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A platform for research: civil engineering, architecture and urbanism
Thermal comfort and ventilation effectiveness in an office room with radiant floor cooling and displacement ventilation
The influence of displacement ventilation and a cooled floor on indoor climate in the cooling season were experimentally studied in a room representing an office with a shaded window, occupied by two simulated employees. The aim was to investigate whether the combination of these two systems can retain the favorable air and temperature distribution patterns and high ventilation effectiveness that are typically attained by displacement ventilation, while exploiting the energy conservation advantages of a high temperature cooling system. The tests were performed under a range of boundary conditions, varying the nominal air change rate from 4.5 h−1 down to 1.5 h−1. Contaminant removal and mean-age-of-air measurements were performed to characterize the ventilation effectiveness and air velocity; air and operative temperature profiles were measured, together with thermal manikin equivalent temperatures, to evaluate the thermal environment. The combined system was able to achieve good ventilation effectiveness close to a heat source, so that in the occupant's breathing zone the ventilation effectiveness was significantly better than for ideal mixing, even at a nominal air change rate as low as 1.5 h−1. However, for a broad range of boundary conditions, decreasing the floor temperature resulted in vertical air temperature differences of up to 6 K and vertical equivalent temperature differences of up to 8 K for a seated person. Thus although the maximum draught rating at ankle level was 21% at the highest nominal air change rate of 4.5 h−1, even for an occupant sitting 1 meter in front of the supply diffuser, the local thermal discomfort occasioned by the excessive vertical temperature differences gives chilled ceilings the advantage over chilled floors for use with displacement ventilation.
Thermal comfort and ventilation effectiveness in an office room with radiant floor cooling and displacement ventilation
The influence of displacement ventilation and a cooled floor on indoor climate in the cooling season were experimentally studied in a room representing an office with a shaded window, occupied by two simulated employees. The aim was to investigate whether the combination of these two systems can retain the favorable air and temperature distribution patterns and high ventilation effectiveness that are typically attained by displacement ventilation, while exploiting the energy conservation advantages of a high temperature cooling system. The tests were performed under a range of boundary conditions, varying the nominal air change rate from 4.5 h−1 down to 1.5 h−1. Contaminant removal and mean-age-of-air measurements were performed to characterize the ventilation effectiveness and air velocity; air and operative temperature profiles were measured, together with thermal manikin equivalent temperatures, to evaluate the thermal environment. The combined system was able to achieve good ventilation effectiveness close to a heat source, so that in the occupant's breathing zone the ventilation effectiveness was significantly better than for ideal mixing, even at a nominal air change rate as low as 1.5 h−1. However, for a broad range of boundary conditions, decreasing the floor temperature resulted in vertical air temperature differences of up to 6 K and vertical equivalent temperature differences of up to 8 K for a seated person. Thus although the maximum draught rating at ankle level was 21% at the highest nominal air change rate of 4.5 h−1, even for an occupant sitting 1 meter in front of the supply diffuser, the local thermal discomfort occasioned by the excessive vertical temperature differences gives chilled ceilings the advantage over chilled floors for use with displacement ventilation.
Thermal comfort and ventilation effectiveness in an office room with radiant floor cooling and displacement ventilation
Krajčík, Michal (author) / Tomasi, Roberta (author) / Simone, Angela (author) / Olesen, Bjarne W. (author)
Science and Technology for the Built Environment ; 22 ; 317-327
2016-04-02
11 pages
Article (Journal)
Electronic Resource
English
| British Library Online Contents | 2012
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