Nonlinear Model Suitable for the Offline Cosimulation of Fault-Tolerant PM Motors Drives

Autor: Francesco Parasiliti Collazzo, Marco Tursini, Marco Villani, Alessio Di Tullio, G. Fabri
Jazyk: angličtina
Rok vydání: 2017
Předmět:
Rapid prototyping
Engineering
virtual prototyping
Brushless dc drives
fault-tolerant machines
finite element analysis
modeling
multiphase machines
simulation
virtual prototyping
multiphase machines
02 engineering and technology
finite element analysis
Counter-electromotive force
01 natural sciences
Industrial and Manufacturing Engineering
law.invention
fault-tolerant machines
law
Control theory
0103 physical sciences
0202 electrical engineering
electronic engineering
information engineering
Torque
Electrical and Electronic Engineering
Independence (probability theory)
010302 applied physics
Rotor (electric)
business.industry
020208 electrical & electronic engineering
Control engineering
Fault tolerance
modeling
Brushless dc drives
simulation
Finite element method
Range (mathematics)
Control and Systems Engineering
business
Popis: This paper presents a dynamic model suitable for accurate cosimulation of fault-tolerant permanent-magnet motor drives featuring independent-phase structure. The model is developed in a circuital form where the usual inductive parameters and back electromotive force coefficient are replaced by current and rotor position dependent functions, so that the exact electromagnetic nature and geometry of the machine are accounted over the large flux-current operating range. The model functions are precomputed by a finite element method analysis of a single phase of the machine, once the magnetic independence among the phases has been verified. Then, the circuital model is solved by a dynamical simulator which implements also the drive system, converter, and control, following on the offline cosimulation approach. The proposed model is validated by experiments carried on a fault-tolerant five-phase permanent-magnet motor-drive for aeronautical application, controlled by the brushless dc technique. The results show that the modeling solution is capable to simulate the motor dynamics with a high degree of accuracy, and can be used for an effective rapid prototyping of fault-tolerant drives.
Databáze: OpenAIRE
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