CO2泡沫压裂液酸蚀煤体损伤本构模型建立与应用

Establishment and application of damage constitutive model for acid-etched coal mass in CO2 foam fracturing fluid

  • 摘要: CO2泡沫压裂虽能有效增透煤层,提高煤层透气性,但仍存在因酸化煤体损伤本构关系不清间接导致其致裂范围难以准确预测的问题。为探究酸化−压裂双重作用对煤体本构关系的影响,基于CO2泡沫压裂力学试验系统,开展了不同酸侵时长下煤体单轴压缩试验,定量表征了峰值强度、残余强度、弹性模量及脆性指数等特征参数,分析了酸化煤体在加载过程中的渐进破坏行为,并构建了酸−力复合作用下煤岩损伤分段式本构模型。结果表明:在酸侵作用下煤体内部结构遭受破坏,导致其峰值强度和残余强度显著下降,但由于两者承载机制存在差异,残余强度主要依赖于块体间作用,对微观结构损伤更为敏感,所以下降幅度较大。在CO2泡沫压裂液的化学−物理协同作用下,酸性物质迅速渗流扩散到煤体内部,与碳酸盐及部分黏土胶结物发生反应,导致煤体的力学特征从部分延性向高度脆性演化,并且脆性程度随酸侵时间的延长而增强。基于Lemaitre应变等价假说和弹性损伤力学,建立了煤岩损伤分段式本构模型,通过不同的本构关系式分别表征煤体在峰前阶段、峰后应力跌落阶段及残余稳定阶段的形变规律。该模型中,损伤修正系数δ表征材料残余变形特性,损伤本构系数λ则控制峰后软化速率,二者共同主导模型的整体本构关系特征。相较于传统本构模型,所建模型能够更准确地表征在CO2泡沫压裂下煤体力学特性的阶段式变化,基于此模型与致裂半径修正公式的定量计算,可有效提高致裂半径的预测精度。据此结果提出了“菱形布孔”方式,可实现低透煤层的精准增透,提高瓦斯抽采效率。

     

    Abstract: Although CO2 foam fracturing can effectively increase the permeability of coal seams and improve the air permeability of coal seams, there are still problems that make it difficult to accurately predict the fracturing range due to the unclear constitutive relationship of acidified coal damage. In order to explore the influence of acidification−fracturing on the constitutive relationship of coal, based on the CO2 foam fracturing mechanics experimental system, the uniaxial compression test of coal body under different acid intrusion durations was carried out, and the characteristic parameters such as peak strength, residual strength, elastic modulus and brittleness index were quantitatively characterized, the gradual failure behavior of acidified coal during loading was analyzed, and a segmented constitutive model of coal and rock damage under acid−force compound action was constructed. The results show that the internal structure of the coal body is damaged under acid intrusion, resulting in a significant decrease in its peak strength and residual strength, but due to the difference in the bearing mechanism between the two, the residual strength mainly depends on the interaction between blocks, which is more sensitive to microstructure damage, so the decrease is large. Under the chemical-physical synergy of CO2 foam fracturing fluid, the acidic substances quickly seep and diffuse into the coal body, reacting with carbonates and some clay cements, resulting in the evolution of the mechanical characteristics of the coal body from partial ductility to high brittleness, and the brittleness degree increases with the extension of acid invasion time. Based on the Lemaitre strain equivalence hypothesis and elastic damage mechanics, a segmented constitutive model of coal-rock damage is established, and the deformation laws of coal in the pre-peak stage, post-peak stress drop stage and residual stability stage are characterized by different constitutive relationships. In this model, the damage correction coefficient δ characterize the residual deformation characteristics of the material, while the damage constitutive coefficient λ controls the post-peak softening rate, which together dominate the overall constitutive relationship characteristics of the model. Compared with the traditional constitutive model, the proposed model can more accurately characterize the phased changes of coal mechanical properties under CO2 foam fracturing, and the prediction accuracy of fracturing radius can be effectively improved based on the quantitative calculation of this model and the fracturing radius correction formula. Based on the results, the “diamond-shaped hole” method is proposed, which can achieve precise permeability enhancement of low permeability coal seams and improve the efficiency of gas extraction.

     

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