Abstract
This chapter presents the well-known vector control approach to control the ACIM torque accurately and dynamically. Various control strategies as well as their performances are analyzed and discussed in this chapter, which aims to give guidelines on designing machine control.
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Notes
- 1.
This is why sometimes it is called the torque current.
- 2.
- 3.
\(\textbf{V}_1^\prime \) is not the steady-state solution of the system, but rather a transient solution.
- 4.
The vector controlled electric machines are sometimes used as a torque sensor due to its high accuracy.
- 5.
\(L_m\) can be derived from \(L_{s}\), \(L_{r}\) and \(L_{\delta }\).
- 6.
For the similar reason, the estimation errors with stator, rotor and mutual \(L_s\), \(L_r\) and \(L_m\) are negligible.
References
Abootorabi Zarchi H, Mosaddegh Hesar H, Ayaz Khoshhava M (2019) Online maximum torque per power losses strategy for indirect rotor flux-oriented control-based induction motor drives. IET Electr Power Appl 13(2):259–265
Bozhko S, Dymko S, Kovbasa S, Peresada SM (2016) Maximum torque-per-amp control for traction im drives: theory and experimental results. IEEE Trans Ind Appl 53(1):181–193
Briz F, Degner MW, Lorenz RD (2000) Analysis and design of current regulators using complex vectors. IEEE Trans Ind Appl 36(3):817–825
Clark RN (1996) Control system dynamics. Cambridge University Press
Del Blanco FB, Degner MW, Lorenz RD (1999) Dynamic analysis of current regulators for ac motors using complex vectors. IEEE Trans Ind Appl 35(6):1424–1432
Franklin GF, Powell JD, Emami-Naeini A, Powell JD (2002) Feedback control of dynamic systems, vol 4. Prentice hall Upper Saddle River
Holtz J (1996) On the spatial propagation of transient magnetic fields in ac machines. IEEE Trans Ind Appl 32(4):927–937
Holtz J, Quan J, Schmittt G, Pontt J, Rodriguez J, Newman P, Miranda H (2003) Design of fast and robust current regulators for high power drives based on complex state variables. In: 38th IAS Annual Meeting on Conference Record of the Industry Applications Conference, 2003., IEEE, vol 3, pp 1997–2004
Idris NRN, Yatim AHM (2002) An improved stator flux estimation in steady-state operation for direct torque control of induction machines. IEEE Trans Ind Appl 38(1):110–116
Novotny DW, Lipo TA (1996) Vector control and dynamics of AC drives, vol 41. Oxford University Press
Pellegrino G, Bojoi RI, Guglielmi P (2011) Unified direct-flux vector control for ac motor drives. IEEE Trans Ind Appl 47(5):2093–2102
Sen PC (2021) Principles of electric machines and power electronics. Wiley
Trzynadlowski AM (2000) Control of induction motors. Elsevier
Vukosavic SN, Levi E (2003) A method for transient torque response improvement in optimum efficiency induction motor drives. IEEE Trans Energy Convers 18(4):484–493
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Shen, S., Chen, Qz. (2024). Vector Torque Control. In: Practical Control of Electric Machines for EV/HEVs . Lecture Notes in Electrical Engineering, vol 1064. Springer, Cham. https://doi.org/10.1007/978-3-031-38161-4_6
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DOI: https://doi.org/10.1007/978-3-031-38161-4_6
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