Abstract

Reinforced concrete (RC) structures exposed to cryogenic temperature environment, the bond performance of rebar-concrete is related to the characteristics of concrete material and rebar. The mechanical characteristics of concrete material and rebar vary greatly at cryogenic temperatures. To illustrate the bond behavior of rebar-concrete at cryogenic temperatures, the pull-out specimens were simulated focusing on the coupling effects of cryogenic temperatures and confinements on the bond behavior. The model considers the surface characteristics of deformed reinforcement and the cryogenic temperature effects on the mechanical characteristics of materials. The confinements were applied to the specimens by carbon fiber-reinforced polymer (CFRP) and stirrup respectively, and the temperature ranges from 20 °C to − 120 °C. The effects of thickness diameter ratio (c/d), and confinements on the bond behavior at cryogenic temperatures were discussed. The results showed that at cryogenic temperatures, the failure modes are similar to those at 20 °C for the specimens with c/d ≤ 3.75. However, for the specimen with c/d = 4.0, the specimen at − 120 °C exhibits splitting failure due to the increase of brittleness. The bond strength at cryogenic temperatures is improved with the increasing c/d. The effects of confinements on the failure modes are small, but the bond strength is improved by the CFRP confinements and stirrup confinements. According to the numerical data, the developed bond strength model and bond stress-slip model considering the effects of confinements could provide better predictions of the bond behavior at cryogenic temperatures.

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