Application of Dissolved Air Flotation in Metal Plating Wastewater Treatment: A Life Cycle Perspective

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About the Journal In Memory of Professor Jerzy Radecki Editorial Office Editorial Board Scope Impact Factor Indexed in... Journal Impact Factor contributing items Contact Subscription

Current issue

Online first

Notes to Authors Frequently Asked Questions

Editorial policies PJOES Publication Policy Overview PJOES Peer Review Policy PJOES Research Ethics and Malpractice Policy PJOES Plagiarism Policy PJOES Conflict of Interest Policy PJOES Open Access Policy PJOES Instructions for Reviewers Generative AI and AI-Assisted Technologies Policy

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ORIGINAL RESEARCH

Application of Dissolved Air Flotation in Metal Plating Wastewater Treatment: A Life Cycle Perspective

Dilsad Elif Ozturk ¹

,

Baris Canci ¹

,

Neslihan Manav-Demir ¹

1

Yildiz Technical University, Environmental Engineering Department, Esenler, Istanbul, 34220, Türkiye

Submission date: 2025-09-01

Final revision date: 2025-10-27

Acceptance date: 2025-11-08

Online publication date: 2026-03-26

Corresponding author

Neslihan Manav-Demir

Yildiz Technical University, Environmental Engineering Department, Esenler, Istanbul, 34220, Türkiye

DOI: https://doi.org/10.15244/pjoes/214082

References (43)

KEYWORDS

metal plating wastewater

dissolved air flotation

life cycle assessment (LCA)

wastewater treatment

heavy metal removal

TOPICS

ABSTRACT

The metal plating industry is among the most rapidly developing and widely used industrial processes worldwide, consuming large amounts of water and generating significant environmental problems due to its wastewater. In this study, real wastewater from the metal plating industry was treated, and heavy metals were removed using a pilot-scale treatment process with a total volume of approximately 2.2 m³. The process consisted of sequential coagulation, flocculation, and dissolved air flotation (DAF), which was employed to reduce the area required for sedimentation. Initially, laboratory-scale studies were conducted to optimize the mixing speed, as well as the coagulant/flocculant type and dosage. Pilot-scale studies were then conducted. The study yielded removal efficiencies for COD, Cu, Ni, Zn, CN^-, Cr⁺⁶, and SO4^2- in the coagulation/flocculation/DAF (CF-DAF) process of 83%, 33%, 94%, 99%, 46%, 99%, and 90%, respectively. Additionally, a life cycle assessment was performed using two different methods (ReCiPe 2016 Midpoint (H) and Environmental Footprint 3.1 (EF 3.1)). Environmental impact categories of the process, such as climate change, eutrophication, human toxicity, and resource depletion, were determined, and the factors that provided the highest contribution were identified.

CONFLICT OF INTEREST

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

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