Rotor Temperature Monitoring and Torque Correction for IPMSM of New
Energy Vehicle 2022-01-7063
As the electric vehicle market grows rapidly, thermal analysis related to the
performance of electric drive motors has gained increasing interest. However, it
is hard to obtain rotor temperature for torque correction during operation which
leads to unexpected inaccurate control of motors. Rotor temperature monitoring
and torque correction for IPMSM (Interior Permanent Magnet Synchronous motor) of
new Energy vehicles are discussed in this paper. Considering the practical
application, a low-order lumped parameter thermal network (LPTN) composed of
three nodes is built for calculating the rotor temperature under different
operating conditions on a 160kw IPMSM of a three-in-one electric drive. To
identify the parameters of LPTN, the measurements were done on a test bench with
a prototype of the three-in-one electric drive. K-type thermocouples were used
to directly measure the temperature of each node. The data transmission of rotor
temperature was realized by a wireless transmitter and receiver. Then, by
measuring the back EMF with no-load at different rotor temperatures, the curve
of flux linkage and rotor temperature was achieved. Finally, the Field oriented
Control strategy of IPMSM was optimized with torque correction based on the
rotor temperature model. A comparison test was performed in specified operating
conditions of IPMSM between the base model and the optimized model of torque
control. The test data indicates that under a speed of 16000rpm and torque
request of 50Nm, the maximum measured torque deviation decreases from -8.28%
under the base model to -1.66% under the Optimized model. The torque correction
based on the rotor temperature estimate can effectively improve the torque
control accuracy in the three-in-one electric drive.
Citation: Zhang, Y., Ma, T., Yang, Y., and Liang, Y., "Rotor Temperature Monitoring and Torque Correction for IPMSM of New Energy Vehicle," SAE Technical Paper 2022-01-7063, 2022, https://doi.org/10.4271/2022-01-7063. Download Citation