My Account Log in

1 option

Drive Cycle-Based Design Optimization of Traction Motor Drives for Battery Electric Vehicles Using Data-Driven Approaches Vitesco Technologies Canada Incorporated

SAE Technical Papers (1906-current) Available online

View online
Format:
Book
Conference/Event
Author/Creator:
Mohammadi, Hossain, author.
Contributor:
Balamurali, Aiswarya
Nasirizarandi, Reza
Saini, Sandeep
Conference Name:
WCX SAE World Congress Experience (2024-04-16 : Detroit, Michigan, United States)
Language:
English
Physical Description:
1 online resource cm
Place of Publication:
Warrendale, PA SAE International 2024
Summary:
This paper demonstrates a data-driven methodology for the system-level design of high-power traction motor drives in modern battery electric vehicles. With the immense growth of battery electric vehicles in this transformative decade, the expected time to develop and market these powertrain components is becoming significantly shorter than for internal combustion engines. This rising demand is further complicated due to more stringent cost, efficiency and power density targets set by the U.S. Department of Energy. Hence, a system-level perspective is maintained in this data-driven methodology to identify the design requirements for traction motor drives by relying on a dynamic vehicle simulation toolchain and various drive cycles (e.g., EPA MCT, WLTC, US06, et cetera). The proposed data-driven approach can be used across different battery electric vehicle platforms including passenger and commercial types. A case study for a future-proof high-voltage architecture is demonstrated here for a C-segment all-wheel-drive mass market battery electric vehicle. Simulation results in this case study, validated against real-world driving data, indicate improvement in the total energy loss for different drive cycles as well as reduction in the mass, volume, and current draw of the designed machine using system-level feedback, thereby enabling higher torque and power density. The simulation results indicate that the total energy losses for five drive cycles were reduced by at least 11% and at most 27%, while increasing the Tip-In (0100 kph) acceleration time by 3 seconds; a compromise between vehicle performance and driving efficiency is expected. The operating points from various driving scenarios define the overall sizing requirements of the traction motor drive through statistical analysis in order to meet different optimization targets, such as extending the maximum efficiency region. These system-level requirements of the traction motor drive directly affect the co-design framework of multiphysics simulations along with the vehicle dynamics. The proposed data-driven methodology aids in effectively addressing the vehicle-level performance targets while downsizing the traction motor drive components to increase the overall range and reduce the system costs
Notes:
Vendor supplied data
Publisher Number:
2024-01-2172
Access Restriction:
Restricted for use by site license

The Penn Libraries is committed to describing library materials using current, accurate, and responsible language. If you discover outdated or inaccurate language, please fill out this feedback form to report it and suggest alternative language.

Find

Home Release notes

My Account

Shelf Request an item Bookmarks Fines and fees Settings

Guides

Using the Find catalog Using Articles+ Using your account