Abstract
Efficient thermal management constitutes the key to guarantee the power output of electric vehicle power motors under high temperature environments and high load conditions. This study presents an oil cooling structure design aimed at ensuring the efficient operation of motors. The design concept was founded on five cooling structures, namely Parallel Channel (PC), Series Channel (SC), and Composite Series Channel (CSC) with 2, 3, and 4 branches in each pass respectively, and an optimization study was carried out on the external embedded oil cooling structure of stator for automotive permanent magnet synchronous motor (PMSM). The cooling performance and pressure drop from inlet to outlet were analyzed and compared among different oil cooling structures, based on which the CSC with 4 branches was determined as the basis for further optimization. The Performance Evaluation Criteria (PEC) was introduced in the structure evaluation to analyze the impact of channel form and channel dimension on cooling effect. The results of the study demonstrated that Case III (a composite series channel with height of 4 mm and width of 10 mm) was the best structure. Under rated condition, when the flow rate of coolant is 5 lpm, Case III reduces the average temperature of motor to 82.47 °C and the pressure drop to 57.442 kPa, which results in a 2.98% reduction in average temperature and a 19.77% reduction in pressure drop compared with CSC4. The cooling effect under peak power and peak torque conditions was analyzed, and the effectiveness of the structure was validated.
Issue Section:
Research Papers
Keywords:
power motor,
oil cooling,
structure design,
channel optimization,
electronic cooling,
energy efficiency,
heat exchangers,
heat transfer enhancement
Topics:
Cooling,
Engines,
Motors,
Optimization,
Temperature,
Stators,
Pressure drop,
Flow (Dynamics),
Dimensions,
Electric motors
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