Electrochemical Behavior, Microstructure, and Surface Chemistry of Thermal-Sprayed Stainless-Steel Coatings

Abstract: Thermally sprayed stainless-steel coatings were produced with a wide range of deposition parameters. The electrochemical behavior of polished coatings was monitored for 3 weeks in 3.5 wt.% NaCl aqueous solution and compared to that of reference materials including a wrought stainless steel plate and a bulk ingot produced by arc melting of the spraying powder feedstock. Transitions in the polarization behavior are discussed based on the observed changes in coating microstructures as well as on the shifts in X-r… Show more

“…Nevertheless, the bulk stainless steel performs significantly better than the coatings (E Corr = +88 mV ± 2 mV). These results are as well reported and discussed in detail for AISI 316L HVOF and HVAF coatings in [15,17,30,31].…”

“…The salt spray test or the Corrodkote test are specifically designed to induce sub-corrosion in order to test the apparent density of the coatings. In research, studies often deal with electrochemicalinstrumented tests such as potentiodynamic polarization, electrochemical impedance, and immersion tests in 3.4% to 5% sodium chloride (NaCl) solutions [14][15][16][17]. For these corrosion tests, the following observations can be summarized: the open circuit potential (OCP) and the corrosion potential (E Corr ), respectively, decreases with immersion time due to electrolyte infiltration of the coating toward the substrate.…”

“…Hence, thermal spray coatings with a homogeneous and compact coating microstructure with less oxidation are preferred for corrosive application. In order to improve the corrosion behavior, several authors studied the influence of the spray parameters [15][16][17][18][19][20][21] or post treatments like sealing [22][23][24] or heat treatments [18,25,26]. Post treatments are cost and time consuming and can alter the substrate.…”

Comparison of Aqueous and Gelled 3.5% NaCl Electrolytes for Assessing the Corrosion Resistance of Thermal Spray Stainless-Steel Coatings in Electrochemical Corrosion Tests

“…Nevertheless, the bulk stainless steel performs significantly better than the coatings (E Corr = +88 mV ± 2 mV). These results are as well reported and discussed in detail for AISI 316L HVOF and HVAF coatings in [15,17,30,31].…”

“…The salt spray test or the Corrodkote test are specifically designed to induce sub-corrosion in order to test the apparent density of the coatings. In research, studies often deal with electrochemicalinstrumented tests such as potentiodynamic polarization, electrochemical impedance, and immersion tests in 3.4% to 5% sodium chloride (NaCl) solutions [14][15][16][17]. For these corrosion tests, the following observations can be summarized: the open circuit potential (OCP) and the corrosion potential (E Corr ), respectively, decreases with immersion time due to electrolyte infiltration of the coating toward the substrate.…”

“…Hence, thermal spray coatings with a homogeneous and compact coating microstructure with less oxidation are preferred for corrosive application. In order to improve the corrosion behavior, several authors studied the influence of the spray parameters [15][16][17][18][19][20][21] or post treatments like sealing [22][23][24] or heat treatments [18,25,26]. Post treatments are cost and time consuming and can alter the substrate.…”

Comparison of Aqueous and Gelled 3.5% NaCl Electrolytes for Assessing the Corrosion Resistance of Thermal Spray Stainless-Steel Coatings in Electrochemical Corrosion Tests

Thermally sprayed multi-principal element Cr40Co40Ni20 coatings – Oxidation upon coatings' build-up and electrochemical corrosion