Heat transfer characterization of the solidification process resulting from a spray forming process

Sheng, Xiaoling; Mackie, Calvin; Hall, Carsie A.

doi:10.1016/j.icheatmasstransfer.2004.10.022

Cited by 6 publications

(2 citation statements)

References 16 publications

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“…Finite element numerical simulation is the desirable method to resolve the problem, which makes it possible to forecast the temperature change rule of the composite powders. Many researches [4][5][6] about heat transfer of spray droplets during the metal spray forming process, which is relatively simple, have been carried out. However, the heat process of the sprayed composite powder during the self-reactive spray forming is quite more complicated than that during metal spray forming.…”

Section: Introductionmentioning

confidence: 99%

Study on Temperature Change Rule of Sprayed Composite Powders in Flight

Liu

Wang

Sun

et al. 2011

MSF

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The temperature change process of the single sprayed composite powder during the self-reactive spray forming process for preparing the Ti (C,N)-TiB2 ceramic preforms was numerically simulated by means of finite element analysis. The results show that after the sprayed composite powder with grain size of 50μm has entered the flame field for 0.35ms, the surface temperature of it will reach the igniting temperature and the self-propagating high-temperature synthesis (abbr. SHS) reaction will take place. The heating rate of the particle in this period is about 2.82×106°C/s. After the SHS reaction has taken place, the heating rate becomes quicker because of the double function of the flame and the reactive heat release. When the temperature of the sprayed particle is higher than that of the flame, the heat exchange process will turn into heat absorption from heat release, which leads to the great drop of the heating rate (about 1.20×106°C/s). The composite powder completes the reaction in 0.88ms and reaches the highest temperature of 2920°C, which makes it become a ceramic droplet. After the reaction has finished, the droplet cools down quickly from exterior to interior, and the surface temperature of it descends to the theoretic eutectic melting point of the composite ceramics (2620°C) after 0.34ms. Then the droplet begins to solidify at some degree of supercooling and becomes ceramic particle. The numerically simulated results before, during and after the reaction match the water-quenching experiments of the sprayed particle with particle size of 50μm during the corresponding period. It indicates the heat process of the sprayed composite powder on the whole, which is composed of being heated, heat releasing, cooling and solidifying.

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Section: Introductionmentioning

confidence: 99%

Study on Temperature Change Rule of Sprayed Composite Powders in Flight

Liu

Wang

Sun

et al. 2011

MSF

View full text Add to dashboard Cite

show abstract

“…However, precisely measuring the transient temperature variation of the coating/substrate is a real challenge, because the hot particles are added on the substrate or previously formed coating surface dynamically and randomly with a simultaneous movement of the spray gun [12][13][14]. Numerical simulation provides another way to understand the details of temperature for the thermal sprayed coatings [15]. For example, Finite element and finite difference simulations of temperature field during the thermal spraying processes [16,17], where coating buildup was simplified as a layerby-layer deposition model and the layer thickness was derived from the cross-section profile of an actual coating.…”

Section: Introductionmentioning

confidence: 99%