Capillary Pressure Behavior of CO2 - Shale System at Elevated Temperatures

A. Almutairi, T. Al-Bazali
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Abstract

In this study, changes in capillary entry pressure of shale when interacting with CO2, under different temperatures have been investigated. The combined impact of temperature and petrophysical properties of shale (water content, water activity, permeability and porosity) on capillary entry pressure was addressed.  Pressure breakthrough measurements were used to evaluate the minimum entry pressure of CO2 through shale.  A heavy-duty oven was used to vary the temperature in order to investigate the impact of temperature on CO2 capillary entry pressure through shale.  Results showed that capillary entry pressure of shale when interacting with CO2 was highly affected by temperature. Higher temperatures decreased capillary entry pressure of shale. We believe that pore dilation, where pore throat size expands due to the application of heat, may have caused this decrease in capillary entry pressure.  However, in some cases higher temperature activated clay swelling that may have caused an apparent decrease in pore throat radii of shale which translated into higher capillary entry pressure.  Results also showed that there exists no distinct relationship between petrophysical properties of shale and its measured capillary entry pressure when interacting with CO2 at different temperatures.  Heat could alter pore throat radii and cause pore dilation which may alter measured capillary entry pressure.  Interfacial tension decreases with increasing temperature and that can be attributed to the weakening of intermolecular forces at the two immiscible fluids interface. Swelling of clay could be related to temperature-induced transition from passive to an active clay.
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高温下CO2 -页岩体系的毛细压力行为
本研究研究了不同温度下页岩与CO2相互作用时毛管进入压力的变化。研究了温度和页岩岩石物理性质(含水量、水活度、渗透率和孔隙度)对毛管进入压力的综合影响。压力突破测量用于评估CO2通过页岩的最小进入压力。为了研究温度对CO2通过页岩毛细管进入压力的影响,使用了一个重型烘箱来改变温度。结果表明:页岩与CO2相互作用时毛管进入压力受温度影响较大;较高的温度降低了页岩的毛管进入压力。我们认为,孔喉因受热而扩大的孔扩张可能导致毛细管进入压力的降低。然而,在某些情况下,高温激活粘土膨胀可能导致页岩孔喉半径明显减小,从而转化为更高的毛细管进入压力。结果还表明,在不同温度下,当与CO2相互作用时,页岩的岩石物理性质与其测量的毛细管进入压力之间没有明显的关系。热可以改变孔喉半径,引起孔扩张,从而改变测量的毛细管进入压力。界面张力随温度升高而降低,这可归因于两种不混相流体界面的分子间作用力减弱。粘土的膨胀可能与温度引起的被动粘土向活性粘土的转变有关。
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