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Single Stage Energy Conversion through an RBFN Controller based Boost Type Vienna Rectifier in the Wind Turbine System

Yıl 2017, Cilt: 30 Sayı: 4, 253 - 266, 11.12.2017

Öz

This paper
presents, a Radial Basis Function
Network (RBFN) controller based boost type Vienna Rectifier, which is engaged
for a single stage energy conversion in the wind turbine system (WTS) over
two-stage energy conversion (Diode bridge rectifier + Boost converter). The
boost type Vienna Rectifier converts AC power into DC power with increased
voltage level in a single stage conversion. It is having the benefits of low voltage
stress across switches (50% of DC-link voltage), reduced harmonics, sinusoidal
input current shaping, and improved power factor etc. This sort of AC/DC
conversion is adequate for low voltage DC
distribution, telecommunication systems,
and data centers etc. In this, an RBFN controller is engaged for the fast
dynamic response over the conventional converter controllers. This paper
presents the comparative analysis of single stage boost type Vienna Rectifier
on two-stage conversion for 400V/1kW wind system and results are validated in
MATLAB/Simulink

Kaynakça

  • [1]. Oğuz Y, Güney İ, Çalık H. Power quality control and design of power converter for variable-speed wind energy conversion system with permanent-magnet synchronous generator. The Scientific World Journal. 2013 Dec 22;2013. [2]. Benadja M, Chandra A. A new MPPT algorithm for PMSG based grid connected wind energy system with power quality improvement features. InPower India Conference, 2012 IEEE Fifth 2012 Dec 19 (pp. 1-6). IEEE. [3]. Xia Y, Ahmed KH, Williams BW. A new maximum power point tracking technique for permanent magnet synchronous generator based wind energy conversion system. IEEE Transactions on Power Electronics. 2011 Dec;26(12):3609-20. [4]. Mendis N, Muttaqi KM, Sayeef S, Perera S. Standalone operation of wind turbine-based variable speed generators with maximum power extraction capability. IEEE Transactions on Energy Conversion. 2012 Dec;27(4):822-34. [5]. Xu H, Hui J, Wu D, Yan W. Implementation of MPPT for PMSG-based small-scale wind turbine. InIndustrial Electronics and Applications, 2009. ICIEA 2009. 4th IEEE Conference on 2009 May 25 (pp. 1291-1295). IEEE. [6]. Chen H, David N, Aliprantis DC. Analysis of permanent-magnet synchronous generator with Vienna rectifier for wind energy conversion system. IEEE Transactions on Sustainable Energy. 2013 Jan;4(1):154-63. [7]. Hu KW, Liaw CM. Development of a wind interior permanent-magnet synchronous generator-based microgrid and its operation control. IEEE Transactions on Power Electronics. 2015 Sep;30(9):4973-85. [8]. Adhikari J, Prasanna IV, Ponraj G, Panda SK. Modeling, Design, and Implementation of a Power Conversion System for Small-Scale High-Altitude Wind Power Generating System. IEEE Transactions on Industry Applications. 2017 Jan;53(1):283-95. [9]. Yu TH, Liang TJ, Chen KH, Li JS, Lee JS. Design of an AC-DC and DC-DC interleaved PWM controller for switching power supply. InEnergy Conversion Congress and Exposition (ECCE), 2013 IEEE 2013 Sep 15 (pp. 4172-4179). IEEE. [10]. Kolar JW, Friedli T. The essence of three-phase PFC rectifier systems—Part I. IEEE Transactions on Power Electronics. 2013 Jan;28(1):176-98. [11]. Singh M, Khadkikar V, Chandra A. Grid synchronization with harmonics and reactive power compensation capability of PMSG based variable speed wind energy conversion system. IET Trans. Power Electron. 2011 Jan;4(1):122-30. [12]. Lee JS, Lee KB. A Novel Carrier-Based PWM Method for Vienna Rectifier With a Variable Power Factor. IEEE Transactions on Industrial Electronics. 2016 Jan;63(1):3-12. [13]. Shaon SA, Salam KM. Power Factor Improvement of a Permanent Magnet Synchronous Motor Load Using Vienna Rectifier and a Higly Efiicient Pure Sine-Wave Inverter. [14]. Leibl M, Kolar J, Deuringer J. Sinusoidal Input Current Discontinuous Conduction Mode Control of the VIENNA Rectifier. IEEE Transactions on Power Electronics. 2016 Dec 19. [15]. Kedjar B, Kanaan HY, Al-Haddad K. Vienna rectifier with power quality added function. IEEE Transactions on Industrial Electronics. 2014 Aug;61(8):3847-56. [16]. Szpek M, Sonnenberg BJ, Lisy SM. 400VDC distribution architectures for central offices and data centers. InTelecommunications Energy Conference (INTELEC), 2014 IEEE 36th International 2014 Sep 28 (pp. 1-6). IEEE. [17]. Pahlevani M, Bakhshai A, Goel N, Jain P. A novel control technique for an AC/DC converter used in telecom applications. InTelecommunications Energy Conference (INTELEC), 2014 IEEE 36th International 2014 Sep 28 (pp. 1-6). IEEE. [18]. Whaite S, Grainger B, Kwasinski A. Power quality in DC power distribution systems and microgrids. Energies. 2015 May 15;8(5):4378-99. [19]. Lin WM, Hong CM, Cheng FS, Lu KH. Mppt control strategy for wind energy conversion system based on rbf network. InEnergytech, 2011 IEEE 2011 May 25 (pp. 1-6). IEEE. [20]. Tiwari R. Comparative Analysis of Pitch Angle Controller Strategies for PMSG Based Wind Energy Conversion System. [21]. Lin WM, Hong CM, Ou TC, Chiu TM. Hybrid intelligent control of PMSG wind generation system using pitch angle control with RBFN. Energy Conversion and Management. 2011 Feb 28;52(2):1244-51. [22]. Saravanan S, Babu NR. RBFN based MPPT algorithm for PV system with high step up converter. Energy Conversion and Management. 2016 Aug 15;122:239-51. [23]. Lee JS, Lee KB. Performance analysis of carrier-based discontinuous PWM method for vienna rectifiers with neutral-point voltage balance. IEEE Transactions on Power Electronics. 2016 Jun;31(6):4075-84. [24]. Islam MH, Razzak MA. Design of a modified Vienna rectifier for power factor correction under different three phase loads. InInformatics, Electronics and Vision (ICIEV), 2016 5th International Conference on 2016 May 13 (pp. 764-770). IEEE. [25]. Adhikari J, Prasanna IV, Panda SK. Reduction of Input Current Harmonic Distortions and Balancing of Output Voltages of the Vienna Rectifier Under Supply Voltage Disturbances. IEEE Transactions on Power Electronics. 2017 Jul;32(7):5802-12. [26]. Lu X, Xie Y, Chen L. Feedback linearization and sliding mode control for VIENNA rectifier based on differential geometry theory. Mathematical Problems in Engineering. 2015 Mar 23;2015. [27]. Flores-Bahamonde F, Valderrama-Blavi H, Martínez-Salamero L, Maixé-Altés J, García G. Control of a three-phase AC/DC VIENNA converter based on the sliding mode loss-free resistor approach. IET Power Electronics. 2014 Jan 6;7(5):1073-82. [28]. Lee JS, Lee KB. Predictive Control of Vienna Rectifiers for PMSG Systems. IEEE Transactions on Industrial Electronics. 2017 Apr;64(4):2580-91. [29]. Zhang M, Li B, Hang L, Tolbert LM, Lu Z. Performance study for high power density three-phase Vienna PFC rectifier by using SVPWM control method. InApplied Power Electronics Conference and Exposition (APEC), 2012 Twenty-Seventh Annual IEEE 2012 Feb 5 (pp. 1187-1191). IEEE. [30]. Hang L, Zhang H, Liu S, Xie X, Zhao C, Liu S. A novel control strategy based on natural frame for Vienna-type rectifier under light unbalanced-grid conditions. IEEE Transactions on Industrial Electronics. 2015 Mar;62(3):1353-62. [31]. Adhikari J, Prasanna IV, Panda SK. Voltage oriented control of the three-level Vienna rectifier using vector control method. InApplied Power Electronics Conference and Exposition (APEC), 2016 IEEE 2016 Mar 20 (pp. 9-16). IEEE.
Yıl 2017, Cilt: 30 Sayı: 4, 253 - 266, 11.12.2017

Öz

Kaynakça

  • [1]. Oğuz Y, Güney İ, Çalık H. Power quality control and design of power converter for variable-speed wind energy conversion system with permanent-magnet synchronous generator. The Scientific World Journal. 2013 Dec 22;2013. [2]. Benadja M, Chandra A. A new MPPT algorithm for PMSG based grid connected wind energy system with power quality improvement features. InPower India Conference, 2012 IEEE Fifth 2012 Dec 19 (pp. 1-6). IEEE. [3]. Xia Y, Ahmed KH, Williams BW. A new maximum power point tracking technique for permanent magnet synchronous generator based wind energy conversion system. IEEE Transactions on Power Electronics. 2011 Dec;26(12):3609-20. [4]. Mendis N, Muttaqi KM, Sayeef S, Perera S. Standalone operation of wind turbine-based variable speed generators with maximum power extraction capability. IEEE Transactions on Energy Conversion. 2012 Dec;27(4):822-34. [5]. Xu H, Hui J, Wu D, Yan W. Implementation of MPPT for PMSG-based small-scale wind turbine. InIndustrial Electronics and Applications, 2009. ICIEA 2009. 4th IEEE Conference on 2009 May 25 (pp. 1291-1295). IEEE. [6]. Chen H, David N, Aliprantis DC. Analysis of permanent-magnet synchronous generator with Vienna rectifier for wind energy conversion system. IEEE Transactions on Sustainable Energy. 2013 Jan;4(1):154-63. [7]. Hu KW, Liaw CM. Development of a wind interior permanent-magnet synchronous generator-based microgrid and its operation control. IEEE Transactions on Power Electronics. 2015 Sep;30(9):4973-85. [8]. Adhikari J, Prasanna IV, Ponraj G, Panda SK. Modeling, Design, and Implementation of a Power Conversion System for Small-Scale High-Altitude Wind Power Generating System. IEEE Transactions on Industry Applications. 2017 Jan;53(1):283-95. [9]. Yu TH, Liang TJ, Chen KH, Li JS, Lee JS. Design of an AC-DC and DC-DC interleaved PWM controller for switching power supply. InEnergy Conversion Congress and Exposition (ECCE), 2013 IEEE 2013 Sep 15 (pp. 4172-4179). IEEE. [10]. Kolar JW, Friedli T. The essence of three-phase PFC rectifier systems—Part I. IEEE Transactions on Power Electronics. 2013 Jan;28(1):176-98. [11]. Singh M, Khadkikar V, Chandra A. Grid synchronization with harmonics and reactive power compensation capability of PMSG based variable speed wind energy conversion system. IET Trans. Power Electron. 2011 Jan;4(1):122-30. [12]. Lee JS, Lee KB. A Novel Carrier-Based PWM Method for Vienna Rectifier With a Variable Power Factor. IEEE Transactions on Industrial Electronics. 2016 Jan;63(1):3-12. [13]. Shaon SA, Salam KM. Power Factor Improvement of a Permanent Magnet Synchronous Motor Load Using Vienna Rectifier and a Higly Efiicient Pure Sine-Wave Inverter. [14]. Leibl M, Kolar J, Deuringer J. Sinusoidal Input Current Discontinuous Conduction Mode Control of the VIENNA Rectifier. IEEE Transactions on Power Electronics. 2016 Dec 19. [15]. Kedjar B, Kanaan HY, Al-Haddad K. Vienna rectifier with power quality added function. IEEE Transactions on Industrial Electronics. 2014 Aug;61(8):3847-56. [16]. Szpek M, Sonnenberg BJ, Lisy SM. 400VDC distribution architectures for central offices and data centers. InTelecommunications Energy Conference (INTELEC), 2014 IEEE 36th International 2014 Sep 28 (pp. 1-6). IEEE. [17]. Pahlevani M, Bakhshai A, Goel N, Jain P. A novel control technique for an AC/DC converter used in telecom applications. InTelecommunications Energy Conference (INTELEC), 2014 IEEE 36th International 2014 Sep 28 (pp. 1-6). IEEE. [18]. Whaite S, Grainger B, Kwasinski A. Power quality in DC power distribution systems and microgrids. Energies. 2015 May 15;8(5):4378-99. [19]. Lin WM, Hong CM, Cheng FS, Lu KH. Mppt control strategy for wind energy conversion system based on rbf network. InEnergytech, 2011 IEEE 2011 May 25 (pp. 1-6). IEEE. [20]. Tiwari R. Comparative Analysis of Pitch Angle Controller Strategies for PMSG Based Wind Energy Conversion System. [21]. Lin WM, Hong CM, Ou TC, Chiu TM. Hybrid intelligent control of PMSG wind generation system using pitch angle control with RBFN. Energy Conversion and Management. 2011 Feb 28;52(2):1244-51. [22]. Saravanan S, Babu NR. RBFN based MPPT algorithm for PV system with high step up converter. Energy Conversion and Management. 2016 Aug 15;122:239-51. [23]. Lee JS, Lee KB. Performance analysis of carrier-based discontinuous PWM method for vienna rectifiers with neutral-point voltage balance. IEEE Transactions on Power Electronics. 2016 Jun;31(6):4075-84. [24]. Islam MH, Razzak MA. Design of a modified Vienna rectifier for power factor correction under different three phase loads. InInformatics, Electronics and Vision (ICIEV), 2016 5th International Conference on 2016 May 13 (pp. 764-770). IEEE. [25]. Adhikari J, Prasanna IV, Panda SK. Reduction of Input Current Harmonic Distortions and Balancing of Output Voltages of the Vienna Rectifier Under Supply Voltage Disturbances. IEEE Transactions on Power Electronics. 2017 Jul;32(7):5802-12. [26]. Lu X, Xie Y, Chen L. Feedback linearization and sliding mode control for VIENNA rectifier based on differential geometry theory. Mathematical Problems in Engineering. 2015 Mar 23;2015. [27]. Flores-Bahamonde F, Valderrama-Blavi H, Martínez-Salamero L, Maixé-Altés J, García G. Control of a three-phase AC/DC VIENNA converter based on the sliding mode loss-free resistor approach. IET Power Electronics. 2014 Jan 6;7(5):1073-82. [28]. Lee JS, Lee KB. Predictive Control of Vienna Rectifiers for PMSG Systems. IEEE Transactions on Industrial Electronics. 2017 Apr;64(4):2580-91. [29]. Zhang M, Li B, Hang L, Tolbert LM, Lu Z. Performance study for high power density three-phase Vienna PFC rectifier by using SVPWM control method. InApplied Power Electronics Conference and Exposition (APEC), 2012 Twenty-Seventh Annual IEEE 2012 Feb 5 (pp. 1187-1191). IEEE. [30]. Hang L, Zhang H, Liu S, Xie X, Zhao C, Liu S. A novel control strategy based on natural frame for Vienna-type rectifier under light unbalanced-grid conditions. IEEE Transactions on Industrial Electronics. 2015 Mar;62(3):1353-62. [31]. Adhikari J, Prasanna IV, Panda SK. Voltage oriented control of the three-level Vienna rectifier using vector control method. InApplied Power Electronics Conference and Exposition (APEC), 2016 IEEE 2016 Mar 20 (pp. 9-16). IEEE.
Toplam 1 adet kaynakça vardır.

Ayrıntılar

Bölüm Electrical & Electronics Engineering
Yazarlar

Sudha Ramasamy

Yayımlanma Tarihi 11 Aralık 2017
Yayımlandığı Sayı Yıl 2017 Cilt: 30 Sayı: 4

Kaynak Göster

APA Ramasamy, S. (2017). Single Stage Energy Conversion through an RBFN Controller based Boost Type Vienna Rectifier in the Wind Turbine System. Gazi University Journal of Science, 30(4), 253-266.
AMA Ramasamy S. Single Stage Energy Conversion through an RBFN Controller based Boost Type Vienna Rectifier in the Wind Turbine System. Gazi University Journal of Science. Aralık 2017;30(4):253-266.
Chicago Ramasamy, Sudha. “Single Stage Energy Conversion through an RBFN Controller Based Boost Type Vienna Rectifier in the Wind Turbine System”. Gazi University Journal of Science 30, sy. 4 (Aralık 2017): 253-66.
EndNote Ramasamy S (01 Aralık 2017) Single Stage Energy Conversion through an RBFN Controller based Boost Type Vienna Rectifier in the Wind Turbine System. Gazi University Journal of Science 30 4 253–266.
IEEE S. Ramasamy, “Single Stage Energy Conversion through an RBFN Controller based Boost Type Vienna Rectifier in the Wind Turbine System”, Gazi University Journal of Science, c. 30, sy. 4, ss. 253–266, 2017.
ISNAD Ramasamy, Sudha. “Single Stage Energy Conversion through an RBFN Controller Based Boost Type Vienna Rectifier in the Wind Turbine System”. Gazi University Journal of Science 30/4 (Aralık 2017), 253-266.
JAMA Ramasamy S. Single Stage Energy Conversion through an RBFN Controller based Boost Type Vienna Rectifier in the Wind Turbine System. Gazi University Journal of Science. 2017;30:253–266.
MLA Ramasamy, Sudha. “Single Stage Energy Conversion through an RBFN Controller Based Boost Type Vienna Rectifier in the Wind Turbine System”. Gazi University Journal of Science, c. 30, sy. 4, 2017, ss. 253-66.
Vancouver Ramasamy S. Single Stage Energy Conversion through an RBFN Controller based Boost Type Vienna Rectifier in the Wind Turbine System. Gazi University Journal of Science. 2017;30(4):253-66.