Opportunities to improve energy use in urban wastewater treatment: a European-scale analysis

Ganora, Daniele; Hospido, Almudena; Husemann, Jovana; Krampe, Jörg; Loderer, Christian; Longo, Stefano B.; Bouyat, Lucas Moragas; Obermaier, Nathan; Piraccini, Enrico; Stanev, Stanislav; Váci, László; Pistocchi, Alberto

doi:10.1088/1748-9326/ab0b54

Cited by 36 publications

(12 citation statements)

References 34 publications

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“…While conventional wastewater treatment with the activated sludge system (mechanical, biological and chemical) was well established by the end of the 1990s [1], new issues have risen to the center of attention in the 21st century. The reduction of energy consumption [2,3], stricter effluent quality requirements for carbon and nutrients [4], the recovery of resources [5,6], wastewater reuse [7,8] and the removal of contaminants of emerging concern [9] and of antibiotic resistant genes [10,11] are only some of the new challenges to be addressed. This multitude of new tasks will in some cases not support themselves economically and might have negative side effects on the environment due to higher energy and/or material demands [12].…”

Section: Introductionmentioning

confidence: 99%

Operation and Performance of Austrian Wastewater and Sewage Sludge Treatment as a Basis for Resource Optimization

Amann

Weber

Krampe

et al. 2021

Water

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Recent years came with a paradigm shift for wastewater treatment plants (WWTPs) to extend the sole purpose of contaminant removal to an additional function as resource recovery facilities. This shift is accompanied by the development of new European legislation towards better inclusion of resource recovery from wastewater. However, long operational lifespans and a multitude of treatment requirements demand thorough investigations into how resource recovery can be implemented sustainably. To aid the formulation of new legislation for phosphorus (P) recovery specifically, in 2017 we conducted a survey on Austrian WWTP-infrastructure, with a focus on P removal and sludge treatment, as well as disposal and sludge quality of all WWTPs above 2000 population equivalents (PE). Data were prepared for analysis, checked for completeness and cross-checked for plausibility. This study presents the major findings from this database and draws essential conclusions for the future recovery of P from wastewater. We see results from this study as useful to other countries, describing the current state of the art in Austria and potentially aiding in developing wastewater treatment and P recovery strategies.

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Section: Introductionmentioning

confidence: 99%

Operation and Performance of Austrian Wastewater and Sewage Sludge Treatment as a Basis for Resource Optimization

Amann

Weber

Krampe

et al. 2021

Water

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“…135 The European research project Powerstep is currently elaborating designs for energyneutral and energy-positive WWTPs through six different case studies. 136 The recovery of methane to generate electricity can usually offset 25-50% of a WWTP's energy needs, assuming that conventional treatment technology is used. 40 If thermal energy recovery from effluent is applied along with chemical energy recovery, carbon neutrality or better can be achieved.…”

Section: Summary: Energy Recoverymentioning

confidence: 99%

A critical review of resource recovery from municipal wastewater treatment plants – market supply potentials, technologies and bottlenecks

Kehrein

Loosdrecht

Osseweijer

et al. 2020

Environ. Sci.: Water Res. Technol.

254

169

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“…Furthermore, in practice, the energy demand is inversely proportional to the treatment capacity of the plant, for capacities below approximately 38,000 m 3 /d or 190,000 PE-for 200 L/(PE•d) [1]. This is also observed in Europe, where plants smaller than 50,000 PE represent almost 90% of the total number of plants, but process only 31% of the PE and require 42% of the electricity use [6].…”

Section: Introduction 1energy Consumption and Energy Efficiency In Wwtpmentioning

confidence: 99%

“…Therefore, in optimisation studies, these are usually the first consumers to pay attention to. It is estimated that WWTPs represent about 1-3% of the overall energy use of country [5]; in Europe, the overall electricity use of WWTPs > 2000 PE, is about 0.8% of t total electricity consumption in the EU-28 [6]. Furthermore, in practice, the ener demand is inversely proportional to the treatment capacity of the plant, for capacit below approximately 38,000 m 3 /d or 190,000 PE-for 200 L/(PE•d) [1].…”

Section: Introduction 1energy Consumption and Energy Efficiency In Wwtpmentioning

confidence: 99%

Modelling to Lower Energy Consumption in a Large WWTP in China While Optimising Nitrogen Removal

et al. 2021

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In the last decade, China has sharply tightened the monitoring values for wastewater treatment plants (WWTPs). In some regions with sensitive discharge water bodies, the values (24 h composite sample) must be 1.5 mg/L for NH4-N and 10 mg/L for total nitrogen since 2021. Even with the previously less strict monitoring values, around 50% of the wastewater treatment plants in China were permanently unable to comply with the nitrogen monitoring values. Due to the rapid changes on-site to meet the threshold values and the strong relation to energy-intensive aeration strategies to sufficiently remove nitrogen, WWTPs do not always work energy-efficiently. A Chinese WWTP (450,000 Population equivalents or PE) with upstream denitrification, a tertiary treatment stage for phosphorus removal and disinfection, and aerobic sludge stabilisation was modelled in order to test various concepts for operation optimisation to lower energy consumption while meeting and undercutting effluent requirements. Following a comprehensive analysis of operating data, the WWTP was modelled and calibrated. Based on the calibrated model, various approaches for optimising nitrogen elimination were tested, including operational and automation strategies for aeration control. After several tests, a combination of strategies (i.e., partial by-pass of primary clarifiers, NH4-N based control, increase in the denitrification capacity, intermittent denitrification) reduced the air demand by up to 24% and at the same time significantly improved compliance with the monitoring values (up to 80% less norm non-compliances). By incorporating the impact of the strategies on related processes, like the bypass of primary settling tanks, energy consumption could be reduced by almost 25%. Many of the elaborated strategies can be transferred to WWTPs with similar boundary conditions and strict effluent values worldwide.

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Opportunities to improve energy use in urban wastewater treatment: a European-scale analysis

Cited by 36 publications

References 34 publications

Operation and Performance of Austrian Wastewater and Sewage Sludge Treatment as a Basis for Resource Optimization

Operation and Performance of Austrian Wastewater and Sewage Sludge Treatment as a Basis for Resource Optimization

A critical review of resource recovery from municipal wastewater treatment plants – market supply potentials, technologies and bottlenecks

Modelling to Lower Energy Consumption in a Large WWTP in China While Optimising Nitrogen Removal

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