Radiation Modeling of a Hydrogen Fueled Scramjet

Crow, Andrew J.; Boyd, Iain D.; Terrapon, Vincent

doi:10.2514/1.t3751

Cited by 14 publications

(11 citation statements)

References 24 publications

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“…The computational results for the simulation of a Mach 6.5 flight of the HIFiRE 2 scramjet with an equivalence ratio of 1.0 for a 0.36-0.64 methane-ethylene fuel are given in the paper by Crow et al [25]. However, only the exit plane quantities are of interest in the current work and are given in Fig.…”

Section: Resultsmentioning

confidence: 96%

“…(6), where a is the quadrature weight, l is the quadrature index, and k is the spectral band index. The extreme simplification of this approach is to take a quadrature point at the statistical average of the absorption band and set the quadrature weight equal to 1 for the single point in the band [1]:…”

Section: Spectral Modelmentioning

confidence: 99%

“…The role of thermal radiation in the energy balance inside a combustor has been little studied and is poorly understood. Previous work studied the hydrogen-fueled HyShot II combustion chamber and found the thermal radiation to be insignificant [1]. The current work considers combustion chambers similar to the Hypersonic International Flight Research Experiment 2 (HIFiRE 2) supersonic combustor [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

“…= area, m 2 a = spectral quadrature weight B ν = blackbody intensity, W∕m 2 · Hz · sr c 1 = tuning parameter E = estimated error F = spectrally integrated heat flux, W∕m 2 F ν = spectrally specific heat flux, W∕m 2 · Hz f ν = scattering redistribution function I ν = radiative intensity, W∕m 2 · Hz · sr i = location index j = ordinate index k = frequency index l = spectral quadrature index N = maximum index number n = species index S ν = spectral line strength, 1∕m s = trace location, m T = temperature, K U = spectral uncertainty w = standoff position, m X = mole fraction x = streamwise position, m y = vertical position, m z = spanwise position, m θ = azimuthal angle, rad θ 0 = secondary azimuthal angle, rad κ = extinction coefficient, 1∕m μ = ordinate angle factor relative to path, cosϕ μ 0 = secondary ordinate angle factor relative to path, cosϕ 0 ν = frequency, Hz ξ n = normalized number density σ = standard deviation of extinction coefficient, 1∕m ϕ = vertical angle, rad ϕ 0 = secondary vertical angle, rad Ω = optical scattering angle, rad Subscripts band = number of frequency bands filt = quantity at filter LBL = line-by-line variable max = domain upper limit min = domain lower limit quad = correlated-k quadrature scheme sens = quantity at sensor spec = number of species ν = frequency-specific value 0 = nominal state…”

mentioning

confidence: 99%

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Thermal Radiative Simulations and Measurements of a Scramjet Test Rig

Crow

Boyd

Brown

et al. 2014

Journal of Propulsion and Power

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Thermal radiation is a poorly understood process in scramjet engines, but it may play a significant role in the flow and wall heating of the combustion chamber. However, current simulation methods for predicting the thermal radiation in a flight scramjet combustion chamber have yet to be validated with experiments. An experimental measurement apparatus is placed at the rear exit of the HIFiRE 2 direct-connect rig at NASA's Langley Research Center. An array of photodetectors gather emission in the infrared along several lines of sight across the combustor exit. The fields of view are simulated using a ray-tracing-method program that postprocesses a computational fluid dynamics flowfield simulation of the test rig. The ray-tracing program employs a simplified two-point correlated-k spectral model with spectral model error bars. The predictions show an overlap in sensor and experimental predictions for 13 of 16 photodetectors. Nomenclature A = area, m 2 a = spectral quadrature weight B ν = blackbody intensity, W∕m 2 · Hz · sr c 1 = tuning parameter E = estimated error F = spectrally integrated heat flux, W∕m 2 F ν = spectrally specific heat flux, W∕m 2 · Hz f ν = scattering redistribution function I ν = radiative intensity, W∕m 2 · Hz · sr i = location index j = ordinate index k = frequency index l = spectral quadrature index N = maximum index number n = species index S ν = spectral line strength, 1∕m s = trace location, m T = temperature, K U = spectral uncertainty w = standoff position, m X = mole fraction x = streamwise position, m y = vertical position, m z = spanwise position, m θ = azimuthal angle, rad θ 0 = secondary azimuthal angle, rad κ = extinction coefficient, 1∕m μ = ordinate angle factor relative to path, cosϕ μ 0 = secondary ordinate angle factor relative to path, cosϕ 0 ν = frequency, Hz ξ n = normalized number density σ = standard deviation of extinction coefficient, 1∕m ϕ = vertical angle, rad ϕ 0 = secondary vertical angle, rad Ω = optical scattering angle, rad Subscripts band = number of frequency bands filt = quantity at filter LBL = line-by-line variable max = domain upper limit min = domain lower limit quad = correlated-k quadrature scheme sens = quantity at sensor spec = number of species ν = frequency-specific value 0 = nominal state

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Section: Resultsmentioning

confidence: 96%

Section: Spectral Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Thermal Radiative Simulations and Measurements of a Scramjet Test Rig

Crow

Boyd

Brown

et al. 2014

Journal of Propulsion and Power

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“…Previous work studied the hydrogen-fueled HyShot II combustion chamber and found the thermal radiation to be insignificant. 1 The current work considers combustion chambers similar to the HIFiRE-2 supersonic combustor. 2,3 It is anticipated that the radiative component of wall heat flux may be higher in the HIFiRE-2 combustor due to two effects: (1) its use of hydrocarbon fuel that generates significant quantities of radiating species such as carbon dioxide that are absent from HyShot II; and (2) the HIFiRE-2 combustor is significantly larger in volume than that for HyShot II.…”

Section: Introductionmentioning

confidence: 99%

Thermal Radiative Analysis of the HIFiRE-2 Scramjet Engine

Crow

Boyd

Brown

et al. 2012

43rd AIAA Thermophysics Conference

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Thermal radiation is a poorly understood process in scramjet engines but may play a significant role in the flow and wall heating of the combustion chamber. Previous work has looked at the HyShot II combustion chamber and found the thermal radiation to be insignificant. The current work considers a combustion chamber similar to the HIFiRE-2 supersonic combustion chamber. The combustion flow is computed using a turbulent RANS fluid code, finding the convective heat flux to be on the order of 1.0 to 3.0 MW/m 2 . The flow-field results are post-processed with a Discrete Ordinates Method radiative heat transfer code using a spectrally resolved narrow-band approximation resulting in a radiative heat flux to the wall of 15 to 56 kW/m 2 . A method of estimating the epistemic uncertainty of the radiative wall heat flux stemming from the uncertainty in the spectral model found the radiative wall heat flux to vary by 11 to 15 %. The cooling of the flow due to radiation is predicted using an uncoupled method. Depending on the individual flow-path, the predicted temperature reduction due to radiation can range from 2 to 245 K. Thermal radiative measurements are obtained in an experimental setup of the HIFiRE-2 engine on the HIFiRE Direct-Connect Rig (HDCR) in theArc-Heated Scramjet Test Facility (AHSTF) at NASA Langley Research Center. An array of photodetectors gathered emission in the infrared along several lines-of-sight across the combustor exit. Predictions of radiation along these same lines are compared to the measurements indicating strengths and weaknesses of the simulation approach.

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