During a fire, concrete structures behave in most cases very well. It could therefore be of economic
interest to repair the damaged structures, as costs for demolition and rebuilding can be avoided and
the building can be reused faster. To assess the remaining loadbearing capacity in a scientific based
way, information is necessary about the temperature distribution inside the concrete element and the
residual material properties of both concrete and steel. But, at least of equal importance is a
fundamental insight in how a concrete structure could behave during a heating cycle, as indirect
actions due to thermal restraints can occur and cause significant cracking. These effects should be
noticed during a visual inspection of the structure, however, cracks introduced by internal thermal
restraints are not visible from the concrete surface. In this paper, fundamental knowledge is given
about the effect of heating and cooling on the compressive strength of concrete. Diagnosis tools are
discussed to obtain the temperature distribution, especially in the neighborhood of the
reinforcement. Those techniques are based on the physico-chemical transformations of the cement
matrix and the aggregates that occur during heating. To determine the effect of thermal restraints on
the structural behavior, a methodology based on finite element methods is illustrated