Autoignition of n-butanol at elevated pressure and low-to-intermediate temperature

Weber, Bryan W.; Kumar, Kamal; Zhang, Yu; Sung, Chih-Jen

doi:10.1016/j.combustflame.2011.02.005

Cited by 151 publications

(109 citation statements)

References 58 publications

(100 reference statements)

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“…This approach to mixture preparation has been validated in several previous studies by withdrawing gas samples from the mixing tank and analyzing the contents by GC/MS [14], GC-FID [20], and GC-TCD [21]. The study of Weber et al [14] verified that the mole fraction of fuel was within 5 % of the expected mole fraction and the study of Das et al [21] verified that the mole fraction of water was within 2 % of the expected value.…”

Section: Typical Experimental Proceduresmentioning

confidence: 87%

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On the uncertainty of temperature estimation in a rapid compression machine

Weber

Sung

Renfro

2015

Combustion and Flame

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Rapid compression machines (RCMs) have been widely used in the combustion literature to study the low-to-intermediate temperature ignition of many fuels. In a typical RCM, the pressure during and after the compression stroke is measured. However, measurement of the temperature history in the RCM reaction chamber is challenging. Thus, the temperature is generally calculated by the isentropic relations between pressure and temperature, assuming that the adiabatic core hypothesis holds. To estimate the uncertainty in the calculated temperature, an uncertainty propagation analysis must be carried out. Our previous analyses assumed that the uncertainties of the parameters in the equation to calculate the temperature were normally distributed and independent, but these assumptions do not hold for typical RCM operating procedures. In this work, a Monte Carlo method is developed to estimate the uncertainty in the calculated temperature, while taking into account the correlation between parameters and the possibility of non-normal probability distributions. In addition, the Monte Carlo method is compared to an analysis that assumes normally distributed, independent parameters. Both analysis methods show that the magnitude of the initial pressure and the uncertainty of the initial temperature have strong influences on the magnitude of the uncertainty. Finally, the uncertainty estimation methods studied here provide a reference value for the uncertainty of the reference temperature in an RCM and can be generalized to other similar facilities.

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Section: Typical Experimental Proceduresmentioning

confidence: 87%

“…Such analyses have been conducted in the past, for example in the work of Weber et al [14] and Mittal and Sung [15]. Previous analyses generally assumed that the uncertainty of each parameter was normally distributed and independent (i.e.…”

Section: Methods Of Uncertainty Analysismentioning

confidence: 99%

On the uncertainty of temperature estimation in a rapid compression machine

Weber

Sung

Renfro

2015

Combustion and Flame

Self Cite

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“…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%

“…An error propagation analysis is needed to determine the contributions of 37 these factors to the uncertainty of the calculation of the compressed temperature. Weber et al [73] reported that the largest contributor to the total uncertainty in compressed temperature is the error in the initial pressure measurement, whereas the contributions from the measurements of the initial temperature and the compressed pressure are less significant. In addition, the uncertainty of T C is dependent on the actual value of the initial pressure, but not on the values of the other quantities [73].…”

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

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242

123

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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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“…The present work is justified because of the great amount of studies where the auto-ignition of different fuels at low temperatures is analyzed. In them, the ignition delay is obtained in environments poor in oxygen, and the dilution is done by adding N 2 , Ar or CO 2 indistinctly [32][33][34]. This way to control the percent of oxygen is very useful to obtain ignition delays at different temperatures and pressures, and with different combustion temperatures.…”

Section: Justification and Objectivementioning

confidence: 99%

Design of synthetic EGR and simulation study of the effect of simplified formulations on the ignition delay of isooctane and n-heptane

Desantes

López

Molina

et al. 2015

Energy Conversion and Management

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A method to create synthetic mixtures that simulate the Exhaust Gas Recirculation (EGR) of an internal combustion engine, using O 2 , N 2 , CO 2 , H 2 O and Ar, has been designed. Different simplifications of this synthetic EGR error increases with temperature and decreases with pressure, equivalence ratio and oxygen mass fraction. Finally, the limit oxygen mass fractions for the use of each simplification have been obtained. Based on these results, it can be concluded that the only gas that can be obviated to keep the error in ignition delay under 1% is Ar.

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Autoignition of n-butanol at elevated pressure and low-to-intermediate temperature

Cited by 151 publications

References 58 publications

On the uncertainty of temperature estimation in a rapid compression machine

On the uncertainty of temperature estimation in a rapid compression machine

Using rapid compression machines for chemical kinetics studies

Design of synthetic EGR and simulation study of the effect of simplified formulations on the ignition delay of isooctane and n-heptane

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