WWB型脉动式无级变速器运动分析及优化
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摘要
WWB型脉动式无级变速器是适合现代生产工艺流程机械化、自动化发展以及改善机械工作性能的一种通用传动装置。它具有工作可靠、承载能力高、变速性能稳定、调速范围广等的特点,已赢得了广阔的市场。但由于结构的特殊性,机构在高速运转时,会产生很大的惯性力和惯性力矩并难以平衡。本课题借助于ADAMS软件,通过对该机构进行几何建模、运动分析,并以此为基础进行尺度综合优化设计,以达到提高机构的运动和动力性能的目的。主要工作内容如下:
(1) 建立WWB型脉动式无级变速器的几何模型。
(2) 对机构进行运动学仿真分析,得到可视化的结果并以输出构件的平均传动比i_m和速度波动系数δ为特性指标进行运动学分析。
(3) 对影响机构运动和动力性能的关键部件——连杆的质心加速度和角加速度为特性指标进行运动分析。
(4) 以参数化机制为基础,以连杆质心加速度和角加速度为目标函数,通过单因素分析找到优化的初始点,再运用广义简约梯度法(GRG法)对机构进行优化设计。
通过本文的研究,不仅为WWB型脉动式无级变速器的改进提供指导,也为无级变速器的理论研究进行了有益的探索。
WWB Impulse stepless speed variator is a universal transmission device which meets the requirements of mechanization and automatization in morden manufacturing process, and improvement of mechanical performance. It has found a good market with its reliability, high load-bearing, steady capability of variable transmission and broad adjustable-speed range, and so on. Due to its particular structure, considerable unbalanced inertial force and torque, in high-speed motion, bring about variable dynamic loads on the frame and, as a result, vibrations; therefore, it is vital to optimize the structure by synthesize, employing ADAMS, based on geometry modeling and kinematic analysis , and to improve kinematic and dynamic performance greatly. The central works in this paper proceed as follows.
Firstly, the geometry model of WWB Impulse stepless speed variator is presented.
Secondly, graphs of output link are obtained by means of kinematic simulation, on a sound basis of which kinematic study related to laws of average ratio of transmission and velocity fluctuation, as a kinematic characteristic, is carried out.
Thirdly, kinematic study dealing with center of mass acceleration and angular acceleration of the coupler, a key part with a dramatic effect on kinematic and dynamic performance of mechanism, is conducted.
Finally, optimal results, obtained by parametric design optimization in which objective, i.e. combination of center of mass acceleration and angular acceleration of the coupler, is established, and based on initialization derived from Design Study in ADAMS, show that inertial force and torque are dramatically suppressed, due to optimal objective by GRG method , as a result, great reduction of unwanted vibrations and impacts.
This paper supplies references to improvement of WWB Impulse stepless speed variator performance, in addition to useful exploration of new theories about WWB Impulse stepless speed variator.
(1) 建立WWB型脉动式无级变速器的几何模型。
(2) 对机构进行运动学仿真分析,得到可视化的结果并以输出构件的平均传动比i_m和速度波动系数δ为特性指标进行运动学分析。
(3) 对影响机构运动和动力性能的关键部件——连杆的质心加速度和角加速度为特性指标进行运动分析。
(4) 以参数化机制为基础,以连杆质心加速度和角加速度为目标函数,通过单因素分析找到优化的初始点,再运用广义简约梯度法(GRG法)对机构进行优化设计。
通过本文的研究,不仅为WWB型脉动式无级变速器的改进提供指导,也为无级变速器的理论研究进行了有益的探索。
WWB Impulse stepless speed variator is a universal transmission device which meets the requirements of mechanization and automatization in morden manufacturing process, and improvement of mechanical performance. It has found a good market with its reliability, high load-bearing, steady capability of variable transmission and broad adjustable-speed range, and so on. Due to its particular structure, considerable unbalanced inertial force and torque, in high-speed motion, bring about variable dynamic loads on the frame and, as a result, vibrations; therefore, it is vital to optimize the structure by synthesize, employing ADAMS, based on geometry modeling and kinematic analysis , and to improve kinematic and dynamic performance greatly. The central works in this paper proceed as follows.
Firstly, the geometry model of WWB Impulse stepless speed variator is presented.
Secondly, graphs of output link are obtained by means of kinematic simulation, on a sound basis of which kinematic study related to laws of average ratio of transmission and velocity fluctuation, as a kinematic characteristic, is carried out.
Thirdly, kinematic study dealing with center of mass acceleration and angular acceleration of the coupler, a key part with a dramatic effect on kinematic and dynamic performance of mechanism, is conducted.
Finally, optimal results, obtained by parametric design optimization in which objective, i.e. combination of center of mass acceleration and angular acceleration of the coupler, is established, and based on initialization derived from Design Study in ADAMS, show that inertial force and torque are dramatically suppressed, due to optimal objective by GRG method , as a result, great reduction of unwanted vibrations and impacts.
This paper supplies references to improvement of WWB Impulse stepless speed variator performance, in addition to useful exploration of new theories about WWB Impulse stepless speed variator.
引文
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[9] Keven R. Lang. An Overview of CVT Research Past, Present, and Future. http://web.mit.edu/WWW./cvt.pdf, 2000
[10] 尹成湖.多盘式无级变速器的动力分析模型[J].现代制造工程,2003,(8):P80-82
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[14] 刘开昌,蓝兆辉,石宗宝.行星锥盘式无级变速器的创新设计[J].包装与食品机械,2003,21(4):P22-23
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[16] Heilich F W, Shube E. Traction Drives-Selection and Application[M]. New York: Marcel Dekker, Inc, 1983
[17] 徐维军.摩擦式机械无级变速器改型研究[J].机电工程技术,2003,32(5):P52-54
[18] 冯樱,罗永革,何晓春,郝琪.CVT——无级变速器的发展综述[J].湖北汽车??工业学院学报,1999,13(4):P15-18
[19] 蒋凌山.奥迪无级变速器Multitronic简介[J].汽车技术,2002,(7):P18-22
[20] 杨亚联,秦大同,谢勇.汽车无级变速器的类型及基本原理[J].汽车技术,1997,(3):P96-99
[21] 彭明涛.汽车带式无级变速器的发展现状[J].重庆工商大学学报(自然科学版),2003,20(4):P100-102
[22] 石福华,刘创.无级变速传动综述[J].机电工程技术,2004,33(2):P14-17
[23] Michael A. Kluger. Continuous Variable Transmission Technology. http://WWW.swri.edu/4org/d03/home.htm. Accessed 03/11/02
[24] Stuart Birch. Audi takes CVT from 15th century to 21st century. Automotive Engineering International, January/2000.
[25] Tauran Ivall. Continuous VariableTransmission. http:/lWWW.engr.orst.edu/-sayler/44x/white_papers/turan_whitepaper.doc, 09/05/02
[26] 于杰栋,睢相林.无级变速技术的发展与展望[J].机电工程技术,2004,33(2):P10-11
[27] Tsukasa Yuki, Mitsunao Takayama, Hisato Kato. Development of dry hybrid belt CVT[J]. JSAE Review, 1995, 16, P251-256
[28] T.F.CHEN, D.W.LEE, C.K.SUNG. An experimental study on transmission efficiency ofarubberV-beltCVT[J]. Mech.Mach.Theory, 1998, 33(4), P351-363
[29] 杜力,李林.脉动式机械无级变速器结构参数的设计[J].渝州大学学报(自然科学版),2002,19(1):P21-24
[30] 杜力,黄茂林,向成宣,安培文.可调函数发生机构的尺度综合设计[J].中国机械工程,2004,15(7):P639-643
[31] 杜力,黄茂林,李太福.脉动式无级变速器真实运动规律的研究[J].中国机械工程,2004,15(12):P1080-1084
[32] 向成宣,黄茂林,林军.双输出脉冲发生器等价机构的综合原理和方法[J].机械设计,2003,20(10):P37-39
[33] 林军,任亨斌,黄茂林.双输出脉冲发生机构的运动规律求解[J].西南石油学院学报,2002,24(2):P63-65[34] 林军,黄茂林,任亨斌.双输出脉冲发生器的功能实现及其高阶综合方程的建立[J].机床与液压,2002,(2):P20-22
[35] 黄靖远,张浩,王序云,堵广智,王军.链环式超越离合器的数学模型和特性分析[J].清华大学学报(自然科学版),1997,37(11):P35-38
[36] 黄靖远,李平林,庄企华等.挠性环面接触式超越离合器的原理与应用[J].机械工程学报,1995,31(6):P73-77
[37] 罗吴翔.链环式超越离合器的应用基础研究[D].北京:清华大学,1999
[38] 黄靖远,张浩,王序云,褚广智,王军.链环式超越离合器的工作原理和物理本质[J].中国机械工程,1997,8(1):P108-111
[39] 罗吴翔,黄靖远.链环式双向超越离合器[J].机械,1996,26(6):P4-5
[40] 古纯效,任家骏,古辉.一种新型的扩环式单向超越离合器[J].工程设计,1997,(3):P42-43
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