重庆理工大学学报(自然科学) ›› 2024, Vol. 38 ›› Issue (1): 20-29.

• “轮胎力学特性建模与结构设计”专栏 • 上一篇    下一篇

轮胎等效模型与快速计算研究

周磊,肖振,付宏勋,张猛,姜洪旭   

  1. 山东理工大学交通与车辆工程学院,浦林成山(山东)轮胎有限公司
  • 出版日期:2024-02-07 发布日期:2024-02-07
  • 作者简介::周磊,男,硕士研究生,主要从事轮胎模型仿真研究,Email:21402010138@stumail.sdut.edu.cn;通信作者肖振,男,博士,讲师,主要从事新型安全轮胎与技术研究,Email:xiaozhen@sdut.edu.Cn

An investigation of tire equivalent model and efficient computation

  • Online:2024-02-07 Published:2024-02-07

摘要: 复杂的轮胎结构和橡胶等超弹材料是影响轮胎有限元模型精度和计算速度的重要因素。为实现模型的快速计算,通过探索线性材料构建轮胎有限元模型,对模型进行等效处理。构建了轮胎有限元精细模型,并通过台架试验对精细模型的有效性进行验证。对轮胎精细模型提出3种简化方式,分别为实体单元建模、实体单元和壳单元混合建模、实体单元和梁单元混合建模,并采用线性材料计算3种等效模型的充气侧向变形量、充气径向变形量以及径向加载下沉量,最终得到其最优等效模型。通过对等效模型接地印记和接地压力以及各阶模态与精细模型对比,验证了等效模型的准确性和计算效率,为整车有限元仿真提供一种轮胎建模方法

关键词: 有限元分析, 轮胎等效模型, 计算效率, 静态性能

Abstract: The intricate tire structure and hyperelastic materials such as rubber significantly impact the accuracy and computational speed of finite element models for tires. This stands as a crucial consideration in the tire modeling process. To ensure rapid computation of the finite element model for tires after matching with the entire vehicle, an exploration of simplified finite element model approaches is conducted. This involves constructing a linear material-based finite element model for tires and achieving equivalent processing of the model. Constructing a detailed finite element model for tires, conducting simulation analyses of stiffness characteristics and ground interaction properties, and validating the effectiveness of the detailed model through experimental and simulation comparisons. Three simplification approaches are proposed for the detailed tire model: solid element modeling, a hybrid model combining solid and shell elements, and a hybrid model combining solid and beam elements. Linearization of nonlinear materials is applied to these models. The inflation-induced lateral deformation, inflation-induced radial deformation, and radial load indentation are calculated using linear materials for the three equivalent models. Sensitivity analysis of material parameters based on deformation is conducted to obtain the optimal equivalent model. The results indicate that the equivalent model’s ground contact imprint and ground pressure, when compared with the detailed model, exhibit deviations within acceptable limits, confirming the accuracy of the equivalent model. The comparison of computational time between the equivalent model and the detailed model verifies a noticeable improvement in computational efficiency for the equivalent model. Furthermore, the feasibility of substituting the equivalent model for the detailed model is confirmed through a comparison of various modal orders between the two models. The proposed equivalent model provides a simplified approach for complex tire finite element simulations, offering a modeling simplification strategy. It serves as a tire modeling method for overall vehicle finite element simulations.

中图分类号: 

  • U463.3