Producing hydrogen-rich syngas via microwave heating and co-gasification: a systematic review

IF 14.4 Q1 ENERGY & FUELS Biofuel Research Journal-BRJ Pub Date : 2022-03-01 DOI:10.18331/brj2022.9.1.4
I. Rosyadi, S. Suyitno, Albert Xaverio Ilyas, Afif Faishal, Andres Budiono, Mirza Yusuf
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引用次数: 11

Abstract

Co-gasification contributes significantly to the generation of hydrogen-rich syngas since it not only addresses the issue of feedstock variation but also has synergistic benefits. In this article, recent research on hydrogen concentration and yield, tar content, gasification efficiency, and carbon conversion efficiency is explored systematically. In feedstocks with high water content, steam gasification and supercritical hydrothermal gasification technologies are ideal for producing hydrogen at a concentration of 57%, which can be increased to 82.9% using purification technology. Carbonized coals, chars, and cokes have high microwave absorption when used as feedstocks. Moreover, coconut activated carbon contains elements that provide a high tan δ value and are worthy of further development as feedstocks, adsorbents or catalysts. Meanwhile, the FeSO4 catalyst has the greatest capacity for storing microwave energy and producing dielectric losses; therefore, it can serve as both a catalyst and microwave absorber. Although microwave heating is preferable to conventional heating, the amount of hydrogen it generates remains modest, at 60% and 32.75% in single-feeding and co-feeding modes, respectively. The heating value of syngas produced using microwaves is 17.44 MJ/m³, much more than that produced via conventional heating. Thus, despite a lack of research on hydrogen-rich syngas generation based on co-gasification and microwave heating, such techniques have the potential to be developed at both laboratory and industrial scales. In addition, the dielectric characteristics of feedstocks, beds, adsorbents, and catalysts must be further investigated to optimize the performance of microwave heating processes.
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微波加热和共气化生产富氢合成气的系统综述
共气化对富氢合成气的产生有重要贡献,因为它不仅解决了原料变化的问题,而且具有协同效益。本文系统地探讨了近年来在氢气浓度和产率、焦油含量、气化效率和碳转化效率等方面的研究进展。在高含水量的原料中,蒸汽气化和超临界水热气化技术产氢浓度为57%,采用净化技术可将其提高到82.9%。作为原料,碳化煤、焦炭和焦炭具有较高的微波吸收量。此外,椰子活性炭含有高tan δ值的元素,值得进一步开发作为原料,吸附剂或催化剂。同时,FeSO4催化剂具有最大的储存微波能量和产生介电损耗的能力;因此,它既可以作为催化剂,又可以作为微波吸收剂。虽然微波加热优于传统加热,但它产生的氢气量仍然不大,在单次加料和共加料模式下分别为60%和32.75%。微波产生的合成气热值为17.44 MJ/m³,大大高于传统加热产生的合成气热值。因此,尽管缺乏基于共气化和微波加热的富氢合成气产生的研究,但这种技术具有在实验室和工业规模上发展的潜力。此外,必须进一步研究原料、床层、吸附剂和催化剂的介电特性,以优化微波加热过程的性能。
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
CiteScore
22.10
自引率
1.50%
发文量
15
审稿时长
8 weeks
期刊介绍: Biofuel Research Journal (BRJ) is a leading, peer-reviewed academic journal that focuses on high-quality research in the field of biofuels, bioproducts, and biomass-derived materials and technologies. The journal's primary goal is to contribute to the advancement of knowledge and understanding in the areas of sustainable energy solutions, environmental protection, and the circular economy. BRJ accepts various types of articles, including original research papers, review papers, case studies, short communications, and hypotheses. The specific areas covered by the journal include Biofuels and Bioproducts, Biomass Valorization, Biomass-Derived Materials for Energy and Storage Systems, Techno-Economic and Environmental Assessments, Climate Change and Sustainability, and Biofuels and Bioproducts in Circular Economy, among others. BRJ actively encourages interdisciplinary collaborations among researchers, engineers, scientists, policymakers, and industry experts to facilitate the adoption of sustainable energy solutions and promote a greener future. The journal maintains rigorous standards of peer review and editorial integrity to ensure that only impactful and high-quality research is published. Currently, BRJ is indexed by several prominent databases such as Web of Science, CAS Databases, Directory of Open Access Journals, Scimago Journal Rank, Scopus, Google Scholar, Elektronische Zeitschriftenbibliothek EZB, et al.
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