Numerical Study of Heat Transfer in Film Cooled Thrust Chambers

Betti, B.; Martelli, Emanuele; Nasuti, Francesco; Onofri, Marcello

doi:10.2514/6.2012-3907

Cited by 19 publications

(14 citation statements)

References 19 publications

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“…To realize the validation of combustion pressure distributions in the combustion chamber, one cannot use the combustion gas instead Figure 6 Averaged heat §ux in circumferential direction: (a) 0.46-millimeter slot; (b) 1.00-millimeter slot dimension; and (c) no ¦lm cooling. Signs refer to experiments and curves to CFD of the actual coaxial injector con¦guration, which was proposed in the previous works [5,6]. Figure 6 shows the circumferentially averaged heat §uxes for the experiment and simulation.…”

Section: Validationmentioning

confidence: 99%

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Numerical and experimental investigation of the methane film cooling in subscale combustion chamber

Daimon

Negishi

Koshi

et al. 2016

Progress in Propulsion Physics

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The characteristics of ¦lm cooling in a CH 4 /O 2 subscale chamber with multiinjector elements and two kinds of ¦lm cooling slot dimensions are investigated using a calorimeter chamber in experiments and simulations, in which the ¦nite rate chemistry with a reduced CH 4 /O 2 reaction mechanism is taken into account. The computed wall heat §ux and pressure distributions are compared to the experimental results, which overall show good agreement. A large slot dimension is shown to induce mixing with core §ow. This mixing causes a low heat- §ux distribution near face plate along with high combustion e©ciency.

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Section: Validationmentioning

confidence: 99%

“…In the previous numerical works [5,6], the coaxial injector of CH 4 and O 2 was simpli¦ed to simulate the heat §ux to the thrust chamber wall of the CH 4 /O 2 subscale combustor. The near injector plate phenomena were neglected, and equilibrium combustion products were injected into the chamber at the adiabatic §ame temperature.…”

Section: Introductionmentioning

confidence: 99%

Numerical and experimental investigation of the methane film cooling in subscale combustion chamber

Daimon

Negishi

Koshi

et al. 2016

Progress in Propulsion Physics

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“…Wall heat flux evaluation has been validated by reproducing a benchmark test case involving a supersonic nozzle operated with air. 16 B. Coolant and wall: quasi-2D solver A simplified quasi-2D approach 7 is used to study the coupled problem of coolant flow and wall structure heat transfer in rectangular cooling channels of liquid rocket engine thrust chambers. The cooling channel flow model is developed by using the steady-state conservation laws of mass, momentum, and energy, taking into account the effects of heat transfer and friction.…”

Section: A Hot Gas: Cfd Solvermentioning

confidence: 99%

“…In particular, combustion is not simulated, but a flow of combustion products in chemical equilibrium at the chamber temperature and pressure is injected using a "full-inlet" approach. 16 The numerical solutions are carried out by means of an in-house 3D multi-block finite volume RANS equations solver able to treat multi-component mixtures of thermally perfect gases. Multicomponent diffusion has been validated 17 reproducing experimental test cases retrieved in open literature.…”

Section: A Hot Gas: Cfd Solvermentioning

confidence: 99%

Coupled Heat Transfer Analysis in Regeneratively Cooled Thrust Chambers

Betti¹,

Pizzarelli²,

Nasuti³

2012

48th AIAA/ASME/SAE/ASEE Joint Propulsion Conference &Amp;amp; Exhibit

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A computational procedure able to describe the coupled hot-gas/wall/coolant environment that occurs in most liquid rocket engines and to provide a quick and reliable prediction of thrust-chamber wall temperature and heat flux as well as coolant-flow characteristics, like pressure drop and temperature gain in the regenerative circuit is presented and demonstrated. The coupled analysis is performed by means of an accurate CFD solver of the Reynolds-Averaged Navier-Stokes equations for the hot-gas flow and a simplified quasi-2D approach, which widely relies on semi-empirical relations, to study the problem of coolant flow and wall structure heat transfer in the cooling channels. Coupled computations of the Space Shuttle Main Engine Main Combustion Chamber are performed and compared with available literature data. Results show a reasonable agreement in terms of coolant pressure drop and temperature gain with nominal data, whereas the computed wall temperature peak is quite closer to hot-firing data than to the nominal value. © 2012 by B. Betti, M. Pizzarelli, F. Nasuti

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“…Turbulence is described by means of the Spalart-Allmaras one-equation model [28], a constant turbulent Schmidt number is adopted to model turbulent diffusivity, and a constant turbulent Prandtl number is adopted to model turbulent conductivity. The present solver has been validated in different operative conditions against experimental data [29][30][31]. Frozen flow assumption is adopted without aiming to describe the details of injection and combustion of propellants in the thrust chamber.…”

mentioning

confidence: 99%

Development of Thrust Chamber Components for a System Analysis Tool

Leonardi¹,

Onofri²,

Nasuti³

et al. 2014

50th AIAA/ASME/SAE/ASEE Joint Propulsion Conference

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In this paper a new thrust chamber component for the object oriented tool EcosimPro is presented. The numerical approach consists of a finite volume formulation of the unsteady quasi one-dimensional Euler equations for multispecies flow coupled with finite-rate chemistry. The inviscid convective fluxes are treated with two schemes, specifically formulated for multispecies flows: the approximate Riemann solver of Roe and the AUSM+ -up. Both the schemes are implemented with a spatial accuracy up to the third order by means of the Monotonic Upstream Centered Scheme for Conservation Laws (MUSCL). The reaction mechanism presented consists of six species and eight reactions for the combustion of hydrogen and oxygen while time integration is left to the DASSL implicit solver embedded in EcosimPro. After the description of the numerical model, some validation test cases for the schemes and the finite-rate chemistry mechanism are presented. The component is then tested on the Space Shuttle Main Engine (SSME) Main Combustion Chamber (MCC) and the results are compared against those obtained with an already validated software. The tests show that the component is able to reach the expected steady-state solution in terms of both evolution of the thermodynamic properties and mixture composition and that the implicit solver is able to deal with the stiffness introduced by the source terms representing the finite-rate chemistry. The SSME MCC and its regenerative cooling channel are then modelled in EcosimPro. Limitations related with the use of classical semi-empirical correlations for the hot gas side heat transfer coefficient are highlighted and overcome through a coupling procedure, in which the solution coming from a CFD analysis of the MCC is coupled with those obtained with EcosimPro for the cooling channels. The results of this iterative procedure are compared with those available in open literature, showing that wall heat flux and wall temperature profile are in line with those obtained by other methods. Furthermore, an accurate calculation of the wall heat flux allows the cooling channel component presently available in EcosimPro to obtain results that are comparable with those proposed by higher fidelity models

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Numerical Study of Heat Transfer in Film Cooled Thrust Chambers

Cited by 19 publications

References 19 publications

Numerical and experimental investigation of the methane film cooling in subscale combustion chamber

Numerical and experimental investigation of the methane film cooling in subscale combustion chamber

Coupled Heat Transfer Analysis in Regeneratively Cooled Thrust Chambers

Development of Thrust Chamber Components for a System Analysis Tool

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