In this work, the decomposition behaviour of methane hydrate in porous media was investigated microscopically using powder X-ray diffraction, cryogenic scanning electron microscopy and in situ Raman spectroscopy. The effect of grain sizes on the decomposition of methane hydrate was measured. The results showed that bulk hydrates could exist stably at 223 K and atmospheric pressure because of the self-preservation effect. However, hydrate formed in sands was relatively easier to decompose because it had a higher equilibrium pressure compared with bulk hydrate at the same temperature. In this case, there would be a higher decomposition driving force. Interestingly, the complete decomposition time for hydrate formed in sands did not decrease with the decrease in particle size. The shortest decomposition time was observed for the sands with the particle size range of 38–55 μm, which was less than 30 minutes. Moreover methane hydrate was found to decompose faster in the porous medium containing 3.5 wt% NaCl, which suggested that there was almost no self-preservation effect. In situ Raman measurements showed that the integrated intensity ratio of methane in large and small cages ( A _(L) / A _(S) ) did not change during the decomposition process, suggesting that the methane hydrate crystal units decomposed as an entity in sands. This study provided important data as a basis for drilling fluid technology in hydrate mining.
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机译:在这项工作中,使用粉末X射线衍射,低温扫描电子显微镜和原位拉曼光谱技术对多孔介质中甲烷水合物的分解行为进行了微观研究。测量了晶粒尺寸对甲烷水合物分解的影响。结果表明,由于自保存作用,大块水合物在223 K和大气压下可以稳定存在。但是,与相同温度下的块状水合物相比,砂中形成的水合物相对较容易分解,因为它具有较高的平衡压力。在这种情况下,会有更高的分解驱动力。有趣的是,沙中形成的水合物的完全分解时间并没有随着粒径的减小而减少。观察到粒径范围为38–55μm的砂的分解时间最短,不到30分钟。此外,发现甲烷水合物在含有3.5 wt%NaCl的多孔介质中分解更快,这表明几乎没有自保存作用。拉曼原位测量结果表明,在分解过程中,大大小小的笼子中甲烷的积分强度比(A _(L)/ A _(S))没有改变,表明甲烷水合物晶体单元分解为一个整体。金沙。该研究提供了重要数据,为水合物开采钻井液技术的基础。
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