通过压力/真空变速吸附从空气中分离氧气的评估

IF 3 4区 工程技术 Q3 CHEMISTRY, PHYSICAL
Gabriel Jesus de Almeida Henrique, Antônio Eurico Belo Torres, Diana Cristina Silva de Azevedo, Rafael Barbosa Rios, Moisés Bastos-Neto
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引用次数: 0

摘要

本研究旨在通过在 PSA/VSA 装置中进行实验,评估高纯度氧气(90-95%)的生产情况,并建立一个数学模型来描述工艺的动态行为。研究了不同的操作参数和死体积对工艺性能的影响。实验使用了一个实验室规模的装置,其中装满了商用 LiX 沸石珠,以获得用于模型验证的突破和 PSA/VSA 数据。在 0 至 3 巴的压力范围内,分别在 288、298 和 313 K 测量了纯氧和氮气的平衡等温线。在 PSA/VSA 实验中使用了合成空气(纯度 5.0 级,不包括氩气),其成分为 20% (± 0.5%) O2 和 80% (± 0.5%) N2。我们开发了一种新方法,使用为模拟 PSA/VSA 循环而设计的数学模型来考虑此类装置中常见的死体积效应。该模型使用 gPROMS® 软件实现并求解。模拟数据与实验数据十分吻合,准确地反映了工艺过程中浓度、压力、温度和纯度的变化历史。经过验证的模型揭示了 VSA 装置的最佳运行条件:吸附时间为 7.5 秒,吸附压力为 1.5 巴,解吸压力为 0.1 巴,流速为 1 SLPM,纯度约为 94%,回收率约为 20%。增加吸附时间对氧气纯度有负面影响,但对工艺回收率和生产率有正面影响。增加均衡阶段可使 PSA 的工艺回收率提高 18.9%,VSA 的工艺回收率提高 14.5%。此外,增加色谱柱中的死体积对 PSA 和 VSA 装置的纯度、生产率和回收率都有不利影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Evaluation of oxygen separation from air by pressure/vacuum swing adsorption

Evaluation of oxygen separation from air by pressure/vacuum swing adsorption

Evaluation of oxygen separation from air by pressure/vacuum swing adsorption

This study aimed to evaluate the production of high purity oxygen (90–95%) through experiments in a PSA/VSA unit and develop a mathematical model to describe the dynamic behavior of the process. Different operational parameters and the dead volume were investigated for their impact on process performance. The experiments used a laboratory-scale unit filled with beads of a commercial LiX zeolite to obtain breakthrough and PSA/VSA data for model validation. Equilibrium isotherms of pure oxygen and nitrogen were measured at 288, 298 and 313 K for the pressure range of 0 to 3 bar. Single and multicomponent breakthrough curves were obtained at 298 K. Synthetic air (grade 5.0 purity, excluding argon) with a composition of 20% (± 0.5%) O2 and 80% (± 0.5%) N2 was used in the PSA/VSA experiments. A novel approach was developed using the mathematical model designed to simulate PSA/VSA cycles to account for the dead volume effects commonly found in units of this type. The model was implemented and solved using gPROMS® software. The simulation data matched well with the experimental data, accurately representing histories of concentration, pressure, temperature, and purity variations during the process. The validated model revealed optimal operating conditions for a VSA unit: 7.5 s adsorption time, 1.5 bar adsorption pressure, 0.1 bar desorption pressure, and a flow rate of 1 SLPM, producing a purity of approximately 94% and a recovery of about 20%. Increasing the adsorption duration negatively affected the oxygen purity but positively influenced process recovery and productivity. Adding an equalization stage improved process recovery by 18.9% for PSA and 14.5% for VSA. Additionally, increased dead volume in the column had adverse effects on purity, productivity, and recovery for both PSA and VSA units.

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来源期刊
Adsorption
Adsorption 工程技术-工程:化工
CiteScore
8.10
自引率
3.00%
发文量
18
审稿时长
2.4 months
期刊介绍: The journal Adsorption provides authoritative information on adsorption and allied fields to scientists, engineers, and technologists throughout the world. The information takes the form of peer-reviewed articles, R&D notes, topical review papers, tutorial papers, book reviews, meeting announcements, and news. Coverage includes fundamental and practical aspects of adsorption: mathematics, thermodynamics, chemistry, and physics, as well as processes, applications, models engineering, and equipment design. Among the topics are Adsorbents: new materials, new synthesis techniques, characterization of structure and properties, and applications; Equilibria: novel theories or semi-empirical models, experimental data, and new measurement methods; Kinetics: new models, experimental data, and measurement methods. Processes: chemical, biochemical, environmental, and other applications, purification or bulk separation, fixed bed or moving bed systems, simulations, experiments, and design procedures.
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