Development and Verification of a Simulation Model for 120 kW Class Electric AWD (All-Wheel-Drive) Tractor during Driving Operation

This study was conducted to develop a simulation model of a 120 kW class electric all-wheel-drive (AWD) tractor and verify the model by comparing the measurement and simulation results. The platform was developed based on the power transmission system, including batteries, electric motors, reducers,...

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Bibliographic Details
Published in:Energies (Basel) 2020-05, Vol.13 (10), p.2422
Main Authors: Baek, Seung-Yun, Kim, Yeon-Soo, Kim, Wan-Soo, Baek, Seung-Min, Kim, Yong-Joo
Format: Article
Language:English
Subjects:
Agricultural equipment
Alternating current
Batteries
Computer programs
Computer simulation
Control algorithms
Controller area network
Driving ability
driving test
Efficiency
electric AWD tractor
Electric converters
Electric motors
Energy
Farm machinery
Generators
Ground speed
Hybrid vehicles
Load
load measurement system
Optimization
Plows
Shafts (machine elements)
Simulation
simulation model
SOC level
Software
State of charge
Torque
Vehicle wheels
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Summary:This study was conducted to develop a simulation model of a 120 kW class electric all-wheel-drive (AWD) tractor and verify the model by comparing the measurement and simulation results. The platform was developed based on the power transmission system, including batteries, electric motors, reducers, wheels, and a charging system composed of a generator, an AC/DC converter, and chargers on each axle. The data measurement system was installed on the platform, consisting of an analog (current) and a digital part (rotational speed of electric motors and voltage and SOC (state of charge) level of batteries) by a CAN (controller area network) bus. The axle torque was calculated using the current and torque curves of the electric motor. The simulation model was developed by 1D simulation software and used axle torque and vehicle velocity data to create the simulation conditions. To compare the results of the simulation, a driving test using the platform was performed at a ground speed of 10 km/h in off- and on-road conditions. The similarities between the results were analyzed using statistical software and we found no significant difference in axle torque data. The simulation model was considered to be highly reliable given the change rate and average value of the SOC level. Using the simulation model, the workable time of driving operation was estimated to be about six hours and the workable time of plow tillage was estimated to be about 2.4 h. The results showed that the capacity of the battery is slightly low for plow tillage. However, in future studies, the electric AWD tractor performance could be improved through battery optimization through simulation under various conditions.
ISSN:1996-1073
1996-1073
DOI:10.3390/en13102422