Comparative Autoignition Trends in Butanol Isomers at Elevated Pressure

Weber, Bryan W.; Sung, Chih-Jen

doi:10.1021/ef302195c

Cited by 82 publications

(80 citation statements)

References 36 publications

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“…The volume traces were determined from the measured pressure trace of the non-reactive experiment using isentropic core relations and a temperature-dependent mixture specific heat ratio [31]. Details on compositions and volume histories can be found in Supplementary…”

Section: Simulations and Sensitivity Analysismentioning

confidence: 99%

The influence of n -butanol blending on the ignition delay times of gasoline and its surrogate at high pressures

Agbro

Tomlin

Lawes

et al. 2017

Fuel

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The influence of blending n-butanol at 20% by volume on the ignition delay times for a reference gasoline was studied in a rapid compression machine (RCM) for stoichiometric fuel/air mixtures at 20 bar and 678 K-858 K. Delay times for the blend lay between those of stoichiometric gasoline and stoichiometric n-butanol across the temperature range studied. At lower temperatures, delays for the blend were however, much closer to those of n-butanol than gasoline despite n-butanol being only 20% of the mixture. Under these conditions n-butanol acted as an octane enhancer over and above what might be expected from a simple linear blending law. The ability of a gasoline surrogate, based on a toluene reference fuel (TRF), to capture the main trends of the gasoline/ n-butanol blending behaviour was also tested within the RCM. The 3-component TRF based on a mixture of toluene, n-heptane and iso-octane was able to capture the trends well across the temperature range studied. Simulations of ignition delay times were also performed using a detailed blended nbutanol/TRF mechanism based on the adiabatic core assumption and volume histories from the experimental data. Overall, the model captured the main features of the blending behaviour, although at the lowest temperatures, predicted ignition delays for stoichiometric n-butanol were longer than those observed. A bruteforce local sensitivity analysis was performed to evaluate the main chemical processes driving the ignition behaviour of the TRF, n-butanol and blended fuels. The reactions of fuel + OH dominated the sensitivities at lower temperatures, with H abstraction from nn-butanol and the blend. At higher temperatures the decomposition of H 2 O 2 and reactions of HO 2 and that of formaldehyde with OH became critical, in common with the ignition behaviour of other fuels. Remaining uncertainties in the rates of these key reactions are discussed.

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Section: Simulations and Sensitivity Analysismentioning

confidence: 99%

The influence of n -butanol blending on the ignition delay times of gasoline and its surrogate at high pressures

Agbro

Tomlin

Lawes

et al. 2017

Fuel

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show abstract

“…In this approach, continuous stirring is needed to ensure a homogeneous mixture, for instance by using a magnetic stirrer [cf. 44,65,[70][71][72][73][74][75]. In addition, the possibility of fuel cracking/pyrolysis within the mixture preparation vessel over an extended time period needs to be avoided, and characterization experiments should be conducted to confirm the assumptions of minimal/negligible fuel loss, mixture homogeneity, and non-decomposition of fuel in the mixture preparation vessel, as carried out in [e.g., 65,73,74].…”

Section: Uncertainties and Issues For Rcm Experimentsmentioning

confidence: 99%

Using rapid compression machines for chemical kinetics studies

Sung¹,

Curran²

2014

Progress in Energy and Combustion Science

Self Cite

242

122

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Rapid compression machines (RCMs) are used to simulate a single compression stroke of an internal combustion engine without some of the complicated swirl bowl geometry, cycle-to-cycle variation, residual gas, and other complications associated with engine operating conditions. RCMs are primarily used to measure ignition delay times as a function of temperature, pressure, and fuel/oxygen/diluent ratio; further they can be equipped with diagnostics to determine the temperature and flow fields inside the reaction chamber and to measure the concentrations of reactant, intermediate, and product species produced during combustion. This paper first discusses the operational principles and design features of RCMs, including the use of creviced pistons, which is an important feature in order to suppress the boundary layer, preventing it from becoming entrained into the reaction chamber via a roll-up vortex. The paper then discusses methods by which experiments performed in RCMs are interpreted and simulated. Furthermore, differences in measured ignition delays from RCMs and shock tube facilities are discussed, with the apparent initial gross disagreement being explained by facility effects in both types of experiments. Finally, future directions for using RCMs in chemical kinetics studies are also discussed.

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“…Experiments have also been performed in rapid compression machines, although the acquired ignition delay times [20] reaction network for iso-butanol oxidation, especially the pathways involving oxygen addition to fuel radicals [22]. No speciation studies have been reported at high pressures and low to intermediate temperatures.…”

Section: Introductionmentioning

confidence: 99%

“…No speciation studies have been reported at high pressures and low to intermediate temperatures. Weber and Sung [20] commented that none of the existing models can predict the ignition delays at high pressure (30 bar) and low to intermediate temperature (754-857 K) well, and highlighted the importance of the peroxy chemistry in the low temperature pathways of iso-butanol oxidation based on sensitivity analysis of the ignition delay time using the Sarathy mechanism [17]. Without intermediate species information, the competing ratios between β-scission reactions and fuel propagation into the low temperature chain branching pathway of oxygen addition to fuel radicals were not investigated directly.…”

Section: Introductionmentioning

confidence: 99%

Intermediate species measurement during iso-butanol auto-ignition

Zhang

et al. 2015

Combustion and Flame

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Comparative Autoignition Trends in Butanol Isomers at Elevated Pressure

Cited by 82 publications

References 36 publications

The influence of n -butanol blending on the ignition delay times of gasoline and its surrogate at high pressures

The influence of n -butanol blending on the ignition delay times of gasoline and its surrogate at high pressures

Using rapid compression machines for chemical kinetics studies

Intermediate species measurement during iso-butanol auto-ignition

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