Simulation analysis of gas–liquid flow and mass transfer in a shaking triethylene glycol dewatering absorber

IF 4.2 3区 工程技术 Q2 ENERGY & FUELS
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Abstract

Tall towers with large diameters on floating liquefied natural gas devices are highly sensitive to sway. If tower equipment is relatively high, swaying can easily cause uneven gas–liquid contact in the tower, inhibiting its absorption capacity. In this paper, gas–liquid counterflow triethylene glycol dehydration absorption towers are taken as the research object. A porous medium model was used to simplify the packing environment, and the Euler–Euler method was used to simulate the flow field in the tower. The flow field encompasses the effects of the gas–liquid phase dispersion force, gas–liquid phase diffusion coefficient, and interphase mass transfer. By introducing a dynamic grid model to establish sway boundary conditions, we quantitatively examine the influence of sway duration and angle on gas–liquid flow and mass transfer performance in absorption towers. The results show that, when the sloshing angle of the absorption tower is 9° and the sloshing period is 20 s, the influence of the disturbance of the absorption tower's internal flow field is increased by 85% and 78% respectively compared with normal working conditions. When the sloshing angle of the absorption tower is 9° and the sloshing period exceeds 21 s, the gas–liquid mass transfer inside the absorption tower diminishes. When the sloshing period of the regeneration tower is 6 s and the sloshing angle reaches 20°, the mass fraction of poor ethylene glycol in the regeneration tower fluctuates significantly in the first sloshing cycle, and unqualified products appear.

振动三甘醇脱水吸收器中的气液流动和传质模拟分析
浮式液化天然气装置上直径较大的高塔对晃动非常敏感。如果塔设备相对较高,摇摆很容易造成塔内气液接触不均匀,抑制其吸收能力。本文以气液逆流三甘醇脱水吸收塔为研究对象。采用多孔介质模型来简化填料环境,并使用欧拉-欧拉方法来模拟塔内流场。流场包括气液相分散力、气液相扩散系数和相间传质的影响。通过引入动态网格模型建立摇摆边界条件,我们定量研究了摇摆持续时间和角度对吸收塔中气液流和传质性能的影响。结果表明,当吸收塔的滑动角为 9°、滑动周期为 20 秒时,吸收塔内部流场的扰动影响与正常工况相比分别增加了 85% 和 78%。当吸收塔的滑动角为 9°、滑动周期超过 21 秒时,吸收塔内部的气液传质效果减弱。当再生塔的滑动周期为 6 s,滑动角达到 20°时,再生塔中劣质乙二醇的质量分数在第一个滑动周期内波动较大,出现不合格产品。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Natural Gas Industry B
Natural Gas Industry B Earth and Planetary Sciences-Geology
CiteScore
5.80
自引率
6.10%
发文量
46
审稿时长
79 days
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