Hydrogen production via natural gas reforming: A comparative study between DRM, SRM and BRM techniques

2021 Third International Sustainability and Resilience Conference: Climate Change Pub Date : 2021-11-15 DOI:10.1109/IEEECONF53624.2021.9668026

Mohammad Yusuf, Leila Bazli, Mohammad Azad Alam, F. Masood, L. K. Keong, A. Noor, K. Hellgardt, Bawadi Abdullah

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引用次数: 9

Abstract

The world population is escalating at a tremendous scale, and hence the global energy demands. The utilization of fossil fuels on a massive scale is not environmentally friendly and posing threats to global warming. CH4 and CO2 are the two major greenhouse gases (GHGs) that are mainly responsible for the greenhouse effect. Gas reforming techniques are promising alternatives to utilize the two GHGs and produce alternative sources of fuel such as syngas and hydrogen. Steam, dry and bireforming of methane are the three main gas reforming processes that can be used for hydrogen and syngas production. These gas reforming reactions are highly endothermic in nature; hence catalyst development is another aspect that is still persistent. The SRM reaction is an extensively used and accepted method for hydrogen production due to its comparatively lower activation energy requirement than BRM and DRM. However, DRM can be a promising technique to produce syngas, since the syngas produces is with H2: CO of unity. The syngas produced by DRM can be used directly in Fischer-Tropsch synthesis to produce higher hydrocarbons.

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天然气重整制氢:DRM、SRM和BRM技术的比较研究

世界人口正在以巨大的规模增长，因此全球能源需求也在不断增加。大规模使用化石燃料对环境不友好，对全球变暖造成威胁。CH4和CO2是造成温室效应的两种主要温室气体(ghg)。气体重整技术是利用这两种温室气体并生产合成气和氢气等替代燃料的有希望的替代方法。甲烷的蒸汽重整、干式重整和双重整是可用于氢气和合成气生产的三种主要气体重整工艺。这些气体重整反应本质上是高度吸热的;因此，催化剂的发展是另一个仍在持续的方面。SRM反应比BRM和DRM反应需要的活化能更低，是一种被广泛使用和接受的制氢方法。然而，DRM是一种很有前途的合成气生产技术，因为合成气生产是与H2: CO统一的。DRM产生的合成气可直接用于费托合成，以生产高级碳氢化合物。

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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2021 Third International Sustainability and Resilience Conference: Climate Change

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