Mass transfer studies in batch fermentation: Mixing characteristics

M. N. Ahmad; C. R. Holland; G. McKay

doi:10.1016/0260-8774(94)90083-3

Mass transfer studies in batch fermentation: Mixing characteristics

M. N. Ahmad^*, C. R. Holland, G. McKay

^*Corresponding author for this work

Queen's University Belfast

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

8 Citations (Scopus)

Abstract

Studies have been undertaken to investigate the mass transfer parameters due to mixing effects during fermentation using Candida utilis in a 2·0-dm³ batch fermentor. Mechanical agitation and mixing via air flow have been studied and each varied independently of the other. Oxygen transfer rates were found to increase up to a limiting value when both air flow rate and agitation were increased. Aerobic fermentation is characterised by the specific oxygen rate which increased with agitation and air flow rate. It was found, however, that agitation and aeration had no effect on the carbon dioxide production rate but the mass transfer coefficient increased markedly with increasing agitation. Values for all the mass transfer terms were determined. The mass transfer coefficient, k_La, has been correlated with the impeller agitation speed, N, as follows: k_La=1·079×10^-3N^1·96.

Original language	English
Pages (from-to)	145-158
Number of pages	14
Journal	Journal of Food Engineering
Volume	23
Issue number	2
DOIs	https://doi.org/10.1016/0260-8774(94)90083-3
Publication status	Published - 1994
Externally published	Yes

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title = "Mass transfer studies in batch fermentation: Mixing characteristics",

abstract = "Studies have been undertaken to investigate the mass transfer parameters due to mixing effects during fermentation using Candida utilis in a 2·0-dm3 batch fermentor. Mechanical agitation and mixing via air flow have been studied and each varied independently of the other. Oxygen transfer rates were found to increase up to a limiting value when both air flow rate and agitation were increased. Aerobic fermentation is characterised by the specific oxygen rate which increased with agitation and air flow rate. It was found, however, that agitation and aeration had no effect on the carbon dioxide production rate but the mass transfer coefficient increased markedly with increasing agitation. Values for all the mass transfer terms were determined. The mass transfer coefficient, kLa, has been correlated with the impeller agitation speed, N, as follows: kLa=1·079×10-3N1·96.",

author = "Ahmad, {M. N.} and Holland, {C. R.} and G. McKay",

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AU - Ahmad, M. N.

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AU - McKay, G.

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N2 - Studies have been undertaken to investigate the mass transfer parameters due to mixing effects during fermentation using Candida utilis in a 2·0-dm3 batch fermentor. Mechanical agitation and mixing via air flow have been studied and each varied independently of the other. Oxygen transfer rates were found to increase up to a limiting value when both air flow rate and agitation were increased. Aerobic fermentation is characterised by the specific oxygen rate which increased with agitation and air flow rate. It was found, however, that agitation and aeration had no effect on the carbon dioxide production rate but the mass transfer coefficient increased markedly with increasing agitation. Values for all the mass transfer terms were determined. The mass transfer coefficient, kLa, has been correlated with the impeller agitation speed, N, as follows: kLa=1·079×10-3N1·96.

AB - Studies have been undertaken to investigate the mass transfer parameters due to mixing effects during fermentation using Candida utilis in a 2·0-dm3 batch fermentor. Mechanical agitation and mixing via air flow have been studied and each varied independently of the other. Oxygen transfer rates were found to increase up to a limiting value when both air flow rate and agitation were increased. Aerobic fermentation is characterised by the specific oxygen rate which increased with agitation and air flow rate. It was found, however, that agitation and aeration had no effect on the carbon dioxide production rate but the mass transfer coefficient increased markedly with increasing agitation. Values for all the mass transfer terms were determined. The mass transfer coefficient, kLa, has been correlated with the impeller agitation speed, N, as follows: kLa=1·079×10-3N1·96.

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Mass transfer studies in batch fermentation: Mixing characteristics

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