Infrared temperature distribution characteristics and state assessment method of sandstone under tension and compression stress
•The evolution characteristics of rock IRT were obtained.•The correlation between stress and IRT was quantitatively characterized.•The skewed distribution pattern of rock IRT was identified. Abnormalities in infrared radiation temperature (IRT) often accompany the loading In this investigation, stre...
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Veröffentlicht in: | Infrared physics & technology 2024-11, Vol.142, p.105549, Article 105549 |
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Sprache: | eng |
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Zusammenfassung: | •The evolution characteristics of rock IRT were obtained.•The correlation between stress and IRT was quantitatively characterized.•The skewed distribution pattern of rock IRT was identified.
Abnormalities in infrared radiation temperature (IRT) often accompany the loading In this investigation, stress experiments and splitting tests were conducted on sandstone to investigate the IRT characteristics of sandstone under various loading conditions. The results shows that the Maximum Infrared Radiation Temperature (MAXIRT) increases by up to 5 °C, while in splitting tests, the minimum infrared radiation temperature (MINIRT) decreases by approximately 1.5 °C. Compared to the average infrared radiation temperature (AIRT), MAXIRT is more sensitive to compressive stress, whereas (MINIRT) is more responsive to tensile stress. The correlation between IRT indicators and stress were further analyzed. The findings reveal a positive correlation between IRT and compressive stress. At low stress levels, the correlation coefficient fluctuates between −0.4 and 0.6, generally showing low correlation. As stress increases, the correlation coefficient rises, reaching above 0.8, indicating a high correlation. Tensile stress exhibits a negative correlation, with a consistent trend. Additionally, a statistical analysis of the frequency distribution of IRT under different stress conditions was conducted, followed by hypothesis testing. The results demonstrate that the probability distribution of IRT during loading follows a skewed normal distribution. The changes in skewness can be divided into three stages: initial fluctuation, stable variation, and abrupt failure. Under compressive stress, a right-skewed distribution is observed, with skewness exceeding 3.5 before fracture and reaching above 10 near fracture. Under tensile stress, a left-skewed distribution is noted, with skewness reaching −4.5 near fracture. These findings contribute to the assessment of rock stress states and provide early warning information for predicting rock failure. |
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ISSN: | 1350-4495 |
DOI: | 10.1016/j.infrared.2024.105549 |