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XeraCarb Limited: A Spin-out from Sheffield Hallam University Manufacturing Novel Ceramic Composites

Summary of the impact

XeraCarb Ltd is a spin-out company formed in 2011 to exploit a class of ceramic composite materials co-invented by Jones. These materials were first devised in 2008 via a Materials and Engineering Research Institute (MERI) Knowledge Transfer activity and developed from 2009 onwards through a series of UK Ministry of Defence (UK MoD)-funded research projects. XeraCarb was spun out after the underpinning research won a national award in 2011 as the most promising UK materials system for commercialisation. The applications for XeraCarb's materials range from body- and vehicle-armour to kiln furniture and wear-resistant components. The company has attracted significant venture capital investment and is valued at over £1m. It has set up an independent production facility, has appointed employees, has been awarded a TSB grant, has materials undergoing trials in respect of a number of applications, and has delivered its first orders.

Submitting Institution

Sheffield Hallam University

Unit of Assessment

Electrical and Electronic Engineering, Metallurgy and Materials

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Materials Engineering

Lightweight Self-Reinforced Plastics for Ultimate Recyclability

Summary of the impact

Research carried out by Prof. Ton Peijs and colleagues has led to significant breakthroughs in engineering plastics: PURE® and its licensed Tegris® technology, which are lightweight self- reinforced alternatives to traditional polypropylene (PP) composites such as glass-fibre or natural- fibre-reinforced PP. Environmentally friendly and 100% recyclable, these strong and ultra-light self- reinforced plastics have been successfully used across a number of applications, from suitcases and sports gear to protective armour and automotive panels, with impressive results. When used for car, truck and van components, they have been shown to help lower exhaust emission levels and increase fuel economy.

Submitting Institution

Queen Mary, University of London

Unit of Assessment

Electrical and Electronic Engineering, Metallurgy and Materials

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Aerospace Engineering, Civil Engineering, Materials Engineering

ECRE: Composites to Industry led Consortium – the NIACE Centre

Summary of the impact

Ulster research groups in the fields of composites and metal forming have had a long-term and fruitful engagement with major industries such as Caterpillar (FG Wilson), Rolls Royce and Bombardier. Since 2008 this has resulted in new patented technologies, significant cost/performance improvement in manufacturing, the delivery of on-site industrial training, the formation of spin-out companies and the establishment of the £6m N. Ireland Advanced Composites and Engineering Centre with currently 10 member companies. In particular, Ulster research has been at the heart of patented Bombardier processes which underpinned their strategic entry into the commercial narrow body aircraft market which is worth $43billion per annum globally. The C Series wing programme, which utilises composites, employs 800 people directly in Belfast at full production, with a further 2,000 employed in the supply chain. As of today, Bombardier has global orders and commitments for 388 C Series aircraft, which include firm orders for 177 of the new airliner.

Submitting Institution

University of Ulster

Unit of Assessment

Electrical and Electronic Engineering, Metallurgy and Materials

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Aerospace Engineering, Materials Engineering, Mechanical Engineering

Ilika plc: Driving Global Innovation in Next Generation Materials

Summary of the impact

The unique application of combinatorial chemistry in materials science at Southampton has directly underpinned the success of University spin-out, Ilika Technologies. Since 2008, the breadth of applications of the research has allowed Ilika:

  • to form a partnership, worth around £4m, with Toyota in the development of battery materials for electric vehicles
  • to optimise new phase change memory materials now used by NXP in embedded memory applications, and
  • to create and sell a subsidiary, Altrika Ltd, that has provided cell-based skin regeneration therapies to 50 severe burn victims.

Between 2008 and 2012, Ilika enjoyed considerable growth, doubling employment to 35 staff, increasing turnover by approximately 25% annually, and floating on the AIM with a market capitalisation of £18.7 million.

Submitting Institution

University of Southampton

Unit of Assessment

Chemistry

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Macromolecular and Materials Chemistry, Physical Chemistry (incl. Structural), Theoretical and Computational Chemistry

Reduction of non-degradable waste from used plastic food packaging materials

Summary of the impact

The production of plastic (polymer) waste and the difficulties associated with its disposal is a major environmental challenge. Many polymer food packaging structures are made using thermoforming processes in which hot thin oil-based polymer sheets are forced under pressure into moulds and then cooled to become thin-walled packaging structures. These structures are not eco-friendly and do not degrade after use. Thus unless they are recycled, which is a complicated process and mostly does not happen, these structures cause major environmental problems worldwide.

Researchers in Brunel Institute of Computational Mathematics (BICOM) have undertaken extensive computational modelling of the thermoforming of packaging structures made from bio-materials (thermoplastics). This computational work, together with the necessary laboratory experiments which were executed by Brunel engineers, has contributed to a far better understanding of the behaviour of starch-based biodegradable food packaging. In turn, the availability of such knowledge has contributed to the steady move by food packagers and food retailers towards the adoption of such packaging which is helping to reduce the amount of long term non-biodegradable waste produced.

Submitting Institution

Brunel University

Unit of Assessment

Mathematical Sciences

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Macromolecular and Materials Chemistry
Engineering: Materials Engineering

Bringing nanomaterials research to industrial production

Summary of the impact

Nanomaterials research at Ulster into materials including diamond-like carbon (DLC) ultra-thin films, carbon nanotubes (CNT), graphene, silicon and metal oxide nanoparticles has resulted in direct uptake by major industrial manufacturers and led to a directly quantifiable socio-economic impact via added value, improved efficiencies and cost-savings and has secured or increased the employment of skilled engineering staff. Examples of this impact since 2008 include ceramic nanoparticles research in partnership with AVX Ltd that resulted in improved production efficiency processes (up 20%) and higher quality devices (up 10%). [text removed for publication] Research into ultra-thin DLC films, funded by Seagate, has led to their incorporation into magnetic media. [text removed for publication] Our nanoparticle research has attracted a new spin-in company SiSaf Ltd. (2009) and by incorporating NIBEC's expertise in nanomaterials into its business plan, the company was able to grow to a valuation of £3.5m and employ 7 people in skilled technical positions.

Submitting Institution

University of Ulster

Unit of Assessment

Electrical and Electronic Engineering, Metallurgy and Materials

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Analytical Chemistry, Macromolecular and Materials Chemistry
Engineering: Materials Engineering

Dielectric Materials for HVAC and HVDC Electrical Power Transmission Components (Nanocomposite Insulating Materials)

Summary of the impact

Electrical power companies are tasked with operating a highly reliable and robust power system. Electrical power outages (blackouts) have serious consequences for the companies concerned as well as society. The health of electrical insulating materials is critical for the reliability of these systems as it often determines equipment lifetime.

Leicester was the first to demonstrate experimentally that polymer based nanocomposite materials could increase the service life and reliability of electrical insulation as used in high voltage power transmission systems. Its research has also led to the development of measurement techniques to assess the health and the extent of thermal ageing of HV power cables.

National Grid has used Leicester's research findings to manage and monitor its electricity transmission equipment, with resulting impacts on its safety, efficiency and financial economy. Borealis, a major international supplier of insulating materials has used the research to solve manufacturing problems and to set up test facilities for medium voltage cables. A Knowledge Transfer Partnership with Alstom Grid has led to the the establishment of a £1M commercial size HVDC cable test facility which has attracted £0.5M investment from cable manufacturers worldwide.

Submitting Institution

University of Leicester

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Inorganic Chemistry, Macromolecular and Materials Chemistry
Engineering: Materials Engineering

CS1 - Innovative chemistry reduces the environmental impact of mining and pharmaceutical manufacture

Summary of the impact

The technology in this impact study is based on organofunctionalised silica materials that can address market needs for high purity in compounds that underpin many areas of the pharma, electronic and medical sectors as well as the recovery of limited resources such as precious metals that are used in diverse industries. Since the launch of the product portfolio in 2006, the materials have become embedded in purification or recovery steps in commercial production processes of leading mining (South Africa), pharmaceutical (UK) and petrochemical (Germany) companies and make a significant impact on the business of these companies as well as limiting waste of limited resources.

Submitting Institution

Queen Mary, University of London

Unit of Assessment

Chemistry

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Inorganic Chemistry, Organic Chemistry, Other Chemical Sciences

Fabrication of 3D electro-optic circuits by printing (FAB-3D)

Summary of the impact

Prof Silver's research on the development of the technology to fabricate 3D electro-optic circuits via ink-jet and screen printing has provided a more sustainable solution to conventional back-lit posters (energy saving up to 75%) and printed displays. Due to the flexibility of the components (they can be printed in any shape or design) and low maintenance (battery operational), the technology has been commercially exploited by several industrial collaborators. Johnson Matthey have used Brunel research to gain knowledge of the market and supply chain, to sell silver and palladium nano-particles for ink-jet printing and to inform the investment of around £2M on R&D in this area. Intrinsiq Materials Ltd successfully marketed copper-based inks for ink-jet printing of ACEL displays, allowing the company to employ 22 additional staff. In addition, they have secured $4M of venture capital investment to develop the technology. Printed Electronics Ltd have secured £8.6M of investment to develop a high-volume supply chain for printed electronics, and have employed an additional 9 staff within the company. As a result of working with Brunel, Keeling and Walker have begun to sell ink that contains antimony-doped tin oxide nano-powders.

Submitting Institution

Brunel University

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Macromolecular and Materials Chemistry, Physical Chemistry (incl. Structural)
Engineering: Materials Engineering

Realising innovative and adaptive product design and optimisation through an integrated materials and modelling system

Summary of the impact

The investigators of this impact case study have utilised their expertise in materials engineering, theoretical/numerical modelling and product development to achieve significant economic, social and environmental impacts in a range of fields through developing a systematic methodology for innovative product design and optimisation. Through several industrial projects and collaborations, significant impacts have been witnessed including new products creating several million pounds in revenue annually for businesses in different sectors and green manufacturing technologies in repair and reclamation of components. All the described impacts were results of investigation in the Mechanical Engineering and Materials Research Centre (MEMARC) over the assessment period.

Submitting Institution

Liverpool John Moores University

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Analytical Chemistry, Macromolecular and Materials Chemistry
Engineering: Materials Engineering

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