Hydrodynamic extensional stress during the bubble bursting process for bioreactor system design

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dc.contributor.authorT T Tran-
dc.contributor.authorEun Gyo Lee-
dc.contributor.authorI S Lee-
dc.contributor.authorN S Woo-
dc.contributor.authorS M Han-
dc.contributor.authorY J Kim-
dc.contributor.authorW R Hwang-
dc.date.accessioned2017-04-19T10:30:53Z-
dc.date.available2017-04-19T10:30:53Z-
dc.date.issued2016-
dc.identifier.issn1226-119X-
dc.identifier.uri10.1007/s13367-016-0032-5ko
dc.identifier.urihttps://oak.kribb.re.kr/handle/201005/13589-
dc.description.abstractCell damage, one of critical issues in the bioreactor design for animal cell culture, is caused mainly from the bubble bursting at the free surface subjected to strong extensional flows. In this work, extensive computational studies are performed to investigate bubble bursting process in great details. Extensive numerical simulations are performed for a wide range of bubble diameters (from 0.5 to 6 mm) and the surface tension values (from 0.03 to 0.072 N/m), with which effects of the bubble size and surfactant (PF68) concentration on the hydrodynamic stress are investigated. For all the cases, the maximum extensional stress appears at the instance when receding films impact each other at the bottom of the bubble. A model equation based on numerical simulations is presented to predict the maximum extensional stress as a function of the bubble diameter and the surface tension. The bubble diameter has turned out to contribute significantly the maximum hydrodynamic extensional stress. In addition, the bubble collapsed time and the affected volume around a bubble subjected to the critical extensional stress are investigated. The extensional stress estimation is reported as a function of the bubble size and the surface tension. The influence of the bubble size on the maximum stress dominates and extensional stress reaches up to the order of 104 Pa for bubble size of 0.5 mm.-
dc.publisherKorea Soc-Assoc-Inst-
dc.titleHydrodynamic extensional stress during the bubble bursting process for bioreactor system design-
dc.title.alternativeHydrodynamic extensional stress during the bubble bursting process for bioreactor system design-
dc.typeArticle-
dc.citation.titleKorea-Australia Rheology Journal-
dc.citation.number4-
dc.citation.endPage326-
dc.citation.startPage315-
dc.citation.volume28-
dc.contributor.affiliatedAuthorEun Gyo Lee-
dc.contributor.alternativeNameTran-
dc.contributor.alternativeName이은교-
dc.contributor.alternativeName이인수-
dc.contributor.alternativeName우남섭-
dc.contributor.alternativeName한상목-
dc.contributor.alternativeName김영주-
dc.contributor.alternativeName황욱렬-
dc.identifier.bibliographicCitationKorea-Australia Rheology Journal, vol. 28, no. 4, pp. 315-326-
dc.identifier.doi10.1007/s13367-016-0032-5-
dc.subject.keywordAnimal cell culture-
dc.subject.keywordBioreactor-
dc.subject.keywordBubble bursting-
dc.subject.keywordCell damage-
dc.subject.keywordExtensional stress-
dc.subject.localAnimal cell culture-
dc.subject.localanimal cell culture-
dc.subject.localBioreactor-
dc.subject.localbioreactor-
dc.subject.localbio-reactor-
dc.subject.localBubble bursting-
dc.subject.localCell damage-
dc.subject.localExtensional stress-
dc.description.journalClassY-
Appears in Collections:
Division of Bio Technology Innovation > BioProcess Engineering Center > 1. Journal Articles
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