Sage Journals: Discover world-class research

Abstract

Sliver quality in the spinning process can be enhanced significantly by using an autoleveling control system (ACS) of the drawing frame, which improves the uniformity of sliver linear density. Most existing research on closed-loop control systems focuses on theoretical analysis, and fixed-time open-loop control systems cannot accurately detect and control slivers. This paper develops and experimentally evaluates an open-loop fixed-length control system for the drawing frame to enhance the stability of the sliver thickness detection and improve the sliver quality, based on the fundamental autoleveling control equation. The proposed ACS adopts a digital signal processor (DSP) as its core, integrating key modules including a touchscreen, speed sensor, servo drive, sliver thickness sensor, and analog-to-digital converter. The autoleveling, communication, and online monitoring algorithms for sliver quality have all been implemented successfully. The proposed ACS is subsequently evaluated on an experimental platform to assess its performance. The proposed ACS reduces the CV_5m of the sliver by 93.10% compared with the unleveled sliver, improving sliver quality significantly. Compared with the existing advanced ACS, the proposed ACS reduces the root mean square error and average CV of sliver weight by 11.75% and 5.59%, respectively. This work provides theoretical and technical support for advancing domestic high-speed drawing frame development.

Keywords

drawing frame autoleveling control fixed-length control open-loop control

Get full access to this article

View all access options for this article.

References

Shen

Qian

A study on the dynamic motion of floating fibers in the double apron drafting process. Text Res J 2022; 92: 2476-2486.

Zheng

, et al. The model of ring-spun slub yarn based on random fiber arrangement and its application: Part 2 Prediction of morphology parameters for slub yarn and simulation of slub fabric. Text Res J 2024; 94: 1069-1082.

Tayyar

Celep

Tetik

, et al. Features of cotton and viscose vortex yarns directly spun from card slivers. Text Res J 2023; 93: 5083-5091.

Simulation of fiber arrangement in slub strands and twisting on the slub yarn with the finite element method. Text Res J 2023; 93: 1445-1455.

Sun

Yang

Modeling fiber arrangement and distribution during the roller drafting process. Text Res J 2019; 89: 4295-4305.

Cui

Cheng

, et al. Modeling and simulation of fiber movement in the drafting zone based on the iterative method. Text Res J 2023; 93: 33-46.

Fan

Wang

Zhang

, et al. The influence rule of uneven input sliver on floating fiber motion during the dynamic drafting process. J Text Inst 2025; 116: 701-712.

Wang

A new approach to the control of autolevelling for drafting process: Part 2: Experimental verification. J Text Inst 2019; 110: 215-218.

Luan

Development of the autolevelling device for high-speed drawing frame. Master Thesis, Qingdao University, Qingdao, 2005.

10.

Chen

Feng

Cui

Control theory and practice of auto-levelling in drawing frame. Cotton Text Technol 2020; 48: 21-25.

11.

Zhou

Wang

Dual open-loop control system on autoleveler of drawing frame. J Text Res 2010; 31: 106-109+114.

12.

Zheng

Application summary of VSGPG in autoleveller control. Microcomput Inform 2006; 22: 66-68.

13.

Zhu

Zou

A new control system for auto-leveling of high speed drawing frame. Int J Adv Manuf Tech 2007; 34: 156-160.

14.

Duan

Study on autoleveller system of drawing frame based on adaptive control and fuzzy control. Master Thesis, Donghua University, Shanghai, 2012.

15.

Yang

Chen

An embedded auto-leveling system based on ARM and FPGA. TELKOMNIKA Indones J Electr Eng 2013; 11: 7094-7101.

16.

Shen

Chen

, et al. A compensation controller based on a nonlinear wavelet neural network for continuous material processing operations. CMC-Comput Mater Con 2019; 61.

17.

Mupfudze

Cao

Shen

, et al. Fiber motion and the accelerated point distribution in roller drafting. Text Res J 2019; 89: 1224-1236.

18.

Qian

Zhou

Isometric fiber distribution in the roller drafting zone. Text Res J 2024; 94: 1233-1244.

19.

Zhang

, et al. A prediction method and its application for twist of slub yarn based on micro-element yarn. Text Res J 2025; 95: 584-598.

20.

Zhou

, et al. The model of ring-spun slub yarn based on random fiber arrangement and its application: Part 1. Study on the relationship between fiber distribution and the length of the transitional segment of slub yarn. Text Res J 2023; 93: 4302-4314.

21.

Wang

A new approach to the control of autolevelling for drafting process: part 1: theoretical model based on the discrete-event simulation. J Text I 2019; 110: 219-222.

22.

Peng

Xie

Dai

Design of constant yarn feeding tension control system for circular knitting machines based on active disturbance rejection control. J Text Res 2024; 45: 211-219.

Design and experimental validation of the autoleveling control system for a high-speed drawing frame

Abstract

Keywords

Get full access to this article

References