20th AIAA International Space Planes and Hypersonic Systems and Technologies Conference 2015
DOI: 10.2514/6.2015-3621
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Numerical Studies for Heat Transfer of Hydrocarbon Fuel with Thermal Cracking

Abstract: Coolant flow and thermal cracking process play key roles in regenerative cooling of a hydrocarbon-fueled scramjet. In order to study the heat transfer and thermal cracking process of regenerative cooling structure, a three dimensional numerical method is established. The Modified Kumar-Kunzru chemical kinetics model consisting of primary reaction and secondary reactions is used to simulate the thermal cracking process. The SIMPLE algorithm is applied to solve the low speed flow field. The data of electrically … Show more

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Cited by 2 publications
(3 citation statements)
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“…Xing et al (2009) and Zhong et al (2009b) studied the kinetic parameters of global reaction of RP-3 at p =2.0–3.9 MPa, T = 663–703 K and p = 3.5–4.5 MPa, T = 700–1100 K. Jiang et al (2013) presented a molecular reaction model with 28 species and 24 reactions, and the computational accuracy was acceptable when the cracking conversion was less than 86%. Furthermore, this chemical cracking mechanism was adopted by Zhao et al (2015), Zhang et al (2015), Xu and Meng (2015a) and Jing et al (2018) to study the impact of pressure on the fuel cracking, thermo-hydrodynamic characteristics and curved regenerative cooling channels, respectively. Hou et al (2013) established a global reaction of one-step thermal cracking based on the proportional product distributions and gaseous-product experiments.…”
Section: Introductionmentioning
confidence: 99%
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“…Xing et al (2009) and Zhong et al (2009b) studied the kinetic parameters of global reaction of RP-3 at p =2.0–3.9 MPa, T = 663–703 K and p = 3.5–4.5 MPa, T = 700–1100 K. Jiang et al (2013) presented a molecular reaction model with 28 species and 24 reactions, and the computational accuracy was acceptable when the cracking conversion was less than 86%. Furthermore, this chemical cracking mechanism was adopted by Zhao et al (2015), Zhang et al (2015), Xu and Meng (2015a) and Jing et al (2018) to study the impact of pressure on the fuel cracking, thermo-hydrodynamic characteristics and curved regenerative cooling channels, respectively. Hou et al (2013) established a global reaction of one-step thermal cracking based on the proportional product distributions and gaseous-product experiments.…”
Section: Introductionmentioning
confidence: 99%
“…(2015),Zhang et al (2015),Xu and Meng (2015a) andJing et al (2018) to study the impact of pressure on the fuel cracking, thermo-hydrodynamic characteristics and curved regenerative cooling channels, respectively Hou et al (2013). established a global reaction of one-step thermal cracking based on the proportional product distributions and gaseous-product experiments.…”
mentioning
confidence: 99%
“…The model is able to predict thermal cracking behaviors of RP-3 at a high conversion up to 86%. Using this molecular kinetic model, numerical studies have been performed to investigate the effects of thermal cracking on the regenerative cooling process. , However, the effect of pressure on the pyrolysis of RP-3 was not included in these researches because of the lack of the necessary kinetic parameters for other pressures.…”
Section: Introductionmentioning
confidence: 99%