Numerical simulation and mechanism analysis of hydrogen fuel HVOF spraying process based on EDC and EDM combustion models

Abstract

High-Velocity Oxygen-Fuel (HVOF) spraying is an advanced surface treatment technique. Combustion reactions directly govern the in-flight behavior of spraying jets and particles. Quantitatively analyzing these mechanisms is therefore essential for high-quality coating fabrication. This paper conducts a numerical simulation study on the HVOF thermal spraying process using hydrogen as the fuel by establishing a 2D axisymmetric computational fluid dynamics (CFD) model for the JP5000 spray gun. The model included combustion process, spraying flame flow injection process and the flight characteristics of the particles. Using hydrogen as fuel, the process of spraying magnesium alloy substrate was solved by numerical calculation. Flame dynamics and dispersed particle phases were simulated under contrasting combustion models: Eddy Dissipation (EDM) and Eddy Dissipation Concept (EDC). Computational results demonstrate that under the EDC model can be used to quantify the effects of multi-step chemical reaction and small-scale turbulence on the combustion reaction rate, and the calculation results of the EDC model are smoother and more stable. The results demonstrate that the EDC model, with its detailed chemical mechanism, provides fundamentally different and more physically plausible predictions of the flame and particle conditions, underscoring its necessity for high-fidelity modeling of advanced thermal spraying processes.

Keywords

HVOF EDC combustion reaction model turbulence model

Get full access to this article

View all access options for this article.

References

Praveen

Arjunan

. Parametric optimisation of high-velocity oxy-fuel nickel-chromium-silicon-boron and aluminium-oxide coating to improve erosion wear resistance. Mater Res Express 2019; 6(9): 096560.

Cheng

Trapaga

McKelliget

, et al. Mathematical modelling of high velocity oxygen fuel thermal spraying of nanocrystalline materials: an overview. Model Simul Mater Sci Eng 2003; 11: R1–R31.

Cheng

Lavernia

, et al. The effect of particle size and morphology on the in-flight behavior of particles during high-velocity oxyfuel thermal spraying. Metallurgical Mater Trans B 2001; 32(3): 525–535.

Zhao

Jiang

, et al. Mechanistic study on the influence of hydrogen fuel in high-velocity oxygen-fuel (HVOF) thermal spraying process. JOM 2024; 76: 57–70.

Tabbara

. Computational simulation of liquid-fuelled HVOF thermal spraying. Surf Coat Technol 2009; 204(5): 676–684.

Zhang

Harris

McCartney

. Microstructure formation and corrosion behaviour in HVOF-sprayed Inconel 625 coatings. Mater Sci Eng A 2003; 344: 45–56.

Pradeep Raj

Thirumalaikumarasamy

Ashokkumar

. Erosion–corrosion behaviour of HVOF coated WC-10Ni-5Cr coatings on 35 CrMo steel. Canadian Metallurgical Quarterly 2026; 65(1): 675–691.

Sathiyamoorthy

Duraisamy

Mohankumar

. HVOF-sprayed silicon carbide-enhanced TiO₂ cermet coatings for titanium alloys: a study on solid particle erosion behavior. Silicon 2025; 17: 3333–3354.

Rajendran

Duraisamy

Chidambaram Seshadri

, et al. Optimisation of HVOF spray process parameters to achieve minimum porosity and maximum hardness in WC-10Ni-5Cr coatings. Coatings 2022; 12: 339.

10.

Prasad

Rajesh

Thirumalaikumarasamy

, et al. Multi response optimization of HVOF process parameters in low carbon steels. Sādhanā 2022; 47: 265.

11.

Escue

Cui

. Comparison of turbulence models in simulating swirling pipe flows. Appl Math Model 2010; 34(10): 2840–2849.

12.

Zhao

, et al. Mechanism study on the influence of combustion models and spray gun geometric parameters on high-velocity oxygen-fuel (HVOF) thermal spraying. J Manuf Process 2023; 98: 173–185.

13.

Jadidi

Moghtadernejad

Dolatabadi

. Numerical modeling of suspension HVOF spray. J Therm Spray Technol 2016; 25(3): 451–464.

14.

Christofides

. Computational study of particle in-flight behavior in the HVOF thermal spray process. Chem Eng Sci 2006; 61(19): 6540–6552.

15.

Gao

Zhang

, et al. Numerical analysis of the activated combustion high-velocity air-fuel (AC-HVAF) thermal spray process: a survey on the parameters of operation and nozzle geometry. Surf Coat Technol 2021; 405: 126588.

16.

Gao

Zhang

, et al. Numerical investigation on the flame characteristics and particle behaviors in a HVOF spray process using kerosene as fuel. J Therm Spray Technol 2021; 30(3): 725–738.

17.

Toosi

Farokhi

Mashadi

. Application of modified eddy dissipation concept with large eddy simulation for numerical investigation of internal combustion engines. Computers & Fluids 2015; 109: 85–99.

18.

Emami

Jafari

Mahmoudi

. Effects of combustion model and chemical kinetics in numerical modeling of hydrogen-fueled dual-stage HVOF system. J Therm Spray Technol 2019; 28(3): 333–345.

19.

Chen

Huang

Wang

. Further development of the modified eddy dissipation model. J Phys Conf Ser 2020; 1509(1): 012014.

20.

Magnussen

Hjertager

. On mathematical modeling of turbulent combustion with special emphasis on soot formation and combustion. Symp Combust 1977; 16(1): 719–729.

21.

Gordon

Mcbride

. Computer program for calculation of complex chemical equilibrium compositions and applications. Part 1: analysis. NASA Reference Publications, 1994.

22.

Magnussen

. On the structure of turbulence and a generalized eddy dissipation concept for chemical reaction in turbulent flow. In: 19th Aerospace Sciences Meeting, 1981.

23.

Zhao

Kazakov

, et al. An updated comprehensive kinetic model of hydrogen combustion. Int J Chem Kinet 2004; 36(10): 566–575.

24.

Gran

Magnussen

. A numerical study of a bluff-body stabilized diffusion flame. Part 2. Influence of combustion modeling and finite-rate chemistry. Combust Sci Technol 1996; 119(1-6): 191–217.

25.

Lyu

Song

, et al. Comparative numerical analysis and optimization in downhole combustion chamber of thermal spallation drilling. Appl Therm Eng 2017; 119: 481–489.

26.

Kamnis

. Numerical modelling of propane combustion in a high velocity oxygen–fuel thermal spray gun. Chem Eng Process Process Intensification 2006; 45: 246–253.

27.

Zhou

Chen

, et al. Numerical Investigation of particles in warm-particle peening-assisted high-velocity oxygen fuel (WPPA-HVOF) spraying. J Therm Spray Technol 2020; 29: 1682–1694.

28.

Zhu

Liu

, et al. Effects of spraying parameters on the velocity of HVOF-sprayed particles based on the PIV method. J Therm Spray Technol 2022; 31: 2147–2156.

29.

Papageorgakis

Assanis

. Comparison of linear and nonlinear RNG-based k-epsilon models for incompressible turbulent flows. Numer Heat Transf B Fundam 1999; 35(1): 1–22.

30.

Oberkampf

Talpallikar

. Analysis of a high-velocity oxygen-fuel (HVOF) thermal spray torch part 1: numerical formulation. J Therm Spray Technol 1996; 5(1): 53–61.

31.

Srivatsan

Dolatabadi

. Simulation of particle-shock interaction in a high velocity oxygen fuel process. J Therm Spray Technol 2006; 15(4): 481–487.

32.

Rice

Bell

. Chemical kinetics. Dover Publications, 1976.