Renishaw additive manufacturing technology supports Wales initiative

The system, which allows the construction of fully dense, highly complex metal parts and structures, will be used by a new 'Aerospace & Manufacturing' multidisciplinary research team within the University's College of Engineering. Part of the team's focus is the ASTUTE (Advanced Sustainable Manufacturing Technologies) project, a pan-Wales joint initiative part-funded by the EU's Convergence European Regional Development Fund through the Welsh Government. The aim of the project is to promote growth within manufacturing industry in West Wales and the Valleys by adopting more advanced technologies. "The project targets the aerospace, automotive and high technology sectors and aims to create sustainable, higher value goods," Says Johann Sienz, director of ASTUTE and Professor of Aerospace and Manufacturing at Swansea University. "By applying Advanced Engineering techniques, such as additive manufacturing, to both the design of products and to the production process, the project aims ultimately to create new skilled jobs in the manufacturing sector in Wales." Says Simon Scott, director of Renishaw's Additive Manufacturing Products Division: "Renishaw is very pleased to have won this tender against strong competition from other additive manufacturing suppliers. There is great potential for additive technologies, and through the work of centres of excellence like Swansea University, the global possibilities to improve energy efficiency and product performance can be thoroughly investigated." Renishaw's additive manufacturing (AM) technology is a digitally driven process that uses a high powered ytterbium fibre laser to fuse fine metallic powders in to 3D objects, direct from 3D CAD data. The metallic powder is distributed evenly across the build plate in layer thicknesses ranging from 20 to 100 microns forming the 2D cross section. The layer of powder is then fused using the laser in a tightly controlled atmosphere. The process is repeated, building up parts of complex geometries, layer by layer.