A novel experimental technique to study single bubble-bitumen attachment in flotation

Guoxing Gu; R. Sean Sanders; K. Nandakumar; Zhenghe Xu; Jacob H. Masliyah

doi:10.1016/j.minpro.2003.08.002

A novel experimental technique to study single bubble-bitumen attachment in flotation

Guoxing Gu, R. Sean Sanders, K. Nandakumar, Zhenghe Xu, Jacob H. Masliyah^*

^*Corresponding author for this work

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

46 Scopus citations

Abstract

A novel apparatus was developed to monitor bubble-bitumen droplet attachment process and to determine induction time required for the attachment. This unique apparatus is capable of generating individual hydrogen bubbles with a desired size larger than 10 μm. Once a hydrogen bubble of a desired diameter is produced, it is released to contact a suspended bitumen droplet. The entire bubble sliding and attachment process is recorded with a high-speed digital imaging system for subsequent playback and analysis. A number of factors that affect bitumen flotation were studied with this technique, including process temperature, bubble size and aqueous phase chemistry. The induction time, which is a measure of the time required to form a stable, three-phase contact between a gas bubble and a particle or droplet in an aqueous medium, is used to quantify the attachment process. The induction time of hydrogen bubble-bitumen droplet attachment was measured as a function of temperature, bubble size and rise velocity, and aqueous phase chemistry. The results showed that higher process temperature and smaller bubble size are favorable to bitumen flotation. It was found that the maximum (critical) bubble size required for effective bitumen flotation is highly dependent on dissolved air content and ionic composition in the aqueous phase. For experiments where the aqueous phase chemistry resembled that typically found in the oil sands industry, only very small bubbles were found to attach to the bitumen droplet.

Original language	English
Pages (from-to)	15-29
Number of pages	15
Journal	International Journal of Mineral Processing
Volume	74
Issue number	1-4
DOIs	https://doi.org/10.1016/j.minpro.2003.08.002
State	Published - 19 Nov 2004
Externally published	Yes

Keywords

Attachment
Bitumen droplet
Flotation
Hydrogen bubble
Induction time

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10.1016/j.minpro.2003.08.002

Cite this

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title = "A novel experimental technique to study single bubble-bitumen attachment in flotation",

abstract = "A novel apparatus was developed to monitor bubble-bitumen droplet attachment process and to determine induction time required for the attachment. This unique apparatus is capable of generating individual hydrogen bubbles with a desired size larger than 10 μm. Once a hydrogen bubble of a desired diameter is produced, it is released to contact a suspended bitumen droplet. The entire bubble sliding and attachment process is recorded with a high-speed digital imaging system for subsequent playback and analysis. A number of factors that affect bitumen flotation were studied with this technique, including process temperature, bubble size and aqueous phase chemistry. The induction time, which is a measure of the time required to form a stable, three-phase contact between a gas bubble and a particle or droplet in an aqueous medium, is used to quantify the attachment process. The induction time of hydrogen bubble-bitumen droplet attachment was measured as a function of temperature, bubble size and rise velocity, and aqueous phase chemistry. The results showed that higher process temperature and smaller bubble size are favorable to bitumen flotation. It was found that the maximum (critical) bubble size required for effective bitumen flotation is highly dependent on dissolved air content and ionic composition in the aqueous phase. For experiments where the aqueous phase chemistry resembled that typically found in the oil sands industry, only very small bubbles were found to attach to the bitumen droplet.",

keywords = "Attachment, Bitumen droplet, Flotation, Hydrogen bubble, Induction time",

author = "Guoxing Gu and Sanders, {R. Sean} and K. Nandakumar and Zhenghe Xu and Masliyah, {Jacob H.}",

note = "Funding Information: Financial support from NSERC Industrial Research Chair in Oil Sands Engineering (held by JHM) and the Alberta Department of Energy is greatly appreciated. Also, the authors thank Robert Lopetinsky for his efforts during the early stages of this work, particularly during the development of the experimental apparatus. Support of this project by Syncrude Canada is gratefully acknowledged.",

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AU - Gu, Guoxing

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AU - Nandakumar, K.

AU - Xu, Zhenghe

AU - Masliyah, Jacob H.

N1 - Funding Information: Financial support from NSERC Industrial Research Chair in Oil Sands Engineering (held by JHM) and the Alberta Department of Energy is greatly appreciated. Also, the authors thank Robert Lopetinsky for his efforts during the early stages of this work, particularly during the development of the experimental apparatus. Support of this project by Syncrude Canada is gratefully acknowledged.

PY - 2004/11/19

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N2 - A novel apparatus was developed to monitor bubble-bitumen droplet attachment process and to determine induction time required for the attachment. This unique apparatus is capable of generating individual hydrogen bubbles with a desired size larger than 10 μm. Once a hydrogen bubble of a desired diameter is produced, it is released to contact a suspended bitumen droplet. The entire bubble sliding and attachment process is recorded with a high-speed digital imaging system for subsequent playback and analysis. A number of factors that affect bitumen flotation were studied with this technique, including process temperature, bubble size and aqueous phase chemistry. The induction time, which is a measure of the time required to form a stable, three-phase contact between a gas bubble and a particle or droplet in an aqueous medium, is used to quantify the attachment process. The induction time of hydrogen bubble-bitumen droplet attachment was measured as a function of temperature, bubble size and rise velocity, and aqueous phase chemistry. The results showed that higher process temperature and smaller bubble size are favorable to bitumen flotation. It was found that the maximum (critical) bubble size required for effective bitumen flotation is highly dependent on dissolved air content and ionic composition in the aqueous phase. For experiments where the aqueous phase chemistry resembled that typically found in the oil sands industry, only very small bubbles were found to attach to the bitumen droplet.

AB - A novel apparatus was developed to monitor bubble-bitumen droplet attachment process and to determine induction time required for the attachment. This unique apparatus is capable of generating individual hydrogen bubbles with a desired size larger than 10 μm. Once a hydrogen bubble of a desired diameter is produced, it is released to contact a suspended bitumen droplet. The entire bubble sliding and attachment process is recorded with a high-speed digital imaging system for subsequent playback and analysis. A number of factors that affect bitumen flotation were studied with this technique, including process temperature, bubble size and aqueous phase chemistry. The induction time, which is a measure of the time required to form a stable, three-phase contact between a gas bubble and a particle or droplet in an aqueous medium, is used to quantify the attachment process. The induction time of hydrogen bubble-bitumen droplet attachment was measured as a function of temperature, bubble size and rise velocity, and aqueous phase chemistry. The results showed that higher process temperature and smaller bubble size are favorable to bitumen flotation. It was found that the maximum (critical) bubble size required for effective bitumen flotation is highly dependent on dissolved air content and ionic composition in the aqueous phase. For experiments where the aqueous phase chemistry resembled that typically found in the oil sands industry, only very small bubbles were found to attach to the bitumen droplet.

KW - Attachment

KW - Bitumen droplet

KW - Flotation

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A novel experimental technique to study single bubble-bitumen attachment in flotation

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Keywords

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