Numerical simulation of the flow characteristics inside a novel plasma spray torch

Liu, Sen-Hui; Trelles, Juan Pablo; Murphy, Anthony B.; Li, Lu; Zhang, Shan-Lin

doi:10.1088/1361-6463/ab228b

Cited by 33 publications

(19 citation statements)

References 55 publications

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“…shown that a trumpet-like shape of the anode favors the expansion of arc column and reduces the compression effect of the cold boundary around the arc (29).…”

Section: Current Non-transferred Plasma Torches 21 Energetic Featuresmentioning

confidence: 99%

Relationships between arc plasma jet properties and plasma/liquid interaction mechanisms for the deposition of nanostructured ceramic coatings

Rat¹,

Bienia²,

Dhamale³

et al. 2022

Plasma Phys. Control. Fusion

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Ceramic nanostructured coatings with intermediate thicknesses between 10 and 100 µm exhibit improved thermal and mechanical properties for thermal barrier coatings or wear resistant coatings. Such coatings comply with the technical requirements of aeronautical and automotive applications. This implies to develop deposition processes with high throughput and deposition rates promoting the formation of nanostructured coatings. The use of a liquid phase as a carrier medium of nanoparticles or of solution precursors has been shown to be of major interest when being injected within a thermal plasma jet. The as-sprayed materials can form ceramic nanostructured coatings provided the liquid injection encompassing the physicochemical properties of liquid and its injection method copes with the plasma properties. Especially the repeatability of the interaction phenomena between the liquid phase and the arc jet has a key role in the efficiency deposition so that some research efforts are devoted to stabilize the arc while a liquid jet is continuously injected within the plasma. Alternatively a pulsed arc plasma jet can be generated and associated with a time-phased injection of droplets. This paper presents the different issues related to the arc plasma properties produced by direct plasma torches including the arc instabilities and their influence on plasma/liquid interaction mechanisms leading to the formation of nanomaterials. A focus is made on pulsed plasma spraying associated with a synchronized injection of microsized droplets by means of an inkjet printing method.

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“…shown that a trumpet-like shape of the anode favors the expansion of arc column and reduces the compression effect of the cold boundary around the arc (29).…”

Section: Current Non-transferred Plasma Torches 21 Energetic Featuresmentioning

confidence: 99%

Relationships between arc plasma jet properties and plasma/liquid interaction mechanisms for the deposition of nanostructured ceramic coatings

Rat¹,

Bienia²,

Dhamale³

et al. 2022

Plasma Phys. Control. Fusion

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“…Hence, the air jet ejection case validation is already discussed in [42] with the experimental data of Eugene [15]. Now, in the case of plasma, the computational setup for generated plasma inside the nozzle is validated with the available experimental data of Liu [43].…”

Section: Problem Descriptionmentioning

confidence: 99%

“…Setup. e plasma nozzle geometry and boundary conditions for plasma torch validation are extracted from the work of Sen-Hui Liu [43]. e ionized gas comprises the mixture of 70% nitrogen and 30% argon.…”

Section: Validation Of Plasma Nozzlementioning

confidence: 99%

Modeling and Analysis of Shock Reduction through Counterflow Plasma Jets

Rashid

Nawaz

Maqsood

et al. 2021

Mathematical Problems in Engineering

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The study presents a numerical investigation of aerodynamic drag reduction by implementing a counterflow plasma jet, emanating from the stagnation point of an aerodynamic surface in a supersonic regime with a constant pressure ratio PR = 3 , and compares findings with a conventional opposing jet. The computational study is carried out by solving three-dimensional and axisymmetric Navier–Stokes equations for counterflow plasma-jet interaction. The calculations are performed at free-stream Mach ( M ∞ = 1.4) with sea level stagnation conditions. The weakly ionized argon plasma jet generated by a plasma torch has constant stagnation pressure and temperature of 303,975 Pa and 3000 K . The effect of the Mach number and the angle of attack variation on plasma-jet effectiveness is also analyzed. The results indicate that the counterflow plasma jet reduces more drag (in twice) compared to the conventional jet (nonplasma). The gravitational, magnetic field effect and chemical processes in the plasma formation are considered negligible. It is inferred that the effectiveness of the counterflow plasma jet strongly depends upon the jet stagnation temperature.

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“…By introducing Steenbeck's minimum principle and the assumption of the gas-dynamic force should be balanced by the magnetic body force around the arc attachment, the qualitative analysis of possible arc root loca-tion on the anode has been discussed [16]. The two-dimensional (2D) steady laminar model [17] and k-epsilon model [18] are used separately to simulate the plasma flow behaviour and heat transfer. To compare their numerical results with experiments on plasma jet temperature, there exists apparent deviation between the laminar model and turbulent model while ejecting out of the nozzle exit, and the latter model fits the experimental data well.…”

Section: Introductionmentioning

confidence: 99%

Numerical analysis of direct-current (DC) plasma processing for high efficient steel surface modification

Wei¹,

Xu²,

Bennett³

et al. 2022

Preprint

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Nowadays, direct-current (dc) non-transferred arc plasma torch has drawn significant interest from both academia and industry due to the capability to process products in an efficient and convenient way. The core of this technology is to clarify and manipulate the arc behavior at the interior of the torch and produces ideal plasma jets for processing. To solve this problem, a quasi-steady axisymmetric model is built to simulate and compare the arc characteristics in different operating conditions and different nozzle structures. The results uncover distinct aspects of the study on arc characteristics, including the detection of the region of primary arc attachment, the effect of changing operating conditions, and the choking effect caused by torch structure. The thermal efficiency focused on processing substrate is also calculated in this paper. The results show that increasing mass flow rate brings better thermal efficiency, whereas improving the arc current value causes the opposite result. Meanwhile, two types of nozzle are discussed by thermal efficiency, and the wide nozzle is chosen for torch optimization due to its high power efficiency. The secondary arc attachment on the metal substrate is discovered, but its effect on the processing could be ignored for the extremely low electric current value.

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Numerical simulation of the flow characteristics inside a novel plasma spray torch

Cited by 33 publications

References 55 publications

Relationships between arc plasma jet properties and plasma/liquid interaction mechanisms for the deposition of nanostructured ceramic coatings

Relationships between arc plasma jet properties and plasma/liquid interaction mechanisms for the deposition of nanostructured ceramic coatings

Modeling and Analysis of Shock Reduction through Counterflow Plasma Jets

Numerical analysis of direct-current (DC) plasma processing for high efficient steel surface modification

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