Research and proposal the configuration of the booster circuit in the grid connected solar cell system and MPPT simulation in the partially shaded conditions

  • Affiliations:

    1 Institute of Energy Science - VAST, Hanoi, Vietnam
    2 HCMC University of Technology and Educatio, Ho Chi Minh City, Vietnam
    3 Thai Binh University, Thai Binh,Vietnam
    4 Hanoi University of Mining and Geology, Hanoi, Vietnam
    5 Hanoi University of Industry, Hanoi, Vietnam

  • *Corresponding:
    This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Received: 25th-Mar-2021
  • Revised: 2nd-July-2021
  • Accepted: 29th-July-2021
  • Online: 31st-Aug-2021
Pages: 79 - 90
Views: 2189
Downloads: 900
Rating: 1.0, Total rating: 89
Yours rating

Abstract:

This paper proposes a new turbocharger configuration that uses fewer semiconductor locks, fewer reactor coils, and a higher turbidity factor than conventional turbocharger configurations. This allows for easier control, less component loss, high efficiency, reduced circuit size and weight, and low cost. A booster circuit configuration with recommended neutral is required and is suitable for T-shaped and NPC 3-order inverters. In addition, the article also applies the maximum power point tracking algorithm for PV systems working in partially shaded conditions to improve the working efficiency of PV systems, to meet the requirements of the PV systems. grid-connected large capacity PV system.

How to Cite
Nguyen, M.Duc, Truong, A.Viet, Le, P.Hoang, Vu, L.Thuy Thi, Do, Y.Nhu and Trinh, C.Trong 2021. Research and proposal the configuration of the booster circuit in the grid connected solar cell system and MPPT simulation in the partially shaded conditions (in Vietnamese). Journal of Mining and Earth Sciences. 62, 4 (Aug, 2021), 79-90. DOI:https://doi.org/10.46326/JMES.2021.62(4).09.
References

Figueres, E., Garceras, G., Sandia, J., Espisn, F. G., and Rubio, J. C., (2009). Sensitivity study of the dynamics of three-phase photovoltaic inverters with an LCL grid filter. IEEE Trans. Ind. Electron., vol. 56, no. 3, pp. 706–717.

Deshpande, S., and Bhasme N. R., (2018). A review of topologies of inverter for grid connected PV systems. 2017 Innov. Power Adv. Comput. Technol. i-PACT 2017, vol. 2017-Janua, pp. 1–6.

 Selvaraj, J., and Rahim, N. A., (2009). Multilevel Inverter For Grid-ConnectedPV System Employing Digital PI Controller. IEEE Trans. Ind. Electron., vol. 56, no. 1, pp. 149–158.

Scarpa, V. V. R., Buso, S., and Spiazzi, G., (2009). Low-complexity MPPT technique exploiting the PV module MPP locus characterization. IEEE Trans. Ind. Electron., vol. 56, no. 5, pp. 1531–1538.

Li, W., Liu, J., Wu, J., and He, X., (2007). Design and analysis of isolated ZVT boost converters for high-efficiency and high-step-up applications. IEEE Trans. Power Electron., vol. 22, no. 6, pp. 2363–2374.

Sahoo, M., and Kumar, K. S., (2014). High gain step up DC-DC converter for DC micro-grid application. 2014 7th Int. Conf. Inf. Autom. Sustain. "Sharpening Futur. with Sustain. Technol. ICIAfS 2014.

Chen, S., Zhou, L., Luo, Q., and Zhu, B., (2013). Interleaved non-isolated high step-up DC/DC converter based on the diode–capacitor multiplier. IET Power Electron., vol. 7, no. 2, pp. 390–397.

Marabeas, P., Coutellier, D., Yang, J., Choi, S., and Agelidis, V. G., (2011). Analysis, design and experimental results of a floating-output interleaved-input boost-derived DC–DC high-gain transformer-less converter. IET Power Electron., vol. 4, no. 1, p. 168.

Das, D., and Pradhan, S. K. P., (2011). Modeling and Simulation of PV Array With Boost Converter : An Open Loop Study. pp. 1–47.

Khan, A., and Pal, S., (2017). Study PV Module Characteristics. Int. Conf. Energy, Commun. Data Anal. Soft Comput., no. 3, pp. 2399–2403.

Kumari J. S., and Babu, C. S., (2013) Mathematical Modeling and Simulation of Photovoltaic Cell using Matlab-Simulink Environment. Int. J. Electr. Comput. Eng., vol. 2, no. 1, pp. 26–34.

Armstrong, M., Atkinson, D. J., Johnson, C. M., and Abeyasekera, T. D., (2006). Auto-calibrating dc link current sensing technique for transformerless, grid connected, H-bridge inverter systems. IEEE Trans. Power Electron., vol. 21, no. 5, pp. 1385–1393.

Other articles