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This case study is an example of the impact of the ERC, which specialises in furnace and utility boiler modelling and monitoring through research in collaboration with European Industrial partners. Modelling work primarily based around the zone method and physical acid-alkali modelling has led to significant NOx reductions (50%+) for the glass melting process and this work is currently being demonstrated on the furnaces of Owens Illinois and SiseCam. The monitoring work has demonstrated that by monitoring spectral information from individual flames it is possible to reduce NOx emissions from utility power station burners by as much as 40%.
A US$1.5 billion clean coal project at the YiHe Coal Field in Inner Mongolia was established in June 2011 as a joint venture between UK based Seamwell International Ltd and the state-owned China Energy Conservation and Environmental Protection Group. This is the first commercial project to employ the novel "Linear UCG Gasifier" design developed specifically for use under extremely weak underground roof conditions by Durucan, Korre and Shi at Imperial College London. Underground gasification under such conditions is made possible solely because of the novel gasifier design, which has opened up the potential to transform over 720 million tonnes of coal resource, that would otherwise have remained trapped, as a clean coal energy source for the next 20 years.
Instrumentation technologies developed at Kent, in particular pulverised fuel flow metering, on-line particle sizing, on-line fuel tracking and burner flame imaging, have enabled combustion engineers to diagnose large-scale complex combustion processes and optimize the operation of coal, biomass and heavy-oil fired power plants. The technologies operate on novel sensing and advanced measurement principles and have produced real-time measurement and plant condition monitoring data that were previously unavailable. Instrumentation systems operating on the technologies have been applied successfully to a range of pilot plants and on full-scale power plants in countries including the UK, France, China and Saudi Arabia. Work has enabled the power industry to produce electricity safely while minimising environmental impact and employing a diverse range of fuels. The instrumentation technology informed the conversion of Drax power station from 100% coal firing to biomass/coal co-firing during 2011/2012 as it sought to halve its carbon footprint within five years. The technology sourced and informed the alleviation of significant vibration problems within a heavy-oil fired power plant in Saudi Arabia.
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.
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.
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.
A €470 million earth observation mission (BIOMASS) based on research carried out in the University of Sheffield's Centre for Terrestrial Carbon Dynamics was approved by the European Space Agency Programme Board on 7 May 2013, for launch in 2020, to measure the biomass and height of the Earth's forests, globally, at a scale of ~200 m. The twenty European member states have committed contributions to fund the mission, representing a significant reallocation of public budgets. The mission was selected as the most scientifically convincing of the six initially shortlisted in 2005 (further down-selected to three in 2009), and is the only one that will be funded. The project has already led to two European industrial consortia receiving some €5.6 million for studies to demonstrate feasibility. A further €277 million of the €470 million approved funding has been specifically earmarked for industrial spending to prepare for the mission.
The impacts from over 20 years bioenergy research at Aston University, have been through influence and support for businesses to generate and use environmentally advantageous sources of power, fuels and chemicals. Pilot scale systems that exploit pyrolysis and gasification of biomass residues and renewable feed-stocks are operational. The EU, UK and local governments have developed policies with the Unit's advice on the potential of bioenergy for power generation and waste reduction. Technical and business advice have been provided, a new company formed, investments made in new business directions by SMEs and large multinational companies. This has generated new employment opportunities in consultancy, design and manufacture of systems, social and environmental benefits, along with greater public awareness.