Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study
Large-scale production systems such as offshore oil platform and subsea production system (SPS) usually have the characteristics of long service life, high economic value, high risk, and difficult to maintain. Existing reliability-based design methods are difficult to meet the requirements of high r...
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Institute of Electrical and Electronics Engineers Inc.
2023
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oai:scholars.utp.edu.my:379972023-12-11T03:09:50Z http://scholars.utp.edu.my/id/eprint/37997/ Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study Gao, C. Cai, B. Sheng, C. Liu, Y. Liu, K. Khan, J.A. Shi, M. Liu, Z. Ji, R. Large-scale production systems such as offshore oil platform and subsea production system (SPS) usually have the characteristics of long service life, high economic value, high risk, and difficult to maintain. Existing reliability-based design methods are difficult to meet the requirements of high reliability, risk control, and maintenance economy in their full life cycle. In order to solve this problem, a life cycle structural integrity design method integrating operational reliability, risk controllability, and maintenance economy is proposed. Based on the existing reliability design theory, risk and maintenance are added, and the time dimension is extended to the full life cycle of structures. The interactions between the system, the subsystem, and the components are considered. Prediction of component degradation using existing mature theoretical methods or experimental studies is adopted. The advanced first-order second moment method is applied to calculate the structural reliability. Risk assessment and maintenance are based on the results of the reliability analysis. The SPS of an oilfield in the South China Sea is the application scenario and data is collected, and a surface-controlled subsurface safety valve is designed using the proposed method. IEEE Institute of Electrical and Electronics Engineers Inc. 2023 Article NonPeerReviewed Gao, C. and Cai, B. and Sheng, C. and Liu, Y. and Liu, K. and Khan, J.A. and Shi, M. and Liu, Z. and Ji, R. (2023) Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study. IEEE/ASME Transactions on Mechatronics. pp. 1-11. ISSN 10834435 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85177031796&doi=10.1109%2fTMECH.2023.3329831&partnerID=40&md5=8e6cbc83fdc9f36fb0a9345ab87ac392 10.1109/TMECH.2023.3329831 10.1109/TMECH.2023.3329831 10.1109/TMECH.2023.3329831 |
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Large-scale production systems such as offshore oil platform and subsea production system (SPS) usually have the characteristics of long service life, high economic value, high risk, and difficult to maintain. Existing reliability-based design methods are difficult to meet the requirements of high reliability, risk control, and maintenance economy in their full life cycle. In order to solve this problem, a life cycle structural integrity design method integrating operational reliability, risk controllability, and maintenance economy is proposed. Based on the existing reliability design theory, risk and maintenance are added, and the time dimension is extended to the full life cycle of structures. The interactions between the system, the subsystem, and the components are considered. Prediction of component degradation using existing mature theoretical methods or experimental studies is adopted. The advanced first-order second moment method is applied to calculate the structural reliability. Risk assessment and maintenance are based on the results of the reliability analysis. The SPS of an oilfield in the South China Sea is the application scenario and data is collected, and a surface-controlled subsurface safety valve is designed using the proposed method. IEEE |
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Gao, C. Cai, B. Sheng, C. Liu, Y. Liu, K. Khan, J.A. Shi, M. Liu, Z. Ji, R. |
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Gao, C. Cai, B. Sheng, C. Liu, Y. Liu, K. Khan, J.A. Shi, M. Liu, Z. Ji, R. Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study |
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Gao, C. Cai, B. Sheng, C. Liu, Y. Liu, K. Khan, J.A. Shi, M. Liu, Z. Ji, R. |
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Gao, C. |
title |
Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study |
title_short |
Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study |
title_full |
Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study |
title_fullStr |
Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study |
title_full_unstemmed |
Life Cycle Structural Integrity Design Approach for the Components of Subsea Production System: SCSSV as a Case Study |
title_sort |
life cycle structural integrity design approach for the components of subsea production system: scssv as a case study |
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Institute of Electrical and Electronics Engineers Inc. |
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2023 |
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http://scholars.utp.edu.my/id/eprint/37997/ https://www.scopus.com/inward/record.uri?eid=2-s2.0-85177031796&doi=10.1109%2fTMECH.2023.3329831&partnerID=40&md5=8e6cbc83fdc9f36fb0a9345ab87ac392 |
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