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Research conducted by Professor Short in the use of natural ventilation and passive cooling in non-domestic buildings is altering policies and plans in the refurbishment of existing healthcare buildings and in new-build for acute and primary care, both within and outside the UK. Moreover, the massive demolition and replacement of healthcare building stock, presumed to be required to simultaneously adapt to the increased ambient temperatures due to climate change and mitigate carbon emissions through improved energy efficiency, has been shown to be unnecessary.
University of Nottingham research into the use of natural lighting and ventilation in building design has resulted in the development, marketing and application of two new sister products (SunCatcher and Sola-Vent) by a leading supplier of low-carbon, low-energy solutions. Since 2008, 745 installations of Sola-Vent units have been carried out by Monodraught Ltd. Homes and commercial premises, both in the UK and overseas, have benefitted from the low energy demands of the system. As well as delivering economic benefits for the company, this work has had a positive impact on building owners and occupiers and the wider environment.
Alliance researchers have demonstrated that it is possible to refurbish existing buildings, which make up over 90% of our stock of over 26m buildings, to achieve a reduction in CO2 emissions of up to 80% (domestic properties) and 50% (non-domestic). The research has underpinned a shift of emphasis by UK government from new to existing buildings and the formulation of incentives to encourage building owners to make energy-saving improvements. In partnership with not-for-profit, public and private stakeholders, it has been used by national and local agencies to highlight the potential of improving the energy performance of traditionally constructed, timber-framed and residential mobile homes and incorporated into practical guidance by the Chartered Institution of Building Services Engineers. It is also the technical foundation for an educational software package developed with 100 school children and teachers and praised as exemplary by Education Scotland.
Ground-breaking research in the field of Dynamic Insulation (DI) at Aberdeen University has contributed to international efforts to combat climate change through the reduction of the carbon emissions associated with the heating, ventilation and air conditioning of buildings. Through the establishment of a spin-out company and the development of the world's first modular DI product, jobs have been created and developers have been able to use the first commercially available DI products and systems to meet strict new environmental targets. The success of such projects has led to greater public awareness of the issues around global warming.
Research at Loughborough University during the period 2008-2013 in the areas of control, commissioning and design of advanced naturally-ventilated buildings has led to:
A subsequent KTP project with SE Controls has led to:
Research by staff of the Energy Systems Research Unit (ESRU) at Strathclyde has resulted in advances in the state-of-the-art in dynamic building energy modelling as encapsulated within the Open Source ESP-r program. This new capability enabled practitioners to analyse phenomena and technologies hitherto not capable of being modelled in building simulation tools. The impact stems from the embedding of ESP-r within companies resulting in service improvement and job creation, and applications of ESP-r resulting in energy demand reduction, low carbon energy systems integration and environmental impact mitigation.
The Thermal Comfort Unit at Oxford Brookes University has, since its formation in 1992, been a world-leader in developing, applying and promoting the adaptive approach to thermal comfort and energy saving in buildings. Developed by Professor Humphreys and Professor Nicol, the adaptive model treats thermal comfort as a self-regulating system, placing human thermal behaviour at the centre of the system. The Unit, now part of the Low Carbon Building Group, has had a profound influence internationally on the way of thinking about comfort, and its research findings have been embodied in national professional guidance for building services engineers, influenced international standards bodies as well as developing global networks.
The Welsh School of Architecture (WSA) is recognised internationally for its research in developing advanced computational numerical models for simulating the energy and environmental performance of the built environment. These models have been used by leading design practices in the design of major buildings and urban developments. This impact case study presents three models from this research activity that have been widely taken up by industry worldwide, namely, the `building energy' model HTB2, the urban scale `energy and environment prediction' framework EEP and the `building environment' model ECOTECT.
Application of the models, often linked (e.g. HTB2 is the numerical engine for EEP and is accessible within the ECOTECT framework), has resulted in extensive environmental benefits, through reductions in global CO2 emissions. Additionally, there has been a marked impact on practitioners and professional practices, through new guidelines for major international developments (e.g. Pearl Island Qatar and the Chongqing Ba'nan Low Carbon Development).
Research at the University of Nottingham into the use of phase- change materials as a means for heating and cooling buildings has resulted in the development of COOL-PHASE®, a product which is sold by Monodraught ltd. The system was launched in 2008 and has been installed in 136 buildings in the UK. COOL-PHASE® underpins the long-term growth strategy for the company and Monodraught has invested in employing 3 new staff and £250k in capital expenditure to make the unit suitable for mass production.
Prof Kolokotroni's research confirming unusually high night-time temperatures in London due to the urban heat island effect, and her recommendations to mitigate this effect, have both industrial and political impacts. As 80% of current buildings are expected to be standing in 2050, her assessment of the environmental benefits of cool roof technologies (highly reflective, well-insulated roofs) have provided affordable and practical solutions for politicians and building engineers: in 2009, the European Cool Roofs Council was launched at Brunel, committing to advocating cool roof products for their impacts on mitigating climate change, reducing the urban heat island effect. In 2010, the Greater London Authority, in the `Climate Change Adaptation Strategy for London', committed to assessing and promoting cool roof technologies in London.