Abstract
The use of electric vehicles and their various configurations is seen as a major alternative in efforts towards reducing pollutant emissions from motor vehicles that continue to use fossil fuels. Electric transport technology presents more efficient means of energy conversion in vehicles: electric (EV), hybrid (VH), and hybrid electric (HEV) vehicles. For example, the energy storage system in the latter can be made up of ultracapacitors (UCs), batteries (Bs), and fuel cells. This work focuses on HEVs powered by batteries and ultracapacitors. In particular, the multiple converter configuration (C-CM) for the HEV powertrain system is analyzed using electric models of the vehicle powertrain components. To analyze the multiple converter configuration, parameters of a vehicle taken from the literature and the electrical model of the configuration were developed. With the above, the proposed configuration was evaluated before driving cycles (CITY II and ECE) and the configuration performance was compared with respect to other configurations. In the C-CM model, limitations in the choice of the number of Bs and UCs were observed in the powertrain depending on the maximum power of both energy sources and vehicle load demand. The results show that more energy is extracted from the batteries in the ECE cycle than in the CITY taking into account that the batteries are used as the main power source. C-CM results compared to other configurations show that energy extracted from batteries in the CITY is the same across all configurations. While energy consumption is lower in the ECE, C-CM results were not very significant compared to other configurations. However, the C-MC has the advantage of having better power flow control due to having two converters, thus improving HEV safety.
Highlights
Climate change brought on by environmental pollution has given rise to new requirements for energy conversion efficiency
This is the simplest method of combining a battery pack (Bs) and an ultracapacitor bank (UC)
The model was simulated in a vehicle study case and submitted to two terrain conditions (CITY and ECE)
Summary
Climate change brought on by environmental pollution has given rise to new requirements for energy conversion efficiency. EVs and HEVs today are considered a viable alternative since they offer an intelligent and efficient transport system without polluting emissions [8,9,10,11,12] Companies such as Honda, BMW, Kia, and Tesla, among others, already offer electric vehicles powered by batteries for sale [1,8,13]. Some authors have studied the infrastructure and environmental impacts of EVs in different cities These authors determined that the use of EVs is viable because electricity costs are much lower than the gasoline costs per km of the vehicle [10,11,12,13]. There are currently HEV prototypes powered by batteries (Bs) and ultracapacitors (UCs) [7,14,15,16], which feature good performance and autonomy [14,16,17,18]
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