Optimizing Grid-Connected Inverter Performance Through Voltage Stability Control

Fazle Rabbi Sweet; Jahidul Islam; Ramani Ranjan Sikder; Suvash Chandra Roy; Mostafa Kamal; Amathul Hadi Shakara; Tareq Hasan; Kalyan Kumar Mallick1

1

Publication Date: 2024/07/05

Abstract: Everyday, non-renewable energy sources are being depleted while energy use rises. In response to these arguments, we ought to generate more renewable energy. But a big problem with renewable energy is that its production is weather-dependent. In overcast and unfavorable weather, the energy generated on the grid side is insufficient to match the demand on the load side. The primary load-side issues may be non-linear loads that lower the energy network’s power quality or excessive or unmanaged energy demand. When compared to the production of renewable energy, energy sources that are connected to the grid through an electronic converter or inverter have quite different operating characteristics. The stability of the grid and solutions to the grid-to- transmission-line stability issue are the main topics of this study. The benefits of using inverters in a power system from the grid to the transmission line with MPPT and PI controllers are examined in this article. A robust control system with an inverter-equipped PI controller and MPPT addresses the main problem.

Keywords: IGBT; Boost Converter; PI Controller; MPPT; PV Array.

DOI: https://doi.org/10.38124/ijisrt/IJISRT24JUN092

PDF: https://ijirst.demo4.arinfotech.co/assets/upload/files/IJISRT24JUN092.pdf

REFERENCES

  1. Viawan, F. (2008). Voltage control and voltage stability of power distribution systems in the presence of distributed generation. Chalmers Tekniska Hogskola (Sweden).
  2. Chowdhury, V. R., & Kimball, J. W. (2020). Robust Control Scheme for a Three Phase Grid-Tied Inverter with $ LCL $ Filter During Sensor Failures. IEEE Transactions on Industrial Electronics68(9), 8253-8264.
  3. Adekola, O. I. (2015). Design and development of a smart inverter system (Doctoral dissertation, Cape Peninsula University of Technology).
  4. Yang, S., Lei, Q., Peng, F. Z., & Qian, Z. (2010). A robust control scheme for grid-connected voltage-source inverters. IEEE transactions on Industrial Electronics58(1), 202-212.
  5. Şahin, M. E., & Blaabjerg, F. (2020). A hybrid PV-battery/supercapacitor system and a basic active power control proposal in MATLAB/simulink. Electronics9(1), 129.
  6. ARAVA, V. N. Voltage Stability Assessment of Power Systems by Decision Tree Classification and Preventive Control by Pre-Computing Secure Operating Conditions.
  7. Sahoo, B., Routray, S. K., & Rout, P. K. (2021). Robust control and inverter approach for power quality improvement. In Green Technology for Smart City and Society: Proceedings of GTSCS 2020 (pp. 143-156). Springer Singapore.
  8. Airoboman, A. E., Okakwu, I. K., Alayande, A. S., & Seun, O. E. (2015). On the assessment of power system stability using Matlab/Simulink model. International Journal of Energy and Power Engineering4(2), 51-64.