دانشگاه تربیت دبیر شهید رجائی

  اخبار و اعلانات

 آمار

تعداد نشریات13
تعداد شماره‌ها200
تعداد مقالات2,008
تعداد مشاهده مقاله2,679,620
تعداد دریافت فایل اصل مقاله1,936,951
Amiri, F., Moradi, M.. (1398). Designing a new robust control for virtual inertia control in the microgrid with regard to virtual damping. فناوری آموزش, 8(1), 53-70. doi: 10.22061/jecei.2020.6913.347
F. Amiri; M. Moradi. "Designing a new robust control for virtual inertia control in the microgrid with regard to virtual damping". فناوری آموزش, 8, 1, 1398, 53-70. doi: 10.22061/jecei.2020.6913.347
Amiri, F., Moradi, M.. (1398). 'Designing a new robust control for virtual inertia control in the microgrid with regard to virtual damping', فناوری آموزش, 8(1), pp. 53-70. doi: 10.22061/jecei.2020.6913.347
Amiri, F., Moradi, M.. Designing a new robust control for virtual inertia control in the microgrid with regard to virtual damping. فناوری آموزش, 1398; 8(1): 53-70. doi: 10.22061/jecei.2020.6913.347

Designing a new robust control for virtual inertia control in the microgrid with regard to virtual damping

Journal of Electrical and Computer Engineering Innovations (JECEI)
دوره 8، شماره 1، فروردین 2020، صفحه 53-70    اصل مقاله (1.43 M)
نوع مقاله: Original Research Paper
شناسه دیجیتال (DOI): 10.22061/jecei.2020.6913.347
نویسندگان
F. Amiri؛ M. Moradi*
Department of Electrical Engineering, Bu-Ali Sina University, Hamedan, Iran
تاریخ دریافت: 29 اسفند 1397،  تاریخ بازنگری: 13 تیر 1398،  تاریخ پذیرش: 15 آذر 1398 
چکیده
Background and Objectives: Virtual inertia control, as a component of a virtual synchronous generator, is used for the implementation of synchronous generator behaviour in microgrids. In microgrids that include high-capacity distributed generation resources, in addition to virtual inertia, virtual damping can also lead to improvement of frequency stability of the microgrid. The purpose of the control method for the islanded microgrid is to be: 1) robust to the uncertainty of the microgrid parameters. 2) Weaken the disturbances on the islanded microgrid (wind turbine, solar cell, Loads). 3) Improved response speed related to microgrid frequency deviation (reduced settling time).
Methods In this paper, designing a new robust control method for controlling virtual inertia in microgrids, with regard to virtual damping, has been attempted. The proposed method has a higher degree of freedom compared to the conventional robust controllers, which provides better control of the system.
Results: Results of the proposed method for virtual inertia control with regard to virtual damping has been compared in several scenarios –with virtual inertia control based on optimized PI controllers with regard to virtual damping, virtual inertia control based on model predictive control (controller) with regard to virtual damping,Self-adaptive virtual inertia control using fuzzy logic, virtual inertia control with regard to virtual damping, and virtual inertia control without virtual damping (conventional methods). Compared to other control methods, the proposed controller has improved the settling time due to the frequency deviations of the islanded microgrid by 27%. According to the results of the scenarios, the proposed controller has been able to reduce the frequency error due to load and distributed generation resource disturbances and compared to other controllers, and this frequency deviation has been reduced by 68%.
Conclusion: According to the simulation results, the proposed controller has a better performance than other controllers in improving the frequency stability of the islanded microgrid.
کلیدواژه‌ها
A new robust control method Output feedback؛ Virtual inertia control؛ The islanded microgrid
مراجع
[1] G. Yang, Y. Jia, M. Qin, Y. Fang, "Research of low voltage shore power supply used on shipping based on sliding control," Journal of Electrical and Computer Engineering Innovations, 4(1): 85-93, 2016.

[2] A. Movahednasab, M. Rashidinejad, A. Abdollahi, "Market Based Analysis of Natural Gas and Electricity Export via System Dynamics," Journal of Electrical and Computer Engineering Innovations, 5(2): 109-120, ‏ 2017.

[3] H. Amiri, G. A. Markadeh, N. Mahdian, "Voltage control and load sharing in a DC Islanded Microgrid Based on Disturbance Observer," Journal of Electrical and Computer Engineering Innovations, 7(1): 1-10, 2019.

[4] M. Feli, F. Parandin, "A Numerical Optimization of an Efficient Double Junction InGaN/CIGS Solar Cell," Journal of Electrical and Computer Engineering Innovations, 6(1): 53-58, 2018.

[5] M. HojatyDana, M. AlizadehPahlavani, "Control-Strategies-for-Performance-Assessment-of-an-Autonomous Wind Energy Conversion System. Journal of Electrical and Computer Engineering Innovations," 2(1): 15-20, 2014.

[6] Li, X. Wang, J. Xiao, "Adaptive Event-Triggered Load Frequency Control for Interconnected Microgrids by Observer-Based Sliding Mode Control," in IEEE Access, 7: 68271-68280, 2019.

[7] M. W. Siti, D. H. Tungadio, Y. Sun, N. T. Mbungu, R. Tiako, "Optimal frequency deviations control in microgrid interconnected systems," in IET Renewable Power Generation, 13(13): 2376-2382, 2019.

[8] F. Amiri, M. H. Moradi, "Designing a Fractional Order PID Controller for a Two-Area Micro-Grid under Uncertainty of Parameters," Iranian journal of energy 20(4): 49-78, 2018.

[9] F. Amiri, A. Hatami, "A Model Predictive Control Method for Load-Frequency Control in Islanded Microgrids," Computational Intelligence in Electrical Engineering, 8(1): 9-24, 2017.

[10] F. Amiri, A. Hatami, "Nonlinear Load Frequency Control of Isolated Microgrid using Fractional Order PID Based on Hybrid Craziness-based Particle Swarm Optimization and Pattern Search," Journal of Iranian Association of Electrical and Electronics Engineers, 17(2): 135-148, 2020.

[11] W. Wu et al., "A Virtual Inertia Control Strategy for DC Microgrids Analogized With Virtual Synchronous Machines," in IEEE Transactions on Industrial Electronics, 64(7): 6005-6016, 2017.

[12] Ali et al. , "A New Frequency Control Strategy in an Islanded Microgrid Using Virtual Inertia Control-Based Coefficient Diagram Method," in IEEE Access, 7: 16979-16990, 2019.

[13] Z. Yi, X. Zhao, D. Shi, J. Duan, Y. Xiang, Z. Wang, "Accurate Power Sharing and Synthetic Inertia Control for DC Building Microgrids With Guaranteed Performance," in IEEE Access, 7: 63698-63708, 2019.

[14] J. Li, B. Wen, H. Wang, "Adaptive Virtual Inertia Control Strategy of VSG for Micro-Grid Based on Improved Bang-Bang Control Strategy," in IEEE Access, 7: 39509-39514, 2019.

[15] J. Liu, M. J. Hossain, J. Lu, F. H. M. Rafi, H. Li, "A hybrid AC/DC microgrid control system based on a virtual synchronous generator for smooth transient performances," Electric Power Systems Research, 162: 169-182.‏ 2018.

[16] P. Li, W. Hu, X. Xu, Q. Huang, Z. Liu, Z. Chen, "A frequency control strategy of electric vehicles in microgrid using virtual synchronous generator control," Energy, 189: 116389, 2019.

[17] Ali et al., "A New Frequency Control Strategy in an Islanded Microgrid Using Virtual Inertia Control-Based Coefficient Diagram Method, " in IEEE Access, 7: 16979-16990, 2019.

[18] X. Hou, Y. Sun, X. Zhang, J. Lu, P. Wang, J. M. Guerrero, "Improvement of Frequency Regulation in VSG-Based AC Microgrid Via Adaptive Virtual Inertia, " in IEEE Transactions on Power Electronics, 35(2): 1589-1602, 2020.

[19] K. Tan, F. Lin, C. Shih, C. Kuo, "Intelligent Control of Microgrid With Virtual Inertia Using Recurrent Probabilistic Wavelet Fuzzy Neural Network," in IEEE Transactions on Power Electronics, 35(7): 7451-7464, 2020.

[20] T. Kerdphol, F. S. Rahman, Y. Mitani, M. Watanabe, S. K. Küfeoǧlu, "Robust Virtual Inertia Control of an Islanded Microgrid Considering High Penetration of Renewable Energy," in IEEE Access, 6: 625-636, 2018.

[21] T. Kerdphol, M. Watanabe, K. Hongesombut, Y. Mitani, "Self-Adaptive Virtual Inertia Control-Based Fuzzy Logic to Improve Frequency Stability of Microgrid With High Renewable Penetration," in IEEE Access, 7: 76071-76083, 2019.

[22] T. Kerdphol, F. S. Rahman, M. Watanabe, Y. Mitani, "Robust Virtual Inertia Control of a Low Inertia Microgrid Considering Frequency Measurement Effects," in IEEE Access, 7: 57550-57560, 2019.

[23] T. Kerdphol, F. S. Rahman, Y. Mitani, K. Hongesombut, S. Küfeoğlu, "Virtual inertia control-based model predictive control for microgrid frequency stabilization considering high renewable energy integration," Sustainability, 9(5): 773, 2017.

[24] T. Kerdphol, F. S.Rahman, Y. Mitani, "Virtual inertia control application to enhance frequency stability of interconnected power systems with high renewable energy penetration," Energies, 11(4): 981, 2018.

[25] T. Kerdphol, F. S. Rahman, M. Watanabe, Y. Mitani, D. Turschner, H. Beck, "Enhanced Virtual Inertia Control Based on Derivative Technique to Emulate Simultaneous Inertia and Damping Properties for Microgrid Frequency Regulation, " in IEEE Access, 7: 14422-14433, 2019.

[26] C. Scherer, P. Gahinet, M. Chilali, "Multiobjective output-feedback control via LMI optimization," in IEEE Transactions on Automatic Control, 42(7): 896-911, 1997.

[27] H. Li, X. Jing, H. R. Karimi, "Output-Feedback-Based H∞Control for Vehicle Suspension Systems With Control Delay, " in IEEE Transactions on Industrial Electronics, 61(1): 436-446, 2014.

آمار
تعداد مشاهده مقاله: 4,751
تعداد دریافت فایل اصل مقاله: 2,071


سامانه مدیریت نشریات علمی. قدرت گرفته از سیناوب