Research progress of fabric friction performance test system

Abstract

Abstract: Friction performance is an important index to measure the friction behavior of fabric materials, which is of great significance for the design, production and application of textiles. With the development of textile science and technology, the research and improvement of fabric friction performance test system has attracted more and more attention, because friction determines the quality of fiber products processing links such as spinning, weaving, knitting and finishing. As one of the most basic mechanical properties of the fabric, the friction performance of the fabric surface affects the fabric style and wearability. Fabric style is the comprehensive effect of the inherent properties of the fabric itself on the human senses. The surface friction performance of the fabric affects the tactile style evaluation of the smoothness, slipperiness and waxiness, and clamminess of the fabric, and gives the fabric a rich surface handle. In order to better evaluate the performance of the fabric in the friction process, the friction performance of the fabric was quantitatively and qualitatively evaluated. The research and development of the fabric friction performance test system were reviewed. The research background, friction mechanism and research process of fabric friction were introduced. Starting from the material of the friction part in contact with the fabric, the fabric-metal friction, fabric-fabric friction and fabric-skin/skin-like fabric surface friction performance test devices were introduced.
When friction occurs within or between fabrics and between fabrics and other substances, there will be low-frequency vibration, which will produce a sound spectrum and affect the fabric’s acoustic style. More and more people have realized that fabric sound is one of the key factors that determine the performance of fabrics. By studying the sound generated by fabric friction, the acoustic characteristics related to fabric structural factors and auditory sensation are determined to meet the growing consumer demand for fabrics’ auditory properties affecting clothing comfort. The test method of fabric friction sound was introduced, but there is no universal test instrument for fabric friction sound test device in the world.
The research of the fabric friction performance test system aims to accurately and reliably evaluate the friction performance of fabric materials, provide scientific basis for textile design and application, and is of great significance in the field of textile science and technology. The surface friction performance of the fabric will also affect its wearability, that is, the comfort of the fabric, and the surface friction performance of the fabric will also have a certain impact on the post-processing and some special functions. Through in-depth understanding of the friction behavior and performance characteristics of fabrics, it can provide scientific basis for the design, production and application of fabric materials, and promote the development and innovation of the textile industry. However, further research and improvement of test methods are still needed to improve the accuracy and practicability of the test system to meet the needs of the developing textile industry.

Key words: fabric style, friction performance, auditory style, friction sound, test method, testing device

摘要： 织物表面摩擦性能是织物最基本的力学性能之一，为更好地评估该性能，文章对织物摩擦性能测试系统的研究和发展情况进行了综述，介绍了织物摩擦的研究背景、摩擦机理和研究历程，以及织物表面摩擦性能测试装置和织物摩擦声测试方法，分析了织物摩擦性能测试装置及织物摩擦声的研究现状及不足，分析发现：织物摩擦性能测试装置在不断改进，但依旧存在精度问题，只有KES系统被广泛应用，但KES系统价格昂贵且不能进行实时测量，目前国际上并没有通用织物摩擦声测试装置。文章最后展望了未来的研究方向。

关键词: 织物风格, 摩擦性能, 听觉风格, 摩擦声, 测试方法, 测试装置

CLC Number:

TS103

TIAN Yuan, DU Zhaoqun, ZHENG Dongming, ZOU Haochen. Research progress of fabric friction performance test system[J]. Advanced Textile Technology, 2024, 32(4): 125-140.

田源, 杜赵群, 郑冬明, 邹昊宸. 织物摩擦性能测试系统的研究进展[J]. 现代纺织技术, 2024, 32(4): 125-140.

References

[1] BINNS H. The discrimination of wool fabrics by the sense of touch[J]. British Journal of Psychology General Section, 1926, 16(3): 237-247.
[2] BINNS H. A comparison between the judgments of individuals skilled in the textile trade and the natural judgments of untrained adults and children[J]. Journal of the Textile Institute Transactions, 1926, 17(12): T615-T641.
[3] PEIRCE F T. The “handle” of cloth as a measurable quantity[J]. Journal of the Textile Institute Transactions, 1930, 21(9): T377-T416.
[4] KAWABATA S. Appendix A-The Standardization and Analysis of Hand Evaluation (Second Edition)[M]. Japan: Textile Machinery Society of Japan. 1980: 389-442.
[5] BOOS A D, TESTER D. SiroFAST – fabric assurance by simple testing [M]. Effect of Mechanical and Physical Properties on Fabric Hand. Amsterdam: Elsevier,2005: 443-463.
[6] DHINGRA R C, LIU D, POSTLE R. Measuring and interpreting low-stress fabric mechanical and surface properties [J]. Textile Research Journal, 1989, 59(6): 357-368.
[7] 左召光. 织物表面摩擦性能测试系统的研究[D]. 天津：天津工业大学, 2019:4-5.
ZUO Zhaoguang. Research on Fabric Surface Friction Performance Testing System[D]. Tianjing: Tiangong University, 2019:4-5.
[8] ARVANITAKI A, BRISCOE B J, ADAMS M J, et al. The friction and lubrication of elastomers [M]. Tribology Series Amsterdam: Elsevier, 1995: 503-511.
[9] RAMKUMAR S S, RAJANALA R, PARAMESWARAN S, et al. Experimental verification of failure of Amontons' law in polymeric textiles [J]. Journal of Applied Polymer Science, 2004, 91(6): 3879-3885.
[10] HOWELL H G, MAZUR J. Amontons' law and fibre friction [J]. Journal of the Textile Institute Transactions, 1953, 44(2): T59-T69.
[11] MICHIELSEN S. Device for measuring sliding friction on highloft nonwovens [J]. Journal of Engineered Fibers and Fabrics, 2006, 1(1): 23-31.
[12] ARSHI A, JEDDI A A A, KATBAB A A. Frictional behavior of plain woven fabrics constructed from polyester and cotton yarns in different environmental conditions [J]. Journal of Engineered Fibers and Fabrics, 2012, 7(2): 99-108.
[13] 冯萌雨. 织物表面摩擦性能的研究进展 [J]. 纺织科学与工程学报, 2018, 35(4): 152-157.
FENG Mengyu. Study on the friction properties of fabric surface [J]. Journal of Textile Science and Engineering, 2018, 35(4): 152-157.
[14] WANG X, LIU P, WANG F. Fabric‐skin friction property measurement system [J]. International Journal of Clothing Science and Technology, 2010, 22(4): 285-296.
[15] GUL M, KOC I M, GURSOY N C. A study on the investigation of frictional properties of woven woolen fabrics [C]. 5th International Textile, Clothing & Design Conference-Magic World of Textiles. Dubrovnk, Croatia. 2010.
[16] GERHARDT L C, STRASSLE V, LENZ A, et al. Influence of epidermal hydration on the friction of human skin against textiles [J]. Journal of the Royal Society Interface, 2008, 5(28): 1317-1328.
[17] 姚宝国, 张德品, 闫丽霞, 等. 织物表面摩擦特性测试装置及试验研究 [J]. 摩擦学学报,2016, 36(6): 769-775.
YAO Baoguo, ZHANG Depin, YAN Lixia, et al. A measurement apparatus and evaluation for surface friction properties of fabrics [J]. Tribology, 2016, 36(6): 769-775.
[18] 向忠, 刘杨, 钱淼, 等. 纤维及其制品摩擦性能测试方法的研究进展 [J]. 纺织学报, 2018, 39(11): 168-175.
XIANG Zhong, LIU Yang, QIAN Miao, et al. Research progress in test methods of friction properties of fiber and its products[J]. Journal of Textile Research, 2018, 39(11): 168-175.
[19] 陈胜慧, 刘华丽, 杨亚江. 织物湿摩擦系数测试仪F-Tester的研制与应用 [J]. 纺织学报, 2003, 24(3): 248-251.
CHEN Shenghui, LIU Huali, YANG Yajiang. Development and application of fabric wet friction coefficient tester F-Tester[J]. Journal of Textile Research, 2003, 24(3): 248-251.
[20] 翟亚丽, 张一风. 织物表面静摩擦系数测定仪的研制 [J]. 纺织器材, 2006, (2): 26-29.
ZHAI Yali, ZHANG Yifeng. Development of the Friction Factor Determiner on the Fabric Surface [J]. Textile Accessories, 2006, (2): 26-29.
[21] 任建, 王正伟. 用圆盘法测试织物表面摩擦性能的研究 [J]. 纺织科技进展, 2007, (6): 23-24.
REN Jian, WANG Zhengwei. Testing frictional properties of fabric surface by a new disc method [J]. Progress in Textile Science & Technology, 2007, (6): 23-24.
[22] 孙博. 力学角度测试织物表面粗糙度的方法研究 [D]. 上海：东华大学, 2009.
SUN Bo. The Study on Testing the Roughness of Fabric Surface by a Mechanical Method[D]. Shanghai: Donghua University, 2009.
[23] KALEBEK N A, BABAARSLAN O. A study of abrasion and frictional behaviour of nonwoven interlining produced with different coating methods [J]. Fibers and Polymers, 2011, 12(3): 371-375.
[24] 李莎, 赵岩, 左召光, 等. 新型织物表面摩擦性能测试系统 [J]. 天津工业大学学报, 2020, 39(1): 43-47.
LI Sha, ZHAO Yan, ZUO Zhaoguang, et al. New testing system of fabric surface friction performance[J]. Journal of Tiangong University, 2020, 39(1): 43-47.
[25] WANG T Y, ZUO Z G, XIE J, et al. A novel instrument for testing the frictional properties of fabric surfaces [J]. Fibers and Polymers, 2022, 23(8): 2340-2350.
[26] PARMARB M S, SISODIA N, SINGH M. Development of fabric smoothness tester [J]. Indian Journal of Fibre & Textile Research, 2020, 45(2): 190-196.
[27] 冯萌雨, 张一心. 一种多方向可控的织物摩擦测试仪设计 [J]. 化纤与纺织技术, 2022, 51(7): 131-134.
FENG Mengyu, ZHANG Yixin. Design of a multi-directional controllable fabric friction tester[J]. Chemical Fiber & Textile Technology, 2022, 51(7): 131-134.
[28] CHASSAGNE F, BENOIST E, BADEL P, et al. Characterization of fabric-to-fabric friction: application to medical compression bandages [J]. Autex Research Journal, 2020, 20(2): 220-227.
[29] AJAYI J O. Fabric smoothness, friction, and handle [J]. Textile Research Journal, 1992, 62(1): 52-59.
[30] 吕柏祥, 李伟光, 艾哈麦德. 织物表面摩擦性能测定 [J]. 纺织学报, 1996(1): 37-39.
LÜ Boxiang, LI Weiguang, AI Hamaide. Determination of friction properties of fabric surface[J]. Journal of Textile Research, 1996(1): 37-39.
[31] FETFATSIDIS K A, GAMACHE L M, GORCZYCA J L, et al. Design of an apparatus for measuring tool/fabric and fabric/fabric friction of woven-fabric composites during the thermostamping process [J]. International Journal of Material Forming, 2013, 6(1): 1-11.
[32] FETFATSIDIS K A, JAUFFRèS D, SHERWOOD J A, et al. Characterization of the tool/fabric and fabric/fabric friction for woven-fabric composites during the thermostamping process [J]. International Journal of Material Forming, 2013, 6(2): 209-221.
[33] Carrera-Gallissà E, Capdevila X, Escusa M. Assessing friction in silk-like finished polyester fabrics [J]. The Journal of The Textile Institute, 2017, 109(1): 113-120.
[34] 张毅, 陈红. 用绞盘法测定织物表面摩擦性能探讨[J]. 天津纺织工学院学报, 1998, 17(4): 87-91.
ZHANG Yi, CHEN Hong. Discussion on determination of fabric surface friction performance by winch method[J]. Journal of Tiangong University, 1998, 17(4): 87-91.
[35] KUHM D, BUENO M A, KNITTEL D. Fabric friction behavior: study using capstan equation and introduction into a fabric transport simulator [J]. Textile Research Journal, 2014, 84(10): 1070-1083.
[36] XIANG Z, LIU Y, ZHOU X Q, et al. Interlayer contact mechanism of the frictional behavior of glass-fiber woven fabrics and improvements of winding characteristics [J]. Composite Structures, 2020, 233:111497.
[37] LIMA M, HES L, VASCONCELOS R, et al. Frictorq, accessing fabric friction with a novel fabric surface tester [J]. Autex Research Journal, 2005, 5(4): 194-201.
[38] DAS A, KOTHARI V K, VANDANA N. A study on frictional characteristics of woven fabrics [J]. AUTEX Research Journal, 2005, 5(3): 133-140.
[39] ALLAOUI S, HIVET G, BILLOëT J L. Experimental analysis of the contact between layers of dry fabrics [J]. International Journal of Material Forming, 2009, 2(1): 209-212.
[40] ALLAOUI S, HIVET G, WENDLING A, et al. Influence of the dry woven fabrics meso-structure on fabric/fabric contact behavior [J]. Journal of Composite Materials, 2012, 46(6): 627-639.
[41] MOORTHY R R, KANDHAVADIVU P. Surface friction characteristics of woven fabrics with nonconventional fibers and their blends [J]. Journal of Textile and Apparel, Technology and Management, 2015, 9(3): 1-14.
[42] GWOSDOW A R, STEVENS J C, BERGLUND L G, et al. Skin friction and fabric sensations in neutral and warm environments [J]. Textile Research Journal, 1986, 56(9): 574-580.
[43] KENINS P. Influence of fiber type and moisture on measured fabric-to-skin friction [J]. Textile Research Journal, 1994, 64(12): 722-728.
[44] 王停停,陈敏之.织物与皮肤间摩擦特性研究现状与展望[J].现代纺织技术,2016,24(3):58-64.
WANG Tingting, CHEN Minzhi. Research status and prospect on fabric-skin friction property[J]. Advanced Textile Technology, 2016,24(3):58-64.
[45] 王旭. 织物和皮肤间的摩擦性能研究 [D]. 上海：东华大学, 2011.
WANG Xu. Friction Property between Fabric and Human Skin[J]. Shanghai: Donghua University,2011.
[46] WANG X, ZHANG Q L, WANG F-M. The standard friction test condition between woven fabric and skin in wet states [J]. Tribology Transactions, 2012, 55(6): 747-751.
[47] 姜瑞涛, 胡吉永, 丁辛. 织物/指尖接触摩擦振动信号的时频联合分析方法 [J]. 东华大学学报(自然科学版), 2017, 43(6): 878-885.
JIANG Ruitao, HU Jiyong, DING Xin. A time-frequency analysis method of textile/fingertip friction-induced vibration signal[J]. Journal of Donghua University (Natural Science), 2017, 43(6): 878-885.
[48] LI W L, SHEN H Y, HUNG J T, et al. The effect of moisture on friction coefficient of fabrics used on taekwondo personal protective equipment [J]. Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology, 2019, 233(1): 87-94.
[49] 余闯. 织物舒适度的摩擦触觉感知研究 [D]. 徐州:中国矿业大学, 2021.
YU Chuang. Study on the Frictional Tactile Perception of Fabric Comfort[D]. Xuzhou: China University of Mining and Technology,2021.
[50] TANG W, ZHANG S S, YU C, et al. Tactile perception of textile fabrics based on friction and brain activation [J]. Friction, 2023,11(7):1320-1333.
[51] DERLER S, SCHRADE U, GERHARDT L C. Tribology of human skin and mechanical skin equivalents in contact with textiles [J]. Wear, 2007, 263(7/8/9/10/11/12): 1112-1116.
[52] BERTAUX E, LEWANDOWSKI M, DERLER S. Relationship between friction and tactile properties for woven and knitted fabrics [J]. Textile Research Journal, 2007, 77(6): 387-396.
[53] GERHARDT L, MATTLE N, SCHRADE G, et al. Study of skin-fabric interactions of relevance to decubitus: friction and contact-pressure measurements [J]. Skin Research and Technology, 2007, 14(1): 77-88.
[54] VAN AMBER R R, LOWE B J, NIVEN B E, et al. The effect of fiber type, yarn structure and fabric structure on the frictional characteristics of sock fabrics [J]. Textile Research Journal, 2015, 85(2): 115-127.
[55] EZAZSHAHABI N, LATIFI M, TEHRAN M A. Analysis of frictional behavior of woven fabrics by a multi-directional tactile sensing mechanism [J]. Journal of Engineered Fibers and Fabrics, 2015, 10(3): 129-135.
[56] EZAZSHAHABI N, TEHRAN M A, LATIFI M. Predictive model for the frictional characteristics of woven fabrics optimized by the genetic algorithm [J]. The Journal of The Textile Institute, 2018, 109(8): 1083-1090.
[57] KIM M S, KIM I Y, PARK Y K, et al. The friction measurement between finger skin and material surfaces [J]. Wear, 2013, 301(1/2): 338-342.
[58] CHEN S, GE S R. Experimental research on the tactile perception from fingertip skin friction [J]. Wear, 2017, 376/377: 305-314.
[59] THORSEN W J, VENEKLASEN P. The spectral distribution of sound produced by fibers and fabrics in friction [J]. Textile Research Journal, 1961, 31(9): 804-809.
[60] THORSEN W J. The spectral distribution of sound produced by fibers and fabrics in friction[J]. Textile Research Journal, 1962, 32(8): 670-676.
[61] Yi E, Cho G. Fabric sound parameters and their relationship with mechanical properties [J]. Textile Research Journal, 2000, 70(9): 828-836.
[62] Yi E, Cho G. Sound sensation and its related objective parameters of nylon fabrics for sports outerwear [J]. Journal of the Korean Society of Clothing and Textiles, 2001, 25: 1593-1602.
[63] Yi E, Cho G. Fabric-sound classification by autoregressive parameters [J]. Journal of the Textile Institute, 2000, 91(4): 530-545.
[64] Kim C, Cho G, Yoon H, et al. Characteristics of rustling sounds created by the structure of polyester warp and knitted fabrics [J]. Textile Research Journal, 2003, 73(8): 685-691.
[65] Yi E, Cho G, Na Y, et al. A fabric sound evaluation system for totally auditory-sensible textiles [J]. Textile Research Journal, 2002, 72(7): 638-644.
[66] Cho J, Cho G. Determining the psychoacoustic parameters that affect subjective sensation of fabric sounds at given sound pressures [J]. Textile Research Journal, 2007, 77(1): 29-37.
[67] LEE E, HAN S J, LEE K H, et al. Comparison between fabric frictional sound parameters and wearers’ subjective auditory sensibility of PCM-treated combat uniforms [J]. Fibers and Polymers, 2015, 16(6): 1410-1416.
[68] WANG H S, ZHANG P. Characteristics of rustling sounds created by the cotton fabrics with variable-rubbing speeds [M]. Lecture Notes in Electrical Engineering. London: Springer London,. 2012: 1470-1475.
[69] SCHLOßER U, BAHNERS T, SCHOLLMEYER E, et al. Fabric handle evaluation by means of sound analysis [J]. Technical Textiles, 2013, 56(4): 195-197.
[70] COOPER C, NORTON J, MARSHMAN C, et al. The acoustics of friction and microstructure of model and apparel fabrics [J]. Textile Research Journal, 2014, 84(6): 626-637.
[71] Jemma C C. Acoustics and friction of apparel and model fabrics, and consumer perceptions of fabric Sounds [D]. The University of Birmingham, 2013.
[72] WANG P N, HO M H, CHENG K B, et al. Study on the friction sound properties of natural-fiber woven fabrics [J]. Fibres and Textiles in Eastern Europe, 2017, 25: 34-42.
[73] YOSOUF K, LATROCH H, SCHACHER L, et al. Frictional sound analysis by simulating the human arm movement [J]. Autex Research Journal, 2017, 17(1): 12-19.
[74] LECLINCHE F, ADOLPHE D C, DREAN E, et al. Modeling of wear sound production based on mechanical and friction properties of woven fabric [J]. Textile Research Journal, 2019, 89(13): 2511-2521.
[75] TAO C, DUAN Y F, HONG X H. Discrimination of fabric frictional sounds based on Haar features [J]. Textile Research Journal, 2019, 89(11): 2067-2074.
[76] TUVSHINBAYAR K, EHRMANN A. Acoustic investigation of textile fabrics [J]. Tekstilec, 2020, 63(4): 287-293.