Accès libre

Coupling Characteristics of Needles and Backing Cloth During the Carpet Tufting Process

Yang Xu
Yang Xu
, 
Shuang Huang
Shuang Huang
, 
Xiaowei Sheng
Xiaowei Sheng
 et 
Sun Zhijun
Sun Zhijun
   | 28 sept. 2022
Fibres & Textiles in Eastern Europe's Cover Image
À propos de cet article
Article précédent
Article suivant
Citez
Article Category: Research Article
Publié en ligne: 28 sept. 2022
Pages: 9 - 17
DOI: https://doi.org/10.2478/ftee-2022-0017
Mots clés
© 2022 Yang Xu, et al., published by Sciendo
This work is licensed under the Creative Commons Attribution 3.0 Public License.

Meng, Z., Sun, J. J., Zhou, T. Z., & Gu, S. H. (2008). Research on the Influence that Stop Position of Carpet Tufting Machine to Yarn Tension and the Method of Elimination Stop Mark. Key Engineering Materials, 375–376, 724–728. MengZ. SunJ. J. ZhouT. Z. GuS. H. 2008 Research on the Influence that Stop Position of Carpet Tufting Machine to Yarn Tension and the Method of Elimination Stop Mark Key Engineering Materials 375–376 724 728 10.4028/www.scientific.net/KEM.375-376.724 Search in Google Scholar

Xue, S. (2003). Machine-made carpet. Beijing: Chemical Industry Press. XueS. 2003 Machine-made carpet Beijing Chemical Industry Press Search in Google Scholar

Gotlih, K. (1997). Sewing needle penetration force study. International Journal of Clothing Science & Technology, 9 (3), 241–248. GotlihK. 1997 Sewing needle penetration force study International Journal of Clothing Science & Technology 9 3 241 248 10.1108/09556229710168388 Search in Google Scholar

Haghighat, E., Etrati, S. M., & Najar, S. S. (2013). Modeling of needle penetration force in denim fabric. International Journal of Clothing Science & Technology, 25(25), 361–379. HaghighatE. EtratiS. M. NajarS. S. 2013 Modeling of needle penetration force in denim fabric International Journal of Clothing Science & Technology 25 25 361 379 10.1108/IJCST-01-2012-0031 Search in Google Scholar

Haghighat, E., Etrati, S. M., Najar, S. S., & Shamsi, M. (2015). Theoretical prediction of the needle penetration force in denim fabric part 1: Yarn tensile extension component. International Journal of Clothing Science & Technology, 27(3), 397–416. HaghighatE. EtratiS. M. NajarS. S. ShamsiM. 2015 Theoretical prediction of the needle penetration force in denim fabric part 1: Yarn tensile extension component International Journal of Clothing Science & Technology 27 3 397 416 10.1108/IJCST-03-2014-0034 Search in Google Scholar

Carvalho, H., Rocha, A. M., & Monteiro, J. L. (2009). Measurement and analysis of needle penetration forces in industrial high-speed sewing machine. Journal of the Textile Institute, 100(4), 319–329. CarvalhoH. RochaA. M. MonteiroJ. L. 2009 Measurement and analysis of needle penetration forces in industrial high-speed sewing machine Journal of the Textile Institute 100 4 319 329 10.1080/00405000701806839 Search in Google Scholar

Lomov, S. V. (1998). A predictive model for the penetration force of a woven fabric by a needle. International Journal of Clothing Science & Technology, 10(2), 91–103. LomovS. V. 1998 A predictive model for the penetration force of a woven fabric by a needle International Journal of Clothing Science & Technology 10 2 91 103 10.1108/09556229810213728 Search in Google Scholar

Mallet, E., & Du, R. (2013). Finite element analysis of sewing process. International Journal of Clothing Science & Technology, 11(11), 19–36. MalletE. DuR. 2013 Finite element analysis of sewing process International Journal of Clothing Science & Technology 11 11 19 36 10.1108/09556229910258089 Search in Google Scholar

Goda I., & Girardot J. (2021). Numerical modeling and analysis of the ballistic impact response of ceramic/composite targets and the influence of cohesive material parameters. International Journal of Damage Mechanics, 30(7):1079–1122. GodaI. GirardotJ. 2021 Numerical modeling and analysis of the ballistic impact response of ceramic/composite targets and the influence of cohesive material parameters International Journal of Damage Mechanics 30 7 1079 1122 10.1177/1056789521992107 Search in Google Scholar

Elias A., Laurin F., Kaminski M. & Gornet L. (2017). Experimental and numerical investigations of low energy/velocity impact damage generated in 3D woven composite with polymer matrix. Composite Structures, 159, 228–239. EliasA. LaurinF. KaminskiM. GornetL. 2017 Experimental and numerical investigations of low energy/velocity impact damage generated in 3D woven composite with polymer matrix Composite Structures 159 228 239 10.1016/j.compstruct.2016.09.077 Search in Google Scholar

Wu Z.Y., Zhang L. C., Ying Z.P., Ke J., & Hu X. D. (2020). Low-velocity impact performance of hybrid 3D carbon/glass woven orthogonal composite: Experiment and simulation. Composites Part B: Engineering, 196(1): 1–14. WuZ.Y. ZhangL. C. YingZ.P. KeJ. HuX. D. 2020 Low-velocity impact performance of hybrid 3D carbon/glass woven orthogonal composite: Experiment and simulation Composites Part B: Engineering 196 1 1 14 10.1016/j.compositesb.2020.108098 Search in Google Scholar

Haque B. Z., & Gillespie J. W. (2021). Perforation mechanics of UHMWPE soft ballistic sub-laminate and soft ballistic armor pack: A finite element study. Journal of thermoplastic composite materials, 1–29 (online). HaqueB. Z. GillespieJ. W. 2021 Perforation mechanics of UHMWPE soft ballistic sub-laminate and soft ballistic armor pack: A finite element study Journal of thermoplastic composite materials 1 29 (online). 10.1177/08927057211042058 Search in Google Scholar

Zhang R., Qiang L. S., Han B., Zhao Z.Y., Zhang Q. C., Ni C. Y., & Lu T. J. (2020). Ballistic performance of uhmwpe laminated plates and uhmwpe encapsulated aluminum structures: numerical simulation. Composite Structures, 252: 112686. ZhangR. QiangL. S. HanB. ZhaoZ.Y. ZhangQ. C. NiC. Y. LuT. J. 2020 Ballistic performance of uhmwpe laminated plates and uhmwpe encapsulated aluminum structures: numerical simulation Composite Structures 252 112686 10.1016/j.compstruct.2020.112686 Search in Google Scholar

Yiping Shi, Y. Z. (2006). Finite element analysis of detailed examples using ABAQUS. Beijing: Mechanical Engineering Press. Yiping ShiY. Z. 2006 Finite element analysis of detailed examples using ABAQUS Beijing Mechanical Engineering Press Search in Google Scholar

Wang, P., Ma, Q., & Sun, B. (2011). Finite element modelling of woven fabric tearing damage. Textile Research Journal, 81(12):1273–1286. WangP. MaQ. SunB. 2011 Finite element modelling of woven fabric tearing damage Textile Research Journal 81 12 1273 1286 10.1177/0040517510397578 Search in Google Scholar

Masoumeh V., Stepan L., & Sayed A. (2010). Finite element modeling of a yarn pullout test for plain woven fabrics. Textile Research Journal, 80(10):892–903. MasoumehV. StepanL. SayedA. 2010 Finite element modeling of a yarn pullout test for plain woven fabrics Textile Research Journal 80 10 892 903 10.1177/0040517509346436 Search in Google Scholar

Ding, C. H., Zhang, S. P., & Sun, Y. Z. (2006). Kinematical analysis of the needle's driving mechanism within a carpet tufting machine. Journal of Textile Research, 27(5), 37–40. DingC. H. ZhangS. P. SunY. Z. 2006 Kinematical analysis of the needle's driving mechanism within a carpet tufting machine Journal of Textile Research 27 5 37 40 Search in Google Scholar

eISSN:
2300-7354
Langue:
Anglais
Périodicité:
6 fois par an
Sujets de la revue:
Business and Economics, Business Management, Business Informatics, Process Management, Industrial Chemistry, Cellulose, Paper and Textiles, Polymer Science and Technology, Materials Sciences, Biomaterials and Natural Materials
RSS Feed de la revue