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Using Dynamic Thermal Rating of HVDC Transmission Corridors to Increase Penetration of Renewable Energy
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- Author / Creator
- Pemachandra, Beddage Veenavi W
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As the world shifts its focus toward achieving net-zero emissions, every contributor to greenhouse gas emissions, including the electricity industry, is transitioning to eco-friendly solutions such as renewable generation. Simultaneously, the significant increase in electrical consumption has also highlighted the need to increase the capacity of the transmission infrastructure. As a result, much attention has been paid to the large-scale use of renewable energy through high-voltage direct current (HVDC) transmission technology, ascribing to its economic feasibility. The growing demand for electricity and the increasing penetration of renewable energy sources has prompted the electric power industry to explore methods to optimize the use of existing grid infrastructure.
Dynamic Thermal Line Rating (DTLR) is one of the promising techniques that allow transmission lines to operate close to their actual maximum capacity considering real-time operating conditions such as conductor temperature, sag, tension, and weather parameters. Numerous practical implementations and studies on this subject have been carried out thus far starting from the period before World War 2. However, the majority of existing research on this topic has been limited to employing DTLR in classical alternating current based power systems.
To this end, this study presents a novel approach by employing DTLR for an HVDC transmission system to maximize the utilization of the transmission capacity and to improve the penetration of renewable energy. This approach can allow the transmission utility companies to expand their utilization of renewable energy integration to the generation mix while reducing or even avoiding capital investments into new transmission line infrastructure.
The feasibility and performance of the proposed approach are evaluated by conducting a case study for an HVDC transmission line in Alberta, Canada. The study results find that, on average, the mean increase in HVDC line conductor ampacity rating above the static rating is 64% during winter and 34% during summer. This additional capacity is proposed to integrate wind energy, replacing coal-fired energy generation. This would lead to a significant reduction in greenhouse gas emissions, especially a 13.78 tons per hour reduction in carbon dioxide (CO2). Furthermore, the financial benefits comparison indicates an additional benefit of CA$ 0.10 M/GWh when using DTLR for enhancing the transmission capacity rather than the conventional line upgrading method. Ultimately, this study offers a practical approach to reducing greenhouse gas emissions by integrating more renewable energy resources into the generation mix and reducing curtailment. Furthermore, looking into the global scale, since the long distance transmission from HVDC is gaining more popularity, this will allow the utility companies to optimally choose the best locations where renewable sources are available even though they are either offshore or far away from the load centers. -
- Subjects / Keywords
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- Graduation date
- Spring 2024
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- Type of Item
- Thesis
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- Degree
- Master of Science
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- License
- This thesis is made available by the University of Alberta Libraries with permission of the copyright owner solely for non-commercial purposes. This thesis, or any portion thereof, may not otherwise be copied or reproduced without the written consent of the copyright owner, except to the extent permitted by Canadian copyright law.