A comprehensive experimental and modeling study of isobutene oxidation

Zhou, Chong‐Wen; Li, Yang; O'Connor, Eoin; Somers, Kieran P.; Thion, Sébastien; Keesee, Charles L.; Mathieu, Olivier; Petersen, Eric L.; DeVerter, Trent A.; Oehlschlaeger, Matthew A.; Kukkadapu, Goutham; Sung, Chih-Jen; Alrefae, Majed A.; Khaled, Fethi; Farooq, Aamir; Dirrenberger, Patricia; Glaude, Pierre‐Alexandre; Battin‐Leclerc, Frédérique; Santner, Jeffrey; Ju, Yiguang; Held, Timothy; Haas, Francis M.; Dryer, Frederick L.; Curran, Henry J.

doi:10.1016/j.combustflame.2016.01.021

Cited by 287 publications

(198 citation statements)

References 66 publications

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“…超燃发动机中空气在燃烧室内只能停留几个毫秒, 要在这样短的时间内完成点火并燃烧, 点火延时的研究是关键 [1] . [9] 和最新的 AramcoMech_2.0 [10] 能够描述乙烯宽温度范围燃烧反应动力学过程; Ranzi 等通过加入三类新的低温反应类型, 完善了从低温到高温的 Creck [11] 集总反应机理; Glarborg 等 [12] 在 600～900 K, 60×10 5 Pa 下, 通过分析乙烯氧化重要反应, 再结合量化计算得到一套乙烯低温高压燃烧反应机理, 并与平推流实验测得的物种浓度吻合良好; Williams 等通过研究乙烷和丙烷低温点火 [13] 更新的 UCSD 机理 [14] 只包含 50 个物种 247 步反应, 是研究小分子碳氢燃料燃烧机理和实验验证的重要参考 [8,15] [19] 软件激波管模型和封闭均相模型, 用 AramcoMech_1.3 [9] 机理、 UCSD [14] 核心机理, Glarborg [12] 的机理、Wang [16] 的乙烯氧化反应详细机理和 Exp. [5] Exp.…”

Section: 引言unclassified

“…[21] 图 1 乙烯点火延时实验数据比较 Figure 1 Comparison of ethylene experimental ignition delay times Figure 4 Comparison of R1 and R2 reactions' rate constants in different mechanisms with calculated results [23] 围内, 随温度降低 τ～1000/T 斜率变小, 即乙烯在中温段出现负温度效应趋势, 这是新出现的现象, 也是区分高温和低温机理的关键 [17] . AramcoMech_2.0 机理也采用 Goldsmith 等 [23] 的数据更新了 R1 和 R2 反应的动力学参数, 主要用于研究 C4 物种的机理 [10] . 与 AramcoMech Exp.…”

Section: 引言unclassified

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Investigations of Chemical Kinetic Mechanisms for Low-to-medium Temperature Ignition of Ethylene

Li¹,

Wang²,

Guo³

et al. 2017

Acta Chim. Sinica

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Section: 引言unclassified

Investigations of Chemical Kinetic Mechanisms for Low-to-medium Temperature Ignition of Ethylene

Li¹,

Wang²,

Guo³

et al. 2017

Acta Chim. Sinica

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“…The system has a good retention time resolution for C1-C3 species, while C4 species quantification suffer from overlapping peaks of as shown in shows ethane conversion at various temperatures at 5 and 15 atm compared to with two models by Wang et al [26] and AramcoMech 2.0 [70]. Aramco Mech 2.0 was chosen for As explained in chapter 3, the fuel and diluent is premixed before entering the heated section.…”

Section: Measurement Of C4 Speciesmentioning

confidence: 99%

“…In flow species composition are XC 4 H 10 =0.02, with three different models by Wang et al [26], Pyun et al [80] and Curran and coworkers (AramcoMech 2.0 [70]). In flow species composition are XC 4 H 10 =0.02, with three different models by Wang et al [26], Pyun et al [80] and Curran and coworkers (AramcoMech 2.0 [70] …”

mentioning

confidence: 99%

“…[26] , Naik and Dean [76] and Curran and co-workers (AramcoMech 2.0 [70]), for inflow species compositions of XC 2 H 6 = 0.02, XN 2 [26] , Naik and Dean [76] and Curran and co-workers (AramcoMech 2.0 [70]), for inflow species compositions of XC 2 H 6 = 0.02, XN 2 with three different models by Wang et al [26], Pyun et al [80]and Curran and coworkers (AramcoMech 2.0 ) [70]. In flow species composition are XC 4 H 10 =0.02, with three different models by Wang et al [26], Pyun et al [80] and Curran and coworkers (AramcoMech 2.0 [70]). In flow species composition are XC 4 H 10 =0.02, with three different models by Wang et al [26], Pyun et al [80] and Curran and coworkers (AramcoMech 2.0 [70] …”

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confidence: 99%

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Fuel Pyrolysis at Atmospheric and Elevated Pressure Conditions in Micro-Flow Tube Reactor

Shrestha

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Improved efficiency and reduced emissions are essential elements of more sustainable propulsion systems. In addition to providing energy, the fuel in propulsion systems can be also used as coolant for critical engine components. Both the choice of fuel and understanding the fuel pyrolysis and oxidation behavior is critical for design of future propulsion systems. Specifically, well validated chemical kinetic models are needed in designing such systems. A fundamental approach in developing detailed chemical kinetic models is to start with the simplest fuel molecule and progressively increase the complexity of the molecular structure. Unfortunately, real fuels, and jet fuels in particular, consist of hundreds of hydrocarbon species and therefore the development of appropriate chemical kinetic models is challenging. As part of development of chemical kinetic models for these complex fuels, several surrogate models have been identified in order to simplify the modelling effort. Despite the fact that the surrogate reaction models represent a major simplification, they are still too large and require further simplification before implementation in computational simulation of propulsion systems.The present research work aims at solving this problem by decoupling the fuel pyrolysis and oxidation processes. The idea of semi-global model with a fast-thermal pyrolysis of large fuel molecules, in combination with more detailed H2/C1-C4 base model, is considered. The work described here is mainly focused on the experimental aspects of fuel decomposition into H2 and C1-C4 species. For this purpose, a novel micro flow tube reactor (MFTR) with a small mixing volume was designed and developed. Extensive investigations were performed to better understand the uncertainties associated with

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Hydrogen effects on ignition delay time of methyl butanoate in a rapid compression machine

Lee

2020

Intl J of Energy Research

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The effect of hydrogen addition on the ignition delay time of methyl butanoate was studied using a rapid compression machine experiment and ANSYS CHEMKIN-PRO 19.0 numerical analysis. The ignition delay was measured under engine-relevant conditions by varying equivalence ratios (0.5 and 1.0), compression pressures (15 and 30 bar), compression temperatures (860-1060 K), and hydrogen mole fractions in the methyl butanoate/hydrogen mixture (0%, 25%, 50%, and 75%). The kinetic mechanism was modified by adding the methyl butanoate mechanism to the NUIG Aramco 3.0 mechanism and modifying the rate parameters of the H-atom abstraction reactions of methyl butanoate. The numerical results obtained using the modified mechanism were in good agreement with the experimental results. The methyl butanoate/hydrogen mixture did not show a negative temperature coefficient characteristic. With hydrogen addition, the ignition delay increased at low temperatures but decreased at high temperatures. The results of the chemical and dilution effect analysis using the imaginary inert H 2 showed that the chemical effects differ depending on the temperature. Most added hydrogen molecules participate in the chain propagation reactions to produce H radicals and consume OH by the reaction H 2 + OH ! H + H 2 O. This, in turn, changes the reactions of other species, such as HO 2 and H 2 O 2. The results of the reaction path analysis for the related species showed that the addition of hydrogen reduced radical reactions at low temperatures, while increasing them at high temperatures.

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A comprehensive experimental and modeling study of isobutene oxidation

Cited by 287 publications

References 66 publications

Investigations of Chemical Kinetic Mechanisms for Low-to-medium Temperature Ignition of Ethylene

Investigations of Chemical Kinetic Mechanisms for Low-to-medium Temperature Ignition of Ethylene

Fuel Pyrolysis at Atmospheric and Elevated Pressure Conditions in Micro-Flow Tube Reactor

Hydrogen effects on ignition delay time of methyl butanoate in a rapid compression machine

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