Assessment of the Integrity of the PVDF Barrier in Unbonded Flexible Pipes

The polymer barrier is the most important component in unbonded flexible pipe, providing the leak-tight boundary for transporting hydrocarbon medium. Premature failure of the barrier during service can be costly and may lead to disastrous environmental consequences. Design of the barrier for 25 years’ service integrity is therefore a major requirement in the flexible pipe design process. However, the API design code does not give a specific procedure for the design of the barrier and is mainly concerned with the design of other layers in the pipe which are intended to provide integrity to the polymer barrier. The selection of barrier material depends on many factors including the service temperature/pressure range and pipe bending requirements. Polyvinylidene fluoride (PVDF) is used as a barrier material in cases where high pressure and relatively high temperature applications are involved. However, a hard polymer such as PVDF can be susceptible to crazing and cracking under specific conditions and therefore the use of PVDF in flexible pipe barriers requires critical consideration of the above issues. This paper discusses the general design requirements of a single layer barrier, and different barriers in relation to static and dynamic applications. The details of a qualification test program performed to establish service integrity of single layer Solef 60512 PVDF barriers is discussed. The unique testing facilities developed to test the integrity of the barrier are presented.

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An Analytical Model to Predict the Bending Behavior of Unbonded Flexible Pipes

Journal of Ship Research ◽

10.5957/jsr.2013.57.3.171 ◽

2013 ◽

Vol 57 (03) ◽

pp. 171-177

Author(s):

Leilei Dong ◽

Yi Huang ◽

Qi Zhang ◽

Gang Liu

Keyword(s):

Bending Moment ◽

Bending Stiffness ◽

Nonlinear Formulation ◽

Flexible Pipe ◽

Flexible Pipes ◽

Bending Behavior ◽

Interlayer Slip ◽

Unbonded Flexible Pipes ◽

Relationship Of ◽

Theoretical Results

Analytical formulations are presented to determine the bending moment-curvature relationship of a helical layer in unbonded flexible pipes. Explicit expressions describing the variation of both bending stiffness and moment as a function of the applied curvature are given. The approach takes into account the nonlinearity of the response caused by the interlayer slip. The contribution of local bending and torsion of individual helical elements to the bending behavior of helical layers is included. Theoretical results for a typical unbonded flexible pipe using the nonlinear formulation for helical layers are compared with experimental data from the available literature. Encouraging correlations are found and the importance of the initial interlayer pressures is seen. The influence of local bending and torsion of individual helical elements on the bending behavior of the entire pipe is also evaluated. The results show that the inclusion of this local behavior significantly influences the full-slip bending stiffness.

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Qualification Approach to Unbonded Flexible Pipes With Fibre Reinforced Armour Layer

23rd International Conference on Offshore Mechanics and Arctic Engineering, Volume 2 ◽

10.1115/omae2004-51175 ◽

2004 ◽

Author(s):

Jan Rytter

Keyword(s):

Offshore Structure ◽

Flexible Pipe ◽

Load Bearing ◽

Compression Load ◽

Metal Parts ◽

Analysis Tools ◽

Industry Standards ◽

Flexible Pipes ◽

Unbonded Flexible Pipes ◽

Load And Resistance Factor

The future water depth capabilities for unbonded flexible pipes is being pushed by NKT Flexibles I/S through the development of an innovative flexible pipe structure, taking full advantage of the material characteristics of metallic, polymeric and fibre reinforced materials. The fluid tight liner and possible insulation of this pipe structure are supported by an inner armour, capable of carrying the external hydrostatic pressure, clamp and crushing loads, as well as axial compression load, and an outer armour, consisting of two cross wound layers of carbon/epoxy composites, carrying the internal pressure as well as end cap forces and applied tension. A permeable and radially flexible outer layer protects the composite armour. Combining known and well-proven flexible pipe technologies and new solutions for materials, structure and functionality of the flexible pipe, positions this future product outside the present industry standards for flexible pipes, e.g. API-17J. The analysis tools used for the conventional flexible pipes are validated by NKT according to the API-17J specification. The API-17J describes load cases and corresponding allowable utilization ratios, stated as design criteria. However, this approach is not directly applicable to the composite pipe, where the same analysis tools will be used, but the material in one of the two primary load bearing layers is made of fibre reinforced polymer, a material class not covered by the API allowable utilization factors. The DNV offshore standard DNV-OS-C501 considers any offshore structure in which the load bearing material is a composite. An accompanying Recommended Practice DNV-RP-F202 for composite risers has also been issued, but is not applicable to the composite flexible pipe. The design equations of the DNV standard are formulated in the so-called Load and Resistance Factor Design (LRFD) format, where partial safety factors are applied to the load effects and to the resistance variables that enter the design equations. The DNV standard DNV-OS-C501 covers composite materials and composite metal interfaces of a structure, metal parts should be designed according to other relevant standards. The API standard can therefore be used for the metal parts. One of the challenges in using this combined approach is the different ways loads are defined in the two standards. In short, this will result in a conventional API design check of the inner armour, the polymer layers, and the secondary layers, whereas the composite tensile armour, special intermediate layers and the interfaces will be analyzed with composite specific tools based on the criteria derived from the DNV standard. The qualification procedure is described and exemplified in the following.

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Controlling Factors of Carcass Fatigue in Unbonded Flexible Pipes

Volume 5A: Pipelines, Risers, and Subsea Systems ◽

10.1115/omae2019-96310 ◽

2019 ◽

Author(s):

Upul S. Fernando ◽

Andrew P. Roberts ◽

Michelle Davidson

Keyword(s):

Fatigue Failure ◽

Failure Modes ◽

Dynamic Stress ◽

External Pressure ◽

Controlling Factors ◽

Flexible Pipe ◽

Flexible Pipes ◽

Innermost Layer ◽

Key Features ◽

Unbonded Flexible Pipes

Abstract Carcass, the innermost layer of a flexible pipe structure is designed to prevent the collapse of the pressure sheath due to external pressure. Weakness, damage or failure of the carcass layer can result in collapse with associated loss of production and potentially serious risk to pipe integrity and hydrocarbon leakage to the environment. Avoiding carcass failure in service is therefore an essential consideration during the design of unbonded flexible pipes. Carcass failure is rare in service. This paper highlights the three possible failure modes and presents further analysis on the fatigue failure mode, relevant to dynamic service. Two key features of carcass manufacture are identified as causes for dynamic stress; locking of the carcass profile due to extended pitch and polymer ingress within the carcass cavity. Guidelines for the design of carcass profiles, setting safe pitch limits and appropriate barrier profile controls to mitigate carcass fatigue failure in dynamic service are presented.

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Analysis of Structural Parameters for Unbonded Flexible Pipes

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.652-654.1514 ◽

2013 ◽

Vol 652-654 ◽

pp. 1514-1519

Author(s):

Zhi Bo Li ◽

Hui Xu ◽

Gui Zhen Zhang

Keyword(s):

Structural Parameters ◽

Steel Strip ◽

Complex Structure ◽

Flexible Pipe ◽

Complex Deformation ◽

Flexible Pipes ◽

Bending Behavior ◽

Unbonded Flexible Pipes ◽

Walled Cylinder ◽

Nonuniform Material

Due to the complex structure and nonuniform material of unbonded flexible pipes, an elastic thin-walled cylinder model and a helical steel strip model were established respectively to simulate different layers based on the specific structure form and parameters. Quasi-static incremental load was adopted to identify the structural parameters which had significant effects on the axial, radial and bending behavior of the pipes during the complex deformation. Sensitivity of these parameters were also analysed. The conclusion in this paper could provide guaidance for the design of unbonded flexible pipe.

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Helical Wire Behavior of Unbonded Flexible Pipes Under Bending

Volume 5A: Pipeline and Riser Technology ◽

10.1115/omae2015-41134 ◽

2015 ◽

Author(s):

Yutian Lu ◽

Huibin Yan ◽

Yong Bai ◽

Peng Cheng

Keyword(s):

Finite Element ◽

Finite Element Model ◽

Axial Strain ◽

Bending Moment ◽

Element Model ◽

Flexible Pipe ◽

Slip Mechanism ◽

Flexible Pipes ◽

Bending Behavior ◽

Unbonded Flexible Pipes

The bending behavior of unbonded flexible pipe is governed by the response of the helical wires in the tensile armor to bending. The behavior of the helical wire, especially the axial strain, is influenced by the slip mechanism as a result of an increasing curvature under bending. In the present paper, two limit curves are considered with a certain curvature. A 3-D finite element model using ABAQUS is developed to simulate the practical behavior of the helical wires under bending. By comparing the FEA and theoretical results, a basic conclusion about the real slip path of the helical wire between two limit curves is introduced. A hysteretic bending moment-curvature relationship induced by the slip mechanism is obtained from the finite element model as well.

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Axial mechanical experiments of unbonded flexible pipes

Petroleum Science ◽

10.1007/s12182-020-00504-3 ◽

2020 ◽

Vol 17 (5) ◽

pp. 1400-1410

Author(s):

Jun-Peng Liu ◽

Murilo Augusto Vaz ◽

Rong-Qi Chen ◽

Meng-Lan Duan ◽

Irving Hernandez

Keyword(s):

Global Analysis ◽

Axial Stiffness ◽

Loading Frequency ◽

Structural Damping ◽

Flexible Pipe ◽

Friction Forces ◽

Damping Behavior ◽

Flexible Pipes ◽

Unbonded Flexible Pipes ◽

Tensile Experiment

Abstract Axial structural damping behavior induced by internal friction and viscoelastic properties of polymeric layers may have an inevitable influence on the global analysis of flexible pipes. In order to characterize this phenomenon and axial mechanical responses, a full-scale axial tensile experiment on a complex flexible pipe is conducted at room temperature, in which oscillation forces at different frequencies are applied on the sample. The parameters to be identified are axial strains which are measured by three kinds of instrumentations: linear variable differential transformer, strain gauge and camera united particle-tracking technology. The corresponding plots of axial force versus axial elongation exhibit obvious nonlinear hysteretic relationship. Consequently, the loss factor related to the axial structural damping behavior is found, which increases as the oscillation loading frequency grows. The axial strains from the three measurement systems in the mechanical experiment indicate good agreement, as well as the values of the equivalent axial stiffness. The damping generated by polymeric layers is relatively smaller than that caused by friction forces. Therefore, it can be concluded that friction forces maybe dominate the axial structural damping, especially on the conditions of high frequency.

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A Methodology to Predict the Remaining Fatigue Life of a Flexible Pipe With Broken Tensile Armor Wires

Volume 6A: Pipeline and Riser Technology ◽

10.1115/omae2014-23969 ◽

2014 ◽

Author(s):

José Renato M. de Sousa ◽

Fernando Jorge M. de Sousa ◽

Marcos Q. de Siqueira ◽

Luís Volnei S. Sagrilo ◽

George Campello ◽

...

Keyword(s):

Fatigue Life ◽

Experimental Investigations ◽

Flexible Pipe ◽

Premature Failure ◽

Flexible Pipes ◽

Remaining Fatigue Life

In this work, an approach to predict the remaining fatigue life of flexible pipes with damages in their tensile armor wires is proposed. This approach relies on a previous proposed approach to calculate the fatigue life of intact flexible pipes. By relying on results from theoretical and experimental investigations, the previous proposed expressions were modified in order to account for damages in the tensile armor wires of these structures. Furthermore, the computation of the fatigue life was also modified in order to account for results from inspections in these pipes thus allowing the estimative of the remaining fatigue life of the pipe. The use of this methodology is illustrated in the analysis of a 9.13″ flexible pipe considering different conditions in its outer tensile armor wires: intact and with one up to ten wires broken along time. The results obtained indicate that the rupture of the tensile armor wires may significantly reduce the fatigue life of flexible pipes and, consequently, may lead to the premature failure of the pipe.

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Verification Scheme for Unbonded Flexible Pipes: Definition, Implementation and Reflection of API 17J

Volume 5A: Pipelines, Risers, and Subsea Systems ◽

10.1115/omae2017-61916 ◽

2017 ◽

Author(s):

Fabien Conti ◽

François Migeon ◽

Aymeric David

Keyword(s):

Manufacturing Processes ◽

High Complexity ◽

Flexible Pipe ◽

Verification Scheme ◽

Type Approval ◽

Flexible Pipes ◽

Normative Requirements ◽

Qualification Testing ◽

Unbonded Flexible Pipes ◽

Verification Methodology

The present paper is related to the verification of unbonded flexible pipes designed and manufactured as per API 17J [1]. Back in the early nineties, in response to the needs of the industry for better quality, reliability and safety in unbonded flexible pipe products, Bureau Veritas established an innovative verification scheme relying not only on qualification testing, but also on the assessment of design methods, materials as well as manufacturing processes. This approach has proven particularly relevant considering several specificities of the flexible pipe industry: no ‘on-the-shelf’ design (each pipe being designed for project specific conditions), manufacturer specific local design methodologies, specific materials and manufacturing methods, high complexity and cost of testing. This paper presents the verification methodology, its application as well as its ability to embody the latest normative requirements given in [1]. The specificity of the verification scheme, which consists in a breakdown between a Type Approval phase and a project phase, is also presented.

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Experimental Comparison of Tensile Armor Wires Using Strain Gages and Fiber Bragg Grating Techniques

Volume 6A: Pipeline and Riser Technology ◽

10.1115/omae2014-23706 ◽

2014 ◽

Author(s):

Felipe Arêas Vargas ◽

Diogo Garcia Lopes ◽

Paulo Pedro Kenedi ◽

Judimar Clevelario ◽

Fabio de Souza Pires

Keyword(s):

Fatigue Life ◽

Fiber Bragg Grating ◽

High Strain ◽

Experimental Comparison ◽

Bragg Grating ◽

Strain Gages ◽

Flexible Pipe ◽

Flexible Pipes ◽

Unbonded Flexible Pipes ◽

Monitoring Technologies

Flexible pipes are being installed and operated in more marginal and challenging offshore conditions related to deep-water environments. Especially important is the accurate assessment of the remaining life of a flexible riser so operators can avoid costly premature change outs. So, emerging inspection and monitoring technologies are being several developed to achieve a comprehensive flexible pipes integrity approach. For unbonded flexible pipes, the primary challenges include fatigue life, collapse, axial compression loading of the tensile armor wires and end fitting development. This paper is related to end fitting development area, due to necessary folding/unfolding process on the tensile armor wires during pipe assembling. This mechanical forming generates high levels of plastic strain on the wires, which may therefore reduce the fatigue life of the flexible pipe in the field. This paper presents an analysis of the high strain level involved in the folding and unfolding process along tensile armour wire, using the strain gages and fiber Bragg grating techniques. Besides that, this paper describes a comparison analysis, which correlates the performance of both methods to assess high strain levels.

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Erosion Analysis for the Carcass of Unbonded Flexible Pipes

10.21203/rs.3.rs-1194029/v1 ◽

2022 ◽

Author(s):

Jianxing Yu ◽

Haoda Li ◽

Yang Yu ◽

Xin Liu ◽

Weipeng Xu ◽

...

Keyword(s):

Erosion Rate ◽

Ocean Engineering ◽

Cfd Simulations ◽

Premature Failure ◽

Erosion Prediction ◽

Flexible Pipes ◽

Oil Exploitation ◽

Erosion Models ◽

Unbonded Flexible Pipes ◽

Improved Model

Abstract At present, unbonded flexible pipes (UFPs) are widely used in ocean engineering for oil exploitation. In practice, erosion will lead to premature failure of pipelines. There is a lack of researches on the erosion of interlock carcass of UFPs. As the authority in the field of offshore engineering, DET NORSKE VERITAS(DNV) suggested a way to estimate the erosion rate of pipes, however, it does not study the erosion mechanism of UFPs in detail and the relevant parameters are not specified. This paper modifies erosion prediction of UFPs based on a user defined Fortran subroutine. A series of CFD simulations have been conducted, and three widely used erosion models were used for comparative verification. The effect of geometric shape on erosion rate has been carefully studied. and the effect of velocity, particle size, and concentration are also studied to verify the reliability of the improved model.

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