Three-D Numerical Thermal Analysis of Electric Motor with Cooling Jacket

The need of a sustainable clean future has paved the way for environmental friendly electric vehicle technology. In electric vehicles, overloading is limited by the maximum temperature rise in the electric motor. Although an improved cooling jacket design is of vital importance in lowering the maximum temperature of the motor, there has not been as much study in the thermal analysis of motors compared to electromagnetic design studies. In this study, a three-dimensional steady state numerical method is used to investigate the performance of a cooling jacket using water as the primary coolant of a three-phase induction motor with special emphasis on the maximum temperature and the required pumping power. The effective thermal conductivity approach is employed to model the stator winding, stator yoke, rotor winding and rotor yoke. Heat transfer by induced air is treated as forced convection at the motor ends and effective conductivity is obtained for air in the stator-rotor gap. Motor power losses, i.e., copper and iron losses, are treated as heat generation sources. The effect of bearings and end windings is not considered in the current model. Pressure and temperature distributions under various coolant flow rates, number of flow passes and different cooling jacket configurations are obtained. The study is successful in identifying the hot spots and understanding the critical parameters that affect the temperature profile. The cooling jacket configuration affects the region of maximum temperature inside the motor. Increasing the number of flow passes and coolant flow rate decreases maximum motor temperature but results in an increase in the pumping power. Of the cooling jacket configurations and operating conditions investigated, a cooling jacket with six passes at a flow rate of 10 LPM with two-port configuration was found to be optimal for a 90-kW induction motor for safe operation at the maximum output.

[1]  Kevin J. Warner,et al.  The Climate-Independent Need for Renewable Energy in the 21st Century , 2017 .

[2]  Ranjan K. Behera,et al.  Design of a Three Phase Squirrel Cage Induction Motor for Electric Propulsion System , 2014 .

[3]  Peixin Liang,et al.  Temperature Field Accurate Modeling and Cooling Performance Evaluation of Direct-Drive Outer-Rotor Air-Cooling In-Wheel Motor , 2016 .

[4]  Thomas G. Habetler,et al.  Magnetic Effects of DC Signal Injection on Induction Motors for Thermal Evaluation of Stator Windings , 2011, IEEE Transactions on Industrial Electronics.

[5]  Desheng Li,et al.  Design and Performance of a Water-cooled Permanent Magnet Retarder for Heavy Vehicles , 2011, IEEE Transactions on Energy Conversion.

[6]  A. Vallan,et al.  Evaluation of radiation thermal resistances in industrial motors , 2005, IEEE Transactions on Industry Applications.

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

[8]  B. Laporte,et al.  A combined electromagnetic and thermal analysis of induction motors , 2005, IEEE Transactions on Magnetics.

[9]  Oscar Duque-Perez,et al.  State of the Art and Trends in the Monitoring, Detection and Diagnosis of Failures in Electric Induction Motors , 2017 .

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

[11]  Ping Zheng,et al.  Research on the High Power Density Electromagnetic Propeller , 2007, IEEE Transactions on Magnetics.

[12]  Ronghai Qu,et al.  Thermal Model of Totally Enclosed Water-Cooled Permanent-Magnet Synchronous Machines for Electric Vehicle Application , 2015, IEEE Transactions on Industry Applications.

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

[14]  Moo-Yeon Lee,et al.  Evaluation of the Effect of Operating Parameters on Thermal Performance of an Integrated Starter Generator in Hybrid Electric Vehicles , 2015 .

[15]  Sanjeevikumar Padmanaban,et al.  A Comprehensive Study of Key Electric Vehicle (EV) Components, Technologies, Challenges, Impacts, and Future Direction of Development , 2017 .

[16]  A. Boglietti,et al.  TEFC induction motors thermal models: a parameter sensitivity analysis , 2004, IEEE Transactions on Industry Applications.

[17]  Thomas Bäuml,et al.  Thermal Model and Behavior of a Totally-Enclosed-Water-Cooled Squirrel-Cage Induction Machine for Traction Applications , 2008, IEEE Transactions on Industrial Electronics.

[18]  Andrea Cavagnino,et al.  Evolution and Modern Approaches for Thermal Analysis of Electrical Machines , 2009, IEEE Transactions on Industrial Electronics.

[19]  Han-Wook Cho,et al.  Investigation of Temperature Rise in an Induction Motor Considering the Effect of Loading , 2014, IEEE Transactions on Magnetics.

[20]  A. Bousbaine Thermal Modelling of Induction Motors Based on Accurate Loss Density Distribution , 1999 .