Power system strength for renewable energy resource hosting capacity enhancement
This dissertation investigates the critical issue of enhancing power system strength to facilitate the hosting capacity of renewable energy resources. With the increasing integration of RES such as wind and solar power into the electrical grid, system strength—defined as the grid’s ability to mai...
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| Format: | Thesis-Master by Coursework |
| Language: | English |
| Published: |
Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/178108 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This dissertation investigates the critical issue of enhancing power system strength
to facilitate the hosting capacity of renewable energy resources. With the increasing
integration of RES such as wind and solar power into the electrical
grid, system strength—defined as the grid’s ability to maintain stable voltage
levels under dynamic conditions—becomes a paramount concern. This study
aims to address the challenges posed by the integration of RES, which often
leads to reduced system strength, characterized by lower short-circuit levels and
increased susceptibility to voltage fluctuations.
The research begins with a comprehensive literature review, examining the theoretical
foundations of system strength and its significance in the context of renewable
energy integration. It explores various factors influencing system strength,
including the SCR and the X/R ratio, and their impact on grid stability. The
dissertation then systematically evaluates different strategies to enhance system
strength, such as the deployment of synchronous condensers, the utilization of
FACTS devices, and the integration of BESS. Each solution is assessed for its
effectiveness in improving grid resilience, operational flexibility, and the ability
to support higher levels of renewable penetration.
Through detailed system modeling and simulation, the dissertation presents an
empirical analysis of these strategies, using advanced tools like PSCAD to simulate
grid behavior under various scenarios. The simulations focus on the dynamic
responses of the grid to renewable energy fluctuations and fault condiiii
tions, providing insights into the performance of different system strengthening
solutions.
The findings of this research contribute to the broader understanding of power
system dynamics in the era of renewable energy, offering practical recommendations
for utilities, grid operators, and policymakers to enhance system strength.
The dissertation underscores the necessity of a proactive approach to grid management
and infrastructure investment to ensure reliable and sustainable energy
supply in the face of rapidly evolving energy landscapes. |
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