Abstract
This paper discusses kinetic energy recovery into electrical energy during deceleration of an industrial three-phase induction motor. The energy recovery helps to improve the efficiency of the induction motor drive. Simulation of direct torque control (DTC) drive for induction motor with load is carried out, and energy recovery results are shown. Improving energy utilization of a DTC-based induction motor drive for traction and industrial drives is discussed. Energy-saving opportunity is more where rapid deceleration/acceleration occurs. High inertia load like elevators, escalators, high-inertia rotary saws, rock crushers and grinders with flywheels, sheet saws driven by high-inertia wheels, centrifuges, and flywheel presses have more chance to get energy regeneration during deceleration. Induction motor drives which use braking resistors need to be removed, and energy storage devices need to be charged during deceleration of induction motor through the bidirectional converter for energy recovery.
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References
Bose BK (2001) Modern power electronics and AC drives. Prentice Hall PTR, pp 408–413
Reza CMFS, Islam MD, Mekhilef S (2014) A review of reliable and energy efficient direct torque controlled induction motor drives. Renew Sustain Energy (Elsevier) 37
Buja G, Kazmierkowski M (2004) Direct torque control of PWM inverter-fed AC motors—a survey. IEEE Trans Ind Electron 51(4):744–757
Isao T, Toshihiko N (1986) A new quick-response and high-efficiency control strategy of an induction motor. IEEE Trans Ind Appl 22:820–827
Depenbrock (1988) Direct self-control (DSC) of inverter-fed induction machine. IEEE Trans Power Electron 3:420–429
Pandya SN, Chatterjee JK (2008) Torque ripple minimization in direct torque control based IM drive Part-I: single-rate control strategy. In: Joint international conference on power system technology and IEEE power India conference, New Delhi, pp 1–8
Ferreira FJTE, Cistelecan MV, de Almeida AT, Baoming G (2008) Simple strategy to recover energy during stopping period in large high-inertia line-fed induction motor driven systems. In: 2008 18th international conference on electrical machines, Vilamoura, pp 1–6
Geraeea S et al (2018) Regenerative braking of electric vehicle using a modified direct torque control and adaptive control theory. Comput Electr Eng (Elsevier)
Itani K et al (2016) Comparison between two braking control methods integrating energy recovery for a two-wheel front driven electric vehicle. Energy Convers Manag (Elsevier)
Bjornsson L-H, Karlsson S (2016) The potential for brake energy regeneration under Swedish conditions. Appl Energy (Elsevier)
Chua CL et al (2011) Study of an electric vehicle drive dynamic testing system with energy recovery. In: 2011 International conference on power electronics and engineering application, Taiwan. Procedia Eng (Elsevier)
Patel PD, Pandya SN (2019) Energy regeneration during deceleration of direct torque control of induction motor drive for electric vehicles. In: Third IEEE international conference on electrical, computer and communication technologies (ICECCT 2019), Coimbtore, India, 20–22 Feb 2019
Kazmierkowski MP, Tunia H (1994) Automatic control of converter-fed drives. Elsevier, Amsterdam
Trzynadlowski AM (2001) Control of induction motors. Academic press, USA
Yan X, Patterson D (1999) Improvement of drive range, acceleration and deceleration performance in an electric vehicle propulsion system. In: 30th annual IEEE power electronics specialists conference. Record. Charleston, SC, vol 2, pp 638–643
Saleh M, Esa Y, Mhandi Y, Brandauer W, Mohamed A (2016) Design and implementation of CCNY DC microgrid testbed. In: IEEE industry applications society annual meeting, Portland, OR, pp 1–7
Kim S, Jeon J, Cho C, Ahn J, Kwon S (2008) Dynamic modeling and control of a grid-connected hybrid generation system with versatile power transfer. IEEE Trans Ind Electron 55(4):1677–1688. https://doi.org/10.1109/TIE.2007.907662
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Patel, P.D., Pandya, S.N. (2020). Energy Regeneration in Direct Torque Control Drive of Induction Motor. In: Mehta, A., Rawat, A., Chauhan, P. (eds) Advances in Control Systems and its Infrastructure. Lecture Notes in Electrical Engineering, vol 604. Springer, Singapore. https://doi.org/10.1007/978-981-15-0226-2_14
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DOI: https://doi.org/10.1007/978-981-15-0226-2_14
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