Simulation tool for the analysis of in-situ combustion experiments that considers complex kinetic schemes and detailed mass transfer- theoretical analysis of the gas phase CO oxidation reaction

IF 0.5 4区工程技术 Q4 ENERGY & FUELS

Ct&f-Ciencia Tecnologia Y Futuro Pub Date : 2022-06-29 DOI:10.29047/01225383.402

Juan Felipe Hincapié Álvarez, Sebastian López Gómez, A. Molina

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引用次数: 0

Abstract

A simulation tool was designed for analyzing various experimental setups that include the ability to model detailed chemical reaction schemes for in-situ combustion (ISC) analysis.,. The simulation tool was illustrated with a theoretical example to the extent of CO oxidation in a gaseous phase takes place during ISC. The models in the simulation tool are based on fundamental conservation laws, physical correlations for porous media properties, and property databases available in literature. Emphasis is made on the analysis of chemical reactions in the gas phase, a characteristic that may be useful when temperatures are above 700°C and oxygen, unburned hydrocarbons, and CO coexist. The three modules of the simulation tool: (i) Kinetic cell, (ii) One-dimensional reactor, and (iii) Combustion tube, can be used to represent in detail the processes taking place in the typical laboratory-scale equipment used to characterize ISC. Tools for the analysis of transport phenomena and multiphase reactions, present in all three models, can support the process of finding chemical kinetic parameters for an easier calculation of device-independent kinetic constants. Four applications have the simulator scope: (i) Analysis of reactions in the gas phase, (ii) Axial gradients in a kinetic cell, (iii) Pressure build-up in a combustion tube, and (iv) Ignition in a combustion tube. These examples highlight the importance that homogeneous reactions may have in these systems and the existence, under certain conditions, of concentration gradients that are normally neglected, and can affect the interpretation of ISC experiments.

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考虑复杂动力学方案和详细传质的原位燃烧实验分析模拟工具-气相CO氧化反应的理论分析

设计了一个模拟工具，用于分析各种实验设置，包括模拟原位燃烧(ISC)分析的详细化学反应方案。用一个理论实例说明了模拟工具在ISC过程中CO在气相氧化的程度。模拟工具中的模型基于基本守恒定律、多孔介质性质的物理相关性和文献中可用的性质数据库。重点放在气相化学反应的分析上，当温度高于700°C，氧气、未燃烧的碳氢化合物和CO共存时，这一特性可能是有用的。模拟工具的三个模块:(i)动力单元，(ii)一维反应器和(iii)燃烧管，可用于详细表示用于表征ISC的典型实验室规模设备中发生的过程。在这三种模型中都有用于分析输运现象和多相反应的工具，可以支持寻找化学动力学参数的过程，从而更容易计算与装置无关的动力学常数。模拟器的应用范围有四种:(i)气相反应分析，(ii)动力池的轴向梯度，(iii)燃烧管内的压力积聚，(iv)燃烧管内的点火。这些例子突出了均相反应在这些体系中可能具有的重要性，以及在某些条件下通常被忽视的浓度梯度的存在，这些浓度梯度可能影响ISC实验的解释。

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

Ct&f-Ciencia Tecnologia Y Futuro Energy-General Energy

CiteScore

1.50

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The objective of CT&F is to publish the achievements of scientific research and technological developments of Ecopetrol S.A. and the research of other institutions in the field of oil, gas and alternative energy sources. CT&F welcomes original, novel and high-impact contributions from all the fields in the oil and gas industry like: Acquisition and Exploration technologies, Basins characterization and modeling, Petroleum geology, Reservoir modeling, Enhanced Oil Recovery Technologies, Unconventional resources, Petroleum refining, Petrochemistry, Upgrading technologies, Technologies for fuels quality, Process modeling, and optimization, Supply chain optimization, Biofuels, Renewable energies.