A Quantitative Comparison Study of Power-Electronic-Driven Flux-Modulated Machines Using Magnetic Field and Thermal Field Co-Simulation

Low-speed flux-modulated permanent-magnet (PM) machines do not need to conform to the conventional design rule which requires identical number of pole-pairs in both stator and rotor. In flux-modulated machines, special ferromagnetic segments in the airgap are used to modulate the magnetic field. In this paper, a general rule to compare different types of electric machines as well as measures to improve the torque density in these machines are presented. In this paper, the energy conversion capacity of different machines with the same physical size and the same operating temperature-rise are compared. An adaptive-order method for modeling the load-temperature-rise relationship is presented to reduce the computing time for this inverse problem. Three power-electronic-driven PM electric machines, which are, namely, a traditional PM machine, a radial-flux-modulated machine (RFMM), and an axial-flux-modulated machine (AFMM), are analyzed and compared based on their temperature distribution and electromagnetic torque density using magnetic field and thermal field computation. Experimental results of an AFMM prototype are used to validate the temperature-rise which is computed using 3-D finite-element method (3-D FEM).

[1]  Zhuoran Zhang,et al.  Temperature Calculation for Tubular Linear Motor by the Combination of Thermal Circuit and Temperature Field Method Considering the Linear Motion of Air Gap , 2014, IEEE Transactions on Industrial Electronics.

[2]  Andrea Cavagnino,et al.  Solving the more difficult aspects of electric motor thermal analysis in small and medium size industrial induction motors , 2005 .

[3]  V. Hatziathanassiou,et al.  Thermal analysis of an electrical machine taking into account the iron losses and the deep-bar effect , 1999 .

[4]  Lei Wang,et al.  A novel magnetic-geared outer-rotor permanent-magnet brushless motor , 2008 .

[5]  Jing Zhao,et al.  Optimization of the Magnetic Pole Shape of a Permanent-Magnet Synchronous Motor , 2007, IEEE Transactions on Magnetics.

[6]  Claudio Bruzzese,et al.  Computationally Efficient Thermal Analysis of a Low-Speed High-Thrust Linear Electric Actuator With a Three-Dimensional Thermal Network Approach , 2015, IEEE Transactions on Industrial Electronics.

[7]  P. Lagonotte,et al.  Thermal modeling of an induction machine through the association of two numerical approaches , 2006, IEEE Transactions on Energy Conversion.

[8]  Li Weili,et al.  Three-Dimensional Electromagnetic Field Calculation and Analysis of Axial–Radial Flux-Type High-Temperature Superconducting Synchronous Motor , 2013, IEEE Transactions on Applied Superconductivity.

[9]  B. G. Fernandes,et al.  A High-Torque-Density Permanent-Magnet Free Motor for in-Wheel Electric Vehicle Application , 2012, IEEE Transactions on Industry Applications.

[10]  K.T. Chau,et al.  A Magnetic-Geared Outer-Rotor Permanent-Magnet Brushless Machine for Wind Power Generation , 2007, 2007 IEEE Industry Applications Annual Meeting.

[11]  Chris Gerada,et al.  Integrated PM Machine Design for an Aircraft EMA , 2008, IEEE Transactions on Industrial Electronics.

[12]  K. Atallah,et al.  A novel high-performance magnetic gear , 2001 .

[13]  Shuangxia Niu,et al.  Design and Analysis of a Novel Axial-Flux Electric Machine , 2011, IEEE Transactions on Magnetics.

[14]  Li Liyi,et al.  Calculation and Experimental Study on Temperature Rise of a High OverLoad Tubular Permanent Magnet Linear Motor , 2013, IEEE Transactions on Plasma Science.

[15]  Andrea Cavagnino,et al.  A simplified thermal model for variable speed self cooled industrial induction motor , 2002 .

[16]  Ching Chuen Chan,et al.  Overview of Permanent-Magnet Brushless Drives for Electric and Hybrid Electric Vehicles , 2008, IEEE Transactions on Industrial Electronics.

[17]  S. Ho,et al.  A Quantitative Comparative Analysis of a Novel Flux-Modulated Permanent-Magnet Motor for Low-Speed Drive , 2010, IEEE Transactions on Magnetics.

[18]  Mahdi Ashabani,et al.  Multiobjective Shape Optimization of Segmented Pole Permanent-Magnet Synchronous Machines With Improved Torque Characteristics , 2011, IEEE Transactions on Magnetics.

[19]  L. Weili,et al.  Calculation and Analysis of Heat Transfer Coefficients and Temperature Fields of Air-Cooled Large Hydro-Generator Rotor Excitation Windings , 2011, IEEE Transactions on Energy Conversion.

[20]  Chunhua Liu,et al.  Design of a Magnetic-Geared Outer-Rotor Permanent-Magnet Brushless Motor for Electric Vehicles , 2007, IEEE Transactions on Magnetics.

[21]  Guan Chunwei,et al.  Calculation of a Complex 3-D Model of a Turbogenerator With End Region Regarding Electrical Losses, Cooling, and Heating , 2011, IEEE Transactions on Energy Conversion.

[22]  Jin Huang,et al.  Design, Analysis, and Sensorless Control of a Self-Decelerating Permanent-Magnet In-Wheel Motor , 2014, IEEE Transactions on Industrial Electronics.