液态CO2循环冻融煤体变形损伤规律试验研究

doi:10.3724/1000-6915.jrme.2025.0855

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摘要为了研究液态CO2循环冻融对煤体变形损伤的影响规律，采用自主研发的液态CO2冻融煤体试验系统，开展液态CO2循环冻融次数不同条件下煤体变形损伤特性试验，分析液态CO2循环冻融次数不同条件下煤体应变的变化规律，揭示液态CO2循环冻融煤体变形损伤机制。结果表明，随着液态CO2循环冻融次数由1次增加到12次，煤体轴向应变、环向应变、体积应变均呈现先下降后上升的“U”型的变化规律，轴向应变变化数值略高于环向应变降低数值，煤体的体积应变增加，总体呈现上升的趋势；煤体循环冻融次数与最小应变绝对值增长率呈幂指数变化，与煤体的累积残余应变呈线性增加；循环冻融次数越多，煤体残余应变越大，胀缩率越大，循环冻融对煤体的变形损伤作用越明显；冻融煤体渗透率与液态CO2循环冻融次数增加呈正相关性。研究结果对掌握液态CO2循环冻融增透煤体强化瓦斯抽采技术，确定液态CO2冻融致裂工艺参数提供了有益参考。

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	白刚1
	2
	3*
	贺汇鑫1
	辛天宇1
	2
	张潇文1
	2
	周忠杰4

关键词 ：岩石力学, 液态CO2冻融, 循环冻融次数, 变形损伤, 应变, 瓦斯抽采

Abstract： To investigate the influence of liquid CO2 freeze-thaw cycles on the deformation and damage of coal bodies, a self-developed experimental system for liquid CO2 freeze-thaw cycles was utilized. The deformation and damage characteristics of coal under varying conditions of these cycles were examined. An analysis of the strain variation of the coal body revealed the underlying mechanisms of deformation and damage caused by liquid CO2 freeze-thaw cycles. The results indicate that as the number of freeze-thaw cycles increases from 1 to 12, the axial strain, circumferential strain, and volumetric strain of the coal body exhibit a U-shaped trend, first decreasing and then increasing. Notably, the change in axial strain is slightly greater than the reduction observed in circumferential strain, while volumetric strain shows an overall increasing trend. The relationship between the number of freeze-thaw cycles and the absolute growth rate of the minimum strain is exponential, whereas it increases linearly with the cumulative residual strain of the coal body. Greater numbers of freeze-thaw cycles correlate with higher residual strain, increased expansion and contraction rates, and more pronounced effects on the deformation and damage of the coal body. Furthermore, the permeability of freeze-thaw affected coal is positively correlated with the number of liquid CO2 freeze-thaw cycles. These findings provide valuable insights for optimizing gas extraction technologies using liquid CO2 cyclic freeze-thaw processes and for determining the relevant process parameters for liquid CO2 freeze-thaw cracking.

Key words： rock mechanics liquid CO2 freeze-thaw freeze-thaw cycles deformation damage strain gas extraction

引用本文:

白刚1，2，3*，贺汇鑫1，辛天宇1，2，张潇文1，2，周忠杰4. 液态CO2循环冻融煤体变形损伤规律试验研究[J]. 岩石力学与工程学报, 2026, 45(6): 1657-1669.
BAI Gang1, 2, 3*, HE Huixin1, XIN Tianyu1, 2, ZHANG Xiaowen1, 2, ZHOU Zhongjie4. Deformation damage variation law of liquid CO2 cyclic freeze-thaw coal. , 2026, 45(6): 1657-1669.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0855 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I6/1657

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