Investigation of temperature effects in RC-Steel composite industrial building model with FEM

Abstract

Today, composite structure design has become very popular. The most important goal in composite structure design is to create the most efficient structural system under load by using materials that respond positively to different cross-section effects. Industrial type buildings, on the other hand, consist of very wide openings. In addition, industrial buildings are required to be designed to be constructed quickly and simply. For all these reasons, there has been an increase in the construction of industrial buildings in the form of reinforced concrete-steel composite structures. The effect of temperature in buildings is a parameter that should be considered both in design and use. It is a scientific fact that the expansion and contraction coefficients of reinforced concrete and steel are different. The temperature effect has an even more important place in composite construction systems where both are used together. For all these reasons, in this study, a reinforced concrete-steel composite industrial building model was created and its responses at -50°C and 50°C were examined. As a result of the findings obtained, the effect of temperature in reinforced concrete-steel composite industrial structures should definitely be taken into account both in the design and in the use and maintenance stages.

Keywords

• Industrial buildings
• temperature effect
• composite structures
• finite element method

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