Traveling column for comparison of invasive and non-invasive fluidization voidage measurement techniques

K. Dubrawski; S. Tebianian; H. T. Bi; J. Chaouki; N. Ellis; R. Gerspacher; R. Jafari; A. Kantzas; C. Lim; G. S. Patience; T. Pugsley; M. Z. Qi; J. X. Zhu; J. R. Grace

doi:10.1016/j.powtec.2012.10.031

Traveling column for comparison of invasive and non-invasive fluidization voidage measurement techniques

K. Dubrawski, S. Tebianian, H. T. Bi, J. Chaouki, N. Ellis, R. Gerspacher, R. Jafari, A. Kantzas, C. Lim, G. S. Patience, T. Pugsley, M. Z. Qi, J. X. Zhu, J. R. Grace

Research output: Journal Publication › Article › peer-review

73 Citations (Scopus)

Abstract

This paper compares invasive and non-invasive voidage measurement techniques from five different Canadian laboratories for the determination of local voidage profiles in gas-fluidized beds of 104 μm Fluid Cracking Catalyst (FCC) and 332 μm silica sand in a column of 133. mm i.d. A novel modular system and auxiliary components were designed and constructed to facilitate transportation to, and deployment at, different research centers. Profiles of time-averaged voidage were determined by optical fiber probes, dynamic pressure measurements, electrical capacitance tomography, X-ray computed tomography and radioactive particle tracking by researchers from different research groups. These results are compared with average measurements from pressure gradients and overall bed expansion. Results were kept separate from each other in a double-blind method. There is general, but imperfect, agreement among the different methods for average voidage for both the FCC and silica sand. Invasive probes gave similar results and scatter to non-invasive techniques.

Original language	English
Pages (from-to)	203-220
Number of pages	18
Journal	Powder Technology
Volume	235
DOIs	https://doi.org/10.1016/j.powtec.2012.10.031
Publication status	Published - Feb 2013
Externally published	Yes

Keywords

Electrical capacitance tomography
Fluidized beds
Hydrodynamic database
Optical fiber probes
Radioactive particle tracking
X-ray computed tomography

ASJC Scopus subject areas

General Chemical Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.powtec.2012.10.031

Cite this

Dubrawski, K., Tebianian, S., Bi, H. T., Chaouki, J., Ellis, N., Gerspacher, R., Jafari, R., Kantzas, A., Lim, C., Patience, G. S., Pugsley, T., Qi, M. Z., Zhu, J. X., & Grace, J. R. (2013). Traveling column for comparison of invasive and non-invasive fluidization voidage measurement techniques. Powder Technology, 235, 203-220. https://doi.org/10.1016/j.powtec.2012.10.031

@article{e21e203a6cb8413ca91b60d42bede463,

title = "Traveling column for comparison of invasive and non-invasive fluidization voidage measurement techniques",

abstract = "This paper compares invasive and non-invasive voidage measurement techniques from five different Canadian laboratories for the determination of local voidage profiles in gas-fluidized beds of 104 μm Fluid Cracking Catalyst (FCC) and 332 μm silica sand in a column of 133. mm i.d. A novel modular system and auxiliary components were designed and constructed to facilitate transportation to, and deployment at, different research centers. Profiles of time-averaged voidage were determined by optical fiber probes, dynamic pressure measurements, electrical capacitance tomography, X-ray computed tomography and radioactive particle tracking by researchers from different research groups. These results are compared with average measurements from pressure gradients and overall bed expansion. Results were kept separate from each other in a double-blind method. There is general, but imperfect, agreement among the different methods for average voidage for both the FCC and silica sand. Invasive probes gave similar results and scatter to non-invasive techniques.",

keywords = "Electrical capacitance tomography, Fluidized beds, Hydrodynamic database, Optical fiber probes, Radioactive particle tracking, X-ray computed tomography",

author = "K. Dubrawski and S. Tebianian and Bi, {H. T.} and J. Chaouki and N. Ellis and R. Gerspacher and R. Jafari and A. Kantzas and C. Lim and Patience, {G. S.} and T. Pugsley and Qi, {M. Z.} and Zhu, {J. X.} and Grace, {J. R.}",

note = "Funding Information: The authors thank Kyla Clarke (UofS), Bangyou Wu (UofC) and Ebrahim Alizadeh (Poly) for their assistance. We are also grateful to the Natural Sciences and Engineering Research Council of Canada for an RTI grant, making it possible to build the equipment, and for Discovery grant funding which assisted in supporting graduate students and in covering transportation, travel and operation of the equipment. Finally, we acknowledge helpful input from Coanda Research & Development in the design, construction and commissioning of the travelling experimental facility.",

year = "2013",

month = feb,

doi = "10.1016/j.powtec.2012.10.031",

language = "English",

volume = "235",

pages = "203--220",

journal = "Powder Technology",

issn = "0032-5910",

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AU - Dubrawski, K.

AU - Tebianian, S.

AU - Bi, H. T.

AU - Chaouki, J.

AU - Ellis, N.

AU - Gerspacher, R.

AU - Jafari, R.

AU - Kantzas, A.

AU - Lim, C.

AU - Patience, G. S.

AU - Pugsley, T.

AU - Qi, M. Z.

AU - Zhu, J. X.

AU - Grace, J. R.

N1 - Funding Information: The authors thank Kyla Clarke (UofS), Bangyou Wu (UofC) and Ebrahim Alizadeh (Poly) for their assistance. We are also grateful to the Natural Sciences and Engineering Research Council of Canada for an RTI grant, making it possible to build the equipment, and for Discovery grant funding which assisted in supporting graduate students and in covering transportation, travel and operation of the equipment. Finally, we acknowledge helpful input from Coanda Research & Development in the design, construction and commissioning of the travelling experimental facility.

PY - 2013/2

Y1 - 2013/2

N2 - This paper compares invasive and non-invasive voidage measurement techniques from five different Canadian laboratories for the determination of local voidage profiles in gas-fluidized beds of 104 μm Fluid Cracking Catalyst (FCC) and 332 μm silica sand in a column of 133. mm i.d. A novel modular system and auxiliary components were designed and constructed to facilitate transportation to, and deployment at, different research centers. Profiles of time-averaged voidage were determined by optical fiber probes, dynamic pressure measurements, electrical capacitance tomography, X-ray computed tomography and radioactive particle tracking by researchers from different research groups. These results are compared with average measurements from pressure gradients and overall bed expansion. Results were kept separate from each other in a double-blind method. There is general, but imperfect, agreement among the different methods for average voidage for both the FCC and silica sand. Invasive probes gave similar results and scatter to non-invasive techniques.

AB - This paper compares invasive and non-invasive voidage measurement techniques from five different Canadian laboratories for the determination of local voidage profiles in gas-fluidized beds of 104 μm Fluid Cracking Catalyst (FCC) and 332 μm silica sand in a column of 133. mm i.d. A novel modular system and auxiliary components were designed and constructed to facilitate transportation to, and deployment at, different research centers. Profiles of time-averaged voidage were determined by optical fiber probes, dynamic pressure measurements, electrical capacitance tomography, X-ray computed tomography and radioactive particle tracking by researchers from different research groups. These results are compared with average measurements from pressure gradients and overall bed expansion. Results were kept separate from each other in a double-blind method. There is general, but imperfect, agreement among the different methods for average voidage for both the FCC and silica sand. Invasive probes gave similar results and scatter to non-invasive techniques.

KW - Electrical capacitance tomography

KW - Fluidized beds

KW - Hydrodynamic database

KW - Optical fiber probes

KW - Radioactive particle tracking

KW - X-ray computed tomography

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DO - 10.1016/j.powtec.2012.10.031

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SN - 0032-5910

VL - 235

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EP - 220

JO - Powder Technology

JF - Powder Technology

ER -

Traveling column for comparison of invasive and non-invasive fluidization voidage measurement techniques

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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