Advanced Compound Coating for Delaying Corrosion of Fast-Dissolving Alloy in High Temperature and Corrosive Environment
Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33093
Advanced Compound Coating for Delaying Corrosion of Fast-Dissolving Alloy in High Temperature and Corrosive Environment

Authors: Lei Zhao, Yi Song, Tim Dunne, Jiaxiang (Jason) Ren, Wenhan Yue, Lei Yang, Li Wen, Yu Liu

Abstract:

Fasting dissolving magnesium (DM) alloy technology has contributed significantly to the “Shale Revolution” in oil and gas industry. This application requires DM downhole tools dissolving initially at a slow rate, rapidly accelerating to a high rate after certain period of operation time (typically 8 h to 2 days), a contradicting requirement that can hardly be addressed by traditional Mg alloying or processing itself. Premature disintegration has been broadly reported in downhole DM tool from field trials. To address this issue, “temporary” thin polymers of various formulations are currently coated onto DM surface to delay its initial dissolving. Due to conveying parts, harsh downhole condition, and high dissolving rate of the base material, the current delay coatings relying on pure polymers are found to perform well only at low temperature (typical < 100 ℃) and parts without sharp edges or corners, as severe geometries prevent high quality thin film coatings from forming effectively. In this study, a coating technology combining Plasma Electrolytic Oxide (PEO) coatings with advanced thin film deposition has been developed, which can delay DM complex parts (with sharp corners) in corrosive fluid at 150 ℃ for over 2 days. Synergistic effects between porous hard PEO coating and chemical inert elastic-polymer sealing leads to its delaying dissolution improvement, and strong chemical/physical bonding between these two layers has been found to play essential role. Microstructure of this advanced coating and compatibility between PEO and various polymer selections has been thoroughly investigated and a model is also proposed to explain its delaying performance. This study could not only benefit oil and gas industry to unplug their High Temperature High Pressure (HTHP) unconventional resources inaccessible before, but also potentially provides a technical route for other industries (e.g., bio-medical, automobile, aerospace) where primer anti-corrosive protection on light Mg alloy is highly demanded.

Keywords: Dissolvable magnesium, coating, plasma electrolytic oxide, sealer.

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 580

References:


[1] Z. Y. Xu, and Z. H. Zhang, “The Art of Disintegration–Ten Years in Review of Disintegrable Metals and Downhole Tools,” in Offshore Technology Conference, Houston, USA, May 2019
[2] M. Fripp, and Z. Walton, “Degradable Metal for Use in a Fully Dissolvable Frac Plug,” in Offshore Technology Conference, Houston, USA, May 2016
[3] J. F. Nie, “Precipitation and Hardening in Magnesium Alloys,” Metall. Mater. Trans. A., vol. 43, pp. 3891–3939, Nov. 2012.
[4] S. Tekumalla, S. Seetharaman, A. Almajid and M. Gupta, “Mechanical Properties of Magnesium-Rare Earth Alloy Systems: A Review,” Metals, vol. 5, no. 1, pp. 1–39, Dec. 2014.
[5] D. K. Xu, E. H. Han, and Y. B. Xu, “Effect of long-period stacking ordered phase on microstructure, mechanical property and corrosion resistance of Mg alloys: A review,” Prog. Nat. Sci., vol. 5, pp. 117–128, 2016
[6] M. K. Surappa, “Microstructure evolution during solidification of DRMMCs (Discontinuously reinforced metal matrix composites): State of art,” J. Mater. Process. Technol., vol. 63, pp. 325–333, 1997
[7] M. Li, L. Chen, R. Wei, C. L. Liao, and T. Fu, “The Application of Fully Dissolvable Frac Plug Technique in Weiyuan Gasfield,” in SPE Kingdom of Saudi Arabia Annual Technical Symposium and Exhibition, Dammam, Saudi Arabia, April 2018
[8] D. Kumar; E. D. Hernaez, J. S. Sanchez and Z. Y. Xu, “Temporary Coating for Dissolving Frac-Balls Used in Multi-Stage Fracturing Systems”, in Offshore Technology Conference, Houston, USA, April 2018
[9] R. G. Hu, S. Zhang, J. F. Bu, C. J. Lin and G. L. Song, “Recent progress in corrosion protection of magnesium alloys by organic coatings,” Prog. Org. Coat., vol. 73, pp. 129–141, 2012
[10] J. Wang, X. Pang, and H. Jahed, “Surface protection of Mg alloys in automotive applications: A review,” AIMS Mater. Sci., vol. 6, pp. 567–600, 2019
[11] L. A. Dobrzanski, K. Lukaszkowicz, D. Pakula and J. Mikula, “Corrosion resistance of multilayer and gradient coatings deposited by PVD and CVD techniques,” Arch. Mater. Sci. Eng., vol. 28, pp. 12–18, 2007
[12] H. Hu, X. Y. Nie and Y. Y. Ma, “Corrosion and Surface Treatment of Magnesium Alloys,” in Magnesium Alloys: Properties in Solid and Liquid States, IntechOpen, 2014, pp. 92–101
[13] J.E. Gray and B. Luan, “Protective coatings on magnesium and its alloys-a critical review,” J. Alloys Compd., vol. 336, pp. 88–113, 2002
[14] S. Y. Zhang, Q. Li, X. K. Yang, Y. Dai and F. Luo, “Corrosion resistance of AZ91D magnesium alloy with electroless plating pretreatment and Ni–TiO2 composite coating,” Mater. Charact., vol. 61, pp. 269–276, 2010
[15] Gh. Barati Darband, M. Aliofkhazraei, P. Hamghalam, and N. Valizade, “Plasma electrolytic oxidation of magnesium and its alloys: Mechanism, properties and applications,” J. Magnes. Alloy., vol. 5, pp. 74–132, 2017
[16] Y. X. Gan, A. S. Hamdan, J. B. Gan and M. H. Li, “Chemical Vapor Deposition of Bi-Te-Ni-Fe on Magnesium Oxide Substrate and Its Seebeck Effect,” Coatings, vol. 7, pp. 164, 2017
[17] P. B. Srinivasan, N. Scharnagl, C. Blawert and W. Dietzel, “Enhanced corrosion protection of AZ31 magnesium alloy by duplex plasma electrolytic oxidation and polymer coatings,” Surf. Eng., vol. 26, pp.354-360, 2013
[18] J. W. Wang, J. W. Tang and Y.D. He, “Top coating of low-molecular weight polymer MALPB used for enhanced protection on anodized AZ31B Mg alloys,” J. Coat. Technol. Res., vol. 7, pp. 737–746, 2010