Abstract
Recent developments in emissions regulations are pushing Non-Road Mobile Machineries manufacturers towards the adoption of more efficient solutions to reduce the amount of pollutants per unit of work performed. Electrification can be a reasonable alternative to traditional powertrain to achieve this goal. The higher complexity of working machines architectures requires, now more than ever, better design and testing methodologies to better integrate electric systems into mechanical and hydraulic layouts. In this work, the attention focused on the use of a Hardware in the Loop (HIL) approach to test performance of an energy management strategy (called load observer) developed specifically for an orchard tractor starting from field characterization. The HIL bench was designed to replicate a scaled architecture of a parallel hybrid electric tractor at mechanical and electrical level. The vehicle behavior was simulated with a personal computer connected on the CAN BUS network designed for the HIL system. Several tasks were simulated starting from data gathered during field measurements of a daily use of the machine. Results showed good performance in terms of load split between the two power sources and stability of the speed control although the variability of the applied load.
Highlights
Electric systems have demonstrated their capabilities in improving powertrain efficiency in vehicles applications [1,2]
Their adoption in hybrid electric vehicles (HEVs) and battery electric vehicles (BEVs) is increasing year by year especially in the automotive field contributing to the overall reduction of transportation emissions [3,4]
The Hardware in the Loop (HIL) testing activity proposed in this work focused on replicating a scaled version of a parallel hybrid electric orchard tractor to test feasibility of the electro-mechanical solution and performance of the energy management strategy
Summary
Electric systems have demonstrated their capabilities in improving powertrain efficiency in vehicles applications [1,2]. Machineries (NRMMs) or the wide population of machines used in off road applications. This category comprises construction, handling and agricultural machines, usually powered by diesel engines, known for their contribution to air pollution due to the production of CO, NOx , hydrocarbons and particulate matter [5,6,7]. The first solution includes the adoption of filtering systems whose size increases with the amount of exhaust gas to be treated [10]. With this solution, on board vehicle space is used without any improvement with respect to functionalities of the architecture. The adoption of electric machines and battery technologies together with efficient diesel engines or, in some licenses/by/4.0/)
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