Coupling effects of axial static pressure ratio and high temperature on dynamic mechanical properties and crushing fractal characteristics of concrete under static-dynamic coupled loads

Concrete in buildings is susceptible to the coupling effects of high temperature and static-dynamic coupled loads in case of fire. To explore the coupling effects of axial static pressure and high temperature on dynamic mechanical properties and crushing modes of concrete under static -dynamic coupled loads, static-dynamic coupled loading tests were conducted on plain concrete (PC) with axial static pressure ratios (0, 0.2, 0.4, 0.6, 0.8) and temperatures (20 degrees C, 200 degrees C, 400 degrees C, 600 degrees C, 800 degrees C) as variable conditions. The stress-strain relationship, strength charac-teristics, dynamic increase factor (DIF), deformation characteristics, energy absorption charac-teristics and crushing fractal characteristics of concrete were analyzed. It is shown in the results that when axial static pressure ratio (ASPR) does not exceed 0.4, axial static pressure can close the microcracks and fine pores in concrete, thus significantly improving the dynamic strength characteristics and DIF, and decreasing the deformation characteristics and crushing degree of concrete. The effect of axial static pressure is most obvious at ASPR of 0.4. When ASPR exceeds 0.6, axial static pressure causes microcracks and pores to expand again, thus reducing the dy-namic strength characteristics, and increasing the deformation characteristics and crushing de-gree of concrete. Axial static pressure can significantly change the percentage of energy absorbed before and after the peak stress of concrete. High temperature can cause serious damage dete-rioration to concrete when it exceeds 400 degrees C, thus obviously decreasing the dynamic strength characteristics and energy absorption characteristics, and improving the deformation character-istics and impact crushing degree of concrete. The dynamic compressive strength and energy absorption characteristics are the best at 200 degrees C. The DIF value is the largest at ASPR of 0.4 and temperature of 200 degrees C. 400 degrees C is the turning point of the transition from the dominant influence of ASPR to that of high temperature. Fractal dimension is used to depict the impact crushing degree of concrete, and the larger it is, the higher the crushing degree of concrete is.

Automated summary

Concrete in buildings is susceptible to the coupling effects of high temperature and static-dynamic coupled loads in case of fire. Dynamic mechanical properties and crushing modes of concrete under static-dynamic coupled loads were analyzed through tests with different axial static pressure ratios and temperatures. It was found that axial static pressure can significantly improve dynamic strength characteristics at ASPR of 0.4, but can lead to deterioration at higher ratios, while high temperature above 400 degrees C significantly decreases dynamic strength.