Numerical investigation of hydrogen production from low-pressure microwave steam plasma

IF 3.9 2区 工程技术 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Computers & Chemical Engineering Pub Date : 2023-06-01 DOI:10.1016/j.compchemeng.2023.108230
Oytun Oner, Ibrahim Dincer
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引用次数: 2

Abstract

Hydrogen is recognized as a suitable energy carrier that can facilitate the storage and transport of renewable energy. In this context, hydrogen production from microwave-excited steam plasma is one of the least researched techniques and lacks numerical study due to the complex plasma kinetics and difficullty of the simulation process. Therefore, in this study, a kinetic model is developed for steam plasma, considering forty-one reactions and fourteen species. Two-dimensional microwave steam plasma is modeled using COMSOL Multiphysics software for the first time. At a microwave power of 800 W, plasma formation and hydrogen production from low pressure (1 Torr) and high temperature (150 °C) steam plasma are numerically studied within the time domain of 10−10 to 10−4 s. The presented results demonstrate that the maximum electron density reaches 5 1017 m−3 at 10−4s, and 16.8% of the water molecules dissociate to form various species. The conversion rate of water molecules to hydrogen is calculated as 24%. According to the thermodynamic evaluations, the proposed system's energy and exergy efficiencies are 10.31% and 10.14%, respectively, with a hydrogen production rate of 0.68 μg/s. Furthermore, the effect of the applied microwave power on plasma properties and hydrogen production is parametrically studied. Despite the proportional relationship between the input power and hydrogen production, no correlation is found between microwave power and system efficiency.

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低压微波蒸汽等离子体制氢的数值研究
氢被认为是一种合适的能量载体,可以促进可再生能源的储存和运输。在这种情况下,微波激发蒸汽等离子体制氢是研究最少的技术之一,由于等离子体动力学复杂和模拟过程困难,缺乏数值研究。因此,本研究建立了考虑41种反应和14种物质的蒸汽等离子体动力学模型。首次利用COMSOL Multiphysics软件对二维微波蒸汽等离子体进行建模。在800 W的微波功率下,在10−10 ~ 10−4 s的时间域内,对低压(1 Torr)和高温(150°C)蒸汽等离子体的等离子体形成和产氢进行了数值研究。结果表明,在10−4s时电子密度达到最大5 1017 m−3,16.8%的水分子解离形成各种形态。水分子转化为氢的速率计算为24%。热力学评价表明,该系统的能量效率和火用效率分别为10.31%和10.14%,产氢速率为0.68 μg/s。此外,还参数化研究了微波功率对等离子体性能和产氢量的影响。尽管输入功率与产氢量成正比关系,但微波功率与系统效率之间没有相关性。
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来源期刊
Computers & Chemical Engineering
Computers & Chemical Engineering 工程技术-工程:化工
CiteScore
8.70
自引率
14.00%
发文量
374
审稿时长
70 days
期刊介绍: Computers & Chemical Engineering is primarily a journal of record for new developments in the application of computing and systems technology to chemical engineering problems.
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