A Comprehensive Review and Analysis on Voltage Stability Enhancement Using Distributed Generation

Shehzad Haneef; Amjad Ali; Syed Muhammad Ali Shah; Agha Yasir Ali; Muhammad Salman Saeed; Zeeshan Rashid

Authors

Shehzad Haneef The Islamia University of Bahawalpur, Pakistan
Amjad Ali The Islamia University of Bahawalpur, Pakistan
Syed Muhammad Ali Shah Mehran University of Engineering and Technology, Pakistan
Agha Yasir Ali Sir Syed University of Engineering and Technology, Pakistan
Muhammad Salman Saeed Multan Electric Power Company (MEPCO)
Zeeshan Rashid The Islamia University of Bahawalpur, Pakistan

Keywords:

Smart Grids, Power System Stability, Load Flow Control, Photovoltaic Systems, Microgrids

Abstract

The present-day scenario of electrical power system engineering mainly comprises issues like power paucity, blackout, load shedding, and ineptness in meeting the necessary demand for power. Therefore, new power plants are built and old ones are expanded and upgraded. Although these developments play a key role in today’s scenario, there remains a field where the scope of development persists. This review article focuses on incorporating load models in traditional (OPF) studies and comparing the results of the above with those obtained from OPF analysis with the incorporation of (DG). The study of stability analysis and its behavior is a very important aspect of power system planning and its design for reliable operation. The determination of the transient stability of an electric power system is a crucial step in power system analysis. It has become imperative for power engineers to look out for improvement in the voltage stability of a power system. For this purpose, the IEEE 9 bus system is considered. The main objective is the analysis of the transient stability of an IEEE 9 bus system consisting of three generators and nine buses. Further, transient analysis of the power system network will facilitate the design of a better DG network. Here, MATLAB software is used to analyze the stability of the power system.

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