Comprehensive performance and numerical analysis of pressure swing adsorption process-based medical oxygen concentrators under various operating conditions

IF 2.3 4区 工程技术 Q3 CHEMISTRY, MULTIDISCIPLINARY Separation Science and Technology Pub Date : 2023-08-20 DOI:10.1080/01496395.2023.2245132
Xianqiang Zhu, Yuan Sun, Liang Dong, Xianhang Sun, Shuhui Li, Hong Chen, Junyu Zhang, Jinju Chen
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Abstract

ABSTRACT One common application of pressure swing adsorption technology is medical oxygen concentrator (MOC) which directly produces ~ 94% O2 from air. The operating condition determines the separation efficiency of MOC and is varied with practical requirements. A better understanding of performance, mass and heat transfer inside adsorption bed at wide operating conditions is of great importance. The impacts of key operating parameters on the performances, the concentration and temperature distributions of MOC have been numerically investigated. The numerical results demonstrate that high comprehensive performances are achieved at an optimal condition with combination of adsorption pressure, product and feed flowrate and feed temperature. As adsorption pressure increases, the front of gas concentration and temperature becomes sharp, which effectively benefits for improving the performance. It is nearly identical shapes of nitrogen concentration and gas temperature profiles after adsorption and the profiles are pushed forward near production end with increasing of product flowrates and decreasing of feed flowrates. The increasing of feed temperature is beneficial to improve the performance. However, the adverse mass transfer and thermal effects are dominant at very high pressures, flowrates and temperatures conditions and this variation increases the unit power of MOC.
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变压吸附法医用氧浓缩器在不同工况下的综合性能及数值分析
变压吸附技术的一个常见应用是医用氧浓缩器(MOC),它直接从空气中产生~ 94%的氧气。操作条件决定了MOC的分离效率,并随实际需要而变化。更好地了解吸附床在宽工况下的性能、传质和传热具有重要意义。数值研究了关键操作参数对MOC性能、浓度和温度分布的影响。数值计算结果表明,在吸附压力、产物和进料流量、进料温度相结合的最优条件下,可获得较高的综合性能。随着吸附压力的增大,气体浓度和温度的前沿变陡,有效地有利于性能的提高。吸附后的氮浓度和气体温度曲线形状基本一致,且随着产品流量的增大和进料流量的减小,该曲线在接近生产端时向前推进。提高进料温度有利于提高性能。然而,在非常高的压力、流量和温度条件下,不利的传质和热效应占主导地位,这种变化增加了MOC的单位功率。
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来源期刊
Separation Science and Technology
Separation Science and Technology 工程技术-工程:化工
CiteScore
6.10
自引率
3.60%
发文量
131
审稿时长
5.7 months
期刊介绍: This international journal deals with fundamental and applied aspects of separation processes related to a number of fields. A wide range of topics are covered in the journal including  adsorption, membranes, extraction, distillation, absorption, centrifugation, crystallization, precipitation, reactive separations, hybrid processes, continuous separations, carbon capture,  flocculation and  magnetic separations. The journal focuses on state of the art preparative separations and theoretical contributions to the field of separation science. Applications include environmental, energy, water, and biotechnology. The journal does not publish analytical separation papers unless they contain new fundamental contributions to the field of separation science.
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