Vehicle Design
Total results returned: 2
The Electric Vehicle Design page hosts a collection of resources aimed at exploring the evolving architecture of electric vehicles. Featuring reports, research papers, and industry insights, this section delves into how EV design is transforming traditional vehicle structures, from battery placement to lightweight materials and aerodynamics. Whether you're focused on the technical or aesthetic aspects of EV design, these materials provide a wealth of knowledge to help shape the future of electric vehicle innovation.
PerfECT Design Tool: Electric Vehicle Modelling and Experimental Validation
This article addresses a common issue in the design of battery electric vehicles (BEVs) by introducing a comprehensive methodology for the modeling and simulation of BEVs, referred to as the “PerfECT Design Tool”. The primary objective of this study is to provide engineers and researchers with a robust and streamlined approach for the early stages of electric vehicle (EV) design, offering valuable insights into the performance, energy consumption, current flow, and thermal behavior of these advanced automotive systems.
Automotive Designers, Automotive Engineers, Automotive Software Developers, Electric Powertrain Researchers, Electric Vehicle Manufacturers, Policymakers, Regulatory Bodies, Simulation Tool Providers, Thermal Management Researchers, Vehicle Dynamics Researchers
Batteries, Design Methodology, Electric Powertrain, Electric Vehicles, Modelling and Simulation, Vehicle Dynamics
Link:
mdpi.com
Simulation models of the High-Scape vehicles, PE systems and components
The Horizon Europe HighScape project will explore the feasibility of a family of highly efficient power electronics (PE) components and systems for Battery Electric Vehicles (BEVs), including integrated traction inverters, onboard chargers (OBCs), DC-DC converters, and electric drives for auxiliaries and chassis actuators.
In the work leading to this deliverable, the HighScape component providers and developers, focusing on the adoption of Wide Bandgap (WBG) based PE devices, have been generating the detailed simulation models of the respective components and systems (i.e., traction motor and traction inverter, OBCs, DC-DC converters, drives for Heating, Ventilation, and Air Conditioning (HVAC), and high voltage levelling suspension systems, and thermal systems for PE components/the whole vehicle), with a coverage of their parametrisation involving a wide range of BEV applications targeted in the project. The models enable model-based component and system design at the electrical, electronic, thermal and control levels. The components and systems models have been assembled into a vehicle simulation toolchain, for the rapid assessment of the implications of component design at the vehicle level, including considerations of thermal aspects. Due to the associated computational effort, the component models have been converted into surrogate models, such as Functional Mock-up Units (FMU) before their inclusion in the BEV simulation model. The definition, benefits and limitations of such surrogate models are discussed in the document.
Automotive Engineers, Automotive Industry Policymakers, Control System Designers, Electric Vehicle Manufacturers, Power Electronics Researchers, Simulation and Modelling Professionals, Thermal Management Researchers