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Reliability Analysis of Flexural Deflection of Reinforced Concrete Members under Ultra-Low Temperature

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Abstract:

Based on the Monte Carlo method, the functional function under the normal use limit state given by the specification introduces the concrete tensile strength of each temperature gradient under ultra-low temperature, and the coefficient of change of concrete elastic modulus. By changing the temperature of the member, the thickness of the protective layer, the bending moment effect ratio, the reinforcement size,the concrete grade and the length of the bending beam. Analyze the reliable index of the deflection control of the flexural member under ultra-low temperature to obtain: When the reinforced concrete flexural member is reduced from normal temperature 20°C to-160°C, the reliable deflection index of the component increases non-linearly, reaches the maximum value at-130°C, and then decreases slightly, the concrete strength grade and the thickness of the protective layer under each temperature gradients have the greatest influence on the deflection control of the bending beam under ultra-low temperature, followed by beam length, steel bar size, load effect ratio,which is different from normal temperature.

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Periodical:

Key Engineering Materials (Volume 881)

Pages:

131-135

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.881.131

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Online since:

April 2021

Authors:

Meng Xi Tan*, Yang Li

Keywords:

Flexural Deflection, Monte Carlo Method, Reinforced Concrete, Reliability, Ultra-Low Temperature

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© 2021 Trans Tech Publications Ltd. All Rights Reserved

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* - Corresponding Author

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