Abstract
PurposeA scalable life cycle inventory (LCI) model of a permanent magnet electrical machine, containing both design and production data, has been established. The purpose is to contribute with new and easy-to-use data for LCA of electric vehicles by providing a scalable mass estimation and manufacturing inventory for a typical electrical automotive traction machine. The aim of this article (part I of two publications) is to present the machine design, the model structure, and an evaluation of the models’ mass estimations.MethodsData for design and production of electrical machines has been compiled from books, scientific papers, benchmarking literature, expert interviews, various specifications, factory records, and a factory site visit. For the design part, one small and one large reference machine were constructed in a software tool, which linked the machines’ maximum ability to deliver torque to the mass of its electromagnetically active parts. Additional data for remaining parts was then gathered separately to make the design complete. The two datasets were combined into one model, which calculates the mass of all motor subparts from an input of maximum power and torque. The range of the model is 20–200 kW and 48–477 Nm. The validity of the model was evaluated through comparison with seven permanent magnet electrical traction machines from established brands.Results and discussionThe LCI model was successfully implemented to calculate the mass content of 20 different materials in the motor. The models’ mass estimations deviate up to 21% from the examples of real motors, which still falls within expectations for a good result, considering a noticeable variability in design, even for the same machine type and similar requirements. The model results form a rough and reasonable median in comparison to the pattern created by all data points. Also, the reference motors were assessed for performance, showing that the electromagnetic efficiency reaches 96–97%.ConclusionsThe LCI model relies on thorough design data collection and fundamental electromagnetic theory. The selected design has a high efficiency, and the motor is suitable for electric propulsion of vehicles. Furthermore, the LCI model generates representative mass estimations when compared with recently published data for electrical traction machines. Hence, for permanent magnet-type machines, the LCI model may be used as a generic component estimation for LCA of electric vehicles, when specific data is lacking.
Highlights
1.1 BackgroundLife cycle assessment (LCA) of electrified vehicles for road transport, for example plug-in hybrid or fully electric passenger cars, is an active research area where many case studies are conducted and published (Hawkins et al 2012; Nordelöf et al 2014)
For permanent magnet-type machines, the life cycle inventory (LCI) model may be used as a generic component estimation for LCA of electric vehicles, when specific data is lacking
The electrical machine data represents a permanent magnet synchronous machine (PMSM), which is the most common type of motor for electric vehicles (Chan 2007; Miller 2013b). This dataset is limited in scope since it has been derived for an electric vehicle of a specific size and class, e.g., a Volkswagen Golf or similar, and it represents a fixed component mass, material composition, and set of performance parameters (Del Duce et al 2016; Weidema et al 2013)
Summary
A scalable life cycle inventory of an electrical automotive traction machine—Part I: design and composition. Anders Nordelöf1 & Emma Grunditz2 & Anne-Marie Tillman1 & Torbjörn Thiringer2 & Mikael Alatalo. Received: 15 July 2016 / Accepted: 23 March 2017 / Published online: 5 April 2017 # The Author(s) 2017. This article is published with open access at Springerlink.com
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