Simulation of Gaseous Oxygen/Hydroxyl-Terminated Polybutadiene Hybrid Rocket Flowfields and Comparison with Experiments

Bianchi, Daniele; Betti, B.; Nasuti, Francesco; Carmicino, Carmine

doi:10.2514/1.b35587

Cited by 52 publications

(21 citation statements)

References 31 publications

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“…13 The ensuing flowfield is completely different from the one of developing turbulent flows through pipes with a resulting regression rate which is both increased and differently distributed along the motor axis. 15 As was inferred in Ref. 14 and numerically proved in Ref.…”

Section: Introductionmentioning

confidence: 70%

“…14 and numerically proved in Ref. 15, two different regimes can be distinguished during the motor operation in case of axial injector: i) when the port diameter is sufficiently small with respect to the jet diameter at the fuel port entry, the flowfield is similar to a turbulent developing flow through a pipe and the solution resembles that of the injection through a stagnation chamber that uniformly distributes the oxidizer at the fuel port inlet; ii) when the port diameter is large with respect to the jet diameter, the recirculation zone penetrates farther downstream into the fuel port significantly broadening the combustion region, increasing the mixing and the fuel regression rate.…”

Section: Introductionmentioning

confidence: 95%

“…Moreover, ballistic calculations based on classical boundary-layer theory can fail to reproduce the motor behavior due to a lack of modeling of the oxidizer injection effects. 14,15 More specifically, experimental results highlighted the importance of the oxidizer entrance conditions, 13 which, as mentioned above, are often assumed to determine second order effects in classical hybrid systems. If the oxidizer is fed into the combustion port by an axial nozzle, the motor behavior is absolutely influenced by the recirculation zone induced by the oxidizer axial injection.…”

Section: Introductionmentioning

confidence: 96%

“…Considering, as a reference, a lab-scale hybrid motor tested at the University of Naples "Federico II" 13, 14, 16 equipped with an axial subsonic nozzle to feed gaseous oxygen into the port of Hydroxyl-Terminated PolyButadiene (HTPB) grains, former studies have shown the dependence of the flowfield on mass flux for different tests. 15 Goal of the present study is to exploit experimental data from Ref. 16 to extend the analysis of injection effects to that of port diameter.…”

Section: Introductionmentioning

confidence: 99%

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Numerical Analysis of Port Diameter Effect on Hybrid Rocket Fuel Regression Rate with Axial Injection

Bianchi¹,

Nasuti

Carmicino

2015

51st AIAA/SAE/ASEE Joint Propulsion Conference

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Numerical simulations of the flowfield in a hybrid rocket motor are carried out with a Reynolds averaged Navier-Stokes solver including detailed gas surface interaction modeling based on surface mass and energy balances. Results are compared with several test data obtained from two dedicated test campaigns conducted with static firings of a laboratoryscaled hybrid rocket in which gaseous oxygen is fed into axisymmetric hydroxyl-terminated polybutadiene cylindrical grains through an axial conical subsonic nozzle. A first numerical rebuilding of all of the firing tests has been performed to validate the model, highlighting its prediction capabilities and modeling limits. Despite the several geometrical simplifications, which allowed relatively modest grid sizes to be used and efficient parametrical analysis to be performed, the presented CFD approach is fairly able to capture the main features of the motor internal ballistics both in terms of average chamber pressure and regression rate trends with oxidizer mass flux and port diameter. Computed flowfields showed the establishment of a significant recirculation region at the motor head end, which promotes propellant mixing, and raises the fuel regression rate. Numerical simulations, supported by the experimental results, demonstrated the main role played by the characteristics of this particular injection configuration in determining the fuel regression rate spatial distribution and trend, and clarified the mechanism for which the port diameter has a direct influence on the fuel regression. Nomenclaturē m = time-averaged mass flow rate, kg/ṡ ω i = species source term in control surface, kg/m 2 · ṡ m = mass blowing rate per unit area, kg/m 2 · ṡ q = heat flux, W/m 2 r = regression rate, m/ṡ w i = species source term in control volume, kg/m 3 · s η = inward (from solid to gas) coordinate normal to surface ρ = density, kg/m 3 D im = effective diffusion coefficient, m 2 /s h = enthalpy, J/kg k = thermal conductivity, W/m · K M = molecular weight of the species, kg/kmole N = number of species p = pressure, N/m 2 T = temperature, K v = velocity component normal to surface, m/s y = mass fraction y + = dimensionless wall distance Subscripts f = fuel i = species s = solid material w = wall Superscripts = average in time and spacê = average in space

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Section: Introductionmentioning

confidence: 70%

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Numerical Analysis of Port Diameter Effect on Hybrid Rocket Fuel Regression Rate with Axial Injection

Bianchi¹,

Nasuti

Carmicino

2015

51st AIAA/SAE/ASEE Joint Propulsion Conference

Self Cite

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“…25 This solver has been validated against experimental data in different operating conditions. 3,[26][27][28][29] If attention is restricted to the wall heat transfer far away from the injector plate, details of the injection geometry are relatively unimportant, and an axisymmetric solution is adequate to evaluate heat transfer models, at a limited computational cost. Accordingly, the numerical simulation can be started somewhere downstream of the injector plate, possibly once recirculation (of rather uncertain predictability) is over.…”

Section: Modelling Approach and Numerical Algorithmmentioning

confidence: 99%

Convective and Radiative Contributions to Wall Heat Transfer in Liquid Rocket Engine Thrust Chambers

Betti

Bianchi²,

Leccese

et al. 2015

51st AIAA/SAE/ASEE Joint Propulsion Conference

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The paper is intended to evaluate the relative weight of convective and radiative wall heat transfer in LRE thrust chambers. In particular, an appropriate computational tool, based on the Discrete Transfer Method, is set up to evaluate the radiative heat flux at the wall. Numerical results are compared against experimental data from the literature, concerning subscale thrust chambers fed with either oxygen/hydrogen or oxygen/methane. Then, the effect of varying the chamber pressure or the wall temperature are investigated via a parametric analysis. Results indicate a contribution of radiation around 15% of the total wall heat flux for oxygen/methane, and around 10% for oxygen/hydrogen. An extension to account for sooting, and its associated thermal radiation, is underway. © 2015, American Institute of Aeronautics and Astronautics Inc, AIAA. All rights reserved

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Numerical Approach for the Estimation of Throat Heat Flux in Liquid Rocket Engines

Concio

Migliorino

Nasuti

2020

Aerotec. Missili Spaz.

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The problem of prediction of heat flux at throat of liquid rocket engines still constitutes a challenge, because of the little experimental information. Such a problem is of obvious importance in general, and becomes even more important when considering reusable engines. Unfortunately, only few indirect experimental data are available for the validation of throat heat flux prediction. On the numerical side, a detailed solution would require a huge resolution and codes able to solve at the same time combustion, boundary layer with possible finite-rate reactions, expansion up to at least sonic speed, and in some cases radiative heat flux. Therefore, it is important to validate, with the few experimental data available in the literature, simplified CFD approaches whose aim is to predict heat flux in the nozzle in affordable times. Results obtained by different numerical models based on a RANS approach show the correctness and quality of the approximations made, indicating the main phenomena to be included in modeling for the correct prediction of throat heat flux.

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Simulation of Gaseous Oxygen/Hydroxyl-Terminated Polybutadiene Hybrid Rocket Flowfields and Comparison with Experiments

Cited by 52 publications

References 31 publications

Numerical Analysis of Port Diameter Effect on Hybrid Rocket Fuel Regression Rate with Axial Injection

Numerical Analysis of Port Diameter Effect on Hybrid Rocket Fuel Regression Rate with Axial Injection

Convective and Radiative Contributions to Wall Heat Transfer in Liquid Rocket Engine Thrust Chambers

Numerical Approach for the Estimation of Throat Heat Flux in Liquid Rocket Engines

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