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Ghaffari, N., Zakipour, A., Salimi, M.. (1399). State Space Modeling and Sliding Mode Current Control of the Grid Connected Multi-Level Flying Capacitor Inverters. فناوری آموزش, 9(2), 215-228. doi: 10.22061/jecei.2021.7626.412
N. Ghaffari; A. Zakipour; M. Salimi. "State Space Modeling and Sliding Mode Current Control of the Grid Connected Multi-Level Flying Capacitor Inverters". فناوری آموزش, 9, 2, 1399, 215-228. doi: 10.22061/jecei.2021.7626.412
Ghaffari, N., Zakipour, A., Salimi, M.. (1399). 'State Space Modeling and Sliding Mode Current Control of the Grid Connected Multi-Level Flying Capacitor Inverters', فناوری آموزش, 9(2), pp. 215-228. doi: 10.22061/jecei.2021.7626.412
Ghaffari, N., Zakipour, A., Salimi, M.. State Space Modeling and Sliding Mode Current Control of the Grid Connected Multi-Level Flying Capacitor Inverters. فناوری آموزش, 1399; 9(2): 215-228. doi: 10.22061/jecei.2021.7626.412

State Space Modeling and Sliding Mode Current Control of the Grid Connected Multi-Level Flying Capacitor Inverters

Journal of Electrical and Computer Engineering Innovations (JECEI)
مقاله 9، دوره 9، شماره 2، مهر 2021، صفحه 215-228    اصل مقاله (2.18 M)
نوع مقاله: Original Research Paper
شناسه دیجیتال (DOI): 10.22061/jecei.2021.7626.412
نویسندگان
N. Ghaffari1؛ A. Zakipour* 1؛ M. Salimi2
1Electrical Engineering Department, Arak University of Technology, Arak, Iran
2Faculty of Technology and Engineering, Electrical Engineering Department, Ardabil Branch, Islamic Azad University, Ardabil, Iran
تاریخ دریافت: 01 مرداد 1399،  تاریخ بازنگری: 12 آبان 1399،  تاریخ پذیرش: 13 دی 1399 
چکیده
Background and Objectives: In this paper, a novel approach for regulation of the output current in the grid-connected three-level flying capacitor inverter is presented by using the sliding mode (SM) method. In the proposed method, it is possible to control the active and reactive components of the inverter output current independently, and therefore it can be employed for grid connection of the renewable energy resources or for harmonic and reactive power compensation of the local loads. The designed controller uses an external loop to control the voltage of the inverter DC link and has a constant switching frequency. The stability of the proposed method has also been proved by using the Lyapunov stability theory. The simulation results show that in different operating conditions, the proposed controller has a stable and robust response.
Methods: Grid-connected three-level flying capacitor inverter is modeled by using averaged state space technique. Considering nonlinearity of the obtained model, an equivalent SM controller is developed for output current control of the multilevel grid connected inverter. To improve robustness and stability of the system against uncertainty of model parameters, a nonlinear component is added to the equivalent controller.
Results: The proposed controller enjoys very fast dynamic response, so it can be employed in wide ranges of application e.g. reactive compensation and harmonic mitigation modes. In active power filtering operation, it is able to eliminate harmonic components of the grid from 20.61% to 1.34% which is compatible with IEEE and IEC standards.
Conclusion: The stability of the proposed method has also been proved by using the Lyapunov stability theory. The simulation results show that in different operating conditions, the proposed controller has a stable and robust response.

کلیدواژه‌ها
multi-level inverters؛ grid connected inverter؛ sliding mode control؛ active power filter
مراجع

[1] Z. Hekss, A. Abouloifa, I. Lachkar, F. Giri, S. Echalih, J.M. Guerrero, "Nonlinear adaptive control design with average performance analysis for photovoltaic system based on half bridge shunt active power filter," Int. J. Electr. Power Energy Syst., 125, 2021.

[2] Q. Su, W. Quan, W. Quan, G. Cai, J. Li, "Improved robust adaptive backstepping control approach on STATCOM for non-linear power systems," IET Gener. Transm. Distrib., 11(3): 3428-3437, 2017.

[3] M. Salimi, J. Soltani, A. Zakipour, "Experimental design of the adaptive backstepping control technique for single-phase shunt active power filters," IET Power Electron., 10(8): 911-918, 2017.

[4] A. Zakipour, S.S. Kojori, M. Salimi, "Low-Cost wind power conversion system based on permanent magnet synchronous generator and grid connected single-phase impedance source inverter," in Proc. 2019 International Power System Conference (PSC): 616-622, 2019.

[5] M.A. Hannan, P.J. Ker, M.S.H. Lipu, Z.H. Choi, M.S.A. Rahman, K.M. Muttaqi, et al., "State of the art of solid-state transformers: Advanced topologies, implementation issues, recent progress and improvements," IEEE Access, 8: 19113-19132, 2020.

[6] X. Li, Y. Tan, X. Liu, Q. Liao, B. Sun, G. Cao, et al., "A cost-benefit analysis of V2G electric vehicles supporting peak shaving in Shanghai," Electr. Power Syst. Res., 179: 106058, 2020.

[7] Y.P. Siwakoti, P. Fang Zheng, F. Blaabjerg, L. Poh Chiang, G.E. Town, "Impedance-Source Networks for Electric Power conversion Part I: A topological review," IEEE Trans. Power Electron., 30(2): 699-716, 2015.

[8] P. Hamedani, A. Shoulaei, "Utilization of CHB multilevel inverter for harmonic reduction in fuzzy logic controlled multiphase LIM drives," J. Electr. Comput. Eng. Innovations (JECEI), 8(1): 19-30, 2019.

[9] M.T. Bina, D.C. Hamill, "Average circuit model for angle-controlled STATCOM," IEE J. Electr. Power Appl., 152(3): 653-659, 2005.

[10] X. Zhao, L. Chang, "Active and reactive power decoupling control of grid-connected inverters in stationary reference frame," Chin. J. Electr. Eng., 3(3): 18-24, 2017.

[11] M. Cespedes, J. Sun, "Adaptive control of grid-connected inverters based on online grid impedance measurements," IEEE Trans. Sustainable Energy, 5(2): 516-523, 2014.

[12] Y. Wang, B. Ren, Q.-C. Zhong, "Robust power flow control of grid-connected inverters," IEEE Trans. Ind. Electron., 63(11): 6887-6897, 2016.

[13] A. Akhavan, H.R. Mohammadi, J.C. Vasquez, J. M. Guerrero, "Passivity-based design of plug-and-play current-controlled grid-connected inverters," IEEE Trans. Power Electron., 35(2): 2135-2150, 2019.

[14] H. Makhamreh, M. Sleiman, O. Kükrer, K. Al-Haddad, "Lyapunov-based model predictive control of a PUC7 grid-connected multilevel inverter," IEEE Trans. Ind. Electron., 66(9): 7012-7021, 2018.

[15] M. Salimi, J. Soltani, A. Zakipour, N.R. Abjadi, "Hyper-plane sliding mode control of the DC-DC buck/boost converter in continuous and discontinuous conduction modes of operation," IET Power Electron., 8(8): 1473-1482, 2015.

[16] J.-J.E. Slotine, W. Li, Applied nonlinear control vol. 199: Prentice hall Englewood Cliffs, NJ, 1991.

[17] S. Mohammadi, H. Mosaddegh, M. Yousefian, "Mitigation of switching harmonics in shunt active power filter based on variable structure control approach," J. Electr. Comput. Eng. Innovations (JECEI), 1(2): 83-88, 2013.

[18] H. Zahedi, G. Arab Markadeh, S. Taghipour, "Real-time implementation of sliding mode control for cascaded doubly fed induction generator in both islanded and grid connected modes," J. Electr. Comput. Eng. Innovations (JECEI), 8(2): 285-296, 2020.

[19] H. Xiang, Y. Xu, L. Tao, H. Lang, C. Wenjie, "A Sliding-Mode controller with multiresonant sliding surface for single-phase grid-connected VSI with an LCL Filter," IEEE Trans. Power Electron., 28(5): 2259-2268, 2013.

[20] S.-W. Kang, K.-H. Kim, "Sliding mode harmonic compensation strategy for power quality improvement of a grid-connected inverter under distorted grid condition," IET Power Electron., 8(8): 1461-1472, 2015.

[21] H. Komurcugil, S. Ozdemir, I. Sefa, N. Altin, O. Kukrer, "Sliding-mode control for single-phase grid-connected LCL-Filtered VSI with double-band hysteresis scheme," IEEE Trans. Ind. Electron., 63(2): 864-873, 2016.

[22] S.M. Parida, P.K. Rout, S.K. Kar, "An auxiliary control aided modified sliding mode control for a PMSG based wind energy conversion system," World J. Eng., 16(6): 725-736 , 2019.

[23] N.M. Dehkordi, N. Sadati, M. Hamzeh, "A robust backstepping high-order sliding mode control strategy for grid-connected DG units with harmonic/interharmonic current compensation capability," IEEE Trans. Sustainable Energy, 8(2): 561-572, 2016.

[24] J. Ritonja, D. Dolinar, B. Polajzer, "Adaptive and robust controls for static excitation systems," Compel: Int. J. Comput. Math. Electr. Electron. Eng., vol. 34(3): 864-881, 2015.

[25] R.P. Vieira, L.T. Martins, J.R. Massing, M. Stefanello, "Sliding mode controller in a multiloop framework for a grid-connected VSI with LCL filter," IEEE Trans. Ind. Electron., 65: 4714-4723, 2017.

[26] A. Zakipour, S. Shokri Kojori, M. Tavakoli Bina, "Closed-loop control of the grid-connected Z-source inverter using hyper-plane MIMO sliding mode," IET Power Electron., 10(15): 2229 – 2241, 2017.

[27] U.K. Shinde, S.G. Kadwane, S.Gawande, M.J.B. Reddy, D. Mohanta, "Sliding mode control of single-phase grid-connected quasi-Z-source inverter," IEEE Access, 5: 10232-10240, 2017.

[28] F. Sebaaly, H. Vahedi, H.Y. Kanaan, N. Moubayed, K. Al-Haddad, "Design and implementation of space vector modulation-based sliding mode control for grid-connected 3L-NPC inverter," IEEE Trans. Ind. Electron., 63: 7854-7863, 2016.

[29] F. Sebaaly, H. Vahedi, H.Y. Kanaan, N. Moubayed, K. Al-Haddad, "Sliding mode fixed frequency current controller design for grid-connected NPC inverter," IEEE J. Emerging Sel. Top. Power Electron., 4: 1397-1405, 2016.

[30] H. Makhamreh, M. Trabelsi, O. Kükrer, H. Abu-Rub, "An effective sliding mode control design for a grid-connected puc7 multilevel inverter," IEEE Trans.Indu. Electron., 67: 3717-3725, 2019.

[31] M. Mehrasa, E. Pouresmaeil, M.F. Akorede, B.N. Jørgensen, J.P. Catalão, "Multilevel converter control approach of active power filter for harmonics elimination in electric grids," Energy, 84: 722-731, 2015.

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