The application prospects of liquid-fueled rotating detonation engine (RDE) in the aerospace field are extensive. However, numerical simulations of liquid-fueled RDE, particularly for the non-premixed fuel and oxidant injection, are significantly lacking compared to pure gas-phase modeling efforts. Therefore, an Eulerian-Lagrangian model is established in the present study to elucidate the propagation characteristics of rotating detonation wave (RDW) supplied with liquid octane and oxygen-rich air. The fuel droplets, considered as the discrete phase, are described by the Lagrangian governing system to capture the movement and atomization process of droplets. The continuous gas-phase is described by the Euler equations. The detonation combustion flow field and the unsteady motion process of fuel particles in the combustor are depicted in detail. The effect of equivalence ratio on the detonation propagation characteristics is also analyzed. The numerical results show the fluctuations in the transient filling height of the oxidant and the detonation velocity, attributed to the detonation instability. Along the intersection of the rotating detonation front and the oblique shock wave, the oxidant trailing strip is found to penetrate the detonation product zone. As a result, part of the fuel does not participate in the reaction in the combustor. When the equivalence ratio increases above 1.3, the propagation of RDW transits from single-wave mode to dual-wave mode. This study demonstrates the complexity of propagation mechanism of RDW involving liquid fuel droplets.
PalPXuCKumarG, et al.Large-eddy simulation and chemical explosive mode analysis of non-ideal combustion in a non-premixed rotating detonation engine. In: AIAA SciTech 2020 forum, Orlando, Florida, USA, 6–10 January 2020.
8.
LiQLiuPZhangH. Further investigations on the interface instability between fresh injections and burnt products in 2-D rotating detonation. Comput Fluids2018; 170: 261–272.
9.
JinSQiLZhaoN, et al.Experimental and numerical research on rotating detonation combustor under non-premixed conditions. Int J Hydrogen Energy2020; 45: 10176–10188.
10.
AnandVGeorgeASDriscollR, et al.Characterization of instabilities in a rotating detonation combustor. Int J Hydrogen Energy2015; 40: 16649–16659.
11.
HeWXieQJiZ, et al.Characterizing continuously rotating detonation via nonlinear time series analysis. Proc Combust Inst2019; 37: 3433–3442.
12.
WuDZhouRLiuM, et al.Numerical investigation of the stability of rotating detonation engines. Combust Sci Technol2014; 186: 1699–1715.
13.
GeorgeASDriscollRAnandV, et al.On the existence and multiplicity of rotating detonations. Proc Combust Inst2017; 36: 2691–2698.
14.
MaZZhangSLuanM, et al.Experimental research on ignition, quenching, reinitiation and the stabilization process in rotating detonation engine. Int J Hydrogen Energy2018; 43: 18521–18529.
15.
BluemnerRBohonMDPaschereitCO, et al.Effect of inlet and outlet boundary conditions on rotating detonation combustion. Combust Flame2020; 216: 300–315.
KindrackiJ. Experimental research on rotating detonation in liquid fuel-gaseous air mixtures. Aero Sci Technol2015; 43: 445–453.
18.
LimDHumbleJHeisterSD. Experimental testing of an RP-2-GOX rotating detonation rocket engine. In: AIAA SciTech 2020 forum, Orlando, Florida, USA, 6–10 January 2020.
19.
ZhengQMengHWengC, et al.Experimental research on the instability propagation characteristics of liquid kerosene rotating detonation wave. Def Technol2020; 16: 1106–1115.
20.
ZhongYWuYJinD, et al.Investigation of rotating detonation fueled by the pre-combustion cracked kerosene. Aero Sci Technol2019; 95: 105480.
21.
FrolovSMShamshinIOAksenovVS, et al.Rocket engine with continuously rotating liquid film detonation. Combust Sci Technol2020; 192: 144–165.
22.
SubramanianSMeadowsJ. Novel approach for computational modeling of a non-premixed rotating detonation engine. J Propul Power2020; 36: 617–631.
23.
SunJZhouJLiuS, et al.Numerical investigation of a rotating detonation engine under premixed/non-premixed conditions. Acta Astronaut2018; 152: 630–638.
24.
JourdaineNTsuboiNOzawaK, et al.Three-dimensional numerical thrust performance analysis of hydrogen fuel mixture rotating detonation engine with aerospike nozzle. Proc Combust Inst2019; 37: 3443–3451.
25.
LiuYZhouWYangY, et al.Numerical study on the instabilities in H2-air rotating detonation engines. Phys Fluids2018; 30: 046106.
26.
TengHZhouLYangP, et al.Numerical investigation of wavelet features in rotating detonations with a two-step induction-reaction model. Int J Hydrogen Energy2020; 45: 4991–5001.
27.
ZhaoMZhangH. Origin and chaotic propagation of multiple rotating detonation waves in hydrogen/air mixtures. Fuel2020; 275: 117986.
28.
WeissSBohonMDPaschereitCO, et al.Computational study of reactants mixing in a rotating detonation combustor using compressible RANS. Flow Turbul Combust2020; 105: 267–295.
29.
GaillardTDavidenkoDDupoirieuxF. Numerical optimisation in non reacting conditions of the injector geometry for a continuous detonation wave rocket engine. Acta Astronaut2015; 111: 334–344.
30.
MengQZhaoNZhengH, et al.Numerical investigation of the effect of inlet mass flow rates on H2/air non-premixed rotating detonation wave. Int J Hydrogen Energy2018; 43: 13618–13631.
31.
ZhaoMClearyMJZhangH. Combustion mode and wave multiplicity in rotating detonative combustion with separate reactant injection. Combust Flame2021; 225: 291–304.
WangFWengCWuY, et al.Numerical research on kerosene-air rotating detonation engines under different injection total temperatures. Aero Sci Technol2020; 103: 105899.
34.
WangFWengCWuY, et al.Effects of total pressures and equivalence ratios on kerosene/air rotating detonation engines using a paralleling CE/SE method. Def Technol2021; 17(6): 1805–1816.
35.
HayashiAKTsuboiNDzieminskaE. Numerical study on JP-10/air detonation and rotating detonation engine. AIAA J2020; 58: 5078–5094.
36.
ZuzioDEstivalèzesJDiPierroB. An improved multiscale Eulerian-Lagrangian method for simulation of atomization process. Comput Fluids2018; 176: 285–301.
37.
WenJHuYNakanishiA, et al.Atomization and evaporation process of liquid fuel jets in crossflows: a numerical study using Eulerian/Lagrangian method. Int J Multiphas Flow2020; 129: 103331.
38.
AnezJAhmedAHechtN, et al.Eulerian-Lagrangian spray atomization model coupled with interface capturing method for diesel injectors. Int J Multiphas Flow2019; 113: 325–342.
39.
LainSSommerfeldM. Influence of droplet collision modelling in Euler/Lagrange calculations of spray evolution. Int J Multiphas Flow2020; 132: 103392.
40.
ZhangZWenCLiuY, et al.Application of CE/SE method to gas-particle two-phase detonations under an Eulerian-Lagrangian framework. J Comput Phys2019; 394: 18–40.
41.
IsmailNIKuangSYuA. CFD-DEM study of particle-fluid flow and retention performance of sand screen. Powder Technol2021; 378: 410–420.
42.
YokooKKishidaMYamamotoT. Numerical investigation of PM filtration in fluidized-bed-type PM removal device based on force balance via CFD-DEM simulation. Powder Technol2021; 380: 506–517.
43.
RenZZhengL. Numerical study on rotating detonation stability in two-phase kerosene-air mixture. Combust Flame2021; 231: 111484.
44.
MengQZhaoMZhengH, et al.Eulerian-Lagrangian modelling of rotating detonative combustion in partially pre-vaporized n-heptane sprays with hydrogen addition. Fuel2021; 290: 119808.
45.
HabchiCVerhoevenDHuuCH, et al.Modeling atomization and break up in high-pressure diesel sprays. IN: International congress and exposition, 1997.
46.
Brito LopesAV. Advanced modelling of turbulent spray flames in aero gas-turbines with liquid bio-fuels. PhD Thesis, Coventry University, Coventry, 2021.
47.
Brito LopesAVEmekwuruNJoshiK. Are the available data from laboratory spray burners suitable for CFD modelling validations? A review. Energy Convers Manag X2022; 16: 100289.
48.
WestbrookCKDryerFL. Simplified reaction mechanisms for the oxidation of hydrocarbon fuels in flames. Combust Sci Technol1981; 27: 31–43.
49.
NiXWengCXuH, et al.Numerical analysis of heat flow in wall of detonation tube during pulse detonation cycle. Appl Therm Eng2021; 187: 116528.
50.
WangGZhangDLiuK, et al.An improved CE/SE scheme for numerical simulation of gaseous and two-phase detonations. Comput Fluids2010; 39: 168–177.
51.
ShenHJahdaliRAParsaniM. A class of high-order weighted compact central schemes for solving hyperbolic conservation laws. J Comput Phys2022; 466: 111370.
52.
ZhangZYuSTJChangS. A space-time conservation element and solution element method for solving the two- and three-dimensional unsteady Euler equations using quadrilateral and hexahedral meshes. J Comput Phys2002; 175: 168–199.
53.
Brito LopesAVEmekwuruN. Impact of the number of computational parcels on the prediction of highly swirling spray-flame mode and structure. In: Proceedings of the 10th European combustion meeting–Virtual edition, 14–15 April 2021.
54.
Brito LopesAVEmekwuruNBonelloB, et al.On the highly swirling flow through a confined bluff-body. Phys Fluids2020; 32(5): 055105.
