Bubble shape,gas flow and gas–liquid mass transfer in pulp fibre suspensions |
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Authors: | L. K. Ishkintana C. P. J. Bennington |
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Affiliation: | Department of Chemical and Biological Engineering, University of British Columbia, Vancouver, BC, Canada V6T 1Z3 |
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Abstract: | Gas–liquid mass transfer in pulp fibre suspensions in a batch‐operated bubble column is explained by observations of bubble size and shape made in a 2D column. Two pulp fibre suspensions (hardwood and softwood kraft) were studied over a range of suspension mass concentrations and gas flow rates. For a given gas flow rate, bubble size was found to increase as suspension concentration increased, moving from smaller spherical/elliptical bubbles to larger spherical‐capped/dimpled‐elliptical bubbles. At relatively low mass concentrations (Cm = 2–3% for the softwood and Cm ? 7% for the hardwood pulp) distinct bubbles were no longer observed in the suspension. Instead, a network of channels formed through which gas flowed. In the bubble column, the volumetric gas–liquid mass transfer rate, kLa, decreased with increasing suspension concentration. From the 2D studies, this occurred as bubble size and rise velocity increased, which would decrease overall bubble surface area and gas holdup in the column. A minimum in kLa occurred between Cm = 2% and 4% which depended on pulp type and was reached near the mass concentration where the flow channels first formed. |
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Keywords: | pulp fibre suspensions bubble columns bubble shape gas flow gas– liquid mass transfer oxygen delignification |
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