Mathematical Model of Hydrodynamic Torque Converter and Analytic Description of Streamline 被引量：7

Mathematical Model of Hydrodynamic Torque Converter and Analytic Description of Streamline

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摘要 The mathematical model of a 3-element centripetal-turbine hydrodynamic torque converter and analytic description of fluid flow inside the hydrodynamic torque converter are investigated. A new torus coordinate system is proposed so as to quantitatively describe fluid movement inside the hydrodynamic torque converter. The particle movement inside the hydrodynamic torque converter is decomposed into meridional component movement and torus component movement, and a universal meridional streamline equation is derived. According to the relationship between the converter wheel velocity polygon and its blade angle, a torus streamline differential equation is established. The universal meridional streamline equation is approximated with square polynomials. The approximation error curve is given and the percentage error is not greater than 0.86%. Considered as a function of polar angle, the blade angle cotangent of each converter wheel varies linearly with polar angle. By using integral calculus, torus streamline equations are obtained. As a result, the problem of difficult flow description of the hydrodynamic torque converter is solved and a new analytic research system is established. The mathematical model of a 3-element centripetal-turbine hydrodynamic torque converter and analytic description of fluid flow inside the hydrodynamic torque converter are investigated. A new torus coordinate system is proposed so as to quantitatively describe fluid movement inside the hydrodynamic torque converter. The particle movement inside the hydrodynamic torque converter is decomposed into meridional component movement and torus component movement, and a universal meridional streamline equation is derived. According to the relationship between the converter wheel velocity polygon and its blade angle, a torus streamline differential equation is established. The universal meridional streamline equation is approximated with square polynomials. The approximation error curve is given and the percentage error is not greater than 0.86%. Considered as a function of polar angle, the blade angle cotangent of each converter wheel varies linearly with polar angle. By using integral calculus, torus streamline equations are obtained. As a result, the problem of difficult flow description of the hydrodynamic torque converter is solved and a new analytic research system is established.

作者 LIU Shiping QUAN Long

机构地区 Institute of Mechatronics Engineering

出处《Chinese Journal of Mechanical Engineering》 SCIE EI CAS CSCD 2009年第1期70-77,共8页 中国机械工程学报（英文版）

基金 supported by Henan Provincial Tackle Key Program of China (Grant No. 0424260038)

关键词 hydrodynamic torque converter toms coordinate system analytic description meridional streamline equation toms streamline equation hydrodynamic torque converter, toms coordinate system, analytic description, meridional streamline equation, toms streamline equation

分类号 TH137.332 [机械工程—机械制造及自动化] O141.4 [理学—基础数学]

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Chinese Journal of Mechanical Engineering

2009年第1期

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