Thermal effect of a fire on a steel beam with corrugated wall with fireproof mineral-wool cladding

Authors

DOI:

https://doi.org/10.15587/1729-4061.2021.241268

Keywords:

steel beam with corrugated wall, standard temperature regime, temperature distributions

Abstract

This paper reports a study into the possibility of applying a simplified approach, recommended by standards for conventional steel beams, to determine the heating temperature under the conditions of a fire in relation to steel I-beams with a corrugated wall. The research is predetermined by the limitation of methods that make it possible to determine the heating temperature of this type of beam in a fire using engineering methods with a small amount of calculations.

Technical data on steel beams with cladding have been considered for calculation, the features of heat impact of fire on them have been analyzed, a calculation procedure has been devised, the estimation schemes have been built, and the calculations have been performed. Data on the temperature distribution in the cross-sections of beams with and without cladding were obtained by using a simplified method recommended by standards and the refined method based on a finite-element method.

Mathematical models have been constructed for calculations that describe the effect of a standard temperature regime of fire on the distribution of temperature in each minute in the cross-sections of steel beams with and without cladding. The models have been described on the basis of the differential equation of thermal conductivity, boundary conditions of the third kind, which take into consideration convective and radiant heat transfer.

It was established that the mineral wool cladding of the beam with a corrugated wall is a reliable fire protection agent. The heating temperature of the beam does not reach a critical value of 500 °C in 60 minutes, which provides the class of this beam with the most stringent requirements for its fire resistance in accordance with the classification in line with the acting norms in Ukraine.

The simplified method, recommended by the current standards of the European Union and Ukraine, could be effectively used to analyze the fire resistance of these beams and is the basis of the procedure for the estimated assessment of the fire resistance of these structures

Author Biographies

Valeriia Nekora, Institute of Public Administration and Research in Civil Protection

Senior Researcher

Sector of Fire Safety and Technology

Center of Fire Protection Research

Stanislav Sidnei, Cherkasy Institute of Fire Safety named after Chornobyl Heroes of National University of Civil Protection of Ukraine

PhD, Associate Professor

Department of Safety of Construction and Occupational Safety

Taras Shnal, Lviv Polytechnic National University

Doctor of Technical Sciences, Associate Professor

Department of Building Constructions and Bridges

Olga Nekora, Cherkasy Institute of Fire Safety named after Chornobyl Heroes of National University of Civil Protection of Ukraine

PhD, Senior Researcher, Leading Researcher

Department of Organization of Scientific Activities

Ludmila Lavrinenko, Kyiv National University of Construction and Architecture

PhD, Associate Professor

Department of Metal and Wooden Structures

Serhii Pozdieiev, Cherkasy Institute of Fire Safety named after Chornobyl Heroes of National University of Civil Protection of Ukraine

Doctor of Technical Sciences, Professor, Chief Researcher

Department of Safety of Construction and Occupational Safety

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Published

2021-10-31

How to Cite

Nekora, V., Sidnei, S., Shnal, T., Nekora, O., Lavrinenko, L., & Pozdieiev, S. (2021). Thermal effect of a fire on a steel beam with corrugated wall with fireproof mineral-wool cladding . Eastern-European Journal of Enterprise Technologies, 5(1(113), 24–32. https://doi.org/10.15587/1729-4061.2021.241268

Issue

Vol. 5 No. 1(113) (2021): Engineering technological systems

Section

Engineering technological systems

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Copyright (c) 2021 Valeriia Nekora, Stanislav Sidnei, Taras Shnal, Olga Nekora, Ludmila Lavrinenko, Serhii Pozdieiev

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