Using green corrosion inhibitor to reduce maintenance cost for carbon steel saline water storage systems in the oil industry
By:
References
- Wang C., et al. Modified chitosan-oligosaccharide and sodium silicate as efficient sustainable inhibitor for carbon steel against chloride-induced corrosion, <em>J Clean Prod</em>, <bold>2019</bold>, 238, p. 117823.
- Obot I. B., Onyeachu I. B., Kumar A. M. Sodium alginate: A promising biopolymer for corrosion protection of API X60 high strength carbon steel in saline medium, <em>Carbohydr Polym</em>, <bold>2017</bold>, 178, 200–208
- Awizar D. A., et al. Nanosilicate extraction from rice husk ash as green corrosion inhibitor, <em>Int J Electrochem Sci</em>, <bold>2013</bold>, 8, 2, 1759–1769
- Ji G., et al. Musa paradisica peel extract as green corrosion inhibitor for mild steel in HCl solution, <em>Corros Sci</em>, <bold>2015</bold>, 90, 107–117
- Asra D., Othman N. K., Dasuki Z., Nano-silicate inhibitor derived from rice husk for corrosion mitigation of steel in distilled water, in <em>AIP Conference Proceedings</em>, <bold>2017</bold>, 1838, 1, p. 020004
- Madlangbayan M. S., et al. Corrosion inhibition of sodium silicate with nanosilica as coating in pre-corroded steel, <em>Civil Engineering Journal (Iran)</em>, <bold>2021</bold>, 7, 11, 1806–1816
- Patel K. G., Shettigar R. R., Misra N. M., Recent Advance in Silica Production Technologies from Agricultural Waste Stream–Review” <em>Journal of Advanced Agricultural Technologies</em>, <bold>2017</bold>, 4, 3, 274–279
- Singh S. P. and Endley N. Fabrication of nano-silica from agricultural residue and their application, <em>Nanomaterials for Agriculture and Forestry Applications</em>, <bold>2020</bold>, 107–134.
- Othman N., et al. <em>Anticorrosive properties of nano silicate from paddy husk in salt medium</em>, <bold>2016</bold>, Accessed: Feb. 04, 2023. Online.. Available: <ext-link ext-link-type="uri" xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="https://core.ac.uk/download/pdf/84306697.pdf">https://core.ac.uk/download/pdf/84306697.pdf</ext-link>.
- Asra Awizar D., et al. The Performance of Nanosilicate from Rice Husk Ash as Green Corrosion Inhibitor for Carbon Steel in 0.5M HCl, <em>Materials Science Forum</em>, <bold>2013</bold>, 756, 266–272
- Ajeel S. A., Sukkar K. A., Zedin N. K. Evaluation of acid leaching process and calcination temperature on the silica extraction efficiency from the sustainable sources, <em>Journal of Physics: Conference Series</em>, <bold>2021</bold>, 1773, 1, p. 012014
- Zedin N. K., Ajeel S. A., Sukkar K. A., Nanosilicon powder extraction as a sustainable source (from Iraqi rice husks) by hydrothermal process, <em>AIP Conference Proceedings</em>, <bold>2020</bold>, 2213, 1, p. 020155
- Tao Z., et al. Corrosion inhibition of mild steel in acidic solution by some oxo-triazole derivatives, <em>Corros Sci</em>, <bold>2009</bold>, 51, 11, 2588–2595
- Ashassi-Sorkhabi H., Majidi M. R., Seyyedi K. Investigation of inhibition effect of some amino acids against steel corrosion in HCl solution, <em>Appl Surf Sci</em>, <bold>2004</bold>, 225, 1–4, 176–185
- Behpour M., et al. Investigation of some Schiff base compounds containing disulfide bond as HCl corrosion inhibitors for mild steel, <em>Corros Sci</em>, <bold>2010</bold>, 52, 12, 4046–4057
- Valero Vidal C. and Igual Muñoz A. Study of the adsorption process of bovine serum albumin on passivated surfaces of CoCrMo biomedical alloy, <em>Electrochim Acta</em>, <bold>2010</bold>, 55, 28, 8445–8452
- Cosman N. P., Fatih K., Roscoe S. G. Electrochemical impedance spectroscopy study of the adsorption behaviour of α-lactalbumin and <em>β</em>-casein at stainless steel, <em>Journal of Electroanalytical Chemistry</em>, <bold>2005</bold>, 574, 2, 261–271
- Tamalmani K. and Husin H., “Review on corrosion inhibitors for oil and gas corrosion issues,” <em>Applied Sciences</em>, <bold>2020</bold>, 10, 10
- Hamdy A. S., Alfosail F., Gasem Z. Eco-friendly, cost-effective silica-based protective coating for an A6092/SiC/17.5p aluminum metal matrix composite, <em>Electrochim Acta</em>, <bold>2013</bold>, 89, 749–755
- “NACE RP0775 - Preparation, Installation, Analysis, and Interpretation of Corrosion Coupons in Oilfield Operations |Engineering360.” <ext-link ext-link-type="uri" xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="https://store.ampp.org/sp0775-2013-formerly-rp0775-2">https://store.ampp.org/sp0775-2013-formerly-rp0775-2</ext-link> (accessed Jan. 20, 2023).
- Namus R. and Rainforth W. M. The influence of cathodic potentials on the surface oxide layer status and tribocorrosion behaviour of Ti<sub>6</sub>Al<sub>4</sub>V and CoCrMo alloys in simulated body fluid, <em>Biotribology</em>, 2022, 30, 00212
- Namus R., et al. The influence of protein concentration, temperature and cathodic polarization on the surface status of CoCrMo biomedical grade alloys, <em>Appl Surf Sci</em>, <bold>2020</bold>, 499, 143908
- Satapathy A. K., et al. Corrosion inhibition by Justicia gendarussa plant extract in hydrochloric acid solution, <em>Corros Sci</em>, <bold>2009</bold>, 51, 12, 2848–2856
- Valero Vidal C. and Igual Muñoz A. Influence of protein adsorption on corrosion of biomedical alloys, <em>Bio-Tribocorrosion in Biomaterials and Medical Implants</em>, Elsevier, <bold>2013,</bold> 187–219.
- Khaled K. F. and Hackerman N. Investigation of the inhibitive effect of ortho-substituted anilines on corrosion of iron in 1 M HCl solutions, <em>Electrochim Acta</em>, <bold>2003</bold>, 48, 19, 2715–2723
- Li X., Deng S., Fu H. Allyl thiourea as a corrosion inhibitor for cold rolled steel in H<sub>3</sub>PO<sub>4</sub> solution, <em>Corros Sci</em>, <bold>2012</bold>, 55, 280–288
- Deyab M. A., et al. Experimental evaluation of new inorganic phosphites as corrosion inhibitors for carbon steel in saline water from oil source wells, <em>Desalination</em>, <bold>2016</bold>, 383, 38–45
- Jackson D. R., Omanovic S., Roscoe S. G. Electrochemical studies of the adsorption behavior of serum proteins on titanium, <em>Langmuir</em>, <bold>2000</bold>, 16, 12, 5449–5457
- Valero Vidal C., Olmo Juan A., Igual Muñoz A. Adsorption of bovine serum albumin on CoCrMo surface: Effect of temperature and protein concentration, <em>Colloids Surf B Biointerfaces</em>, <bold>2010</bold>, 80, 1, 1–11
- Singh A. K. and Quraishi M. A. Effect of Cefazolin on the corrosion of mild steel in HCl solution, <em>Corros Sci</em>, <bold>2010</bold>, 52, 1, 152–160
- Deng S. and Li X. Inhibition by Ginkgo leaves extract of the corrosion of steel in HCl and H<sub>2</sub>SO<sub>4</sub> solutions, <em>Corros Sci</em>, <bold>2012</bold>, 55, 407–415
- Chen Y. and Jepson W. P. EIS measurement for corrosion monitoring under multiphase flow conditions, <em>Electrochim Acta</em>, <bold>1999</bold>, 44, 24, 4453–4464
- Lee W. J. Inhibiting effects of imidazole on copper corrosion in 1 M HNO<sub>3</sub> solution, <em>Materials Science and Engineering A</em>, <bold>2003</bold>, 348, 217–226
- Yang X., Roonasi P., Holmgren A. A study of sodium silicate in aqueous solution and sorbed by synthetic magnetite using in situ ATR-FTIR spectroscopy, <em>J Colloid Interface Sci</em>, <bold>2008</bold>, 328, 1, 41–47
- Gao H., et al. Study of the corrosion inhibition effect of sodium silicate on AZ91D magnesium alloy, <em>Corros Sci</em>, <bold>2011</bold>, 53, 4, 1401–1407
- Bass J. L. and Turner G. L. Anion distributions in sodium silicate solutions. Characterization by 29SI NMR and infrared spectroscopies, and vapor phase osmometry, <em>Journal of Physical Chemistry B</em>, <bold>1997</bold>, 101, 50, 10638–10644
Language: English
Page range: 43 - 50
Published on: May 19, 2024
Published by: Association of Czech and Slovak Corrosion Engineers
In partnership with: Paradigm Publishing Services
Publication frequency: 4 times per year
Related subjects:
© 2024 R. M. Namus, M. H. Abass, M. Alali, N. K. Zedin, published by Association of Czech and Slovak Corrosion Engineers
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.