The first application of high-order Virial equation of state and ab initio multi-body potentials in modeling supercritical oxidation in jet-stirred reactors

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-02 DOI:arxiv-2409.01099

Mingrui Wang, Ruoyue Tang, Xinrui Ren, Hongqing Wu, Ting Zhang, Song Cheng

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Abstract

Supercritical oxidation processes in jet-stirred reactors (JSR) have been modeled based on ideal gas assumption. This can lead to significant errors in or complete misinterpretation of modeling results. Therefore, this study newly developed a framework to model supercritical oxidation in JSRs by incorporating ab initio multi-body molecular potentials and high-order mixture Virial equation of state (EoS) into real-fluid conservation laws, with the related numerical strategies highlighted. With comparisons with the simulation results based on ideal EoS and the experimental data from high-pressure JSR experiments, the framework is proved to be a step forward compared to the existing JSR modeling frameworks. To reveal the real-fluid effects on the oxidation characteristics in jet-stirred reactors, simulations are further conducted at a wide range of conditions (i.e., temperatures from 500 to 1100 K and pressures from 100 to 1000 bar), the real-fluid effect is found to significantly promote fuel oxidation reactivity, especially at low temperatures, high pressures, and for mixtures with heavy fuels. The significant influences of real-fluid behaviors on JSR oxidation characteristics emphasize the need to adequately incorporate these effects for future modeling studies in JSR at high pressures, which has now been enabled through the framework proposed in this study.

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高阶维里亚尔状态方程和 ab initio 多体势能在喷射搅拌反应器超临界氧化建模中的首次应用

喷射搅拌式反应器（JSR）中的超临界氧化过程是根据理想气体假设建模的。这会导致建模结果出现重大误差或完全误解。因此，本研究通过在真实流体守恒定律中加入初始多体分子势和高阶混合物维里亚尔状态方程（EoS），并强调了相关的数值策略，新开发了喷射搅拌反应器中超临界氧化的建模框架。通过与基于理想 EoS 的模拟结果和高压 JSR 实验数据的比较，证明该框架比现有的 JSR 建模框架向前迈进了一步。为了揭示真实流体对喷气搅拌反应器氧化特性的影响，我们在多种条件下（即温度从 500 到 1100 K，压力从 100 到 1000 bar）进一步进行了模拟，发现真实流体效应显著促进了燃料氧化反应性，尤其是在低温、高压和重燃料混合物条件下。实际流体行为对 JSR 氧化特性的显著影响强调了将这些效应充分纳入未来高压 JSR 建模研究的必要性，而本研究中提出的框架现已实现了这一点。

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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arXiv - PHYS - Chemical Physics

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