UKERC EDC: Landscapes

Author		Prof Bob Lowe University College London (UCL) with assistance of Dr Jim Halliday STFC Rutherford Appleton Laboratory
Last Updated		30 April 2014
Status		Peer reviewed document
Download Landscape		PDF 545 KB

Section 1	Overview	Section 6	Research Facilities and Other Assets
Section 2	Capabilities Assessment	Section 7	Networks
Section 3	Basic and applied strategic research	Section 8	UK Participation in EU Activities
Section 4	Applied Research and Development	Section 9	International Initiatives
Section 5	Demonstration Funding

Section :

Characterisation of the Field

The design, production, management and operation of buildings involve complex socio-technical processes. Buildings represent a crucial element of energy systems at all scales from local, through national to continental. Buildings and the wider built environment are key determinants of human health and quality of life. Buildings and their supporting infrastructures shelter, protect and structure almost the whole of our individualand collective lives, and the working lives of hundreds of thousands of people are devoted to their design, production, management, operation and occupation. Interactions between people and physical systems in the built environment are complex, and take place at all of these stages. As a result, energy use in buildings is a complex field of study involving many disciplines: the STEM (science, technology, engineering, and mathematics) disciplines, the professional built environment disciplines (building services engineering, architecture, construction management, surveying), the social and human sciences including economics and psychology, and a range of disciplines associated with human health. Key phenomena, such as “takeback”, give rise to multiple competing hypotheses and interpretations, which can only be resolved by interdisciplinary working.

Energy efficiency is defined by the International Energy Agency (IEA) as follows: “something is more energy efficient if it delivers more services for the same energy input, or the same services for less energy input.” This apparently simple formulation conceals deep problems of definition, measurement and evaluation, commensurability, intertemporality, contingency and disciplinary perspective. Garrett Hardin s first law of human ecology “you can never do only one thing - applies throughout the study of the built environment.

Thetask of improving energy efficiency in the built environment is dominated by context- and process-bound problems that arise from the deployment, as opposed to the initial development of technology. This domination is likely to increase as the UK moves towards the large-scale deployment of energy end use technologies through mechanisms such as Green Deal. The Green Deal indirectly stimulated fundamental research on U valuesby revealing the weakness of U value assumptions built on work done decades ago, with different equipment, different analysis techniques and for different purposes. This illustrates how high-value scientific problems can arise from the policy-driven deployment of interventions.

The Research Councils most directly involved with energy demand in buildings are the Engineering and Physical Sciences Research Council (EPSRC) and theEconomic and Social Research Council (ESRC). The Technology Readiness Level (TRL) model used by EPSRC to define its own role leaves little room for it to engage with the complex and multi-layered RDD&D process in the Built Environment. Hitherto this has meant that much research in this area has been funded, not by Research Councils, but by Technology Strategy Board (TSB) and Energy Technologies Institute (ETI) and their predecessors, and by charities and agencies, such as Historic Scotland, English Heritage, and the Society for the Protection of Ancient Buildings (SPAB) (who have funded much of the recent fundamental work on solid wall U values) with interests in the area. Until the mid-1990s, the directly-funded Building Research Establishment and energy industry research centres were also major providers of built environment research. Since privatisation, this work has declined or ceased, resulting in both a loss of capacity and much-diminished access to the results of research undertaken historically by these organisations.

One of the factors that impedes progress in this area is the mismatch between the comprehensiveness of the system established by Research Councils UK (RCUK) Research to report research outcomes, and absence of such systems for other funding bodies. The Research Outcomes System (ROS) is a web-based system through which the holders of grants awarded by AHRC, BBSRC, EPSRC, ESRC, NERC and NC3Rs are required to report the research outcomes resulting from those grants. Information reported to ROS is used to demonstrate the impact of research funding to Government, and is being made publicly available through Gateway to Research. The reporting of research undertaken for other organisations is generally less consistent and rigorous. This mismatch can lead to a situation in which researchers funded predominantly from RCUK resources may be unaware of work taking place with other sources of funding.

Research Challenges

To do justice in a few pages to the full spectrum of research in support of Energy Efficiency in Residential & Commercial Buildings is impossible. The following is written primarily from a particular perspective building physics - and will inevitably omit important areas of work. The author’s hope is that readers will interpret this review generously, and in some cases make the connections to their own experiences of researching in this area.

This “Landscape Document” groups research challenges under 14 headings, ranging from Modelling to Translational Research. Modelling of energy demand of buildings is a major task involving physics, engineering, and built environment disciplines. At this point it is worth noting that the majority of delivered energy demand (but not exergy demand) in the built environment in the UK is due to heating. As a result, heat demand is a dominant theme in UK research. At its most basic, under the headings of Materials Science, and Building Technologies and Systems, there is significant research into insulants and insulation systems though a great deal of this work is undertaken by industry and much is based outside the UK. Modelling has been dominated for most of the last three decades by heat.

A very significant, two-pronged effort was made in this area in the 1980s. The first was coordinated by the IEA, with significant support for UK researchers from EPSRC (then known as the SERC), and focused on the development and comparison of dynamic thermal simulation packages. The initial driverof this work was the desire to understand the performance of passive solar buildings (see Balcombe,1992 for a discussion of the early work on passive solar from a US perspective), but the approach and the software packages that were developed have found a much wider range of uses over the subsequent decades. The second effort was spear-headed by the Building Research Establishment, but with significant input from Chapman (Chapman, 1990) (basedat the Open University) and involved the development of the SAP-BREDEM family of static models of energy use, primarily for use in dwellings. Similar developments took place in other countries and an overarching framework subsequently emerged through CEN and ISO (ISO 13790).

Subsequent developments included computational fluid dynamics, to model air flow in and around buildings (and indeed, planets) and, in the last decade, combined thermal and moisture models, such as WUFI (in English, transient heat and moisture transport model). These models are likely to be central to the understanding of side-effects of insulating existing buildings.

Historically energy demand has been seen as technically determined. But the interaction of people with technical systems has over the last decade been recognised as crucial. This has led to a demand among research funders and policy makers for socio-technical models of energy demand in buildings, primarily as an aid to the development of policies and technical intervention strategies. Among the many problems faced by builders and funders of socio-technical models are the completely different languages used to describe technical systems and human behaviour. These differences are fundamental and will not be transcended easily. A broad level of knowledge on the part of research funders and major stakeholders of the disciplinary perspectives on energy demand and of the fundamental nature of the underlying processes will be essential to ensure that calls for research are well framed, and objectives are realistic.

Related to building models are stock models of the entire residential or commercial sector energy demand of a nation or region. Stock models typically rely on bottom-up models such as the UK’s SAP and USA’s EnergyPlus to combine measured or certified sub-system performance data based on laboratory measurements with a simple conceptual model of energy flows in buildings, to predict overall energy use. These models then estimate overall energy demand based on physical properties of buildings and systems. The problem of characterising new technologies and combinations of technologies,and representing the interactions between building fabric, systems, climate and people for the purposes of modelling is a profound one. Historically, predictions have been adequately close to performance, where this has been measured. This is less and less likely to be the case in the future. The problem is apparent even with a technology as simple as the condensing boiler. Technologies such as heat pumps, and the increasing number of buildings with multiple heat supply systems (condensing boilers and solar thermal), are likely to be even more vulnerable to systemic influences on performance. The difficulty of predicting behaviour of complex systems from sub-system performance suggests that in the future more reliance will need to be placed on empirical feedback on whole system performance from the field.

The study of the interactions between buildings and building systems and the rest of the energy supply system is an area of increasing importance, but one in which the growth of capacity lags. The UK has developed a significant capacity for energy supply system modelling through the Supergen Consortium and for whole system techno-economic modelling through the UK MARKAL/UK TIMES team. But use of physical modelling to understand the complex, multi-layered, dynamic interactions between systems such as heat pumps and the rest of the energy system is less developed. Some of the more interesting work has been done through consultancy.

All models depend on assumptions about the basic processes at work (in the case of building physics models, these start with the laws of thermodynamics), data and understandings (which, in the context of building physics, are expressed in the form of parameterisations) of the influence of wider system contexts. Recent results, particularly of convective bypasses in domestic construction and of solid wall U values, have reminded the research community of the vulnerability of all models to the absence of good empirical data and interpretation. As the demands on models increase, so the need for high quality empirical work will also increase. The lack of emphasis over the last three decades on physical measurement of buildings has left the UK capacity for such work significantly reduced. Conversely, advances in measurement and imaging technology, coupled with the ongoingIT revolution, have made it possible to undertake work more quickly, with greater precision and at significantly lower cost than ever before. The necessity of measuring performance and detecting and diagnosing unintended consequences of unprecedentedly large-scale interventions in the building stock sufficiently quickly to assist policy makers and the supply chain, presents both a huge challenge and a huge opportunity for the UK research community.

The systematic collection and analysis of data on energy use in buildings has become referred to as Building Energy Epidemiology. Energy Epidemiology is the systematic study of the distributions and patterns of energy use and their causes or influences in populations. It uses statistical association to impose top-down, constraints on bottom-up thermodynamics. It deals with the whole energy system as well as its sub-systems, focuses on outcomes such as reduced delivered energy or carbon emissions as well as intermediate performance indicators. It is interdisciplinary, facilitating and illuminating enquiry from the perspectives of economics and social science as well as thermodynamics. It will support the developments of technologies, changes in behaviour and policies and is action-oriented. Examples of the sorts of questions that the epidemiological approach can address include: what has been the empirical impact on energy demand of successive changes in Building Regulations over thelast two decades? And, what is the actual effect on energy demand of insulating existing dwellings?

There are numerous constraints on the practice of energy epidemiology. The approach requires access to large datasets on energy use and related factors. Much of this data is sensitive, and access to it has managed in a way that balances legitimate concerns over privacy and commercial confidentiality against the very large potential benefit to energy companies, policymakers and the nation as a whole. Using existing administrative datasets for purposes that they were not designed to support is likely to reveal quality control problems. Initiatives such as smart metering, have the potential to generate very much larger volumes of data than are currently available. All of these issues will need to be worked through over the coming decade.

We have already mentioned the importance of interdisciplinarity in this sector. Interdisciplinary working and trainingposes significant challenges for the individual researcher and research student, as well as for existing disciplines. Interdisciplinarity imposes significant additional learning requirements, requiring that researchers have at least “second-language” competence in disciplines other than their home discipline. Researchers who set out to cultivate breadth of understanding risk placing themselves at a competitive disadvantage compared with colleagues who have worked only within the confines of a single discipline. Critical disciplinary knowledge and insights risk being incompletely or incoherently transmitted to new cohorts of researchers. And yet, recent studies e.g. on deep retrofit, suggest the very high value of work that combines physical, process and social enquiry.

This is an appropriate point at which discuss the diversity of models for how buildings and energy research can support economic activity in the wider economy the National Importance agenda. Models and data are not necessarily the most important end-products of such research. Among other outputs are: the movement of highly trained people into industry, and the co-creation, with industry, and embedding of knowledge in industry, about how to make new and existing buildings more efficient. Action Research represents a collaborative tradition, in the UK going back to World War II, involving academia and industry using research methods directly, to address complexproblems in context. The potentially transformative capacity of Action or Intervention Research have been demonstrated by the Stamford Brook Project, which impacted directly on regulation and construction practice in the run up to the 2006 revision of the Building Regulations for England & Wales (Part L).

Despite its successes, the Stamford Brook project also revealed weaknesses, particularly around effective implementation of interdisciplinary working and capacity to undertake Action Research effectively.

Works Cited

Balcombe, D. J. (1992). Passive Solar Buildings. MIT.
Chapman, P. F. (1990). The Milton Keynes Energy Cost Index. Energy and Buildings, 14 (2): 82 - 101.

UK Capability	Area	Market potential
High	Building performance evaluation	Worldwide
High	Environmental rating systems	Worldwide
Medium	Translational research	Worldwide
Medium	Building physics	Worldwide
Medium	Building engineering	Worldwide
Medium	Building simulation	Worldwide
Medium	Building stock modelling - domestic	Worldwide
Medium	Building stock modelling - commercial	Worldwide
Medium	Whole system energy modelling	Worldwide
Medium	Human behaviour and social practices in buildings, including occupant-building interactions	Worldwide
Medium	Materials science	Worldwide
Low	Building technologies and systems	Worldwide
Low	Policy and regulatory system research	Worldwide
Low	Supply chain research	Worldwide

Programme	Funding Agency	Description	Committed Funds	Period	Representative Annual Spend
RCUK Energy Programme	RCUK	The RCUK programme focuses on energy-efficient processes for saving energy from domestic lighting and appliances. It also addresses the social and economic issues that influence how we use technology and how much we are prepared to pay for energy-saving products. It has number of collaborations with both public sector and industrial partners to ensure exploitation of energy efficiency research.	£39M for all activities	Ongoing
End Use Energy Demand (EUED) Research Centres	EPSRC, ESRC, industry	Five End Use Energy Demand (EUED) research centres, that look into the complexities of energy use across society and how energy can be both saved and used more efficiently, receive over £26 million funding from two research councils, the Engineering and Physical Sciences Research Council (EPSRC) and the Economic and Social Research Council (ESRC), and a further £13 million from industrial partners. The five centres, each funded for five years, are : RCUK Centre for Energy Epidemiology (CEE) - led by UCL. Centre for Sustainable Energy Use in Food Chains (CSEF) - led by Brunel University partnered with the universities of Manchester and Birmingham. UK Indemand - led by Cambridge University partnered with University of Bath, University of Leeds, Nottingham Trent University. DEMAND: Dynamics of Energy, Mobility and Demand Centre - led by Lancaster University partnered with the universities of Aberdeen, Birmingham, Leeds, Reading, Southampton, Sheffield, Sussex, Birkbeck College ,and UCL. Centre on Innovation and Energy Demand (CIED) - led by University of Sussex partnered with University of Oxford and University of Manchester.	£39 million	2013-2018
BuildTEDDI	EPSRC	The Research Councils’ Energy and Digital Economy programmes are seeking to support joint research projects concerned with the application of digital technologies to transform energy demand reduction within the envelope of a single building. BuildTEDDI (Transforming Energy Demand In Buildings Through Digital Innovation) follows on from the earlier TEDDI (Transforming Energy Demand Through Digital Innovation) programme. BuildTEDDI projects were launched in March 2012.	£6 million	March 2012-
Centres for Doctoral Training	EPSRC	EPSRC-funded centres for doctoral training provide a supportive and exciting environment for students to carry out a challenging PhD-level research project together with taught coursework. Includes the London-Loughborough Centre, focussing on the complex, multidisciplinary task of driving down energy demand and CO₂ emissions from the UK building stock.	£7.3M	2009-2018	£850K
UK Energy Research Centre Phase II	NERC	The UK Energy Research Centre (UKERC) is funded through NERC’s for the Towards a Sustainable Energy Economy (TSEC) programme, but with funding also coming from the EPSRC and the ESRC. UKERC carries out world-class research into sustainable future energy systems. It is the hub of UK energy research and the gateway between the UK and the international energy research communities. Energy Demand in Buildings is a sub-theme of the Energy Demand theme. In 2012, RCUK indicated that it would consider a bid for a 3rd round of funding for UKERC.	£4.3M for Energy Demand Theme	2009-2014	£850K
Cross-Discipline Interface	EPSRC	The cross-discipline interface programme aims to support the next generation of talented cross disciplinary researchers throughout their academic careers, identify emerging research and training opportunities at cross-disciplinary interfaces, fund transformative research at targeted cross disciplinary interfaces, and contribute to knowledge exchange between academia and users of cross-disciplinary research. This includes cross-research council projects such as Energy and Communities Collaborative Venture (with ESRC)		ongoing
EPSRC Fellowships	EPSRC	Academic fellowships are available for academics at three stages of their careers: postdoctoral, early and established career researchers. There are open calls via universities for proposals in pre-set areas, including energy.		ongoing
Information & Communication Technology	EPSRC	The ICT programme aims to bring information technology to energy building systems including human-computer interaction and research related to the digital economy programme.		ongoing
Infrastructure & International	EPSRC	In the area of energy research, these grants are for cross-disciplinary research with an international partner.		ongoing
Materials, Mechanical and Medical Engineering	EPSRC	The Materials, Mechanical and Medical Engineering programme seeks to improve understanding of the principles and practice of mechanical engineering. This involves the application of insight derived from the physical, computational, social and life sciences to the analysis, design, manufacture and operation of engineering systems. The programme has specific foci on mechanical systems, materials processing and medical engineering.		ongoing
Process Environment and Sustainability	EPSRC	This supports research and training in process engineering (the design, operation and maintenance of processes for chemicals and materials manufacture), the built environment, structural and ground engineering, water engineering, waste, pollution, and transport operations & management. The Programme also has responsibility for responsive mode support for energy.		ongoing
Public Engagement	EPSRC	This programme seeks pioneer new ways of stimulating research across disciplines and breaking down the barriers to multidisciplinary collaboration. Now known as Pathways to Impact.		ongoing
User-Led Research	EPSRC	Discretionary grants given to researchers on a one-off basis.		ongoing
People, Energy and Buildings	EDF/EPSRC	EDF and EPSRC have entered into a strategic partnership and Energy Efficiency/Demand Reduction in buildings is the first research area in which EDF and EPSRC are developing an activity. The research Councils Energy Programme (RCEP) and EDF have invested £4 million in a collaborative research programme in the general area of the social and economic sciences of energy efficiency in buildings.	£4M	2009-2013	£1M
Tyndall Centre Energy and Emissions Theme	Initially NERC, EPSRC and ESRC; now universities and grants	The Tyndall Research Centre opened in November 2000, with core funding from NERC, EPRSC and ESRC and with support from the DTI (now BIS). The Tyndall Centre has been one of the more significant developments in this area, with links to centres of expertise in the built environment (UMIST), climate science (Climate Research Unit UEA and Hadley Centre for Climate Prediction and Research) and social and political science (CSERGE, UEA). The Tyndall Centre Energy Theme is framed by the need for a sustainable energy transformation, and considers a multitude of issues and perspectives: from technologies and economies to behaviours and societies; from micro-scale to systemic; from retrospective to prospective; from mitigation to adaptation. The Energy Theme brings together natural and physical scientists, social scientists, engineers and economists to conduct interdisciplinary and policy relevant research.	The Centre was funded by Research Council grants until 2010, now funded by the participant Universities, and specific project grants	2000 -

Name	Description	Sub-topics covered	No of staff	Field
De Montfort University: Institute of Energy and Sustainable Development (IESD)	The Institute employs a multi-disciplinary team of Professors, Lecturers and Researchers - supported by higher degree students - who are respected internationally for the quality of their work. Their disciplines range from mathematics and physics, through engineering, to economics, sociology and psychology. This enables them to lead multi-disciplinary projects that address environmental, economic and social research problems.	People and Energy Sustainable urbanism	10 faculty, 15 researchers, 18 PhD students	Geography and Environmental Sciences
Imperial College: Digital Economy Lab	Through connecting citizens, business and government to real-time intelligence and enabling ‘smart’ decision making, the Digital Economy could revolutionise almost every aspect of our everyday lives leading to better monitoring and controlling of infrastructure to reduce CO₂ emissions and waste.	People and Energy	2 faculty, 3 researchers, 3 PhD students	Business and Management Studies
Department of Sociology and Lancaster Environment Centre Lancaster University	Department of Sociology: Current research includes examining the relationship between consumption, everyday practice and ordinary technology. Leads the EUED DEMAND: Dynamics of Energy, Mobility and Demand Centre - partners include the universities of Aberdeen, Birmingham, Leeds, Reading, Southampton, Sheffield, Sussex, Birkbeck College ,and UCL. Lancaster Environment Centre: Special interests : how energy is related to notions of need, rights and justice; on the work of energy managers using energy management and control systems; on the dynamics of energy use in everyday life	People and buildings		Sociology
Loughborough University: Civil and Building Engineering	The civil and engineering department of Loughborough University specialises in energy efficiency and low carbon technologies for the built environment. The department centres on the understanding of energy use in buildings as a science discipline.	Sustainable construction Buildings energy modelling Energy monitoring HVAC systems development	23 faculty, 28 researchers, 44 PhD students	Civil Engineering
Environmental Change Institute, Oxford University	The ECI work on energy concentrates on understanding the links between social and individual behaviour, technologies, policy formulation and markets. It is organised by themes : The energy in buildings theme encompasses work on low energy buildings and appliances, low-carbon housing refurbishment and energy management; the behaviour and society theme includes research on energy demand and low-carbon communities; and the policy, equity, security and fuel poverty theme investigates practices, supply chain, governance and policy related to energy systems, as well as carbon markets and futures analysis, and fuel poverty.	Energy in buildings Behaviour and society Policy, equity, security and fuel poverty	13 researchers	Architecture and the Built Environment
Energy Systems Research Unit, Strathclyde University	ESRU undertook fundamental work on dynamic thermal simulation and building physics simulation throughout the 80s and 90s. Current research within ESRU is concerned with the development and testing of new methods and technologies for energy reduction and supply, and the evolution of computational tools to assist designers in their attempts to devise clean and sustainable solutions. ESRU has developed HUE a housing energy model (which can be applied at National housing stock level, community or Local Authority level or to individual dwelling level) designed to support domestic carbon and energy policy formulation, carbon foot-printing and roadmap formulation, strategic or concept low carbon design, carbon and energy performance rating, and cost effective improvement identification	Building environment and energy modelling		Architecture and the Built Environment
University of Bath: BRE Centre for Innovative Construction Materials	The Centre conducts leading research, development and consultancy in the field of innovative and sustainable construction materials. Developing the use of radical, low-carbon building materials and reinforcement technologies for the construction industry, the centre is assisting in reducing the UK s eco footprint - vital to mitigate the projected doubling of cement-based CO₂ emissions by 2050.	Sustainable construction Materials science	15 faculty, 10 researchers, 25 PhD students	Civil Engineering
University of Cambridge : The Martin Centre for Architectural and Urban Studies	The sustainable building group addresses issues related to the modelling, design, construction, monitoring and use of buildings, both in the UK and internationally, developing innovative technologies, methodologies and tools for sustainable design. Coordinated within the Cambridge Energy Efficient Cities Initiative with Departments of Engineering, Architecture, Chemical Engineering, Computer Science, JBS and BP Institute at the University of Cambridge.	Sustainable construction Energy monitoring	3 faculty, 3 researchers, 10 PhD students	Architecture and the Built Environment
University of Cambridge: Materials Science & Metallurgy	Work includes solid-state lighting to reduce electricity consumption, materials for higher-temperature (and therefore more efficient) gas turbines, innovative processing for energy-efficient materials extraction, lighter weight materials for energy-efficient transport, more efficient refrigeration, lower-energy electronics, and sensors for efficient control.	Materials science Building controls	5 faculty, 7 researchers, 10 PhD students	Metallurgy and Materials
University College London: UCL Energy Institute and Bartlett School of Graduate Studies	The UCL Energy Institute brings together different perspectives, understandings and procedures in energy research, transcending the boundaries between academic disciplines. There is some crossover with the Complex Built Environment Systems group (CBES) in the Bartlett School of Graduate Studies. CBES is a team of academics working together to gain a deeper understanding of the physical performance of built environment choices and their implications for energy use, health, conservation, productivity and climate change.	Building environment and energy modelling Energy monitoring Data frameworks and analysis People and Energy	38 faculty, 35 researchers, 45 PhD students	Architecture and the Built Environment
Science, Technology and Innovation Studies, School of Social and Political Science, University of Edinburgh	The Group are working on the theme of innovation studies, and includes studies of energy systems, and thus offers impartial, evidence-based advice to public and private stakeholders	Policy, equity, security and fuel poverty		Politics and International Studies
Energy Policy Group, University of Exeter	The Energy Policy Group (EPG) at the University of Exeter specialises in the interdisciplinary study of energy policy, placing sustainability and change at the heart of debates about energy policy and governance. The Group works collaboratively with stakeholders and researchers on the economics and politics of energy to find new and innovative approaches for enabling the transition to a low carbon, sustainable and affordable energy system.	Policy, equity, security and fuel poverty	6 faculty, 9 PhD students	Politics and International Studies
University of Manchester: Manchester Architectural Research Centre	Work lead by social construction of design, principally focusing on the field of sustainable architecture. Research into the nature of urban sustainability as it is played out within competing discourses of green building. Also research work on urban climatology and its relationship with urban and building design and the planning process; and studying the social scientific understanding of habitual behaviour in areas of everyday consumption with consequences for sustainability; and investigating the issue of energy consumption as a socio-technical phenomenon by unpacking the social and material dimensions of energy and carbon challenges related to ‘thermal experience’ in domestic settings	Sustainable urbanism Urban climatology People and buildings	5 faculty, 3 researchers, 3 PhD students	Architecture and the Built Environment
University of Plymouth: Environmental Building	The main research concentrations of this group are in the fields of building science and technology and construction management. Projects deal with a breadth of sub-topics, like for instance thermography, laboratory and in-situ measurements of thermal and humidity properties of building materials, building performance simulation, off-site construction, low and zero carbon technologies, POE (Post Occupancy Evaluation), building operational conditions and control (including occupant behaviour and climate change), values and attitudes regarding sustainability, and many others.	Sustainable construction Materials science People and buildings	5 faculty, 5 researchers, 10 PhD students	Architecture and the Built Environment
University of Reading: Construction Management and Engineering	Research in energy efficiency in buildings at Reading is centred in the Technologies for Sustainable Built Environments (TSBE) Centre. The TSBE is structured around sustainable building and services systems, energy management in buildings and infrastructure systems.	Sustainable construction	12 faculty, 18 researchers, 5-10 PhD students	Civil Engineering
University of Southampton: Electronics and Computer Science	Research of electronics and computer science related to energy efficiency of buildings. Includes research into agent-based modelling and intelligent systems for energy management and smart buildings and developing low-powered devices to feed this data to occupants in the future.	Photonics Agent-based modelling	5 faculty, 10 researchers, 6 PhD students	Computer Science and Informatics
The Sussex Energy Group, University of Sussex	The Group specialises in research in two areas : Transitions to sustainable energy systems. Research under this theme looks principally at the dynamics of both established and new energy systems at various scales: locally, nationally, and internationally. It also analyses the processes that are helping and hindering transitions to more sustainable, low carbon energy systems. Insights from these projects inform many of our engagements with and recommendations to policy-makers, businesses and civil society organisations. Governance of sustainable energy systems. Under this theme, we analyse the formulation and implementation of energy policies locally, nationally and internationally. This includes studying the way industry, government and civil society identify and promote particular energy challenges and options. We focus on how governments intervene with policies and other measures to guide the development of energy systems - and the often complex process of balancing policy objectives including emissions reduction, enhanced energy security and socially just access to energy.	Behaviour and society Policy, equity, security and fuel poverty	12 faculty, 10 researchers, 11 PhD students	Sociology Politics and International Studies

Name	Description	Type of asset	Number of Supporting Staff	Annual Operating Budget
BRE Test Facilities and Innovation Park	BRE’s testing services are supported by expert consultancy and research capabilities, and include: Performance assessment and service life design and prediction of all construction elements. Problem solving construction troubleshooting and building investigations, for example indoor air quality. Research and development testing often as part of innovation projects. Design testing, including: acoustics, air quality, airtightness, HVAC systems, wind tunnel testing, geotechnical.	Test facility
BRE Domestic Energy Model (BREDEM)	BREDEM 2012 is a model for estimating the energy consumption in dwellings for space heating, water heating, lighting and electrical appliances, and cooking.
Cambridge Housing Model	This model was developed by Cambridge Architectural Research Limited. The Cambridge Housing Model is closely linked to SAP 09, and has been the basis for the 2011, 2012 and 2014 editions of the Housing Energy Fact File (These documents follow on from the Domestic Energy Fact File series, which was produced by BRE until 2008).	Model
Centre for Alternative Technology, Wales	CAT is an education and visitor centre which demonstrates practical solutions for sustainability. It covers all aspects of green living: environmental building, eco-sanitation, woodland management, renewable energy, energy efficiency and organic growing.	Laboratory / Centre	20	£3M for all activities
CoRE Centre of Refurbishment Excellence	The Centre of Refurbishment Excellence (CoRE) is a partnership between private industry, Stoke City Council, Stoke College and the Building Research Establishment. It provides, in a purpose built complex marrying the old and the new, an exhibition space and a national training facility in the techniques and materials needed to refurbish the UK housing stock to the highest modern standards. CoRE is transforming a derelict Victorian pottery factory into a 6000 sq m centre of excellence and knowledge transfer link to sustainable refurbishment.	Laboratory/ Centre
English Housing Survey (EHS)	In April 2008 the English House Condition Survey (EHCS) was integrated with the Survey of English Housing (SHE) resulting in a new survey known as the English Housing Survey (EHS). The EHS has three component surveys: a household interview, followed by a physical inspection and a market value survey of a sub sample of the properties. It also now forms part of the Office for National Statistics Integrated Household Survey (HIS). The reports are available for download via the Communities and Local Government Website.	Database
Home Energy Efficiency Database (HEED)	The Home Energy Efficiency Database was designed and implemented to help monitor and improve the UK’s housing stock. The database includes data on property characteristics, heating systems, insulation installed and micro generation technologies installed. HEED now contains at least 1 piece of date-stamped information for approximately 51 of the UK’s homes. Registration and use of HEED is free of charge, but restricted to certain non-commercial organisations.	Database	Number of staff unknown	Unknown
National non-domestic energy and emissions model (N-DEEM)	Data from the NDBS database have been used by the Building Research Establishment (BRE) to construct a national non-domestic energy and emissions model (N-DEEM). N-DEEM links national floor areas from the NDBS database, to figures for specific energy use, disaggregated by fuel and application.	Model
Non-Domestic Building Stock Database (NDBS)	The National Non-Domestic Building Stock (NDBS) project, ran for ten years from 1991 to 2001. The database was constructed from data from the Valuation Office of the Inland Revenue and a series of street surveys of non-domestic buildings on 3,500 addresses in central Manchester, Swindon, Tamworth and Bury St Edmunds.	Database
Scottish Enterprise Technology Park (East Kilbride)	The Scottish Enterprise Technology Park (SETP), located in Scotland s largest new town, East Kilbride, began life over 50 years ago as the National Engineering Laboratory (NEL), which undertook research and development work for both government and business including a major site for the BRE recently expanded to include the Energy Technology Centre. Innovation Park at Ravenscraig currently in the master planning stage.	Test facility	<10	£2.8M for research (annual report)
Simplified Building Energy Model (SBEM)	SBEM is a software tool developed by BRE that provides an analysis of a building’s energy consumption. SBEM is used for non domestic buildings in support of the National Calculation Methodology (NCM) and the Energy Performance of Buildings Directive (EPBD). The tool helps to determine CO₂ emission rates for new buildings in compliance with Part L of the Building Regulations. It is also used to generate Energy Performance Certificates for non-domestic buildings in construction, sale or let. The tool is accompanied by a basic user interface called iSBEM.	Model

Network	Date Established	Description	Membership Profile	Activities
Association of Environmentally Conscious Builders	1989	AECB, the Sustainable Building Association, is a network of individuals and companies with a common aim of promoting sustainable building. It brings together builders, architects, designers, manufacturers, housing associations and local authorities, to develop, share and promote best practice in environmentally sustainable building.	Membership is open to individual supporters, private companies, and educational institutions.	The AECB’s three main roles are To provide a forum for members and others to discuss, test and share principles and methods of sustainable building To draw this experience together into rigorous standards To inform and lobby the construction sector and government
European Council for an Energy Efficient Economy	1993	eceee is a non-profit, membership-based European NGO.	Membership of eceee is open to both organisations and individuals	The goal of eceee is to stimulate energy efficiency through information exchange and co-operation. An analogous network exists in the USA (ACEEE) in which most academics also participate. There is an extensive database of opportunities and relevant information at the European level. There are also workshops and summer studies organised in alternate years from the ACEEE.
International Building Performance Simulation Association-England	2006	IBPSA England is an affiliate of International Building Performance Simulation Association, a non-profit international society of building performance simulation researchers, developers and practitioners, dedicated to improving the built environment.	Academics in “centres of excellence” for building performance and corporate partners involved in green building initiatives.	Regular meetings and workshops. Forum for the exchange of information between researchers, developers and practitioners operating in the area of building performance simulation and related issues. Connected to international network and conferences (IBPSA).
International Initiative for a Sustainable Built Environment	Before 2004	International not-for-profit organization focused on a global sustainable built environment.	Membership is open to both individuals and organisations	Major organiser of a series of regional feeders to its international conference and heavily associated with the journal Building Research and Information. Promotes an alternative open source methodology for the energy performance of buildings to LEED and BREEAM called SB-Tool.
Passive and Low Energy Architecture		PLEA serves as an open, international, interdisciplinary forum	Membership is open to professionals, academics and students from over 40 countries.	Promotes high quality research, practice and education in environmentally sustainable design. International conferences and workshops; expert group meetings and consultancies; scientific and technical publications; and architectural competitions and exhibitions.
Sustainable Development Research Network		SDRN aims to facilitate and strengthen the links between providers of research and policymakers across government, in order to improve evidence-based policymaking to deliver the UK government’s objectives for sustainable development.	Open to all interested researchers and analysts	Newsletter and events to contribute to sustainable development by encouraging the better use of evidence and research in policy-making.
UKERC National Energy Research Network	2004	NERN aims to network energy researchers from all disciplines, giving members visibility of a wide and multifaceted area and providing opportunities through information and through interaction with other members.	All organisations and individuals involved in energy research who can make a contribution towards energy R&D in the UK	Free informational resource to develop the coherence and capacity of UK energy research, with regular newsletters, jobs postings, and blogs.
UK Green Building Council	2007	The UK Green Building Council (UK-GBC) is a membership organisation that is campaigning for a sustainable built environment one that minimises negative environmental impacts while maximising benefits for people everywhere.	Membership is composed mostly of construction and engineering firms and consultancies with some involvement of major academic research centres. Not open to individuals.	The UK-GBC organises task groups to tackle pressing issues, events for information exchange primarily between practitioners but also academics, and an information centre of government policy, regulations, and relevant research.
UK Passivhaus Trust		The Passivhaus Trust is an independent, non-profit organisation that will provide leadership in the UK for the adoption of the Passivhaus standard and methodology. Its aim is to promote the principles of Passivhaus as a highly effective way of reducing energy use and carbon emissions from buildings in the UK, as well as providing high standards of comfort and building health.	Membership is open to individual supporters, private companies, public sector organisations, and educational institutions.	The Passivhaus Trust aims to: preserve the integrity of Passivhaus standards and methodology. promote Passivhaus principles to the industry and government. undertake research and development on Passivhaus standards in the UK.

Project	Objectives	Action Line	Type of Action	UK Participants	Co-ordinator and Partners	Total Funding	EU Funding	Duration	Annual Spend
ACtions in low income Households to Improve energy efficiency through Visits and Energy diagnosis (ACHIEVE)	The aim of ACHIEVE is to contribute to practical (energy uses and behaviours) and structural (retrofitting buildings) solutions for reduction of fuel poverty in Europe.	FP7- ENERGY / Intelligent Energy Europe	Medium-sized research project	Severn Wye Energy Agency	Groupe Energies Renouvelables Environnement et Solidarités, France plus 6 partners	€1.3M	€1M	2011-2014	€430K
Ecoheat4Cities (ECOHEAT4CITIES)	The main aim is to promote the use of renewable sources coupled to an overall decrease of primary energy consumption and development of higher efficiency on the heating and cooling market.	FP7- ENERGY / Intelligent Energy Europe	Medium-sized research project /td>	BRE	Euroheat and Power, Belgium plus 7 partners	€988K	€800K	2010-2012	€494K
Environmental Design in University Curricula and Architectural Training in Europe (EDUCATE)	EDUCATE seeks to foster competence in sustainable environmental design at all levels of architectural education and practice aiming to achieve comfort, well-being and energy efficiency in new and existing buildings.	FP7- ENERGY / Intelligent Energy Europe	Knowledge Transfer	University of Nottingham Architectural Association	University of Nottingham plus 8 partners	€1.6M	€1.2M	2009-2012	€530K
European Network of Information Centres promoting Energy Sustainability and CO₂ reduction among local COMmunities (ENESCOM)	ENESCOM aims at enhancing the role of local communities in mitigating climate change by creating a common methodology to promote and develop capacity building in energy sustainability and for the adoption of sustainable energy policies.	FP7- ENERGY / Intelligent Energy Europe	Knowledge Transfer	Powys County Council	Unione di Comuni Valle del Samoggia, Italy plus 14 partners	€1.8M	€1.3M	2010-2012	€900K
IDEAL-EPBD	The IDEAL-EPBD project aims to investigate why energy certificates seem to hardly motivate dwelling owners to take measures to improve the energy performance of their dwelling.	FP7- ENERGY / Intelligent Energy Europe	Consumer-focused project	BRE	Energy research centre of the Netherlands plus 9 partners	€1.3M	€1M	2007-2011	€300K
Sharing urban sustainable energy strategies - promoting the Covenant of Mayors (COME2COM)	come2CoM aims to promote the Covenant of Mayors within Europe by empowering cities and municipalities to prepare a baseline emissions inventory and a Sustainable Energy Action Plan.	FP7- ENERGY / Intelligent Energy Europe	Knowledge Transfer	Severn Wye Energy Agency	B.&S.U. Beratungs- und Servicegesellschaft Umwelt mbH, Germany plus 14 partners	€1.5M	€1.0M	2010-2012	€500K
Universities and Students for Energy Efficiency (USE EFFICIENCY)	Students will be the main actors of the project. They will participate in an innovative, practical training experience in tandem with building technicians in team-work activities.	FP7- ENERGY / Intelligent Energy Europe	Medium-sized project	Brunel University	University of Rome “Tor Vergata”, Italy plus 12 partners	€1.8M	€1.2M	2009-2012	€530K

Name	Type	Description	UK Contact Point
Demand Side Management Programme	IEA Implementing Agreement (Multilateral Technology Initiative)	The IEA Demand-Side Management Programme is an international collaboration of 20 countries working together to develop and promote opportunities for demand-side management (DSM). DSM offers solutions to problems such as load management, energy efficiency, strategic conservation and related activities.	Paul Davidson, Building Research Establishment
District Heating and Cooling	IEA Implementing Agreement (Multilateral Technology Initiative)	District Heating and Cooling (DHC) has proven to be a major contributor to Greenhouse Gas (GHG) reduction in many member countries and recognition of DHC’s importance is growing. In fact, many countries where it is established are renewing their commitment to DHC as they find new ways to use the technology to reduce environmental impacts. DHC facilitates linkages between supplies that are environmentally desirable and end users that could not otherwise make use of those energy sources.	Robin Wiltshire, Building Research Establishment
Efficient Electrical End-Use Equipment	IEA Implementing Agreement (Multilateral Technology Initiative)	The co-operation will focus on efficiency of electrical end-use equipment. Energy efficiency is more than ever a top priority on the international agenda. Using energy-efficient equipment is the most cost-effective short-term path to greater energy security and lower greenhouse gas emissions to combat climate change.	Mike Walker, DEFRA
Energy in Buildings and Communities (EBC)	IEA Implementing Agreement (Multilateral Technology Initiative)	The IEA (International Energy Agency) Energy in Buildings and Communities Programme (EBC, formerly ECBCS) carries out research and development activities toward near-zero energy and carbon emissions in the built environment. The R&D activities focus on the integration of energy-efficient and sustainable technologies into healthy buildings and communities. EBC projects and activities have produced long-lasting decision-making tools and integrated systems technologies. Outcomes from the Programme are publicised through many seminars and conferences. EBC s mission is to develop and facilitate the integration of technologies and processes for energy efficiency.	Prof Paul Ruyssevelt UCL Energy Institute, University College London
Heat Pumping Technologies	IEA Implementing Agreement (Multilateral Technology Initiative)	The IEA Heat Pump Centre (HPC) is an international information service for heat pumping technologies, applications and markets. The goal is to accelerate the implementation of heat pumps and related heat pumping technologies, including air conditioning and refrigeration.	Penny Dunbabin, DECC