Linear and nonlinear tensile creep of steam-cured UHPC: Fid-Bau Portal

Linear and nonlinear tensile creep of steam-cured UHPC

Xu, Tengfei / Xu, Ziyi / Liu, ZhiFeng / Zhang, Yingda / Castel, Arnaud / Yang, Guotao

Abstract In bridges, UHPC can bear significant sustained tensile stress without cracking under service loading. Its significant impact on the long-term behavior of large-span bridges due to tensile creep characteristics becomes evident. In this paper, both linear and nonlinear tensile creep behavior of steam-cured UHPC was experimentally investigated by using dog-bone-shaped specimens under sustained direct tension for a duration of 360 days. The tensile creep test was conducted under varied tensile stress levels ranging from $0.3 f_{t}$ to $0.9 f_{t}$ . Tensile creep coefficients were calculated by using the experimental results. Nonlinear tensile creep occurs in the steam-cured UHPC when the sustained tensile stress is larger than 0.3 $f_{t}$ . The threshold of nonlinear tensile creep is lower than that of normal-strength concrete under compression. When the sustained tensile stress is larger than 0.8 $f_{t}$ , tensile creep failure occurs a short time after loading. The nonlinear creep impact under tension is less pronounced than that under compression due to the distinct function of steel fibers within UHPC when subjected to compression and tension force. The findings in the scanning electron microscopy (SEM) test reveal that the mechanism driving the nonlinear tensile creep of UHPC is the damage growth at the fibers-matrix interface under the high sustained tensile stress. A design-oriented model for the creep coefficient of UHPC is developed, which incorporates both linear and nonlinear creep effects. The model’s credibility is verified using the experimental results.

Highlights • Nonlinear tensile creep occurs in the steam-cured UHPC when $σ_{c} > 0.3 f_{t}$ . • Damage growth at the fibers-matrix interface drives the nonlinear tensile creep behavior. • Nonlinear creep impact under tension is less pronounced than that under compression. • A creep coefficient model is proposed for steam-cured UHPC and was verified.