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ASTM Selected Technical Papers
Flammability and Sensitivity of Materials in Oxygen-Enriched Atmospheres: Eleventh VolumeAvailable to Purchase
By
DB Hirsch,
DB Hirsch
1
Sverdrup Inc. NASA White Sands Test Facility
?Symposium Chairman and Editor
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R Zawierrucha,
R Zawierrucha
2
Materials Consultant East Aurora, New York,
USA
Symposium Chairman and Editor
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TA Steinberg,
TA Steinberg
3
School of Engineering Systems Faculty of Built Environment and Engineering Queensland University of Technology
?Brisbane, Queensland,
Australia
Symposium Chairman and Editor
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H Barthelemy
H Barthelemy
4
L'Air Liquide Group
?Paris,
France
Symposium Chairman and Editor
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ISBN-10:
0-8031-3405-3
ISBN:
978-0-8031-3405-8
No. of Pages:
377
Publisher:
ASTM International
Publication date:
2006
eBook Chapter
Effect of Sample Geometry on Regression Rate of the Melting Interface for Carbon Steel Burned in Oxygen Available to Purchase
By
T Suvorovs
,
T Suvorovs
1
Postgraduate Students, Faculty of Built Environment and Engineering
, School of Engineering Systems, Queensland University of Technology
, Gardens Point, QLD,
.Australia
, 4001
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NR Ward
,
NR Ward
1
Postgraduate Students, Faculty of Built Environment and Engineering
, School of Engineering Systems, Queensland University of Technology
, Gardens Point, QLD,
.Australia
, 4001
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R Wilson
,
R Wilson
2
Senior Lecturer
, School of Mathematics, The University of Queensland
, St. Lucia, QLD,
.Australia
, 4072
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TA Steinberg
TA Steinberg
3
Senior Lecturer
, Faculty of Built Environment and Engineering, School of Engineering Systems, Queensland University of Technology
, Gardens Point, QLD,
.Australia
, 4001
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Page Count:
9
-
Published:2006
Citation
Suvorovs, T, Ward, N, Wilson, R, & Steinberg, T. "Effect of Sample Geometry on Regression Rate of the Melting Interface for Carbon Steel Burned in Oxygen." Flammability and Sensitivity of Materials in Oxygen-Enriched Atmospheres: Eleventh Volume. Ed. Hirsch, D, Zawierrucha, R, Steinberg, T, & Barthelemy, H. 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959 : ASTM International, 2006.
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Promoted-ignition testing on carbon steel rods of varying cross-sectional area and shape was performed in high pressure oxygen to assess the effect of sample geometry on the regression rate of the melting interface. Cylindrical and rectangular geometries and three different cross sections were tested and the regression rates of the cylinders were compared to the regression rates of the rectangular samples at test pressures around 6.9 MPa. Tests were recorded and video analysis used to determine the regression rate of the melting interface by a new method based on a drop cycle which was found to provide a good basis for statistical analysis and provide excellent agreement to the standard averaging methods used. Both geometries tested showed the typical trend of decreasing regression rate of the melting interface with increasing cross-sectional area; however, it was shown that the effect of geometry is more significant as the sample's cross sections become larger. Discussion is provided regarding the use of 3.2-mm square rods rather than 3.2-mm cylindrical rods within the standard ASTM test and any effect this may have on the observed regression rate of the melting interface.
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