EJ2222 Design of Electrical Machines
KTH Royal Institute of Technology
Knowledge in electromagnetic field theory corresponding to EI1200. An introduction to electric machinery corresponding to EJ2201 is recommended but is not a formal requirement. 120 hp and English B or equivalent.
The course covers the following topics:
· The theory related to MMF waves (including harmonics) and how this theory is applied to electric machinery
· The steady-state equivalent circuit of the induction machine derived using the MMF theory
· Analytical models to estimate corresponding circuit parameters for IMs and PMSMs
· Magnetic and thermal sizing of IMs
· The finite element method and how it can be applied to solve static and quasi static two-dimensional magnetic problems
· Transient models of PMSMs
· Thermal modeling of electric machinery using the finite-element method
The overall goal of the course is that the participant, after a completed course, should have a deep understanding of how Maxwell’s equations and fundamental principles within heat transfer can be applied to analyze and design electric machines.
After the course, the participants should be able to:
· Apply the theory of MMF-waves to estimate air-gap flux densities, magnetic flux, inductances, and to derive the steady-state equivalent circuit of the induction machine (IM)
· Apply the theory of MMF-waves to analyze and understand limits of permanent-magnet synchronous machines (PMSMs)
· Implement a finite-element (FEM) based solver in a Matlab environment to solve static and quasi static, two-dimensional magnetic problems
· Use FEM-based computations to estimate different performance parameters of IMs and PMSMs
· Estimate stator and rotor resistances, magnetizing inductances and leakage-inductance components for IMs and corresponding parameters for PMSMs using analytical and numerical methods
· Carry out a preliminary electromagnetic sizing of an IM given a defined torque request and thermal limitations
· Carry out FEM-based computations on PMSMs to extract data to implement transient PMSM models including magnetic saturation, magnetic cross saturation and the impact of harmonics
· Carry out FEM-based computations to estimate the resulting temperature distribution in an electric machine of IM or PMSM type
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