DOMINANT TECHNOLOGIES IN “INDUSTRY 4.0”
Study of energy parameters in alternative power source microgrid systems with multilevel inverters
- 1 Faculty of Mechanics and Energy – Ukrainian State University of Railway Transport, Ukraine
Abstract
Microgrid-systems with alternative energy sources in which multilevel inverters are used are becoming more widespread. Possible circuit implementations of multilevel inverters for thus systems are shown. A comparative analysis of the energy parameters of multilevel inverters using various modulation algorithms is presented. important requirement of multilevel voltage inverters is to ensure high quality output voltage, as well as ensuring minimum power loss and maximum efficiency. An overview of known modulation algorithms for output voltage generation in multilevel inverters is presented. The analysis of existing algorithms was performed and the choice of the optimal algorithm for use in the scheme of solar power plants was carried out.
Keywords
References
- Smolenski R. Conducted electromagnetic interference in Smart Grids. Springer-Verlag London. 2012. P. 160. DOI: 10.1007/978-1-4471-2960-8.
- Wilker S., Meisel M., Sauter T. Smart Grid architecture modelstandardization and the applicability of domain language specificmodeling tools. 2017 IEEE 26th International Symposium on Industrial Electronics. Edinburgh, 2017. P. 152–157.
- Neureiter C., Engel D., Uslar M. Domain specific and modelbased systems engineering in the Smart Grid as prerequesite for security by design. MDPI Electronics. 2016. Vol. 5, Issue 2. P. 24.
- Nerubatskyi V. P. Determination of optimal control of traction motor of electric rolling stock of DC rail in terms of power consumption. Information and Control Systems at Railway Transport. 2011. No. 1. P. 59–64.
- Nerubatskyi V., Plakhtii O., Kotlyarov V. Analysis of topologies of active four-quadrant rectifiers for implementing the INDUSTRY 4.0 principles in traffic power supply systems. International scientific journal «Industry 4.0». 2019. Vol. 4, Issue 3. P. 106–109.
- Franсa B. W. Static synchronous generator with sliding droop control for distributed generation in microgrids. da Universidade Federal do Rio de Janeiro. 2016. P. 110.
- Ortiz G. High-Power DC-DC converter technologies for Smart Grid and traction applications. Eidgenossische Technische Hochschule ETH Zurich. 2014. 283 p.
- Padmane P. V., Rane P. R. Improvement of power quality in multibus system by interphase power controller. International Journal of Scientific Engineering and Research. 2015. Vol. 3, Issue 10. P. 80–84.
- Hsieh Y. P., Liang T. J., Yang L. S. Novel high step-up DC-DC converter for distributed generation system. IEEE Transactions on Industrial Electronics. 2013. Vol. 60, Issue 4. P. 1473–1482. DOI: 10.1109/tie.2011.2107721.
- Khanchi S., Garg V. Unified power flow controller: a review. International Journal of Engineering Research and Applications. 2013. Vol. 3, Issue 4. P. 1430–1435.
- Scherback Ya. V., Plakhtiy O. A., Nerubatskiy V. P. Control characteristics of active four-quadrant converter in rectifier and recovery mode. Tekhnichna elektrodynamika. 2017. No 6. P. 26–31. DOI: https://doi.org/10.15407/techned2017.06.026.
- Plakhtii O. A., Nerubatskyi V. P., Hordiienko D. A., Tsybulnyk V. R. Analysis of the energy efficiency of a two-level voltage source inverter in the overmodulation mode. Scientific Bulletin of National Mining University. 2019. No. 4 (172). P. 68– 72. DOI: 10.29202/nvngu/2019-4/9.
- Kazachkovsky N. N., Yakupov D. V. Control of active rectifier with relay-vector current circuit for systems of frequency-regulated electric drive. Bulletin of the Priazovsky State Technical University. 2008. Vol. 18, Issue 2. P. 40–43.
- Nerubatskyi V., Plakhtii O., Hordiienko D., Khoruzhevskyi H. Simulation of surge protection according IEC 61000-4-5. International scientific journal «Industry 4.0». 2019. Vol. 4, Issue 6. P. 293–296.
- Kostic D. J., Avramovic Z. Z., Ciric N. T. A new approach to theoretical analysis of harmonic content of PWM waveforms of single- and multiple-frequency modulators. IEEE Trans. Power Electron. 2013. Vol. 28, No. 10. P. 4557–4567.
- Naderi R., Rahmati A. Phase-shifted carrier PWM technique for general cascaded inverters. IEEE Trans. Power Electron. 2008. Vol. 23, No. 3. P. 1257–1269.
- Zinoviev G. S. Fundamentals of Power Electronics, uk. allowance, 3rd ed. Novosibirsk: ed. NGTU. 672 p.
- Rashid M. H. Power electronics handbook: devices, circuits, and applications handbook. 3rd. ed. Elsevier Inc. 2011. 1389 p.
- Plakhtii O., Nerubatskyi V. Analyses of energy efficiency of interleaving in active voltage-source rectifier. 2018 IEEE 3rd International Conference on Intelligent Energy and Power Systems (IEPS). P. 253–258. DOI: 10.1109/IEPS.2018.8559514.
- Lazzarin T., Bauer G., Barbi I. A control strategy for parallel operation of single-phase voltage source inverters: analysis, design and experimental results. IEEE Trans. Ind. Electron. 2013. Vol. 60, No. 6. P. 2194–2204.
- Nerubatsky V. P., Plakhtiy O. A., Gladka A. V. EMC improvment research of three-phase active rectifiers with power factor correction in regenerative mode. Collection of scientific works of the Ukrainian State University of Railway Transport. 2018. Issue 178. P. 21–28. DOI: 10.18664/1994-7852. 178.2018.138906.
- Borrega M., Marroyo L., Gonzalez R., Balda J., Agorreta J., Modeling and control of a master-slave PV inverter with n-paralleled inverters and three-phase three-limb inductors. IEEE Trans. Power Electron. 2013. Vol. 28, No. 6. P. 2842–2855.
- Zhuang X., Rui L., Hui Z., Dianguo X., Zhang C. H. Control of parallel multiple converters for direct-drive permanent-magnet wind power generation systems. IEEE Trans. Power Electron. 2012. Vol. 27, No. 3. P. 1259–1270.
- Piatkowska E., Bajraktari A., Chhajed D., Smith P. Tool supportfor data protection impact assessment in the Smart Grid. Elektrotechnik und Informationstechnik. 2017. Vol. 134, Issue 1. P. 2629.
- Rylatt R. M. Exploring Smart Grid possibilities: a complex system modelling approach. Smart Grid. 2015. Vol. 1, No. 1. P. 1– 15.
- Plakhtii O. A., Nerubatskyi V. P., Kavun V. Ye., Hordiienko D. A. Active single-phase four-quadrant rectifier with improved hysteresis modulation algorithm. Scientific Bulletin of National Mining University. 2019. No. 5 (173). P. 93–98. DOI: 10.29202/nvngu/2019-5/16.
- Vijayapriya T., Kothari D. Smart Grid: An Overview / Smart Grid and Renewable Energy. 2011. Vol. 2, No. 4. P. 305– 311. DOI: 10.4236/sgre.2011.24035.
- Padmane P. V., Rane P. R. Improvement of power quality in multibus system by interphase power controller. International Journal of Scientific Engineering and Research. 2015. Vol. 3, Issue 10. P. 80–84.
- Seyezhai R., Arthi K., Bhavani J., Archana A., Deepa M. Design and control of switched-inductor quasi-Z-source inverter for photovoltaic applications. International Refereed Journal of Engineering and Science. 2014. Vol. 3, Issue 10. P. 15–28.
- Nerubatskyi V. P., Plakhtiі O. А., Kavun V. E., Mashura A. V., Hordiienko D. A., Tsybulnyk V. R. Analysis of indices of energy efficiency of autonomous voltage inverters with various modulation types. Collection of scientific works of the Ukrainian State University of Railway Transport. 2018. Issue 180. P. 106–120.
- Vijayakumar Y., Sivanagaraju D. Application оf interline powerflow controller for powertransmission system. International Journal of Innovative Research in Electrical, Instrumentation and Control Engineering. 2014. Vol. 2, Issue 10. P. 2138–2142. DOI: 10.17148/ijireeice.2014.21104.
- Caldeira E., Brandao G., Campos H. Characterizing and evaluating fraud in electronic transactions. Proceedings of the 2012 Eighth Latin American Web Congress. 2012. P. 115–122.
- Plakhtii O., Nerubatskyi V., Tsybulnyk V., Mittsel N. The analysis of modulation algorithms and electromagnetic processes in a five-level voltage source inverter with clamping diodes. 2019 IEEE International Conference on Modern Electrical and Energy Systems (MEES). P. 294–297. DOI: 10.1109/MEES.2019.8896567.
- Aghdam M., Fathi S., Gharehpetian G. B. Harmonic Optimization Techniques in Multi-Level Voltage-Source Inverter with Unequal DC Sources. Journal of Power Electronics. 2008. Vol. 8, Issue 2. P. 171–180.