Journal of Textile Research ›› 2023, Vol. 44 ›› Issue (05): 198-204.doi: 10.13475/j.fzxb.20211205201

• Machinery & Accessories • Previous Articles     Next Articles

Yarn tension non-contacts detection system on string vibration based on machine vision

JI Yue1,2(), PAN Dong1,2, MA Jiedong1,2, SONG Limei1,2, DONG Jiuzhi1,3   

  1. 1. School of Control Science and Engineering, Tiangong University, Tianjin 300387, China
    2. Tianjin Key Laboratory of Intelligent Control of Electrical Equipment, Tiangong University, Tianjin 300387, China
    3. School of Mechanical Engineering, Tiangong University, Tianjin 300387, China
  • Received:2021-12-24 Revised:2022-05-27 Online:2023-05-15 Published:2023-06-09

RichHTML

8

PDF (PC)

84

Abstract:

Objective The objective of the research on the non-contact detection system for yarn tension based on machine vision is to improve the accuracy of tension detection for moving yarns. The current contact tension measurement makes direct contact with yarn during the detection process, which causes additional friction to the yarn and wears the measuring device at the same time, affecting the accuracy of tension measurement. The machine vision technology provides a new direction for yarn tension detection. Based on string vibration theory and machine vision image processing method, this poper aimed to study and design a non-contact detection system for yarn tension based on machine vision to achieve accurate tension detection.

Method In order to investigate the relationship between yarn tension and vibration frequency in non-contact detection, the yarn in transverse vibration in the system was regarded as string vibration, and a mathematical model of yarn tension and vibration frequency was established and the theoretical relationship was derived. The yarn winding motion device was designed, the camera shooting field of view was planned, and the yarn tightening roller was designed to make the yarn vibrate freely in the detection range. A line array industrial camera was selected to complete the yarn image acquisition, and the strip light source was adopted to assist the illumination. A series of image pre-processing was carried out to smooth out the yarn image noise, edge extraction was selected to obtain the upper boundary of the image, and the frequency was calculated from the peaks and valleys of two adjacent frames to measure the yarn tension.

Results In order to verify the accuracy of yarn tension measurement, test experiments were conducted using the constructed detection device, where the yarn was wound around the winding roller and placed in the middle of the pulley and clamping roller (Fig.7). A tension sensor was used for tension detection comparison, the yarn guide roller and the winding roller were driven by servo motors, and the line array light source provided stable light. The frame rate of the image acquisition by the line array camera was set to 100 frames per second, and the exposure time was 100 ms. Three strands of Kevlar yarn were used in the experiment, where the yarn length was 50 m, the yarn linear density was 8.2 tex, and the yarn diameter was 0.6 mm. During the experiment, the yarn moved at about 25 m/min, the winding speed of the winding roller motor was 180 r/min, and the winding speed of the clamping roller motor was 98.2 r/min. The fitted line of yarn vibration frequency and tension showed, where it was evident that according to the time sequence, the measured value of the tension sensor correponds to that of the vision measurement system (Fig.9). The results showed that yarn frequency was positively correlated with yarn tension, and the yarn vibration frequency was quadratically related to yarn tension, and the correlation coefficient of the fit reached 0.992. The deviation of the system measured values and the sensor measured values were different, and the collected frequency information effectively reflect the stability of the yarn tension was indicated (Tab.1 and Fig.10). The results showed that the current tension of the moving yarn determined by the vibration frequency is within the tension range of 5-30 cN, and the relative error rate between the visual system measured value and the tension sensor measured value was about ±10%.

Conclusion When the yarn running state changes, the yarn moving speed will also change and so will the measurement value of the vision system. In the vision measurement system, when the yarn runs to the winding roller and clamping roller, the yarn is subjected to a relatively large force. When the yarn runs to the middle, the yarn tends to run smoothly and the tension will be relatively uniform, causing the detected yarn tension to fluctuate within a certain range. The non-contact yarn tension detection does not directly contact the yarn and will not change the original force state of the yarn. Theoretically, the measurement accuracy is higher than the direct contact method, which proves the feasibility of the non-contact detection system to complete the yarn tension measurement and has reference significance for the research of non-contact detection of yarn tension and has a broad prospect in engineering application.

Key words: yarn tension, non-contact detection, string vibration, tension sensor, machine vision

CLC Number: 

  • TS103.7

Fig.1

String vibration coordinate system"

Fig.2

Mechanical structure diagram of detection system"

Fig.3

Schematic diagram of yarn image collected by camera"

Fig.4

Camera field of view"

Fig.5

Algorithm processed yarn images. (a) Original image after splicing; (b) Gaussian filtering threshold image; (c) Boundary extraction image"

Fig.6

Experimental platform"

Fig.7

Captured images of different pixel sizes"

Tab.1

Relative error of yarn tension value"

接触式张力传感器
测量值/cN		 视觉系统
测量值/cN		 相对误差/%
5± 0.05 5.40 8.00
7.5± 0.05 7.79 3.80
10± 0.05 9.77 -2.30
12.5± 0.05 12.45 -0.40
15± 0.05 15.10 0.66
17.5± 0.05 15.90 -9.14
20± 0.05 20.40 1.71
25± 0.05 23.80 -4.80

Fig.8

Yarn vibration frequency and tension fitting line"

Fig.9

Comparison of vision system measurement and tension sensor measurement"

[1] 刘行, 缪旭红, 赵帅权. 纱线张力测试方法研究进展[J]. 棉纺织技术, 2015, 43(1):78-82.
LIU Xing, MIAO Xuhong, ZHAO Shuaiquan. Research progress of yarn tension testing methods[J]. Cotton Textile Technology, 2015, 43(1):78-82.
[2] 庾在海, 吴文英, 陈瑞琪. 纺织过程中的纱线张力测试方法[J]. 传感器世界, 2004(1):27-29.
YU Zaihai, WU Wenying, CHEN Ruiqi. Yarn tension testing method in the textile process[J]. Sensor World, 2004(1):27-29.
[3] Protechna Herbst GmbH & Co.KG. Device for determining the yarn tension of a single yarn in a yarn sheet in textile processing:DE102004046998A1[P]. 2004-2-28.
[4] 熊秋元, 高晓平. 纱线张力检测与控制技术的研究现状与展望[J]. 棉纺织技术 2011, 39(6):65-68.
XIONG Qiuyuan, GAO Xiaoping. Research status and prospects of yarn tension detection and control technology[J]. Cotton Textile Technology 2011, 39(6):65-68.
[5] 吴成进, 陈跃华. 纱线速度的非接触式测量方法的研究[J]. 纺织学报, 2001, 22(1):15-17,2.
WU Chengjin, CHEN Yuehua. Research on the non-contact measurement method of yarn speed[J]. Journal of Textile Research, 2001, 22(1):15-17,2.
[6] ZHANG D, MA Q, TAN Y, et al. Non-contact detection of polyester filament yarn tension in the spinning process by the laser Doppler vibrometer method[J]. Textile Research Journal, 2022, 92(5-6): 919-928.
doi: 10.1177/00405175211034246
[7] 曹飞. 基于图像处理的纱线检测系统[D]. 武汉: 武汉理工大学, 2009:28-30.
CAO Fei. Image processed based yarn detection system[D]. Wuhan: Wuhan University of Technology, 2009:28-30.
[8] 缪宇轩, 孟祥益, 夏港东, 等. 非接触式纱线张力监测系统的研制与开发[J]. 毛纺科技, 2020, 48(5):71-76.
MIAO Yuxuan, MENG Xiangyi, XIA Gangdong, et al. Research and development of non-contact yarn tension monitoring system[J]. Wool Textile Journal, 2020, 48(5):71-76.
[9] 张楠, 景军锋. 基于机器视觉的纱线张力检测方法[C]// 2016全国针织技术交流会论文集. 无锡: [出版者不详], 2016:121-124.
ZHANG Nan,JING Junfeng. Yarn tension detection method based on machine vision[C] //Proceedings of 2016 National Knitting Technology Exchange Conference. Wuxi: [s.n.] 2016:121-124.
[10] HAGEDORN P, DASGUPTA A. Vibrations and waves in continuous mechanical systems[M]. [s.n.]John Wiley & Sons, 2007: 28-32.
[11] 张能辉, 王建军, 程昌钧. 轴向变速运动粘弹性弦线横向振动的复模态 Galerkin 方法[J]. 应用数学和力学, 2007, 28(1):1-8.
ZHANG Nenghui, WANG Jianjun, CHENG Changjun. Complex mode Galerkin method for lateral vibration of viscoelastic string in axial variable speed motion[J]. Applied Mathematics and Mechanics, 2007, 28(1):1-8.
doi: 10.1007/s10483-007-0101-x
[12] CHUNG J, HAN C S. Vibration of an axially moving string with geometric non-linearity and translating acceleration[J]. Journal of Sound and Vibration, 2001, 240(4):733-746.
doi: 10.1006/jsvi.2000.3241
[13] 周泰. 用谐振频率测量纺丝张力的研究[J]. 自动化仪表, 1987(9):12-15,36.
ZHOU Tai. Research on measuring spinning tension with resonance frequency[J]. Automation Instrumentation, 1987(9):12-15,36.
[14] 林红. 运动纱线的动力学行为与控制[D]. 苏州: 苏州大学, 2014:12-18.
LIN Hong. Kinetic behavior and control of motion yarns[D]. Suzhou: Soochow University, 2014:12-18.
[15] 田硕. 弦振动偏微分方程的求解[J]. 科学咨询(科技·管理), 2015(8):68-69.
TIAN Shuo. Solving partial differential equations of string vibration[J]. Scientific Consultation, 2015(8):68-69.
[16] 于伟东, 储才元. 纺织物理[M]. 上海: 东华大学出版社, 2002: 28-32.
YU Weidong, CHU Caiyuan. Textile physics[M]. Shanghai: Donghua University Press, 2002:28-32.
[17] 张开明. 弦振动的研究[J]. 太原师范学院学报(自然科学版), 2010, 9(4):96-99.
ZHANG Kaiming. Research on string vibration[J]. Journal of Taiyuan Normal University (Natural Science Edition), 2010, 9(4):96-99.
[18] WANG Qing, LU Changhou, HUANG Ran, et al. Computer vision for yarn micro tension measure-ment[J]. Applied Optics, 2016, 55(9):2393-2398.
doi: 10.1364/AO.55.002393
[19] 牟新刚, 蔡逸超, 周晓, 等. 基于机器视觉的筒子纱缺陷在线检测系统[J]. 纺织学报, 2018, 39(1):39-145.
MOU Xingang, CAI Yichao, ZHOU Xiao, et al. On-line inspection system for cheese defects based on machine vision[J]. Journal of Textile Research, 2018, 39(1):139-145.
[20] 刘亚梅. 基于梯度边缘最大值的图像清晰度评价[J]. 图学学报, 2016, 37 (2):97-102.
LIU Yamei. Evaluation of image sharpness based on the maximum value of gradient edge[J]. Journal of Graphics, 2016, 37 (2):97-102.
[21] 张建新, 李琦. 基于机器视觉的筒子纱密度在线检测系统[J]. 纺织学报, 2020, 41(6):141-146.
ZHANG Jianxin, LI Qi. On-line inspection system for cheese density based on machine vision[J]. Journal of Textile Research, 2020, 41(6):141-146.
[1] TAO Jing, WANG Junliang, XU Chuqiao, ZHANG Jie. Feature extraction method for ring-spun-yarn evenness online detection based on visual calibration [J]. Journal of Textile Research, 2023, 44(04): 70-77.
[2] YING Zhiping, WANG Weiqing, WU Zhenyu, HU Xudong. Compression after impact performance of three-dimensional orthogonal woven composites [J]. Journal of Textile Research, 2023, 44(01): 129-135.
[3] WANG Bin, LI Min, LEI Chenglin, HE Ruhan. Research progress in fabric defect detection based on deep learning [J]. Journal of Textile Research, 2023, 44(01): 219-227.
[4] PENG Laihu, ZHANG Yujuan, LÜ Yongfa, DAI Ning, LI Jianqiang. Detection method and dynamic characteristics of weft yarn delivery [J]. Journal of Textile Research, 2022, 43(12): 167-172.
[5] JIN Shoufeng, HOU Yize, JIAO Hang, ZHNAG Peng, LI Yutao. An improved AlexNet model for fleece fabric quality inspection [J]. Journal of Textile Research, 2022, 43(06): 133-139.
[6] ZHOU Qihong, PENG Yi, CEN Junhao, ZHOU Shenhua, LI Shujia. Yarn breakage location for yarn joining robot based on machine vision [J]. Journal of Textile Research, 2022, 43(05): 163-169.
[7] LÜ Wentao, LIN Qiqi, ZHONG Jiaying, WANG Chengqun, XU Weiqiang. Research progress of image processing technology for fabric defect detection [J]. Journal of Textile Research, 2021, 42(11): 197-206.
[8] GUO Min, GAO Weidong, ZHU Bo, LIU Jianli, GUO Mingrui. Test method for abrasion resistance of sized yarn under simulated weaving conditions [J]. Journal of Textile Research, 2021, 42(11): 46-50.
[9] ZHENG Baoping, JIANG Gaoming, XIA Fenglin, ZHANG Aijun. Design of dynamic tension compensation system for warp knitting let-off based on model predictions [J]. Journal of Textile Research, 2021, 42(09): 163-169.
[10] WU Liubo, LI Xinrong, DU Jinli. Research progress of motion trajectory planning of sewing robot based on contour extraction [J]. Journal of Textile Research, 2021, 42(04): 191-200.
[11] TIAN Yuhang, WANG Shaozong, ZHANG Wenchang, ZHANG Qian. Rapid detection method of single-component dye liquor concentration based on machine vision [J]. Journal of Textile Research, 2021, 42(03): 115-121.
[12] FENG Wenqian, LI Xinrong, YANG Shuai. Research progress in machine vision algorithm for human contour detection [J]. Journal of Textile Research, 2021, 42(03): 190-196.
[13] ZHU Shigen, YANG Hongxian, BAI Yunfeng, DING Hao, ZHU Qiaolian. Investigation on automatic deformation inspection system of long and thin parts with hooks [J]. Journal of Textile Research, 2020, 41(10): 158-163.
[14] ZHANG Jianxin, LI Qi. Online cheese package yarn density detection system based on machine vision [J]. Journal of Textile Research, 2020, 41(06): 141-146.
[15] LU Hao, CHEN Yuan. Surface defect detection method of carbon fiber prepreg based on machine vision [J]. Journal of Textile Research, 2020, 41(04): 51-57.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备14006648号
Copyright 2021 © Editorial office of Journal of Textile Research
Supported by Beijing Magtech Co.Ltd