Your search keyword '"Yu, Tian"' showing total 2 results

1. Combustion study of a surrogate jet fuel

Author

Yue-Xi Liu, Sandra Richter, Marina Braun-Unkhoff, Clemens Naumann, and Zhen-Yu Tian

Subjects

Work (thermodynamics), Materials science, 020209 energy, General Chemical Engineering, General Physics and Astronomy, Energy Engineering and Power Technology, Thermodynamics, alternative fuel, 02 engineering and technology, Jet fuel, Combustion, law.invention, 020401 chemical engineering, law, Range (aeronautics), 0202 electrical engineering, electronic engineering, information engineering, Chemische Kinetik, 0204 chemical engineering, Shock tube, aviation combustor, Surrogate, Laminar flow, General Chemistry, Ignition system, Fuel Technology, Combustor, combustion kinetics

Abstract

The oxidation of a three-component surrogate jet fuel (consisting of n-dodecane 66.2%, n-propylbenzene 15.8% and 1,3,5-trimethylcyclohexane 18.0%, in mol) was studied experimentally and numerically within a wide range of temperature, fuel equivalence ratio, and pressure. Three different experimental set-ups were exploited, here a jet stirred reactor (JSR), a shock tube, and a laminar burner referring to measured data of species profiles (φ = 2.0, T = 575–1100 K, p = 1 bar), ignition delay times (φ = 1.0, p = 16 atm, T = 700–1500 K), and burning velocities (T = 473 K, p = 1atm, φ = 0.6–2.0). Based on the experimental measurements, an updated detailed chemical-kinetic mechanism involving 401 species and 2838 reactions was developed, for a more detailed understanding of the oxidation and combustion of the surrogate fuel. In addition, quantum chemical methods have been applied for the determination of important initiation reactions by using the Gaussian and ChemRate software. In general, the predictions obtained with the mechanism developed in this work show a reasonable, often good agreement with respect to the measured mol fraction profiles (JSR), ignition delay time data (shock tube), and burning velocities data (flame). A negative temperature coefficient (NTC) behavior was observed in the JSR and shock tube experiments, due to the long-chain alkanes, here n-dodecane. The NTC effect was successfully predicted by the reaction model, with the predictions matching the measurements well. From the JSR experiments, 1-octene, 2-propenylbenzene, and propene were detected by GC and GC–MS as major intermediates within the oxidation of the surrogate. According to rate-of-production analysis performed at 675 K and 900 K, 1,3,5-trimethylcyclohexane (T135MCH) was found to be mainly consumed through H-abstraction reactions and forming C9H17 radicals, which mostly isomerize to iso-alkane radicals and further on, decompose to light hydrocarbons. According to the comparison of predicted data on ignition (shock tube) and burning velocity (flame) with experimental ones, the selected surrogate fuel is considered to be able to reproduce the combustion behavior of a typical crude-oil stemming jet fuel. The surrogate fuel mechanism as well as the experimental data will be of significant impact on the use in the further work of the combustion of a jet fuel and of other synthetic aviation fuels as well.

Published

2019

2. A wide-range experimental and modeling study of oxidation and combustion of n-propylbenzene

Author

Sandra Richter, Marina Braun-Unkhoff, Clemens Naumann, Bing-Yin Wang, Thomas Kick, Jun-Jie Weng, Zhen-Yu Tian, Yue-Xi Liu, and Dan Yu

Subjects

Materials science, 020209 energy, General Chemical Engineering, Analytical chemistry, General Physics and Astronomy, Energy Engineering and Power Technology, 02 engineering and technology, Mole fraction, Combustion, Diesel fuel, chemistry.chemical_compound, Reaction rate constant, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Chemische Kinetik, 0204 chemical engineering, Indene, Shock tube, Naphthalene, experiment, n-propylbenzene, modeling, General Chemistry, Flame speed, Fuel Technology, chemistry, combustion kinetics

Abstract

The oxidation of n-propylbenzene (NPB) was studied in a jet-stirred reactor (JSR) equipped with online GC and GC–MS for temperatures ranging between 700 and 1100 K, at φ = 0.4–2.0. In addition, laminar flame speeds were measured at p = 1, 3 and 6 bar at a preheat temperature of T = 473 K, and ignition delay times in a shock tube device behind reflected shock waves, for stoichiometric mixtures at around p = 16 bar. Mole fraction profiles of 25 intermediates including six species, namely 1-propenylbenzene, 2-propenylbenzene, α-methylstyrene, naphthalene, indene, and benzofuran were observed additionally. With φ increasing, NPB consumption shifts to higher temperatures, and the reaction temperature zone becomes broader. Based on the experimental measurements and on new calculations of the rate constants for the H-abstractions from NPB with OH, an updated kinetic model involving 292 species and 1919 reactions was developed with a reasonable agreement with the measured species profiles, flame speed values, and ignition delay times. Rate of production analysis reveals that NPB consumption is generally governed by C H bond cleavage to form three A1C3H6 radicals, which mostly transform to styrene under rich condition and to benzaldehyde under lean condition. Compared to the aromatics formed in the oxidation of two other aromatic C9 fuels, 1,3,5-trimethylbenzene and 1,2,4-trimethylbenzene, NPB exhibits to be the most reactive fuel with the least aldehyde intermediates. Moreover, the present model gives a reasonable agreement with the literature-reported ignition delay times and JSR data. These results can improve the understanding of the oxidation and combustion of NPB as a surrogate fuel constituent for kerosene and diesel.

Published

2018