Numerical and Experimental Investigation of <i>n</i>-Heptane Autoignition in the Ignition Quality Tester (IQT)

Bogin, Gregory E.; DeFilippo, Anthony; Chen, Jyh-Yuan; Chin, Gregory T.; Luecke, Jon; Ratcliff, Matthew A.; Zigler, Bradley T.; Dean, Anthony M.

doi:10.1021/ef201079g

Cited by 64 publications

(71 citation statements)

References 46 publications

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“…Bogin et al have modified the IQT controls and operating parameters for use in more fundamental ignition delay and kinetic mechanism validation studies [63][64][65]. The authors observed that for a sufficiently long auto-ignition delay time (ID) (e.g., >40 ms), the mixture conditions are nearly homogeneous in nature.…”

Section: Constant Volume Autoignition Experimentsmentioning

confidence: 99%

Performance of lignin derived compounds as octane boosters

Tian

McCormick

Ratcliff

et al. 2017

Fuel

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h i g h l i g h t sVarious anisoles and guaiacols which can be derived from lingin have been evaluated as octant boosters. All compounds match or outperform RON 95 gasoline with respect to anti-knock quality, and showed equal or improved thermal efficiency. The trends of auto-ignition delay time measured in a modified IQT are in line with the engine test. a b s t r a c tThe performance of spark ignition engines is highly dependent on fuel anti-knock quality, which in turn is governed by autoignition chemistry. In this study, we explore this chemistry for various aromatic oxygenates (i.e., anisole, 4-methyl anisole, 4-propyl anisole, guaiacol, 4-methyl guaiacol, 4-ethyl guaiacol) that can be produced from lignin, a low value residual biomass stream that is generated in paper pulping and cellulosic ethanol plants. All compounds share the same benzene ring, but have distinct oxygen functionalities and degrees of alkylation. The objective of this study is to ascertain what the impact is of said side groups on anti-knock quality and, by proxy, on fuel economy in a modern Volvo T5 spark ignition engine. To better comprehend the variation in behavior amongst the fuels, further experiments have been conducted in a constant volume autoignition device. The results demonstrate that alkylation has a negligible impact on anti-knock quality, while the addition of functional oxygen groups manifests as a deterioration in anti-knock quality.

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Section: Constant Volume Autoignition Experimentsmentioning

confidence: 99%

Performance of lignin derived compounds as octane boosters

Tian

McCormick

Ratcliff

et al. 2017

Fuel

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“…This indicates that the oscillations in the pressure trace are related to the injection process. This rela- tionship was investigated in the National Renewable Energy Laboratory (NREL) [29,32] by monitoring the N.L and the corresponding changes in high speed images taken for the fuel spray during the injection process. NREL concluded that the oscillations were caused by the changes in the rate of fuel delivery during the injection process.…”

Section: Analysis Of the Oscillations In The Pressure Tracementioning

confidence: 99%

“…It is worth noting that a detailed analysis of the pressure traces for the 32 tests, used to determine the DCN in this investigation, indicated test-to-test variability in these oscillations. Such variability can be explained by the test-to-test variability in the needle oscillations reported by NREL [29,32].…”

Section: Analysis Of the Oscillations In The Pressure Tracementioning

confidence: 99%

Investigation of Physical and Chemical Delay Periods of Different Fuels in the Ignition Quality Tester

Zheng¹,

Badawy²,

Henein

et al. 2013

Journal of Engineering for Gas Turbines and Power

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This paper investigates the physical and chemical ignition delay (ID) periods in the constant volume combustion cflamber of the Ignition Quality Tester (IQT). IQT was used to determine the derived cetane number (DCN) according to ASTM D6890-10a standards. The fuels tested were ultra low sulfur diesel (ULSD),, and two synthetic fuels ofSasol IPK and F-T SPK (S-8). A comparison was made between the DCN and cetane number (CN) determined according to ASTM-D613 standards. Tests were conducted under steady state conditions at a constant pressure of 21 bars and various air temperatures ranging from 778 K to 848 K. The rate of heat release (RHR) was calculated from the measured pressure trace, and a detailed analysis of the RHR trace was made particularly for the auto-ignition process. Tests were conducted to determine the physical and chemical delay periods by comparing results obtained from two tests. In the first test, the fuel was injected into air according to ASTM standards. In the second test, the fuel was injected into nitrogen. The point at which the two resultant pressure traces separated was considered to be the end of the physical delay period. The effects of the charge temperature on the total ID as defined in ASTM D6890-10a standards, as well as on the physical and chemical delays, were determined. It was noticed that the physical delay represented a significant part of the total ID over all the air temperatures covered in this investigation. Arrhenius plots were developed to determine the apparent activation energy for each fuel using dijferent IDs. The first was based on the total ID measured according to ASTM standards. The second was the chemical delay determined in this investigation. The activation energy calculated from the total ID showed higher values for lower CN fuels except Sasol IPK. The activation energy calculated from the chemical delay period showed consistency in the increase of the activation energy with the drop in CN including Sasol IPK. The difference between the two findings could be explained by examining the sensitivity of the physical delay period of different fuels to the change in air temperature.

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“…The culmination of the large body of experimental work was the development of a detailed kinetic mechanism for n-heptane, primarily through efforts by researchers at Lawrence Livermore National Laboratory [22,23]. Recent results have been reported on autoignition of nheptane in the IQT [5,6], which is particularly relevant to this study due to the similarity between the IQT and CID devices. The chemical kinetic mechanism of n-heptane predicts a clear NTC (negative temperature coefficient) region in which, counterintuitively, ignition delay increases with increasing temperature.…”

Section: Introductionmentioning

confidence: 99%

“…The experimental platform is similar to the well-known ignition quality tester (IQT). Recent work on autoignition of n-heptane and several of its isomers suggests that systems like the IQT and CID can, under the right circumstances, be used to validate chemical-kinetic mechanisms [5,6]. A key factor in such efforts is the ignition delay itself, which must be sufficiently long to allow for significant fuel-air mixing and thus a relatively homogeneous mixture at the time of ignition.…”

Section: Introductionmentioning

confidence: 99%

Experimental and Computational Study of n-Heptane Autoignition in a Direct-Injection Constant-Volume Combustion Chamber

Allen

Pitz

Fisher

2014

Journal of Engineering for Gas Turbines and Power

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The purpose of this study was to characterize experimental n-heptane combustion behavior in a direct-injection constant-volume combustion chamber (DI-CVCC), using chamber pressure to infer ignition delay and heat-release rate. Measurements generally displayed expected trends and indicated entirely premixed combustion with no mixingcontrolled phase. A significant finding was the observation of negative temperature coefficient (NTC) behavior. Comparing results with CHEMKIN-PRO simulations, it was found that a homogeneous combustion model was reasonably accurate for ignition delays longer than 5 ms. The combination of NTC behavior and homogeneous fuel-air mixtures suggests that this DI-CVCC can be useful for validation of chemical-kinetic mechanisms.

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Numerical and Experimental Investigation of n-Heptane Autoignition in the Ignition Quality Tester (IQT)

Cited by 64 publications

References 46 publications

Performance of lignin derived compounds as octane boosters

Performance of lignin derived compounds as octane boosters

Investigation of Physical and Chemical Delay Periods of Different Fuels in the Ignition Quality Tester

Experimental and Computational Study of n-Heptane Autoignition in a Direct-Injection Constant-Volume Combustion Chamber

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