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Upgrading our buildings through retrofit will be at the cornerstone of the green-economic recovery and a key priority of global climate action, this theme therefore also looks at the application of new methods and approaches to accelerate and future-proof the crucial retrofit challenge in the UK and beyond. Modelling and monitored data are used to investigate the impact of various energy efficiency measures on energy consumption and environmental performance. As economies move away from the use of fossil fuels for heating and cooling, system upgrades such as the adoption of heat pumps are also studied. High performance approaches such as Passivhaus and adaptation measures to limit indoor overheating in a warming climate, are also investigated.ÌýÌý

This work is vital in supporting the transition towards net-zero carbon whilst maintaining and promoting healthy indoor environments. Whole building retrofit coupled with the provision of renewables makes carbon positive buildings possible, helping to off-set harder to decarbonise sectors.Ìý

It is important that building retrofit is performed without compromising the indoor environmental quality of buildings, avoids unintended consequences and remain resilient in the face of future challenges. A systems thinking approach is adopted in line with the ethos of IEDE. It is important that the transition to net-zero is equitable and inclusive.ÌýÌýÌýÌýÌýÌý

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Research areas

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Optimal retrofit design

This research area seeks to assess and identify optimal retrofit solutions for buildings and the building stocks. Evolutionary and other algorithms are used to optimise retrofit design considering uncertainty and robustness across multiple output metrics. These metrics include various parameters such as energy use/carbon, indoor environmental quality, and costs.Ìý

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Building stock modellingÌý

This research involves assessment of the impacts of retrofits across building stocks. Both domestic and non-domestic (e.g. schools) models are employed to investigate impacts across the population. Within the work, many scenarios may be tested under various retrofit and climate projections.ÌýÌýÌý

Recent projects

Our research has involved a wealth of strategic projects in decarbonising the builtÌýenvironment through retrofit including the assessment of roll-out schemes, novel solutions, fuelÌýpoverty alleviation, health impacts and unintended consequences of decarbonisation.

Examples of our projects:

• Advancing School Performance: Indoor environmental quality, Resilience & Educational outcomes (ASPIRE)
• Complex Urban Systems for Sustainability and Health (CUSSH)
• Human health in an increasingly urbanised and warming world
• Health Protection Research Unit (HPRU)
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Energy use, retrofit and net zeroÌýin teaching

Our teaching in this area focuses on establishing a sound understanding of the energy consumption of our buildings and how to improve it. We aim to introduce future designers and practitioners to the methods, practice and consequences of retrofit, building their expertise in how retrofit is designed and deployed at various scales.Ìý

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Environmental Design and EngineeringÌýMSc

Our flagship MSc degree aims to equip students with the knowledge to tackle increasingly critical issues regarding the built environment and expertise in the design of more energy efficient, sustainable and healthier buildings.

Relevant modules:

• Low Energy Housing Retrofit
• Efficient Building Service SystemsÌý
• Methods of Environmental Analysis

Examples of past dissertation titles:

• 'Reversible retrofit: design for deconstruction applied to solid brick wall thermal insulation'
• 'Retrofit assessment on Hard to Decarbonise Homes: economic feasibility of measures and their robustness to climate change'
• 'Multi Objective Optimisation for the minimisation of Life Cycle Carbon Footprint and Life Cycle Cost using NSGA II: A Refurbished High-Rise Residential Building Case Study'

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Health, Wellbeing and Sustainable BuildingsÌýMSc

This Masters programme aims to drive the health and wellbeing agenda for human centred retrofit design. It helps to train a new generation of partitioners in this fast-growing field where they will understand the main impacts of retrofit on indoor environmental quality.Ìý

Relevant modules:

• Health, Comfort and Wellbeing in the Built Environment
• Integrated Building Design for Health and Wellbeing
• Indoor Air Quality in Buildings

Examples of past dissertation titles:

• 'Creating healthy workplaces: A future-fit approach to retrofit'
• 'Housing overheating mitigation: The role of Building Regulations'
• 'Modelling temperature exposure in indoor environments occupied by people with epilepsy'Ìý

Doctoral Research (PhD)

IEDE PhD research within this area includes cutting edge research in the areas of Energy and Buildings; Building Stock Modelling; Environmental Policy and Performance. Our PhD researchers are working across diverse topics such as:

• Fady Abdel Aziz: A multi-objective optimization model towards an energy efficient housing stock in new cities in Egypt
• Cheng Cui: A robust and efficient optimisation framework towards heat resilience in retrofitted dwellings
• Amr Hamada: Retrofit strategies for public administrative buildings in Egypt
• Kubra Doguc: Retrofit of Hospital buildings: Investigating life cycle performance of hospital building refurbishment through low carbon measures: An integrated methodological framework
• Guokai Chen: Control Rule Extraction in the HVAC system with Model Predictive Control
• : Combining building dynamic simulation with multi-criteria decision-making methods for a participatory design framework for net-zero carbon buildings
• : Occupant behavior and the design of district energy networks for a zero-carbon future
• : Collaborative Decision-making in Community Co-design of Urban Greenspace Regeneration, an Analysis of a Complex Network and System
• : Rethinking retrofit: putting users in the center in order to reduce energy and unintened consequences
• : Timeless Digital Twins for the Energy Health Nexus
• : Physics-informed Machine Learning Modelling for Multi-scale Building Energy Systems with Enhanced Accuracy and Interpretability
• : Cognitive Digital Twins for Adaptive Smart Building Energy Management
• : The development of a multi-objective optimisation tool in assessing future Building Energy Intensity (BEI), cost-benefit and payback in Malaysia
• : Systems thinking in the built environment
• : Cost-benefit analysis of achieving net zero targets across the UK hospitality sector
• : Dynamic Holistic Life Cycle Assessment: Integrating Embodied and Operational Carbon, Energy, Water and wider ecosystem impacts
• : Physics-informed Machine Learning Modelling for Multi-scale Building Energy Systems with Enhanced Accuracy and Interpretability

Researchers

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