A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Comfort cooling by wind towers in the Australian residential context – Experimental wind tunnel study of comfort
https://orcid.org/0000-0002-3414-290X
Abstract Comfort performance of a wind tower in a residential setting was evaluated in a series of wind tunnel experiments using a sealed, four storey apartment building model at 1:100 scale. This study was structured into three phases; first, the pressure distribution over the wind tower openings and the building fenestrations were measured in a boundary layer wind tunnel. From these data, internal bulk flow air change rates and mean indoor room air speeds were derived. Second, the pressure coefficient results of the first phase were applied to the Sydney Typical Meteorological Year (TMY) to assess the ventilation performance of the wind tower in terms of hourly indoor air speed. Wind tower results were benchmarked against through-window cross ventilation. In the third phase, increased indoor air speeds under wind tower ventilation were processed through the Standard Effective Temperature (SET*) comfort model to compute the additional comfort degree hours resulting from inclusion of a wind tower. Results indicate that the wind tower reduced indoor SET* values by an average 3.2 °C relative to conventional through-window cross-ventilation during Sydney’s summer when outdoor temperatures were warmer than neutral.
Highlights A typical Sydney apartment fitted with a windtower was tested in a wind tunnel. Indoor air speeds with windtower are benchmarked against through-window cross-ventilation. Benefits of elevated indoor air speeds are expressed in degrees-hours of equivalent air cooling. Windtowers enhance occupant comfort without requiring mechanical cooling or energy.
Comfort cooling by wind towers in the Australian residential context – Experimental wind tunnel study of comfort
https://orcid.org/0000-0002-3414-290X
Abstract Comfort performance of a wind tower in a residential setting was evaluated in a series of wind tunnel experiments using a sealed, four storey apartment building model at 1:100 scale. This study was structured into three phases; first, the pressure distribution over the wind tower openings and the building fenestrations were measured in a boundary layer wind tunnel. From these data, internal bulk flow air change rates and mean indoor room air speeds were derived. Second, the pressure coefficient results of the first phase were applied to the Sydney Typical Meteorological Year (TMY) to assess the ventilation performance of the wind tower in terms of hourly indoor air speed. Wind tower results were benchmarked against through-window cross ventilation. In the third phase, increased indoor air speeds under wind tower ventilation were processed through the Standard Effective Temperature (SET*) comfort model to compute the additional comfort degree hours resulting from inclusion of a wind tower. Results indicate that the wind tower reduced indoor SET* values by an average 3.2 °C relative to conventional through-window cross-ventilation during Sydney’s summer when outdoor temperatures were warmer than neutral.
Highlights A typical Sydney apartment fitted with a windtower was tested in a wind tunnel. Indoor air speeds with windtower are benchmarked against through-window cross-ventilation. Benefits of elevated indoor air speeds are expressed in degrees-hours of equivalent air cooling. Windtowers enhance occupant comfort without requiring mechanical cooling or energy.
Comfort cooling by wind towers in the Australian residential context – Experimental wind tunnel study of comfort
https://orcid.org/0000-0002-3414-290X
Abstract Comfort performance of a wind tower in a residential setting was evaluated in a series of wind tunnel experiments using a sealed, four storey apartment building model at 1:100 scale. This study was structured into three phases; first, the pressure distribution over the wind tower openings and the building fenestrations were measured in a boundary layer wind tunnel. From these data, internal bulk flow air change rates and mean indoor room air speeds were derived. Second, the pressure coefficient results of the first phase were applied to the Sydney Typical Meteorological Year (TMY) to assess the ventilation performance of the wind tower in terms of hourly indoor air speed. Wind tower results were benchmarked against through-window cross ventilation. In the third phase, increased indoor air speeds under wind tower ventilation were processed through the Standard Effective Temperature (SET*) comfort model to compute the additional comfort degree hours resulting from inclusion of a wind tower. Results indicate that the wind tower reduced indoor SET* values by an average 3.2 °C relative to conventional through-window cross-ventilation during Sydney’s summer when outdoor temperatures were warmer than neutral.
Highlights A typical Sydney apartment fitted with a windtower was tested in a wind tunnel. Indoor air speeds with windtower are benchmarked against through-window cross-ventilation. Benefits of elevated indoor air speeds are expressed in degrees-hours of equivalent air cooling. Windtowers enhance occupant comfort without requiring mechanical cooling or energy.
Comfort cooling by wind towers in the Australian residential context – Experimental wind tunnel study of comfort
Sadeghi, Mahsan (author) / Samali, Bijan (author) / Wood, Graeme (author) / de Dear, Richard (author)
2019-10-13
Article (Journal)
Electronic Resource
English
Wind tunnel study on the pedestrian-level wind comfort in residential areas of Harbin
| DOAJ | 2019
Wind comfort predictions by wind tunnel tests: comparison with full-scale data
| British Library Conference Proceedings | 1994
Wind comfort predictions by wind tunnel tests: comparison with full-scale data
| Online Contents | 1994