Dependence of IPMSM Motor Efficiency on Parameter Estimates
Abstract
:1. Introduction
2. Motor Efficiency and Maximum Torque per Current
2.1. Maximum Torque per Current (MTPC)
2.2. Parameter Estimation
2.2.1. Flux Linkage Map (FLM)
2.2.2. Frequency Domain Identification in Standstill (OffFreq)
2.2.3. Online Frequency Domain Identification (OlFreq)
2.2.4. Recursive Least Squares (RLS)
2.3. Optimal MTPC Using Torque Sensor
3. Laboratory Equipment
4. Experimental Results
4.1. Estimated Parameters
- Injections of the excitation signal significantly improve the accuracy of the RLS-based methods in all regimes except the full load conditions. This may be related to the inductance saturation or signal-to-noise ratio of the current measurements.
- For all methods with constant , the estimated inductance is decreasing with the increasing rotation speed, and is strongly current-dependent, see Figure 5. Estimates of the inductances obtained by the RLS that jointly estimate the flux are stabilized at values significantly lower than nominal, the variability has been absorbed by the flux parameter, see Figure 6. This seems to be an artifact of the RLS approach, since parameter variability can be tuned in more sophisticated methods such as the extended Kalman filter.
- The peak on the estimate obtained by the OlFreq method in Figure 5 is caused by the interference of the injected signal and multiples of the mechanical frequency during the transient.
4.2. Analysis of Motor Losses
4.3. Efficiency Evaluation
4.4. Discussion
- All parametric methods optimize the MPTC and in ideal condition should approach the results of the Sensor method which measures the optimal MPTC. However, it is not the most efficient method when other losses are taken into account. Thus bias in the estimated parameters method may actually improve the overall efficiency of the method if the bias is systematic towards the overall efficiency. This seems to be the case for the OffFreq method, which always performs better than Sensor and the RLS version at low loads. This clearly suggests that MTPC is not the optimal criteria and should be replaced by maximum torque per losses (MPTL) which also minimizes iron losses in the machine (for details see [10,29]).
- The best overall efficiency was obtained for parameters obtained from offline identification by the frequency analysis, see Figure 13. This is due to its consistency, being one of the top three methods at all loads. It is clearly the best at 100% load condition. For lower loads, the RLS method achieves marginally better results. This may be surprising, since OffFreq uses fixed parameters without any adaptation to operating conditions. This suggests that consistency of the method across operating regimes is more important than its accuracy under come conditions. This can be demonstrated by the OlFreq methods that perform well under 33% loads, but quickly deteriorates for higher loads.
- The findings of [23] that RLS is capable to improve drive efficiency are confirmed only for profiles with a low percentage of the full load operation. If the profile contains more full load conditions, the outcome may be quite the opposite and the RLS will yield worse efficiency than that with constant parameters. However, such conditions are unlikely in many applications such as electro-mobility and the use of RLS for parameter estimation can be recommended.
- The relative efficiency of the methods based on RLS slightly improves with the injection of the excitation signal. However, a decrease in performance was also observed for the method.
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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Glac, A.; Šmídl, V.; Peroutka, Z.; Hackl, C.M. Dependence of IPMSM Motor Efficiency on Parameter Estimates. Sustainability 2021, 13, 9299. https://doi.org/10.3390/su13169299
Glac A, Šmídl V, Peroutka Z, Hackl CM. Dependence of IPMSM Motor Efficiency on Parameter Estimates. Sustainability. 2021; 13(16):9299. https://doi.org/10.3390/su13169299
Chicago/Turabian StyleGlac, Antonín, Václav Šmídl, Zdeněk Peroutka, and Christoph M. Hackl. 2021. "Dependence of IPMSM Motor Efficiency on Parameter Estimates" Sustainability 13, no. 16: 9299. https://doi.org/10.3390/su13169299
APA StyleGlac, A., Šmídl, V., Peroutka, Z., & Hackl, C. M. (2021). Dependence of IPMSM Motor Efficiency on Parameter Estimates. Sustainability, 13(16), 9299. https://doi.org/10.3390/su13169299