Particle Properties of Air Nanobubbles and Their Inhibition Mechanism on Brass Corrosion in Recirculating Cooling Water: Effects of Concentration Ratio and Flow Velocity

The corrosion inhibition performance of air nanobubbles (A‐NBs) is expected to address the environmental problems arising from chemical corrosion. In order to regulate the corrosion inhibition performance of A‐NBs, the particle characteristics of A‐NBs in flowing composite salt solutions are investi...

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Veröffentlicht in:Particle & particle systems characterization 2024-07, Vol.41 (7)
Hauptverfasser: Zhang, Yuling, Duan, Haiyang, Lu, Shaolei, Yang, Shaoxia, Qiu, Yaqin, Liu, Songtao, Wu, Yinwei
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container_issue 7
container_start_page
container_title Particle & particle systems characterization
container_volume 41
creator Zhang, Yuling
Duan, Haiyang
Lu, Shaolei
Yang, Shaoxia
Qiu, Yaqin
Liu, Songtao
Wu, Yinwei
description The corrosion inhibition performance of air nanobubbles (A‐NBs) is expected to address the environmental problems arising from chemical corrosion. In order to regulate the corrosion inhibition performance of A‐NBs, the particle characteristics of A‐NBs in flowing composite salt solutions are investigated, and the corrosion inhibition effect of A‐NBs under different concentration ratios and rotational speed of simulated circulating cooling water is studied. High salt concentrations significantly reduced the particle size, concentration, and zeta‐potential value of A‐NBs, thus reducing the stability of A‐NBs. The flow velocity has a slight effect on A‐NBs. The results of the weight loss and electrochemical method showed that A‐NBs achieved the highest corrosion inhibition rate of 55% under a concentration ratio of 1.5 and a rotational speed of 100 r min −1 . The surface characterization of brass specimens revealed that A‐NBs facilitated the formation of Cu 2 (OH) 2 CO 3 passivation film, calcium carbonate scale film, and a layer of bubbles on the surface of brass, which subsequently mitigated the erosive impact of the fluid. A‐NBs can adsorb cations and thus reduce the concentration of corrosive ions. However, the increase in concentration ratio and rotational speed impeded the formation of the bubble layer and passivation film.
doi_str_mv 10.1002/ppsc.202300224
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subjects Calcium carbonate
Corrosion
Corrosion effects
Corrosion mechanisms
Corrosion rate
Flow stability
Flow velocity
Fluid flow
Passivity
Saline solutions
Surface properties
Weight loss
title Particle Properties of Air Nanobubbles and Their Inhibition Mechanism on Brass Corrosion in Recirculating Cooling Water: Effects of Concentration Ratio and Flow Velocity
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