Reliability of HVDC substations in long-distance power transmission
1 Department of Electrical and Electronics Engineering, Government Polytechnic, Belagavi, Karnataka, India.
2 Department of Electrical and Electronics Engineering, Government Polytechnic, Vijayapur, Karnataka, India.
3 Department of Electrical and Electronics Engineering, D R R Government Polytechnic, Davanagere, Karnataka, India.
Review Article
World Journal of Advanced Research and Reviews, 2022, 15(03), 545-559
Publication history:
Received on 16 August 2022; revised on 21 September 2022; accepted on 23 September 2022
Abstract:
High Voltage Direct Current (HVDC) technology plays a pivotal role in modern power transmission systems, particularly for long-distance and high-capacity applications. Compared to conventional Alternating Current (AC) transmission, HVDC offers advantages such as reduced transmission losses, enhanced grid stability, and improved integration of renewable energy sources. However, the reliability of HVDC substations remains a critical challenge, as failures in key components can lead to extensive power disruptions, economic losses, and grid instability. This paper provides an in-depth analysis of reliability concerns in HVDC substations, highlighting failure modes in essential components such as converters, transformers, circuit breakers, and control systems. Various factors influencing the operational dependability of HVDC infrastructure, including thermal stress, insulation degradation, switching transients, and cybersecurity threats, are discussed. Additionally, the study examines advanced diagnostic tools, predictive maintenance techniques, and redundancy strategies designed to enhance system resilience and minimize failure risks. Furthermore, recent technological advancements in HVDC substation design, including modular converter topologies, improved insulation materials, and AI-driven fault detection, are explored. The effectiveness of these innovations in improving system robustness is evaluated through statistical analysis. To support the discussion, the paper includes relevant figures, tables, and bar charts illustrating reliability trends, failure rates, and technological improvements. The findings underscore the need for continued research and development to optimize the reliability and efficiency of HVDC substations, ensuring the sustainability of modern power transmission networks.
Keywords:
HVDC substations; Reliability; Predictive maintenance; Redundancy; Electromagnetic interference (EMI); Wide-bandgap semiconductors; Silicon carbide (SiC); Gallium nitride (GaN)
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