Details

Autor(en) / Beteiligte

• Pérez-Andreu, Víctor
• Aparicio-Fernández, Carolina
• Martínez-Ibernón, Ana
• Vivancos, José-Luis

Titel

Impact of climate change on heating and cooling energy demand in a residential building in a Mediterranean climate

Ist Teil von

• Energy (Oxford), 2018-12, Vol.165, p.63-74

Ort / Verlag

Oxford: Elsevier Ltd

Erscheinungsjahr

2018

Link zum Volltext

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• A range of energy improvement measures applied to a typical Mediterranean residential building are modelled under various climate-change scenarios. Global Circulation Models (CNRM-CM5 and MPI-ESM-LR), under two emission scenarios (RCP4.5 and RCP8.5), downscaled by the Spanish Meteorological Agency, are used to generate four temperature projections. Energy simulations are obtained with TRNSYS tools in a Mediterranean climate based on temperature projections in two periods: 2048–2052 and 2096–2100, with the same time span. Various energy measures apply thermal improvements to a conventional residential building model that complies with current regulations for this analysis of best practice in passive construction solutions. Sequential implementation of eight different energy improvements measures are applied to the initial building model: six passives (infiltration, insulation thickness, glazing and frame type, window area, shading devices and natural cross ventilation) and two active (mechanical ventilation and a heat recovery system) measures. The climatic trends that are predicted show a local scenario with a warming climate and the thermal behaviour of the building is shown to differ in each scenario. The demand for indoor heating decreases significantly when the outdoor temperature increases, while the demand for cooling and the risk of overheating increase considerably in all the scenarios. The data for the building conditions that are projected in this study predict that natural and forced ventilation strategies will have the least impact, while increased thermal insulation and reductions in infiltration will have a greater effect on global energy demand. •Temperatures are projected under two Global Circulation Models for 2050 and 2100.•Eight energy measures are modelled under Mediterranean climate-change scenarios.•Passive and active improvements are modelled in a residential building.•Heating energy demand decreases significantly and cooling energy demand increases.•Thermal insulation and infiltration have the greatest effect on total energy demand.