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B
backend.orbit.dtu.dk
article
https://backend.orbit.dtu.dk/ws/portalfiles/portal/2714025/oersted-dtu2746.pdf
1 Abstract - This paper compares the commercial simulation tools: PSCAD/EMTDC, PowerFactory, SIMPOW and PSS/E for analysing fault sequences defined in the Danish grid code requirements for wind turbines connected to a voltage level below 100 kV. 0.98 1 1.02 1.04 1.06 1.08 1.1 1.12 1.14 0.5 1 1.5 2 2.5 3 3.5 4 4.5 Two phase to ground short circuit on Bus 1 t [s] Amplitude of the generator current [pu] Power Factory Simpow PSCAD Simpow pos seq (RMS) PSS/E pos seq (RMS) Fig. 9 Generator current during the first 2-phase to ground short circuit The first current overshoot of the EMT simulations is ap-proximately 2.5 times as large as the overshoot of the posi-tive sequence current from the RMS simulation of PSS/E and SIMPOW. 1 1.5 2 2.5 3 3.5 0.99 1 1.01 1.02 1.03 1.04 1.05 Two phase to ground short circuit on Bus 1 Generator speed [pu] t [s] Power Factory Simpow PSCAD Simpow (RMS) PSS/E (RMS) Fig. 11 Speed during both 2-phase to ground short circuits Fig. 12 reveals differences between the speed from the RMS simulations and the EMT simulations.
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link.springer.com
article
https://link.springer.com/article/10.1007/s12541-014-0582-8
by K Kim · 2014 · Cited by 28 — The tool consists of models of aerodynamics, drive train, generator, actuators, and controllers for pitch and yaw controls.
S
simscale.com
article
https://www.simscale.com/blog/wind-turbine-simulation-and-design
# Wind Turbine Simulation and Design. BlogEnergyWind Turbine Simulation and Design. Wind turbines are at the forefront of utilizing this energy as they provide a long-term, cost-effective, and low-maintenance solution for the conversion of wind energy into electricity. Computational Fluid Dynamics (CFD) Finite Element Analysis (FEA) Rotating Machinery Wind Simulation Wind Turbine. It is, therefore, crucial to ensure that wind turbines are designed optimally for their specific operating conditions to extract the maximum possible amount of energy. In this article, we discuss how wind turbine design can be enhanced and accelerated with simulation using CFD and FEA tools to achieve optimal efficiency and performance. ## Wind Turbine Design. There are essentially two types of wind turbines, horizontal-axis wind turbines (HAWT) and vertical-axis wind turbines (VAWT). The vast majority of wind turbines in use today are horizontal-axis types as they have proven to be more efficient than the vertical-axis types. The design of wind turbines has largely to do with the design of the turbine blades.
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en.wikipedia.org
article
https://en.wikipedia.org/wiki/Wind_energy_software
# Wind energy software. Specialized **wind energy software** applications aid in the development and operation of wind farms. The RETScreen software wind power model is designed to evaluate energy production and savings, costs, emission reductions, financial viability and risk for central-grid, isolated-grid and off-grid wind energy projects, for multi-turbine and single-turbine hybrid systems. Developed by the Government of Canada, the software is multilingual, and includes links to wind energy resource maps. The Wind Data Generator (WDG) is a Wind Energy Software tool capable of running WRF (Weather Research and Forecasting) model to create a wind atlas and to generate wind data at resolutions of 3 km to 10 km. The National Wind Technology Center (NWTC), a division of the U.S. National Renewable Energy Laboratory (NREL), has developed many packages which are used by turbine manufacturers and researchers. The open source software QBlade developed by the wind energy research group of Hermann Föttinger Institute of TU Berlin (Chair of Fluid Dynamics) is a BEM code coupled with the airfoil simulation code XFOIL.
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nlr.gov
official
https://www.nlr.gov/wind/data-tools
# Wind Data and Tools. The wind energy researchers, scientists, and analysts working within NLR's National Wind Technology Center and wind energy program maintain open-source data sets and develop multifidelity predictive modeling and simulation capabilities to benefit the wind energy industry. Created using Nalu-Wind simulation code, this visualization of two NLR 5-MW wind turbines demonstrates a turbine wake interaction flow field, which can improve understanding of wind plant performance. The tools formerly hosted on the National Wind Technology Center's archived information portal, an open-source library for wind and water power research, are now included on this page. The software and data are primarily for the benefit of the U.S. government and organizations that collaborate with the U.S. Department of Energy. Others are welcome to use the software and data, but please note that they are meant for professionals with expertise in wind or water power technologies and are subject to a data use disclaimer agreement. The NLR Annual Technology Baseline provides a consistent set of technology cost and performance data for energy analysis.
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cener.com
article
https://www.cener.com/en/offshore-wind-resource
CENER has developed its own in-house tools for numerical simulation of offshore wind energy systems.
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qblade.org
article
https://qblade.org
## Wind Turbine Simulation Software. ## The QBlade Software. QBlade is an advanced multi-physics wind turbine simulation software for comprehensive aero-servo-hydro-elastic design, prototyping, wind farm analysis, and certification of wind turbines. Developed and validated over 15 years, QBlade empowers wind energy researchers, engineers, students, and industry users to create and analyze turbine models with confidence. This image shows different wind turbine designs that were created in the QBlade software. ## Results You Can Rely On. Ensuring the reliability of simulation results is of utmost importance when conducting wind turbine design, optimization or certification tasks. Checkout the**Quick Start Guide,** get QBlade-CE for free from our **Downloads** page (Community Edition for non-commercial use) or **Contact** us to request a trial of QBlade-EE (Enterprise Edition for commercial projects). this image shows the wind turbine design module in QBlade. this image shows the view of wind turbine simulation results in QBlade. this image shows the wind turbine simulation module in QBlade. this image shows a vertical axis wind turbine simulation that is running in QBlade.
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etap.com
article
https://etap.com/product/wind-turbine-generator-software
# Wind Turbine Generator Software. ## Wind Turbine Generator. ## Wind Turbine Generator Analysis. ETAP Wind Turbine Generator includes two approaches for studying wind power systems when combined with the appropriate network analysis capabilities and simulation scenarios:. ### Wind Turbine Generator Software Key Features. Wind farm designers or planners can model and simulate wind turbine generators using any technology type, design wind power collector systems, size underground cables, determine adequacy of system grounding, and more. System planners can represent wind turbine generator as a single machine mathematical model of the entire wind farm to understand the impact of wind penetration in the grid under variability of wind. ETAP Wind Turbine Generator can be used to verify grid connection compliance, steady-state and dynamic simulation of whole wind parks, size collector systems, calculate short circuit current levels, analyzing alternative turbine placement, tuning of control parameters, selection and placement of protective devices, and more. ### Generic Models for Wind Turbine Generators. models for use in power system simulations for wind turbine generators – the Western Electricity. Type 1: Wind Turbine Generator. ### Wind Turbine.