Microplastics in Combined Sewer Overflows: An Experimental Study

One of the main sources of microplastics inside surface waters is represented by combined sewer overflows (CSOs), involving severe risks for the environment. The entry of microplastics into water bodies also depends on the characteristics of sewer diversion structures used as flow control devices. I...

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Bibliographic Details
Published inJournal of marine science and engineering Vol. 9; no. 12; p. 1415
Main Authors Di Nunno, Fabio, Granata, Francesco, Parrino, Francesco, Gargano, Rudy, de Marinis, Giovanni
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.12.2021
Subjects
Combined sewer overflows
Control equipment
Dimensional analysis
Diversion structures
Empirical equations
Environmental impact
environmental pollution
Evaluation
Experimental methods
Fibers
Flow control
Flow rates
Flow velocity
Inertia
Microplastics
Outflow
Plastic pollution
Polymers
side weir
Surface water
Water
water bodies
Water flow
Water treatment
Weirs
Baltic Sea
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Summary:One of the main sources of microplastics inside surface waters is represented by combined sewer overflows (CSOs), involving severe risks for the environment. The entry of microplastics into water bodies also depends on the characteristics of sewer diversion structures used as flow control devices. In this work, an experimental investigation was carried out to evaluate the outflow of microplastic particles, consisting of different types of nylon fibers, from a side weir located on a channel with a rectangular section. A specific methodology was developed for the fiber sampling and outflow assessment after the tests were performed. For the tested configurations, an increase in fibers discharged up to 196.15% was measured as the water flow rate increased by 62.75%, combined with an increase in the side weir length up to 40% and a decrease in the crest height up to 20%. The size and weight of the different fibers showed a low impact due to their low inertia, and their motion was governed by the water flow. An empirical equation to evaluate the fiber outflow as a function of water flow rate and side weir geometric characteristics was also proposed and calibrated for the experimentally tested ranges of the dimensionless lateral water outflow Q* = 0.51–0.83 and of the dimensionless geometric parameter S* = 0.114–0.200. These first experimental results make it possible to carry out a preliminary assessment of the impact of CSOs in terms of microplastics spilled into water bodies.
ISSN:2077-1312
2077-1312
DOI:10.3390/jmse9121415