Publication date: 15 December 2017
Source:Materials & Design, Volume 136
Author(s): Martin Neuenschwander, Claudio Scandella, Markus Knobloch, Mario Fontana
High and ultra-high strength steels are increasingly used in structures of tall and super-tall buildings, where fire safety has a substantial impact on the structural design. However, more widespread employment in engineering practice is substantially impeded by the lack of suitable design models for the constitutive mechanical behavior of such steels at elevated temperatures; and respective available experimental research is limited to investigations of unusually thin plate material with respect to structural applications. The present study completes the current database with an extensive series of strain-rate controlled tensile tests at different strain-rates with coupon specimens from high and ultra-high strength steel plates of varying thickness, and approves on the basis of this novel most comprehensive and consistent database that existing constitutive fire design models for mild carbon steels are only restrictedly adoptable for high strength steels. Analysis of the impact of the revealed model shortcomings at the material level on structural fire designs shows that the model's overestimation of the elevated-temperature yield strength leads to unsafe fire designs of structural applications with strength-induced failure modes, whereas in contrast the model's underestimation of the elevated-temperature Young's modulus leads to occasionally highly overconservative fire designs of structural applications with stability-induced failure modes.
Graphical abstract
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