Tractor Three-Point Hitch Control for an Independent Lower Arms System

Yogesh M. Chukewad; Sidakdeep Chadha; Karan S. Jagdale; Nishant Elkunchwar; Uriel A. Rosa; Zachary Omohundro

doi:10.3390/agriengineering6020100

AgriEngineering (Jun 2024)

Tractor Three-Point Hitch Control for an Independent Lower Arms System

Yogesh M. Chukewad,
Sidakdeep Chadha,
Karan S. Jagdale,
Nishant Elkunchwar,
Uriel A. Rosa,
Zachary Omohundro

Affiliations

Yogesh M. Chukewad: Zimeno Inc., dba Monarch Tractor, 203 Lawrence Dr Suite A, Livermore, CA 94551, USA
Sidakdeep Chadha: Zimeno Inc., dba Monarch Tractor, 203 Lawrence Dr Suite A, Livermore, CA 94551, USA
Karan S. Jagdale: Zimeno Inc., dba Monarch Tractor, 203 Lawrence Dr Suite A, Livermore, CA 94551, USA
Nishant Elkunchwar: Zimeno Inc., dba Monarch Tractor, 203 Lawrence Dr Suite A, Livermore, CA 94551, USA
Uriel A. Rosa: Zimeno Inc., dba Monarch Tractor, 203 Lawrence Dr Suite A, Livermore, CA 94551, USA
Zachary Omohundro: Zimeno Inc., dba Monarch Tractor, 203 Lawrence Dr Suite A, Livermore, CA 94551, USA

DOI: https://doi.org/10.3390/agriengineering6020100
Journal volume & issue: Vol. 6, no. 2
pp. 1725 – 1746

Abstract

Read online

The three-point hitch, found on agricultural tractors, facilitates the raising and lowering of an attached implement. Some tractors include a rock shaft that comprises a physical shaft that interconnects and facilitates the raising and lowering of the lower arms of the three-point hitch in a synchronized manner. In this study, we deal with a hitch system with the lower arms actuated by two independent hydraulic cylinders. This innovative tractor hitch system design allows the implement to follow the terrain, instead of the tractor, about the fore–aft (roll) axis of the tractor. However, since the two lower arms are independent, a specialized controller is needed to move these arms in unison. First, we present a position controller for individual arms and a roll controller to move these arms together. Second, we present a unique algorithm to emulate a physical rock shaft while the implement is operating in float mode. The algorithm ensures that the implement does not roll around the fore–aft axis while making sure it moves up and down vertically to follow the terrain. We present experimental results from the step response of the hitch system’s height while tracking a velocity reference. With the roll of the implement defined as the difference between the left arm’s position in percentage and that of the right arm in percentage, we observe that the largest mean roll was 0.23% with a flail mower attached and 0.26% without any implement. We then present results from the implement’s position in the float mode when the software rock shaft was activated and compare them with the case without the software rock shaft. The experiments showed that, when the software rock shaft was turned on, the mean roll reduced from 4.64% to 0.58% with a seed drill implement and from −3.99% to −0.59% with a flail mower implement. The standard deviations in these two implement cases improved from 16.77% to 2.79% and 6.45% to 3.53%, respectively, proving the effectiveness of the software rock shaft and its potential to replace the physical rock shaft found on the traditional tractors.

Published in AgriEngineering

ISSN: 2624-7402 (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Agriculture: Agriculture (General); Technology: Engineering (General). Civil engineering (General)
Website: https://www.mdpi.com/journal/agriengineering

About the journal

Abstract

Keywords