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Yield of valuable biomass fibre components and their utilization in the food industry has been maximised by novel, cost-effective and environment-friendly plant fibre extraction methods developed by BEAA. Specifically, application of these methods enabled patenting and commercialisation of oat fibre extraction by the Swedish company BioVelop, directly resulting in commercial impact through international sales of five nutritional products released since 2010. The most successful of these is produced at a quantity of 180,000 kg, or € 600,000 per year. In May 2013, world-leading food-additive giant Tate & Lyle took over BioVelop, securing the success and lasting commercial impact of the BEAA technology.
This case study describes interdisciplinary impacts developed from research of the Sustainable Energy theme. They examine conversion of energy from alternative sources; from power generation using pyrolysis or biomass burners to energy harvesting of waste heat from electronic components. In all cases the aim is clear: to develop systems that make sustainable energy production a reality. This has important impacts in advancing efficiency and reliability in renewable energy technologies. Importantly, through a number of externally funded projects, this group's members have directly influenced local, national and international companies and governmental bodies. In some cases influencing decisions and having direct impact on efficiency, value from investment and even on balance sheets. In summary, they have conducted numerous energy audits, produced a minimum of 6 best practice case studies, influenced the renewable strategies of at least 52 countries, regions or industries and are recognised as the centre for biomass fuel quality assessment.
The demand for biofuels and alternative energies is increasing globally as a sustainable source of energy is sought for the future. Energy from crops is no longer a viable option due to the increase in wheat prices. Scientists at the BEST Research Institute have managed to bridge the gap by using novel and unique microwave systems for converting waste (biomass, food, animal) into energy. Our advances in this area have generated considerable interest from both national (e.g., United Utilities PLC, Balfour Beatty PLC, Biofuels Wales Ltd, Stopford Projects Ltd, Longma Clean Energy Ltd) and international (e.g., RIKEN-Japan, Fraunhofer-Germany, Sairem-France, Acondaqua-Spain, Ashleigh Farms-Ireland) companies. This has resulted in several collaborative, funded projects leading to industrial adoption of our microwave technologies.
The research led by Dr Convery and Dr Weatherall with other staff members within the unit represents a diverse body of work around the practicalities, implications and uptake of land management to mitigate climate change, particularly through application of biomass based renewable energies and also through carbon sequestration. The group have influenced practitioners (particularly within the forestry and farming sectors), community groups developing renewable energy projects, small to medium enterprises (SMEs) involved in renewable energies, and other non-governmental stakeholder organisations, such as the Lake District National Park.
The University of Southampton's pioneering research into energy harvesting has produced proven economic impacts together with impacts on public policy and international standards. Perpetuum, a spin-out from Southampton employing 10 people locally, has attracted £9.6 million in venture capital and developed the world's leading vibration energy harvester. Perpetuum's harvesters are enabling the deployment of zero maintenance, battery-free wireless systems in the rail industry where the technology has revolutionised bearing monitoring. This has enabled, for the first time, real-time monitoring of rolling stock, leading to cost savings, improved reliability, efficiency and safety. Their systems have been deployed on 200 trains across the UK (Southeastern) and Sweden (SJ AB). Southampton's research has driven wider industrial uptake of the technology and Perpetuum's is also the only energy harvester approved for use with the worlds leading suppliers of wireless condition monitoring equipment (GE Bentley Nevada, National Instruments and Emerson). Promotion of the technology has led to a £1.25 million TSB competition on energy harvesting and Southampton researchers are assisting in the development of international standards and increasing public awareness of the technology.
Developing renewable sources of energy has to go hand in hand with reducing energy demand through increased energy awareness and behavioural change. To this end a multidisciplinary consortium of researchers, led by Professor Christopher Howe (Biochemistry), have developed several biophotovoltaic (BPV) devices for off-grid electricity generation, and as educational tools. This has resulted in impact on commerce (i.e. the acquisition of a BPV spinout company by Ortus Energy Ltd in 2009 through share exchange), on society and culture (an award-winning `Moss Table' developed by the consortium, which incorporates BPV technology, has been exhibited internationally since 2011 and has received extensive international media coverage) and on educational practices (a prototype BPV educational tool for schools has been developed by Howe and colleagues in 2013 and trialled with 6th form students).
Over the past 10 years there has been a massive expansion in biomass use for power generation, particularly in the UK and Europe. Research at the University of Leeds has been crucial in addressing many of the challenges inherent in moving from coal to biomass including milling, combustion characteristics, deposition and corrosion enabling adoption of biomass for power generation. The research has impacted: (1) company strategy and industry practice for the use of biomass and key technology choices; (2) society, health and environment via CO2 reduction and emission reduction; (3) national energy security through an increased fuel inventory; (4) UK Government and EU policy as expert members of advisory groups.
Research conducted at the University of Cambridge under an EPSRC grant between 1999 and 2002 established the viability of using microwave induced pyrolysis as a process for recovering clean, elemental aluminium and hydrocarbon liquids and gases from waste laminate packaging, thus preventing the need to send this material to landfill. The research has been commercialised by Enval Limited — a multi-award-winning University spin-off founded in 2006 that has attracted approximately £2M funding during the REF period and employs 7 people. A pilot scale unit has been operational since 2011, and the first commercial-scale unit has been constructed and has operated since April 2013.
The field of conceptual chemical process design as practiced industrially has been influenced significantly by the outputs from the Centre for Process Integration (CPI) at Manchester. Process Integration Ltd (PIL) was spun-out from Manchester and currently employs over 50 staff globally, who have conducted projects that have resulted in annual cost savings of hundreds of millions of US dollars. The application of CPI technology has led to significant reductions in both energy costs and emissions of greenhouse gases. Since 2008 ca. US$350m of savings have been realized through the exploitation of CPI technology with US$1.4m generated from software sales.
Reducing vehicle noise and vibration is a key quality objective in the automotive industry. Historically, the approach has been costly palliation late in the manufacturing process; now a new approach applied earlier in the vehicle development cycle has been devised by Loughborough University and Ford and implemented at Ford that has led to savings of $7 per vehicle with respect to clutch in-cycle vibration (whoop). Ford has reported savings of $10M over 5 years, whilst reductions in transmission rattle have led to 5% fuel efficiency gains [5.1]. Ford has made an investment of £240M in its engine and transmission work at Bridgend, which includes aspects of work reported here and has created 600 new jobs [5.2].