A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations

Lifting the latest generation offshore wind turbines using floating crane vessels is extremely challenging. This comes with an elevated risk of blades impacting the tower or surrounding structures due to excessive crane tip motions from wave induced vessel motions. The wind turbine blades are primar...

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Published in:Volume 10: Ocean Renewable Energy
Main Authors: Verma, Amrit Shankar, Haselbach, Philipp Ulrich, Vedvik, Nils Petter, Gao, Zhen
Format: Article in Journal/Newspaper
Language:English
Published: American Society of Mechanical Engineers 2018
Subjects:
Arctic
Online Access:https://orbit.dtu.dk/en/publications/a4599f53-7de7-4107-8861-6a748a659348
https://doi.org/10.1115/OMAE2018-78218
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spelling ftdtupubl:oai:pure.atira.dk:publications/a4599f53-7de7-4107-8861-6a748a659348 2023-12-10T09:43:56+01:00 A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations Verma, Amrit Shankar Haselbach, Philipp Ulrich Vedvik, Nils Petter Gao, Zhen 2018 https://orbit.dtu.dk/en/publications/a4599f53-7de7-4107-8861-6a748a659348 https://doi.org/10.1115/OMAE2018-78218 eng eng American Society of Mechanical Engineers info:eu-repo/semantics/closedAccess Verma , A S , Haselbach , P U , Vedvik , N P & Gao , Z 2018 , A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations . in ASME 2018 37th International Conference on Ocean, Offshore and Arctic Engineering . vol. 10 , OMAE2018-78218 , American Society of Mechanical Engineers , 37th International Conference on Ocean, Offshore and Artic Engineering (OMAE2018) , Madrid , Spain , 17/06/2018 . https://doi.org/10.1115/OMAE2018-78218 contributionToPeriodical 2018 ftdtupubl https://doi.org/10.1115/OMAE2018-78218 2023-11-15T23:57:56Z Lifting the latest generation offshore wind turbines using floating crane vessels is extremely challenging. This comes with an elevated risk of blades impacting the tower or surrounding structures due to excessive crane tip motions from wave induced vessel motions. The wind turbine blades are primarily made of composite materials and thus are extremely vulnerable to impact loads causing complex damages and failure modes. One of the most critical damage type for wind turbine blades is delamination because delaminations cannot always be visually detected but can cause significant strength and stiffness reductions. An explicit structural response based approach was proposed in the previous work which is used to derive response based operational limits for single blade lifting operation using floating vessels considering probability of contact/impact and damages in the blade. An assessment of such impact induced damages on the blade was mentioned which includes modelling and predicting damages in the blade for different contact scenarios representing lifting operations in different sea states along with post impact residual strength estimation. This would require an efficient damage assessment methodology which can be utilized in practice with acceptable accuracy along with a reasonable computational cost. In this work, a simplified global-local based damage assessment methodology is presented. The paper focusses on 'shell-to-solid submodelling' based impact damage prediction along with a brief outline of 'shell-solid coupling' based residual strength study. The paper further presents the submodelling technique for impact investigations on DTU 10 MW blade section for a case when a projectile impacts the leading edge. Intraply damage mode based on Hashin failure criteria and Puck's action plane theory was utilized as VUMAT in Abaqus-Explicit along with surface based cohesive behavior to model the interlaminar failure mode. Finally, the damages and failure modes in the blade including impact induced delaminations are ... Article in Journal/Newspaper Arctic Technical University of Denmark: DTU Orbit Volume 10: Ocean Renewable Energy
institution Open Polar
collection Technical University of Denmark: DTU Orbit
op_collection_id ftdtupubl
language English
description Lifting the latest generation offshore wind turbines using floating crane vessels is extremely challenging. This comes with an elevated risk of blades impacting the tower or surrounding structures due to excessive crane tip motions from wave induced vessel motions. The wind turbine blades are primarily made of composite materials and thus are extremely vulnerable to impact loads causing complex damages and failure modes. One of the most critical damage type for wind turbine blades is delamination because delaminations cannot always be visually detected but can cause significant strength and stiffness reductions. An explicit structural response based approach was proposed in the previous work which is used to derive response based operational limits for single blade lifting operation using floating vessels considering probability of contact/impact and damages in the blade. An assessment of such impact induced damages on the blade was mentioned which includes modelling and predicting damages in the blade for different contact scenarios representing lifting operations in different sea states along with post impact residual strength estimation. This would require an efficient damage assessment methodology which can be utilized in practice with acceptable accuracy along with a reasonable computational cost. In this work, a simplified global-local based damage assessment methodology is presented. The paper focusses on 'shell-to-solid submodelling' based impact damage prediction along with a brief outline of 'shell-solid coupling' based residual strength study. The paper further presents the submodelling technique for impact investigations on DTU 10 MW blade section for a case when a projectile impacts the leading edge. Intraply damage mode based on Hashin failure criteria and Puck's action plane theory was utilized as VUMAT in Abaqus-Explicit along with surface based cohesive behavior to model the interlaminar failure mode. Finally, the damages and failure modes in the blade including impact induced delaminations are ...
format Article in Journal/Newspaper
author Verma, Amrit Shankar
Haselbach, Philipp Ulrich
Vedvik, Nils Petter
Gao, Zhen
spellingShingle Verma, Amrit Shankar
Haselbach, Philipp Ulrich
Vedvik, Nils Petter
Gao, Zhen
A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations
author_facet Verma, Amrit Shankar
Haselbach, Philipp Ulrich
Vedvik, Nils Petter
Gao, Zhen
author_sort Verma, Amrit Shankar
title A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations
title_short A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations
title_full A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations
title_fullStr A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations
title_full_unstemmed A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations
title_sort global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations
publisher American Society of Mechanical Engineers
publishDate 2018
url https://orbit.dtu.dk/en/publications/a4599f53-7de7-4107-8861-6a748a659348
https://doi.org/10.1115/OMAE2018-78218
genre Arctic
genre_facet Arctic
op_source Verma , A S , Haselbach , P U , Vedvik , N P & Gao , Z 2018 , A global-local damage assessment methodology for impact damage on offshore wind turbine blades during lifting operations . in ASME 2018 37th International Conference on Ocean, Offshore and Arctic Engineering . vol. 10 , OMAE2018-78218 , American Society of Mechanical Engineers , 37th International Conference on Ocean, Offshore and Artic Engineering (OMAE2018) , Madrid , Spain , 17/06/2018 . https://doi.org/10.1115/OMAE2018-78218
op_rights info:eu-repo/semantics/closedAccess
op_doi https://doi.org/10.1115/OMAE2018-78218
container_title Volume 10: Ocean Renewable Energy
_version_ 1784887127462379520

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