为了研究海上天然气脱 CO2时因摇摆导致吸附罐空隙率变化对吸附净化效果的影响,搭建吸附实验台,利用实验数据,建立二维吸附净化模型,并验证了模型的有效性。结果表明:不流动吸附状态下,随着吸附罐空隙率的增加,吸附罐出口处的甲烷摩尔分数呈现上升趋势,且摩尔分数大于99%。同时空隙率范围在0.25~0.5之间,吸附罐内的吸附热随着空隙率的增大呈现上升趋势;流动吸附时,随着空隙率的增大,吸附罐内压降呈现下降趋势且下降剧烈。吸附罐空隙率为0.35时,吸附净化效果最佳。吸附罐内沿轴线方向吸附热呈现下降趋势,并且吸附罐空隙率越小,吸附热沿轴线方向下降越剧烈。本文的研究结果有助于海上天然气的开采,对天然气的快速发展具有十分重要的意义。%The porosity of adsorption column was changed due to the swing motion of the boat for the offshore natural gas production. To study the effect of adsorption column porosity on adsorption purification, an adsorption experimental apparatus was built. A two-dimensional adsorption purification model was established based on the experiment data, and the validity of the model was confirmed. Result shows that the mass fraction of CH4at the exit of adsorption column rose to more than 0.99 mole fraction with the increase of adsorption column porosity at the static state. The adsorption heat in the adsorption column rose with the increase of adsorption column porosity. In the case of flowing adsorption, the pressure drop in the adsorption column decreased dramatically with the increase of adsorption column porosity. The best adsorption purification achieved when the adsorption column porosity was 0.35. Along the axis direction of the adsorption column, adsorption heat showed a downward trend, and decreased rapidly with the decrease of the adsorption column porosity. This study will help improve the production efficiency of offshore natural gas, and have a significant effect on the rapid development of natural gas.
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