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Metal-glass welding 'to transform manufacturing' – Heriot Watt

06 Mar 2019

Researchers led by Duncan Hand have welded glass and various metals/alloys using an ultrafast pulsed laser system.

Scientists from Heriot-Watt University, Edinburgh, UK, have welded glass and metal together using an ultrafast laser system, in what they are describing as “a breakthrough for the manufacturing industry”.

Various optical materials such as quartz, borosilicate glass and even sapphire have all been successfully welded to metals like aluminium, titanium and stainless steel using the Heriot-Watt laser system, which provides very short, picosecond pulses of infrared light in tracks along the materials to fuse them together.

Being able to weld glass and metals together will be a huge step forward in manufacturing and design flexibility, says the Heriot-Watt team: the new process could transform the manufacturing sector and have direct applications in the aerospace, defence, optical technology and even healthcare fields.

Professor Duncan Hand, director of the five-university EPSRC Centre for Innovative Manufacturing in Laser-based Production Processes based at Heriot-Watt, commented, “Traditionally it has been very difficult to weld together dissimilar materials like glass and metal due to their different thermal properties - the high temperatures and highly different thermal expansions involved cause the glass to shatter.

“Being able to weld glass and metals together will be a huge step forward in manufacturing and design flexibility.

“At the moment, equipment and products that involve glass and metal are often held together by adhesives, which are messy to apply and parts can gradually creep, or move. Outgassing is also an issue - organic chemicals from the adhesive can be gradually released and can lead to reduced product lifetime.

Glass-to-metal welding.

Glass-to-metal welding.

‘Megawatt peak power’

“The process relies on the incredibly short pulses from the laser, which last only a few picoseconds. The parts to be welded are placed in close contact, and the laser is focused through the optical material to provide a very small and highly intense spot at the interface between the two materials - we achieved megawatt peak power over an area just a few microns across.

“This creates a microplasma, like a tiny ball of lightning, inside the material, surrounded by a highly-confined melt region. We tested these welds across the temperature range –50°C to 90°C and the welds remained intact, so we know they are robust enough to cope with extreme conditions.”

Professor Hand and his team are working with a consortium led by Oxford Lasers, a laser micromachining systems integrator and Coherent Scotland, laser specialists; and Leonardo and Gooch & Housego, both end-users of the technology to develop a prototype for the laser processing system and take it closer to commercialisation.

Two other partners, Glass Technology Services and the Centre for Process Innovation, provide additional routes to commercialisation, including in packaging of OLED devices. The project is funded by Innovate UK, Heriot-Watt University and contributions from additional industry partners.

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