Corrosion behavior of the expandable tubular in formation water

详细信息    查看全文

• 作者：Shu-jun Gao ; Chao-fang Dong ; An-qing Fu…
• 关键词：steel corrosion ; expandable tubes ; formation water ; electrochemical behavior
• 刊名：International Journal of Minerals, Metallurgy, and Materials
• 出版年：2015
• 出版时间：February 2015
• 年：2015
• 卷：22
• 期：2
• 页码：149-156
• 全文大小：3,677 KB
• 参考文献：1. R.M. Merritt, R. Gusevik, W. Buckler, and N. Steinsberger, Well remediation using expandable cased-hole liners, / World Oil, 223(2002), No. 7, p. 56.
  2. T. Grant and M. Bullock, The evolution of solid expandable tubular technology: lessons learned over five years, [in] / Offshore Technology Conference, Houston, USA, 2005, Article No. 17442.
  3. O.S. Al-Abri and T. Pervez, Structural behavior of solid expandable tubular undergoes radial expansion process-analytical, numerical, and experimental approaches, / Int. J. Solids Struct., 50(2013), No. 19, p. 2980. CrossRef
  4. Y.P. Zhang, R.Q. Ren, H. Wang, and J. Wang, Multilateral drilling and completion technology based on solid expandable tubular fixing system, / Pet. Explor. Dev., 36(2009), No. 6, p. 768. CrossRef
  5. W. Furlow, Expandable casing program helps operator hit TD with larger tubulars, / Offshore, 60(2000), No. 1, p. 48.
  6. A.C. Seibi, A. Karrech, T. Pervez, S. Al-Hiddabi, A. Al-Yahmadi, and A. Al-Shabibi, Dynamic effects of mandrel/tubular interaction on downhole solid tubular expansion in well engineering, / J. Energy Resour. Technol., 131(2009), No. 1, article No. 013101.
  7. T. Pervez, S.Z. Qamar, S.A. Al-Hiddabi, F.K. Al-Jahwari, F. Marketz, S. Al-Houqani, and M.V.D. Velden, Tubular expansion in irregularly shaped boreholes: computer simulation and field measurement, / Pet. Sci. Technol., 29(2011), No. 7, p. 735. CrossRef
  8. S. Talabani, B. Atlas, M.B. Al-Khatiri, and M.R. Islam, An alternate approach to downhole corrosion mitigation, / J. Pet. Sci. Eng., 26(2000), No. 1-, p. 41. CrossRef
  9. M.A. Deyab and S.S. Abd El-Rehim, Inhibitory effect of tungstate, molybdate and nitrite ions on the carbon steel pitting corrosion in alkaline formation water containing Cl<sup>?/sup> ion, / Electrochim. Acta, 53(2007), No. 4, p. 1754. CrossRef
  10. M.A. Migahed, M.A. Hegazy, and A.M. Al-Sabagh, Synergistic inhibition effect between Cu2+ and cationic gemini surfactant on the corrosion of downhole tubing steel during secondary oil recovery of old wells, / Corros. Sci., 61(2012), p. 10. CrossRef
  11. Y. Zhang, K. Gao, G. Schmitt, and R.H. Hausler, Modeling steel corrosion under supercritical CO₂ conditions, / Mater. Corros., 64(2013), No. 6, p. 478. CrossRef
  12. B.G. Xu, Y.P. Zhang, H. Wang, H.W. Yin, and T. Jia, Application of numerical simulation in the solid expandable tubular repair for casing damaged wells, / Pet. Explor. Dev., 36(2009), No. 5, p. 651. CrossRef
  13. V.V. Ananyan and M.V. Bunyashin, Mastering the manufacturing technology for thin-walled tube production on a TPA 159-426 tube-rolling aggregate, / Steel Transl., 37(2007), No. 1, p. 57. CrossRef
  14. A. Yamanaka, T. Takaki, and Y. Tomita, Coupled simulation of microstructural formation and deformation behavior of ferrite-pearlite steel by phase-field method and homogenization method, / Mater. Sci. Eng. A, 480(2008), No. 1-, p. 244. CrossRef
  15. S. Allain and O. Bouaziz, Microstructure based modeling for the mechanical behavior of ferrite-pearlite steels suitable to capture isotropic and kinematic hardening, / Mater. Sci. Eng. A, 496(2008), No. 1-, p. 329. CrossRef
  16. F.M. Al-Abbasi, Predicting the deformation behavior of ferrite-pearlite steels using micro mechanical modeling of cells, / Mech. Mater., 63(2013), p. 48. CrossRef
  17. M. Alizadeh and S. Bordbar, The influe</sup>
• 刊物类别：Chemistry and Materials Science
• 刊物主题：Materials Science
  Metallic Materials
  Mineral Resources
  
• 出版者：Journal Publishing Center of University of Science and Technology Beijing, in co-publication with Sp
• ISSN：1869-103X

文摘

The corrosion behavior of expandable tubular materials was investigated in simulated downhole formation water environments using a series of electrochemical techniques. The corrosion morphologies in the real downhole environment after three months of application were also observed by stereology microscopy and scanning electron microscopy (SEM). The results show that, compared with the unexpanded sample, the area of ferrite increases dramatically after a 7.09% expansion. The expanded material shows a higher corrosion current in the polarization curve and a lower corrosion resistance in the electrochemical impedance spectroscopy (EIS) plot at every studied temperature. The determined critical pitting temperatures (CPT) before and after expansion are 87.5°C and 79.2°C, respectively. SEM observations demonstrate stress corrosion cracks, and CO2 corrosion and H2S corrosion also occur in the downhole environment. Due to additional defects generated during the plastic deformation, the corrosion performance of the expanded tubing deteriorates.