Home            Contact us            FAQs
    
      Journal Home      |      Aim & Scope     |     Author(s) Information      |      Editorial Board      |      MSP Download Statistics

     Research Journal of Applied Sciences, Engineering and Technology

Research Article   |   OPEN ACCESS

Photovoltaic Simplified Boost Z Source Inverter for Ac Module Applications

J. Sam Alaric and K. Suresh Manic
ST. Peter University, Avadi, Chennai, India
Research Journal of Applied Sciences, Engineering and Technology  2014  6:760-766
http://dx.doi.org/10.19026/rjaset.8.1032  |  © The Author(s) 2014
Received: May ‎19, ‎2014  |  Accepted: ‎July ‎01, ‎2014  |  Published: August 15, 2014
Back to issue  |  PDF   |   HTML

Abstract

This study mainly proposed PV z source boost inverter used to boundary grid or ac module applications. Separate types of converter used for solar system due to its current lagging, here capacitor multiplier based boost converter introduced for maintain the current lagging and voltage gain. Here, the switched inductor z source inverter implemented for grid interface. Proposed z source inverter is controlled by pulse width modulation. A simplified capacitor multiplier controlled by continuous conduction mode, A detailed topology analysis and a generalized discussion are given. The multiplier boost converter has the merits of maintain voltage level and reducing cost and current lagging. Simulation results are implemented and analysis MATLAB software.

Keywords:

Capacitor multiplier , CCM, MPPT, PWM, switched z source inverter,

References

  1. Adar, D., G. Rahav and S. Ben-Yaakov, 1997. A uni?ed behavioral average model of SEPIC converters with coupled inductors. Proceeding of the 28th Annual IEEE Conference of the Power Electronics Specialists Conference (PESC, 97), pp: 441-446.
    CrossRef    
  2. Chen, S.M., T.J. Liang, L.S. Yang and J.F. Chen, 2013. A boost converter with capacitor multiplier and coupled inductor for AC module applications. IEEE T. Ind. Electron., 60(4): 1503-1511.
    CrossRef    
  3. Chiang, S.J., H.J. Shieh and M.C. Chen, 2009. Modeling and control of PV charger system with SEPIC converter. IEEE T. Ind. Electron., 56(11): 4344-4353.
    CrossRef    
  4. Falin, J., 2010. Designing dc/dc converters based on ZETA topology. Analog Appl. J., pp: 16-23, 2Q.
  5. Ioinovici, A., 2001. Switched-capacitor power electronics circuits. IEEE Circuits Syst. Mag., 1(4): 37-42.
    CrossRef    
  6. Kerekes, T., M. Liserre, C. Klumpner and M. Sumner, 2009. Evaluation of three-phase transformer less photovoltaic inverter topologies. IEEE T. Power Electr., 24(9): 2202-2211.
    CrossRef    
  7. Kim, I.D., J.Y. Kim, E.C. Nho and H.G. Kim, 2010. Analysis and design of a soft-switched PWM Sepic DC-DC converter. J. Power Electron., 10(5): 461-467.
    CrossRef    
  8. Li, W. and X. He, 2011. Review of non-isolated high step-up DC/DC converters in photovoltaic grid-connected applications. IEEE T. Ind. Electron., 58(4): 1239-1250.
    CrossRef    
  9. Peng, F.Z., 2002. Z-source inverter. Proceeding of the 37th Annual Meeting Conference Record of the Industry Application Conference, pp: 775-781.
    CrossRef    
  10. Peng, F.Z., M. Shen, J. Wang and A. Joseph, 2004. Maximum constant boost control of the Z-source inverter. Proceeding of the 39th IAS Annual IEEE Conference on Power Electron, pp: 833-838.
  11. Rodriguez, C. and G.A.J. Amaratunga, 2008. Long-lifetime power inverter for photovoltaic ac modules. IEEE T. Ind. Electron., 55(7): 2593-2601.
    CrossRef    
  12. Shimizu, T., K. Wada and N. Nakamura, 2006. Flyback-type single-phase utility Interactive inverter with power pulsation decoupling on the DC input for an AC photovoltaic module system. IEEE T. Power Electr., 21(5): 1264-1272.
    CrossRef    
  13. Xue, Y., L. Chang, S.B. Kjaer, J. Bordonau and T. Shimizu, 2004. Topologies of single-phase inverters for small distributed power generators: An overview. IEEE T. Power Electr., 19(5): 1305-1314.
    CrossRef    
  14. Yang, C. and K. Smedley, 2008. Three-phase boost-type grid-connected inverter. IEEE T. Power Electr., 23(5): 2301-2309.
    CrossRef    
  15. Zhu, M. and F.L. Luo, 2009. Super-lift DC-DC converters: Graphical analysis modeling. J. Power Electron., 9(6): 854-865.
  16. Zhu, M., K. Yu and F.L. Luo, 2010. Switched inductor Z-source inverter. IEEE T. Power Electr., 25(8): 2150-2158.
    CrossRef    

Competing interests

The authors have no competing interests.

Open Access Policy

This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Copyright

The authors have no competing interests.
ISSN (Online):  2040-7467
ISSN (Print):   2040-7459
Submit Manuscript
   Information
   Sales & Services
Home   |  Contact us   |  About us   |  Privacy Policy
Copyright © 2025. MAXWELL Scientific Publication Corp., All rights reserved