A Comparative Study of Ignition Delay of Cracked Kerosene/Air and Kerosene/Air over a Wide Temperature Range

WANG, Yijun; ZHANG, Dexiang; WAN, Zhongjun; Li, Ping; ZHANG, Changhua

doi:10.3866/pku.whxb201806042

Cited by 7 publications

(4 citation statements)

References 22 publications

(25 reference statements)

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“…Experimental research on the combustion characteristics of fossil fuels with the addition of blending agents has been conducted, and some combustion models have been developed to predict the combustion performance of various fuel blends. Wang et al 8 studied the ignition delay of kerosene cracking products/RP-3 kerosene over a relatively wide temperature range from 657 to 1333 K via a shock tube. Liu et al 9 determined the flame radius diffusion rate, Markstein length, and laminar flame speed of methane/RP-3 aviation kerosene based on studies in the combustion bomb facility.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Combustion Characteristics When Adding Hydrogen and Short-Chain Hydrocarbons to RP-3 Aviation Kerosene Based on the Variation Disturbance Method

Guo

Wang

et al. 2019

Energy Fuels

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Hydrogen and five short-chain hydrocarbons are mixed with RP-3 aviation kerosene (RP-3) to study their blending effects on the combustion of RP-3. Seven combustion characteristics, the ignition delay time, burnout time, adiabatic flame temperature, extinction temperature, rate of production of hydroxyl radicals, laminar flame speed, and extinction strain rate, are simulated in four different reactors. The simulated data are preprocessed to match the requirements for a variation disturbance method proposed in this paper, and then the disturbance is obtained for representing the total influence of hydrogen and five short-chain hydrocarbons blending on the combustion properties of RP-3. The results show that H2, CH4, and C2H4 have a greater degree of disturbance to RP-3. In contrast, the influence of C3H6 is the weakest. The rate of disturbance shows that H2 and C2H4 have a positive effect on each of the combustion characteristics, and especially, C2H4 plays a promoting role in the combustion performance of RP-3. The reaction paths of seven fuels are analyzed by time-integrated element flux analysis, and the viability and rationality of the variation disturbance method are supported by the calculation of branching ratios of six main reaction channels.

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Section: Introductionmentioning

confidence: 99%

Analysis of Combustion Characteristics When Adding Hydrogen and Short-Chain Hydrocarbons to RP-3 Aviation Kerosene Based on the Variation Disturbance Method

Guo

Wang

et al. 2019

Energy Fuels

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“…For different flight regimes, correspondingly different cracking conditions, the species and quantities of pyrolysis products vary drastically 10 . The conversion rate can reach 93%, and the gaseous pyrolysis products are up to 85% in mole fraction under the literature tested conditions 11 . Since no atomization and evaporation the pyrolysis gas can be quickly mixed with air and forms a combustible mixture.…”

Section: Introductionmentioning

confidence: 99%

“…Pei et al 13 measured ignition delay times of the cracked n‐C 10 H 22 in shock tube experiment at the temperature of 1296‐1915 K. For cracked n‐C 10 H 22 , it presented that thermal cracking improves the ignitability at certain conditions to a limited conversion degree. Wang et al 11 comparatively studied the ignition delay time of kerosene and cracked products at wider temperature ranges from 657 to 1333 K. the cracked products ignites faster than kerosene at 830‐1000 K, while kerosene ignites much faster than cracked products below 830 K. The experimental pressure and equivalence ratios is limited to 1 MPa and 1.0 at low temperature regimes.…”

Section: Introductionmentioning

confidence: 99%

Experimental study of ignition behaviors of pyrolysis gas of kerosene‐based endothermic hydrocarbon fuel

2021

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Summary The pyrolysis gas consisting of 29.4% CH4, 21.3% C2H4, 30.8% C2H6, and 18.5% C3H6 in mole fraction is presented, as the surrogate of the actual gaseous pyrolysis products. At the conditions of TC = 877.7‐963 K, PC = 3.22‐4.37 MPa, φ = 0.5 and 1.0, the ignition delays of pyrolysis gas/air (diluted with 52% Ar) have been measured. With TC or PC increasing, the ignition delay time decreases. The auto‐ignition of φ = 1.0 is faster than that of φ = 0.5. Furthermore, two widely used small hydrocarbons chemical mechanisms are validated with the measured results. The USC‐II mechanism can well predict experimental results at high‐T regimes, but fails at low‐T regimes. By sensitivity analysis of temperature, the two elementary reactions C2H6 + OH = C2H5 + H2O (negative sensitivity coefficient) and C3H6 + OH = aC3H5 + H2O (positive sensitivity coefficient) have been identified, which have higher reactivity at low‐T and lower reactivity at high‐T. Considering the extreme uncertainty of rate constants of C3H6 + OH = aC3H5 + H2O, the kinetic parameters have been modified for improving the predictions. The validated results indicate that the optimized mechanism improves predictions of the auto‐ignition behavior at low temperature regimes.

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“…Numerous publications are devoted to the consideration of this issue using an experimental approach as well as different mathematical models. , The optimization of igniton is always of interest for scientists and engineers who deal with different fuels in different conditions . Last time, some approaches were proposed that use an Arrhenius equation for description of the dependence of the IDT on the environmental temperature. − However, all of these works describe only the gas-phase ignition of disel fuel or some types of kerosene in different conditions. This is a simple enough case of the homogeneous gas-phase ignition, and authors have shown that the IDT clearly satisfy the inverted Arrhenius dependence.…”

Section: Introductionmentioning

confidence: 99%

Efficiency of Different Heat Exchange Mechanisms for Ignition of Coal–Water Compositions

2019

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An optimal self-ignition of different fuels requires certain conditions according to the fuel properties. It is clear that the main factor is the surrounding temperature, but in fact, the chosen mechanism of heat transfer has a definitive influence on the ignition delay time. We have shown that ignition of the fuel composition containing 35−40 wt % water has very different dependencies of ignition delay versus temperature when radiative and convective heating are used. The estimation of a generalized activation energy of the ignition process at radiative heating shows that it is 3 times higher than that at convective heating. Together with this, the changes of the fuel composition up to 5 wt % do not change the activation energy more than 30%. The water evaporation decreases the efficiency of convective heat transfer and makes the growth of the furnace temperature almost useless for fuel ignition.

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A Comparative Study of Ignition Delay of Cracked Kerosene/Air and Kerosene/Air over a Wide Temperature Range

Cited by 7 publications

References 22 publications

Analysis of Combustion Characteristics When Adding Hydrogen and Short-Chain Hydrocarbons to RP-3 Aviation Kerosene Based on the Variation Disturbance Method

Analysis of Combustion Characteristics When Adding Hydrogen and Short-Chain Hydrocarbons to RP-3 Aviation Kerosene Based on the Variation Disturbance Method

Experimental study of ignition behaviors of pyrolysis gas of kerosene‐based endothermic hydrocarbon fuel

Efficiency of Different Heat Exchange Mechanisms for Ignition of Coal–Water Compositions

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