Gas flow rates through inert and chemically reactive porous beds

dc.contributor.authorBaker, Jonathan
dc.contributor.authorChampneys, Alan
dc.contributor.authorCorreia, Joaquim M.C.
dc.contributor.authorCeseri, Maurizio
dc.contributor.authorCurtis, John
dc.contributor.authorHicks, Peter D.
dc.contributor.authorHinch, John
dc.contributor.authorLacey, Andrew
dc.contributor.authorLawn, Heather
dc.contributor.authorOckendon, John
dc.contributor.authorPlease, Colin
dc.contributor.authorTsardakas, Michael
dc.date.accessioned2015-03-26T17:12:10Z
dc.date.available2015-03-26T17:12:10Z
dc.date.issued2014-06-13
dc.description.abstractThe Atomic Weapons Establishment is interested in the behaviour of highly reactive chemical beds, in order to produce more reliable explosives. To improve understanding of the reaction evolution and bed mechanics the study group investigated the experiments of Goveas (1997), which involved the reaction of small beds of potassium picrate particles. The study group developed a mechanistic model and used simplified analyses to investigate the reaction behaviour. The mechanistic model that was developed is able to explain the periodic chuffing observed in experiments, but does not rely on particle compaction. Two simplified analyses are undertaken, which support this mechanistic interpretation of the experiments. These simplified analyses calculate the reaction front speed based on a thermal analysis and the evolution of the gas bubble rising through the porous bed. The study group also suggest additional work that will further understanding of this phenomenon.por
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dc.identifier.citation"Gas flow rates through inert and chemically reactive porous beds", Problem presented by the 'AWE (Atomic Weapons Establishment)' at the 100th European Study Group with Industry, Mathematical Institute, University of Oxford, 7-11 April, 2014por
dc.identifier.scientificarea334por
dc.identifier.urihttp://www.maths-in-industry.org/miis/666/1/AWE_v1_1.pdf
dc.identifier.urihttp://hdl.handle.net/10174/13663
dc.language.isoengpor
dc.publisherStudy Groups with Industry, Mathematics in Industry (http://www.maths-in-industry.org/)por
dc.rightsrestrictedAccesspor
dc.subjectreactive chemical bedspor
dc.subjectchuffingpor
dc.subjectreaction frontpor
dc.subjectthermal analysispor
dc.subjectgas bublespor
dc.subjectporous bedpor
dc.subjectgas flowpor
dc.subjectKozeny-Carman equationpor
dc.titleGas flow rates through inert and chemically reactive porous bedspor
dc.typereportpor

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