Impact of oxidation processes on the composition and biodegradability of soluble organic nutrients in wastewater effluents

Tooker, Nicholas B.; Gao, Ce; Onnis‐Hayden, Annalisa; Gu, April Z.

doi:10.1002/wer.1393

Cited by 1 publication

(1 citation statement)

References 62 publications

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“…Wastewater from chemical manufacturing units, pesticide manufacturers/formulation units, oil production wells and other organic chemical processing units generate highly toxic and non-biodegradable wastewater from their operations such as solvent recovery, plant washings, vessel washings etc. This biodegradability is indicated by BOD/COD ratio (Zhang et al 2020;Saravanathamizhan & Perarasu 2021;Tooker et al 2021); thus it is expected that AOP implementation at the pre-biological stage could break down complex organics and enhance biodegradability ( Jamil et al 2011;Oller et al 2011;Vilar et al 2012). Several AOP-based treatments have been reported at t pre-biological stage for streams such as chemical wastewater (Ribeiro et al 2015;Ramteke & Gogate 2016;Oliveira Guimarães et al 2019), phenolic wastewater (Ahmed et al 2011;de Sá et al 2018;Jay et al 2019;Oliveira Guimarães et al 2019) and oil drilling effluent (Yu et al 2017;Jiménez et al 2019).…”

Section: Graphical Abstract Introductionmentioning

confidence: 99%

TERI Advanced Oxidation Technology (TADOX®) to treat industrial wastewater with integration at pre- and post-biological stage: case studies from India

Bahadur

Bhargava

2022

Water Practice and Technology

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The current problem with industrial wastewater treatment is that we rely heavily on biological treatment systems without realising that these have severe limitations in terms of shock load bearing capacities, ineffectiveness against removal of toxicity and recalcitrant and dissolved organics. However, biological systems have their own benefits as well. Therefore, it is essential to support them with integration of advanced oxidation nanotechnology (AON) interventions, which are expected to address these challenges. In this pursuit, The Energy and Resources Institute (TERI) has developed an AON based wastewater treatment technology called TERI Advanced Oxidation Technology (TADOX®). This paper presents two sections of three case studies each, to showcase how TADOX® Technology intervention at Pre-biological and post-biological treatment helps in achieving adequate treatment. In the first section, TADOX® has been implemented at pre-biological stage for three highly polluting streams from (i) phenolic wastewater from a 2,4-Dichlorophenoxyacetic acid (2,4 D) plant from a Pesticide manufacturing company, (ii) Phenolic wastewater from Anisole plant of a Chemical industry, and (iii) hydrocarbon rich effluent from Oil & Gas sector. Pre-biological integration is expected to support biological treatment by reduction in COD, toxicity, microbial growth hindering compounds and increase in biodegradability (BOD to COD ratio). The second section in the paper explores the implementation potential of TADOX® to treat biologically treated streams from (i) pharmaceutical, (ii) Tannery and (iii) slaughterhouse. The Post biological integration is expected to remove residual COD, Colour, BOD and Odour leading to treated water meeting norms for safe surface discharge and water reuse. Presented studies from India may be useful and relevant to other developing countries like Bangladesh, Sri Lanka, Vietnam, Indonesia, Taiwan etc. as a possible approach to sustainably manage water resources, together meeting the challenges of economic growth, industrial development, and environmental compliance.

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