Fatigue Life Simulation of Tractor Spiral Bevel Gear According to Major Agricultural Operations

Wan-Soo Kim,Nam-Gyu Lee,Seung-Min Baek,Duck-Kyu Choi,Il-Su Choi,Young-Keun Kim,Yong-Joo Kim,Seong-Un Park,Yong Choi,Seok-Pyo Moon,Yeon-Soo Kim,Chang-Hyun Choi

doi:10.3390/app10248898

Abstract

The spiral bevel gear in a tractor, unlike the other gears in the transmission, is one of the most vulnerable gears in terms of fatigue life, as it is consistently driven throughout the operations of the tractor. Conventional fatigue life tests of transmission gears require expensive equipment and repeated tests, and do not reflect dynamic field loads. The aim of this study is to develop a simulation model which can replace conventional fatigue life tests for actual gears, in order to evaluate the fatigue life of a tractor using dynamic field load data. A transmission simulation model including a spiral bevel gear was developed using commercial software. In order to measure the dynamic load of the tractor according to various field operations, an axle torque measurement system was developed, and field experiments were performed for major agricultural operations occurring in the field. Fatigue life was calculated using Rainflow cycle counting (RFC), the Smith–Watson–Topper (SWT) model, and S–N curves based on torque data measured in the field. The fatigue life under moldboard plow tillage, subsoiler tillage, rotary tillage, and baler operation were 13,599, 285, 278,884, and 525,977 h, respectively. The fatigue life of the tractor, according to subsoiler tillage and baler operation, was 0.104 and 192 times the service life, respectively, where the difference between these two operations was about 1846 times. The fatigue life of the tractor, according to the attached implement type, was significantly different. Therefore, it can be seen that the fatigue life of a tractor can be significantly different, depending on agricultural operation type which the farmer uses most often; this can be used as basic data for tractor design and evaluation. In addition, it is considered that the developed simulation model can be applied to fatigue life evaluation using dynamic field load data.

Highlights

The global tractor market is expected to increase gradually from USD 45,300 million in 2017 to USD 59,100 million in 2022, with a compound annual growth rate (CAGR) of 5.5% [1]
The purpose of this study is to develop a simulation model of a tractor transmission, in order to evaluate the fatigue life of an agricultural tractor transmission spiral bevel gear using dynamic field load data measured in the field
The major objectives of this study are as follows: (1) analysis of dynamic field load data for each agricultural operation measured through field experiments; (2) developing a simulation model of a transmission including the spiral bevel gear based on commercial software; (3) evaluation of the fatigue life of the spiral bevel gear for each agricultural operation

Summary

Introduction

The global tractor market is expected to increase gradually from USD 45,300 million in 2017 to USD 59,100 million in 2022, with a compound annual growth rate (CAGR) of 5.5% [1]. Among the various gear pairs of the transmission, the spiral bevel gear receives power from the range shift shaft and distributes the power to the left and right rear wheels at a right angle; a high level of design technology is required [4]. It is driven throughout the entire cycle of tractor operations (unlike other gears, whose frequency of use is determined by the gear stages) and has a high reduction gear ratio (i.e., a higher-load act) than other gears. The spiral bevel gear is the most basic core part, which is considered the most vulnerable in terms of fatigue life

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