Relationship between micro-pores fractal characteristics about NMR T2 spectra and macro cracks fractal laws based on box dimension method of coal under impact load from energy dissipation theory

IF 5.3 1区 数学 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS
Shugang Li , Di He , Xiangguo Kong , Haifei Lin , Yankun Ma , Xuelong Li , Mengzhao Zhan , Pengfei Ji , Songrui Yang
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Abstract

The development and utilization of deep formation resources are easily disrupted by impact loads. To investigate what effect of impact on the pore structure and energy evolution of coal, the dynamic compression tests were performed by using the Split Hopkinson Pressure Bar (SHPB) test system. The fractal characteristics of macro cracks were analyzed by box dimension, the micro-pores structure and fractal features of coal samples were studied about nuclear magnetic resonance (NMR), which clarified the intrinsic relationship between fracture structure characteristics and energy dissipation. The results showed that with increasing impact velocity from 1.27 m/s to 4.90 m/s, the dynamic strength and peak strain increased by 85.11 % and 53.76 %, respectively. The fractal dimension of the cracks grew by 26.87 %, and the fractal dimension of pore network and full aperture decreases gradually. With increasing impact velocity, the fracture dissipation energy and energy dissipation rate of coal samples increase exponentially. As the energy dissipation rate increases, the cracks fractal increases in a quadratic function relationship and the pores fractal decreases continuously. Low-velocity impacts induce dislocation plugging between coal matrix crystals, while impact effect causes more dislocations to form stress concentrations at pore tips. When the energy accumulation reaches its maximum value, the content of mesopores and macropores together with the pore connectivity increases. Instantaneous disturbance creates more macroscopic fracture surfaces in the coal, resulting in large-scale fracture instability. This research findings will provide some theoretical foundations to understand the formation mechanism of dynamic disasters in deep mines.
基于能量耗散理论的冲击载荷下煤炭箱形尺寸法的核磁共振 T2 光谱微孔分形特征与宏观裂缝分形规律之间的关系
深部地层资源的开发和利用很容易受到冲击载荷的干扰。为了研究冲击载荷对煤炭孔隙结构和能量演化的影响,利用分体式霍普金森压力棒(SHPB)试验系统进行了动态压缩试验。通过箱形尺寸分析了宏观裂缝的分形特征,并利用核磁共振(NMR)研究了煤样的微孔结构和分形特征,从而明确了断裂结构特征与能量耗散之间的内在联系。结果表明,随着冲击速度从 1.27 m/s 增加到 4.90 m/s,动态强度和峰值应变分别增加了 85.11 % 和 53.76 %。裂缝的分形维数增加了 26.87%,孔隙网络和全孔径的分形维数逐渐减小。随着冲击速度的增加,煤样的断裂耗能和耗能率呈指数增长。随着耗能率的增加,裂缝分形呈二次函数关系增加,孔隙分形不断减小。低速冲击会引起煤基体晶体间的位错堵塞,而冲击效应会使更多的位错在孔隙尖端形成应力集中。当能量积累达到最大值时,中孔和大孔的含量以及孔隙连通性都会增加。瞬时扰动在煤中形成更多的宏观断裂面,导致大尺度断裂不稳定性。这一研究成果将为理解深部矿井动态灾害的形成机理提供一些理论基础。
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来源期刊
Chaos Solitons & Fractals
Chaos Solitons & Fractals 物理-数学跨学科应用
CiteScore
13.20
自引率
10.30%
发文量
1087
审稿时长
9 months
期刊介绍: Chaos, Solitons & Fractals strives to establish itself as a premier journal in the interdisciplinary realm of Nonlinear Science, Non-equilibrium, and Complex Phenomena. It welcomes submissions covering a broad spectrum of topics within this field, including dynamics, non-equilibrium processes in physics, chemistry, and geophysics, complex matter and networks, mathematical models, computational biology, applications to quantum and mesoscopic phenomena, fluctuations and random processes, self-organization, and social phenomena.
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