Sage Journals: Discover world-class research

Abstract

Loop yarn is a typical fancy yarn composed of three strands and differs significantly from conventional yarn. The loop yarn also suffers from friction and wear during use and processing. To create a unique fuzzing effect, loop yarn is usually sanded by rubbing against an abrasive. The frictional force and coefficient can only roughly reflect the frictional effect between yarn and abrasive, and it is challenging to represent the amount of contact between the two at the microscopic level. A Hertz contact model is first established to evaluate the contact between the loop yarn and the abrasive. This paper derives the calculation formula for the contact number and area between the loop yarn and the abrasive. The calculation results indicate that as the mesh of the abrasive increases, the frictional force and coefficient decrease, the contact number between the loop yarn and the abrasive gradually increases, the contact area first increases and then tends to stabilize, and the contact force and stress decrease and stabilize. The ratio of the fiber distribution force to its contact area can be used as an evaluation index for fiber wear resistance. The product of the square root of contact number, abrasive particle radius, and friction index can provide feedback on friction performance.

Keywords

Loop yarn friction contact mode contact number contact area

Get full access to this article

View all access options for this article.

References

Peng

Sun

HY.

Sanding of polyester knitted fabric with ceramic grinding machine. China Dyeing Finish 2015; 41(14): 45–47.

Huang

Jing

GX.

A hairy yarn processing device: China, 201821954624.7, 2019.

Zhu

Cao

Zhu

HY.

A production method of soft hairy yarn: China, 201710212210.0, 2017.

El Mogahzy

Gupta

BS.

Friction in fibrous materials Part I: Structural model. Text Res J 1991; 61(9): 547–555.

Ning

FG.

Researches on geometrical modeling of braided ropes and their bending fatigue properties when bent over sheaves. PhD thesis, Donghua University, 2016.

Hosseinali

Thomasson

JA.

Variability of fiber friction among cotton varieties: Influence of salient fiber physical metrics. Tribol Int 2018; 127: 433–445.

Cornelissen

Rietman

Akkerman

Frictional behaviour of high performance fibrous tows: Friction experiments. Compos A Appl Sci Manuf 2013; 44: 95–104.

Xie

Yang

, et al. Effect of normal load on the frictional and wear behaviour of carbon fiber in tow-on-tool contact during three-dimensional weaving process. J Ind Text 2022; 51(2S): 2753S–2773S.

Cornelissen

de Rooij

Rietman

, et al. Frictional behavior of carbon fiber tows: a contact mechanics model of tow–tow friction. Text Res J 2014; 84(14): 1476–1488.

10.

Che

Zhang

Hou

, et al. Modeling of fibrous tow transmission considering residual strain and friction. Text Res J 2021; 91(17–18): 2015–2035.

11.

Mulvihill

Smerdova

Sutcliffe

MPF.

Friction of carbon fibre tows. Compos A Appl Sci Manuf 2017; 93: 185–198.

12.

Choi

Kim

KL.

Fiber segment length distribution on the yarn surface in relation to yarn abrasion resistance. Text Res J 2004; 74(7): 603–606.

13.

Subramaniam

Muthukrishnan

Naik

SV.

Sonic modulus of cotton yarn and its relationship to abrasion resistance, friction, and fatigue parameters. Text Res J 1991; 61(1): 58–59.

14.

Wang

Cheng

Zhang

DR.

Effect of hairiness index and twist on cotton yarn abrasion property. Cotton Text Technol 2009; 37(2): 4–6.

15.

Palaniswamy

Mohamed

Effect of the single-yarn twist and ply to single-yarn twist ratio on the hairiness and abrasion resistance of cotton two-ply yarn. AUTEX Res J 2006; 6(2): 59–71.

16.

Chen

Wan

, et al. Damage analysis of 710 mm² ACCC strands considering the contact and friction behavior between strands. Tribology 2017; 37(5): 565–573.

17.

Chen

YP.

Study on mechanical and frictional wear performance of wire rope strand. PhD Thesis, Chongqing University, 2016.

18.

Xiao

Gao

Wang

QX.

Design and production of three-color gradient loop yarn. Cotton Text Technol 2016; 44(9): 36–39.

19.

Alshukur

Gong

Stylios

Structural modelling of multi-thread fancy yarn. Int J Cloth Sci Technol 2018; 30(2): 268–283.

20.

Katarzyna

EG.

A mathematical model of fancy yarn’s strength. The first model developed in the world. Fibres Text East Eur 2008; 16(6): 9–14.

21.

Zhao

Wang

, et al. Modeling and experimental study on yarn’s cross-section compression deformation. J Text Res 2017; 38(2): 118–130.

22.

Bilel

Bernard

Jean-François

Discrete woven structure model: yarn-on-yarn friction. C R Mecanique 2007; 335(3): 150–158.

23.

Chang

Peng

Zhu

, et al. Effects of strand lay direction and crossing angle on tribological behavior of winding hoist rope. Materials 2017; 10(6): 630–659.

24.

Grishanov

Lomov

Harwood

, et al. The simulation of the geometry of two-component yarns. Part I: The mechanics of strand compression: simulating yarn cross-section shape. J Text Inst 1997; 88(2): 118–131.

25.

Yang

TS.

Study on the friction and wear performance of tension looping traction drum. PhD Thesis, University of Jinan, 2020.

26.

Johnson

KL.

Contact Mechanics (9th print edn). Cambridge: Cambridge University Press, 1985; pp. 397–423.

27.

Coated abrasives. Grain size analysis. Part 1 Grain size distribution test first edit: ISO 6344: 1998[S/OL], 1999.

28.

Milad

Mostafa

Ali Asghar

, et al. Double-core helical auxetic yarn: A novel structure, geometrical modeling and experimental verification. J Text Inst 2022; 113(7,19): 1256–1269．

29.

ZJ.

Research on the “rigid-flexible-air” coupling dynamics of yarn winding system. PhD Thesis, Donghua University, 2020.

30.

MJ.

Handbook of Practical Mechanical Engineering Materials. Shenyang: Liaoning Science and Technology Press, 2004.

31.

Yao

Textile Materials Science (4th edn). Beijing: China Textile & Apparel Press, 2015.

32.

Gupta

BS.

Friction in Textile Materials. Sawston: Woodhead Publishing Limited, 2008.

33.

Xia

, et al. The tension fluctuation and packaging quality control of nonwoven winding. J Eng Fibers Fabrics 2024; 19. doi:10.1177/15589250241260886

34.

Xia

Sun

Meng

, et al. Dynamic tension analysis on winding yarn in jacquard device of tufting carpet machine. J Text Res 2015; 36(7): 136–141．

35.

Cornelissen

de Rooij

Rietman

, et al. Frictional behaviour of high performance fibrous tows: A contact mechanics model of tow-metal friction. Wear 2013; 305: 78–88.

36.

Kaliski

EJ.

A plowing theory of yarn surface friction. Text Res J 1958; 28(4): 325–329.

37.

Gupta

El Mogahzy

YE.

Friction in fibrous materials: Part II: Experimental study of the effects of structural and morphological factors. Text Res J 1993; 63(4): 219–230.

Calculation method of contact index between loop yarn and abrasive

Abstract

Keywords

Get full access to this article

References