Abstract
The assumed U-values of solid walls represent a significant source of uncertainty when estimating the energy performance of dwellings. The typical U-value for UK solid walls used for stock-level energy demand estimates and energy certification is 2.1 Wm−2 K−1. A re-analysis (based on 40 brick solid walls and 18 stone walls) using a lumped thermal mass and inverse parameter estimation technique gives a mean value of 1.3 ± 0.4 Wm−2 K−1 for both solid wall types. Among the many implications for policy, this suggests that standard UK solid-wall U-values may be inappropriate for energy certification or for evaluating the investment economics of solid-wall insulation. For stock-level energy modelling, changing the assumed U-value for solid walls reduces the estimated mean annual space heating demand by 16%, and causes a proportion of the stock to change Energy Performance Certification (EPC) band. The analysis shows that the diversity of energy use in domestic buildings may be as much influenced by heterogeneity in the physical characteristics of individual building components as it is by variation in occupant behaviour. Policy assessment and guidance material needs to acknowledge and account for this variation in physical building characteristics through regular grounding in empirical field data.
Highlights
5.7 million solid-walled houses exist in England, comprising 25% of the housing stock (CLG, 2012b)
The impact of insulating solid walls on energy demand is subject to a number of areas of uncertainty relating to: assumed physical characteristics used in modelling; design and installation issues that often degrade Solidwall insulation (SWI) performance; the role SWI plays in changing the whole building heat loss, including ventilation; the way the addition of SWI impacts on the operation of the heating systems and the thermal comfort of the occupants; and the additional opportunities created for ‘comfort taking’
Small changes to other properties of walls: density of brick and plaster, exposure to wind (Bankvall, 1977), moisture penetration (CIBSE, 2006; ISO, 2007a), and, most importantly, the occurrence of small air cavities within nominally solid walls can result in U-values in the range measured in the Energy Saving Trust (EST) Solid Wall Insulation Field Trials (SWIFT)
Summary
5.7 million solid-walled houses exist in England, comprising 25% of the housing stock (CLG, 2012b). The impact of insulating solid walls on energy demand is subject to a number of areas of uncertainty relating to: assumed physical characteristics used in modelling; design and installation issues that often degrade SWI performance; the role SWI plays in changing the whole building heat loss, including ventilation; the way the addition of SWI impacts on the operation of the heating systems and the thermal comfort of the occupants; and the additional opportunities created for ‘comfort taking’.
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