Experiments on floating bed rotating drums using magnetic particle tracking

Tim M.J. Nijssen; Mark A.H. van Dijk; Hans A.M. Kuipers; Jan van der Stel; Allert T. Adema; Kay A. Buist

doi:10.1002/aic.17627

Experiments on floating bed rotating drums using magnetic particle tracking

Tim M.J. Nijssen
, Mark A.H. van Dijk
, Hans A.M. Kuipers
, Jan van der Stel
, Allert T. Adema
, Kay A. Buist (Corresponding author)

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

14 Citations (Scopus)

142 Downloads (Pure)

Abstract

Magnetic particle tracking (MPT) was employed to study a rotating drum filled with cork particles, using both air and water as interstitial medium. This noninvasive monitoring technique allows for the tracking of both particle translation and rotation in dry granular and liquid–solid systems. Measurements on the dry and floating bed rotating drum were compared and detailed analysis of the bed shape and velocity profiles was performed. It was found that the change of particle–wall and particle–particle interaction caused by the presence of water significantly affects the bed behavior. The decreased friction leads to slipping of the particles with respect to the wall, rendering the circulation rate largely insensitive to increased drum speed. It was also found that the liquid–particle interaction is determining for the behavior of the flowing layer. The well-defined experiments and in-depth characterization performed in this study provide an excellent validation case for multiphase flow models.

Original language	English
Article number	e17627
Number of pages	11
Journal	AIChE Journal
Volume	68
Issue number	5
DOIs	https://doi.org/10.1002/aic.17627
Publication status	Published - May 2022

Bibliographical note

Funding Information:
The authors thank Tata Steel Europe for their financial support for this project. This research was carried out under project number S16046 in the framework of the Partnership Program of the Materials innovation institute M2i ( www.m2i.nl ) and the Technology Foundation STW ( www.stw.nl ), which is part of the Netherlands Organization for Scientific Research ( www.nwo.nl ).

Funding

The authors thank Tata Steel Europe for their financial support for this project. This research was carried out under project number S16046 in the framework of the Partnership Program of the Materials innovation institute M2i ( www.m2i.nl ) and the Technology Foundation STW ( www.stw.nl ), which is part of the Netherlands Organization for Scientific Research ( www.nwo.nl ).

Keywords

floating particle bed
liquid–solid systems
magnetic particle tracking
particle dynamics
rotating drum

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title = "Experiments on floating bed rotating drums using magnetic particle tracking",

abstract = "Magnetic particle tracking (MPT) was employed to study a rotating drum filled with cork particles, using both air and water as interstitial medium. This noninvasive monitoring technique allows for the tracking of both particle translation and rotation in dry granular and liquid–solid systems. Measurements on the dry and floating bed rotating drum were compared and detailed analysis of the bed shape and velocity profiles was performed. It was found that the change of particle–wall and particle–particle interaction caused by the presence of water significantly affects the bed behavior. The decreased friction leads to slipping of the particles with respect to the wall, rendering the circulation rate largely insensitive to increased drum speed. It was also found that the liquid–particle interaction is determining for the behavior of the flowing layer. The well-defined experiments and in-depth characterization performed in this study provide an excellent validation case for multiphase flow models.",

keywords = "floating particle bed, liquid–solid systems, magnetic particle tracking, particle dynamics, rotating drum",

author = "Nijssen, \{Tim M.J.\} and \{van Dijk\}, \{Mark A.H.\} and Kuipers, \{Hans A.M.\} and \{van der Stel\}, Jan and Adema, \{Allert T.\} and Buist, \{Kay A.\}",

note = "Funding Information: The authors thank Tata Steel Europe for their financial support for this project. This research was carried out under project number S16046 in the framework of the Partnership Program of the Materials innovation institute M2i ( www.m2i.nl ) and the Technology Foundation STW ( www.stw.nl ), which is part of the Netherlands Organization for Scientific Research ( www.nwo.nl ). ",

year = "2022",

month = may,

doi = "10.1002/aic.17627",

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AU - Nijssen, Tim M.J.

AU - van Dijk, Mark A.H.

AU - Kuipers, Hans A.M.

AU - van der Stel, Jan

AU - Adema, Allert T.

AU - Buist, Kay A.

N1 - Funding Information: The authors thank Tata Steel Europe for their financial support for this project. This research was carried out under project number S16046 in the framework of the Partnership Program of the Materials innovation institute M2i ( www.m2i.nl ) and the Technology Foundation STW ( www.stw.nl ), which is part of the Netherlands Organization for Scientific Research ( www.nwo.nl ).

PY - 2022/5

Y1 - 2022/5

N2 - Magnetic particle tracking (MPT) was employed to study a rotating drum filled with cork particles, using both air and water as interstitial medium. This noninvasive monitoring technique allows for the tracking of both particle translation and rotation in dry granular and liquid–solid systems. Measurements on the dry and floating bed rotating drum were compared and detailed analysis of the bed shape and velocity profiles was performed. It was found that the change of particle–wall and particle–particle interaction caused by the presence of water significantly affects the bed behavior. The decreased friction leads to slipping of the particles with respect to the wall, rendering the circulation rate largely insensitive to increased drum speed. It was also found that the liquid–particle interaction is determining for the behavior of the flowing layer. The well-defined experiments and in-depth characterization performed in this study provide an excellent validation case for multiphase flow models.

AB - Magnetic particle tracking (MPT) was employed to study a rotating drum filled with cork particles, using both air and water as interstitial medium. This noninvasive monitoring technique allows for the tracking of both particle translation and rotation in dry granular and liquid–solid systems. Measurements on the dry and floating bed rotating drum were compared and detailed analysis of the bed shape and velocity profiles was performed. It was found that the change of particle–wall and particle–particle interaction caused by the presence of water significantly affects the bed behavior. The decreased friction leads to slipping of the particles with respect to the wall, rendering the circulation rate largely insensitive to increased drum speed. It was also found that the liquid–particle interaction is determining for the behavior of the flowing layer. The well-defined experiments and in-depth characterization performed in this study provide an excellent validation case for multiphase flow models.

KW - floating particle bed

KW - liquid–solid systems

KW - magnetic particle tracking

KW - particle dynamics

KW - rotating drum

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DO - 10.1002/aic.17627

M3 - Article

AN - SCOPUS:85124709309

SN - 0001-1541

VL - 68

JO - AIChE Journal

JF - AIChE Journal

IS - 5

M1 - e17627

ER -

Experiments on floating bed rotating drums using magnetic particle tracking

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