Comparison of flame spread measurements using the ASTM E 1321 LIFT and a reduced scale adaptation of the cone calorimeter apparatus

dc.contributor.authorMerryweather, Geoffrey Jamesen
dc.date.accessioned2008-09-07T21:52:47Z
dc.date.available2008-09-07T21:52:47Z
dc.date.issued2006en
dc.description.abstractA full-scale ASTM E 1321 Lateral ignition and Flame Transport (LIFT) apparatus was constructed and compared with a Reduced scale Ignition and Flame spread Test apparatus (RIFT) adaptation of the cone calorimeter in the vertical position. The objective was to find a low cost and simple alternative to the LIFT apparatus for measuring opposed flow flame spread. Ignition tests were conducted using the LIFT, RIFT and ISO 5657 ignitability apparatus and flame spread experiments were conducted in the LIFT and RIFT. Nine different types of timber based products were tested for ignition and flame spread, and Quintiere's flame spread model was applied to the results to obtain material properties, such as thermal inertia, flame spread parameter and the minimum heat flux required for flame spread. These materials included plywood, medium density fibreboard (MDF), hardboard, particle board flooring, Melamine (Melteca) covered MDF, New Zealand Rimu, and Beech and New Zealand grown Macrocarpa and Radiata (Monterey) Pine. Further limited tests were conducted on Melteca covered particle board, and a second brand of particle board. The materials in the RIFT were tried with and without preheating to equilibrium. In addition, a view factor for the RIFT was developed, based on earlier work for the cone calorimeter element. The view factor equation was experimentally tested against measured values, and the calculated value was consistently lower than the experimental values, with similar flux profile. The standard procedure is for the material to be preheated before ignition, so that the surface is at equilibrium. The spread of the flame front past points on the sample surface after ignition is recorded, and from the flame front velocity and the model by Quintiere, material specific properties can be derived. The lack of preheating was found to affect the final results, by reducing the flame spread velocity and increasing the scatter in the experimental results. The RIFT gives comparable results to the same materials tested in the LIFT and to the published literature. The results the flame spread parameter and the minimum flux for flame spread are usually higher for the RIFT against the same material in the LIFT. There proved to be an effective limit on suitable materials able to be successfully tested in the RIFT to those that have a minimum flux for flame spread of less than 7kW/m2, with this limitation is dictated by the flux profile along the sample, and the lower resolution dictated by the smaller size. It is approximately equivalent to a minimum ignition flux of 18kW/m2.en
dc.identifier.issn1173-5996
dc.identifier.urihttp://hdl.handle.net/10092/1094
dc.identifier.urihttp://dx.doi.org/10.26021/2409
dc.language.isoen
dc.publisherUniversity of Canterbury. Civil Engineeringen
dc.relation.isreferencedbyNZCUen
dc.rightsCopyright Geoffrey James Merryweatheren
dc.rights.urihttps://canterbury.libguides.com/rights/thesesen
dc.subjectlateral flame spreaden
dc.subjectLIFTen
dc.subjectRIFTen
dc.subjectopposed flow flame spreaden
dc.subjectignitionen
dc.titleComparison of flame spread measurements using the ASTM E 1321 LIFT and a reduced scale adaptation of the cone calorimeter apparatusen
dc.typeTheses / Dissertations
thesis.degree.disciplineFire Engineeringen
thesis.degree.grantorUniversity of Canterburyen
thesis.degree.levelMastersen
thesis.degree.nameMaster of Engineeringen
uc.bibnumber1027371en
uc.collegeFaculty of Engineeringen
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