Title :
A Linear Permanent-Magnet Motor for Active Vehicle Suspension
Author :
Wang, Jiabin ; Wang, Weiya ; Atallah, Kais
Author_Institution :
Dept. of Electron. & Electr. Eng., Univ. of Sheffield, Sheffield, UK
Abstract :
Traditionally, automotive suspension designs with passive components have been a compromise between the three conflicting demands of road holding, load carrying, and passenger comfort. Linear electromagnetic motor-based active suspension has superior controllability and bandwidth, provides shock load isolation between the vehicle chassis and wheel, and, therefore, has great potential. It also has the ability to recover energy that is dissipated in the shock absorber in the passive systems and results in a much more energy-efficient suspension system. This paper describes the issues pertinent to the design of a high force density tubular permanent-magnet (PM) motor for active suspension in terms of performance optimization, the use of a solid stator core for low-cost production and its impact on thrust force, and the assessment of demagnetization risk.
Keywords :
automobiles; linear motors; permanent magnet motors; suspensions (mechanical components); vehicle dynamics; wheels; PM motor; active vehicle suspension; automotive suspension designs; demagnetization risk; energy-efficient suspension system; high-force density tubular permanent magnet motor; linear electromagnetic motor; linear permanent-magnet motor; load carrying; low-cost production; passenger comfort; passive components; passive systems; performance optimization; road holding; shock absorber; shock load isolation; solid stator core; vehicle chassis; wheel; Demagnetization; Force; Iron; Magnetic circuits; Magnetic flux; Stator cores; Suspensions; Linear motors; permanent-magnet (PM) motors; suspension; vehicles;
Journal_Title :
Vehicular Technology, IEEE Transactions on
DOI :
10.1109/TVT.2010.2089546
