Large eddy simulations of flow over additively manufactured surfaces: Impact of roughness and skewness on turbulent heat transfer

Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand–grain roughness. Further research is needed to understand these effects. We conducted high-fidelity heat transfer simulations over three-dimensional additive man...

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Published inPhysics of fluids (1994) Vol. 36; no. 8
Main Authors Garg, Himani, Sahut, Guillaume, Tuneskog, Erika, Nogenmyr, Karl-Johan, Fureby, Christer
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 01.08.2024
Subjects
Additive manufacturing
Bearbetnings-, yt- och fogningsteknik
Diffusivity
Engineering and Technology
Equivalence
Fluid flow
Heat flux
Heat transfer
Impact analysis
Large eddy simulation
Manufacturing, Surface and Joining Technology
Materials Engineering
Materialteknik
Momentum transfer
Prandtl number
Pressure effects
Pressure loss
Reynolds number
Roughness
Sand
Simulation
Skewness
Teknik
Temperature profiles
Thermal diffusivity
Turbulence
Turbulent heat transfer
Velocity distribution
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Abstract Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand–grain roughness. Further research is needed to understand these effects. We conducted high-fidelity heat transfer simulations over three-dimensional additive manufactured surfaces with varying roughness heights and skewness. Based on an additive manufactured Inconel 939 sample from Siemens Energy, we created six surfaces with different normalized roughness heights, Ra/D=0.001,0.006,0.012,0.015,0.020, and 0.028, and a fixed skewness, sk=0.424. Each surface was also flipped to obtain negatively skewed counterparts ( sk=−0.424). Simulations were conducted at a constant Reynolds number of 8000 and with temperature treated as a passive scalar (Prandtl number of 0.71). We analyzed temperature, velocity profiles, and heat fluxes to understand the impact of roughness height and skewness on heat and momentum transfer. The inner-scaled mean temperature profiles are of larger magnitude than the mean velocity profiles both inside and outside the roughness layer. This means, the temperature wall roughness function, ΔΘ+, differs from the momentum wall roughness function, ΔU+. Surfaces with positive and negative skewness yielded different estimates of equivalent sand–grain roughness for the same Ra/D values, suggesting a strong influence of slope and skewness on the relationship between roughness function and equivalent sand–grain roughness. Analysis of the heat and momentum transfer mechanisms indicated an increased effective Prandtl number within the rough surface in which the momentum diffusivity is larger than the corresponding thermal diffusivity due to the combined effects of turbulence and dispersion. Results consistently indicated improved heat transfer with increasing roughness height and positively skewed surfaces performing better beyond a certain roughness threshold than negatively skewed ones.
AbstractList Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand–grain roughness. Further research is needed to understand these effects. We conducted high-fidelity heat transfer simulations over threedimensional additive manufactured surfaces with varying roughness heights and skewness. Based on an additive manufactured Inconel 939sample from Siemens Energy, we created six surfaces with different normalized roughness heights, Ra=D ¼ 0:001; 0:006; 0:012; 0:015; 0:020;and 0.028, and a fixed skewness, sk ¼ 0:424. Each surface was also flipped to obtain negatively skewed counterparts (sk ¼ 0:424).Simulations were conducted at a constant Reynolds number of 8000 and with temperature treated as a passive scalar (Prandtl number of0.71). We analyzed temperature, velocity profiles, and heat fluxes to understand the impact of roughness height and skewness on heat andmomentum transfer. The inner-scaled mean temperature profiles are of larger magnitude than the mean velocity profiles both inside and outside the roughness layer. This means, the temperature wall roughness function, DHþ; differs from the momentum wall roughness function,DUþ. Surfaces with positive and negative skewness yielded different estimates of equivalent sand–grain roughness for the same Ra=D values,suggesting a strong influence of slope and skewness on the relationship between roughness function and equivalent sand–grain roughness.Analysis of the heat and momentum transfer mechanisms indicated an increased effective Prandtl number within the rough surface in whichthe momentum diffusivity is larger than the corresponding thermal diffusivity due to the combined effects of turbulence and dispersion.Results consistently indicated improved heat transfer with increasing roughness height and positively skewed surfaces performing betterbeyond a certain roughness threshold than negatively skewed ones.VC 2024 Author(s). All article content, except where otherwise noted, is li
Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand-grain roughness. Further research is needed to understand these effects. We conducted high-fidelity heat transfer simulations over three-dimensional additive manufactured surfaces with varying roughness heights and skewness. Based on an additive manufactured Inconel 939 sample from Siemens Energy, we created six surfaces with different normalized roughness heights, R a / D = 0.001 , 0.006 , 0.012 , 0.015 , 0.020 , and 0.028, and a fixed skewness, s k = 0.424 . Each surface was also flipped to obtain negatively skewed counterparts ( s k = − 0.424 ). Simulations were conducted at a constant Reynolds number of 8000 and with temperature treated as a passive scalar (Prandtl number of 0.71). We analyzed temperature, velocity profiles, and heat fluxes to understand the impact of roughness height and skewness on heat and momentum transfer. The inner-scaled mean temperature profiles are of larger magnitude than the mean velocity profiles both inside and outside the roughness layer. This means, the temperature wall roughness function, Δ Θ + , differs from the momentum wall roughness function, Δ U + . Surfaces with positive and negative skewness yielded different estimates of equivalent sand-grain roughness for the same R a / D values, suggesting a strong influence of slope and skewness on the relationship between roughness function and equivalent sand-grain roughness. Analysis of the heat and momentum transfer mechanisms indicated an increased effective Prandtl number within the rough surface in which the momentum diffusivity is larger than the corresponding thermal diffusivity due to the combined effects of turbulence and dispersion. Results consistently indicated improved heat transfer with increasing roughness height and positively skewed surfaces performing better beyond a certain roughness threshold than negatively skewed ones.
Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand–grain roughness. Further research is needed to understand these effects. We conducted high-fidelity heat transfer simulations over three-dimensional additive manufactured surfaces with varying roughness heights and skewness. Based on an additive manufactured Inconel 939 sample from Siemens Energy, we created six surfaces with different normalized roughness heights, Ra/D=0.001,0.006,0.012,0.015,0.020, and 0.028, and a fixed skewness, sk=0.424. Each surface was also flipped to obtain negatively skewed counterparts (sk=−0.424). Simulations were conducted at a constant Reynolds number of 8000 and with temperature treated as a passive scalar (Prandtl number of 0.71). We analyzed temperature, velocity profiles, and heat fluxes to understand the impact of roughness height and skewness on heat and momentum transfer. The inner-scaled mean temperature profiles are of larger magnitude than the mean velocity profiles both inside and outside the roughness layer. This means, the temperature wall roughness function, ΔΘ+, differs from the momentum wall roughness function, ΔU+. Surfaces with positive and negative skewness yielded different estimates of equivalent sand–grain roughness for the same Ra/D values, suggesting a strong influence of slope and skewness on the relationship between roughness function and equivalent sand–grain roughness. Analysis of the heat and momentum transfer mechanisms indicated an increased effective Prandtl number within the rough surface in which the momentum diffusivity is larger than the corresponding thermal diffusivity due to the combined effects of turbulence and dispersion. Results consistently indicated improved heat transfer with increasing roughness height and positively skewed surfaces performing better beyond a certain roughness threshold than negatively skewed ones.
Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand–grain roughness. Further research is needed to understand these effects. We conducted high-fidelity heat transfer simulations over three-dimensional additive manufactured surfaces with varying roughness heights and skewness. Based on an additive manufactured Inconel 939 sample from Siemens Energy, we created six surfaces with different normalized roughness heights, Ra/D=0.001,0.006,0.012,0.015,0.020, and 0.028, and a fixed skewness, sk=0.424. Each surface was also flipped to obtain negatively skewed counterparts ( sk=−0.424). Simulations were conducted at a constant Reynolds number of 8000 and with temperature treated as a passive scalar (Prandtl number of 0.71). We analyzed temperature, velocity profiles, and heat fluxes to understand the impact of roughness height and skewness on heat and momentum transfer. The inner-scaled mean temperature profiles are of larger magnitude than the mean velocity profiles both inside and outside the roughness layer. This means, the temperature wall roughness function, ΔΘ+, differs from the momentum wall roughness function, ΔU+. Surfaces with positive and negative skewness yielded different estimates of equivalent sand–grain roughness for the same Ra/D values, suggesting a strong influence of slope and skewness on the relationship between roughness function and equivalent sand–grain roughness. Analysis of the heat and momentum transfer mechanisms indicated an increased effective Prandtl number within the rough surface in which the momentum diffusivity is larger than the corresponding thermal diffusivity due to the combined effects of turbulence and dispersion. Results consistently indicated improved heat transfer with increasing roughness height and positively skewed surfaces performing better beyond a certain roughness threshold than negatively skewed ones.
Author Sahut, Guillaume
Nogenmyr, Karl-Johan
Fureby, Christer
Tuneskog, Erika
Garg, Himani
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https://research.chalmers.se/publication/542464$$DView record from Swedish Publication Index
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Snippet Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand–grain roughness....
Additive manufacturing creates surfaces with random roughness, impacting heat transfer and pressure loss differently than traditional sand-grain roughness....
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SubjectTerms Additive manufacturing
Bearbetnings-, yt- och fogningsteknik
Diffusivity
Engineering and Technology
Equivalence
Fluid flow
Heat flux
Heat transfer
Impact analysis
Large eddy simulation
Manufacturing, Surface and Joining Technology
Materials Engineering
Materialteknik
Momentum transfer
Prandtl number
Pressure effects
Pressure loss
Reynolds number
Roughness
Sand
Simulation
Skewness
Teknik
Temperature profiles
Thermal diffusivity
Turbulence
Turbulent heat transfer
Velocity distribution
Title Large eddy simulations of flow over additively manufactured surfaces: Impact of roughness and skewness on turbulent heat transfer
URI http://dx.doi.org/10.1063/5.0221006
https://www.proquest.com/docview/3092452186/abstract/
https://lup.lub.lu.se/record/dc37bf7f-cb64-4b99-8ec4-3b311d7f0dd4
https://research.chalmers.se/publication/542464
Volume 36
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