Aspects of kerogen oxidative dissolution in subcritical water using oxygen from air

IF 1.3 4区 工程技术 Q4 ENERGY & FUELS
Oil Shale Pub Date : 2021-01-01 DOI:10.3176/oil.2021.3.02
K. Kaldas, A. Niidu, Gert Preegel, J. Uustalu, K. Muldma, M. Lopp
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引用次数: 2

Abstract

. Society’s growing demands on everyday products and materials are increasingly difficult to meet in an environment that seeks to avoid petroleum-based processes. Instead of abandoning fossil materials altogether, more research should be done on their efficient and clean conversion. One option for this is the oxidative dissolution of kerogen in water under conditions that satisfy the subcritical range (T = 150–200 °C, pO 2 = 0.5–4 MPa). The resulting mixture contains a substantial amount of various aliphatic carboxylic and dicarboxylic acids. Both batch and semi-continuous processes were set up to find the main factors and optimal conditions for the kerogen dissolution process. The rate of transformation of organic carbon to dissolved organic compounds was mainly influenced by elevated temperature and oxygen partial pressure. To obtain high yields of organic carbon dissolution and to avoid the formation of excess CO 2 , the oxidation of kerogen should be carried out fast (< 1 h) and under high oxygen pressure. By employing a temperature of 175 °C and O 2 pressure of 2 MPa, over 65% of the initial organic carbon dissolves in about one hour. Prolonged reaction times or harsher oxidation conditions resulted in a rapid degradation of dissolved matter and also of the valuable products formed. The organic matter content of the initial oil shale had a direct effect on the further degradation of dicarboxylic acid and consequently on the overall yield. The suitability of using a trickle-bed reactor for kerogen dissolution is discussed in detail on the basis of experimental results.
利用空气中的氧气在亚临界水中氧化溶解干酪根的几个方面
. 社会对日常产品和材料日益增长的需求越来越难以在一个寻求避免以石油为基础的过程的环境中得到满足。与其完全放弃化石材料,还不如对它们的高效和清洁转换进行更多的研究。其中一个选择是在满足亚临界范围(T = 150-200°C, p_2 = 0.5-4 MPa)的条件下,干酪根在水中的氧化溶解。所得到的混合物含有大量的各种脂肪族羧酸和二羧酸。建立了间歇式和半连续式两种工艺,找出了影响干酪根溶解的主要因素和最佳工艺条件。有机碳向溶解有机物转化的速率主要受温度升高和氧分压的影响。为了获得较高的有机碳溶解收率和避免过量co2的形成,干酪根的氧化应在高氧压下快速(< 1 h)进行。在175°C的温度和2mpa的o2压力下,超过65%的初始有机碳在大约一个小时内溶解。延长反应时间或严酷的氧化条件导致溶解物质和形成的有价值产品的迅速降解。初始油页岩的有机质含量直接影响二羧酸的进一步降解,从而影响总体产量。在实验结果的基础上,详细讨论了采用滴床反应器进行干酪根溶解的适宜性。
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
Oil Shale
Oil Shale 工程技术-工程:石油
CiteScore
2.90
自引率
15.80%
发文量
14
审稿时长
4.2 months
期刊介绍: The Oil Shale is a scientific-technical open access journal published by the Estonian Academy Publishers in collaboration with the University of Tartu, Tallinn University of Technology, and the Estonian University of Life Sciences.
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