Super-insulate or use renewable technology? Life cycle cost, energy and global warming potential analysis of nearly zero energy buildings (NZEB) in a temperate oceanic climate

Energy and Buildings

Volumn 139, Issue , 2017, Pages 590-607

  Moran, Paul ^a   Goggins, Jamie ^a,b   Hajdukiewicz, Magdalena ^a  

^a NATIONAL UNIVERSITY OF IRELAND   (Ireland)

^b Marine Renewable Energy Ireland (MaREI) Research Centre   (Ireland)

Author keywords

Electricity grid; Embodied energy; Embodied global warming potential; Energy performance; Energy prices; Life cycle cost; Life cycle energy; Life cycle greenhouse gas emissions; Nearly zero energy buildings; Renewable energy

Indexed keywords

ARCHITECTURAL DESIGN; BIOMASS; BOILERS; BUILDINGS; CARBONIZATION; COST BENEFIT ANALYSIS; COSTS; ELECTRIC POWER TRANSMISSION NETWORKS; ENVIRONMENTAL TECHNOLOGY; FOSSIL FUELS; GAS EMISSIONS; GLOBAL WARMING; GREENHOUSE GASES; HEAT PUMP SYSTEMS; HEATING; HEATING EQUIPMENT; LIFE CYCLE; POWER QUALITY; RENEWABLE ENERGY RESOURCES;

ELECTRICITY GRIDS; EMBODIED ENERGY; ENERGY PERFORMANCE; ENERGY PRICES; GLOBAL WARMING POTENTIAL; LIFE CYCLE ENERGIES; LIFE-CYCLE GREENHOUSE GAS EMISSIONS; LIFECYCLE COSTS; RENEWABLE ENERGIES; ZERO ENERGY BUILDING (ZEB);

ENERGY EFFICIENCY;

EID: 85010369411     PISSN: 03787788     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enbuild.2017.01.029     Document Type: Article

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