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SmartPoint: dramatically reducing the failure rate of root canal treatments in orthodontistry

Summary of the impact

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.

Submitting Institution

University of Bradford

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Health

Research Subject Area(s)

Engineering: Manufacturing Engineering, Materials Engineering, Interdisciplinary Engineering

Economic impact through improved product and process development within Carron Phoenix.

Summary of the impact

Initial research into polymer nanocomposites and their formation took place at Strathclyde from 2000 - 2010. This was followed by a collaboration with the world's largest manufacturer of composite kitchen sinks, Carron Phoenix Limited, through a 6-year Knowledge Transfer Partnership (KTP) which resulted in a successful new production process of its high-end synthetic granite kitchen sinks. This led to £4 million of capital investment in new production facilities at their Falkirk site, enabling the company to sustain its leading position in the designer kitchen sink market and retain its workforce of over 400 employees in central Scotland, including the 170 workers in the composite sink division in Falkirk. Within the REF period, the research has led to the manufacture and sale of in excess of one million kitchen sinks, generating sales revenue in excess of over £50M and supporting the UK economy.

Submitting Institution

University of Strathclyde

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Chemical Engineering, Materials Engineering, Resources Engineering and Extractive Metallurgy

Expertise in die drawing of polymers leads to new materials, new manufacturing processes, new products and a new company

Summary of the impact

Research into die drawing of polymers at Bradford has resulted in a new building material that is stronger and more durable than wood; and new bioresorbable shape-memory polymers for use in medical implants that reduce patient trauma and costs. The wood replacement material is commercialised by the United Forest Products/Dow USA 2010 spin out company Eovations LLC for use in a range of construction applications; the bioresorbable shape-memory polymers have recently been patented (4 patents filed) by Smith & Nephew for use in soft tissue fixations. These impacts form part of a range of exploitations of our oriented polymer technology.

Submitting Institution

University of Bradford

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Macromolecular and Materials Chemistry
Engineering: Materials Engineering

Industrial take-up of advanced manufacturing process for nanomaterials

Summary of the impact

Research at Kingston University into the use of flame spray pyrolysis (FSP) to manufacture metal oxide nanoparticles has resulted in the creation of an industrial FSP nanoparticle production line. This achieves production rates an order of magnitude higher than was previously achievable, while allowing particle size to be controlled at the same scale as existing small FSP processes.

TECNAN, a Spanish SME, established in 2007, that manufactures and sells nanomaterials on the international market, has used this production line to produce a range of nanoparticles for commercial customers, for use in a wide range of applications. As well as allowing a broad product range to be offered, the production line also achieves a cost reduction of over 30% compared to previous manufacturing methods.

Submitting Institution

Kingston University

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Interdisciplinary 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

Surrey NanoSystems: Meeting the International Technology Roadmap for Semiconductors

Summary of the impact

Surrey Spin-out Surrey Nano Systems (SNS) is a business based around key patents resulting from the work of Prof. Ravi Silva and his team. SNS has raised over £11M from investors who have scrutinised the technology and recognise its value. The business develops technologies for low-substrate-temperature growth of carbon nanotubes (CNTs) and for novel low-k dielectric materials both of which align with the International Technology Roadmap for Semiconductors (ITRS). SNS is working closely with multinational leaders and has attracted a team that includes senior management experience of selling into the semiconductor process equipment market.

Submitting Institution

University of Surrey

Unit of Assessment

Electrical and Electronic Engineering, Metallurgy and Materials

Summary Impact Type

Technological

Research Subject Area(s)

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

Multi-million pound sales and efficiency gains through formulation development and process optimisation

Summary of the impact

Significant economic impact was achieved as a result of research into polymer nanocomposites and their formation, conducted at WestCHEM from 2000 to 2010. Collaboration over the six-year period 2004-2010 with Carron Phoenix Ltd, the world's largest manufacturer of composite `granite' kitchen sinks, led to nanocomposite technology being incorporated into over one million sinks, generating income for the company in excess of £50M from 2007 to the present day. Considerable production efficiency gains saved in excess of £1M annually through the reduction in manufacturing time, the reduction of raw materials wastage, and the reduction in landfill costs (and commensurate environmental benefit) for failed and out-of-spec products. In addition, a £4M capital investment by the company at the Falkirk plant was secured, enabling the company to sustain its leading position in the designer kitchen sink market. With the site consequently designated as the parent company's competency centre for composite sink technology, employment for 170 workers was secured.

Submitting Institutions

University of Strathclyde,University of Glasgow

Unit of Assessment

Chemistry

Summary Impact Type

Technological

Research Subject Area(s)

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

Affordable Diffusion Bonding (ADB) of laminate sheet to produce micro-cellular structures relevant for ultra-lightweighting and high efficiency thermal and chemical devices for the aerospace, automotive, medical, chemical manufacturing sectors.

Summary of the impact

Diffusion bonding (DB) is well-known for producing structured materials with fine scale features and is a critical technology for high efficiency reactors, e.g. heat exchangers and fuel cells, but currently equipment is slow and expensive (and there are size limitations to the `assemblies' that can be built). The University has researched and developed, with industry partners, a rapid affordable diffusion bonding (ADB) process involving direct heating to provide appropriate temperature and stress states and utilising flexible ultra-insulation (vacuum) for pressing titanium (and now aluminium) sheets together. The process operates at low stresses thus avoiding `channel' collapse. Investment is taking place in the partner companies to exploit the technology. A breakthrough has been achieved in the chemical machining of three dimensional structures for laminar flow technology assemblies in aluminium and titanium, that can be built by ADB.

Submitting Institution

University of Wolverhampton

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Manufacturing Engineering, Materials Engineering

The development of lightweight, high-impact-resistant polymer composites with wide-ranging commercial applicability

Summary of the impact

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).

Submitting Institution

University of Leeds

Unit of Assessment

Physics

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Macromolecular and Materials Chemistry
Engineering: Materials Engineering

New Bottle Manufacturing Technology leads to Energy and Material Savings

Summary of the impact

Multinational companies [text removed for publication] have saved more than 20,000 tonnes of plastic and $10M in less than 4 years, using QUB technology to develop their innovative lightweight plastic bottles.

This has created both economic and environmental impact through the savings in material, transport and energy costs and a reduction in CO2 usage. For example the [text removed for publication] showed savings per year of €3M and 1800 tonnes of plastic and a reduction of CO2 of 800 tonnes/year.

A spin-out company, built on this technology, was created in 2012 and is actively selling process instrumentation (THERMOscan) to both USA and EU customers enabling them to make further reductions in material and energy usage. The product won a clean energy award in 2011.

Submitting Institution

Queen's University Belfast

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Analytical Chemistry
Engineering: Manufacturing Engineering, Materials Engineering

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