Compressive Property of an Auxetic-Knitted Composite Tube Under Quasi-Static Loading

• Autorzy: Boakye Andrews , Raji Rafui King , Ma Pibo , Cong Honglian

Identyfikatory

DOI

10.2478/aut-2019-0020

• Języki publikacji: PL

Abstrakty

EN

This research investigates the compressive property of a novel composite based on a weft-knitted auxetic tube subjected to a quasi-static compression test. In order to maximize the influence of the fiber content on the compression test, a Kevlar yarn was used in knitting the tubular samples using three different auxetic arrow-head structures (i.e. 4 × 4, 6 × 6 and 8 × 8 structure). A quasi-static compression test was conducted under two different impact loading speeds (i.e. 5 mm/min and 15 mm/min loading speed). The results indicate that the energy absorption (EA) property of the auxetic composite is highly influenced by the auxeticity of the knitted tubular fabric.

Słowa kluczowe

PL

auksetyk; rura kompozytowa; pochłanianie energii

EN

auxetic; knitted composite tube; energy absorption

• Wydawca: Lodz University of Technology, Faculty of Material Technologies and Textile Design
• Czasopismo: Autex Research Journal
• Rocznik: 2020
• Tom: Vol. 20, no. 2
• Strony: 101--109
• Opis fizyczny: Bibliogr. 22 poz.

Twórcy

autor

Boakye Andrews

• Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Wuxi 214122, China

autor

Raji Rafui King

• Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Wuxi 214122, China

autor

Ma Pibo

• Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Wuxi 214122, China

autor

Cong Honglian

• Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Wuxi 214122, China

Bibliografia

• [1] Glazzard, M., Breedon, P. (2014). Weft-knitted auxetic textile design. Physica Status Solidi (b), 251(2), 267-272.
• [2] Boakye, A., Chang, Y., Raji Rafiu K., Ma P. (2017). Design and manufacture of knitted tubular fabric with auxetic effect. The Journal of The Textile Institute, 1-7.
• [3] Hu, H., Wang, Z., Liu, S. (2011). Development of auxetic fabrics using flat knitting technology. Textile Research Journal, p. 0040517511404594.
• [4] Zhou, L., Jiang, L., Hu, H. (2016). Auxetic composites made of 3D textile structure and polyurethane foam. physica status solidi (b), 253(7): p. 1331-1341.
• [5] Rana, S., Magalhães, R., Fangueiro, R. (2017). Advanced auxetic fibrous structures and composites for industrial applications.
• [6] Jiang, N., Hu, H. (2017). A study of tubular braided structure with negative Poisson’s ratio behavior. Textile Research Journal, p. 0040517517732086.
• [7] Wang, Z., Zulifqar, A., Hu, H. (2016). Auxetic composites in aerospace engineering. Advanced composite materials for aerospace engineering: Processing, properties and applications. Cambridge: Woodhead Publishing, pp. 213-240.
• [8] Grima, J. N., Caruana-Gauci, R., Attard, D, Gatt, R. (2012). Three-dimensional cellular structures with negative Poisson’s ratio and negative compressibility properties. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Science, 468(2146), 3121-3138.
• [9] Chang, Y., Ma, P., Jiang, G. (2017). Energy absorption property of warp-knitted spacer fabrics with negative Possion’s ratio under low velocity impact. Composite Structures, 182, 471-477.
• [10] Cabras, L., Brun, M. (2014). Auxetic two-dimensional lattices with Poisson’s ratio arbitrarily close to− 1. In Proceedings of the Royal Society of London A: Mathematical, Physical and Engineering Sciences. The Royal Society.
• [11] Rana, S., Fangueiro, R. (2016). Advanced composite materials for aerospace engineering: Processing, properties and applications. Woodhead Publishing.
• [12] Mamalis, A.G., Robinson, M., Manolakos, D. E., Demosthenous, G. A., Ioannidis, M. B., Carruthers, J. (1997). Crashworthy capability of composite material structures. Composite Structures, 37(2), 109-134.
• [13] Harte, A.-M., Fleck, N. A., Ashby, M.F. (2000). Energy absorption of foam-filled circular tubes with braided composite walls. European journal of mechanics-A/Solids, 19(1), 31-50.
• [14] Mohsenizadeh, S., Alipour, R., Shokri Rad, M., Farokhi Nejad, A., Ahmad, Z. (2015). Crashworthiness assessment of auxetic foam-filled tube under quasi-static axial loading. Materials & Design, 88, 258-268.
• [15] Jiang, L., Gu, B., Hu, H. (2016). Auxetic composite made with multilayer orthogonal structural reinforcement. Composite Structures, 135, 23-29.
• [16] Yoon, M. -K., Baidoo, J., Gillespie Jr, J. W., Heider, D. (2005). Vacuum Assisted Resin Transfer Molding (VARTM) Process Incorporating Gravitational Effects: A Closed-form Solution. Journal of Composite Materials, 39(24), 2227-2242.
• [17] ASTM, D. (1999). Standard test method for void content of reinforced plastics. West Conshohocken (PA): ASTM International.
• [18] Boey, F., Lye, S. (1992). Void reduction in autoclave processing of thermoset composites: Part 1: High pressure effects on void reduction. Composites, 23(4), 261-265.
• [19] Liu, L., Zhang, B. -M., Wang, D. –F., Wu, Z. -J. (2006). Effects of cure cycles on void content and mechanical properties of composite laminates. Composite structures, 73(3), 303-309.
• [20] Schroeder, D. (2000). An Introduction to Thermal Physics. United States: Addison Wesley Longman.
• [21] Chang, Y., Ma, P., Jiang, G. (2017). Energy absorption property of warp-knitted spacer fabrics with negative Possion’s ratio under low velocity impact. Composite Structures.
• [22] Gideon, R. K., Zhou, H., Li, Y., Sun, B., Gu, B. (2016). Quasi-static compression and compression–compression fatigue characteristics of 3D braided carbon/epoxy tube. The Journal of The Textile Institute, 107(7), 938-948.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).