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Journal of Chinese Society for Corrosion and protection  2025, Vol. 45 Issue (2): 359-370    DOI: 10.11902/1005.4537.2024.161
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Finite Element Analysis of Local Hydrogen Concentration in Hydrogen Pipeline With Corrosion Defects
CUI Dechun1,2, XIONG Liang1, YU Bangting1, WU Haozhi3, DONG Shaohua3, CHEN Lin3()
1.New Energy Research Department, CNOOC Research Institute Co., Ltd., Beijing 100028, China
2.Shanxi Research Institute of Huairou Laboratory, Taiyuan 030032, China
3.College of Safety and Ocean Engineering, China University of Petroleum, Beijing 102249, China
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CUI Dechun, XIONG Liang, YU Bangting, WU Haozhi, DONG Shaohua, CHEN Lin. Finite Element Analysis of Local Hydrogen Concentration in Hydrogen Pipeline With Corrosion Defects. Journal of Chinese Society for Corrosion and protection, 2025, 45(2): 359-370.

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Abstract  

Deep understanding on the interaction of hydrogen atoms with pipeline steel is crucial for the matter of the integrity and safety in-service of hydrogen pipeline infrastructure, especially for the case when the existing pipelines with corrosion defects were adopted as hydrogen transportation pipeline. Herein, a finite element (FE) model was developed by coupling mechanical- and diffusion-fields in COMSOL Multiphysics, so that the effect of internal pressure, defect location, defect length and depth on the hydrogen diffusion and distribution was assessed. Results demonstrated that internal pressure may induce local stress concentration and non-uniform hydrogen distribution at defect. Hydrogen concentration at defect increases with the internal pressure, but the threshold of hydrogen concentration at internal corrosion defects is lower than that at external corrosion defects, and the corresponding positions of the maximum hydrogen concentration are different for the two defects. Moreover, the defect length and depth also affect the hydrogen concentration threshold and where the hydrogen concentration maximum emerges, but such effects vary depending on whether the corrosion in question is internal or external.
Key words:  corrosion defect      finite element model      hydrogen distribution      X52 steel     
Received:  22 May 2024      32134.14.1005.4537.2024.161
TG111.91  
Corresponding Authors:  CHEN Lin, E-mail: chenlin@cup.edu.cn
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CUI Dechun
XIONG Liang
YU Bangting
WU Haozhi
DONG Shaohua
CHEN Lin

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https://www.jcscp.org/EN/10.11902/1005.4537.2024.161     OR     https://www.jcscp.org/EN/Y2025/V45/I2/359

Fig.1  Schematic diagrams of a pipe segment under internal pressure (a), top and cross-sectional views of a corrosion defect present on the pipe (b), a quarter model used in numerical analysis (c), an internal corrosion defect and an external corrosion defect on the model (d), Schematic diagrams of the left and right edges of internal (e) and external (f) corrosion defect
Fig.2  Mesh of the model: (a) mesh of the whole model, (b) mesh of the region 1 and 2, (c) mesh of the corrosion defect
Fig.3  Maximum von Mises stress, hydrostatic stress and hydrogen concentration at the external corrosion defect and mesh sensitivity analysis
Fig.4  Distributions of von Mises stresses (MPa) at internal (a-c) and external (d-f) corrosion defects under an internal pressure of 6 MPa (a, d), 8 MPa (b, e) and 10 MPa (c, f)
Fig.5  Liner distributions of von Mises stresses along the left edge (a, c) and right edge (b, d) of the internal corrosion defect (a, b) and the external corrosion defect (c, d)
Fig.6  Distributions of hydrostatic stresses (MPa) at internal (a-c) and external (d-f) corrosion defects under an internal pressure of 6 MPa (a, d), 8 MPa (b, e) and 10 MPa (c, f)
Fig.7  Liner distributions of hydrostatic stresses along the left edge (a, c) and right edge (b, d) of the internal corrosion defect (a, b) and the external corrosion defect (c, d)
Fig.8  Hydrogen diffusion process at external corrosion defect at 10 MPa (Color legend: hydrogen concentration, mol/m3): (a) 1 × 105 s, (b) 5 × 105 s, (c) 1 × 106 s, (d) 1.5 × 106 s, (e) 2 × 106 s, (f) 2.5 × 106 s
Fig.9  Distributions of hydrogen concentrations (mol/m3) at internal (a-c) and external (d-f) corrosion defects under an internal pressure of 6 MPa (a, d), 8 MPa (b, e) and 10 MPa (c, f) at 5 × 106 s
Fig.10  Liner distributions of hydrogen concentrations along the left edge (a, c) and right edge (b, d) of the internal corrosion defect (a, b) and the external corrosion defect (c, d)
TypeP / MPaCmax / mol·m-3Location coordinates
x / mmy / mmz / mm
Internal corrosion defect610.200-249.84502.82
810.390-250.30500.00
1010.600-250.90500.82
External corrosion defect610.940-248.56500.70
811.160-248.18500.00
1011.530-248.18500.00
Table 1  The maximum hydrogen concentrations under different internal pressures
Fig.11  Locations of the maximum hydrogen concentrations of internal corrosion defect (a) and external corrosion defect (b)
Fig.12  Hydrogen distribution at internal (a-d) and external (e-h) corrosion defects with different lengths under an internal pressure of 10 MPa at 5 × 106 s (Color legend: hydrogen concentration, mol/m3): (a, e) 10 mm, (b, f) 12 mm, (c, g) 14 mm, (d, h) 16 mm
TypeDefect length mmCmax / mol·m-3Location coordinates
x / mmy / mmz / mm
Internal corrosion defect1010.530-250.29500.00
1210.530-250.86500.97
1410.540-250.87500.93
1610.570-250.90500.82
External corrosion defect1011.200-248.18500.00
1211.300-248.18500.00
1411.340-248.18500.00
1611.530-248.18500.00
Table 2  The maximum hydrogen concentrations at different defect lengths
Fig.13  Hydrogen distribution at internal (a-d) and external (e-h) corrosion defects with different depths under an internal pressure of 10 MPa at 5 × 106 s (Color legend: hydrogen concentration, mol/m3): (a, e) 1.91 mm, (b, f) 2.86 mm, (c, g) 3.81 mm, (d, h) 4.76 mm
TypeDefect depth / mmCmax / mol·m-3Location coordinates
x / mmy / mmz / mm
Internal corrosion defect1.9110.300-248.46501.05
2.8610.400-249.24503.21
3.8110.500-250.27500.94
4.7610.570-250.90500.82
External corrosion defect1.9110.620-250.75500.00
2.8610.940-249.32501.00
3.8111.210-248.94500.00
4.7611.530-248.18500.00
Table 3  The maximum hydrogen concentrations at different defect depths
1 Rusman N A A, Dahari M. A review on the current progress of metal hydrides material for solid-state hydrogen storage applications [J]. Int. J. Hydrog. Energy, 2016, 41: 12108
2 Dutta S. A review on production, storage of hydrogen and its utilization as an energy resource [J]. J. Ind. Eng. Chem., 2014, 20: 1148
3 Cipriani G, Di Dio V, Genduso F, et al. Perspective on hydrogen energy carrier and its automotive applications [J]. Int. J. Hydrog. Energy, 2014, 39: 8482
4 Chen T P. Hydrogen delivery infrastructure options analysis [R]. San Fancisco: Nexant, Inc., 2010
5 Demir M E, Dincer I. Cost assessment and evaluation of various hydrogen delivery scenarios [J]. Int. J. Hydrog. Energy, 2018, 43: 10420
6 van der Zwaan B C C, Schoots K, Rivera-Tinoco R, et al. The cost of pipelining climate change mitigation: an overview of the economics of CH4, CO2 and H2 transportation [J]. Appl. Energy, 2011, 88: 3821
7 Tan K, Mahajan D, Venkatesh T A. Computational fluid dynamic modeling of methane-hydrogen mixture transportation in pipelines: estimating energy costs [J]. MRS Adv., 2022, 7: 388
8 Hall J E, Hooker P, Jeffrey K E. Gas detection of hydrogen/natural gas blends in the gas industry [J]. Int. J. Hydrog. Energy, 2021, 46: 12555
9 Ozturk M, Dincer I. A comprehensive review on power-to-gas with hydrogen options for cleaner applications [J]. Int. J. Hydrog. Energy, 2021, 46: 31511
10 Dodds P E, Staffell I, Hawkes A D, et al. Hydrogen and fuel cell technologies for heating: a review [J]. Int. J. Hydrog. Energy, 2015, 40: 2065
11 Li X, Zhu Q J, Zhou N, et al. Oil-gas pipe corrosion and protection [J]. Surf. Technol., 2017, 46(12): 206
李 雪, 朱庆杰, 周 宁 等. 油气管道腐蚀与防护研究进展 [J]. 表面技术, 2017, 46(12): 206
12 Lynch S. Hydrogen embrittlement phenomena and mechanisms [J]. Corros. Rev., 2012, 30: 105
13 Kumnick A J, Johnson H H. Deep trapping states for hydrogen in deformed iron [J]. Acta Metall., 1980, 28: 33
14 Guo S W, Wu H Z, Dong S H, et al. Simulation of hydrogen distribution in pipeline with double corrosion defects [J]. J. Chin. Soc. Corros. Prot., 2024, 44: 335
郭诗雯, 吴浩志, 董绍华 等. 含双腐蚀缺陷管道的氢浓度分布模拟 [J]. 中国腐蚀与防护学报, 2024, 44: 335
doi: 10.11902/1005.4537.2023.333
15 Liu W C, Wei B X, Yin H, et al. Finite element analysis of hydrogen permeation in X80 pipeline with corrosion defects under axial strain [J]. Surf. Technol., 2024, 53(8): 84
刘韦辰, 韦博鑫, 尹 航 等. 轴向应变作用下含腐蚀缺陷X80管道氢渗透的有限元分析 [J]. 表面技术, 2024, 53(8): 84
16 Gorban A N, Sargsyan H P, Wahab H A. Quasichemical models of multicomponent nonlinear diffusion [J]. Math. Model. Nat. Phenom., 2011, 6: 184
17 Krom A H M, Koers R W J, Bakker A. Hydrogen transport near a blunting crack tip [J]. J. Mech. Phys. Solids, 1999, 47: 971
18 Cisneros M M, Lopez H F, Salas N, et al. Hydrogen permeability in a plasma nitrided API X52 steel [J]. Mater. Sci. Forum, 2003, 442: 85
19 Yang F Q, Zhan W J, Yan T, et al. Numerical analysis of the coupling between hydrogen diffusion and mechanical behavior near the crack tip of titanium [J]. Math. Probl. Eng., 2020, 2020: 3618589
20 Wijmans J G, Baker R W. The solution-diffusion model: a review [J]. J. Membrane Sci., 1995, 107: 1
21 Sofronis P, McMeeking R M. Numerical analysis of hydrogen transport near a blunting crack tip [J]. J. Mech. Phys. Solids, 1989, 37: 317
22 Hirth J P. Effects of hydrogen on the properties of iron and steel [J]. Metall. Trans., 1980, 11A: 861
23 McLellan A G. Non-hydrostatic thermodynamics of chemical systems [J]. Proc. Roy. Soc., 1970, 314A: 443
24 Wikipedia. Nominal pipe size [DB/OL]. [2022-01-09].
25 Hafsi Z, Mishra M, Elaoud S. Hydrogen embrittlement of steel pipelines during transients [J]. Procedia Struct. Integr., 2018, 13: 210
26 Chouchaoui B A, Pick R J. Behaviour of longitudinally aligned corrosion pits [J]. Int. J. Press. Vess. Pip., 1996, 67: 17
27 Xu L Y, Cheng Y F. Corrosion of X100 pipeline steel under plastic strain in a neutral pH bicarbonate solution [J]. Corros. Sci., 2012, 64: 145
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