SCORCH JIP - Feedback on MIC and Pitting Corrosion from Field Recovered Mooring Chain Links

Mooring systems that are used to secure position keeping of floating offshore oil and gas facilities are subject to deterioration processes, such as pitting corrosion and fatigue crack growth. Past investigations show that pitting corrosion has a significant effect on reducing the fatigue resistance of mooring chain links. In situ inspections are essential to monitor the development of the corrosion condition of the components of mooring systems and ensure sufficient structural safety. Unfortunately, offshore inspection campaigns require large financial commitments. As a consequence, inspecting all structural components is unfeasible. This article proposes to use value of information analysis to rank identified inspection alternatives. A Bayesian Network is proposed to model the statistical dependence of the corrosion deterioration among chain links at different locations of the mooring system. This is used to efficiently update the estimation of the corrosion condition of the complete mooring system given evidence from local observations and to reassess the structural reliability of the system. A case study is presented to illustrate the application of the framework.

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Adaptable legged-magnetic adhesion tracked wheel robotic platform for misaligned mooring chain climbing and inspection

Industrial Robot the international journal of robotics research and application ◽

10.1108/ir-04-2018-0074 ◽

2018 ◽

Vol 45 (5) ◽

pp. 634-646 ◽

Cited By ~ 1

Author(s):

Mahesh Dissanayake ◽

Tariq Pervez Sattar ◽

Shehan Lowe ◽

Ivan Pinson ◽

Tat-hean Gan

Keyword(s):

Offshore Structures ◽

Daily Basis ◽

Robotic Platform ◽

Destructive Testing ◽

Content Type ◽

Integrity Assessment ◽

Human Operators ◽

Chain Links ◽

Mooring Chain ◽

Magnetic Adhesion

Purpose Mooring chains used to stabilise offshore floating platforms are often subjected to harsh environmental conditions on a daily basis, i.e. high tidal waves, storms, etc. Therefore, the integrity assessment of chain links is vital, and regular inspection is mandatory for offshore structures. The development of chain climbing robots is still in its infancy due to the complicated climbing structure presented by mooring chains. The purpose of this paper is to establish an automated climbing technique for mooring chain inspection. Design/methodology/approach This paper presents a Cartesian legged tracked-wheel crawler robot developed for mooring chain inspection. The proposed robot addresses the misalignment condition of the mooring chains which is commonly evident in in situ conditions. Findings The mooring chain link misalignment is investigated mathematically and used as a design parameter for the proposed robot. The robot is validated with laboratory-based climbing experiments. Practical implications Chain breaking can lead to vessel drift and serious damage such as riser rupture, production shutdown and hydrocarbon release. Currently, structural health monitoring of chain links is conducted using either remotely operated vehicles which come at a high cost or by manual means which increase the danger to human operators. The robot can be used as a platform to convey equipment, i.e. tools for non-destructive testing/evaluation applications. Originality/value This study has upgraded a previously designed magnetic adhesion tracked-wheel mooring chain climbing robot to address the misalignment issues of operational mooring chains. As a result of this study, the idea of an orthogonally placed Cartesian legged-magnetic adhesion tracked wheel robotic platform which can eliminate concerns related to the misaligned mooring chain climbing has been established.

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Fatigue Performance of High Strength and Large Diameter Mooring Chain in Seawater

Volume 3: Structures, Safety, and Reliability ◽

10.1115/omae2019-95984 ◽

2019 ◽

Cited By ~ 1

Author(s):

Yan-Hui Zhang ◽

Philip Smedley

Keyword(s):

Large Diameter ◽

High Strength ◽

Crack Size ◽

Fatigue Tests ◽

Fatigue Performance ◽

Link Failures ◽

Fatigue Design ◽

Steel Grades ◽

Chain Links ◽

Mooring Chain

Abstract Fatigue design recommendations provided by API RP 2SK, ISO 19901-7 and DNVGL-OS-E301 for studless chain links are based on data of steel grades R3 and R4 and mainly of link diameter of 76mm. Mooring systems utilising larger diameter links and higher strength steels (e.g. grade R5) are now in operation. Consequently, industry expressed a need for fatigue test data in seawater of higher steel grade and larger diameter chain to confirm whether the existing fatigue design guidance is applicable. A joint industry project (JIP) was launched by TWI to investigate fatigue performance of high strength and large diameter mooring chain in free corrosion seawater. A test rig was designed and manufactured which was capable of testing studless mooring chain links up to 127mm link diameter under tension-tension loading. Twenty-three full-scale fatigue tests were conducted on high strength steel grades (R4 and R5) and larger diameter chains (76mm and 127mm) generating 72 link failures. Magnetic particle inspections (MPI) were carried out to characterise the location of cracking, crack size and crack growth rate. This paper describes the results obtained in the JIP.

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Fracture mechanics analysis for mooring chain links subjected to out-of-plane bending (OPB)

Marine Structures ◽

10.1016/j.marstruc.2020.102740 ◽

2020 ◽

Vol 71 ◽

pp. 102740

Author(s):

Xutian Xue ◽

Nian-Zhong Chen ◽

Yongchang Pu ◽

Xifeng Gao

Keyword(s):

Fracture Mechanics ◽

Mechanics Analysis ◽

Out Of Plane ◽

Plane Bending ◽

Chain Links ◽

Mooring Chain

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Out-of-Plane Bending Testing of Chain Links

24th International Conference on Offshore Mechanics and Arctic Engineering: Volume 3 ◽

10.1115/omae2005-67353 ◽

2005 ◽

Cited By ~ 6

Author(s):

Cecil Melis ◽

Phillipe Jean ◽

Pedro Vargas

Keyword(s):

Empirical Relationship ◽

Chain Link ◽

Out Of Plane ◽

Bending Stresses ◽

Test Frame ◽

Scale Test ◽

Plane Bending ◽

A Chain ◽

Chain Links ◽

Mooring Chain

Several mooring chains of an off-loading buoy failed after only 8 months of service. These chains were designed according to conventional fatigue assessment using API RP 2SK T-N curves to a fatigue life or 20 years with a factor of safety equal to 3 on life. Of particular interest is that the mooring chain failure underwent significant mooring chain motions that caused interlink rotations. Although traditionally neglected, these interlink rotations, when combined with significant chain tensions can cause bending stresses in the chain links. In this paper we identify a mechanism, here identified as Out-of-Plane Bending (OPB) that explains the extensive fatigue damage causing the mooring chains of the off-loading buoy to fail. A full scale test frame was constructed that has the capacity of applying inter-link rotation to a pre-tensioned chain. Although the test frame limits the number of links that can be tested together as a chain, a significant amount of testing was performed for the following chain sizes: 1. 81 mm Studded Grade R3S. 2. 107 mm Studdless Grade RQ3. 3. 124 mm Studless Grade R4. 4. 146 mm Studless Grade RQ4. Various pretension levels were used, with instrumentation to extract link angles and chain link stresses. In this paper the OPB mechanism is explained, and the test frame and results are presented. An empirical relationship is found to predict the OPB stresses in the chain links as a function of pretension and inter-link rotation. The OPB stress relationship obtained was applied to the failed mooring chain of the off-loading buoy with reasonable agreement. To comply with Single Buoy Moorings (SBM) requirements addressing publication of internal research, many of the graphs included in this paper have had the stress values removed from the y-axis. However, with SBM’s management approval, some numerical references to stress amplitudes remain in the text. Overall, this limitation does not detract from the study, trends are evident and relevant comparisons can be made.

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Out-Of-Plane Bending Stiffnesses in Offshore Mooring Chain Links Based on Conventional and Advanced Numerical Simulation Techniques

Journal of Ocean Engineering and Technology ◽

10.26748/ksoe.2018.6.32.5.297 ◽

2018 ◽

Vol 32 (5) ◽

pp. 297-309

Author(s):

Joonmo Choung ◽

Jae-bin Lee ◽

Young Hun Kim

Keyword(s):

Numerical Simulation ◽

Simulation Techniques ◽

Out Of Plane ◽

Plane Bending ◽

Chain Links ◽

Mooring Chain

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Mooring Fatigue Assessment Evaluating Chain Twist and Out-of-Plane Bending for a Semi-submersible

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4046856 ◽

2020 ◽

Vol 142 (6) ◽

Author(s):

Xutian Xue ◽

Nian-Zhong Chen ◽

Yongchang Pu

Keyword(s):

Fracture Mechanics ◽

Comparative Study ◽

Mooring System ◽

Safety Factors ◽

Fatigue Assessment ◽

Pure Tension ◽

Out Of Plane ◽

Plane Bending ◽

Chain Links ◽

Mooring Chain

Abstract A mooring fatigue assessment for mooring chain links of a semi-submersible in Offshore West Africa (OWA) is presented. Three cases that mooring chain links are subjected to pure tension, out-of-plane bending (OPB), and torque are considered in the assessment. For the case that mooring chain links are subjected to pure tension, a comparative study on S–N curves, T–N curves, and fracture mechanics (FM)-based mooring system fatigue analyses is made, and the results show that the fatigue lives predicted by these three approaches are generally comparable if the safety factors suggested by API and DNVGL are applied to T–N curves and S–N curves based approaches. For the cases that mooring chain links are subjected to the OPB and torque, the investigation shows that fatigue lives of mooring chain links are decreased significantly due to the OPB effects, while the decline of fatigue lives of mooring chain links happens when the twist angles are more than 10 deg.

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Fatigue Testing of Out-of-Plane Bending Mechanism of Chain Links

Volume 3: Safety and Reliability; Materials Technology; Douglas Faulkner Symposium on Reliability and Ultimate Strength of Marine Structures ◽

10.1115/omae2006-92488 ◽

2006 ◽

Cited By ~ 2

Author(s):

Lucile Rampi ◽

Pedro Vargas

Keyword(s):

Fatigue Testing ◽

Empirical Relationship ◽

Fatigue Tests ◽

Full Scale ◽

Fatigue Performance ◽

Special Focus ◽

Out Of Plane ◽

Plane Bending ◽

Chain Links ◽

Mooring Chain

Three years ago, several mooring chains of an off-loading buoy failed after only 8 months of service. These chains were designed according to conventional fatigue assessment using API RP 2SK T-N curves to a fatigue life or 20 years with a factor of safety equal to 3 on life. Of particular interest is that the mooring chain failure underwent significant mooring chain motions that caused interlink rotations. Although traditionally neglected, these interlink rotations, when combined with significant chain tensions can cause bending stresses in the chain links (See Figure 1). This recently identified phenomena, Out-of-Plane Bending (OPB), explains the extensive fatigue damage causing the mooring chains of the off-loading buoy to fail [3][4][5]. References [3] and [4] document full scale tests of the OPB mechanism using a full scale test frame with the ability of applying inter-link rotation to a pre-tensioned chain. This testing confirmed that interlink rotations with a constant tension load can result in significantly high stresses. OPB stresses were measured on four different chain sizes of various grades: 1) 81 mm Studded Grade R3S, 2) 107 mm Stud-less Grade RQ3, 3) 124 mm Stud-less Grade R4, and 4) 146 mm Stud-less Grade RQ4, Grade R3 in [3] and [4], but no actual fatigue tests were performed. References [3] and [5] document analytical and computational efforts to explain and quantify the OPB stresses. In this paper, special focus is placed on obtaining actual fatigue failures of chains from OPB loading. Smaller chain sizes (40 mm) are used to accommodate the load limits of the testing frame. To mimic the actual loading as close as possible, sub size models of actual chainhawses were used in the testing. Two chainhawses were used: 1) the chainhawse has internal curvature where a link rests on the intrados, similar to offloading buoy that failed in eight months, and 2) a straight chainhase, a design that is in use today with demonstrated improved fatigue performance over the curved chainhawse. OPB stresses are measured and reported. Fatigue loading in the OPB mode was applied for several configurations. The two chainhawse exhibit very different stress levels and fatigue performance. An empirical relationship previously reported in [3][4][5] is compared to the measured OPB stresses with mixed results. Although limited in number, the fatigue tests indicate that overall the chain fatigue performance is at or above the B1 DnV curve. The BS B1 curve is also compared.

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