System of Adsorption of CO2 in Coalbed

Southern Brazilian Journal of Chemistry, Volume 26, No. 26, 2018 Pub Date : 2018-06-30 DOI:10.37633/sbjc.26(26)2018.2-9

M. A. Klunk, S. Dasgupta, M. Das, Z. Shah

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引用次数: 2

Abstract

Carbon capture and storage (CCS) has been observed as an alternative measure to mitigate emissions from greenhouse gases. CCS systems separate CO2 during the process of converting fuel and transport to the facilities where they are stored, e.g., under geological formation conditions. Capture and sequestration technologies are now widely used in different industries. CO2 capture is currently a costly and energy-consuming technology. The costs obviously depend on the size of the plant and the type of fuel used. Generally, capture systems are categorized into three categories: pre-combustion, post-combustion, and oxy-fuel combustion. The saline aquifer, depleted oil, and gas fields are large-capacity storage sinks. The coalbeds also provide as a substitute to geological storage. One of the main advantages of coal storage is renewable methane fuel and coal desulfurization. The studied coal reserves are located in Candiota, State of Rio Grande do Sul, Brazil. These are the largest coal deposits in the country, with a reserve of 1 billion tons. This work will represent a study on CO2 storage in Candiota coalbed system. The use of a synthetic CO2 cylinder with a flow of 0.2 L /min varies the time of contact with the coalbed. The results from the volatile matter increase by 11%. The results of the ultimate analysis exhibited an 8% increase for carbon and oxygen after 60 minutes of CO2 flow in the coalbed. On the other hand, there was a reduction of 32% for sulfur. The resultant phenomena occur due to the adsorption capacity of CO2, where the compounds are released from the pores of coal

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二氧化碳在煤层中的吸附体系

碳捕获与封存(CCS)已被视为减少温室气体排放的一种替代措施。CCS系统在转换燃料和运输到储存设施的过程中分离二氧化碳，例如，在地质构造条件下。捕获和封存技术现在广泛应用于不同的行业。二氧化碳捕获目前是一项昂贵且耗能的技术。成本显然取决于电厂的规模和所用燃料的类型。一般来说，捕集系统分为三类:燃烧前、燃烧后和全氧燃料燃烧。咸水层、枯竭的油气田是大容量的储水池。煤层也可以作为地质储存的替代品。储煤的主要优点之一是可再生的甲烷燃料和煤的脱硫。研究的煤炭储量位于巴西南里奥格兰德州的坎迪奥塔。这些是全国最大的煤矿，储量达10亿吨。这项工作将代表二氧化碳在坎迪奥塔煤层系统中的储存研究。使用流量为0.2 L /min的合成CO2钢瓶，会改变与煤层的接触时间。挥发物的结果提高了11%。最终分析结果显示，在二氧化碳在煤层中流动60分钟后，碳和氧增加了8%。另一方面，硫减少了32%。所产生的现象是由于二氧化碳的吸附能力，其中化合物从煤的孔隙中释放出来

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来源期刊

Southern Brazilian Journal of Chemistry, Volume 26, No. 26, 2018

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