Fuzzy Dynamic Thermal Rating System-Based Thermal Aging Model for Transmission Lines

Yaqoob, Yasir; Marzuki, Arjuna; Lai, Ching-Ming; Teh, Jiashen

doi:10.3390/en15124395

Cited by 3 publications

(1 citation statement)

References 36 publications

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“…Following the successful implementation of DTR, the transmission lines (TLs) will operate at higher temperatures. Thus, conductor thermal ageing refers to the gradual deterioration of transmission conductors due to prolonged exposure to high temperatures, which could occur due to DTR implementation [17], [18]. Monitoring temperature and load capacity in real-time is crucial to assess operational risks and mitigate the effects of thermal ageing.…”

Section: Introductionmentioning

confidence: 99%

Synchrophasor-Based DTR and SIPS Cyber-Physical Network Reliability Effects Considering Communication Network Topology and Total Network Ageing

Jimada-Ojuolape,

Teh,

Alharbi

2023

IEEE Access

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The lifespan of overhead transmission conductors is influenced by various factors, including design, maintenance, and operating conditions. Prolonged exposure to high temperatures, particularly near maximum design values, can significantly age transmission lines (TLs). The dynamic thermal rating (DTR) system, an advanced technology that increases TL capacities, can contribute to these stringent conditions. DTR overlays a cyber layer with communication and control systems onto the physical network, transforming it into a cyber-physical network. Currently, the increased risk of TL ageing associated with DTR, and the cyber layer's functionality lack a unified framework for quantification. This study introduces a novel framework that considers the cyber layer's network topology and its impact on TL ageing due to DTR implementation. It also proposes the implementation of system integrity protection schemes (SIPS) within the framework. SIPS detects abnormal conditions from DTR deployment, like excessive line loading, and takes corrective actions to optimize DTR system's performance. The study employs a Sequential Monte Carlo Simulation (SMCS) technique on a modified cyber-physical IEEE RTS-79. The study reveals that topologies like double ring and mesh, cause higher line ageing indices compared to line and star topologies. ETNA values remain relatively stable across the network topologies within a year, suggesting minimal short-term impact on transmission line ageing. However, cumulative effects over several years can potentially reduce lifespan. SIPS can slow network ageing by up to 5hr/yr, but their contingencies can cause the opposite effect. Nonetheless, a reliable SIPS can maintain an ETNA value of 101hr/yr without increasing load curtailment.

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Section: Introductionmentioning

confidence: 99%

Synchrophasor-Based DTR and SIPS Cyber-Physical Network Reliability Effects Considering Communication Network Topology and Total Network Ageing

Jimada-Ojuolape,

Teh,

Alharbi

2023

IEEE Access

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The overhead transmission line temperature impact on the phase-shifting transformer settings

Albrechtowicz

2023

Electric Power Systems Research

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Linear modeling analysis of the heat balance of the transmission line in high frequency critical ice melting state

Tan,

Liu,

Yuan

et al. 2024

International Journal of Low-Carbon Technologies

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The icing of transmission lines can cause many problems such as increased line load, unbalanced tension, and galloping, posing a serious threat to the reliable operation of the power system. Therefore, linear modeling analysis of the heat balance under a high-frequency critical ice melting state of transmission lines is studied. The thermal conduction states of melting, heating, twisting, rotating melting, and ice layer detachment of ice melting conductors are analyzed. Based on the heat conduction process of thermal melting of ice on transmission lines, a simplified calculation formula for thermal melting ice time is derived to calculate times for heating, ice layer torsion, and air gap increase. At the same time, based on the law of conservation of energy, thermodynamic boundary conditions for iced conductors were established and corresponding physical models were constructed. Based on this model, we conduct a linear modeling of the heat balance in the melting state in order to provide a more accurate prediction of temperature distribution. The experimental results show that there is a negative correlation between environmental temperature and critical melting current, and the melting time decreases with the increase of environmental temperature.

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Fuzzy Dynamic Thermal Rating System-Based Thermal Aging Model for Transmission Lines

Cited by 3 publications

References 36 publications

Synchrophasor-Based DTR and SIPS Cyber-Physical Network Reliability Effects Considering Communication Network Topology and Total Network Ageing

Synchrophasor-Based DTR and SIPS Cyber-Physical Network Reliability Effects Considering Communication Network Topology and Total Network Ageing

The overhead transmission line temperature impact on the phase-shifting transformer settings

Linear modeling analysis of the heat balance of the transmission line in high frequency critical ice melting state

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