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首页> 外文会议>SPE Annual Technical Conference and Exhibition >A Comprehensive Kinetics Model for Light Oil Oxidation/Combustion Reactions under High Pressure Air Injection Process (HPAI)
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A Comprehensive Kinetics Model for Light Oil Oxidation/Combustion Reactions under High Pressure Air Injection Process (HPAI)

机译:高压空气喷射过程下轻型油氧化/燃烧反应的综合动力学模型(HPAI)

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摘要

It is acknowledged that chemical reactions and their kinetics play a major role on the success of both light and heavy oil air injection processes. Historically, Light oil reactions have been characterized mostly using conventional heavy oil kinetics models. However, sensitivity of the reaction kinetics to phase behavior and compositional changes in light oils call for a comprehensive study of kinetics of light oil oxidation. This paper provides a new and comprehensive kinetic model for light oils oxidation/combustion reactions under HPAI, through experimental studies and numerical simulation. For the purpose of this research, a high pressure ramped temperature oxidation reactor (HPRTO) was designed. 15 air injection and nitrogen injection experiments were conducted on the mixture of light oil, water, and core. Based on the data, observations, and understandings achieved during the course of the experimental study, a reaction kinetic model was set up. This primary kinetic model was then incorporated into a thermal numerical simulation model to replicate the behavior of the conducted air injection tests. After fine-tuning of some kinetic parameters against the experimental data, the final proposed model was verified by its successful application to two other different cases. The significant finding of this research, which is the main feature of the proposed kinetic model, was the recognition and characterization of the potential vapor phase combustion reactions during the HPAI process and incorporating them into a light oil kinetics model. The model integrates the hydrocarbon compositional changes and energy generation characteristics of the oxygen addition or so called LTO reactions. Introducing the concept of flammability range into the kinetic model and defining the flammable limits for vapor fuel mixture in this model enables accurate prediction of ignition and exhaustion of the combustion reactions in the vapor phase. Lack of a reliable kinetics model for incorporation into field numerical simulations has been a limiting factor to the prospective vast applications of HPAI as an enhanced recovery method. The kinetics model proposed in this paper, which is supported by extensive experimental data, could successfully predict the oxidation/combustion behavior of two different light oils under the conditions associated with high-pressure air injection tests. The paper also presents a framework for application of the kinetics model to any light oil under HPAI.
机译:它承认,化学反应及其动力学对光和重油空气注入过程的成功起主要作用。从历史上看,轻油反应的特点是主要使用传统的重油动力学模型。然而,反应动力学对轻油中相位行为和组成变化的敏感性呼吁轻油氧化动力学研究。本文通过实验研究和数值模拟提供了HPAI下的轻油氧化/燃烧反应的新型和综合动力学模型。出于本研究的目的,设计了高压斜坡温度氧化反应器(HPRTO)。在轻油,水和核的混合物上进行15空气喷射和氮注射实验。基于在实验研究过程中实现的数据,观察和谅解,建立了反应动力学模型。然后将该主要动力学模型结合到热数模拟模型中以复制进行的空气喷射测试的行为。在对实验数据进行微调的一些动力学参数之后,最终提出的模型通过其成功应用于其他另外两种不同案例来验证。本研究的重要发现是所提出的动力学模型的主要特征,是在HPAI过程中识别和表征潜在的气相燃烧反应,并将它们掺入轻油动力学模型中。该模型整合了氧气添加剂的烃组成变化和所谓的LTO反应的能量产生特性。将可燃性范围的概念引入动力学模型并定义该模型中的蒸汽燃料混合物的易燃局限性,可以精确地预测蒸汽相中燃烧反应的点火和耗尽。缺乏用于纳入现场数值模拟的可靠动力学模型是HPAI作为增强恢复方法的预期广泛应用的限制因素。本文提出的动力学模型由广泛的实验数据支持,可以在与高压空气喷射试验相关的条件下成功预测两种不同轻油的氧化/燃烧行为。本文还介绍了动力学模型将动力学模型应用于HPAI下的任何轻油的框架。

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