analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf

analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf

This work highlights how the costs and CO2-emissions of land-based wind turbines can be reduced by means of an innovative and material efficient support structure concept. Thereby the yaw system is placed at the tower base, allowing the whole wind turbine tower to be rotated. The potential of a rota...

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Γλώσσα:English
Έκδοση: KIT Scientific Publishing 2021
id oapen-20.500.12657-48827
record_format dspace
spelling oapen-20.500.12657-488272021-05-28T00:57:17Z Analysis of a Rotatable Wind Turbine Tower by means of Aero-Servo-Elastic Load Simulations Struve, Achim Windenergie Turm Drehbar Stahl FAST Wind Tower Rotatable Steel bic Book Industry Communication::T Technology, engineering, agriculture::TN Civil engineering, surveying & building This work highlights how the costs and CO2-emissions of land-based wind turbines can be reduced by means of an innovative and material efficient support structure concept. Thereby the yaw system is placed at the tower base, allowing the whole wind turbine tower to be rotated. The potential of a rotatable inclined lattice tower concept was analysed by means of aero-servo-elastic load simulations in the FAST environment. A balance between different cost aspects revealed significant savings. 2021-05-27T09:28:19Z 2021-05-27T09:28:19Z 2021 book ONIX_20210527_9783731510451_24 2198-7912 9783731510451 https://library.oapen.org/handle/20.500.12657/48827 eng Berichte zum Stahl- und Leichtbau application/pdf n/a analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf KIT Scientific Publishing 10.5445/KSP/1000123255 10.5445/KSP/1000123255 44e29711-8d53-496b-85cc-3d10c9469be9 9783731510451 11 340 Karlsruhe open access
institution OAPEN
collection DSpace
language English
description This work highlights how the costs and CO2-emissions of land-based wind turbines can be reduced by means of an innovative and material efficient support structure concept. Thereby the yaw system is placed at the tower base, allowing the whole wind turbine tower to be rotated. The potential of a rotatable inclined lattice tower concept was analysed by means of aero-servo-elastic load simulations in the FAST environment. A balance between different cost aspects revealed significant savings.
title analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf
spellingShingle analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf
title_short analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf
title_full analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf
title_fullStr analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf
title_full_unstemmed analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf
title_sort analysis-of-a-rotatable-wind-turbine-tower-by-means-of-aero-servo-elastic-load-simulations.pdf
publisher KIT Scientific Publishing
publishDate 2021
_version_ 1771297544492548096

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