NREL Collaborates with SWAY on Offshore Wind Demonstration (Fact Sheet)
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| Total Pages | : 0 |
| Release | : 2012 |
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NWTC researchers gain valuable data from one of the first floating offshore wind prototypes.
Demonstration Of Nrel Modeling Capability To Design The Next Generation Of Floating Offshore Wind Turbines With Stiesdal And Magellan Wind Cooperative Research And Development Final Report Crada Number Crd 19 00787
Download Demonstration Of Nrel Modeling Capability To Design The Next Generation Of Floating Offshore Wind Turbines With Stiesdal And Magellan Wind Cooperative Research And Development Final Report Crada Number Crd 19 00787 full books in PDF, epub, and Kindle. Read online free Demonstration Of Nrel Modeling Capability To Design The Next Generation Of Floating Offshore Wind Turbines With Stiesdal And Magellan Wind Cooperative Research And Development Final Report Crada Number Crd 19 00787 ebook anywhere anytime directly on your device. Fast Download speed and no annoying ads. We cannot guarantee that every ebooks is available!
NREL Software Aids Offshore Wind Turbine Designs (Fact Sheet)
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| Total Pages | : 0 |
| Release | : 2013 |
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NREL researchers are supporting offshore wind power development with computer models that allow detailed analyses of both fixed and floating offshore wind turbines. While existing computer-aided engineering (CAE) models can simulate the conditions and stresses that a land-based wind turbine experiences over its lifetime, offshore turbines require the additional considerations of variations inwater depth, soil type, and wind and wave severity, which also necessitate the use of a variety of support-structure types. NREL's core wind CAE tool, FAST, models the additional effects of incident waves, sea currents, and the foundation dynamics of the support structures.
New Modeling Tool Analyzes Floating Platform Concepts for Offshore Wind Turbines (Fact Sheet)
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| Total Pages | : 0 |
| Release | : 2011 |
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Researchers at the National Renewable Energy Laboratory (NREL) developed a new complex modeling and analysis tool capable of analyzing floating platform concepts for offshore wind turbines. The new modeling tool combines the computational methodologies used to analyze land-based wind turbines with the comprehensive hydrodynamic computer programs developed for offshore oil and gas industries. Thisnew coupled dynamic simulation tool will enable the development of cost-effective offshore technologies capable of harvesting the rich offshore wind resources at water depths that cannot be reached using the current technology.
NREL Computer Models Integrate Wind Turbines with Floating Platforms (Fact Sheet)
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| Total Pages | : 0 |
| Release | : 2011 |
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Far off the shores of energy-hungry coastal cities, powerful winds blow over the open ocean, where the water is too deep for today's seabed-mounted offshore wind turbines. For the United States to tap into these vast offshore wind energy resources, wind turbines must be mounted on floating platforms to be cost effective. Researchers at the National Renewable Energy Laboratory (NREL) aresupporting that development with computer models that allow detailed analyses of such floating wind turbines.
Floating Offshore Wind Energy
| Author | : Joao Cruz |
| Publisher | : Springer |
| Total Pages | : 345 |
| Release | : 2016-08-20 |
| Genre | : Technology & Engineering |
| ISBN | : 3319293982 |
This book provides a state-of-the-art review of floating offshore wind turbines (FOWT). It offers developers a global perspective on floating offshore wind energy conversion technology, documenting the key challenges and practical solutions that this new industry has found to date. Drawing on a wide network of experts, it reviews the conception, early design stages, load & structural analysis and the construction of FOWT. It also presents and discusses data from pioneering projects. Written by experienced professionals from a mix of academia and industry, the content is both practical and visionary. As one of the first titles dedicated to FOWT, it is a must-have for anyone interested in offshore renewable energy conversion technologies.
Wind Energy R&D Collaboration between NIRE and NREL: Cooperative Research and Development Final Report, CRADA Number CRD-11-437
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| Total Pages | : 0 |
| Release | : 2015 |
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This work includes, but is not limited to, research and development of joint technology development and certification efforts in the wind power sector; providing access to commercial wind farm and federal facilities to enhance R and D; identification of workforce development best practices. This work will be done at Contractor and Participant facilities.
NREL Assesses National Design Standards for Offshore Wind (Fact Sheet)
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| Total Pages | : 0 |
| Release | : 2014 |
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Report summarizes regulations, standards, and guidelines for the design and operation of offshore wind projects in the United States.
New Framework Transforms FAST Wind Turbine Modeling Tool (Fact Sheet)
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| Total Pages | : 0 |
| Release | : 2014 |
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A recent overhaul of the tool makes it a powerful, robust, and flexible modeling software to aid the development of innovative wind and water power technologies.
Reliability-Based Optimization of Floating Wind Turbine Support Structures
| Author | : Mareike Leimeister |
| Publisher | : Springer Nature |
| Total Pages | : 336 |
| Release | : 2023-01-01 |
| Genre | : Technology & Engineering |
| ISBN | : 3030968898 |
This book pursues the ambitious goal of combining floating wind turbine design optimization and reliability assessment, which has in fact not been done before. The topic is organized into a series of very ambitious objectives, which start with an initial state-of-the-art review, followed by the development of high-fidelity frameworks for a disruptive way to design next generation floating offshore wind turbine (FOWT) support structures. The development of a verified aero-hydro-servo-elastic coupled numerical model of dynamics for FOWTs and a holistic framework for automated simulation and optimization of FOWT systems, which is later used for the coupling of design optimization with reliability assessment of FOWT systems in a computationally and time-efficient manner, has been an aim of many groups internationally towards implementing a performance-based/goal-setting approach in the design of complex engineering systems. The outcomes of this work quantify the benefits of an optimal design with a lower mass while fulfilling design constraints. Illustrating that comprehensive design methods can be combined with reliability analysis and optimization algorithms towards an integrated reliability-based design optimization (RBDO) can benefit not only the offshore wind energy industry but also other applications such as, among others, civil infrastructure, aerospace, and automotive engineering.
An Integrated Nonlinear Wind-Waves Model for Offshore Wind Turbines
| Author | : Enzo Marino |
| Publisher | : Firenze University Press |
| Total Pages | : 232 |
| Release | : 2010 |
| Genre | : Coastal engineering |
| ISBN | : 8866550515 |
This thesis presents a numerical model capable of simulating offshore wind turbines exposed to extreme loading conditions. External condition-based extreme responses are reproduced by coupling a fully nonlinear wave kinematic solver with a hydro-aero-elastic simulator. First, a two-dimensional fully nonlinear wave simulator is developed. The transient nonlinear free surface problem is formulated assuming the potential theory and a high-order boundary element method is implemented to discretize Laplace's equation. For temporal evolution a second-order Taylor series expansion is used. The code, after validation with experimental data, is successfully adopted to simulate overturning plunging breakers which give rise to dangerous impact loads when they break against wind turbine substructures. Emphasis is then placed on the random nature of the waves. Indeed, through a domain decomposition technique a global simulation framework embedding the numerical wave simulator into a more general stochastic environment is developed. The proposed model is meant as a contribution to meet the more and more pressing demand for research in the offshore wind energy sector as it permits taking into account dangerous effects on the structural response so as to increase the global structural safety level.
