Quantification of greenhouse gas emission from wastewater treatment plants

Bai, Ruolin; Jin, Lei; Sun, Shichang; Cheng, Yong; Wei, Yuansong

doi:10.1002/ghg.2171

Cited by 7 publications

(2 citation statements)

References 28 publications

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“…The emissions generated on-site during the operation of the water treatment system [84][85][86] stem from chemical reactions such as alkalinity consumption by coagulants in mechanical mixing processes (e.g., rapid mixing and flocculation) [1] and are calculated based on the emissions factors for the type of coagulant used.…”

Section: Discussionmentioning

confidence: 99%

Lifecycle Assessment of Two Urban Water Treatment Plants of Pakistan

Jamil,

Pervez,

Sarwar

et al. 2023

Sustainability

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Water treatment technologies are striving to retain their ecological and economic viability despite the rising demand, conventional infrastructure, financial constraints, fluctuating climatic patterns, and highly stringent regulations. This study evaluates the lifecycle environmental impact of urban water treatment systems within the two densely populated South Asian municipalities of Islamabad and Rawalpindi, Pakistan. The scope of this study includes a process-based Life Cycle Assessment (LCA) of the entire water treatment system, particularly the resources and materials consumed during the operation of the treatment plant. The individual and cumulative environmental impact was assessed based on the treatment system data and an in-depth lifecycle inventory analysis. Other than the direct emissions to the environment, the electricity used for service and distribution pumping, coagulant use for floc formation, chlorine gas used for disinfection, and caustic soda used for pH stabilization were the processes identified as the most significant sources of emissions to air and water. The water distribution consumed up to 98% of energy resources. The highest global warming impacts (from 0.3 to 0.6 kg CO2 eq./m3) were assessed as being from the coagulation and distribution processes due to extensive electricity consumption. Direct discharge of the wash and wastewater to the open environment contributed approximately 0.08% of kg-N and 0.002% of kg-P to the eutrophication potential. The outcome of this study resulted in a thorough lifecycle inventory development, including possible alternatives to enhance system sustainability. A definite gap was identified in intermittent sampling at the treatment systems. However, more stringent sampling including the emissions to air can provide a better sustainability score for each unit process.

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Section: Discussionmentioning

confidence: 99%

Lifecycle Assessment of Two Urban Water Treatment Plants of Pakistan

Jamil,

Pervez,

Sarwar

et al. 2023

Sustainability

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“…Anaerobic digesters generate a great deal of biogas (CH 4 ), which is typically used as a fuel source for the boilers maintaining adequate operating temperatures in the digesters, with the excess biogas flared to convert CH 4 to CO 2 , reducing the GHG potential as well as increasing safety. Current biogas flares can vary in terms of performance with respect to local conditions such as the methane content of the gas being flared, the configuration of the flare stack, and the local wind conditions [ 30 , 31 ]. Generally, well-operated flares can be assumed to have conversion efficiencies of 96%–98% [ 30 ].…”

Section: Economic and Environmental Impact Analysismentioning

confidence: 99%

Waste Activated Sludge-High Rate (WASHR) Treatment Process: A Novel, Economically Viable, and Environmentally Sustainable Method to Co-Treat High-Strength Wastewaters at Municipal Wastewater Treatment Plants

Johnson,

Mehrvar

2023

Bioengineering

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High-strength wastewaters from a variety of sources, including the food industry, domestic septage, and landfill leachate, are often hauled to municipal wastewater treatment plants (WWTPs) for co-treatment. Due to their high organic loadings, these wastewaters can cause process upsets in both a WWTP’s liquid and solids treatment trains and consume organic treatment capacity, leaving less capacity available to service customers in the catchment area. A novel pre-treatment method, the Waste Activated Sludge-High Rate (WASHR) process, is proposed to optimize the co-treatment of high-strength wastewaters. The WASHR process combines the contact stabilization and sequencing batch reactor processes. It utilizes waste activated sludge from a municipal WWTP as its biomass source, allowing for a rapid start-up. Bench-scale treatment trials of winery wastewater confirm the WASHR process can reduce loadings on the downstream WWTP’s liquid and solids treatment trains. A case study approach is used to confirm the economic viability and environmental sustainability of the WASHR process compared to direct co-treatment, using life-cycle cost analyses and greenhouse gas emissions estimates.

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