The present paper discusses issues, scenarios, new ideas and processes with the specific purpose of quantitatively evaluating the feasibility of applying industrial symbiosis (IS) to regions where Waste-to-Energy (WtE) processes are not fully utilised (e.g. many Mediterranean regions), in order to exploit the potential synergies between 1) wastewater treatment (WWT), 2) WtE and 3) Anaerobic Digestion (AD) processes in a new, holistic approach that is able to maximise the efficient use of resources, while reducing the current environmental impacts.The enormous energy that can be obtained from residual waste is partially used, through an IS-based bio-refinery approach, to thermally support the AD and drying processes of organic waste and sludge, thereby allowing 100% of the increased biogas production to be upgraded to biomethane. The need to landfill can be reduced to less than 5-10%, which allows the 2035 EU target to be achieved, with relevant economic and environmental benefits.Electricity from the WtE plant is exploited to supply the utilities of the 3 main processes and in particular to lower the costs of the required tertiary WWT and wastewater pumping phases in order to make the reclaimed water cost competitive with that of conventional water resources and thus to make this marginal water resource fully sustainable. The proposed approach can be applied in numerous countries, where landfilling is still predominant, to help stakeholders favouring a cultural shift towards a more sustainable, integrated waste/wastewater management while lowering the sterile "Not In Anyone's BackYard" (NIABY) opposition to WtE plants.

A water-waste-energy nexus approach to bridge the sustainability gap in landfill-based waste management regions

Bolzonella, D.;
2021-01-01

Abstract

The present paper discusses issues, scenarios, new ideas and processes with the specific purpose of quantitatively evaluating the feasibility of applying industrial symbiosis (IS) to regions where Waste-to-Energy (WtE) processes are not fully utilised (e.g. many Mediterranean regions), in order to exploit the potential synergies between 1) wastewater treatment (WWT), 2) WtE and 3) Anaerobic Digestion (AD) processes in a new, holistic approach that is able to maximise the efficient use of resources, while reducing the current environmental impacts.The enormous energy that can be obtained from residual waste is partially used, through an IS-based bio-refinery approach, to thermally support the AD and drying processes of organic waste and sludge, thereby allowing 100% of the increased biogas production to be upgraded to biomethane. The need to landfill can be reduced to less than 5-10%, which allows the 2035 EU target to be achieved, with relevant economic and environmental benefits.Electricity from the WtE plant is exploited to supply the utilities of the 3 main processes and in particular to lower the costs of the required tertiary WWT and wastewater pumping phases in order to make the reclaimed water cost competitive with that of conventional water resources and thus to make this marginal water resource fully sustainable. The proposed approach can be applied in numerous countries, where landfilling is still predominant, to help stakeholders favouring a cultural shift towards a more sustainable, integrated waste/wastewater management while lowering the sterile "Not In Anyone's BackYard" (NIABY) opposition to WtE plants.
2021
Industrial symbiosis
Circular economy
Green deal
Waste
Wastewater
Energy
Anaerobic digestion
Waste to energy
Nexus
Sustainability
Costs
Sludge
Biogas
Wastewater reuse
Landfill
Leachate
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11562/1144827
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