Influence of load interaction and hydrogen on fatigue crack growth behavior in steel pipelines under mean load pressure fluctuations

Tehinse, Olayinka; Lamborn, Lyndon; Chevil, Karina; Gamboa, Erwin; Chen, Weixing

doi:10.1111/ffe.13414

Cited by 7 publications

(4 citation statements)

References 34 publications

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“…A similar phenomenon was also observed in small-scale tests: no crack growth was detected in the specimen subjected to a monotonic loading even at the highest stress intensity factor used in the study [33]. It is therefore suggested in [34][35][36] that the growth of NNpHSCC cracks can be better characterized by corrosion fatigue (CF) than SCC. CF is one type of EAC that occurs under the synergistic effects of corrosion and cyclic stress [11,37].…”

Section: Nnphscc On Pipelinessupporting

confidence: 69%

“…Many researchers have claimed that cyclic stress is essential to the growth of NNpHSCC cracks [32][33][34][35][36]. Full-scale experiments showed that the absence of cyclic components in the loading spectra led to non-growth of NNpHSCC cracks in pipe specimens and that controlling pressure fluctuations in pipelines resulted in reduced crack growth [32].…”

Section: Nnphscc On Pipelinesmentioning

confidence: 99%

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A review of crack growth models for near-neutral pH stress corrosion cracking on oil and gas pipelines

Sun

Zhou

Kang

2021

J Infrastruct Preserv Resil

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This paper presents a review of four existing growth models for near-neutral pH stress corrosion cracking (NNpHSCC) defects on buried oil and gas pipelines: Chen et al.’s model, two models developed at the Southwest Research Institute (SwRI) and Xing et al.’s model. All four models consider corrosion fatigue enhanced by hydrogen embrittlement as the main growth mechanism for NNpHSCC. The predictive accuracy of these growth models is investigated based on 39 crack growth rates obtained from full-scale tests conducted at the CanmetMATERIALS of Natural Resources Canada of pipe specimens that are in contact with NNpH soils and subjected to cyclic internal pressures. The comparison of the observed and predicted crack growth rates indicates that the hydrogen-enhanced decohesion (HEDE) component of Xing et al.’s model leads to on average reasonably accurate predictions with the corresponding mean and coefficient of variation (COV) of the observed-to-predicted ratios being 1.06 and 61.2%, respectively. The predictive accuracy of the other three models are markedly poorer. The analysis results suggest that further research is needed to improve existing growth models or develop new growth models to facilitate the pipeline integrity management practice with respect to NNpHSCC.

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Section: Nnphscc On Pipelinessupporting

confidence: 69%

Section: Nnphscc On Pipelinesmentioning

confidence: 99%

A review of crack growth models for near-neutral pH stress corrosion cracking on oil and gas pipelines

Sun

Zhou

Kang

2021

J Infrastruct Preserv Resil

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“…These cracks will converge with the main cracks to accelerate the corrosion FCP, so that the corrosion FCP can be completed at a lower number of cycles. 37 The corrosion FCP is strongly dependent on loading frequency. At a lower loading frequency, the longer the corrosion solution contacts the fresh metal at the crack tip in each cycle, the greater the corrosion damage.…”

Section: Mechanism Analysismentioning

confidence: 99%

Effect of corrosion on the fatigue crack propagation properties of butt weld with G20Mn5QT cast steel and Q355D steel in 3.5‐wt% NaCl solution

Han,

Li,

et al. 2023

Fatigue Fract Eng Mat Struct

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The corrosion fatigue crack propagation (FCP) of the butt weld with G20Mn5QT cast steel and Q355D steel in 3.5‐wt% NaCl solution was investigated experimentally. Considering the influences of stress ratio and loading frequency, the corrosion FCP rate curve was obtained. The results indicated that the corrosion FCP rate in the corrosion environment is three times that in air. Increasing the stress ratio or decreasing the loading frequency will increase the corrosion FCP rate. The fracture morphology of the specimens in the corrosion environment had more corrosion pits and intergranular characteristics due to anodic dissolution than that in air. Anodic dissolution and hydrogen embrittlement jointly promoted the corrosion FCP of butt weld in simulated seawater. The corrosion FCP rate model was established considering the effects of stress ratio and loading frequency.

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“…HE results in a loss of ductility, which is evident from the occurrence of brittle fracture features observed on the fractured surface. 15,18,19 Several viable mechanisms have been proposed to give insight into this phenomenon, including "hydrogen-enhanced local plasticity" (HELP), "hydrogen-enhanced decohesion" (HEDE), "hydrogenenhanced strain-induced vacancy" formation (HESIV), hydride formation, and "adsorption-induced dislocation emission" (AIDE). [20][21][22][23][24] Out of the proposed HE mechanisms, the HELP and HEDE models of HE mechanisms are mostly accepted.…”

Section: Introductionmentioning

confidence: 99%

The fatigue crack growth behavior of hydrogenated 9Cr‐1Mo steel: An experimental and numerical study

Bharati,

Maity,

Singh

et al. 2024

Fatigue Fract Eng Mat Struct

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This research investigates the fatigue crack evolution in P91 steel through experiments and extended finite element method (XFEM) simulation for as‐received and hydrogenated conditions. Hydrogen pre‐charging is performed using a constant current electrochemical method in 1 M sulfuric acid solution. The study compares the experimental fatigue crack growth rate (FCGR) of hydrogenated and as‐received conditions and employs an XFEM simulation to replicate FCGR. The results of the experiments reveal an increased FCGR in hydrogenated specimens. Fracture surface analysis confirms the co‐occurrence of the “hydrogen‐enhanced localized plasticity” (HELP) and “hydrogen‐enhanced decohesion” (HEDE) mechanism (HELP+HEDE, HEDE>HELP). The simulation results closely align with the experimental findings, validating the model's accuracy. Consequently, these findings are the basis for proposing a damage tolerance approach‐based numerical algorithm. This algorithm allows the prediction of component integrity by considering a known crack length. Furthermore, fracture toughness (KIQ) was experimentally evaluated to enhance the understanding of the material's mechanical properties.

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Influence of load interaction and hydrogen on fatigue crack growth behavior in steel pipelines under mean load pressure fluctuations

Cited by 7 publications

References 34 publications

A review of crack growth models for near-neutral pH stress corrosion cracking on oil and gas pipelines

A review of crack growth models for near-neutral pH stress corrosion cracking on oil and gas pipelines

Effect of corrosion on the fatigue crack propagation properties of butt weld with G20Mn5QT cast steel and Q355D steel in 3.5‐wt% NaCl solution

The fatigue crack growth behavior of hydrogenated 9Cr‐1Mo steel: An experimental and numerical study

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