Evaluation of Mixing Effects and Particle Breakage on a Cross Flow Turbine with DEM

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Evaluation of Mixing Effects and Particle Breakage on a Cross Flow Turbine with DEM. / Denzel, Michael; Prenner, Michael; Sifferlinger, Nikolaus August.
in: Berg- und hüttenmännische Monatshefte : BHM, Jahrgang 169.2024, Nr. 4, 02.2024, S. 211-220.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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@article{6bb99633357944dab1d84a22d811b7d5,
title = "Evaluation of Mixing Effects and Particle Breakage on a Cross Flow Turbine with DEM",
abstract = "Various effects during conveying and storage processes lead to size segregation of bulk material, but many applications require a mostly constant particle size distribution. Especially during bunker filling, segregation effects are noticed, which are further intensified by possible core flow effects. In order to reduce segregation effects during bunker filling, a cross flow turbine is installed at a bunker used for storage of blast furnace sinter. In this contribution, discrete element simulations were performed to analyze mixing effects and possible particle breakage due to the cross flow turbine. Significant mixing effects during bunker filling are noticed due to the cross flow turbine. The results show a more evenly distributed bunker outflow in terms of particle size.Particle breakage is analyzed by means of a newly developed breakage model for the Discrete Element Method (DEM). The model is based on a probabilistic particle replacement with voronoi-tessellated fragments. The validated breakage model allows high accuracy in prediction of fragment size distribution. Fragments are further breakable, which allows simulation of processes with several damaging effects. The breakage model was calibrated with a specially developed automated single particle impact tester for rapid analysis of breakage characteristics of bulk materials.",
keywords = "Size segregation, Particle size distribution, Mixing equipment, Blending equipment, Discrete element method, Bunker filling, Bulk storage, Blast furnace sinter",
author = "Michael Denzel and Michael Prenner and Sifferlinger, {Nikolaus August}",
year = "2024",
month = feb,
doi = "10.1007/s00501-024-01442-y",
language = "English",
volume = "169.2024",
pages = "211--220",
journal = "Berg- und h{\"u}ttenm{\"a}nnische Monatshefte : BHM",
issn = "0005-8912",
publisher = "Springer Wien",
number = "4",

}

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TY - JOUR

T1 - Evaluation of Mixing Effects and Particle Breakage on a Cross Flow Turbine with DEM

AU - Denzel, Michael

AU - Prenner, Michael

AU - Sifferlinger, Nikolaus August

PY - 2024/2

Y1 - 2024/2

N2 - Various effects during conveying and storage processes lead to size segregation of bulk material, but many applications require a mostly constant particle size distribution. Especially during bunker filling, segregation effects are noticed, which are further intensified by possible core flow effects. In order to reduce segregation effects during bunker filling, a cross flow turbine is installed at a bunker used for storage of blast furnace sinter. In this contribution, discrete element simulations were performed to analyze mixing effects and possible particle breakage due to the cross flow turbine. Significant mixing effects during bunker filling are noticed due to the cross flow turbine. The results show a more evenly distributed bunker outflow in terms of particle size.Particle breakage is analyzed by means of a newly developed breakage model for the Discrete Element Method (DEM). The model is based on a probabilistic particle replacement with voronoi-tessellated fragments. The validated breakage model allows high accuracy in prediction of fragment size distribution. Fragments are further breakable, which allows simulation of processes with several damaging effects. The breakage model was calibrated with a specially developed automated single particle impact tester for rapid analysis of breakage characteristics of bulk materials.

AB - Various effects during conveying and storage processes lead to size segregation of bulk material, but many applications require a mostly constant particle size distribution. Especially during bunker filling, segregation effects are noticed, which are further intensified by possible core flow effects. In order to reduce segregation effects during bunker filling, a cross flow turbine is installed at a bunker used for storage of blast furnace sinter. In this contribution, discrete element simulations were performed to analyze mixing effects and possible particle breakage due to the cross flow turbine. Significant mixing effects during bunker filling are noticed due to the cross flow turbine. The results show a more evenly distributed bunker outflow in terms of particle size.Particle breakage is analyzed by means of a newly developed breakage model for the Discrete Element Method (DEM). The model is based on a probabilistic particle replacement with voronoi-tessellated fragments. The validated breakage model allows high accuracy in prediction of fragment size distribution. Fragments are further breakable, which allows simulation of processes with several damaging effects. The breakage model was calibrated with a specially developed automated single particle impact tester for rapid analysis of breakage characteristics of bulk materials.

KW - Size segregation

KW - Particle size distribution

KW - Mixing equipment

KW - Blending equipment

KW - Discrete element method

KW - Bunker filling

KW - Bulk storage

KW - Blast furnace sinter

U2 - 10.1007/s00501-024-01442-y

DO - 10.1007/s00501-024-01442-y

M3 - Article

VL - 169.2024

SP - 211

EP - 220

JO - Berg- und hüttenmännische Monatshefte : BHM

JF - Berg- und hüttenmännische Monatshefte : BHM

SN - 0005-8912

IS - 4

ER -