because of homogeneous dispersion. Consequently, the best 3mm Aramid chopped fiber and rubber improved the tensile strength and elongation at break of the composite. Also, 3mm Aramid chopped fiber improved the oil-resistant, ozone resistant and cold resistant.
Keywords
aramid; chopped fiber; mechanical properties; poly(phenylene benzobisoxazole) (PBO); rubber composites;
Citations & Related Records
연도 인용수 순위
  • Reference
1 J. K. Kim and Y. J. Yum, Effect of Interface in Three Phase Cord-rubber Composites, Transactions of Korean Society of Mechanical Engineering, 33(11), 1249(2009).   DOI
2 T. S. Lee, B. S. Kim, H. N. Choi, K. Y. Lee, and S. G. Lee, Interfacial Adhesion Properties of Plasma Treated Aramid Fiber with Chloroprene Rubber, Textile Science and Engineering, 47(3), 205(2010).
3 M. R. Kashani, Aramid-Short-Fiber Reinforced Rubber as a Tire Tread Composite, Journal of Applied Polymer Science, 133, 1355(2009).   DOI
4 B. Zhang, X. Shao, T. Liang, W. Wang, M. Tian, N. Ning, and L. Zhag, Enhanced Interfiacial Adhesion of Aramid Fiber Reinforced Rubber Composites through Bio-inspired Surface Modification and Aramid Nanofiber Coating, Applied Polymer Science, 138(39), 1(2021).
5 S. H. Jeong, J. H. Song, H. Huh, J. W. Kim, and J. Y. Kim, 3-D Finite Element Modeling of Fiber Reinforced Rubber Composites using a Rebar Element, Transactions of Korean Society of Mechanical Engineering, 30(12), 1518(2006).   DOI
6 S. Y. Bak, Y. M. Baek, Y. Kim, and S. K. An, Mechanical Properties of Composites According to Weft Types of Unidirectional Aramid Fabrics, The Korean Fiber Society, 57(1), 57(2020).
7 Z. Hashin, Thin Interphase/Imperfect interface in conduction, Journal of Applied Physics, 89(4), 2261(2001).   DOI
8 N. V. David, X. L. Gao, and J. Q. Zheng, Creep of a Twaron®/Natural Rubber Composite, Mechanics of Advanced Materials and Structures, 20, 464(2013).   DOI
9 Y. S. Park and K. H. Chung, Effect of Surface Modification of Polyester Cord on the Adhesion of SBR/Polyester, Elastomer, 42(2), 75(2007).
10 S. G. Bang, D. J. Yeom, Y. J. Jeong, H. T. Kim, J. D. Kim, and J. M. Lee, Effect of Aramid Fiber on the Mechanical Properties of Secondary Barrier for LNG Cargo Containment System, Journal for the Society of Naval Architects of Korea, 58(4), 206(2021).   DOI
11 C. Xie, Z. X. Guo, T. Qiu, and X. Tuo, Construction of Aramid Engineering Materials via Polymerization Induced para-Aramid Nanofiber Hydrogel, Advance Materials, 33(31), 1(2021).