Log in
Nanoforce Technology Ltd. is a spin-out company wholly owned by QMUL, active in the field of polymeric and ceramic materials. Bridging the gap between academic research and industrial applications, Nanoforce has done business with over 100 companies since 2008, providing the key research expertise and specialist facilities to enable the development of new materials and commercial products, including Sugru® a room temperature vulcanizing silicone rubber, Zelfo® a self-binding cellulose material, and BiotexTM a range of high-performance yarns, fabrics and pre- consolidated sheets based renewable resources such as PLA and natural flax fibres. Nanoforce has been promoting the development and commercialisation of spark plasma sintering (SPS) since 2006, which resulted in Kennametal recently opening the first commercial SPS facility in the UK to produce advanced ceramic armour. Nanoforce's clients have included large multi-nationals such as DSM, Dow Chemical, General Electric, SABIC, L'Oreal, Shell, Sibelco, governmental agencies such as Defence Science and Technology Laboratory (Dstl), and a large number of SME's.
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.
The Thin Film Centre (TFC) group at UWS pioneered thin film materials and processes for plastic electronics with Dupont Teijin Films (DTF) Ltd and Plastic Logic (PL) Ltd over a period of nine years. This work was pivotal to the growth of PL from a start-up position resulting in the first all-polymer e-book reader and was the basis of a world leading position in the supply of specialised substrates for DTF Ltd.
The development of disentangled, ultrahigh molecular weight polyethylene at Loughborough University since January 2007 has provided an environmental friendly route to the manufacture of high modulus, high tensile strength tapes with applications ranging from body armour to helmets, ropes and cables. Commercialisation is being undertaken by the Japanese company Teijin, in the Netherlands, under the brand name Endumax®. The new business, started in 2011, now employs >80 staff and predicts annual sales of >€15M from 2014 with an increase of ~10% over the first five years. Competitors such as Du Pont (Tensylon®) and DSM (Dyneema BT10®) have also initiated development of products using the new process route.
Workers at the University of Leeds researched, then developed and patented the `hot compaction' process for the manufacture of single polymer composites [1]. In this process highly oriented polymer fibres are heated so that a proportion of the surface of every oriented element melts. Upon cooling, this skin recrystallises to form the matrix of a self-reinforced fibre composite. Important resultant properties include high stiffness and strength, lightweight and outstanding impact strength, leading to a material with crucial commercial advantage. The reach of this impact is demonstrated by commercialisation of the polymer composite over a wide range of applications including anti-ballistic body armour, sports goods (Nike, Bauer), lightweight luggage (Samsonite), audio speakers (Wharfedale) and radar covers for helicopters (Westland). Examples include Samsonite using the material Curv® to manufacture two new high profile product ranges (Cosmolite and Cubelite) and Bauer using it in their elite-level ice hockey skate range (SUPREME and VAPOR).
A manufacturing process developed by Bradford researchers has revolutionised the way endodontists perform root canal treatments. When coated with a hydrophilic polymer, the highly-filled hygroscopic material has enabled UK company DRFP to develop SmartPoint — a new endodontic technique that dramatically reduces failure rates of root canal treatments from 11-30% over five years to approximately 1%, and gives lower levels of post-operative pain when compared with conventional techniques. The technology has won three awards for innovation and DRFP has expanded significantly, with a dedicated production facility and sales team offering visits to dentists to demonstrate the benefits of the technology.
The Leicester Variwave project, in relation to electrostatic dust precipitation, utilises a novel high voltage, high frequency, high power transformer within the power supply, which has enabled cuts in industrial emissions of ~50 per cent and considerable cost savings. Most new-build power stations and many other industrial sites now use technology based on that developed in Leicester. As well as fly ash and dust, the technology has the ability to trap sub-micron particulates thought to be partly responsible for the increase in the number of asthma cases during the past few decades. The MD of [text removed for publication] states `Through publications made by ...Leicester ...we were interested to learn how the team designed their high voltage transformer, and how that transformer operated with the high frequency, high power switched-mode electronics. They achieved that `Holy Grail' combination [of high voltage, frequency, high power] in a 70 kW switched-mode power supply (SMPS) running at 20 KHz and at 50 kV. The publication in the IEEE Transactions on Power Delivery was very helpful, and enabled us to choose the direction when pushing the design boundaries in developing our own high power, high voltage technology for electrostatic precipitators'. Dr Devine, a key member of the Leicester team between 1995 and 2000, was employed by [text removed for publication] in 2001 purely on the basis of his knowledge of Variwave. [text removed for publication] now have 200 units in operation. In 2002 Dr Devine was head-hunted for his knowledge of Variwave and moved to [text removed for publication], who also developed commercial units. The uptake of the technology has been growing steadily since 2001. Exemplar data from one company on the associated reduction in emissions shows 195 switched mode power units installed in boiler plants worldwide by 2004 gave a reduction of around 60%. A 60% reduction in emissions is equivalent to a reduction from 40 mg.m-3 to 16 mg.m-3 of flue gas particulates. Since 2004 to date there are now estimated to be at least 5000 units installed worldwide.
A significant body of research in ultrasonics at the University of Strathclyde led to the formation of Alba Ultrasound Limited in 2000. This successful UK engineering manufacturing company designs and manufactures high quality wideband ultrasonic array transducers for sonar applications to a worldwide client base, delivering benefits ranging from naval and maritime security through to safer ocean environments and informed exploitation of marine resources. Alba Ultrasound's unique array transducers constitute the sensor front-end in many leading sonar systems, and its innovative products are incorporated in a range of sonar devices used by the military and commercial companies. Through application of Strathclyde research, the company has experienced a significant period of growth during 2008-2013, with a three-fold increase in employees and turnover rising from £750k to £3.8M.
The impact presented in this case study is the commercialisation of 15 products with perfume microcapsules by Procter and Gamble (P&G), made possible using capsule mechanical strength data provided by Prof Zhibing Zhang's research group at Birmingham. Use of microcapsules gives improved freshness performance, and thus commercial advantage, compared with traditional formulations; they have been incorporated in P&G's four major billion-dollar brands — Downy, Febreze, Lenor and Tide. This has significantly improved their competitiveness enabling P&G to retain their leading position in the USA and Western Europe. A novel micromanipulation technique developed at the University of Birmingham has been used extensively to obtain mechanical properties data for the micro-particles, including microcapsules prepared in Birmingham and provided by companies, which is related to their formulation and processing conditions and end- use performance. In addition, the knowledge generated has helped 15 other companies to commercialise new functional products containing micro-particles.
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.