K.P.S. Cheng scite author profile

2003

100

This study investigates the working principle of compact spinning technology and the structural differences between Com4® yams spun by a Rieter ComforSpin® K40 compact spinning machine and conventional ring spun yarns. Differences in yam quality are observed. The higher tensile strengths and lower hairiness of the Com4 yarns are the key achievements of the compact spinning technology. However, limitations of the new technology are also revealed by investigating the quality of yams with different counts.

Effects of Geometry of Ring Spinning Triangle on Yarn Torque: Part II: Distribution of Fiber Tension within a Yarn and Its Effects on Yarn Residual Torque

Hua

2009

This paper presents a theoretical analysis of fiber tension distribution within a ring spun yarn without relaxation. Yarn residual torque is determined on the basis of the translation of fiber tension at the spinning triangle, as presented in the first part of this series of papers, into the fiber tension within the yarn. The results from numerical simulations indicate that, with fiber buckling, the yarn exhibits a lower average fiber tension and, thus, a much reduced yarn residual torque than that without fiber buckling. Comparison with experiments confirmed that fiber buckling exists in ring yarns while the assumption of no fiber buckling is not realistic. Generally, a low yarn twist results in low average fiber tension in the yarn and, thus, a reduced yarn residual torque. A symmetrical spinning triangle leads to a slightly higher yarn residual torque than a right-angle spinning triangle when the yarn counts and twists are identical and fiber buckling occurs.

JetRing Spinning and Its Influence on Yarn Hairiness

2002

Effect of Strand Spacing and Twist Multiplier on Cotton Sirospun Yarn

Sun

1998

An Artificial Neural Network Model for the Prediction of Spirality of Fully Relaxed Single Jersey Fabrics

Murrells

Tao

et al. 2009

The present paper proposes an artificial neural network model for the prediction of the degree of spirality of single jersey fabrics made from 100 % cotton conventional and modified ring spun yarns. The factors investigated were the yarn residual torque as the measured twist liveliness, yarn type, yarn linear density, fabric tightness factor, the number of feeders, rotational direction and gauge of the knitting machine and dyeing method. The artificial neural network model was compared with a multiple regression model, demonstrating that the neural network model produced superior results to predict the degree of fabric spirality after three washing and drying cycles. The relative importance of the investigated factors influencing the spirality of the fabric was also investigated.