Enhancing Flocculation Kinetics Assessment: Integrating Aggregate Size Distribution into Experimental and Modelling Frameworks

Rodrigo Moruzzi; Andre Luiz de Oliveira; Soroosh Sharifi; Abayomi Bankole; Luiza C. Campos

doi:10.1016/j.jwpe.2024.105433

Enhancing Flocculation Kinetics Assessment: Integrating Aggregate Size Distribution into Experimental and Modelling Frameworks

Rodrigo Moruzzi^*, Andre Luiz de Oliveira, Soroosh Sharifi, Abayomi Bankole^*, Luiza C. Campos

^*Corresponding author for this work

Civil Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Flocculation is crucial in drinking water treatment, yet conventional techniques like jar tests may lack precision in capturing particle heterogeneity. To overcome this, a non-intrusive image-based system was employed to directly assess flocculation using aggregate size distribution (ASD). Integrating ASD into a kinetic model with a single parameter (β) allowed for tracking ASD during flocculation. Bench and pilot-plant scale experiments validated our approach. Sensitivity analysis confirmed β's responsiveness to ASD variations (r > 0.92), with modelling indicating errors averaging around 5%, underscoring its efficacy in assessing flocculation efficiency. Linking ASD coefficients from bench to pilot-scale models facilitates predicting flocculation performance.

Original language	English
Article number	105433
Number of pages	11
Journal	Journal of Water Process Engineering
Volume	63
Early online date	6 May 2024
DOIs	https://doi.org/10.1016/j.jwpe.2024.105433
Publication status	Published - Jun 2024

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title = "Enhancing Flocculation Kinetics Assessment: Integrating Aggregate Size Distribution into Experimental and Modelling Frameworks",

abstract = "Flocculation is crucial in drinking water treatment, yet conventional techniques like jar tests may lack precision in capturing particle heterogeneity. To overcome this, a non-intrusive image-based system was employed to directly assess flocculation using aggregate size distribution (ASD). Integrating ASD into a kinetic model with a single parameter (β) allowed for tracking ASD during flocculation. Bench and pilot-plant scale experiments validated our approach. Sensitivity analysis confirmed β's responsiveness to ASD variations (r > 0.92), with modelling indicating errors averaging around 5%, underscoring its efficacy in assessing flocculation efficiency. Linking ASD coefficients from bench to pilot-scale models facilitates predicting flocculation performance.",

author = "Rodrigo Moruzzi and {de Oliveira}, {Andre Luiz} and Soroosh Sharifi and Abayomi Bankole and Campos, {Luiza C.}",

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T2 - Integrating Aggregate Size Distribution into Experimental and Modelling Frameworks

AU - Moruzzi, Rodrigo

AU - de Oliveira, Andre Luiz

AU - Sharifi, Soroosh

AU - Bankole, Abayomi

AU - Campos, Luiza C.

PY - 2024/6

Y1 - 2024/6

N2 - Flocculation is crucial in drinking water treatment, yet conventional techniques like jar tests may lack precision in capturing particle heterogeneity. To overcome this, a non-intrusive image-based system was employed to directly assess flocculation using aggregate size distribution (ASD). Integrating ASD into a kinetic model with a single parameter (β) allowed for tracking ASD during flocculation. Bench and pilot-plant scale experiments validated our approach. Sensitivity analysis confirmed β's responsiveness to ASD variations (r > 0.92), with modelling indicating errors averaging around 5%, underscoring its efficacy in assessing flocculation efficiency. Linking ASD coefficients from bench to pilot-scale models facilitates predicting flocculation performance.

AB - Flocculation is crucial in drinking water treatment, yet conventional techniques like jar tests may lack precision in capturing particle heterogeneity. To overcome this, a non-intrusive image-based system was employed to directly assess flocculation using aggregate size distribution (ASD). Integrating ASD into a kinetic model with a single parameter (β) allowed for tracking ASD during flocculation. Bench and pilot-plant scale experiments validated our approach. Sensitivity analysis confirmed β's responsiveness to ASD variations (r > 0.92), with modelling indicating errors averaging around 5%, underscoring its efficacy in assessing flocculation efficiency. Linking ASD coefficients from bench to pilot-scale models facilitates predicting flocculation performance.

UR - https://www.sciencedirect.com/science/article/pii/S2214714424006652

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M3 - Article

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JO - Journal of Water Process Engineering

JF - Journal of Water Process Engineering

M1 - 105433

ER -

Enhancing Flocculation Kinetics Assessment: Integrating Aggregate Size Distribution into Experimental and Modelling Frameworks

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