Sound Absorption Properties Of Single-Hole Hollow Polyester Fiber Reinforced Hydrogenated Carboxyl Nitrile Rubber Composites

• Autorzy: Jie H. , Sheng J. , Xiong Y.

Identyfikatory

DOI

10.1515/aut-2016-0014

• Języki publikacji: EN

Abstrakty

EN

A series of single-hole hollow polyester fiber (SHHPF) reinforced hydrogenated carboxyl nitrile rubber (HXNBR) composites were fabricated. In this study, the sound absorption property of the HXNBR/SHHPF composite was tested in an impedance tube, the composite morphology was characterized by scanning electron microscope (SEM), and the tensile mechanical property was measured by strength tester. The results demonstrated that a remarkable change in sound absorption can be observed by increasing the SHHPF content from 0% to 40%. In the composite with 40% SHHPF in 1 mm thickness, the sound absorption coefficient reached 0.671 at 2,500 Hz; the effective bandwidth was 1,800-2,500 Hz for sound absorption coefficient larger than 0.2. But the sound absorption property of the composite deteriorated when the SHHPF content increased to 50% in 1 mm thickness. While with 20% SHHPF proportion, the sound absorption property was improved by increasing the thickness of composites from 1 to 5 mm. Compared with the pure HXNBR of the same thickness, the tensile mechanical property of the composite improved significantly by increasing the SHHPF proportion. As a lightweight composite with excellent sound absorption property, the HXNBR/SHHPF composite has potential practical application value in the fields of engineering.

Słowa kluczowe

EN

hollow; polyester fiber; hydrogenated carboxyl nitrile rubber; HXNBR; sound absorption; composite

PL

wgłębienie; włókno poliestrowe; kauczuk nitrylowo-butadienowy; uwodorniony kauczuk karboksylowy; HXNBR; pochłanianie dźwięku; kompozyt

• Wydawca: Lodz University of Technology, Faculty of Material Technologies and Textile Design
• Czasopismo: Autex Research Journal
• Rocznik: 2017
• Tom: Vol. 17, no. 3
• Strony: 263--267
• Opis fizyczny: Bibliogr. 17 poz.

Twórcy

autor

Jie H.

• Key Laboratory of Textile Science & Technology, Ministry of Education, College of Textiles, Donghua University, Shanghai 201620, China
• College of Textile and Dying Engineering, Jiangsu College of Engineering and Technology , Nantong, Jiangsu 226007, China

autor

Sheng J.

• College of Textile and Dying Engineering, Jiangsu College of Engineering and Technology , Nantong, Jiangsu 226007, China

autor

Xiong Y.

• Key Laboratory of Textile Science & Technology, Ministry of Education, College of Textiles, Donghua University, Shanghai 201620, China

Bibliografia

• [1] Zhou, H., Huang, GS., Chen, XR., et al. (2004). Advances in sound absorption polymers. Rubber & Plastics Resources Utilization (In Chinese), 16(3), 450-455.
• [2] Chen, RJ. (2008). Rubber sound absorption material and their application. China Rubber Industry (In Chinese), 55(2), 122-125.
• [3] Ionov, AV., Buvailo, LE., Volkova, MV., et al. (2010). Elastomer Materials in Ship Vibration and Noise Protection Means. Russian Journal of General Chemistry, 53(4), 41-53.
• [4] Du, YC., Yan, N., Kortschot, MT. (2014). A simplified fabrication process for biofiber-reinforced polymer composites for automotive interior trim applications. Journal of Materials Science, 49(6), 2630-2639.
• [5] Seddeq, HS., Aly, NM., Marwa A., et al. (2013). Investigation on sound absorption properties for recycled fibrous materials. Journal of Industrial Textiles, 43(1), 56-73.
• [6] Gliscinska, E., Michalak, M., Krucinska, I. (2013). Sound absorption property of nonwoven based composites. AUTEX Research Journal, 13(4), 150-155.
• [7] Hassanzadeh, S., Hasani, H., Zarrebini, M. (2014). Analysis and prediction of the noise reduction coefficient of lightly-needled Estabragh/polypropylene nonwovens using simplex lattice design. Journal of The Textile Institute, 105(3), 256-263.
• [8] Jiang, S., Yan, X. (2010). Acoustical absorption property of elastomer composites consisting of chlorinated polyethylene and seven-hole hollow polyester fibers. Journal of Textile Research (In Chinese), 31(3), 32-35.
• [9] Jiang, S., Xu, YY., Zhang, HP., et al. (2012). Sevenhole hollow polyester fibers as reinforcement in sound absorption chlorinated polyethylene composites. Applied Acoustics, 73(3), 243-247.
• [10] Zhou, XO., Jiang, S., Yan, X., et al. (2014). Damping acoustic properties of reclaimed rubber/seven-hole hollow polyester fibers composite materials. Journal of Composite Materials, 48(30), 3719-3726.
• [11] Su, W., Li, XY., Liu, SS. (2009). Influence of thickness and density on sound-absorption capability of nonwoven sound-absorbing material. Journal of Tianjin Polytechnic University (In Chinese), 28(3), 34-36.
• [12] Lou, CW., Lin, JH., Su, KH. (2005). Recycling Polyester and Polypropylene Nonwoven Selvages to Produce Functional Sound Absorption Composites. Textile Research Journal, 75(5), 390-394.
• [13] Lee, YE., Joo, CW. (2004). Sound Absorption Properties of Thermally Bonded Nonwovens Based on Composing Fibers and Production Parameters. Journal of Applied Polymer Science, 92(4), 2295-3302.
• [14] Mathew, L., Narayanankutty, S. (2009). Cure Characteristics and Mechanical Properties of HRH Bonded Nylon-6 Short Fiber-Nanosilica-Acrylonitrile Butadiene Rubber Hybrid Composite. Polymer-Plastics Technology and Engineering, 48(1), 75-81.
• [15] Zainudin, ES., Yan, LH., Haniffah, WH., et al. (2014). Effect of Coir Fiber Loading on Mechanical and Morphological Properties of Oil Palm Fibers Reinforced Polypropylene Composites. Polymer Composites, 35(7), 1418-1425.
• [16] Han, ZQ., Wu, ZP., Wu, DZ. (2013). Surface Modification and Dispersion of Kevlar Fibers Within EPDM Composites. Aerospace Materials & Technology (In Chinese), 43(5), 43-45.
• [17] Han, ZQ., Qi, SL., Liu, W., et al. (2013). Surface-Modified Polyimide Fiber-Filled Ethylenepropylenediene Monomer Insulations for a Solid Rocket Motor: Processing, Morphology, and Properties. Industrial & Engineering Chemistry Research, 52(3), 1284-1290.