To provide a theoretical basis and reference for crack control during construction, this study first monitored the construction of side walls by embedding temperature and stress sensors. The measured data were then compared with the Midas civil finite element model, the law for a temperature field, and the stress field during the construction of the side walls. The field monitoring and numerical analysis showed that the hydration heat reaction of the concrete in the early stage was relatively fast, reaching its maximum value only 20 h after pouring. The temperature was high in summer, and the cooling rate was relatively slow at approximately 0.40 °C/h. However, the cooling rate of the middle layer was relatively fast. The time at which the compressive stress reached its maximum value was close to that at which the temperature reached its maximum value. Subsequently, it entered the shrinkage deformation stage. After the critical condition of zero stress occurred, the tensile stress gradually increased with a continuous decrease in temperature, and the tensile stress at each measuring point tended to be stable 50 h after pouring. The finite element model results were close to the field monitoring data. Thus, it could play a role in the prediction of and theoretical basis for fractures. It could also be used as a reference for actual fracture control in engineering.

subway stations  /  sidewall concrete  /  onsite monitoring  /  temperature field  /  strain  /  finite element analysis