Evolution of pore characteristics in oil shale during pyrolysis under convection and conduction heating modes

IF 1.3 4区 工程技术 Q4 ENERGY & FUELS Oil Shale Pub Date : 2020-01-01 DOI:10.3176/oil.2020.3.04
G. Wang, L. Wang, D. Yang, Yangsheng Zhao
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引用次数: 11

Abstract

The pores in oil shale, which act as channels for the migration of products of cracking of organic matter and the place for heat transfer in the rock mass, directly influence pyrolysis efficiency. In this paper, the pore characteristics of oil shale during pyrolysis under the convection and conduction modes of heating were determined by mercury intrusion porosimetry (MIP). Results show that in case of both the heating modes, the threshold temperatures for transformation of pore structure from simple to complex are 382 °C and 452 °C, respectively. The porosity of oil shale subjected to convection heating is generally higher than that subjected to conduction heating. By the convection heating mode, the high-temperature fluid can extract the shale oil attached to the pore wall and increase the porosity. As the pyrolysis temperature increases from 314 °C to 555 °C, the average pore size of oil shale increases from 23.70 to 218.15 nm in convection heating and from 21.68 to 145.60 nm in conduction heating. During the pyrolysis of organic matter and extraction of oil and gas, high-temperature steam continuously widens the pores. Finally, when the pyrolysis temperature is above 314 °C, pores with a smaller size gradually change into mesopores and macropores with a larger size. It is proved that under the convection heating mode, oil shale changes from a dense rock to a porous medium with an obviously higher amount of pores.
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对流和传导加热模式下油页岩热解过程孔隙特征演化
油页岩孔隙是有机质裂解产物运移的通道和岩体内传热的场所,直接影响热解效率。本文采用压汞孔隙法(MIP)测定了油页岩在对流和传导加热模式下的热解过程中的孔隙特征。结果表明:在两种加热方式下,孔隙结构由简单向复杂转变的阈值温度分别为382℃和452℃;对流加热油页岩孔隙度普遍高于传导加热油页岩孔隙度。高温流体通过对流加热的方式,将附着在孔隙壁上的页岩油萃取出来,提高孔隙度。随着热解温度从314℃升高到555℃,对流加热时油页岩平均孔径从23.70 nm增大到218.15 nm,传导加热时平均孔径从21.68 nm增大到145.60 nm。在有机质热解和油气开采过程中,高温蒸汽不断扩大孔隙。最后,当热解温度高于314℃时,较小尺寸的孔隙逐渐转变为较大尺寸的中孔和大孔。实验证明,在对流加热模式下,油页岩由致密岩石转变为孔隙明显增多的多孔介质。
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来源期刊
Oil Shale
Oil Shale 工程技术-工程:石油
CiteScore
2.90
自引率
15.80%
发文量
14
审稿时长
4.2 months
期刊介绍: The Oil Shale is a scientific-technical open access journal published by the Estonian Academy Publishers in collaboration with the University of Tartu, Tallinn University of Technology, and the Estonian University of Life Sciences.
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