Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method

One of the many challenges faced in fatigue assessment today is determining the stress concentration factor 'SCF' associated with the dents, which are used with appropriate SN curves to determine the fatigue life. This historically has been determined empirically or by using finite element...

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Main Authors: Durowoju, Michael, Pu, Yongchang, Benson, Simon, Race, Julia
Format: Conference Object
Language:unknown
Published: 2016
Subjects:
Hydraulic engineering. Ocean engineering
Arctic
Online Access:https://strathprints.strath.ac.uk/56875/
id ftustrathclyde:oai:strathprints.strath.ac.uk:56875
record_format openpolar
spelling ftustrathclyde:oai:strathprints.strath.ac.uk:56875 2024-04-28T08:04:30+00:00 Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method Durowoju, Michael Pu, Yongchang Benson, Simon Race, Julia 2016-06-17 https://strathprints.strath.ac.uk/56875/ unknown Durowoju, Michael and Pu, Yongchang and Benson, Simon and Race, Julia <https://strathprints.strath.ac.uk/view/author/668729.html> (2016 <https://strathprints.strath.ac.uk/view/year/2016.html>) Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method. In: 35th International Conference on Ocean, Offshore and Arctic Engineering <https://strathprints.strath.ac.uk/view/publications/35th_International_Conference_on_Ocean,_Offshore_and_Arctic_Engineering.html>, 2016-06-19 - 2016-06-24. Hydraulic engineering. Ocean engineering Conference or Workshop Item PeerReviewed 2016 ftustrathclyde 2024-04-10T01:05:58Z One of the many challenges faced in fatigue assessment today is determining the stress concentration factor 'SCF' associated with the dents, which are used with appropriate SN curves to determine the fatigue life. This historically has been determined empirically or by using finite element analysis. This paper presents finite element analysis on a parametric range of industry pipes (both offshore and onshore) to extract SCF data used for fatigue assessment. The parametric dataset focuses on the effects of pipe geometry, dent geometry, material properties and pressure cycling on the prediction of the fatigue life. This parametric dataset will eventually be used to develop an algorithm for fatigue prediction using an artificial neural network. Two types of indenters (Dome and Bar) are used to simulate circumferential and longitudinal dents. Four different dent depths ranging from 2% d/D to 10% d/D are also simulated to investigate the effect of dent geometry. Four different pipe grades (X42, X65, X80 and X100) are analysed to investigate the effect of pipe materials on dent fatigue. Similarly, eight pipes with different diameter to thickness ratio D/t ranging from 18-96 are analyzed to investigate the effect of pipe geometry. Stresses are computed at both 50% SMYS and 72% SMYS to investigate the effect of pressure variation. The results from this study indicate that longitudinal dents have higher stress concentrations compared to circumferential dents of similar dent depth. Results also indicate that the re-round dent depth (i.e. dent depth after pressurization) increases with increasing D/t and increasing dent depth. Similarly, the pipe material has a major effect on the fatigue life. Pipes with higher material strength have higher stress concentration compared to pipes with lower strength of similar dent depth. The stress concentration factors SCF associated with the dents are then computed. Conference Object Arctic University of Strathclyde Glasgow: Strathprints
institution Open Polar
collection University of Strathclyde Glasgow: Strathprints
op_collection_id ftustrathclyde
language unknown
topic Hydraulic engineering. Ocean engineering
spellingShingle Hydraulic engineering. Ocean engineering
Durowoju, Michael
Pu, Yongchang
Benson, Simon
Race, Julia
Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method
topic_facet Hydraulic engineering. Ocean engineering
description One of the many challenges faced in fatigue assessment today is determining the stress concentration factor 'SCF' associated with the dents, which are used with appropriate SN curves to determine the fatigue life. This historically has been determined empirically or by using finite element analysis. This paper presents finite element analysis on a parametric range of industry pipes (both offshore and onshore) to extract SCF data used for fatigue assessment. The parametric dataset focuses on the effects of pipe geometry, dent geometry, material properties and pressure cycling on the prediction of the fatigue life. This parametric dataset will eventually be used to develop an algorithm for fatigue prediction using an artificial neural network. Two types of indenters (Dome and Bar) are used to simulate circumferential and longitudinal dents. Four different dent depths ranging from 2% d/D to 10% d/D are also simulated to investigate the effect of dent geometry. Four different pipe grades (X42, X65, X80 and X100) are analysed to investigate the effect of pipe materials on dent fatigue. Similarly, eight pipes with different diameter to thickness ratio D/t ranging from 18-96 are analyzed to investigate the effect of pipe geometry. Stresses are computed at both 50% SMYS and 72% SMYS to investigate the effect of pressure variation. The results from this study indicate that longitudinal dents have higher stress concentrations compared to circumferential dents of similar dent depth. Results also indicate that the re-round dent depth (i.e. dent depth after pressurization) increases with increasing D/t and increasing dent depth. Similarly, the pipe material has a major effect on the fatigue life. Pipes with higher material strength have higher stress concentration compared to pipes with lower strength of similar dent depth. The stress concentration factors SCF associated with the dents are then computed.
format Conference Object
author Durowoju, Michael
Pu, Yongchang
Benson, Simon
Race, Julia
author_facet Durowoju, Michael
Pu, Yongchang
Benson, Simon
Race, Julia
author_sort Durowoju, Michael
title Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method
title_short Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method
title_full Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method
title_fullStr Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method
title_full_unstemmed Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method
title_sort fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method
publishDate 2016
url https://strathprints.strath.ac.uk/56875/
genre Arctic
genre_facet Arctic
op_relation Durowoju, Michael and Pu, Yongchang and Benson, Simon and Race, Julia <https://strathprints.strath.ac.uk/view/author/668729.html> (2016 <https://strathprints.strath.ac.uk/view/year/2016.html>) Fatigue assessment of pipeline with plain dents under cyclic pressure loading using finite element method. In: 35th International Conference on Ocean, Offshore and Arctic Engineering <https://strathprints.strath.ac.uk/view/publications/35th_International_Conference_on_Ocean,_Offshore_and_Arctic_Engineering.html>, 2016-06-19 - 2016-06-24.
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