Harmonics in Offshore Wind Power Plants
Harmonics in Offshore Wind Power Plants

Author: Jakob Bærholm Glasdam

Publisher: Springer

Published: 2015-10-26

Total Pages: 219

ISBN-13: 3319264761

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This book reports on cutting-edge findings regarding harmonic stability assessment for offshore wind power plants (OWPPs). It presents a timely investigation of the harmonic stability interaction between OWPPs on the one hand, and associated control systems in the wind turbines and other power electronic devices in the transmission system on the other. The book particularly focuses on voltage-sourced converter high-voltage direct current (VSC-HVDC) and static compensator (STATCOM) systems. From a practical perspective, the book reports on appropriate models for power electronic devices. It describes how the frequency domain evaluation approach can be assessed by comparing results obtained with the Nyquist stability criterion against the more detailed electromagnetic transient based model realized in the PSCAD/EMTDC simulation program. The book also provides a concise yet complete overview of large OWPPs that incorporate power electronic devices on a broad scale, and highlights selected challenges and opportunities in the context of real-world applications.

Harmonic Interactions in HVAC-connected Offshore Windfarms
Harmonic Interactions in HVAC-connected Offshore Windfarms

Author: Lara Depla

Publisher:

Published: 2019

Total Pages:

ISBN-13:

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The connection of new Offshore Wind Power Plants (OWPP) in the existing Dutch transmission system gives rise to many technical challenges. For example, it is expected that harmonic issues will occur more frequently when the number of large offshore wind farms increases. Cases have already been reported in which resonances were triggered in HVDC- or HVAC-connected OWPPs and the wind farms had to be taken out of operation. Recently developed offshore wind farms contain wind turbines which are connected to the system with a full-scale back-to-back Voltage Source Converter, which is responsible for inserting harmonics into the system. The onshore grid is also responsible for injecting harmonics. Since the wind turbine converter is an active element, where the control loops actively determine its electrical behaviour, it interacts with other converters and with the background harmonics inserted from the network. The initial harmonic emissions and the harmonic interactions can lead to an excitation of a resonance frequency. The cables, transformers, capacitor banks and filters are responsible for shifting the resonance frequencies. Especially a long HV export cable can strongly alter the resonance frequencies of the system. To analyze the impact of connecting an increasing amount of wind farms to the same Point of Connection on the harmonic emission levels, a Harmonic Impact Assessment was performed for three offshore wind farms in the Dutch North Sea. Since the wind turbine converters are active elements, its electrical behaviour can be captured with an equivalent impedance, or Norton Equivalent. This Norton Equivalent was utilized in the Harmonic Impact Assessment to include the active behaviour of the converter. When comparing this novel approach to the conventional methodology, the expected peaks in the Total Harmonic Distortion (THD) are shifted. When an increasing amount of wind farms is connected, peaks in the THD shifted to lower frequencies. Then, depending on the specific profile of the background harmonics and the impedance profiles of the grid and the OWPP, this translates into the disappearance of appearance of an exceedance of the emission limits. The effect of connecting two wind farms to the same Point of Connection instead of a single wind farm on the harmonic stability, was assessed. Frequency sweeps of the two assessed wind farms made clear that the presence of an additional filter in a wind farm leads to a small shift in the series resonance points. When multiple wind farms are connected instead of solely one wind farm, series resonance frequencies are shifted to lower frequencies and less damping appears to be present in the system. Lastly, the postive-net damping criteria was applied to assess the stability of a system in which a varying number of wind farms is connected. Time-domain simulations in PSCAD were performed to varify the results. It can be concluded that a system becomes less damped, and therefore less stable, when an increasing amount of wind farms is connected. This effect arises since the various wind farms are placed in parallel and the total resistance of the wind farms becomes smaller than the sum of the resistances of each wind farm. Moreover, when less wind turbines are in operation, less damping is present in the system since the resistance of a single OWPP is then decreased.

Harmonic Propagation Studies in Offshore Wind Power Clusters
Harmonic Propagation Studies in Offshore Wind Power Clusters

Author: Marco Vinicio Chavez Baez

Publisher:

Published: 2019

Total Pages: 0

ISBN-13:

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The recent growth of new renewable energy sources has necessitated fresh avenues for research that searches for new methods to optimise the electrical network and reduce power losses. As this issue represents a combinational problem, the larger electrical systems present more complexity - the reason why this problem remains unsolved. This research aims to develop an algorithm that suggests a set of configurations in large offshore wind power clusters to maintain harmonics at levels that let the clusters operate without operational problems caused by harmonics. The major case studies of harmonics in offshore wind farms are focused on the importance of harmonic analysis for obtaining better performance from the design of the components. The interactions between the components of the system affect harmonic performance, which, in turn, may yield adverse effects such as resonances that can cause instability and operational problems that could shut off one or more wind turbines, causing a significant fault if not controlled promptly. Consequently, it is essential to reduce these adverse effects, and it is in this context that this study locates the proposed algorithm. This research pays attention to harmonic minimisation in combination with power losses minimisation, thus implementing an evolutionary algorithm to be applied to offshore wind power clusters. The project is divided into two primary goals: First, developing the objective functions to calculate power flow and harmonic propagation. Second, implementing the objective functions to develop a multi-objective evolutionary algorithm that can minimise harmonic propagation and power losses between the different components of a grid. Once it is obtained a set of better configurations of the offshore wind farm, data is used and helps to the designer to make recommendations for possible control strategies in large offshore wind farm projects that will deliver the offshore capacity generated into the onshore AC grid.

Harmonics in a Wind Power Plant: Preprint
Harmonics in a Wind Power Plant: Preprint

Author:

Publisher:

Published: 2015

Total Pages: 0

ISBN-13:

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Wind power generation has been growing at a very fast pace for the past decade, and its influence and impact on the electric power grid is significant. As in a conventional power plant, a wind power plant (WPP) must ensure that the quality of the power being delivered to the grid is excellent. At the same time, the wind turbine should be able to operate immune to small disturbances coming from the grid. Harmonics are one of the more common power quality issues presented by large WPPs because of the high switching frequency of the power converters and the possible nonlinear behavior from electric machines (generator, transformer, reactors) within a power plant. This paper presents a summary of the most important issues related to harmonics in WPPs and discusses practical experiences with actual Type 1 and Type 3 wind turbines in two WPPs.

Advances in Wind Power
Advances in Wind Power

Author: Rupp Carriveau

Publisher: BoD – Books on Demand

Published: 2012-11-21

Total Pages: 378

ISBN-13: 9535108638

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Today's wind energy industry is at a crossroads. Global economic instability has threatened or eliminated many financial incentives that have been important to the development of specific markets. Now more than ever, this essential element of the world energy mosaic will require innovative research and strategic collaborations to bolster the industry as it moves forward. This text details topics fundamental to the efficient operation of modern commercial farms and highlights advanced research that will enable next-generation wind energy technologies. The book is organized into three sections, Inflow and Wake Influences on Turbine Performance, Turbine Structural Response, and Power Conversion, Control and Integration. In addition to fundamental concepts, the reader will be exposed to comprehensive treatments of topics like wake dynamics, analysis of complex turbine blades, and power electronics in small-scale wind turbine systems.

Renewable Energy Integration in Utility Grids
Renewable Energy Integration in Utility Grids

Author: Om Prakash Mahela

Publisher: Elsevier

Published: 2024-09-23

Total Pages: 400

ISBN-13: 0443190224

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Renewable Energy Integration in Utility Grids: Advances in Power Quality, Protection, Stability, and Flexibility reviews current challenges and technologically driven solutions to mitigate the significant issues associated with increasing renewable resource penetration in utility grid networks. It provides a detailed framework to address significant challenges for high renewable energy integration into the utility grid networks, using intelligent techniques and advanced power electronics technology. Chapters address current advances in the grid integration of wind technology, solar PV systems, solar thermal plants, reactive power management, grid stability, variability, power quality, power system protection, generation-side flexibility, demand-side flexibility, smart monitoring and communication, and regulatory frameworks. - Provides a detailed overview of the core challenges faced by utility grids with high renewable energy penetration, together with potential solutions - Amalgamates highly interdisciplinary technical guidance for optimized design, flexible operation, control, and maintenance in renewable-dominated grids - Draws from the contributions of highly-respected global researchers and practitioners, featuring carefully selected case studies reflecting global practice and perspectives - Provides deep insights on many critical issues pertaining to grid-integrated renewable energy, including flexibility, quality, stability, and protection

Design, Control, and Application of Modular Multilevel Converters for HVDC Transmission Systems
Design, Control, and Application of Modular Multilevel Converters for HVDC Transmission Systems

Author: Kamran Sharifabadi

Publisher: John Wiley & Sons

Published: 2016-10-17

Total Pages: 414

ISBN-13: 1118851560

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Design, Control and Application of Modular Multilevel Converters for HVDC Transmission Systems is a comprehensive guide to semiconductor technologies applicable for MMC design, component sizing control, modulation, and application of the MMC technology for HVDC transmission. Separated into three distinct parts, the first offers an overview of MMC technology, including information on converter component sizing, Control and Communication, Protection and Fault Management, and Generic Modelling and Simulation. The second covers the applications of MMC in offshore WPP, including planning, technical and economic requirements and optimization options, fault management, dynamic and transient stability. Finally, the third chapter explores the applications of MMC in HVDC transmission and Multi Terminal configurations, including Supergrids. Key features: Unique coverage of the offshore application and optimization of MMC-HVDC schemes for the export of offshore wind energy to the mainland. Comprehensive explanation of MMC application in HVDC and MTDC transmission technology. Detailed description of MMC components, control and modulation, different modeling approaches, converter dynamics under steady-state and fault contingencies including application and housing of MMC in HVDC schemes for onshore and offshore. Analysis of DC fault detection and protection technologies, system studies required for the integration of HVDC terminals to offshore wind power plants, and commissioning procedures for onshore and offshore HVDC terminals. A set of self-explanatory simulation models for HVDC test cases is available to download from the companion website. This book provides essential reading for graduate students and researchers, as well as field engineers and professionals who require an in-depth understanding of MMC technology.