Material Properties in Cake Filtration – Discrete Element Simulation of Compression-Permeability Cells

Tiaan Friedrich; Michael Kuhn; Daniel Schiochet Nasato; Heiko Briesen

doi:10.1002/ceat.202100476

Material Properties in Cake Filtration – Discrete Element Simulation of Compression-Permeability Cells

Tiaan Friedrich, Michael Kuhn, Daniel Schiochet Nasato, Heiko Briesen

Chair of Process Systems Engineering

Technical University of Munich

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

3 Scopus citations

Abstract

This simulation study investigates the impact of material properties on the behavior of compressible filter cakes. A compression-permeability (CP) cell is used as a standard experimental technique for characterizing compressible cakes. It contains a bidisperse particle packing simulated by the discrete element method. Using this setup, a set of crucial material properties is varied and their influence on the macroscopic compression behavior as described by established fitting equations is studied. Sobol's sensitivity analysis is performed, and the results indicate that Young's modulus, the coefficient of sliding friction, and the surface energy density have the strongest impact on cake solidity and compressibility.

Original language	English
Pages (from-to)	898-906
Number of pages	9
Journal	Chemical Engineering and Technology
Volume	45
Issue number	5
DOIs	https://doi.org/10.1002/ceat.202100476
State	Published - May 2022

Keywords

Compressible filter cake
Compression-permeability cell
Discrete element method
Filtration
Global sensitivity analysis

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10.1002/ceat.202100476

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title = "Material Properties in Cake Filtration – Discrete Element Simulation of Compression-Permeability Cells",

abstract = "This simulation study investigates the impact of material properties on the behavior of compressible filter cakes. A compression-permeability (CP) cell is used as a standard experimental technique for characterizing compressible cakes. It contains a bidisperse particle packing simulated by the discrete element method. Using this setup, a set of crucial material properties is varied and their influence on the macroscopic compression behavior as described by established fitting equations is studied. Sobol's sensitivity analysis is performed, and the results indicate that Young's modulus, the coefficient of sliding friction, and the surface energy density have the strongest impact on cake solidity and compressibility.",

keywords = "Compressible filter cake, Compression-permeability cell, Discrete element method, Filtration, Global sensitivity analysis",

author = "Tiaan Friedrich and Michael Kuhn and Nasato, {Daniel Schiochet} and Heiko Briesen",

note = "Publisher Copyright: {\textcopyright} 2022 The Authors. Chemical Engineering & Technology published by Wiley-VCH GmbH.",

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T1 - Material Properties in Cake Filtration – Discrete Element Simulation of Compression-Permeability Cells

AU - Friedrich, Tiaan

AU - Kuhn, Michael

AU - Nasato, Daniel Schiochet

AU - Briesen, Heiko

PY - 2022/5

Y1 - 2022/5

N2 - This simulation study investigates the impact of material properties on the behavior of compressible filter cakes. A compression-permeability (CP) cell is used as a standard experimental technique for characterizing compressible cakes. It contains a bidisperse particle packing simulated by the discrete element method. Using this setup, a set of crucial material properties is varied and their influence on the macroscopic compression behavior as described by established fitting equations is studied. Sobol's sensitivity analysis is performed, and the results indicate that Young's modulus, the coefficient of sliding friction, and the surface energy density have the strongest impact on cake solidity and compressibility.

AB - This simulation study investigates the impact of material properties on the behavior of compressible filter cakes. A compression-permeability (CP) cell is used as a standard experimental technique for characterizing compressible cakes. It contains a bidisperse particle packing simulated by the discrete element method. Using this setup, a set of crucial material properties is varied and their influence on the macroscopic compression behavior as described by established fitting equations is studied. Sobol's sensitivity analysis is performed, and the results indicate that Young's modulus, the coefficient of sliding friction, and the surface energy density have the strongest impact on cake solidity and compressibility.

KW - Compressible filter cake

KW - Compression-permeability cell

KW - Discrete element method

KW - Filtration

KW - Global sensitivity analysis

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JO - Chemical Engineering and Technology

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ER -

Material Properties in Cake Filtration – Discrete Element Simulation of Compression-Permeability Cells

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