A Multi-Objective Optimization Framework for Offshore Wind Farm Layouts and Electric Infrastructures

Rodrigues, Sílvio; Restrepo, Carlos; Katsouris, George; Pinto, R. Teixeira; Soleimanzadeh, Maryam; Bosman, Peter A. N.; Bauer, Pavol

doi:10.3390/en9030216

Cited by 36 publications

(28 citation statements)

References 42 publications

(105 reference statements)

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“…This is achieved by selecting bandwidth of the OCC such that it is 10 times smaller than the bandwidth of the ICC. As presented in [32], the OCC PI controller parameters are given as:…”

Section: Control Layout Of Sst-voltage Source Converetermentioning

confidence: 99%

Design of Three Phase Solid State Transformer Deployed within Multi-Stage Power Switching Converters

Tahir¹,

Abbas²,

Glăvan³

et al. 2019

Preprint

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This paper presents a symmetrical topology for the design of solid-state transformer, made up of power switching converters, to replace conventional bulky transformers. The proposed circuitry not only reduces the overall size but also provides power flow control with the ability to be interfaced with renewable energy resources (RESs) to fulfill the future grid requirements at consumer end. Solid state transformer provides bidirectional power flow with variable voltage and frequency operation and has the ability to maintain unity power factor, and current total harmonic distortion (THD) for any type of load within defined limits of IEEE standard. Solid State Transformer offers much smaller size as compared to that of the conventional iron core transformer. MATLAB/Simulink platform is adopted to test the validity of the proposed circuit for different scenarios by providing the simulation results evaluated at 25 kHz switching frequency.

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“…This is achieved by selecting bandwidth of the OCC such that it is 10 times smaller than the bandwidth of the ICC. As presented in [32], the OCC PI controller parameters are given as:…”

Section: Control Layout Of Sst-voltage Source Converetermentioning

confidence: 99%

Design of Three Phase Solid State Transformer Deployed within Multi-Stage Power Switching Converters

Tahir¹,

Abbas²,

Glăvan³

et al. 2019

Preprint

View full text Add to dashboard Cite

show abstract

“…These approaches have similarly, also not considered the irregular seabed exclusion areas for intra-array cables which arise from both bathymetric and regulatory constraints that the developer may face at sites. As these exclusion areas are often non-convex polygons in shape, their accurate inclusion in previous work has proven challenging (Bauer and Lysgaard 2015;Dutta and Overbye 2013;Lindahl et al 2013;Rodrigues et al 2016).…”

Section: Electrical Infrastructure Designmentioning

confidence: 99%

Offshore wind farm layout optimization using particle swarm optimization

Pillai

Chick

Johanning

et al. 2018

J. Ocean Eng. Mar. Energy

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This article explores the application of a wind farm layout optimization framework using a particle swarm optimizer to three benchmark test cases. The developed framework introduces an increased level of detail characterizing the impact that the wind farm layout can have on the levelized cost of energy by modelling the wind farm's electrical infrastructure, annual energy production, and cost as functions of the wind farm layout. Using this framework, this paper explores the application of a particle swarm optimizer to the wind farm layout optimization problem considering three different levels of wind farm constraint faced by modern wind farm developers. The particle swarm optimizer is found to yield improvements in the layout with respect to the levelized cost of energy for the three benchmark cases when compared to two past studies. This highlights both applicability of the particle swarm optimizer to the problem and the ways in which a wind farm developer could make use of the present framework in the development and design of future wind farms.

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“…In addition, a hop-indexed integer programming formulation to achieve the optimization of the string topology was introduced by Bauer et al [14], which replaced the graph theory method, by constructing a connection matrix combined with a random algorithm. Furthermore, Rodrigues et al [15] developed a multi-objective optimization method framework for network topologies and corresponding electrical facilities that took into account a large number of engineering details.…”

Section: Introductionmentioning

confidence: 99%

“…The number and location of substations have a significant impact on the connection topology, and several studies aimed to obtain the optimal match between these two factors [16][17][18][19][20][21][22][23][24]. In these studies, the shortest cable length [17,18], minimal investment [15], highest gain [19], and a minimal energy loss [20] were the optimization objectives, and the substation's spatial coordinates were used as variables. These were combined with the optimization algorithm to obtain the best substation location and the corresponding matching topology structure.…”

Section: Introductionmentioning

confidence: 99%

An Integration Optimization Method for Power Collection Systems of Offshore Wind Farms

Wang

Tang

et al. 2019

Energies

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The traditional power collection system design separately optimizes the connection topology and the cable cross sections, which may result in the inherent shortcoming of lacking the most economical solutions. In this pursuit, the present work envisages the development of an integrated design method for general wind farm power collection systems, which integrated the coupling random fork tree coding, union-find set loop identification, current and voltage drop calculation models, and a high performance optimization algorithm. The proposed coupling random fork tree coding, for the first time, realized the coupling code of the substation location, connection topology, and cable cross sections, providing the basis for the integration design of the power collection system. The optimization results for discrete and regular wind farms indicated that the proposed integration method achieved the best match of topology, substation location, and the cable cross sections, thus presenting the most economical scheme of the power collection system. Compared to the traditional two-step methods, the integration method used more branches while acquiring them, to maintain the lower number of wind turbines in each branch. Furthermore, it also employed large cross-section cables to reduce the energy loss caused by the impedance in the topology, thereby resulting in a slight increased cable cost; however, the total cost was minimized. The proposed method is very versatile and suitable for the optimization of power collection systems containing any number of wind turbines and substations, and can be combined with any evolutionary algorithm.

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A Multi-Objective Optimization Framework for Offshore Wind Farm Layouts and Electric Infrastructures

Cited by 36 publications

References 42 publications

Design of Three Phase Solid State Transformer Deployed within Multi-Stage Power Switching Converters

Design of Three Phase Solid State Transformer Deployed within Multi-Stage Power Switching Converters

Offshore wind farm layout optimization using particle swarm optimization

An Integration Optimization Method for Power Collection Systems of Offshore Wind Farms

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