Building-integrated rooftop greenhouses

A sustainable and secure food supply within a low-carbon and resilient infrastructure is encapsulated in several of The United Nations' 17 sustainable development goals. The integration of urban agriculture in buildings can offer improved efficiencies; in recognition of this, the first south Eu...

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Detalles Bibliográficos
Autores: Nadal, Ana|||0000-0002-9919-5092, Llorach-Massana, Pere|||0000-0003-1162-8162, Cuerva, Eva|||0000-0003-2016-1162, López Capel, Elisa|||0000-0002-0637-4308, Montero Camacho, Juan Ignacio|||0000-0003-2548-4665, Josa Garcia-Tornel, Alejandro|||0000-0003-1180-7910, Rieradevall, Joan|||0000-0003-3360-6829, Royapoor, Mohammad|||0000-0001-7186-6993
Tipo de recurso: artículo
Fecha de publicación:2017
País:España
Institución:Universitat Autònoma de Barcelona
Repositorio:Dipòsit Digital de Documents de la UAB
Idioma:inglés
OAI Identifier:oai:ddd.uab.cat:168410
Acceso en línea:https://ddd.uab.cat/record/168410
https://dx.doi.org/urn:doi:10.1016/j.apenergy.2016.11.051
Access Level:acceso abierto
Palabra clave:Rooftop greenhouse
Building performance simulation
Measured energy data
Energy Plus
Energy-food nexus
Building-rooftop greenhouse symbiosis
Descripción
Sumario:A sustainable and secure food supply within a low-carbon and resilient infrastructure is encapsulated in several of The United Nations' 17 sustainable development goals. The integration of urban agriculture in buildings can offer improved efficiencies; in recognition of this, the first south European example of a fully integrated rooftop greenhouse (iRTG) was designed and incorporated into the ICTA-ICP building by the Autonomous University of Barcelona. This design seeks to interchange heat, CO2 and rainwater between the building and its rooftop greenhouse. Average air temperatures for 2015 in the iRTG were 16.5 °C (winter) and 25.79 °C (summer), making the iRTG an ideal growing environment. Using detailed thermophysical fabric properties, 2015 site-specific weather data, exact control strategies and dynamic soil temperatures, the iRTG was modelled in EnergyPlus to assess the performance of an equivalent 'freestanding' greenhouse. The validated result shows that the thermal interchange between the iRTG and the ICTA-ICP building has considerable moderating effects on the iRTG's indoor climate; since average hourly temperatures in an equivalent freestanding greenhouse would have been 4.1 °C colder in winter and 4.4 °C warmer in summer under the 2015 climatic conditions. The simulation results demonstrate that the iRTG case study recycled 43.78 MWh of thermal energy (or 341.93 kWh/m2/yr) from the main building in 2015. Assuming 100% energy conversion efficiency, compared to freestanding greenhouses heated with oil, gas or biomass systems, the iRTG delivered an equivalent carbon savings of 113.8, 82.4 or 5.5 kg CO2(eq)/m2/yr, respectively, and economic savings of 19.63, 15.88 or 17.33 €/m2/yr, respectively. Under similar climatic conditions, this symbiosis between buildings and urban agriculture makes an iRTG an efficient resource-management model and supports the promotion of a new typology or concept of buildings with a nexus or symbiosis between energy efficiency and food production.