THE INVESTIGATION OF NORMAL FAULT UNDER UPWELLING FORCE AND ITS CRITICAL STRESS STATE
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摘要: 上拱力构造背景下形成的正断裂及断裂极限应力状态研究在构造解释和油气运移成藏中具有重要的意义。在抛物线型莫尔包络线理论的基础上,通过合理的假设和数学推导以及理论模拟,进一步探讨上拱力构造背景影响下形成的正断裂剖面形态和断裂的极限应力状态,并定量给出函数表达式。研究结果表明,断裂在均质岩体中由浅到深,倾角从竖直开始由大变小,呈铲状断裂,而变化的速率只与地层物性有关,泥岩比砂岩变化快。断裂分布的深度与上拱力的大小成一次线性关系,上拱力越大,断裂分布越浅。砂泥岩互层地层中发育有典型的坡坪式正断裂。研究结果不仅与普遍认识相一致,而且可以进一步在实际应用中预测断裂的存在,定量解释断裂形态,求取上拱力和断裂极限应力状态。Abstract: The investigation of normal fault formed under tectonic setting of upwelling force and its critical stress state is of significance in the structural interpretation and the hydrocarbon migration. Based on the theory of parabolic Mohr failure envelope, and certain assumptions, mathematical derivation and theory modeling being carried out, quantitative functions of geometric shape of normal fault and its critical stress state were given. It is found that the fault dip becomes smaller from shallow to deep, being a listric fault. The rate of dip change is only related to the properties of strata. And the rate of dip change is faster in isotopic sandstone than in mudstone. It is also proved that the depth of the fault is linear against the amplitude of upwelling force. A typical ramp-flat normal fault can be drawn from the fracture modeling of interbedded sandstone-mudstone rock body. Not only are these conclusions consistent with the natural phenomena and general cognition, but also they can explain the geometric shape of faults quantitatively and find the critical stress state.
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Key words:
- upwelling force /
- fault geometry /
- critical stress /
- fracture criterion
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图 1 抛物线型莫尔包络线[5]
τ, σ—断裂面上的临界剪应力和临界正应力,MPa;σ1, σ3—发生断裂时最大和最小主应力,MPa;σm—平均应力(σm=(σ1+σ3)/2),MPa;σI—岩石在各向等值拉伸条件下的抗张断裂极限,MPa;$\frac{\theta }{2}$—岩石剪裂角,(°)
Figure 1. The Parabolic Mohr failure envelope
图 2 岩体正断裂剖面数学分析
l—衡量地面水平长度的量,m;h—参考点深度,m;$\frac{\theta }{2}$—岩石剪裂角,(°);σx, σy—深度为h点处岩体水平方向和竖直方向总应力,MPa
Figure 2. Mathematical analysis of geometric shape of normal fault of rock mass
图 3 正断裂剖面及对应的抛物线型莫尔包络线模型
l—衡量地面水平长度的量,m;h0—起弯深度,m
Figure 3. The geometric shape of normal fault and parabolic Mohr failure envelope models
图 4 上拱力构造背景下岩石极限应力及正断裂剖面形态
Figure 4. Critical stress state of rock and geometric shape of fault under tectonic setting of upwelling force
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