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Measurement of three-dimensional soil-tire contact area and its application to the prediction of traction and soil compaction.

机译:三维土壤-轮胎接触面积的测量及其在牵引力和土壤压实度预测中的应用。

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摘要

Both the tractive performance of a pneumatic tire and the resulting soil compaction depend on the geometry of the contact surface developed at the soil-tire interface and the magnitude and distribution of stresses over this interface. The deformation of a pneumatic tire operating on a rigid surface is affected by the dimensions of the tire, carcass stiffness, lug design, inflation pressure and axle load. When the same tire is operated on a deformable soil, the tire deformation is determined to some extent by the strength of the soil.;The use of the measured contact surface in predicting both traction and compaction in the soil profile was demonstrated based upon the 2- scD and 3- scD contact regions and an assumed pressure distribution over the profile. Several soil models were investigated including models based on linear elasticity, a logarithmic pressure-sinkage model, and a semi-logarithmic porosity-stress relationship to obtain the pressure distribution. Procedures for obtaining values of the soil coefficients used in these models were also proposed. Traction predictions based upon the three-dimensional surface were better than those based upon the two-dimensional surface. Compaction predictions based upon both contact surface configurations were similar except for immediately below the soil surface.;A technique for measuring the dynamic three-dimensional contact profile between a tire and deformable soil was developed. The method involves measuring incremental lateral arc lengths of the profile at discrete locations along the contact length and fitting the coefficients of a model of soil deformation at the soil-tire interface to the experimental data using a nonlinear constrained optimization algorithm (scSUMT). Two representations of the measured contact area were compared: (i) The 2- scD surface which is the union of all points on the original undeformed soil surface which undergo deformation by the tire. (ii) The 3- scD final deformed surface. Contact area measurements were made for two different sized tires at two levels of inflation pressure, dynamic load and slip in two different soil conditions.
机译:充气轮胎的牵引性能和所产生的土壤压实性都取决于在土壤-轮胎界面处形成的接触表面的几何形状以及该界面上的应力的大小和分布。在刚性表面上操作的充气轮胎的变形会受到轮胎尺寸,胎体刚度,凸耳设计,充气压力和车轴载荷的影响。当同一轮胎在可变形的土壤上运行时,轮胎的变形在一定程度上取决于土壤的强度。;基于2证明了测得的接触表面在预测土壤剖面的牵引力和压实度方面的用途-scD和3-scD接触区域以及轮廓上的假定压力分布。研究了几种土壤模型,包括基于线性弹性的模型,对数压力-沉陷模型和半对数孔隙率-应力关系,以获得压力分布。还提出了获得这些模型中使用的土壤系数值的程序。基于三维表面的牵引力预测优于基于二维表面的牵引力预测。除紧靠土壤表面以下外,基于两种接触表面构型的压实预测均相似。;开发了一种用于测量轮胎与可变形土壤之间的动态三维接触轮廓的技术。该方法包括在沿接触长度的不连续位置测量剖面的增量侧向弧长,并使用非线性约束优化算法(scSUMT)将土壤-轮胎界面处的土壤变形模型的系数拟合至实验数据。比较了所测量的接触面积的两种表示形式:(i)2-scD表面,该表面是原始未变形土壤表面上所有点的联合,这些点由于轮胎而变形。 (ii)3-scD最终变形表面。在两种不同的土壤条件下,在两个水平的充气压力,动态载荷和打滑情况下,对两种不同尺寸的轮胎进行了接触面积测量。

著录项

  • 作者

    Wulfsohn, Dvoralaio.;

  • 作者单位

    University of California, Davis.;

  • 授予单位 University of California, Davis.;
  • 学科 Engineering Agricultural.;Engineering Automotive.
  • 学位 Ph.D.
  • 年度 1991
  • 页码 409 p.
  • 总页数 409
  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类
  • 关键词

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