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Journal of Materials Engineering and Performance

Erschienen in:

21.03.2022 | Technical Article

Failure Analysis of Abnormal Bulging and Cracking for High-Pressure Steam Pipe

verfasst von: Yunrong Lyu, Weiqi Lian, Zhiwei Sun, Weiming Li, Zhihong Duan, Ruan Chen, Wei Yu, Siyuan Shao

Erschienen in: Journal of Materials Engineering and Performance | Ausgabe 9/2022

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Abstract

High-pressure steam pipes inevitably suffered from reciprocal interaction of high pressure and temperature during long-period service, causing deformation and cracking. To study the dominant influence factor, the bulging and cracking high-pressure steam pipes were investigated with a macro visual inspection, chemical composition analysis, metallographic microscopy, scanning electron microscopy (SEM), and energy dispersive spectroscopy (EDS). According to the analysis of the bulging and cracking samples, no effect of pearlite spheroidization was found for the bulging and cracking phenomenon. The simulation results show that the overlength distance between the steam drain valve and the main steam pipe, generating the alternating thermal stress and the subsequent thermal fatigue. And the Von-Mises modeling further illustrates the stress concentration located at the pipe orifice's fillet weld, causing the final creep cracking. It is concluded that the creep/fatigue interaction was the main factor for the pipe cracking combing with abnormal bulging.

Vorheriger Artikel Environmental Effects on the Creep Response of Thin-Walled Ni-Based Single Crystal Superalloys

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Z. Yue and Y.S. Zhang, Material and Dynamics Analysis of Low-Temperature Superheater Pipe Bulging Accident in Utility Boiler, Adv. Mater. Res., 2012, 507, p 117–122. CrossRef

J. Purbolaksono, J. Ahmad, L.C. Beng, A.Z. Rashid, A. Khinani and A.A. Ali, Failure Analysis on a Primary Superheater Tube of a Power Plant, Eng. Fail. Anal., 2010, 17(1), p 158–167. CrossRef

M. Song, T. Xu, K. Yuan, H. Yu and C. Sun, Creep Failure of a Steam Pipe Girth Weld and NDT Strategy on Creep Damage, Eng. Fail. Anal., 2019, 104, p 673–681. CrossRef

F. Dehnavi, A. Eslami and F. Ashrafizadeh, A Case Study on Failure of Superheater Tubes in an Industrial Power Plant, Eng. Fail. Anal., 2017, 80, p 368–377. CrossRef

N.G. Muralidharan, R. Kaul, K.V. Kasiviswanathan, T. Jayakumar and B. Raj, Failure Analysis of an Ammonia Refrigerant Condenser Tube, J. Mater. Eng. Perform., 1996, 5(2), p 241–246. CrossRef

G.K. Gupta and S. Chattopadhyaya, Critical Failure Analysis of Superheater Tubes of Coal-Based Boiler, Strojniški vestnik – J. Mech. Eng., 2017, 63(5), p 287–299. CrossRef

K.S. Guan, F.B. Xu, Z.W. Wang and H. Xu, Failure Analysis of Hot Corrosion of Weldments in Ethylene Cracking Tubes, Eng. Fail. Anal., 2005, 12(1), p 1–12. CrossRef

Q. Chu, M. Zhang, J. Li, Y. Chen, H. Luo and Q. Wang, Failure Analysis of a Steam Pipe Weld Used in Power Generation Plant, Eng. Fail. Anal., 2014, 44, p 363–370. CrossRef

P. Munda, M.M. Husain, V. Rajinikanth and A.K. Metya, Evolution of Microstructure During Short-term Overheating Failure of a Boiler Water Wall Tube Made of Carbon Steel, J. Fail. Anal. Prev., 2018, 18(1), p 199–211. CrossRef

10.

M. Ohata, N. Kawai, T. Tagawa, F. Minami, T. Yamamoto, K. Arii and S. Niimoto, Investigation of Bulging Behavior of Coke Drum: Feasible Study on Causes of Bulging, J. Press Vess-T Asme, 2014, 136, p 0312053. CrossRef

11.

T. Yamamoto, K. Arii, S. Niimoto, M. Ohata, T. Tagawa and F. Minami, Investigation of Bulging Behavior of Coke Drum-A Practical Analysis of Bulging Under Complex Quench Conditions, J. Press Vess-T Asme, 2014, 136, p 0614016. CrossRef

12.

Y. Kim and Y. Lee, Damage Prevention Design of the Branch Pipe Under Pressure Pulsation Transmitted from Main Steam Header, J. Mech. Sci. Technol., 2008, 22(4), p 647–652. CrossRef

13.

M. Taghipour, A. Bahrami, H. Mohammadi and V. Esmaeili, Root Cause Analysis of a Failure in a Flange-Pipe Welded Joint in a Steam Line in an Ammonia plant: Experimental Investigation and Simulation Assessment, Eng. Fail. Anal., 2021, 129, p 105730. CrossRef

14.

Y. Lin, X. Qi, D. Zhu, D. Zeng, H. Zhu, K. Deng and T. Shi, Failure Analysis and Appropriate Design of Drill Pipe Upset Transition Area, Eng. Fail. Anal., 2013, 31, p 255–267. CrossRef

15.

Z.H. Ning, R.H. Liu, S.Q. Huang and X.S. Lu, Analytical Solution of the Thermoelasticity Problem in a Coke Drum with Cladding, J. Press Vess-T Asme, 2011, 133, p 0312013. CrossRef

16.

Z. Ning and R. Liu, Analysis of Transient Temperature Field in Coke Drums, Appl. Math. Mech., 2010, 31(3), p 291–304. CrossRef

17.

X. Niu, J. Gong, Y. Jiang and J. Bao, Creep Damage Prediction of the Steam Pipelines with High Temperature and High Pressure, Int. J. Press Ves. Pip., 2009, 86(9), p 593–598. CrossRef

18.

X. Zhu, H. Chen, F. Xuan and X. Chen, Cyclic Plasticity Behaviors of Steam Turbine Rotor Subjected to Cyclic Thermal and Mechanical Loads, Eur. J. Mech. A-Solid, 2017, 66, p 243–255. CrossRef

19.

T. Li, H. Chen, W. Chen and J. Ure, On the Ratchet Analysis of a Cracked Welded Pipe, J. Press Vess-T Asme, 2012, 134, p 0112031. CrossRef

20.

T. Hassan, M. Rahman and S. Bari, Low-Cycle Fatigue and Ratcheting Responses of Elbow Piping Components, J. Press Vess-T Asme, 2015, 137, p 0310103.

21.

S. Vishnuvardhan, G. Raghava, P. Gandhi, M. Saravanan, D. M. Pukazhendhi, S. Goyal, P. Arora, S.K. Gupta, Fatigue Ratcheting Studies on TP304 LN Stainless Steel Straight Pipes. In Procedia Engineering; Lukas, P., Ed; Vol. 2, pp. 2209-2218 (2010)

22.

A.R.S Ponter, Direct Evaluation of Limits in Plasticity and Creep Deformation. In IUTAM Bookseries; Reddy, B. D., Ed; Vol. 11, pp. 341-348 (2008)

23.

P. Carter, Analysis of Cyclic Creep and Rupture Part 2: Calculation of Cyclic Reference Stresses and Ratcheting Interaction Diagrams, Int. J. Press Ves Pip., 2005, 82(1), p 27–33. CrossRef

24.

J.H. Dong, L.L. Guo and B.J. Gao, A Finite Element Analysis of the Cyclic Plasticity Behavior of Circumferential Weld of Coke Drum under Moving Axial Temperature Gradient, Procedia Eng., 2015, 130, p 307–321. CrossRef

25.

N. Kasahara, M.A. Al Bari and R. Sakemi, Failure Modes of Piping Under Seismic Loads Which have both Load and Displacement Controlled Characteristics, Int. J. Press Ves. Pip., 2020, 179, p 103938. CrossRef

26.

M. Puliyaneth, D. Barbera, H. Chen and F. Xuan, Study of Ratchet Limit and Cyclic Response of Welded Pipe, Int. J. Press Ves. Pip., 2018, 168, p 49–58. CrossRef

27.

T. Li, H. Chen, W. Chen, J. Ure, Ratchet Limits for a Crack in a Welded Pipe Subjected to a Cyclic Temperature Load and a Constant Mechanical Load. In Waterland, J.; Bouzid, H. A., ^Eds.; pp. 69-77 (2012)

28.

X. Zheng, F. Xuan and P. Zhao, Ratcheting-Creep Interaction of Advanced 9–12% Chromium Ferrite Steel With Anelastic Effect, Int. J. Fatigue, 2011, 33(9), p 1286–1291. CrossRef

29.

J. Zhang, G. Zhang, C. Luo and Y. Zhang, Influence of Creep Strength of Weld on Interfacial Creep Damage of Dissimilar Welded Joint Between Martensitic and Bainitic Heat-Resistant Steel, J. Wuhan Univ. Technol.-Mater Sci, 2013, 28(1), p 178–183. CrossRef

Titel: Failure Analysis of Abnormal Bulging and Cracking for High-Pressure Steam Pipe
verfasst von: Yunrong Lyu
Weiqi Lian
Zhiwei Sun
Weiming Li
Zhihong Duan
Ruan Chen
Wei Yu
Siyuan Shao
Publikationsdatum: 21.03.2022
Verlag: Springer US
Erschienen in: Journal of Materials Engineering and Performance / Ausgabe 9/2022
Print ISSN: 1059-9495
Elektronische ISSN: 1544-1024
DOI: https://doi.org/10.1007/s11665-022-06799-0

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