TY - GEN
T1 - Performance of an air radiative cooling system in a residential building in Chile
AU - Gálvez, Miguel A.
AU - Conteras, Jorge
AU - Barraza, Rodrigo
AU - Díaz, Daniela
N1 - Publisher Copyright:
© 2020 PLEA 2020 - 35th PLEA Conference on Passive and Low Energy Architecture Planning Post Carbon Cities, Proceedings. All Rights Reserved.
PY - 2020
Y1 - 2020
N2 - This paper analyses the performance of a low energy radiative cooling system in Chile. The cooling potential of these systems has not been addressed at all in the context of Chile's varied and complex climatic reality. For this purpose, an air radiative cooling system has been installed in an experimental housing prototype in the Valparaíso region. Ambient conditions, as well as the system variables evolution, have been measured along a complete summer week. Using this set of data and an analytical model, the paper describes the influence of the different parts (e.g., specialized radiator, thermal mass, heat transportation subsystem, and terminal unit) on the performance of the complete system, as well as its coupling with the indoor environment. The experimental results show that with this system, the ambient temperature can be lowered more than 5◦C. Furthermore, it is experimentally proven that the system dissipates 50 W/m2 when it reaches its maximum potential, and 4.3 MJ during the one-week functioning period. This job is the initial step towards a mature cooling system; thus, the next steps include several modifications and upgrades that need to be experimentally tested.
AB - This paper analyses the performance of a low energy radiative cooling system in Chile. The cooling potential of these systems has not been addressed at all in the context of Chile's varied and complex climatic reality. For this purpose, an air radiative cooling system has been installed in an experimental housing prototype in the Valparaíso region. Ambient conditions, as well as the system variables evolution, have been measured along a complete summer week. Using this set of data and an analytical model, the paper describes the influence of the different parts (e.g., specialized radiator, thermal mass, heat transportation subsystem, and terminal unit) on the performance of the complete system, as well as its coupling with the indoor environment. The experimental results show that with this system, the ambient temperature can be lowered more than 5◦C. Furthermore, it is experimentally proven that the system dissipates 50 W/m2 when it reaches its maximum potential, and 4.3 MJ during the one-week functioning period. This job is the initial step towards a mature cooling system; thus, the next steps include several modifications and upgrades that need to be experimentally tested.
KW - Air conditioning systems
KW - Energy efficiency
KW - Radiative cooling
KW - Social housing
UR - http://www.scopus.com/inward/record.url?scp=85185218203&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85185218203
T3 - PLEA 2020 - 35th PLEA Conference on Passive and Low Energy Architecture Planning Post Carbon Cities, Proceedings
SP - 469
EP - 474
BT - PLEA 2020 - 35th PLEA Conference on Passive and Low Energy Architecture Planning Post Carbon Cities, Proceedings
A2 - Alvarez, Jorge Rodriguez
A2 - Goncalves, Joana Carla Soares
A2 - Goncalves, Joana Carla Soares
A2 - Goncalves, Joana Carla Soares
PB - University of A Coruna and Asoc
T2 - 35th PLEA Conference on Passive and Low Energy Architecture Planning Post Carbon Cities, PLEA 2020
Y2 - 1 September 2020 through 3 September 2020
ER -
