Details

Title

An active power filter based on a hybrid converter topology – Part 1

Journal title

Bulletin of the Polish Academy of Sciences Technical Sciences

Yearbook

2021

Volume

69

Issue

No. 1

Affiliation

Gwóźdź, Michał : Poznan University of Technology, Faculty of Control, Robotics and Electrical Engineering, Piotrowo 3A, 60-965 Poznan, Poland ; Ciepliński, Łukasz : Poznan University of Technology, Faculty of Control, Robotics and Electrical Engineering, Piotrowo 3A, 60-965 Poznan, Poland

Authors

Keywords

shunt active power filter ; pulse-width modulation (PWM) ; sigma-delta modulator ; silicon carbide

Divisions of PAS

Nauki Techniczne

Coverage

e136218

Bibliography

  1.  B. Kroposki, C. Pink, R. DeBlasio, H. Thomas, M. Simões, and P. Sen, “Benefits of Power Electronic Interfaces for Distributed Energy Systems”, IEEE Trans. Energy Convers. 25, 901–908 (2010).
  2.  M. Pasko, D. Buła, K. Dębowski, D. Grabowski, and M. Maciążek, “Selected methods for improving operating conditions of three-phase systems working in the presence of current and voltage deformation — Part I”, Arch. .Electr. Eng. 67, 591–602 (2018).
  3.  A. Benchabira and M. Khiat, “A hybrid method for the optimal reactive power dispatch and the control of voltages in an electrical energy network”, Arch. Electr. Eng. 68, 535–551 (2019).
  4.  A. Nami, J.L. Rodríguez Amenedo, S. Arnaltes Gómez, and M.Á. Cardiel Álvarez, “Active power filtering embedded in the frequency control of an offshore wind farm connected to a diode-rectifier-based HVDC link”, Energies 11, 2718 (2018).
  5.  A.J. Christe, S. Negrashov, and P.M. Johnson, “Design, implementation, and evaluation of open power quality”, Energies 13, 4032 (2020).
  6.  B. Lewczuk, G. Redlarski, A. Zak, N. Ziółkowska, B. Przybylska-Gornowicz, and M. Krawczuk, “Influence of Electric, Magnetic, and Electromagnetic Fields on the Circadian System: Current Stage of Knowledge”, in BioMed Research International 2014, 2014, pp. 1–13.
  7.  M. Siwczyński and M. Jaraczewski, “Reactive compensator synthesis in time-domain”, Bull. Pol. Ac.: Tech. 60(1), 119–124 (2012).
  8.  Y. Chen, Z. Huang, Z. Duan, P. Fu, G. Zhou, and L. Luo, “A four-winding inductive filtering transformer to enhance power quality in a high-voltage distribution network supplying nonlinear loads”, Energies 12, 2021 (2019).
  9.  Y. Rozanov, S. Ryvkin, E. Chaplygin, and P. Voronin, Fundamentals of power electronics: operating principles, design, formulas, and applications, CRC Press, 2015.
  10.  M. Rashid, Power Electronics Handbook, Elsevier Ltd.: Oxford, 2018.
  11.  K. Shyu, M. Yang, Y. Chen, and Y. Lin, “Model Reference Adaptive Control Design for a Shunt Active-Power-Filter System”, IEEE Trans. Ind. Electron.55, 97–106 (2008).
  12.  A. Kouzou, M. Mahmoudi, and M. Boucherit, “Evaluation of the Shunt Active Power Filter apparent power ratio using particle swarm optimization”, Arch. Control Sci. 20, 47–76 (2010).
  13.  K. Mikołajuk and A. Toboła, “Average time–varying models of active power filters”, Prz. Elektrotechniczny 95, 53–55 (2010).
  14.  M. Gwóźdź, “Power electronics active shunt filter with controlled dynamics”, Compel-Int. J. Comp. Math. Electr. Electron. Eng. 32, 1337–1344 (2013).
  15.  S. Fryze, “Active, reactive, and apparent power in circuits with nonsinusoidal voltage and current”, Prz. Elektrotechniczny 13, 193–203 (1931).
  16.  M. Artemenko, L. Batrak, and S. Polishchuk, “New definition formulas for apparent power and active current of three-phase power system”, Prz. Elektrotechniczny 95, 81–85 (2019).
  17.  H. Akagi, “Modern active filters and traditional passive filters”, Bull. Pol. Ac.: Tech. 54(3), 255–269 (2006).
  18.  H. Akagi, E. Watanabe, and M. Aredes, Instantaneous power theory and applications to power conditioning, IEEE Press, Hoboken: Piscataway, 2017.
  19.  L. Czarnecki, “Effect of Supply Voltage Harmonics on IRP-Based Switching Compensator Control”, IEEE Trans. Power Electron. 24, 483–488 (2009).
  20.  J. Vásárhelyi, M. Imecs, C. Szabó, I. Incze, and Á. Tihamér, “Managing transients generated by the reconfiguration process at the tandem inverter fed induction motor”, Proceedings of IEEE 7th International Conference on Intelligent Engineering Systems, 2003, pp. 388–393.
  21.  K. Kaneko, J. Mitsuta, K. Matsuse, K. Sasagawa, Y. Abe, and L. Huang, “Analysis of dynamic variation on a combined control strategy for a five-level double converter”, Proceedings of Power Electronics Specialists Conference PESC ’05, 2005, pp. 885–891.
  22.  M. Imecs, A. Trzynadlowski, I. Incze, and C. Szabo, “Vector Control Schemes for Tandem-Converter Fed Induction Motor Drives”, IEEE Trans. Power Electron. 20, 493–501 (2005).
  23.  T. Morizane and N. Kimura, “Circulating current control of double converter system for wind power generation”, Proceedings of the 14th European Conference on Power Electronics and Applications (EPE 2011), 2011.
  24.  A. Tomaszuk and A. Krupa, “High efficiency high step-up DC/ DC converters – a review”, Bull. Pol. Ac.: Tech. 59(4), 475–483 (2011).
  25.  M. Gwóźdź, Ł. Ciepliński, and M. Krystkowiak, “Power supply with parallel reactive and distortion power compensation and tunable inductive filter — Part 1”, Bull. Pol. Ac.: Tech. 68(3), 401–408 (2020).
  26.  X. Rui, L. Jing, L. Fuzhong, and W. Zhi, “The application on active noise cancellation — Research on the series-parallel compensated UPS converter”, International Symposium on Electromagnetic Compatibility EMC 2007, China, 2007, pp.138–141.
  27.  L. Asiminoaei, E. Aeloiza, P. Enjeti, and F. Blaabjerg, “Shunt Active-Power-Filter Topology Based on Parallel Interleaved Inverters”, IEEE Trans. Ind. Electron. 55, 1175–1189 (2008).
  28.  G. Eirea and S. Sanders, “Phase Current Unbalance Estimation in Multiphase Buck Converters”, IEEE Trans. Power Electron. 23, 137–143 (2008).
  29.  M. Hirakawa, M. Nagano, Y. Watanabe, K. Ando, S. Nakatomi, S. Hashino, and T. Shimizu, “High power density interleaved dc/dc converter using a 3-phase integrated close-coupled inductor set aimed for electric vehicles”, Proceedings of Energy Conversion Congress and Exposition (ECCE) 2010, 2010, pp. 2451–2457.
  30.  J. Iwaszkiewicz, P. Bogusławski, A. Krahel, and E. Łowiec, “Three-phase voltage outages compensator with cascaded multilevel converter”, Arch. Electr. Eng. 61, 325–336 (2012).
  31.  J. Wu, H. Jou, P. Huang, and I. Chiu, “Current balancing control for an interleaved boost power converter”, Int. J. .Electron. 106, 1567–1582 (2019).
  32.  M. Schetzen, Linear time-invariant systems, Wiley-IEEE Press, 2003.
  33.  M. Gwóźdź, “Stability of discrete time systems on base of generalized sampling expansion”, Elektryka, Silesian University of Technology 57, 29–40 (2011).
  34.  J. Doyle, B. Francis, and A. Tannenbaum, Feedback Control Theory, Dover Publications, 2013.
  35.  Y. Hasegawa, Control Problems of Discrete-Time Dynamical Systems, Springer, 2015.
  36.  W. Kester, The Data Conversion Handbook, Analog Devices Inc, Newnes, 2005.
  37.  J. de la Rosa, “Sigma-Delta Modulators: Tutorial Overview, Design Guide, and State-of-the-Art Survey”, IEEE Trans. Circuits Syst. I-Regul. Pap. 58, 1–21 (2011).
  38.  A. Jain, M. Venkatesan, and S. Pavan, “Analysis and Design of a High Speed Continuous-time Delta Sigma Modulator Using the Assisted Opamp Technique”, IEEE J. Solid-State Circuit. 47, 1615–1625 (2012).
  39.  B. Razavi, “The Delta-Sigma Modulator [A Circuit for All Seasons]”, IEEE Solid-State Circuit. Mag. 8, 10–15 (2016).
  40.  M. Gwozdz and D. Matecki, “Power electronics inverter with a modified sigma-delta modulator and an output stage based on GaN E-HEMTs”, in Advanced Control of Electrical Drives and Power Electronic Converters, pp. 327–338 Springer, London, 2017.
  41.  J. Chen, Y. Hwang, C. Jheng, Y. Ku, and C. Yu, “A Low-Electromagnetic-Interference Buck Converter with Continuous-Time Delta- Sigma-Modulation and Burst-Mode Techniques”, IEEE Trans. Ind. Electron. 65, 6860–6869 (2018).
  42.  D. Gerber, C. Le, M. Kline, P. Kinget, and S. Sanders, “An Integrated Multilevel Converter with Sigma–Delta Control for LED Lighting”, IEEE Trans. Power Electron. 34, 3030–3040 (2019).
  43.  B. Jacob and M. Baiju, “Space-Vector-Quantized Dithered Sigma–Delta Modulator for Reducing the Harmonic Noise in Multilevel Converters”, IEEE Trans. Ind. Electron. 62, 2064–2072 (2015).
  44.  C. Chang, F. Wu, and Y. Chen, “Modularized Bidirectional Grid-Connected Inverter with Constant-Frequency Asynchronous Sigma-Delta Modulation”, IEEE Trans. Ind. Electron. 59, 4088–4100 (2012).
  45.  B. Wilamowski and J. Irwin, Fundamentals of Industrial Electronics, CRC Press: London, United Kingdom, 2017.
  46.  Y. Kang, T. Ge, H. He, and J. Chang, “A review of audio class D amplifiers”, 2016 International Symposium on Integrated Circuits (ISIC), Singapore, 12–14 (2016).
  47.  X. Jiang, “Fundamentals of Audio Class D Amplifier Design: A Review of Schemes and Architectures”, IEEE Solid-State Circuits Magazine 9, 14–25 (2017).
  48.  G. Scott, “Design Considerations for Class-D Audio Power Amplifiers”, in Application Report (SLOA242A), Texas Instruments, 2019.
  49.  A. Chatterjee, H. Nobahari, and P. Siarry, Advances in Heuristic Signal Processing and Applications, Springer: Berlin, Heidelberg, 2013.
  50.  H. Zhang, C. Qin, and Y. Luo, “Neural-Network-Based Constrained Optimal Control Scheme for Discrete-Time Switched Nonlinear System Using Dual Heuristic Programming”, IEEE Trans. Autom. Sci. Eng. 11, 839–849 (2014).
  51.  R. Kirlin, C. Lascu, and A. Trzynadlowski, “Shaping the Noise Spectrum in Power Electronic Converters”, IEEE Trans. Ind. Electron. 58, 2780–2788 (2011).
  52.  M. Auer and T. Karaca, “Spread spectrum techniques for Class-D audio amplifiers to reduce EMI”, e & i Elektrotechnik und Informationstechnik 133, 43–47 (2016).
  53.  MITSUBISHI ELECTRIC Semiconductors & Devices: Power Modules for Power Applications | Power supply / UPS. [Online]. https:// www.mitsubishielectric.com/semiconductors/application/ups/index.html (accessed Aug. 11 2020).
  54.  Silicon Carbide CoolSiC™ MOSFET Modules – Infineon Technologies. [Online] https://www.infineon.com/cms/en/product/power/mosfet/ silicon-carbide/modules/ (accessed Aug. 11 2020).

Date

22.02.2021

Type

Article

Identifier

DOI: 10.24425/bpasts.2020.136218

Source

Bulletin of the Polish Academy of Sciences: Technical Sciences; 2021; 69; No. 1; e136218
×