Reliability-Based Transmission Reinforcement Planning Associated With Large-Scale Wind Farms

Billinton, R.; Wangdee, Wijarn

doi:10.1109/tpwrs.2006.889126

Cited by 219 publications

(118 citation statements)

References 22 publications

Supporting

Mentioning

116

Contrasting

Unclassified

Order By: Relevance

“…The former is considered obeying Weibull distribution [12], and the latter is a piecewise function of wind speed [13] as shown in (1). …”

Section: Wind Power Distribution Characteristics Of Wind Outputmentioning

confidence: 99%

Flexible Transmission Expansion Planning for Integrating Wind Power Based on Wind Power Distribution Characteristics

Wang¹,

Wang²,

Zeng³

et al. 2015

Journal of Electrical Engineering and Technology

View full text Add to dashboard Cite

-Traditional transmission planning usually caters for rated wind power output. Due to the low occurrence probability of nominal capacity of wind power and huge investment in transmission, these planning methods will leads to low utilization rates of transmission lines and poor economic efficiency. This paper provides a novel transmission expansion planning method for integrating largescale wind power. The wind power distribution characteristics of large-scale wind power output and its impact on transmission planning are analyzed. Based on the wind power distribution characteristics, this paper proposes a flexible and economic transmission planning model which saves substantial transmission investment through spilling a small amount of peak output of wind power. A methodology based on Benders decomposition is used to solve the model. The applicability and effectiveness of the model and algorithm are verified through a numerical case.

show abstract

“…The former is considered obeying Weibull distribution [12], and the latter is a piecewise function of wind speed [13] as shown in (1). …”

Section: Wind Power Distribution Characteristics Of Wind Outputmentioning

confidence: 99%

Flexible Transmission Expansion Planning for Integrating Wind Power Based on Wind Power Distribution Characteristics

Wang¹,

Wang²,

Zeng³

et al. 2015

Journal of Electrical Engineering and Technology

View full text Add to dashboard Cite

show abstract

“…This paradigm is associated with the proliferation of power systems technologies that promise to enhance its flexibility amid uncertain operating environments, for example through the influx of renewable generation. Examples of flexible concepts include: Demand Side Management [8], Special Protection System with ICTs [9], wind farms [10], FACTs [11] and Dynamic Thermal Rating (DTR) [12].…”

Section: Introductionmentioning

confidence: 99%

Network planning evaluation implementing time varying thermal ratings

Kapetanaki

Kopsidas

Tumelo-Chakonta

et al. 2014

2014 International Conference on Probabilistic Methods Applied to Power Systems (PMAPS)

View full text Add to dashboard Cite

Abstract-Contemporary transmission networks are not fully utilized due to increased uncertainty and security buffers resulting mainly from the inefficient operation and planning, currently based on conservative predetermined thermal ratings. However, in a smart operation scheme, which considers time varying thermal ratings of transmission assets, operation and planning could be optimized to facilitate the proliferation of generation expansion projects while maintaining required levels of reliability. This paper presents a methodology which enhances the current methods of network element ratings by incorporating a more detailed modelling of the overhead line (OHL) properties. Three thermal rating models, static (STR), seasonal (SeTR) and time varying (TVTR), are implemented for comparative studies, under both deterministic and probabilistic frameworks with an aim to identify the most cost-effective and optimal flexible network operation plan in today's congestion-driven and competitive power markets. In addition, the effects of line outages on transmission losses in the electric power networks are presented, quantifying the transmission losses in a realistic manner due to the incorporation of real thermal ratings. The IEEE 24-bus RTS is used under sequential modeling to validate the methodological enhancements and to evaluate network performance. The system annual operating costs are reduced when using the proposed TVTR model.

show abstract

“…This paradigm is associated with the proliferation of power systems technologies that promise to enhance its flexibility amid uncertain operating environments, for example, through the influx of renewable generation. Examples of flexible solutions include: ageing of overhead line (OHL) [9], demand side management [10], special protection systems with ICTs [11], wind farms [12], FACTs [12] and time varying thermal rating (TVTR) [13].…”

Section: Introductionmentioning

confidence: 99%

Electricity Network Reliability Planning and Evaluation Considering Flexible Solutions

Tumelo-Chakonta

Kapetanaki

Kopsidas³

2014

MedPower 2014

View full text Add to dashboard Cite

Abstract-Amid contemporary electric power system planning and operating regimes, the transmission network is pervasively operated, and planned, with time-invariant thermal ratings (TITRs) of transmission assets. This results in a transmission network which is not fully (and efficiently) utilized. In the future, however, power systems will be increasingly expected to transition into a smart grid-in order to be more efficient and economical. Consequently, the network will pervasively have to be operated, and planned, with time-varying thermal ratings (TVTRs) of transmission assets. Moreover, the smart grid will further facilitate the inclusion of demand response (DR) into the transmission network planning process. Therefore, this paper aims to discuss the need for, and implications of, adopting novel electricity network reliability planning and evaluation methodical approaches which consider flexible solutions (i.e., DR and TVTR). Subsequently, in order to encourage the adoption of these proposed approaches, the quantification of the benefits from increased, efficient and economical transmission utilization considering flexible concepts such as non-ageing TVTR, controlled-ageing of transmissions assets due to advanced operation of TVTR, and DR within transmission system are performed-and evaluated. The IEEE 24-bus RTS is used under sequential Monte Carlo simulation (SMCS) modelling of the reliability evaluation process in order to validate the proposed methodological enhancements and to evaluate network performance.

show abstract

Reliability-Based Transmission Reinforcement Planning Associated With Large-Scale Wind Farms

Cited by 219 publications

References 22 publications

Flexible Transmission Expansion Planning for Integrating Wind Power Based on Wind Power Distribution Characteristics

Flexible Transmission Expansion Planning for Integrating Wind Power Based on Wind Power Distribution Characteristics

Network planning evaluation implementing time varying thermal ratings

Electricity Network Reliability Planning and Evaluation Considering Flexible Solutions

Contact Info

Product

Resources

About