纺织学报 ›› 2024, Vol. 45 ›› Issue (01): 211-219.doi: 10.13475/j.fzxb.20220803701

• 机械与设备 • 上一篇    下一篇

基于自抗扰控制的圆纬机恒张力输纱控制系统设计

彭来湖1, 谢国旺1, 戴宁1,2()   

  1. 1.浙江理工大学 浙江省现代纺织装备技术重点实验室, 浙江 杭州 310018
    2.浙江理工大学纺织科学与工程学院(国际丝绸学院), 浙江 杭州 310018
  • 收稿日期:2022-08-15 修回日期:2023-03-10 出版日期:2024-01-15 发布日期:2024-03-14
  • 通讯作者: 戴宁(1991—),男,博士。主要研究方向为针织装备技术。E-mail:990713260@qq.com
  • 作者简介:彭来湖(1980—),男,副教授,博士。主要研究方向为针织装备技术。
  • 基金资助:
    浙江省科技尖兵计划项目(2022C01065)

Design of constant yarn feeding tension control system for circular knitting machines based on active disturbance rejection control

PENG Laihu1, XIE Guowang1, DAI Ning1,2()   

  1. 1. Key Laboratory of Modern Textile Machinery & Technology of Zhejiang Province, Zhejiang Sci-Tech University, Hangzhou,Zhejiang 310018, China
    2. College of Textile Science and Engineering(Intemational Institute of Silk),Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
  • Received:2022-08-15 Revised:2023-03-10 Published:2024-01-15 Online:2024-03-14

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摘要:

针对当前圆纬机积极式送纱方式中存在的纱线张力及输送速度不可任意调节、纱线张力波动大等问题,提出了一种可为圆纬机输送恒定张力纱线的输纱控制系统。构建了以无刷直流电动机速度环为内环、以纱线张力为外环的纱线恒张力双闭环反馈控制系统,通过自抗扰控制技术获取纱线实时动态指标,并对无刷直流电动机目标转速进行调整,最后通过磁场定向控制技术驱动无刷直流电动机。详细阐述了纱线张力的形成机制、纱线恒张力输送控制方案、系统硬件设计及控制算法。输纱测试表明,该控制系统可实现多种类型纱线的恒定张力输送。其中,棉纱张力波动标准差为1.5 cN(300 m/min测试条件),氨纶包芯纱的张力波动标准差为0.33 cN(240 m/min测试条件)。输纱速度的调节范围为0 ~600 m/min,纱线张力的控制范围为2.0~50.0 cN。

关键词: 恒张力, 输纱器, 无刷直流电动机, 磁场定向控制, 自抗扰控制, 圆纬机

Abstract:

Objective Yarn tension is a critical parameter in the textile process, and its fluctuation directly affects the fabric quality. Aiming at the problems existing in the yarn feeding mode of circular knitting machines, such as large fluctuation of yarn tension, unadjustable yarn tension and feeding speed, a new yarn feeding control system based on active disturbance rejection control is proposed.

Method Through the mathematical modeling of yarn tension, its formation mechanism and influencing factors were clarified. Based on this, a series of design schemes were proposed, such as the control strategy of feeding with constant tension, the main hardware structure of the system, and the closed-loop control algorithm of yarn tension. The system used PID controller to control the speed loop of the brushless direct-current (DC) motor in the inner closed loop and and active disturbance rejection controller to control the tension loop of yarn in the outer closed loop. Both of them constituted the inner and outer double closed loop control system of constant tension yarn feeding on circular knitting machine. Among them, active disturbance rejection control technology was adopted to obtain real-time yarn dynamic index, and to combine each yarn dynamic index through a nonlinear combination method to obtain the corrected reference speed of the brushless DC motor. The reference speed was finally applied to the brushless DC motor through the field oriented control technology. It was adopted to adjust the yarn feeding speed and ensure that the yarn tension is maintained near the set value.

Results The yarn feeding test showed that the system achieved better results in controlling yarn tension fluctuation and overshoot. Taking the first group of experiments as an example, the yarn tension overshoot decreased by 50% and 54%, respectively, and the standard deviation of tension fluctuation decreased by 15% and 25%, respectively. The second group of experiments also reflected this rule, and it also showed that the fluctuation of yarn tension increased significantly with the increase of yarn feeding speed. When the target yarn tension increased by 52% instantaneously, the actual yarn tension reached the target yarn tension without obvious overshoot within 70ms. At the same time, the tension showed good real-time and following performance during continuous changes. In case of sudden change of yarn feeding speed, the yarn feeder reacted quickly to ensure that the yarn tension was still maintained close to the set value, and the yarn tension overshoot during the speed change process was controlled within 20%. In addition, the feeder also demionstrated good performance of constant tension control for elastic and non-elastic yarn. The test results suggested the suitability for the constant tension yarn feeding control system to be used for feeding yarns with small tension fluctuation and readjustable yarn feeding speed and yarn tension, which meets the process requirements for the circular knitting under different working conditions.

Conclusion The new constant tension yarn feeding control system plays an important role in improving the intelligence of circular knitting machine, reducing the surface defects of fabrics, improving the elastic evenness of fabrics, and reducing the yarn breaking rate. The yarn feeder has the characteristics of programmability and wide range of yarn applications. It can also be conveniently applied to automatic winding machine, hosiery machine, seamless underwear machine and other textile equipments. Considering the large fluctuation of yarn tension under high-speed feeding conditions, a series of optimizations should be made in future research for the wire storage disk of the yarn feeder for yarns with small diameter and weak strength, such as the winding path, the number of winding turns, and the roughness of the contact surface of the wire storage disk.

Key words: constant tension, yarn feeder, brushless direct-current motor, field oriented control, active disturbance rejection, circular knitting machine control

中图分类号: 

  • TS181.8

图1

圆纬机机械结构图"

图2

圆纬机恒张力输纱控制系统总体方案"

图3

系统总体硬件结构框图"

图4

纱线恒张力控制算法框架"

图5

无刷直流电动机磁场定向控制程序框图"

表1

FOC控制算法中的符号变量及其说明"

符号名 符号说明 符号名 符号说明
ωref 电动机参考转速 vα α轴电压矢量
ω 电动机实际转速 vβ β轴电压矢量
θ 电动机转子角度 ia 电动机A相电流
iqref 转速控制信号 ib 电动机B相电流
iq 交轴电流矢量 ic 电动机C相电流
id 直轴电流矢量 Ta A相逆变器开启时间
vq 交轴控制信号 Tb B相逆变器开启时间
vd 直轴控制信号 Tc C相逆变器开启时间

图6

恒张力输纱测试平台"

图7

自抗扰控制在不同目标张力下的纱线张力波动情况"

图8

PID控制在不同目标张力下的纱线张力波动情况"

图9

自抗扰控制在不同输纱速度下的纱线张力波动情况"

图10

PID控制在不同输纱速度下的纱线张力波动情况"

图11

变张力输纱条件下的纱线张力波动情况"

图12

变速度输纱条件下的纱线张力波动情况"

图13

弹性与非弹性纱线张力波动情况"

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