Improvement of Online Diagnostic System to Monitor In-Flight Particles in Thermal Spray Processes

Akbarnozari, Ali; Amiri, Shahin Nayyeri; Moreau, Christian; Bamber, O.; Gernon, J-D.; Choquet, M.; Pouliot, L.

doi:10.31399/asm.cp.itsc2019p0957

Cited by 1 publication

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“…The velocity is determined using the time-of-flight concept [30]. This procedure consists of measuring the thermal radiation emitted by particles at two positions, a known distance apart in the direction of flow; the delay between two signals provides information for calculating the velocity [29]. The working distance of the sensor was the focal length of the equipment, which was 200 mm; this is a standard value for any spraying, regardless of the powder or the gun used.…”

Section: Materials and Methodologymentioning

confidence: 99%

Analysis of the Relationship between APS Thermal Spray Parameters of Ni5Al Particles and Coating Characteristics

Fernández Roiz,

Moreno,

Jorde Cerezo

et al. 2023

Coatings

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The strength and characteristics of a coating are defined by the impact and temperature of the individual molten particles, as well as by the state of the surface to be coated. The parameters selected for thermal spraying determine the parameters of the particles in flight: temperature and velocity. These parameters can be determined by measuring the thermal radiation intensity of the particles in flight. The parameters that define the thermal spray are the mass flow rate, the intensity, and the H2 flow rate in the gas mixture to be propelled into the spray gun. On the other hand, the strength of the coating obtained can be estimated using its hardness and adhesion. In this study, a design of the experiments is developed to determine the relationships between the operating parameters and the parameters characterising the particles. From this design, the results obtained are analysed. The experimental results confirmed the direct relationship between intensity and particle temperature, consistent with the relationship between intensity and energy generated in the arc in the spray device. The velocities followed a similar relationship. Increasing the proportion of H2 in the feed gas led to a higher heat transfer to the particles, consistent with the information found in the literature. A similar effect was detected for the velocity. The adhesion and hardness increase with the speed and temperature of the particle in flight, which is related to a more efficient spatter-flattening process. The applied procedure provides an efficient methodology for the development of useful surfaces for the optimisation of thermal spraying processes.

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Section: Materials and Methodologymentioning

confidence: 99%