Gas flow hydrodynamics in an oxygen delignification retention tower

Gas flow hydrodynamics in an oxygen delignification retention tower

Show other versions (1)

Gas flow hydrodynamics were characterized as a function of pulp suspension concentration in a laboratory-scale residence tower. Three kraft pulps were studied: never-dried brown stock (kappa 33), a fully bleached kraft pulp (88-89% brightness) that never had been dried, and a dried and reslurried...

Full description

Bibliographic Details
Main Author: Pineault, Isabelle
Format: Others
Language:English
Published: 2009
Online Access:http://hdl.handle.net/2429/9318
id ndltd-UBC-oai-circle.library.ubc.ca-2429-9318
record_format oai_dc
spelling ndltd-UBC-oai-circle.library.ubc.ca-2429-93182018-01-05T17:34:41Z Gas flow hydrodynamics in an oxygen delignification retention tower Pineault, Isabelle Gas flow hydrodynamics were characterized as a function of pulp suspension concentration in a laboratory-scale residence tower. Three kraft pulps were studied: never-dried brown stock (kappa 33), a fully bleached kraft pulp (88-89% brightness) that never had been dried, and a dried and reslurried fully bleached kraft pulp (88-89% brightness). The following experiments were performed to charaterize gas flow in pulp retention towers. First, gas flow in a narrow rectangular tower was characterised as a function of suspension mass concentration by calculating the bubble rising velocity. These results were compared with bubble rising velocity measurement made in a pilot-scale column having a L/D ratio of 6.5:1 (inside diameter of27.94 cm).. The same column was used to measure gas holdup with both the gas disengagement technique [Daly et al., 1992] and measurements of the density variation method along the column height. Finally, mass transfer was evaluated in a small laboratory-scale column ( L/D = 4.1:1) using a dissolved oxygen probe. The main results of these experiments are as follows. First is was found that at medium pulp consistency, there are no bubbles formed in the tower due to the lack o f free water. Second, at pulp consistencies higher than 5 %, gas is trapped in the fibre network, which increases considerably the gas holdup. Furthermore, this gas holdup is not influenced by the gas flow rate. Third, the bubble size at low consistencies is influenced by the air flow rate as well as the pulp consistency present in the column. Fourth, the type of pulp used did not have a great influence on the gas holdup in the pilot-scale column. Finally, mass transfer occurs in the laboratory-scale column, with kL a values in the same range as the those reported in bubble columns. Applied Science, Faculty of Chemical and Biological Engineering, Department of Graduate 2009-06-16T23:40:49Z 2009-06-16T23:40:49Z 1999 1999-05 Text Thesis/Dissertation http://hdl.handle.net/2429/9318 eng For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use. 32612203 bytes application/pdf
collection NDLTD
language English
format Others
sources NDLTD
description Gas flow hydrodynamics were characterized as a function of pulp suspension concentration in a laboratory-scale residence tower. Three kraft pulps were studied: never-dried brown stock (kappa 33), a fully bleached kraft pulp (88-89% brightness) that never had been dried, and a dried and reslurried fully bleached kraft pulp (88-89% brightness). The following experiments were performed to charaterize gas flow in pulp retention towers. First, gas flow in a narrow rectangular tower was characterised as a function of suspension mass concentration by calculating the bubble rising velocity. These results were compared with bubble rising velocity measurement made in a pilot-scale column having a L/D ratio of 6.5:1 (inside diameter of27.94 cm).. The same column was used to measure gas holdup with both the gas disengagement technique [Daly et al., 1992] and measurements of the density variation method along the column height. Finally, mass transfer was evaluated in a small laboratory-scale column ( L/D = 4.1:1) using a dissolved oxygen probe. The main results of these experiments are as follows. First is was found that at medium pulp consistency, there are no bubbles formed in the tower due to the lack o f free water. Second, at pulp consistencies higher than 5 %, gas is trapped in the fibre network, which increases considerably the gas holdup. Furthermore, this gas holdup is not influenced by the gas flow rate. Third, the bubble size at low consistencies is influenced by the air flow rate as well as the pulp consistency present in the column. Fourth, the type of pulp used did not have a great influence on the gas holdup in the pilot-scale column. Finally, mass transfer occurs in the laboratory-scale column, with kL a values in the same range as the those reported in bubble columns. === Applied Science, Faculty of === Chemical and Biological Engineering, Department of === Graduate
author Pineault, Isabelle
spellingShingle Pineault, Isabelle
Gas flow hydrodynamics in an oxygen delignification retention tower
author_facet Pineault, Isabelle
author_sort Pineault, Isabelle
title Gas flow hydrodynamics in an oxygen delignification retention tower
title_short Gas flow hydrodynamics in an oxygen delignification retention tower
title_full Gas flow hydrodynamics in an oxygen delignification retention tower
title_fullStr Gas flow hydrodynamics in an oxygen delignification retention tower
title_full_unstemmed Gas flow hydrodynamics in an oxygen delignification retention tower
title_sort gas flow hydrodynamics in an oxygen delignification retention tower
publishDate 2009
url http://hdl.handle.net/2429/9318
work_keys_str_mv AT pineaultisabelle gasflowhydrodynamicsinanoxygendelignificationretentiontower
_version_ 1718588246433202176

Similar Items