铝合金车轮的结构分析及优化
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摘要
本文简述了国内外汽车产品的发展及现状,剖析了目前汽车车轮的发展状况。在深入分析了钢制车轮性能的基础上,以降低耗油率、减轻材料重量和提高车轮的使用寿命为宗旨,详细说明了铝合金车轮的合理性和优越性。
本文详细阐述了优化设计的基本思想,计算步骤,力学基础及其在汽车工业中的应用;具体说明了有限元分析软件ANSYS的功能和它的开放式结构以及ANSYS的主要特点,此外,还对ANSYS的理论部分做了进一步的说明。着重介绍了应用ANSYS对铝合金车轮进行结构强度分析、优化设计的具体过程。
本文所使用的车轮是按照轮辋的国家标准而构建的,而载荷是根据1997年中国汽车行业标准中的汽车轻合金车轮的性能要求和实验方法所规定的疲劳实验载荷所施加的。在车轮的构建上,本文采用了三维绘图软件UG,在UG中首先完成车轮几何建模,然后导入到ANSYS里面进行修改并进行有限元网格的划分,边界载荷的加入,材料特性的定义,对车轮进行强度分析。计算结果表明:最大应力值远小于铝合金车轮的需用盈利,强度储备很大,造成了材料的浪费,存在着进一步优化的潜力和必要。接着ANSYS中定义设计变量(分别为轮辋和轮辐的厚度),确定设计目标(使车轮重量最小),因最大应力不超过铝合金材料的许用应力为限,进行优化设计。结果表明:在不增加车轮最大应力值的情况下,优化后的铝合金车轮的应力分布更加合理,充分利用了材料,减轻了重量,降低了成本。
本次研究结果显示了ANSYS在强度分析和优化设计中的作用和意义,应用ANSYS对车轮进行强度分析和优化设计方法适用于指导任何其它型号车轮的生产。
In this paper, the development and actuality of motor vehicles product at home and aboard are reviewed and the market requisition of road wheel at present is analyzed first. On the basis of profound analysis of steel road wheel, according to the tenet of reducing the consumption of petrol, decreasing the weight of material, enhancing the age of road wheel, the reasonableness and feasibility of using aluminum alloy road wheel were investigated.
Then, the basic idea, calculation step, mechanical foundation of the optimum design and its use in motor vehicles are expatiated in detail. The function and open style structure of the finite-element analysis software, ANSYS, and the main features of ANSYS are concretely explained. Furthermore, the theory section of ANSYS is showed. The processes using ANSYS to carry through strength analysis and optimum design are introduced as a focal point.
Road wheel in this paper is created according to GB/T 3487-1996 and application of load is simulated the actual situation. ANSYS finished is used to build model of road wheel, divide finite element graticule, apply boundary load, and define material properties, which are submitted to ANSYS to analyze strength. The result shows the maximal stress value in original design is much less than the breaking point of aluminum alloy, which make material wasted. So it is necessary to optimize structure of road wheel. Using ANSYS to define design variable, determine design object and restrict constraint upper limit to optimize design. We find that the maximal stress value in road wheel approaches its breaking point. Therefore, this design makes material sufficiently used, the weight of road wheel effectively lightened. At the same time, stress distribution is more reasonable.
Through this study, we can find the function and significance of ANSYS is showed in strength analysis and optimum design. The intent of this paper is to introduce a kind of method, using ANSYS to analyze and optimize road wheel, which is fit to any road wheel.
本文详细阐述了优化设计的基本思想,计算步骤,力学基础及其在汽车工业中的应用;具体说明了有限元分析软件ANSYS的功能和它的开放式结构以及ANSYS的主要特点,此外,还对ANSYS的理论部分做了进一步的说明。着重介绍了应用ANSYS对铝合金车轮进行结构强度分析、优化设计的具体过程。
本文所使用的车轮是按照轮辋的国家标准而构建的,而载荷是根据1997年中国汽车行业标准中的汽车轻合金车轮的性能要求和实验方法所规定的疲劳实验载荷所施加的。在车轮的构建上,本文采用了三维绘图软件UG,在UG中首先完成车轮几何建模,然后导入到ANSYS里面进行修改并进行有限元网格的划分,边界载荷的加入,材料特性的定义,对车轮进行强度分析。计算结果表明:最大应力值远小于铝合金车轮的需用盈利,强度储备很大,造成了材料的浪费,存在着进一步优化的潜力和必要。接着ANSYS中定义设计变量(分别为轮辋和轮辐的厚度),确定设计目标(使车轮重量最小),因最大应力不超过铝合金材料的许用应力为限,进行优化设计。结果表明:在不增加车轮最大应力值的情况下,优化后的铝合金车轮的应力分布更加合理,充分利用了材料,减轻了重量,降低了成本。
本次研究结果显示了ANSYS在强度分析和优化设计中的作用和意义,应用ANSYS对车轮进行强度分析和优化设计方法适用于指导任何其它型号车轮的生产。
In this paper, the development and actuality of motor vehicles product at home and aboard are reviewed and the market requisition of road wheel at present is analyzed first. On the basis of profound analysis of steel road wheel, according to the tenet of reducing the consumption of petrol, decreasing the weight of material, enhancing the age of road wheel, the reasonableness and feasibility of using aluminum alloy road wheel were investigated.
Then, the basic idea, calculation step, mechanical foundation of the optimum design and its use in motor vehicles are expatiated in detail. The function and open style structure of the finite-element analysis software, ANSYS, and the main features of ANSYS are concretely explained. Furthermore, the theory section of ANSYS is showed. The processes using ANSYS to carry through strength analysis and optimum design are introduced as a focal point.
Road wheel in this paper is created according to GB/T 3487-1996 and application of load is simulated the actual situation. ANSYS finished is used to build model of road wheel, divide finite element graticule, apply boundary load, and define material properties, which are submitted to ANSYS to analyze strength. The result shows the maximal stress value in original design is much less than the breaking point of aluminum alloy, which make material wasted. So it is necessary to optimize structure of road wheel. Using ANSYS to define design variable, determine design object and restrict constraint upper limit to optimize design. We find that the maximal stress value in road wheel approaches its breaking point. Therefore, this design makes material sufficiently used, the weight of road wheel effectively lightened. At the same time, stress distribution is more reasonable.
Through this study, we can find the function and significance of ANSYS is showed in strength analysis and optimum design. The intent of this paper is to introduce a kind of method, using ANSYS to analyze and optimize road wheel, which is fit to any road wheel.
引文
[1] 彭晓东,刘江.轻合金在汽车工业中的应用.汽车工艺与材料,1999,(1)
[2] 赵鸿.铝在汽车上的应用.汽车工艺与材料,1997,(1)
[3] 杨映芬,齐洪亮.铝合金汽车轮毂的市场需求及发展趋势.有色金属设计,1999年第1期
[4] 余志生.汽车理论.第二版.北京:机械工业出版社,1998,5
[5] Mark P. Miller. Getting Started With MSC. NASTRAN. The MacNeal-Schwendler Corporation
[6] 张缇,陈建军.轿车车轮的有限元分析.陶瓷,1998,(1)
[7] 陈世平.汽车轻量化及其材料.汽车工艺与材料,1995,(4)
[8] 黎志云.铝合金材料在汽车上的应用.汽车之友,1997,(1)
[9] 吴植民.汽车构造(下).第二版.北京:人民交通出版社,1993.3
[10] DE Joslin, DP Clements. Squeaky Wheel Optimization. Fifteen National Conference on IAAA-98 and IAAI-98 Proceeding, 1998
[11] 于铭.铝制车轮.当代汽车,1991,(3)
[12] 毕林.汽车铝板应用新进展.世界汽车,1995,(4)
[13] 朱建国.汽车用铝材的应用现状与发展趋势.有色金属与稀土应用.1997.4
[14] 赖华清,徐翔,姚雄杰.铝合金铸件在汽车上的应用.材料与工艺.1999,(6)
[15] Aluminum Industry. Vol. 11, No. 2, April/May, 1992
[16] 程国华.铝合金轮毂有什么好处 汽车与社会,2000年第二期
[17] 王祝堂.试论我国汽车铝合金轮毂工业的发展.轻加工技术,1994,Vol.22,No.3
[18] Andrew Currie. Structural Optimization Comes of Age: Wheel Evaluation Yields Real-World Results. MSC Model of the mouth, March 1997
[19] 刘继承,周荣.汽车车轮CAD系统的研究.世界汽车,1998,(9)
[20] 中国汽车工业协会汽车工业十五规划 2001,7
[21] 吕铁山.锻造铝车轮的现状与发展趋势.世界汽车,1997,(3)
[22] 朱伯芳.有限单元法原理与应用.第一版 北京:水利水电出版社,1978,8
[23] 王勖成,邵敏.有限单元法基本原理和数值方法.北京:清华大学出版社,1997,3
[24] 王守信主编.有限元法教程.哈尔滨:哈尔滨工业大学出版社.1994,5
[25] 白忠喜主编.有限单元法基础教程.吉林:吉林科学技术出版社,1992
[26] 陈精一,蔡国忠.脑辅助工程分析ANSYS使用指南.北京:道出版社,2001,3
[27] 王国强.使用工程数值模拟技术及其在ANSYS上的应用.西北工业大学出版社,1999,3
[28] 徐显胜.有限元法在铝合金车轮优化设计中的应用.摩托车技术.1996,(11),P:6
[29] Unigraphics Essentials User Manual, Version 15.0. Unigraphics Solutions Inc, 1998
[30] 嘉木工作室.UG18实体建模实例教程.第一版.机械工业出版社,2002,5
[31] GB/T 3487—1996,中华人民共和国汽车行业标准汽车轮辋规格系列.北京:中华人民共和国机械工业部,1996,10
[32] 夸克工作室Unigraphics v16曲面设计应用第一版.科学出版社,2001,2
[33] H.M.Karandikar. Fatigue life Prediction for Wheels by Simulation of the Rotating Bending Test. SAE900147, P180-190
[34] Vatroslav Grubisic, Gerhard Fisher. Automotive Wheels Methods and Procedure for Optimal Design Testing, SAE Transaction 83135
[35] 秦德申.轿车车轮动态应力的测试与分析.汽车工程,1989,(4)
[36] 郑万东,谭善锟.轿车车轮疲劳寿命的探讨.汽车技术,1993,(3)
[37] 夏卫斌.汽车车轮疲劳试验加载分析.二汽科技,1992,(2)
[38] R.A.Ridha. Finite Element Analysis of Automatic Wheels. SAE Automotive Engineering Congress and Exposition, 1976, Volume 3, 760085
[39] 肖继道.轿车轮辐有限元应力分析.硕士学位论文,1993,11
[40] 韩鸣岗.汽车车轮有限元分析与结构优化.硕士学位论文,1996,6
[41] Coutu A. Finite Element Modeling of Periodic Parts for Stress Analysis. IAHR Sympoiun 1990,Belgrade Yugoslavia, 1990
[42] 叶尚辉.建立有限元模型的一般方法.电子机械工程学报 1999,(6)
[43] 嘉木工作室ANSYS5.7有限元实例分析教程.北京.机械工业出版社.2002,4
[44] Takabatake,Hideo;Imaizumi,Takayuki;Okatomi,Kunihiro. Simplified Analysis of Rectangular Plates with Stepped Thickness. Journal of Structural Engineering, 1995,121(1):28~37
[45] Wu,H.;Ni,X.;Liang,H.;Wang,X.Stress Analysis and Strength Estimation of Vessel Joint.Journal of Mechanical Strength,,2001,23(3):356~357+286
[46] QC-T221-1997,中华人民共和国汽车行业标准,北京:中华人民共和国机械工业部,1997,11
[47] 华东水利学院.弹性力学问题的有限元法.水利电力出版社.1978,10
[48] 刘鸿文.材料力学.第三版.北京.高等教育出版社.1993,9
[49] 邓先礼.最优化技术.第一版.重庆.重庆大学出版社 1998,1
[50] 美国ANSYS公司北京办事处.ANSYS设计优化培训手册.2001
[51] V.B. Venkayya. Design of optimum structures. Computers & Structures, No.12,1971,P265-309
[52] R.A. Gellatly, Helenbrook and L.H.Kocher. Multiple constrains in structural Optimization. Int. J.Num.meth. Eng.,vol.13,1978,P297-307
[53] L.A. Schmit and H. Miura. Approximation concepts for efficient structural Snthesis.NASNCR-252,Mar, 1976
[54] 孙靖民.机械优化设计.第一版.北京.机械工业出版社 1998,5
[55] 杨崇伦,张林瑞,郭家平.直升机机载油箱的应力分析和优化设计.2001年MSC Software
中国 用户论文集,2001,10
[56] Rajagopal K. Bathurst R.J. Development of a Finite Element Analysis Post processing Program. Advances in Engineering Software, 1993(6)
[57] Mikiskav Riesder, Richard I, Devries. Finite Element Anslysis and Structure Optimization of Vehicle Wheel. SAE Paper830133
[58] Morris A J.Foundaion of Structural Optimization. A Unifted Approach Wiley. 1982
[2] 赵鸿.铝在汽车上的应用.汽车工艺与材料,1997,(1)
[3] 杨映芬,齐洪亮.铝合金汽车轮毂的市场需求及发展趋势.有色金属设计,1999年第1期
[4] 余志生.汽车理论.第二版.北京:机械工业出版社,1998,5
[5] Mark P. Miller. Getting Started With MSC. NASTRAN. The MacNeal-Schwendler Corporation
[6] 张缇,陈建军.轿车车轮的有限元分析.陶瓷,1998,(1)
[7] 陈世平.汽车轻量化及其材料.汽车工艺与材料,1995,(4)
[8] 黎志云.铝合金材料在汽车上的应用.汽车之友,1997,(1)
[9] 吴植民.汽车构造(下).第二版.北京:人民交通出版社,1993.3
[10] DE Joslin, DP Clements. Squeaky Wheel Optimization. Fifteen National Conference on IAAA-98 and IAAI-98 Proceeding, 1998
[11] 于铭.铝制车轮.当代汽车,1991,(3)
[12] 毕林.汽车铝板应用新进展.世界汽车,1995,(4)
[13] 朱建国.汽车用铝材的应用现状与发展趋势.有色金属与稀土应用.1997.4
[14] 赖华清,徐翔,姚雄杰.铝合金铸件在汽车上的应用.材料与工艺.1999,(6)
[15] Aluminum Industry. Vol. 11, No. 2, April/May, 1992
[16] 程国华.铝合金轮毂有什么好处 汽车与社会,2000年第二期
[17] 王祝堂.试论我国汽车铝合金轮毂工业的发展.轻加工技术,1994,Vol.22,No.3
[18] Andrew Currie. Structural Optimization Comes of Age: Wheel Evaluation Yields Real-World Results. MSC Model of the mouth, March 1997
[19] 刘继承,周荣.汽车车轮CAD系统的研究.世界汽车,1998,(9)
[20] 中国汽车工业协会汽车工业十五规划 2001,7
[21] 吕铁山.锻造铝车轮的现状与发展趋势.世界汽车,1997,(3)
[22] 朱伯芳.有限单元法原理与应用.第一版 北京:水利水电出版社,1978,8
[23] 王勖成,邵敏.有限单元法基本原理和数值方法.北京:清华大学出版社,1997,3
[24] 王守信主编.有限元法教程.哈尔滨:哈尔滨工业大学出版社.1994,5
[25] 白忠喜主编.有限单元法基础教程.吉林:吉林科学技术出版社,1992
[26] 陈精一,蔡国忠.脑辅助工程分析ANSYS使用指南.北京:道出版社,2001,3
[27] 王国强.使用工程数值模拟技术及其在ANSYS上的应用.西北工业大学出版社,1999,3
[28] 徐显胜.有限元法在铝合金车轮优化设计中的应用.摩托车技术.1996,(11),P:6
[29] Unigraphics Essentials User Manual, Version 15.0. Unigraphics Solutions Inc, 1998
[30] 嘉木工作室.UG18实体建模实例教程.第一版.机械工业出版社,2002,5
[31] GB/T 3487—1996,中华人民共和国汽车行业标准汽车轮辋规格系列.北京:中华人民共和国机械工业部,1996,10
[32] 夸克工作室Unigraphics v16曲面设计应用第一版.科学出版社,2001,2
[33] H.M.Karandikar. Fatigue life Prediction for Wheels by Simulation of the Rotating Bending Test. SAE900147, P180-190
[34] Vatroslav Grubisic, Gerhard Fisher. Automotive Wheels Methods and Procedure for Optimal Design Testing, SAE Transaction 83135
[35] 秦德申.轿车车轮动态应力的测试与分析.汽车工程,1989,(4)
[36] 郑万东,谭善锟.轿车车轮疲劳寿命的探讨.汽车技术,1993,(3)
[37] 夏卫斌.汽车车轮疲劳试验加载分析.二汽科技,1992,(2)
[38] R.A.Ridha. Finite Element Analysis of Automatic Wheels. SAE Automotive Engineering Congress and Exposition, 1976, Volume 3, 760085
[39] 肖继道.轿车轮辐有限元应力分析.硕士学位论文,1993,11
[40] 韩鸣岗.汽车车轮有限元分析与结构优化.硕士学位论文,1996,6
[41] Coutu A. Finite Element Modeling of Periodic Parts for Stress Analysis. IAHR Sympoiun 1990,Belgrade Yugoslavia, 1990
[42] 叶尚辉.建立有限元模型的一般方法.电子机械工程学报 1999,(6)
[43] 嘉木工作室ANSYS5.7有限元实例分析教程.北京.机械工业出版社.2002,4
[44] Takabatake,Hideo;Imaizumi,Takayuki;Okatomi,Kunihiro. Simplified Analysis of Rectangular Plates with Stepped Thickness. Journal of Structural Engineering, 1995,121(1):28~37
[45] Wu,H.;Ni,X.;Liang,H.;Wang,X.Stress Analysis and Strength Estimation of Vessel Joint.Journal of Mechanical Strength,,2001,23(3):356~357+286
[46] QC-T221-1997,中华人民共和国汽车行业标准,北京:中华人民共和国机械工业部,1997,11
[47] 华东水利学院.弹性力学问题的有限元法.水利电力出版社.1978,10
[48] 刘鸿文.材料力学.第三版.北京.高等教育出版社.1993,9
[49] 邓先礼.最优化技术.第一版.重庆.重庆大学出版社 1998,1
[50] 美国ANSYS公司北京办事处.ANSYS设计优化培训手册.2001
[51] V.B. Venkayya. Design of optimum structures. Computers & Structures, No.12,1971,P265-309
[52] R.A. Gellatly, Helenbrook and L.H.Kocher. Multiple constrains in structural Optimization. Int. J.Num.meth. Eng.,vol.13,1978,P297-307
[53] L.A. Schmit and H. Miura. Approximation concepts for efficient structural Snthesis.NASNCR-252,Mar, 1976
[54] 孙靖民.机械优化设计.第一版.北京.机械工业出版社 1998,5
[55] 杨崇伦,张林瑞,郭家平.直升机机载油箱的应力分析和优化设计.2001年MSC Software
中国 用户论文集,2001,10
[56] Rajagopal K. Bathurst R.J. Development of a Finite Element Analysis Post processing Program. Advances in Engineering Software, 1993(6)
[57] Mikiskav Riesder, Richard I, Devries. Finite Element Anslysis and Structure Optimization of Vehicle Wheel. SAE Paper830133
[58] Morris A J.Foundaion of Structural Optimization. A Unifted Approach Wiley. 1982