Initial stages of particulate iron oxide attachment on drinking water PVC pipes characterized by turbidity data and brightfield microscopy from a full-scale laboratory

Iron oxide particles produced by corroding metallic pipes in drinking water networks often accumulate and form material deposits on the wall of downstream polymeric pipes. The aim of this paper is to isolate and examine the physical processes of attachment and subsequent mobilization of iron oxide p...

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Bibliographic Details
Published in:Environmental science water research & technology 2022-06, Vol.8 (6), p.1195-121
Main Authors: Braga, Artur Sass, Filion, Yves
Format: Article
Language:English
Subjects:
Attachment
Calibration
Deposits
Drinking water
Fluid flow
Forces (mechanics)
Gravity
Iron oxides
Laboratories
Mass balance
Microscopy
Particle concentration
Pipes
Polyvinyl chloride
Roughness
Scale (corrosion)
Shear forces
Shear strength
Turbidity
Water distribution
Water distribution systems
Water engineering
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Summary:Iron oxide particles produced by corroding metallic pipes in drinking water networks often accumulate and form material deposits on the wall of downstream polymeric pipes. The aim of this paper is to isolate and examine the physical processes of attachment and subsequent mobilization of iron oxide particles on new PVC pipes in a full-scale laboratory operated under hydraulic conditions that are representative of actual drinking water distribution systems. Particle accumulation was quantified using: 1) a mass balance approach based on the transformation of turbidity data into iron oxide particle concentration through calibration curves, and 2) the direct observation of particles accumulated on coupon samples with automated brightfield microscopy. Results showed that: 1) the iron oxide particle concentration in the bulk water had a major impact on the extent of material deposits observed on the pipe wall; 2) gravity greatly assisted in the attachment stage of fine iron oxide particles (1-10 μm) in the invert position of the pipe. The experimental data led to the hypotheses that the fine particles were seated in the pipe wall roughness "valleys" which protected them from the flow shear force and might explain the different shear strength of material deposits. Turbidity and brightfield microscopy were used to investigate the attachment of iron oxide particles on drinking water PVC pipes. Experimental evidence motivated new insights about the physical process of particle attachment.
ISSN:2053-1400
2053-1419
DOI:10.1039/d2ew00010e