棉精梳机分离罗拉混合驱动系统优化

doi:10.13475/j.fzxb.20220601201

纺织学报 ›› 2023, Vol. 44 ›› Issue (11): 190-198.doi: 10.13475/j.fzxb.20220601201

棉精梳机分离罗拉混合驱动系统优化

刘金儒¹^,², 李新荣¹^,²(), 王浩³, 师帅星¹^,²

1.天津工业大学机械工程学院, 天津 300387
2.天津市现代机电装备技术重点实验室, 天津 300387
3.天津工业大学纺织科学与工程学院, 天津 300387

收稿日期:2022-06-06 修回日期:2023-07-03 出版日期:2023-11-15 发布日期:2023-12-25
通讯作者: 李新荣(1975—),男,教授,博士。主要研究方向为新型纺织机械设计及自动化。E-mail:lixinrong7505@hotmail.com。
作者简介:刘金儒(1997—),男,硕士生。主要研究方向为新型纺织机械设计及自动化。
基金资助:
工信部产业技术基础公共服务平台项目(2021-0173-2-1);天津市131创新型人才团队项目(201916)

Optimization of detaching roller hybrid drive system for cotton comber

LIU Jinru¹^,², LI Xinrong¹^,²(), WANG Hao³, SHI Shuaixing¹^,²

1. School of Mechanical Engineering, Tiangong University, Tianjin 300387, China
2. Tianjin Key Laboratory of Advanced Mechatronics Equipment Technology, Tianjin 300387, China
3. School of Textile Science and Engineering, Tiangong University, Tianjin 300387, China

Received:2022-06-06 Revised:2023-07-03 Published:2023-11-15 Online:2023-12-25

摘要/Abstract

摘要：

为更好地解决现有分离罗拉驱动方式传动链长及难以调整分离罗拉运动规律等缺点,首先,分析精梳机分离接合工艺,提出分离罗拉运动过程中的工艺关键点,并用分段拟合的方法进行拟合,得到理想的分离罗拉运动规律;其次,在对分离罗拉混合驱动方式中的齿轮传动系统进行动力学分析的基础上优化系统中各齿轮的齿数;然后,结合运动学分析及相关要求规划伺服电动机的运动规律,计算得到伺服电动机的速度曲线;最后,通过仿真软件及实验平台进行验证。结果表明,优化后的分离罗拉混合驱动系统可以使分离罗拉按照符合工艺要求的运动规律运行并使分离罗拉的运动具有柔性,解决了现有分离罗拉驱动方式机构传动链长及分离罗拉运动规律调整困难等问题。

关键词: 精梳机, 分离罗拉, 混合驱动, 齿轮传动系统, 动力学

Abstract:

Objective The detaching roller is the core mechanism of the comber. In the process of combing, it needs to complete a high-speed periodic motion that follows the "rise-return-dwell" pattern. Thus, there are stringent requirements on kinematics and dynamics performances of the transmission mechanism of the detaching roller. The conventional mechanical driving mode can generate a large impact and vibrations, and it is difficult to further improve its speed. Therefore, it is particularly important to overcome the shortcomings of the existing drive mode, including long drive chain, high vibration and noise.

Method The paper analyzed the separation and jointing process of comber, and put forward the key points in movement of detaching roller. The segmented fitting method was adopted to fit them, yielding the optimal movement law of detaching roller. The number of teeth of each gear in the system was optimized based on the dynamic analysis of the gear transmission system of detaching roller. Combined with kinematics analysis and relevant requirements, the motions of two servo motors were then planned and the speed curves of the servo motors were determined. The theoretical expectation was verified by software simulation and test evaluation.

Results The curve of displacement of the detaching roller conformed to the "rise-return-dwell" pattern with the maximum error being 0.30 mm, which satisfied the requirements of flock detachment and overlap. The velocity and acceleration at the starting and terminal points were zero, and the detaching roller did not produce rigid or a flexible impact (Fig. 2). Therefore, the fitting results of the motion curve for the detaching roller were ideal. It can be seen from transmission system that, after optimization, the vibration acceleration of most of gears was reduced to varying degrees, and the sum of root mean square vibration accelerations of all gears in the transmission system was reduced by 18.21% compared with the original, achieving the effect of vibration reduction. Vibration accelerations of some gears in the transmission system showed that the speed of the servo motor connected to the sun gear s is always positive, and the speed of the servo motor connected to gear 1 was always negative, that is, both servo motors operate in one direction. Therefore, the motion planning of the servo motor meets the design requirements. In addition, through the results of ADAMS simulation, it can be seen that the detaching roller motion curve obtained by simulation was basically consistent with the motion curve obtained by theoretical calculation. Therefore, the detaching roller drive system designed can make the movement of the detaching roller meet the process requirements. Finally, according to the experimental results, it can be seen that the overall errors between the displacement curve of the detaching roller obtained from the experiment and the theoretical calculation and simulation results was very small, which verified that the detaching roller drive system can replace the conventional mechanical structure, overcome the problems of its long transmission chain and large vibration noise, and complete the drive of the detaching roller. From displacements of different detaching rollers, displacement curves can be obtained by changing the motion law of the servo motor, verifing that the hybrid drive mode of the detaching roller can make the detaching roller meet different process requirements.

Conclusion In this paper, the hybrid drive system of the detaching roller is studied. The driving system can render the motion of the detaching roller flexible. It solves the problems of the long drive chain of the existing detaching roller drive mechanism and the difficulty in adjusting the motion law of the detaching roller. However, this study still needs to be improved. For example, this study considered only the degrees of freedom in the torsional direction in the dynamic model of the driving system of the detaching roller, which is sufficient for engineering. In future research, more factors should be considered to build a dynamic model with multiple degrees of freedom to better reflect the empirical situation.

Key words: comber, detaching roller, hybrid drive, gear transmission system, dynamic

中图分类号:

TS112.2

刘金儒, 李新荣, 王浩, 师帅星. 棉精梳机分离罗拉混合驱动系统优化[J]. 纺织学报, 2023, 44(11): 190-198.

LIU Jinru, LI Xinrong, WANG Hao, SHI Shuaixing. Optimization of detaching roller hybrid drive system for cotton comber[J]. Journal of Textile Research, 2023, 44(11): 190-198.

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参考文献 15

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参数	数值
齿数z	z_s=32,z_s_'=25,z_p_i=22,z_p_'i=29,z_c=95,z₁=80,z₂=87,z₃=28
模数m/mm	m_s=m_s_'=m_p_i=m_p_'i=m_c=m₁=2.5,m₂=m₃=1.25
质量/kg	M_s=1.13,M_s_'=0.48,M_p_i=0.44,M_p_'i=0.97,M_c=13.15,M₁=9.30,M₂=2.51,M₃=0.14
齿宽/mm	T_s=T_s_'=35.0,T_p_i=T_p_'i=34.5,T_c=T₁=T₂=T₃=40.0
啮合刚度/(N·m^-1)	k_sp_i=1.08×10⁸,k_s'p'_i=1.02×10⁸,k_1c=1.87×10⁸,k₂₃=1.48×10⁸
扭转刚度/(N·m·rad^-1)	k_p_i_p_'i=2.24×10⁴,k_2s_'=3.24×10⁵

棉精梳机分离罗拉混合驱动系统优化

Optimization of detaching roller hybrid drive system for cotton comber

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