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Electrical Engineering
Erschienen in: Electrical Engineering 4/2019

15.10.2019 | Original Paper

Functioning ability of multilevel Vienna converter as new parallel active filtering configuration: simulation and experimental evaluation

verfasst von: Oualid Aissa, Samir Moulahoum, Badreddine Babes

Erschienen in: Electrical Engineering | Ausgabe 4/2019

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Abstract

This paper presents a modern solution based on power electronics, recommended to solve the problems posed by harmonic pollution of the electrical network. This pollution is generated mainly by nonlinear loads such as rectifiers with diodes and thyristors, recognized as the principal source of harmonic currents injection. As such, a curative solution was provided by a new three-phase parallel active filter based on the multilevel Vienna converter. The novel task assigned to the Vienna converter is to compensate the reactive power and to eliminate the harmonic currents caused by the nonlinear polluting loads. A simple and effective control approach has been developed guaranteeing sinusoidal shape source currents and unity power factor of the electrical network. In addition, the multilevel Vienna converter-based parallel active filter operates with convincing performances identified through the admitted DC output voltage undulations and the balance between the two partial outputs voltages. Satisfactory results have been obtained when the proposed algorithm has been subjected to simulation using the MATLAB/Simulink software and confirmed in real-time implementation via a dSPACE 1104 card.
Vorheriger Artikel Implementation of capital deferral algorithm in real distribution systems considering reliability by managing major faults
Nächster Artikel Novel active–passive compensator–supercapacitor modeling for low-voltage ride-through capability in DFIG-based wind turbines

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Literatur
1.
Badoni M, Singh A, Singh B (2016) Adaptive recursive inverse-based control algorithm for shunt active power filter. IET Power Electron 9(5):1053–1064CrossRef
2.
Shu Z, Liu M, Zhao L, Song S, Zhou Q, He X (2016) Predictive harmonic control and its optimal digital implementation for MMC-based active power filter. IEEE Trans Ind Electron 63(8):5244–5254
3.
Feng L, Wang Y (2017) Modeling and resonance control of modular three-level shunt active power filter. IEEE Trans Ind Electron 64(9):7478–7486CrossRef
4.
Narongrit T, Areerak K, Areerak K (2015) A new design approach of fuzzy controller for shunt active power filter. Electr Power Compon Syst 43(6):685–694CrossRef
5.
Mehrasa M, Pouresmaeil E, Akorede MF, Jorgensen BN, Catalao JP (2015) Multilevel converter control approach of active power filter for harmonics elimination in electric grids. Energy 84:722–731CrossRef
6.
Benchouia M, Ghadbane I, Golea A, Srairi K, Benbouzid MEH (2015) Implementation of adaptive fuzzy logic and PI controllers to regulate the DC bus voltage of shunt active power filter. Appl Soft Comput 28:125–131CrossRef
7.
Narongrit T, Areerak K, Areerak K (2016) Adaptive fuzzy control for shunt active power filters. Electr Power Compon Syst 44(6):646–657CrossRef
8.
Shu Z, Lin H, Ziwei Z, Yin X, Zhou Q (2016) Specific order harmonics compensation algorithm and digital implementation for multi-level active power filter. IET Power Electron 10(5):525–535CrossRef
9.
Chauhan SK, Shah MC, Tiwari RR, Tekwani P (2014) Analysis, design and digital implementation of a shunt active power filter with different schemes of reference current generation. IET Power Electron 7(3):627–639CrossRef
10.
Aissa O, Moulahoum S, Colak I, Babes B, Kabache N (2016) Analysis, design and real-time implementation of shunt active power filter for power quality improvement based on predictive direct power control. In: Proceedings of ICRERA, Birmingham, UK, pp 79–84
11.
Zhu H, Shu Z, Gao F, Qin B, Gao S (2014) Five-level diode-clamped active power filter using voltage space vector-based indirect current and predictive harmonic control. IET Power Electron 7(3):713–723CrossRef
12.
Tsang KM, Chan WL, Tang X (2013) Multi-level shunt active power filter using modular cascade H-bridge and delay firing. Electr Power Compon Syst 41(6):605–618CrossRef
13.
Qian P, Ma X, Liu G, Chen Z (2018) Reducing neutral-point voltage fluctuation in NPC three-level active power filters. Electr Eng 100(2):721–732CrossRef
14.
Benaissa A, Rabhi B, Benkhoris MF, Zellouma L (2017) An investigation on combined operation of five-level shunt active power filter with PEM fuel cell. Electr Eng 99(2):649–663CrossRef
15.
Colak I, Kabalci E, Gazi Electrical Machines and Energy Control Group (2011) Practical implementation of a digital signal processor controlled multilevel inverter with low total harmonic distortion for motor drive applications. J Power Sources 196(18):7585–7593CrossRef
16.
Valdez-Fernandez AA, Martinez-Rodriguez PR, Escobar G, Limones-Pozos CA, Sosa JM (2013) A model-based controller for the cascade H-bridge multilevel converter used as a shunt active filter. IEEE Trans Ind Electron 60(11):5019–5028CrossRef
17.
Antoniewicz K, Jasinski M, Kazmierkowsk MP, Malinowski M (2016) Model predictive control for 3-level 4-leg flying capacitor converter operating as shunt active power filter. IEEE Trans Ind Electron 63(8):5255–5262
18.
Sadigh AK, Dargahi V, Corzine KA (2016) Analytical determination of conduction and switching power losses in flying-capacitor-based active neutral-point-clamped multilevel converter. IEEE Trans Power Electron 31(8):5473–5494CrossRef
19.
Dekka A, Wu B, Fuentes RL, Perez M, Zargari NR (2017) Voltage-balancing approach with improved harmonic performance for modular multilevel converters. IEEE Trans Power Electron 32(8):5878–5884CrossRef
20.
Karwatzki D, Mertens A (2018) Generalized control approach for a class of modular multilevel converter topologies. IEEE Trans Power Electron 33(4):2888–2900CrossRef
21.
Lee SS, Heng YE (2017) A voltage level based predictive direct power control for modular multilevel converter. Electr Power Syst Res 148:97–107CrossRef
22.
Sundari MG, Rajaram M, Balaraman S (2016) Application of improved firefly algorithm for programmed PWM in multilevel inverter with adjustable DC sources. Appl Soft Comput 41:169–179CrossRef
23.
Gautam SP, Kumar L, Gupta S (2017) Improved configuration of multilevel inverter with reduced semiconductor devices. Electr Power Compon Syst 45(3):233–245CrossRef
24.
Kedjar B, Kanaan HY, Al-Haddad K (2014) Vienna rectifier with power quality added function. IEEE Trans Ind Electron 61(8):3847–3856CrossRef
25.
Aissa O, Moulahoum S, Colak I, Babes B, Kabache N (2017) Design and real time implementation of three-phase three switches three levels Vienna rectifier based on intelligent controllers. Appl Soft Comput 56:158–172CrossRef
26.
Li X, Sun Y, Wang H, Su M, Huang S (2018) A hybrid control scheme for three-phase Vienna rectifiers. IEEE Trans Power Electron 33(1):629–640CrossRef
27.
Adhikari J, Prasanna I, Panda SK (2017) Reduction of input current harmonic distortions and balancing of output voltages of the Vienna rectifier under supply voltage disturbances. IEEE Trans Power Electron 32(7):5802–5812CrossRef
28.
Song WZ, Xing FX, Yan H, Empringham L, De Lillo L, Wheeler P, Li J, Zhong YR (2016) A hybrid control method to suppress the three-time fundamental frequency neutral-point voltage fluctuation in a Vienna rectifier. IEEE J Emerg Sel Top Power Electron 4(2):468–480CrossRef
29.
Ma H, Xie Y, Shi Z (2016) Improved direct power control for Vienna-type rectifiers based on sliding mode control. IET Power Electron 9(3):427–434CrossRef
30.
Madishetti S, Bhuvaneswari G, Singh B (2013) Improved power quality converter for direct torque control-based induction motor drives. IET Power Electron 6(2):276–286CrossRef
31.
Lee JS, Lee KB (2017) Predictive control of Vienna rectifiers for PMSG systems. IEEE Trans Ind Electron 64(4):2580–2591CrossRef
32.
Rajaei A, Mohamadian M, Varjani AY (2013) Vienna-rectifier-based direct torque control of PMSG for wind energy application. IEEE Trans Ind Electron 60(7):2919–2929CrossRef
33.
Liu B, Ren R, Jones EA, Wang F, Costinett D, Zhang Z (2018) A modulation compensation scheme to reduce input current distortion in GaN-based high switching frequency three-phase three-level Vienna-type rectifiers. IEEE Trans Power Electron 33(1):283–298CrossRef
34.
Singh S, Bhuvaneswari G, Singh B (2015) Power quality improvement in three-phase telecommunication power supply system. Electr Power Compon Syst 43(19):2105–2115CrossRef
35.
Gao B, Hong J, Yu S, Chen H (2017) Linear-quadratic output regulator with disturbance rejection: application to vehicle launch control. In: Proceedings of ACC, Seattle, USA, pp 1960–1965
36.
Deng X, Sun X, Liu R, Wei W (2017) Optimal analysis of the weighted matrices in LQR based on the differential evolution algorithm. In: Proceedings of CCDC, Chongqing, China, pp 832–836
37.
Kolar JW, Zach FC (1997) A novel three-phase utility interface minimizing line current harmonics of high-power telecommunications rectifier modules. IEEE Trans Ind Electron 44(4):456–467CrossRef
38.
Moulahoum S, Houassine H, Kabache N (2013) Parallel active filter to eliminate harmonics generated by compact fluorescent lamps. In: Proceedings of MED, Platanias-Chania, Crete, Greece, pp 143–148
39.
Aissa O, Moulahoum S, Colak I, Babes B, Kabache N (2018) Analysis and experimental evaluation of shunt active power filter for power quality improvement based on predictive direct power control. Environ Sci Pollut Res 25(25):24548–24560CrossRef
40.
Reddy AB, Das GRT (2011) High quality rectifiers with reduced THD for enhance mains power quality-Vienna with synchronous logic. ARPN J Eng Appl Sci 6(7):97–109
41.
Suresh Dhanavath, Singh Saijan Pal (2016) Type-2 fuzzy logic controlled three-level shunt active power filter for power quality improvement. Electr Power Compon Syst 44(8):873–882CrossRef
42.
Hoon Yap, Radzi Mohd Amran Mohd, Hassan Mohd Khair, Mailah Nashiren Farzilah (2017) A refined self-tuning filter-based instantaneous power theory algorithm for indirect current controlled three-level inverter-based shunt active power filters under non-sinusoidal source voltage conditions. Energies 10(3):277–298CrossRef
43.
Muhammad Kashif MJ, Hossain Fang Zhuo, Gautam Samir (2018) Design and implementation of a three-level active power filter for harmonic and reactive power compensation. Electr Power Syst Res 165:144–156CrossRef
Metadaten
Titel
Functioning ability of multilevel Vienna converter as new parallel active filtering configuration: simulation and experimental evaluation
verfasst von
Oualid Aissa
Samir Moulahoum
Badreddine Babes
Publikationsdatum
15.10.2019
Verlag
Springer Berlin Heidelberg
Erschienen in
Electrical Engineering / Ausgabe 4/2019
Print ISSN: 0948-7921
Elektronische ISSN: 1432-0487
DOI
https://doi.org/10.1007/s00202-019-00856-z

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