To develop and implement next generation prosthetic interface liners which will utilise a novel manufacturing with embedded features that enhances benefit and comfort for lower limb amputees.

Laser processing can enable higher productivity in manufacturing aerospace structures. However, the lack of large-scale, cost-effective manipulator has limited the applicability of the process – LaserTAU will address this by combining laser processing with the ‘TAU’ robot platform.

The EPSRC Centre for Innovative Manufacturing in Additive Manufacturing will create a sustainable and multidisciplinary body of expertise that will act as a UK and international focus - the 'go to' place for additive manufacturing and its applications. The Centre will undertake a user-defined and user-driven programme of innovative research that underpins Additive Manufacturing as a sustainable and value-adding manufacturing process across multiple industry sectors.Additive Manufacturing (AM) is the direct production of end-use component parts made using additive layer manufacturing technologies. It enables the manufacture of geometrically complex, low to medium volume production components in a range of materials, with little, if any, fixed tooling or manual intervention beyond the initial product design. AM enables a number of value chain configurations, such as personalised component part manufacture but also economic low volume production within high cost base economies. This innovative approach to manufacturing is now being embraced globally across industry sectors from high value aerospace / automotive manufacture to the creative and digital industries. To date AM research has almost exclusively focused upon the production of single material, homogeneous structures (in polymers, metals and ceramics). The EPSRC Centre for Innovative Manufacturing in Additive Manufacturing will move away from single material, 'passive' AM processes and applications that exhibit conventional levels of functionality, toward the challenges of investigating next generation, multi-material active additive manufacturing processes, materials and design systems. This transformative approach is required for the production of the new generation of high-value, multi-functional products demanded by industry. The Centre will initially explore two themes as the centrepieces of a wider research portfolio, supported by a range of platform activities. The first theme takes on the challenge of how to design, integrate and effectively implement multi-material, multi-functional manufacturing systems capable of matching the requirements of industrial end-users for 'ready-assembled' multifunctional devices and structures. Working at the macro level, this will involve the convergence of several approaches to increase embedded value to the product during the manufacturing stage by the direct printing / deposition of electronic / optical tracks potentially on a voxel by voxel basis; the processing and bonding of dissimilar materials that ordinarily require processing at varying temperatures and conditions will be particularly challenging. The second theme will explore the potential for 'scaling down' AM for small, complex components, extending single material AM to the printing of optical / electronic pathways within micro-level products and with a vision to directly print electronics integrally. The platform activities will provide the opportunity to undertake both fundamental and industry driven pilot studies that both feed into and derive from the theme-based research, and grow the capacity and capability of the Centre, creating a truly national UK Centre and Network that maintains the UK at the front of international research and industrial exploitation in Additive Manufacturing.

This Industrial Doctoral Centre (IDC) addresses a national need by building on the strengths of the existing EngD in Micro- and NanoMaterials and Technologies (MiNMaT) and the University of Surrey's excellent track record of working with industry to provide a challenging, innovative and transformative research environment in materials science and engineering. Following the proven existing pattern, each research engineer (RE) will undertake their research with their sponsor at their sponsor's premises. The commitment of potential sponsors is demonstrated in the significant number of accompanying letters of support. Taking place over all four years, carefully integrated intensive short courses (normally one week duration) form the taught component of the EngD. These courses build on each other and augment the research. By using a core set of courses, graduates from a number of physical science/engineering disciplines can acquire the necessary background in materials. This is essential as there are insufficient numbers of students who have studied materials at undergraduate level. The research focus of this IDC will be the solution of academically challenging and industrially relevant processing-microstructure-property relationship problems, which are the corner-stones of the discipline. This will be possible because REs will interact with internationally leading academics and have access to a suite of state-of-the-art characterisation instrumentation, enabling them to obtain extensive hands on experience. As materials features as one of the University's seven research priority areas, there is strong institutional support as demonstrated in the Vice Chancellor's supporting letter, which pledges 2.07M of new money for this IDC. As quality and excellence run through all aspects of this IDC, those graduating with an EngD in MiNMaT will be the leaders and innovators of tomorrow with the confidence, knowledge and research expertise to tackle the most challenging problems to keep UK industry ahead of its competitors.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.