Optimization and type selection for compound transmission with continuously variable characteristic parameter

doi:10.13733/j.jcam.issn.2095-5553.2024.01.019

Abstract

Abstract: The core technology of the composite transmission system is matching. Based on the actual importance and adaptability of each evaluation index in different composite transmission systems, the optimal scheme is selected from all possible applicable power split schemes to complete a complete optimal selection design. In order to avoid the problem that the excellent scheme is missed, the speed ratio and torque of 12 composite transmissions are analyzed firstly, and then proposes 3 torque coefficients at different key places in drive line which are selected according to torque capacities of components. Secondly, with the range of speed ratio and 3 torque coefficients as objective functions, a nondominated genetic algorithmII (NSGAII) is applied to optimize two fixed gear ratios of gear pairs, the comprehensive optimal state of the 12 classic compound transmissions is obtained. Lastly, according to the importance and adaptability of evaluation indicators, a multistep preranked selection method for compound transmission with continuously variable characteristic parameter is proposed, and an integrated design process with optimization and type selection is conducted. Compared to the preoptimization systems, the speed ratio range is increased by 24%, the maximum output torque is increased by 18.92%, and the efficiency is increased by 2.25%.

Key words: planetary gear train, compound transmission, torque coefficient, multiobjective optimization, preranked multistep selection

摘要： 复合传动系的核心技术在于匹配，基于不同复合传动系统中各项评价指标实际的重要性与适应性，从所有可能适用的功率分流方案中选出最优方案，完成一次完整的优化选型设计。为避免优秀方案被漏选的问题，对12种复合传动的速比和转矩进行分析，根据传动系统各部件的转矩能力，提出传动路线中3个关键位置的转矩系数。以速比变化范围和3个转矩系数为目标函数，使用非支配遗传算法NSGA-II优化两个固定齿轮副传动比，得出12种复合传动的综合最优状态。基于评价指标重要性与适应性，提出一套行星排特性参数连续可变复合传动系统的分级多步选型方法，完成一次完整的优化选型设计。相比优化前的系统:速比范围提高24%，最大输出转矩提高18.92%，效率提高2.25%。

关键词: 行星排, 复合传动, 转矩系数, 多目标优化, 分级多步选型

CLC Number:

TH132.2

Tan Yunying, Li Qingtao, Liang Li, Liu Shengzhen, Wang Shuang. Optimization and type selection for compound transmission with continuously variable characteristic parameter[J]. Journal of Chinese Agricultural Mechanization, 2024, 45(1): 130-137.

谭芸颖, 李青涛, 梁丽, 刘圣桢, 王霜. 特性参数连续可变复合传动的优化与选型[J]. 中国农机化学报, 2024, 45(1): 130-137.

References

［1］刘修骥. 车辆传动系统分析［M］. 北京: 国防工业出版社, 1998.
［2］王浩然，曹付义，马可，等. 拖拉机多模式机液复合传动装置设计［J］. 机械传动, 2020, 44(3): 66-71.
Wang Haoran, Cao Fuyi, Ma Ke, et al. Design of multimode hydraulic mechanical composite transmission device for tractor ［J］. Journal of Mechanical Transmission, 2020, 44(3): 66-71.
［3］胡新燕，董昊，何明斐. 无级变速传动技术在中小功率拖拉机上的应用分析与研究［J］. 拖拉机与农用运输车, 2018, 45(4): 25-28.
Hu Xinyan, Dong Hao, He Mingfei. Application analysis and research of infinitely variable speed transmission technology in small and medium power tractors ［J］. Tractor & Farm Transporter, 2018, 45(4): 25-28.
［4］李晨硕，邹娇蓉，李继光. 国际先进中小功率轮式拖拉机的产品技术现状及建议［J］. 拖拉机与农用运输车, 2021, 48(3): 12-15.
Li Chenshuo, Zou Jiaorong, Li Jiguang. Current situation and suggestion of product technology of international advanced small and medium power wheeled tractors ［J］. Tractor & Farm Transporter, 2021, 48(3): 12-15.
［5］伍赛特. 装甲车辆动力传动技术研究现状及发展趋势展望［J］. 传动技术, 2019, 33(2): 44-50.
Wu Saite. Research status and development trend of armored vehicle power transmission technology ［J］. Drive System Technique, 2019, 33(2): 44-50.
［6］张延军，刘敏强. 机电复合传动换挡模式切换过程同步控制方法［J］. 计算机仿真, 2021, 38(7): 118-122.
Zhang Yanjun, Liu Minqiang. Synchronous control method for shift mode switching process of electromechanical compound transmission ［J］. Computer Simulation, 2021, 38(7): 118-122.
［7］周志立. 农业车辆液压机械复合传动与控制［M］. 北京: 科学出版社, 2018.
［8］李艳虎. 装载机液压机械复合传动参数分析与传动特性研究［D］. 西安: 长安大学， 2020.
Li Yanhu. Analysis of hydraulicmechanical compound transmission parameters and research on transmission characteristics of loader ［D］. Xian: Changan University, 2020.
［9］曹付义，周志立，徐立友. 履带车辆液压机械差速转向系统参数优化［J］. 农业工程学报, 2013, 29(18): 60-66.
Cao Fuyi, Zhou Zhili, Xu Liyou. Parameter optimization of hydromechanic differential turning system for tracked vehicle ［J］.Transactions of the Chinese Society of Agricultural Engineering, 2013, 29(18): 60-66.
［10］于宏涛. 适用于农业机械的多功能传动系用油性能要求［J］. 石油商技, 2021, 39(1): 20-24.Yu Hongtao. Oil performance requirements for multifunctional transmission systems suitable for agricultural machinery ［J］. Petroleum Products Application Research, 2021, 39(1): 20-24.
［11］徐万鑫，李景恒，杜海. 斗轮堆取料机液压传动与控制技术现状及发展［J］. 矿山机械, 2020, 48(9): 1-7.
Xu Wanxin, Li Jingheng, Du Hai. Current status and development of hydraulic drive and control technology in bucket wheel stackerreclaimer ［J］. Mining & Processing Equipment, 2020, 48(9): 1-7.
［12］肖家锴，郑高峰，刘朋熙，等. 高速电机发展现状以及关键技术综述［J］. 电气传动, 2020, 50(10): 3-9.
Xiao Jiakai, Zheng Gaofeng, Liu Pengxi, et al. Overview for the development and key technologies of high speed motors ［J］. Electric Drive, 2020, 50(10): 3-9.
［13］王杰，张学敏，张波，等. 电动农机发展现状与趋势［J］.中国农机化学报, 2019, 40(10): 35-41.
Wang Jie, Zhang Xuemin, Zhang Bo, et al. Research status and trend of electric agricultural machinery ［J］. Journal of Chinese Agricultural Mechanization, 2019, 40(10): 35-41.
［14］ Macor A, Rossetti A. Optimization of hydromechanical power split transmissions ［J］. Mechanism and Machine Theory, 2011, 46(12): 1901-1919.
［15］ Liu X J, Sun D Y, Qin D T, et al. Multiobjective design optimization of powercycling hydrodynamic mechanical transmissions ［J］. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2019, 233(4): 1392-1410.
［16］ Zhang Q, Sun D Y, Qin D T. Optimal parameters design method for power reflux hydromechanical transmission system ［J］. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2019, 233(3): 585-594.
［17］ Xia Y, Sun D Y, Qin D T, et al. Optimization of the powercycle hydromechanical parameters in a continuously variable transmission designed for agricultural tractors ［J］. Biosystems Engineering, 2020, 193: 12-24.
［18］ Pei H, Hu X, Yang Y, et al. Configuration optimization for improving fuel efficiency of power split hybrid power trains with a single planetary gear ［J］. Applied Energy, 2018, 214: 103-116.
［19］ Zhang X, Li S E, Peng H, et al. Design of multimode powersplit hybrid vehicles—A case study on the voltec powertrain system ［J］. IEEE Transactions on Vehicular Technology, 2016, 65(6): 4790-4801.
［20］ Li Q, Zhou X, Wang S, et al. Power split transmission with continuously variable planetary ratio ［J］. Mechanism and Machine Theory, 2019, 140: 765-780.
［21］ Akehurst S, Brace C J, Vaughan N D, et al. Performance investigations of a novel rolling traction CVT ［J］. Sae Transactions Journal of Passenger Cars Mechanical Systems, 2001, 1: 874-884.
［22］ Akehurst S, Perrer D A, Schaaf S, et al. Milner无级变速器的动力学模型——基础运动学［J］. 传动技术, 2010, 24(1): 12-21.
Akehurst S, Perrer D A, Schaaf S, et al. Dynamic modeling of the Milner continuously variable transmission—The basic kinematics ［J］. Drive System Technique, 2010, 24(1): 12-21.
［23］ Srinivas N, Deb K. Multiobjective function optimization using nondominated sorting genetic algorithms ［J］. Evolutionary Computation, 1995, 2(3): 221-248.
［24］ Deb K, Pratap A, Agarwal S, et al. A fast and elitist multiobjective genetic algorithm: NSGAⅡ ［J］. IEEE Transactions on Evolutionary Computation, 2002, 6(2): 182-197.
［25］林棻，王伟，张尧文，等. 基于非劣排序遗传算法的三代轮毂轴承多目标优化［J］. 南京航空航天大学学报, 2013, 45(6): 865-870.
Lin Fen, Wang Wei, Zhang Yaowen, et al. Multiobjective optimization for third generation wheel hub bearing based on NSGAⅡ［J］. Journal of Nanjing University of Aeronautics & Astronautics, 2013, 45(6): 865-870.

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