Fouling mechanisms of asphaltenes and fine solids on bare and electroless nickel-phosphorus coated carbon steel

[Display omitted] •Direct force measurements were applied to investigate fouling mechanisms.•Obtained results revealed the driving forces in fouling phenomena.•Bulk fouling tests were conducted to examine fouling and antifouling properties.•Electroless nickel-phosphorus coating shows better antifoul...

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Bibliographic Details
Published in:Fuel (Guildford) 2019-09, Vol.252, p.188-199
Main Authors: Gong, Lu, Wang, Jingyi, Zhang, Ling, Fattahpour, Vahidoddin, Mamoudi, Mahdi, Roostaei, Morteza, Fermaniuk, Brent, Luo, Jing-Li, Zeng, Hongbo
Format: Article
Language:English
Subjects:
AFM colloidal probe technique
Antifouling coatings
Antifouling mechanism
Antifouling substances
Aqueous solutions
Asphaltenes
Atomic force microscopes
Atomic force microscopy
Calcium
Calcium ions
Carbon steel
Carbon steels
Coatings
Economic impact
EN coating
Fouling
Impact analysis
Nickel
Oil and gas industry
Organic chemistry
Petroleum engineering
Phosphorus
Silica
Silicon dioxide
Sodium chloride
Solids
Steel
Substrates
Surface forces
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Summary:[Display omitted] •Direct force measurements were applied to investigate fouling mechanisms.•Obtained results revealed the driving forces in fouling phenomena.•Bulk fouling tests were conducted to examine fouling and antifouling properties.•Electroless nickel-phosphorus coating shows better antifouling performance. Fouling is a critical issue faced by the chemical and oil industries in various operation processes, which has negative impact on the operational efficiency and generates significant economic losses, technical and environmental challenges. Investigating the interaction mechanisms between foulants (e.g., fine solids, asphaltenes) and different substrates is of both fundamental and practical importance in understanding the fouling mechanisms in chemical/petroleum engineering processes and developing antifouling strategies. In this work, atomic force microscope (AFM) colloidal probe technique was employed to directly quantify the interactions between silica or asphaltenes and selected substrates (i.e., carbon steel L80 and L80 with electroless nickel-phosphorus (EN) coating) in aqueous solutions. The effects of salinity, pH and presence of divalent ions (e.g., Ca2+) on the surface interactions were investigated. The obtained force profiles showed that the interactions between silica or asphaltenes and L80 surface were more attractive than that between silica or asphaltenes and EN coating, in NaCl solutions. Bulk fouling tests in silica and asphaltenes-coated silica suspensions revealed that significant fouling of silica and asphaltenes were found on L80 substrates, while EN coating exhibited excellent antifouling performance. Our results provide useful insights into the fundamental understanding of the fouling mechanism of fine solids and asphaltenes, and the development of novel effective antifouling coatings in chemical and oil industries.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2019.04.113