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Publication Citation: Recent Advances in Fire-Structure Analysis

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Author(s): Dat Duthinh; Kevin B. McGrattan; Abed M. Khaskia;
Title: Recent Advances in Fire-Structure Analysis
Published: February 01, 2008
Abstract: One of the recommendations of the National Construction Safety Team for the Federal Building and Fire Safety Investigation of the World Trade Center Disaster (NIST NCSTAR 1, 2005) is to enhance the capability of available computational software to predict the effects of fires in buildings, for use in the design of fire protection systems and the analysis of building response to fires. This paper presents two new interfaces in fire-thermal-structural analysis. The first interface uses adiabatic surface temperatures to provide an efficient way of transferring thermal results from a fire simulation to a thermal analysis. It assigns these temperatures to surface elements of structural members based on proximity and directionality. The second interface allows the transfer of temperature results from a thermal analysis modeled with solid elements to a structural analysis modeled with beams and shells. The interface also allows the reverse, namely the geometric updating of the thermal model with deflections and strains obtained from the structural analysis. This last step is particularly useful in intense fires of long duration, where significant deflections and strains could cause damage to insulation and displace the structure to a different thermal regime. The procedures can be used for a variety of fire simulation, thermal and structural analysis software.
Conference: U.S.-Japan Cooperative Program in Natural Resources; Panel on Wind and Seismic Effects (UJNR)
Proceedings: U.S.-Japan Cooperative Program in Natural Resources; Panel on Wind and Seismic Effects | 39th | 2007 | UJNR |
Volume: 43
Issue: 2
Pages: pp. 161 - 167
Dates: May 14-19, 2007
Keywords: adiabatic surface temperature;deflections;finite elements;fire;insulation;plate thermometer;strains;structural analysis;thermal analysis
Research Areas:
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