Modeling, analysis and optimization of the rear axle of cereal combine harvester under real loads using finite elements method

IF 2.4 4区 农林科学 Q2 AGRICULTURAL ENGINEERING
A. Rezaei, H. Masoudi, H. Zaki Dizaji, Mohamad Esmail Khorasani Ferdavani
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引用次数: 0

Abstract

Cereals combine harvester is one of the agricultural machines that works in difficult conditions and different forces are applied to its parts. The purpose of this study was to analyze static and dynamic loads on the rear axle of JD955 combine harvester to optimize it. First, real loads on the axle were measured by a special electronic system in stationary and moving modes in roads and farm with various forward speeds. Then, geometric model of the axle was designed in the CATIA software. Finally static, harmonic, transient and dynamic analysis were performed using finite element method in the ANSYS Workbench software. Mean of maximum loads on the axle in stopped mode, asphalt road, dirt road and inside the farm (while moving parallel and perpendicular to the farrows and turning in farm end) were equal to 15.067, 18.830, 49.167, 21.428, 27.07 and 27.857 KN, respectively. There was relatively linear relationship between the axle load and deformation. At the maximum load of 49.167 KN, the maximum von Mises stresses of 1200, 85.848, 21.392 and 1.754e-14 MPa were obtained in static, transient, dynamic and harmonic analyzes, respectively. Since structural errors in the axle were numerically close to zero, so the calculated stress values had good accuracy. The axle fatigue life for most of the loads was equal to the ideal value of 106 cycles. The least fatigue safety factor were obtained from 0.072 to 0.745 in static analysis and from 0.174 to 1.029 in linear transient analysis. According to the results of the analysis, it was necessary to optimize the existing design of axle. So, a rectangular piece was suggested as the suitable design for the JD955 rear axle middle section.
谷物联合收割机后桥在实际载荷作用下的有限元建模、分析与优化
谷物联合收割机是一种在艰苦条件下工作的农业机械,它的零件受到不同的力。通过对JD955联合收割机后桥的静、动载荷分析,对其进行优化设计。首先,用一种特殊的电子系统测量了在不同前进速度的道路和农场中静止和移动模式下车轴上的实际载荷。然后,在CATIA软件中设计了轴的几何模型。最后在ANSYS Workbench软件中采用有限元法进行了静力、谐波、暂态和动力分析。停止模式、柏油路、土路和农场内(与犁沟平行、垂直移动和农场末端转弯时)的最大载荷均值分别为15.067、18.830、49.167、21.428、27.07和27.857 KN。轴载荷与变形之间存在相对的线性关系。在最大荷载为49.167 KN时,静、瞬态、动态和谐波分析的最大von Mises应力分别为1200、85.848、21.392和1.754e-14 MPa。由于轴的结构误差在数值上接近于零,因此计算出的应力值具有较好的精度。在大多数载荷作用下,轴的疲劳寿命等于106次的理想值。静态分析的疲劳安全系数最小,为0.072 ~ 0.745,线性瞬态分析的疲劳安全系数最小,为0.174 ~ 1.029。根据分析结果,有必要对现有的车轴设计进行优化。因此,建议采用矩形件作为JD955后桥中段的合适设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Agricultural Engineering
Journal of Agricultural Engineering AGRICULTURAL ENGINEERING-
CiteScore
2.30
自引率
5.60%
发文量
40
审稿时长
10 weeks
期刊介绍: The Journal of Agricultural Engineering (JAE) is the official journal of the Italian Society of Agricultural Engineering supported by University of Bologna, Italy. The subject matter covers a complete and interdisciplinary range of research in engineering for agriculture and biosystems.
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