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Plasma spray-coating

The plasma spraying process involves the generation of a plasma jet, the injection and treatment of particles within the plasma jet and finally the formation of the coating.

Plasma spray process diagram.

Plasma spray process

Plasma spray process diagram showing the main components of the plasma torch. Key features of the process are also included.

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To generate the plasma jet, a working gas such as an argon/hydrogen mixture is passed through a powerful electric arc discharge formed in the gap between a cathode and anode. The energy released rapidly heats up the gas mixture, converting it to high-temperature plasma at about 14 000 K. Rapid expansion occurs, lifting the speed of the jet, giving it a very high nozzle speed of up to 800 m/s. The coating material in a fine powder form (within the range 20–90 mm) is then injected into the plasma jet. Molten droplets form, which are propelled at high speed towards the object to be coated (substrate).

Coating the substrate

On hitting the substrate, each molten droplet splats onto the surface, forming a pancake-like structure that rapidly solidifies. It is important that the droplet thoroughly ‘wets’ the substrate surface, and attention to the composition of the coating material needs to be made to ensure that this happens.

Each splat has a thickness in the micrometre range and a length that varies across the range from several to above 100 micrometres. Splats overlap one another as the deposit builds up to the required thickness. Often, there are small voids present as well as inclusions of rogue materials such as metal oxides. These can interfere with the mechanical strength of the coating and lead to poor adhesion to the substrate.

Plasma spray coating diagram.

Plasma spray coating

If the molten droplets of spray form a disc shape rather than a splat shape then a stronger adhesion occurs, this is due to the temperature at the bonding interface.

Rights: The University of Waikato Te Whare Wānanga o Waikato

The properties of the surface of the substrate also need to be taken into account. In most industrial settings, the pieces arriving at the spraying unit are new or covered with old coatings. Each piece needs to be thoroughly cleaned and then the surface roughened by abrasive grit blasting. Thorough surface preparation ensures that a good mechanical bond between the coating and the substrate can be achieved.

Another factor to be considered is the temperature at the particle’s interface with the substrate on impact. This contact temperature influences the adhesion of the splats as well as the adhesion of the coating to the substrate.

Recent research has shown that, if a molten droplet, on hitting the substrate surface, forms a disc-shaped splat rather than a splashed splat, the coating formed tends to have good adhesion and cohesion with reduced void space.

Adhesion is the force of attraction between molecules of different substances while cohesion is the force of attraction between molecules of the same substance.

Molten droplets of coating material 2 different splat shapes

Types of splat

Molten droplets of coating material splat onto the surface of the substrate with either a disc or splash shape. Controlling conditions to produce disc shapes gives coatings with good adhesion and cohesion.

Rights: Dr Anh Tran, Effects of surface chemistry on splat formation during plasma spraying, University of Auckland, 2010.

Atmospheric plasma spraying

There is a wide range of plasma spray techniques used in the coatings industry. One of these techniques – atmospheric plasma spraying – is extensively used to produce coatings on structural materials. Such coatings provide protection against high temperatures, corrosion and wear. For example, in aircraft jet engines, many of the component parts are subjected to very high temperatures as well as a corrosive and erosive environment. To limit wear and tear on these components and also give them thermal protection, a thin coating of a ceramic material called yttria stabilised zirconia (Y2O3 and ZrO2) is plasma sprayed onto the component surfaces.

Industrial uses of plasma coatings

Dr Steven Matthews is a senior lecturer in the School of Engineering and Advanced Technology at Massey University in Auckland. In this video, he first explains some of the history of thermal plasma spraying and then describes numerous applications of this coating process. For example, in the aero industry, a large number of jet engine components are plasma sprayed with a ceramic material to serve as a thermal barrier coating.

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Process controls

In order to produce molten particles of the correct size, speed and temperature, a number of factors need to be controlled. Some of these are:

  • composition of the working gas stream and its flow rate

  • electric arc discharge power

  • powder particle size, composition and injection rate

  • spray distance

  • speed and number of spraying passes.

For example, in the coating of a generator bearing housing with a ceramic material, an argon/hydrogen working gas mix is chosen. This not only increases the plasma temperature but also minimises oxide levels without compromising the integrity of the coating.

Factors that influence the splat formation process

Factors that influence splat formation during plasma spraying

Factors that influence splat formation

A wide variety of factors can influence splat formation during the plasma spraying process.

Rights: The University of Waikato Te Whare Wānanga o Waikato

Related content

In Plasma spray gun research read about Massey University’s Dr Steven Matthews’s plasma spray gun research. It is focused on two main areas – plasma spray-coating magnesium-based medical implants with hydroxyapatite and the plasma spraying of titanium coatings.

Published: 29 April 2014