Performance Analysis of a Dynamic Line Rating System Based on Project Experiences

Rácz, Levente; Németh, Balázs; Göcsei, Gábor; Zarchev, Dimitar; Mladenov, Valeri

doi:10.3390/en15031003

Cited by 5 publications

(5 citation statements)

References 24 publications

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“…The DLR analysis strictly follows the steady-state heat balanced approach proposed by the IEEE and/or CIGRÉ models [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19]. These models are similar regarding the calculation method; however they differ in the factors that they consider for the heat balance calculation [20]. The energy balance inside the conductor without any heat storage causes the amount of heat supplied completely convert into the outside environment by heat dissipation which is expressed under the simplified equilibrium equation of heat gained (by Joule effect ( ), Solar heating ) and heat lost (by convection ( ), radiation ( )) by EEE Standard 738 [10,20]:…”

Section: Dynamic Line Rating Methods For Maximizing Power Line Capacitymentioning

confidence: 99%

“…Dynamic rating by application of weather model allows increasing the line capacity by up to 20%, depending on the weather conditions [21]. The calculation methods are classified as indirect and direct methods [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24]. The indirect method (Figure 4) uses the measuring data from equipment placed surrounding line system giving all concerning parameters (wind speed, wind direction, solar radiation, and ambient temperature), which is then put into heat exchange equations ( 1), ( 5) to calculate the maximum amount of allowable intensity that the overhead line can carry in that specified time interval.…”

Section: Dynamic Line Rating Methods For Maximizing Power Line Capacitymentioning

confidence: 99%

“…These technologies include remote sensing, measurement, communication, data analytics, high-performance computing, and automation. Implementing a DLR system requires the following steps: line identification; sensor installation; data communication; data analytics; computing and temperature forecasting; and, finally, validation [14][15][16][17][18][19][20][21][22][23][24].…”

Section: Dynamic Line Rating Methods For Maximizing Power Line Capacitymentioning

confidence: 99%

“…Figure 6. Flowchart of the methodology application for transmission line rating implementation[14][15][16][17][18][19][20][21][22][23][24].…”

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Dynamic Line Rating Solution: Deployment Opportunities for the Power Transmission Grid of Vietnam

Nguyen¹,

Nguyen²

2022

IJEPE

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Power system usually have standard static ratings (SLR) that determines load constraints. It refers to the maximum allowable conductor ampacity pre-determined by worst-case conditions (high ambient temperature, maximum solar radiation, and low wind speed) of their overhead transmission lines, that rises the line's temperature without infringing ground clearance and causing loss of conductor tensile strength. Line's dynamic capacity is created as an alternative to standard constant rating that is designed with reference to extreme weather and load conditions. Dynamic line rating allows assets the real power line's operating capacity using available information on weather conditions. DLR is hence often more flexible than SLR, that have a chance of extending capacity of existing power lines for some periods of time with favorable weather conditions for transportation higher electrical power capacity from production site to the load. This paper investigates the possibility of using dynamic line rating (DLR) to expand the existing power transmission capacity of overhead lines which can be implemented on 220 kV transmission lines in Vietnam, especially in some line areas with high-density of renewable energy integration. This work applies a DLR caculation models to determine the power lines' additional theoretical ampacity obtained by using this methodology for a Ninh Thuan region with distinct conditions regarding i) weather database, ii) topography and iii) wind and solar power resource. The results show that the dynamic rating is predominantly higher than the static rating, which potentially enhances the system's reliability. This research provides a comprehensive study of literature on dynamic line rating, current constraints on the power system based on the geography of Vietnam, and analysis in Python and Matlab environment of real-time weather databases applied to dynamic rating on a proposed case study.

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Section: Dynamic Line Rating Methods For Maximizing Power Line Capacitymentioning

confidence: 99%

Section: Dynamic Line Rating Methods For Maximizing Power Line Capacitymentioning

confidence: 99%

Section: Dynamic Line Rating Methods For Maximizing Power Line Capacitymentioning

confidence: 99%

“…Figure 6. Flowchart of the methodology application for transmission line rating implementation[14][15][16][17][18][19][20][21][22][23][24].…”

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confidence: 99%

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Dynamic Line Rating Solution: Deployment Opportunities for the Power Transmission Grid of Vietnam

Nguyen¹,

Nguyen²

2022

IJEPE

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“…Increased 26.6% average ampacity gain with SLR exceeding DLR only 4% of the time [118]. Canada It used on DC bi-poles to analyze wind plant installation.…”

Section: Countrymentioning

confidence: 99%

Optimizing Grid With Dynamic Line Rating of Conductors: A Comprehensive Review

Abas,

Ab Kadir,

Azis

et al. 2024

IEEE Access

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As the world is pledged towards net zero carbon by 2050, the need for clean and efficient energy transitions is more critical than ever. Optimizing the power grid transfer capacity is crucial for maintaining grid stability and reliability. Ageing infrastructure, population growth, and revolutionary technological developments increase the demand for grid modernization and resilience investments. Climate change and natural disasters highlight the need for adaptive load-shedding schemes. The two possible ways to optimize the grid are an ampacity increase or a voltage increase. While increasing voltage provides the most significant rise in rating, it comes with high investment costs. Out of all the options available, dynamic line rating (DLR) is the most efficient and cost-effective solution. This paper provides a comprehensive review of the optimization of the grid transfer capacity using DLR. The review critically examines different line rating methods, the DLR system, factors that need to be considered before DLR implementation, and its advantages and disadvantages. Also, the review presents the real-world applications and case studies, standards and regulations involved, and current approaches and challenges for implementing DLR in Malaysia. Additionally, we highlight the most commonly used standards to calculate the conductor's ampacity for the steady-state and dynamic state. Moreover, this review work presents how DLR can advance the grid's flexibility, considering its significance for cleaner energy production in the future, challenges related to wind energy power generation, and their mitigations. This work provides a shortcut path for researchers and utilities to understand DLR and as a reference for future research to advance clean energy in response to changing energy needs and climate conditions.

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Dynamic line rating forecasting algorithm for a secure power system network

Lawal

The

2023

Expert Systems with Applications

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Performance Analysis of a Dynamic Line Rating System Based on Project Experiences

Cited by 5 publications

References 24 publications

Dynamic Line Rating Solution: Deployment Opportunities for the Power Transmission Grid of Vietnam

Dynamic Line Rating Solution: Deployment Opportunities for the Power Transmission Grid of Vietnam

Optimizing Grid With Dynamic Line Rating of Conductors: A Comprehensive Review

Dynamic line rating forecasting algorithm for a secure power system network

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