Laser Shock Flier Impact Simulation of Particle-Substrate Interactions in Cold Spray

Barradas, Sophie; Guipont, Vincent; Molins, Régine; Jeandin, Michel; Арригони, М.; Boustie, M.; Bolis, C.; Berthe, Laurent; Ducos, M.

doi:10.1007/s11666-007-9069-9

Cited by 50 publications

(26 citation statements)

References 23 publications

(13 reference statements)

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“…Similar microstructural features have also been observed in magnetic pulse welding [66]. analogy between bonding characteristics in explosive welding and CS has also been considered as a basis to devise laser shock experiments [67] as a micron-scale physical model of particle impact in CS. These experiments resemble explosive welding geometrically, but relate to particle impact in terms of system size.…”

Section: Bonding Characteristics In Large-scale Impact Processesmentioning

confidence: 57%

Cold spraying – A materials perspective

et al. 2016

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Cold spraying is a solid-state powder deposition process with several unique characteristics, allowing production of coatings or bulk components from a wide range of materials. The process has attracted much attention from academia and industry over the past two decades.The technical interest in cold spraying is twofold: first as a coating process for applications in surface technology, and second as a solid-state additive manufacturing process, offering an alternative to selective laser melting or electron beam melting methods. Moreover, cold spraying can be used to study materials behaviour under extremely high strain rates, high pressures and high cooling rates. The cold spraying process is thus considered to be relevant for various industrial applications, as well as for fundamental studies in materials science.This article aims to provide an overview of the cold spray process, the current understanding of the deposition mechanisms, and the related models and experiments, from a materials science perspective. IntroductionCold spraying (CS) is a solid-state material deposition technique, where micron-sized particles of a powder bond to a substrate as a result of high-velocity impact and the associated severe plastic deformation. Acceleration of particles to high velocities is obtained via expansion of a pressurised and (ironically) 'hot' gas through a diverging-converging nozzle.Despite heating the process gas -which is to provide higher acceleration of the gas and also to facilitate particle deformation through thermal softening -the feedstock remains in the solid state throughout the entire process; hence the name 'cold' spraying. This is to underline the contrast to conventional thermal spraying where particles are completely or partially molten upon impact onto the substrate. Alternative terminology includes cold gas spray, micro cold spray, cold gas dynamic spray, kinetic spray, supersonic particle deposition and metal powder application (MPA), all of which refer to the same principle of solid-state powder deposition as described above. CS is used for coating and repair. It is also used for additive manufacturing (AM) at relatively high deposition rates as compared to the methods based on selective laser or electron beam melting. The main advantage of CS is that it alleviates the problems associated with high temperature processing of materials, such as oxidation and unfavourable structural changes. It is possibly the only continuous method to produce bulk components of metastable materials that are available only in the powder form, e.g. as obtained from mechanical attrition or gas atomisation. The aim of the present paper is to provide an overview of CS from a materials perspective, particularly for a broader audience in materials research, e.g. with interest in dynamic phenomena, plasticity and phase transformations. In terms of application and properties, CS is perhaps best to be compared to thermal spraying processes, as in [24,25]. In view of relevant physical phenomena, however, CS is mos...

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Section: Bonding Characteristics In Large-scale Impact Processesmentioning

confidence: 57%

Cold spraying – A materials perspective

et al. 2016

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“…Experiments (Ref 12) and numerical simulations ( Ref 13) indicate that, under certain conditions during the creation of cold-sprayed coating, melting cannot occur at the particle-substrate interface. On the other hand, other experimental studies show evidence of local fusion at the substrate-particle interface (Ref 11,14) as well as interlamellar local melting ( Ref 15). These experiments show an increase of coating adhesion due to the presence of molten phases ( Ref 12,14).…”

Section: Introductionmentioning

confidence: 94%

“…On the other hand, other experimental studies show evidence of local fusion at the substrate-particle interface (Ref 11,14) as well as interlamellar local melting ( Ref 15). These experiments show an increase of coating adhesion due to the presence of molten phases ( Ref 12,14). The presence or the absence of local melting seems to depend on the materials and experimental conditions.…”

Section: Introductionmentioning

confidence: 94%

The Influence of the Substrate on the Deposition of Cold-Sprayed Titanium: An Experimental and Numerical Study

et al. 2010

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The deposition of cold-sprayed titanium on various substrates is studied in this work. A rather coarse powder of titanium (270 + 45 lm) was sprayed under uniform spraying conditions using a cold spray system onto five different substrates: two aluminum-based alloys (AISI 1050-H16 and AISI 2017-T4), copper, stainless steel AISI 304L, and Ti-6Al-4V. All the spraying experiments were carried out using alternatively nitrogen (N 2 ) or helium (He) as the process gas. Thick coatings were formed on the various substrates, with the exception of the AISI 2017 substrate. When N 2 was used as the process gas, only a few particles remained adhering to the AISI 2017. The thick pre-existing superficial oxide layer on AISI 2017, which was detected by Electron MicroProbe Analysis (EPMA), appeared to prevent adhesion of cold-sprayed titanium particles. The interaction of the sprayed particles with the various substrates was also studied by means of numerical simulations to better understand the adhesion mechanisms. The microstructure and the characteristics of the coatings were investigated. Deposition efficiency and coating density were found both to be strongly improved by spraying helium as the process gas.

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“…[17][18][19][20] Many researchers hence have made TEM samples by the FIB method from micron-sized powders or small splats or thick coating layers at a desired location. 1,[21][22][23][24][25][26][27][28][29] Because the FIB is an imaging tool in its own right as well as the milling and thinning capability in sample preparation, 30) during the FIB fabrication, one can check the milling state and get images of the sample.…”

Section: Introductionmentioning

confidence: 99%

“…16) Therefore, when observing a thermal-sprayed splat from the surface to the interface of splat/substrate with TEM, it is quite difficult to obtain high resolution atomic structure images near the interface of splat/substrate because the region is too thick to derive the atomic structure. 1,[21][22][23][24] For the high resolution images, several researchers prepared firstly the cross section of a single splat by a conventional polishing method using silicon carbide (SiC) papers or the FIB method and then, from the cross section, several TEM samples were made respectively at desired locations within the single splat. [27][28][29] Once a TEM sample was made and observed, it is generally impossible to prepare much thinner sample at the desired position.…”

Section: Introductionmentioning

confidence: 99%

Observation of High Resolution Microstructures in Thermal Sprayed Coatings and Single Deposited Splats Using Ion Beam Milling

et al. 2011

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We have investigated microstructures of thermal sprayed coatings and single deposited splats using two types of ion beam milling: one is broad argon ion beam for the cross-sectioning of thermal sprayed coatings in a cross section polisher and the other is focused gallium ion beam for the cross-sectioning and transmission electron microscopy (TEM) sample preparation of single splats. The cross section of tungsten carbidecobalt (WC-Co) coatings fabricated by the polisher showed that it created a mirrored surface with minimized artifacts such as pull-outs of ceramic particles or smearings of pores which can be made by conventional metallographic preparations. A thin and locally re-thinned membrane of single nickel (Ni) splat was feasible to observe the internal interface of particle/substrate in high resolution atomic scale images. Substrate was heavily deformed by the impact of nickel particle with high kinetic and thermal energies. The particle and the substrate were intimately bonded without any voids or gaps.

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Laser Shock Flier Impact Simulation of Particle-Substrate Interactions in Cold Spray

Cited by 50 publications

References 23 publications

Cold spraying – A materials perspective

Cold spraying – A materials perspective

The Influence of the Substrate on the Deposition of Cold-Sprayed Titanium: An Experimental and Numerical Study

Observation of High Resolution Microstructures in Thermal Sprayed Coatings and Single Deposited Splats Using Ion Beam Milling

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