Resilience is an important feature to consider when evaluating an electric power system’s ability to withstand extreme events. Multiple flaws, such as short circuits, equipment malfunctions, overloads, and intermittent renewable energy sources, routinely disrupt electric power networks. These faults are often addressed ahead of time through planning studies or planned solutions since specific criteria make them predictable. However, catastrophic events that endanger electric power networks, such as hurricanes, floods, cyberattacks, and earthquakes, have a low probability but a significant impact, demanding resilience research. In this research, we will evaluate the resilience following a simulation of these severe occurrences on an IEEE 33 nod network test, followed by improvement activities via distributed generators and line commutators.

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Comparison of the Effect of Integrating DGs and Tie Switches to Improve the Resilience of Electrical Systems.

  • I. Abdallah,
  • M. Boudour,
  • A. Ladjici

摘要

Resilience is an important feature to consider when evaluating an electric power system’s ability to withstand extreme events. Multiple flaws, such as short circuits, equipment malfunctions, overloads, and intermittent renewable energy sources, routinely disrupt electric power networks. These faults are often addressed ahead of time through planning studies or planned solutions since specific criteria make them predictable. However, catastrophic events that endanger electric power networks, such as hurricanes, floods, cyberattacks, and earthquakes, have a low probability but a significant impact, demanding resilience research. In this research, we will evaluate the resilience following a simulation of these severe occurrences on an IEEE 33 nod network test, followed by improvement activities via distributed generators and line commutators.