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C. Hansen, Christopher Johnson (2011)
The Visualization Handbook
H. Versteeg, W. Malalasekera (2007)
An introduction to computational fluid dynamics - the finite volume method
A. Sova, S. Klinkov, V. Kosarev, N. Ryashin, I. Smurov (2013)
Preliminary study on deposition of aluminium and copper powders by cold spray micronozzle using heliumSurface & Coatings Technology, 220
K. Hanjalic, B. Launder (1972)
A Reynolds stress model of turbulence and its application to thin shear flowsJournal of Fluid Mechanics, 52
M. Liou (1998)
Recent progress and applications of AUSM, 515
A. Agarwal, S. Goyal, D. Srivastava (2011)
Time resolved numerical modeling of oil jet cooling of a medium duty diesel engine pistonInternational Communications in Heat and Mass Transfer, 38
Yukui Cai, Zhanqiang Liu, Zhen-yu Shi (2017)
Effects of dimensional size and surface roughness on service performance for a micro Laval nozzleJournal of Micromechanics and Microengineering, 27
Deibi López, Diego Domínguez, J. Gonzalo (2013)
Impact of turbulence modelling on external supersonic flow field simulations in rocket aerodynamicsInternational Journal of Computational Fluid Dynamics, 27
H. Luo, J. Baum, R. Löhner (1998)
A fast, matrix-free implicit method for compressible flows on unstructured gridsTransactions on Computational Science
A. Dorfman (2009)
Conjugate Problems in Convective Heat Transfer
M. Liou (1996)
A Sequel to AUSMJournal of Computational Physics, 129
Advanced MaterialsProcess, 172
Q. Xiao, H. Tsai, D. Papamoschou (2007)
Numerical investigation of supersonic nozzle flow separationAIAA Journal, 45
A. Sova, A. Sova, S. Grigoriev, A. Okunkova, I. Smurov (2013)
Potential of cold gas dynamic spray as additive manufacturing technologyThe International Journal of Advanced Manufacturing Technology, 69
R. Dykhuizen, Mark Smith (1998)
Gas dynamic principles of cold sprayJournal of Thermal Spray Technology, 7
D. Munday, E. Gutmark, Junhui Liu, K. Kailasanath (2011)
Flow structure and acoustics of supersonic jets from conical convergent-divergent nozzlesPhysics of Fluids, 23
Shuo Yin, Xiaofang Wang, Wenya Li (2011)
Computational analysis of the effect of nozzle cross-section shape on gas flow and particle acceleration in cold sprayingSurface & Coatings Technology, 205
Randolph Lillard (2013)
Turbulence Modeling for Shock Wave/Turbulent Boundary Layer Interactions
S. Killi (2017)
Additive Manufacturing: Design, Methods, and Processes
J. Anderson (1982)
Modern Compressible Flow: With Historical Perspective
V. Champagne, D. Helfritch, S. Dinavahi, P. Leyman (2011)
Theoretical and Experimental Particle Velocity in Cold SprayJournal of Thermal Spray Technology, 20
J. Mendonca, M. Sharif (2010)
Effects of Surface Roughness on Turbulent Transonic Flow Over Circular Arc Bumps in a ChannelEngineering Applications of Computational Fluid Mechanics, 4
Han-Ju Lee (2016)
CFD Performance of Turbulence Models for Flow from Supersonic Nozzle Exhausts
R. Medeiros, J. Fusco, K. Ropelato, G. Aliatti (2014)
Simulation of supersonic flow: comparison of LES against URANS and RANS turbulence models
X. Suo, Taikai Liu, W. Li, Q. Suo, M. Planche, H. Liao (2013)
Numerical study on the effect of nozzle dimension on particle distribution in cold sprayingSurface & Coatings Technology, 220
M. Karimi, A. Fartaj, G. Rankin, D. Vanderzwet, W. Birtch, J. Villafuerte (2006)
Numerical simulation of the cold gas dynamic spray processJournal of Thermal Spray Technology, 15
W. Jones, B. Launder (1972)
The prediction of laminarization with a two-equation model of turbulenceInternational Journal of Heat and Mass Transfer, 15
M. Chong, A. Perry, B. Cantwell (1990)
A general classification of three-dimensional flow fieldsPhysics of Fluids, 2
S. Sarra (2018)
The Method of Characteristics with applications to Conservation Laws
Wen-ya Li, H. Liao, G. Douchy, C. Coddet (2007)
Optimal design of a cold spray nozzle by numerical analysis of particle velocity and experimental validation with 316L stainless steel powderMaterials & Design, 28
J. Villafuerte (2014)
Considering Cold Spray for Additive ManufacturingAM&P Technical Articles
F. Menter (1994)
Two-equation eddy-viscosity turbulence models for engineering applicationsAIAA Journal, 32
Miaosheng He, Lizi Qin, Yu Liu (2015)
Numerical investigation of flow separation behavior in an over-expanded annular conical aerospike nozzleChinese Journal of Aeronautics, 28
Application of cold spray technology may exhibit significant benefits for the additive manufacturing process, particularly for producing intricate objects. To ascertain the feasibility of such an application, this paper aims to present a numerical investigation of the effect of scaling down a convergent-divergent (de Laval) nozzle, which is typically used in the cold spray industry, on the compressible flow parameters and thermal characteristics.Design/methodology/approachThe Navier–Stokes equations and energy equation governing compressible flow are numerically solved using a finite volume method with a coupled solver. The conjugate heat transfer technique is used to couple fluid and solid heat transfer domains and predict the local heat transfer coefficient between the solid and fluid. The use of various RANS turbulence models has also been investigated to quantify the effect of the turbulence model on the simulation.FindingsThe numerical results reveal that the flow and thermal characteristics are altered as the convergent-divergent nozzle is scaled down. The static pressure and temperature profiles at any section in the nozzle are shifted toward higher values, while the Mach number profile at any section in the nozzle is shifted toward a lower Mach number. The turbulent kinetic energy at the nozzle exit increases with the scaling down of the nozzle geometry. This study also provides convincing evidence that the adiabatic approach is still suitable even though the temperature of the nozzle wall is extremely high, as required for industrial application. Results indicate that it is feasible to use the available capabilities of the cold spray technology for additive manufacturing after scaling down the nozzle.Originality/valueThe idea of adopting cold spray technology for additive manufacturing is new and innovative. To develop this idea into a viable commercial product, a thorough understanding of the flow physics within a cold spray nozzle is required. The simulation results discussed in this paper demonstrate the effect that scaling down of a convergent-divergent nozzle has on the flow characteristics in the nozzle.
International Journal of Numerical Methods for Heat and Fluid Flow – Emerald Publishing
Published: Aug 30, 2019
Keywords: Computational fluid dynamics; Supersonic flow; Compressible flow; Convergent-divergent nozzle; RANS models
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