Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application
Multilevel inverters are known for their intial usage in high-voltage and high-power applications.This thesis presents the analysis and design of the Three-Phase Cascaded H-Bridge Multilevel Inverters (CHB-MLI) for three and five levels based on Newton-Raphson technique for harmonic reduction in Dyn...
Saved in:
| Main Author: | |
|---|---|
| Format: | Thesis |
| Language: | English English |
| Published: |
2018
|
| Subjects: | |
| Online Access: | http://eprints.utem.edu.my/id/eprint/23300/1/Performance%20Of%20Multilevel%20Inverters%20For%20Harmonic%20Reduction%20In%20Dynamic%20Voltage%20Restorer%20Application.pdf http://eprints.utem.edu.my/id/eprint/23300/2/Performance%20Of%20Multilevel%20Inverters%20For%20Harmonic%20Reduction%20In%20Dynamic%20Voltage%20Restorer%20Application.pdf |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| id |
my-utem-ep.23300 |
|---|---|
| record_format |
uketd_dc |
| institution |
Universiti Teknikal Malaysia Melaka |
| collection |
UTeM Repository |
| language |
English English |
| advisor |
Omar, Rosli |
| topic |
T Technology (General) T Technology (General) |
| spellingShingle |
T Technology (General) T Technology (General) Nordin, Norsyuhada Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application |
| description |
Multilevel inverters are known for their intial usage in high-voltage and high-power applications.This thesis presents the analysis and design of the Three-Phase Cascaded H-Bridge Multilevel Inverters (CHB-MLI) for three and five levels based on Newton-Raphson technique for harmonic reduction in Dynamic Voltage Restorer (DVR) application.The performance of the inverter outputs to reduce harmonics is crucial for DVR applications.Two DC sources were applied for two types of CHB-MLI.These types of inverters used Newton-Raphson method as their controllers.The main aim of this thesis is to design, model,construct,and conduct laboratory testing upon CHB-MLI of a three and five levels prototype for DVR application.The design of suitable multilevel inverters is very important for DVR purposes,so that the AC output voltage waveforms of the inverters have low content of harmonics during energy conversion process from DC to AC of the proposed inverters.The Digital Signal Processing (DSP) TMS320F2812 was used as a tool in order to create the coding based on the Newton-Raphson technique controller.The coding was developed,and then stored into the Digital Signal Processing (DSP) TMS320F2812 for output processing of the waveform of the inverters.The proposed controller using Newton-Raphson technique was applied to both three and five level of CHB-MLI.The optimization of this system has managed to reduce the harmonic contents of the inverters output.The performance of the developed prototype was tested using source codes of the programming for optimization technique.The experimental results of the developed prototype for both three and five levels were monitored and analysed.In addition,the performance of the proposed system was compared between simulation and experimental results for the optimization technique.The simulation and experimental results had shown the effectiveness of the proposed system in reducing harmonic.The waveforms in term of current and voltage were smooth and contain low contents of harmonic.Types of waveforms for five level of CHB-MLI which were more suitable to be used in the DVR applications. |
| format |
Thesis |
| qualification_name |
Master of Philosophy (M.Phil.) |
| qualification_level |
Master's degree |
| author |
Nordin, Norsyuhada |
| author_facet |
Nordin, Norsyuhada |
| author_sort |
Nordin, Norsyuhada |
| title |
Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application |
| title_short |
Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application |
| title_full |
Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application |
| title_fullStr |
Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application |
| title_full_unstemmed |
Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application |
| title_sort |
performance of multilevel inverters for harmonic reduction in dynamic voltage restorer application |
| granting_institution |
UTeM |
| granting_department |
Faculty Of Electrical Engineering |
| publishDate |
2018 |
| url |
http://eprints.utem.edu.my/id/eprint/23300/1/Performance%20Of%20Multilevel%20Inverters%20For%20Harmonic%20Reduction%20In%20Dynamic%20Voltage%20Restorer%20Application.pdf http://eprints.utem.edu.my/id/eprint/23300/2/Performance%20Of%20Multilevel%20Inverters%20For%20Harmonic%20Reduction%20In%20Dynamic%20Voltage%20Restorer%20Application.pdf |
| _version_ |
1747834031037218816 |
| spelling |
my-utem-ep.233002022-03-15T10:45:04Z Performance Of Multilevel Inverters For Harmonic Reduction In Dynamic Voltage Restorer Application 2018 Nordin, Norsyuhada T Technology (General) TK Electrical engineering. Electronics Nuclear engineering Multilevel inverters are known for their intial usage in high-voltage and high-power applications.This thesis presents the analysis and design of the Three-Phase Cascaded H-Bridge Multilevel Inverters (CHB-MLI) for three and five levels based on Newton-Raphson technique for harmonic reduction in Dynamic Voltage Restorer (DVR) application.The performance of the inverter outputs to reduce harmonics is crucial for DVR applications.Two DC sources were applied for two types of CHB-MLI.These types of inverters used Newton-Raphson method as their controllers.The main aim of this thesis is to design, model,construct,and conduct laboratory testing upon CHB-MLI of a three and five levels prototype for DVR application.The design of suitable multilevel inverters is very important for DVR purposes,so that the AC output voltage waveforms of the inverters have low content of harmonics during energy conversion process from DC to AC of the proposed inverters.The Digital Signal Processing (DSP) TMS320F2812 was used as a tool in order to create the coding based on the Newton-Raphson technique controller.The coding was developed,and then stored into the Digital Signal Processing (DSP) TMS320F2812 for output processing of the waveform of the inverters.The proposed controller using Newton-Raphson technique was applied to both three and five level of CHB-MLI.The optimization of this system has managed to reduce the harmonic contents of the inverters output.The performance of the developed prototype was tested using source codes of the programming for optimization technique.The experimental results of the developed prototype for both three and five levels were monitored and analysed.In addition,the performance of the proposed system was compared between simulation and experimental results for the optimization technique.The simulation and experimental results had shown the effectiveness of the proposed system in reducing harmonic.The waveforms in term of current and voltage were smooth and contain low contents of harmonic.Types of waveforms for five level of CHB-MLI which were more suitable to be used in the DVR applications. 2018 Thesis http://eprints.utem.edu.my/id/eprint/23300/ http://eprints.utem.edu.my/id/eprint/23300/1/Performance%20Of%20Multilevel%20Inverters%20For%20Harmonic%20Reduction%20In%20Dynamic%20Voltage%20Restorer%20Application.pdf text en public http://eprints.utem.edu.my/id/eprint/23300/2/Performance%20Of%20Multilevel%20Inverters%20For%20Harmonic%20Reduction%20In%20Dynamic%20Voltage%20Restorer%20Application.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=112695 mphil masters UTeM Faculty Of Electrical Engineering Omar, Rosli 1. Abdelhamid, T.H., and El-Naggar, K.M., 2007. Optimal PWM Control of a New Generalized Family of Multilevel Inverters. Journal of Electric Power Components and Systems, 36, pp. 73–92. 2. Ashcraft, S.R., and Halpin, S.M., 1996.DC-AC Inverters for Static Condenser and Dynamic Voltage Restorer Applications. Proceedings of the Twenty-Eighth South-Eastern Symposium on System Theory, Baton Rouge, LA, 31 Mar-2 April, 1996, pp. 215-219. 3. Awad, H., and Blaabjerg, F., 2004. Transient Performance Improvement of Static Series Compensator by Double Vector Control. 19th Annual IEEE on Applied Power Electronic Conference and Exposition, 1, pp. 607-613. 4. Awad, H., Svensson, J., and Bollen, M., 2004. Mitigation of Unbalanced Voltage Dips using Static Series Compensator. IEEE Transaction on Power Electronic, 19(3), pp.837- 846. 5. Azli, N.A., and Choong, Y.C., 2007. Analysis on the Performance of a Three-Phase Cascaded H-Bridge Multilevel Inverter. In: Proceedings of 1st International Power and Energy Conference, Purtajaya, Malaysia, 28-29 Nov 2006. 6. Bae, B.Y., Lee, D.Y, Lee, D.K., and Han, B.M., 2008. Development of High-Performance Single-Phase Line Interactive Dynamic Voltage Restorer. Australasian Universities Power Engineering Conference, pp. 1 – 6. 7. Bai, Z., Zhang, and Z., Zhang, Y., 2007. A Generalized Three-Phase Multilevel Current Source Inverter with Carrier Phase-Shifted SPWM. Conference on Power Electronic Specialists. 8. Banaei, M.R., Hosseini, S.H, Khanmohamadi, S., and Gharehpetian, G.B., 2006. Verification of a New Energy Control Strategy for Dynamic Voltage Restorer by Simulation. Elsevier Simulation Modeling Practice and Theory, 14(2), pp. 113-125.130 9. Barton, T.H., 1978. Pulse Width Modulation Waveforms – The Bessel Approximations. IEEE-IAS Conference Record. 10. Bayindir, K.C., Teke, A., and Tumay, M., 2008. A Robust Control of Dynamic Voltage Restorer using Fuzzy Logic. International Aegean Conference on Electrical Machines and Power Electronics, pp. 55 – 60. 11. Blasko, V., 1997. Analysis of a Hybrid PWM based on Modified Space-Vector and Triangle-Comparison Methods. IEEE Transactions on Industry Applications, 33(3), pp.756-764. 12. Boonchiam, P., and Mithulananthan,N., 2007. Dynamic Control Strategy in Medium Voltage DVR for Mitigating Voltage Sags/Swells. International Conference on Power System Technology, pp. 1-5. 13. Centre of Research on Power Electronic, Drives, Automation, and Control. The University of Malaya. TMS320F2812 Digital Signal Processor Implementation Tutorial. Texas Instruments, Spectrum Digital Incorporation, May 2002. 14. Chan, K, Kara, A, and Westermann, D., 2002.Integrated Gate Commutated Thyristor Based Dynamic Voltage Restorer. Proceedinds of the 1998 International Conference on Power System Technology, 1, pp.635-638. 15. Chan, P.K.W., Leung, K.K.S., Chung, H.S.H, and Hui, S.Y.R., 2006. Boundary Controller for Dynamic Voltage Restorers to Achieve Fast Dynamic Response. 21st Conference and Exposition on Applied Power Electronics, pp. 6. 16. Chen, T-P, Lai, Y-S., and Liu, C-H., 1999. A New Space Vector Modulation Technique for Inverter Control. 30th Annual IEEE Conference on Power Electronics Specialists, 2, 27 June-1 July 1999, pp.777-782. 17. Choi, S.S., Li, B.H., and Vilathgamuwa, D.M, 2002. A Comparative Study of Inverter- and Line- Side Filtering Schemes in the Dynamic Voltage Restorer. IEEE Power Engineering Society Winter Meeting, 4, pp. 2967 - 2972.131 18. Colak, I., and Kabalci, E., 2009. The Control Methods of the Multi-Level Inverter. TUBAV Sci ence, pp. 45–54. 19. Colak, I., Kabalci, E., and Bayindir, R., 2011. Review of Multilevel Voltage Source Inverter Topologies and Control Schemes. Energy Conversion and Management, 52(2), pp. 1114–1128. 20. Çolak, I., Kabalci, E., Bayindir, R., and Sagiroglu, S., 2009. The Design and Analysis of a 5-Level Cascaded Voltage Source Inverter with Low THD. In: Proceedings of International Conference on Power Engineering, Energy and Electronic Drives, Lisbon, Portugal. 21. Daehle, P., and Affolter, R., 2002. Requirements and Solutions for Dynamic Voltage Restorer, a Case Study. IEEE Power Engineering Society Winter Meeting, 4, pp.2881- 2885. 22. Dahono, P.A., Purwadi, A., and Qamaruzzaman, 1995. An LC Filter Design Method for Single-Phase PWM Inverters. IEEE International Conference on Power Electronics and Drive Systems, 2, pp. 571 – 576. 23. Di Perna, C., Verde, P., Sannino, A., and Bollen, M.H.J., 2003. Static Series Compensator for Voltage Dip Mitigation. Power Technical Conference Proceeding, Bolongna, 23-26 June 2004, pp. 8. 24. Diong, B., Sepahvand, H., and Corzine, K.A., 2012. Harmonic Distortion Optimization of Cascaded H-Bridge Inverters Considering Device Voltage Drops and Noninteger DC Voltage Ratios. IEEE Transactions on Industrial Electronics, 60(8), pp. 3106–3114. 25. Du, Z., Tolbert, L.M., and Chiasson, J.N., 2005. Reduced Switching Frequency Computed PWM Method for Multilevel Converter Control. IEEE Transaction on Power Electronic, pp. 2560–2564. 26. Du, Z., and Wang, X., 2007. SVPWM Speed Governing System of Induction Motor based on DSP. International Conference on “Computer as A Tool”, Warsaw, September 9-12.132 27. Dugan, R.C., Mcgranaghan, M.F., and Beaty, H.W., 2006. Electric Power Systems Quality. 2nd Edition, New York, Mc Graw Hill. 28. Escalante, M.F., Vannier, J.C., and Arzande, A., 2002. Flying Capacitor Multilevel Inverters and DTC Motor Drive Applications. IEEE Transactions on Industry Electronics, 49(4), pp. 809-815. 29. Fernandes, D.A., Naidu, S.R., and Lima, A.M.N., 2008. A Four Leg Voltage Source Converter based Dynamic Voltage Restorer. Conference on Power Electronics Specialists, pp.3760 – 3766. 30. Ghosh, A., and Ledwich, G., 2002. Compensation of Distribution System Voltage using DVR. IEEE Transactions on Power Delivery, 17(4), pp. 1030-1036. 31. Ghosh, A., and Ledwich, G., 2002. Power Quality Enhancement using Custom Power Devices. Kluwer Academic Publishers, London. 32. Govindaraj, K., Vikneshwaran, G., Sreejith, S., and Sowmiya, T., 2013. Harmonic Analysis of Inverter. International Journal of Engineering Science Invention, 2(11), pp. 53-61. 33. Grainger, J.J., and Stevenson, W.D., 1994. Power System Analysis. Mc Graw-Hill Book Company, New York. 34. Gualous, H., Bouquain, D., Berthon, A., and Kauffmann, J.M., 2003. Experimental Study of Supercapacitor Serial Resistance and Capacitance Variations with Temperature. Journal of Power Sources, 123(1), pp. 86-93. 35. H.S. Patel and R.G. Hoft, 1973. Generalized Harmonic Elimination and Voltage Control in Thyristor Converters: Part I – Harmonic Elimination. IEEE Transaction Industry Applications, IA- 9(3). pp. 310–317. 36. Han, H., Chao, Y., and Yingduo, H., 2002. The Simulation and Experiment of Dynamic Voltage Restorer Control Strategy. Power System Technology, 26(1).133 37. Hangzhou, C., 2008. Research on The SPLL based Single Phase Voltage Sag Detection Technique. Proceedings of the 7th International Conference on Instrumentation, Measurement, Circuits and Systems, pp. 62 – 65. 38. Hava, A.M., Kerkman, R.J., and Lipo, T.A., 2002. "Simple Analytical and Graphical Tools for Carrier Based PWM Methods. 28th Conference on Power Electronics Specialists, 2, 22- 27 June 1997, pp.1462-1471. 39. Heydt, G.T, Tan, W., Larose, T., and Negley, M., 1998. Simulation and Analysis of Series Voltage Boost Technology for Power Quality Enhancement. IEEE Transactions on Power Deliver, 13(4), pp. 1335–1341. 40. Ho, C.N.M., and Chung, H.S.H., 2006. Fast Transient Control of Single-Phase Dynamic Voltage Restorer (DVR), without External DC Source. Conference on Power Electronics Specialists, pp. 1 – 7. 41. Hua, C.C., Wu, C.W., and Chuang, C.W., 2007. Fully Digital Control of a 27-Level Cascade Inverter with Variable Dc Voltage Sources. In: Proceedings of IEEE Conference on Industrial Electronics and Applications, Harbin, China. 42. Ibrahim and A. Metwally, 2007. No Sag Industrial Power with DVRs. IEEE Potentials, 26(6), pp. 30 – 35. 43. IEEE Recommended Practice For Evaluating Electric Power System Compability With Electronic Process Equipment, IEEE Standard 1346-1998. 44. Ismail, B., Hassan, S.I.S, Ismail, R.C., Haron, A.R., and Azmi, A., 2014. Selective Harmonic Elimination of Five-Level Cascaded Inverter using Particle Swarm Optimization. International Journal of Engineering and Technology, 5(6), pp. 5220–5232. 45. Jimichi, T., Fujita, H., and Akagi, H., 2008. Design and Experimentation of a Dynamic Voltage Restorer Capable of Significantly Reducing an Energy-Storage Element. IEEE Transactions on Industry Applications, 44, pp. 817 - 825.134 46. Kim, I-D., Nho, E-C., Kim, H-G., and Ko, J.S., 2004.A Generalized Undeland Snubber for Flying Capacitor Multilevel Inverter and Converter. IEEE Transactions on Industrial Electronics, 51(6). 47. Kazemi, A., and Sohrforouzani, M.V., 2006. Power System Damping using Fuzzy Controlled Facts Devices. Journal of Electrical Power and Energy Systems, 28(5), pp 349– 357. 48. Khomfoi, S., and Tolbert, L., 2007. Power Electronics Handbook (2nd ed.), Academic Press, Florida, USA. 49. Kocalmis, A., and Sunter, S., 2006. Simulation of a Space Vector PWM Controller for a Three-Level Voltage-Fed Inverter Motor Drive. In: Proceedings of the 32nd Annual Conference of the IEEE Industrial Electronics Society, Paris, France. 50. Kuhn, H., Rüger, N.E., and Mertens. A., 2007. Control Strategy for Multilevel Inverter with Non-Ideal DC Sources. In: Proceedings of IEEE Power Electronics Specialists Conference, Orlando, USA. 51. Li, L., Czarkowski, D., Liu, Y., and Pillay, P., 2000. Multilevel Selective Harmonic Elimination PWM in Series Connected Voltage Inverters. IEEE Transactions on Industry Applications, 36, pp. 160–170. 52. Michael, P.A., and Devarajan, N., 2009. FPGA Implementation of Multilevel Space Vector PWM Algorithms. International Journal of Engineering and Technology, 1(3). 53. Mohammed, A.A.E, 2006. Study of Interconnecting Issues of Photovoltaic/Wind Hybrid System with Electric Utility Using Artificial Intelligence, Ph.D. Thesis, Faculty of Engineering, Minia University, 2006.135 54. Mohanty, R., Rath, S., and Mishra, S.P., 2013.A Comparison Study of Harmonic Elimination in Cascade Multilevel Inverter using Particle Swarm Optimization and Genetic Algorithm. IOSR Journal of Electrical and Electronics Engineering, 5(1), pp. 43–49. 55. Munoz, A.M., 2007. Power Quality: Mitigation Technologies in Distributed Environment. Springer-Verlag London Limited. 56. Omar, R., Rasheed, M., and Sulaiman, M., 2015. A Survey of Multilevel Inverter based on Cascaded H-Bridge Topology and Control Schemes. MAGNT Research Report, 3(2), pp. 1097–1108. 57. Omar, R., Sabari, A., and Sulaiman, M., 2015. Harmonic Reduction of Cascaded H-Bridge Multilevel Inverter Based on Newton-Raphson. International Journal of Recent Technology and Engineering, 10(3), Pp. 6569–6580. 58. Panda, K.P., Sahu, B.P., and Samal, D., 2013. Switching Angle Estimation using GA Toolbox for Simulation of Cascaded Multilevel Inverter. International Journal on Computer Applications, 73(21), pp. 21–26. 59. Pantech Solution, 2015. Three Phase Induction Motor Control in TMS320F2812 DSP Kit. Texas Instrument, Pantech Solution Technology beyond the Dreams. 60. Rahim, N.A., Ping, H.W., and Selvaraj, J., 2013. Elimination of Harmonics in Photovoltaic Seven-Level Inverter with Newton-Raphson Optimization, Procedia Environmental Sciences, 17, pp. 519–528. 61. Ramasamy, A.K., Iyer, R.K., Ramachandramuthy, V.K., and Mukherjee, R.N., 2005. Dynamic Voltage Restorer for Voltage Sag Compensation. International Conference on Power Electronic and Drive Systems, pp. 1289-1293. 62. Rathore, A.K., Hotlz, J., and Boller, T., 2010. Synchronous Optimal Pulsewidth Modulation for Low-Switching-Frequency Control of Medium-Voltage Multilevel Inverters. IEEE Transactions on Industrial Electronics, 57(7), pp. 2374–2381.136 63. Rodriguez, J., Lai, J.S., and Peng, F.Z., 2002. Multilevel Inverters: A Survey of Topologies, Controls, and Applications. IEEE Transaction on Industrial Electronic, 49, pp. 724-738. 64. Song, B-M., Kim, J., Lai, J-S., Seong, K-C., Kim, H-J., and Park, S-S., 2001. A Multilevel Soft Switching Inverter with Inductor Coupling. IEEE Transactions on Industry Applications, 37(2), pp. 628-636. 65. Srimaheswaran, V., and Uthirasamy, R., 2013.Cascaded Multilevel Inverter for PV Cell Application using PIC Microcontroller. International Journal of Innovative Technology and Exploring Engineering, 2(3), pp. 2278-3075. 66. Sulaiman, M., Omar, R., and Rasheed, M., 2013. Fundamental Studies of a Three Phase Cascaded H-Bridge and Diode Clamped Multilevel Inverters using Matlab/Simulink. International Review of Automatic Control, 6(5). 67. Sumithira, T.R., Nirmal, A., and Kumar, 2013. Elimination of Harmonics in Multilevel Inverters Connected to Solar Photovoltaic Systems Using ANFIS: An Experimental Case Study. Journal of Applied Research and Technology, 11(February), pp. 124–132. 68. Suresh Kota, M.V.P.M.S., 2012. An Inverted Sine PWM Scheme for New Eleven Level Inverter Topology. International Journal of Advance Engineering Technology, 4(2), pp. 425–433. 69. TMS320C281x Analog to Digital Converter Reference Guide (SPRU060), Texas Instrument TMS320C281x Event Manager Reference Guide (SPRU065), Texas Instruments, 2004. 70. Trzynadlowski, A.M., and Legowski, S., 1994. Minimum-Loss Vector PWM Strategy for Three-Phase Inverters. IEEE Transactions on Power Electronics, 9(1), pp.26-34. 71. Vas, P., 1992. Electrical Machines and Drives: A Space Vector Theory Approach. Oxford University Press.137 72. Yadav, A., and Kumar, J., 2013. Harmonic Reduction in Cascaded Multilevel Inverter. International Journal of Recent Technology and Engineering, 2(2), pp.147–149. 73. Yan, H., Li, J., Tang, G., and Chen, Q., 2004. Study of Series Power Quality Compensator with Feedback Control Strategy for Inverters. Proceeding of the 2004 IEEE International Conference on Electric Utility Deregulation, Restructuring and Power Technologies, Hong Kong, pp. 752-757. 74. Żelechowski, M., 2005. Space Vector Modulated – Direct Torque Control (DTC-SVM) Inverter – Fed Induction Motor Drive. (Ph.D. Thesis). |