- IUT Repository Home
- →
- Electrical and Electronics Engineering (EEE)
- →
- Thesis
- →
- Graduate
- →
- 2012
- →
- View Item
JavaScript is disabled for your browser. Some features of this site may not work without it.
| dc.contributor.author | Hasan, Md Rezaul | |
| dc.date.accessioned | 2018-10-12T09:10:50Z | |
| dc.date.available | 2018-10-12T09:10:50Z | |
| dc.date.issued | 2012-11-15 | |
| dc.identifier.citation | [1] S. A. Nasar, “Electromagnetic Energy Conversion Devices and Systems”. Englewood Cliffs, Prentice-Hall, 1970. [2] S.A. Nasar, “DC Switched Reluctance Motor", Proceedings of the Institution of Electrical Engineers, vol.166, no.6, June, 1996. [3] Miller TJE : Brushless Permanent-Magnet and Reluctance Motor Drives, Clarendon Press (Oxford), 1989 [4] Cheok AD, Fukuda Y : A New Torque and Flux Control Method for Switched Reluctance Motor Drives, IEEE Transactions on Power Electronics, Vol. 17, no. 4 July 2002 [5] Staton DA, Soong WL, Miller TJE : Unified Theory of Torque Production in Switched Reluctance and Synchronous Reluctance Motors, IEEE [6] P. French and A.H. Williams, “A New Electric Propulsion Motor", Proceedings of AIAA, Third Propulsion Joint Specialist Conference, Washington, July, 1967. [7] L.E. Unnewehr and H.W. Koch, “An Axial Air-Gap Reluctance Motor for Variable Speed Application", IEEE Transactions on Power Apparatus and Systems, vol. PAS- 93, no.1, January, 1974. [8] P.J. Lawrenson, J.M. Stephenson, P.T. Blenkinson, J. Corda and N.N. Fulton, “Variable-Speed Switched Reluctance Motors”, IEE Proc., vol. 127, July 1980. [9] P.J. Lawrenson, “Switched Reluctance Motor Drives", Electronics and Power Conference, 1983. 87 [10] T.E.J. Miller, and McGilp," Non-Linear Theory of the Switched Reluctance Motor for Rapid Computer-Aided Design", IEE Proceedings B 137, 1990. [11] R. Colby, F. Mottier, and T. Miller, “Vibration Nodes and Acoustic Noise in a 4- Phase Switched Reluctance Motor”, IEEE Trans. on Industry Applications 32, 1996. [12] J. Faiz, and J.W. Finch, “Aspects of Design Optimisation for Switched Reluctance Motors”, IEEE Trans. on Energy Conversion, 1993. [13] D.A. Torrey, X-M. Niu, and E.J. Unkauf, “Analytical Modelling of Variable- Reluctance Machine Magnetisation Characteristics”, IEE Proceedings Electric Power Application, 1995. [14] A.V. Radun, “Design Considerations for the Switched Reluctance Motor”, IEEE Trans. on Industry Applications 31, 1995. [15] S. Brisset, and P. Brochet, “Optimisation of Switched Reluctance Motors using Deterministic Methods with Static and Dynamic Finite Element Simulations”, IEEE Trans. on Magnetics 34, 1995. [16] I. Boldea and S.A. Nasar, “Electric Drives”, Ch. 12, CRC Press, 1999. [17] C. Roux, and M.M. Morcos, “On the Use of a Simplified Model for Switched Reluctance Motors”, IEEE Trans. on Energy Conversion 17, 2002. [18] P. J. Lawrenson, "Switched Reluctance Drives - A Fast Growing Technology", Electric Drives and Controls, April/May 1985. 88 [19] W.F. Ray and R.M. Davis, " Inverter Drive for Doubly Salient Reluctance Motor: Its Fundamental Behaviour, Linear Analysis and Cost Implications", Electric Power Applications, vol. 2, no. 6, December 1979. [20] H. Klode, A. Omekanda, A. Khalil, S. Underwood, I. Husain “The Potential of Switched Reluctance Motor Technology for Electro-Mechanical Brake Applications”, SAE International Simulation & Modelling Mechatronics, April, 2006. [21] W.F. Ray, P.J. Lawrenson, R.M. Davis, J.M. Stephenson, N.N. Fulton and R.J. Blake, "High Performance Switched Reluctance Brush Less Drives", in Conf. Rec. of IEEE Ind. Appl. Soc. Annual Meeting, 1985. [22] P. J. Lawrenson, J. M. Stephenson, P. T. Blenkinsop, J. Corda, and N. N. Fulton, “Variable-speed switched reluctance motor,” Proc. Inst. Elect. Eng., vol. 127, pp. 253–265, Jul. 1980. [23] N. N. Fulton and J. M. Stephenson, “A review of switched reluctance machine design,” in Proc. IEE Electric Machines Conf., 1988, pp. 120–126. [24] W. F. Ray, R.M.Davis, P. J. Lawrenson, J. M. Stepenson, N. N. Fulton, and R. J. Blake, “Switched reluctance motor drives for rail traction: A second view,” Proc. Inst. Elect. Eng., vol. 131, no. 5, pt. B, pp. 220–264, Sep. 1984. [25] M. R. Harris, J. W. Finch, J. A. Mallick, and T. J. E. Miller, “A review of the integral-horsepower switched reluctance motor drive,” IEEE Trans. Ind. Appl., vol. IA-22, no. 4, pp. 716–721, Jul./Aug. 1986. [26] T. Higuchi, J. O. Fiedler, and R. W. D. Doncker, “On the design of a single-phase reluctance motor,” in Proc. IEEE Electric Machines and Drives Conf., 2003, pp. 561–567. 89 [27] M. V. K. Chari, G. Bedrosian, J. D. Angelo, and A. Konrad, “Finite element applications in electrical engineering,” IEEE Trans. Magn., vol. 29, no. 2, pp. 1306–1314, Mar. 1993. [28] R. Arumugam, D. A. Lowther, R. Krishnan, and J. F. Lindsay, “Magnetic field analysis of a switched reluctance motor using a two dimensional finite element model,” IEEE Trans. Magn., vol. MAG-21, no. 5, pp. 1883–1885, Sep. 1985. [29] D. S. Reay, M. M. Moud, T. C. Green, and B. W.Williams, “Switched reluctance motor control via fuzzy adaptive systems,” in Proc. IEEE Control Systems Conf., Jun. 1995, pp. 527 531. [30] S. Bolognani and M. Zigliotto, “Fuzzy logic control of a switched reluctance motor drive,” IEEE Trans. Ind. Appl., vol. 32, no. 5, pp. 1063–1068, Sep./Oct. 1996. [31] S. Bolognani and M. Zigliotto, “Fuzzy logic control of a switched reluctance motor drive,” IEEE Trans. Ind. Appl., vol. 32, no. 5, pp. 1063–1068, Sep./Oct. 1996. [32] M. G. Rodrigues, W. I. Suemitsu, P. Branco, J. A. Dente, and L. G. B. Rolim, “Fuzzy logic control of a switched reluctance motor,” in Proc. IEEE ISIE, Guimaraes, Portugal, 1997, pp. 527–531. [33] P. C. Kjaer, J. J. Gribble, and T. J. E. Miller, “High-grade control of switched reluctance machines,” IEEE Trans. Ind. Appl., vol. 33, no. 6, pp. 1585–1593, Nov./Dec. 1997. [34] S. Mir, M. E. Elbuluk, and I. Husain, “Torque-ripple minimization in switched reluctance motors using adaptive fuzzy control,” IEEE Trans. Ind. Appl., vol. 35, no. 2, pp. 461–468, Mar./Apr. 1999. 90 [35] K. Russa, I. Husain, and M. E. Elbuluk, “A self-tuning controller for switched reluctance motors,” IEEE Trans. Power Electron., vol. 15, no. 3, pp. 545–552, May 2000. [36] S. Mir, M. S. Islam, T. Sebastian, and I. Husain, “Fault-tolerant switched reluctance motor drive using adaptive fuzzy logic controller,” IEEE Trans. Power Electron., vol. 19, no. 2, pp. 289–295, Mar. 2004. [37] S. Paramasivam and R. Arumugam, “Real time hybrid controller implementation for switched reluctance motor drive,” Amer. J. Appl. Sci., vol. 1, no. 4, pp. 284–294, 2004. [38] D.S.Reay. T.C Green and B.W.williams,“Neural Network used for torque ripple minimization for SRM”, EPE,Briton,Sep 1993,pp 1-5. [39] R. Krishnan “Switched Reluctance Motor Drives: Modelling, Simulation, Analysis, Design, and Applications”, CRC Press, 2001. [40] F. Soares, P.J. Costa Branco “Simulation of a 6/4 Switched Reluctance Motor Based on Matlab/Simulink Environment, IEEE Trans. On Aerospace and Electronic Systems vol. 37, no. 3 July 2001” [41] M. T. DiRenzo “Switched Reluctance Motor Control – Basic Operation and Example Using the TMS320F240”, Application Report SPRA420A – February 2000. [42] I. Husain and M. Ehsani,” Torque Ripple Minimization in Switched Reluctance Motor Drives by PWM Current Control”, Proc. APEC’94, 1994. [43] P. C. Kjaer, J. Gribble, and T. J. E. Miller, “High-grade Control of Switched Reluctance Machines”, IEEE Trans. Industry Electronics, Vol. 33, Nov. 1997. 91 [44] J. Stephenson, A. Hughes, and R. Mann, “Online Torque-Ripple Minimisation in a Switched Reluctance Motor over a Wide Speed Range”, IEE Proceedings Electric Power Application 149, 2002. [45] D. Cameron, J. Lang, and S. Umans, "The Origin and Reduction of Acoustic Noise in Doubly Salient Variable-Reluctance Motors", IEEE Trans. on Industry Applications 28, 1992. [46] C. Wu and C. Pollock, "Analysis and Reduction of Vibration and Acoustic Noise in the Switched Reluctance Drive", IEEE Trans. on Industry Applications 31, 1995. [47] W. Wu, J. B. Dunlop, S. J. Collocott and B. A. Kalati, “Design Optimisation of a Switched Reluctance Motor by Electromagnetic and Thermal Finite Element Analysis”, IEEE Transactions on Magnetics, USA, March 30 - April 3, 2003. [48] R. De Doncker, J. Fiedler, N. Fuengwarodsakul, S. Bauer, C. Carstensen “State-ofthe- Art of Switched Reluctance Drives for Hybrid and Electric Vehicles”, in Proc. 5th International Power Electronics Conference IPEC05, Nigata, Japan, April 2005. [49] V. Török, K. Loreth, “The World's Simplest Motor for Variable Speed Control, the Cyrano Motor, a PM-Biased SR-Motor of High Torque Density”, Proceedings of EPE '93, 5th European Conference on Power Electronics and Applications, IEE Conference Publication No. 377, Vol. 6, September, UK, 1993. [50] N. Fuengwarodsakul, J. Fiedler, S. Bauer, R. De Doncker “New Methodology in Sizing and Predesign of Switched Reluctance Machines Using Normalized Flux- Linkage Diagram”, in Proc. 40th IEEE-IAS Annual Meeting IAS05, Hong Kong, Oct 2005. 92 [51] J. Smart, “Single-Phase Variable Reluctance Motor Having Permanent Magnets Embedded within a Phase Winding”, U.S. patent 5.650.682, 1997. [52] Elliot, C. R., Stephenson, J. M., and McClelland, M. L. (1995) Advances in switched reluctance drive system dynamic simulation, Proceedings of EPE ’95, 3 (1995), 622—626. [53] Franceschini, G., Pirani, S., Rinaldi, M., and Tassoni, C. (1991) SPICE assisted simulation of controlled electric drives: An application to switched reluctance drives. IEEE Transactions on Industry Applications, 27, 6 (Nov./Dec. 1991), 1103—1110. [54] Ichinokura, O., Onda, T., Kimura, M., Watanabe, T., Yanada, T., and Guo, H. J. (1998) Analysis of dynamic characteristics of switched reluctance motor based on SPICE. IEEE Transactions on Magnetics, 34, 4 (1998), 2147—2149. [55] Skvarenina, Wasynczuk, Krause (1996) Simulation of a switched reluctance generator/more electric aircraft power system. In Proceedings of 1996 IECEC, paper 96398. [56] Radun, X. (1995) Switched reluctance starter/generator modeling results. In Proceedings of SAE Aerospace Atlantic Conference, 1995, paper 951407. [57] Pekarek, S. D., Wasynczuk, O., and Hegner, H. J. (1998) An efficient and accurate model for the simulation and analysis of synchronous machine/converter systems. IEEE Transactions on Energy Conversion (Mar. 1998), 42—49. [58] Ong, C-M. (1998) Dynamic Simulation of Electric Machinery using Matlab/Simulink. Englewood Cliffs, NJ: Prentice-Hall, 1998. 93 [59] Jackson, T.W., “Design and development of a low-cost controller for SRM drive, M.S. Thesis”, The Bradley Department of Electrical and Computer Engineering, Virginia Tech., Blacksburg, VA, July 1996. [60] Haupt, R.L., Haupt,S.E., “Practical Genetic Algorithms”,A.John. Wiley & Sons Publication, 1998 [61] Mitchell Melanie, “An Introduction to Genetic Algorithms”, MIT press, 1998. [62] Gen, M., Cheng, R., “Genetic Algorithms and Engineering Optimization”, John Wiley & Sons, Inc, 2000. [63] Reeves, C.R., Rowe, J.E.,”Genetic Algorithms - Principles and Perspectives, A guide to GA theory”, Kluwer Academic publishers, 2002. | en_US |
| dc.identifier.uri | http://hdl.handle.net/123456789/290 | |
| dc.description.abstract | Nowadays, switched reluctance motors (SRMs) attract more and more attention. Switched reluctance machines have emerged as an important technology in industrial automation. They represent a real alternative to conventional variable speed drives in many applications. It not only features a salient pole stator with concentrated coils, which allows earlier winding and shorter end turns than other types of motors, but also features a salient pole rotor, which has no conductors or magnets and is thus the simplest of all electric machine rotors. Simplicity makes the SRM inexpensive and reliable, and together with its high speed capacity and high torque to inertia ratio, makes it a superior choice in different applications. However, the control of the SRM is not an easy task. The motor flux linkage appears to be a nonlinear function of stator currents as well as rotor position, as does the generated electric torque. Apart from the complexity of the model, the SRM should be operated in a continuous phase-to-phase switching mode for proper motor control. This makes the control of SRM a tough challenging. This thesis attempts to first create a MATLAB model of multiphase SRM using the equations governing the dynamic behavior of linear inductance profile SRM. Based on this model, an example case study of single phase SRM operation has been. Small signal analysis of linearized single phase SRM was simulated. Performance analysis of the speed control loop, current control loop and overall SRM drive using PI controller was simulated in MATLAB environment and later all those were simulated again after PI controller was tuned by genetic algorithm. Performance improvement of genetically tuned PI controller is proved in this thesis. | en_US |
| dc.language.iso | en | en_US |
| dc.publisher | Department of Electrical and Electronic Engineering, Islamic University of Technology | en_US |
| dc.title | Development of a smart controller for a switched reluctance motor drives | en_US |
| dc.type | Thesis | en_US |
Files in this item
This item appears in the following Collection(s)
-
2012 [9]