An accurate and robust method for intensification of wastewater sludge pipe flow

Globally, environmental impacts and population growth are driving the process intensification of wastewater treatment plants (WWTPs) via transition from conventional (2–3 wt% solids) to highly concentrated (4–6 wt% solids) wastewater sludges (HCWS). This presents an industrial challenge as HCWS are...

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Bibliographic Details
Published in:The Science of the total environment 2024-11, Vol.949, p.175143, Article 175143
Main Authors: Yousuf, Noman, Kurukulasuriya, Nimmi, Chryss, Andrew, Rudman, Murray, Rees, Catherine, Usher, Shane, Farno, Ehsan, Lester, Daniel, Eshtiaghi, Nicky
Format: Article
Language:English
Subjects:
Numerical simulation
Process intensification
Rheological characterisation
Turbulence
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Summary:Globally, environmental impacts and population growth are driving the process intensification of wastewater treatment plants (WWTPs) via transition from conventional (2–3 wt% solids) to highly concentrated (4–6 wt% solids) wastewater sludges (HCWS). This presents an industrial challenge as HCWS are complex, non-Newtonian materials whose viscosity increases nonlinearly with solids concentration. This viscosity increase is particularly relevant for sludge pipe flow as it leads to considerable pumping pressure that ultimately limits the feasibility of pipe flow transportation. Hence, process intensification demands accurate prediction of HCWS turbulent pipe flow to design and optimise pumping infrastructure and piping systems. Such prediction requires accurate rheological characterisation of HCWS and numerical prediction of HCWS turbulent pipe flow, neither of which has been achieved to date due to respective limitations associated with benchtop rheometry and numerical turbulence models. We address these challenges by first developing accurate methods for rheological characterisation of HCWS via laminar flow of digested sludge at various solids concentrations (2–5 %) in a fully instrumented pipe loop facility at a large-scale WWTP. These rheological parameters are used in direct numerical simulation (DNS) computations (that avoid turbulence models) of turbulent pipe flow of HCWS. These predictions are then validated against turbulent flow pipe loop data. This method yields accurate (2–15 % error) predictions of HCWS turbulent pipe flow, compared with up to ∼75 % error for conventional pipe flow correlations. This validation highlights the need for accurate rheological characterisation and numerical simulation to predict HCWS pipe flow and provides a sound basis for the intensification and optimisation of WWTP pipeline systems. [Display omitted] •A new method is presented for intensification of wastewater sludge pipe flow.•Focus on turbulent pipe flow prediction, enabling pipeline design and optimisation.•Concentrated wastewater sludge rheology characterised from laminar pipe flow data.•Rheology and direct numerical simulation is used to predict turbulent pipe flow.•Predictions match experimental data with 2–15 % error, validating method.
ISSN:0048-9697
1879-1026
1879-1026
DOI:10.1016/j.scitotenv.2024.175143