DEMAND-REPAIR

Development of Advanced Manufacturing Technologies for Repairing Next Generation Aeroengines

The aerospace industry is working towards building a sustainable industry to reduce its environmental impact and effect on climate change. Replacing damaged parts with the new ones is a costly affair, which can be avoided if the parts can be repaired and remanufactured. However, traditional technologies such as electron beam patch welding or high-velocity-oxy fuel or plasma spray are not suitable to effectively repair next generation parts. The extensive heat input from these processes can cause thermal and geometrical distortions and degrade mechanical properties, resulting in an unacceptable risk to safety.

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Therefore, new alternative technologies must be explored for repairing such advanced components. The emerging processes of cold spray, high velocity air fuel (HVAF) spray, extreme high speed laser cladding (EHLA) and laser metal deposition-powder (LMDp) have been identified by the consortium as promising surface engineering and additive manufacturing technologies, due to their lower heat input compared with traditional techniques.

All of these emerging technologies make use of powder feedstock material, with the process reliability and deposit quality dependent on well-controlled powder properties (composition, microstructure, morphology, powder size distribution). Ti-6Al-4V powders are typically manufactured via gas atomization and result in a low yield of powders in the desired size distribution. This results in high costs and limits the uptake of many emerging repair and additive manufacturing technologies.

Detail of airplane engine wing at terminal gate before takeoff - Wanderlust travel concept around the world with air plane at international airport - Retro contrast filter with light blue color tones
3D printer printing metal. Metallic powder for laser sintering machine for metal. Metal powder is sintered under of laser into desired shape. Modern additive technologies 4.0 industrial revolution

Novel approaches to manufacture of high value Ti-6Al-4V powders will create highly flowable titanium powders with a fine and narrow size distribution at a much lower cost. The process is also expected to result in powders with novel microstructures. While less of a concern for the laser-based repair processes that re-melt particles, such changes to microstructure are expected to increase ductility during deformation and as such, significantly benefit the spray-based processes of HVAF and cold spray.

Therefore, the DEMAND-REPAIR project plans to explore novel advanced manufacturing technologies and innovative titanium powders to repair the next generation aero-engine components.

Project Collaborators

The project is headed up by Phoenix Scientific Industries Ltd with TWI and Innovate UK as participants.

TWI
Innovate
GKN Aerospace
University West

Projects & Collaborations

COLDMELT

Continuous melting and atomisation of titanium alloys for near-net-shape AM processes for the aerospace industry via cold-crucible technology. In collaboration with BAE, Proxima and University of Greenwich with support from Airbus, Rolls-Royce and GKN Aerospace.

HILO SILVER

This project will investigate the prospect of commercialising silver alloys as cost-effective and low silver alternatives to front-side pure silver paste in solar cells whilst maintaining the key properties of low resistivity, oxidation resistance and solderability.

ALUMOTOR

UK-Alumotor is a transformative programme that will build a UK supply chain to deliver a high performance, e-machine at a reduced cost and volume in order to drive the electric revolution. This magnet free technology project is driven by RICARDO and Innovate UK.

PURECURE

Innovation project aiming to develop a UK-based manufacturing supply chain for waster copper and converting it into high purity 99.99% copper powder feedstock for high value applications, such as civil nuclear and fusion energy components.