Integrating a passive downdraught evaporative cooling tower into a Saudi house - The impact of climatic conditions on PDEC performance

The Kingdom of Saudi Arabia (KSA) generates the most electricity of any country in the Gulf region, and virtually all that electricity is produced by the burning of fossil fuels - natural gas and crude oil. The residential sector accounts for about 50% of the total electricity demand in the Kingdom,...

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Bibliographic Details
Published in:Building and environment 2023-08, Vol.242, p.110497, Article 110497
Main Authors: Alshenaifi, Mohammad A., Sharples, Steve, Abuhussain, Mohammed A., Alotaibi, Badr S., Aldersoni, Ali A., Abdelhafez, Mohamed H.H.
Format: Article
Language:English
Subjects:
Cooling energy
Hot dry climate
Passive cooling systems
PDEC tower
Typical saudi housing
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Summary:The Kingdom of Saudi Arabia (KSA) generates the most electricity of any country in the Gulf region, and virtually all that electricity is produced by the burning of fossil fuels - natural gas and crude oil. The residential sector accounts for about 50% of the total electricity demand in the Kingdom, and around two-thirds of that electricity consumption is used for air conditioning. As the Kingdom transitions away from its reliance on fossil fuels, reducing air conditioning energy demand in dwellings becomes a key objective. Passive cooling systems can significantly reduce cooling energy loads for buildings while maintaining thermal comfort. This study investigated the potential of integrating a passive downdraught evaporative cooling (PDEC) tower into a typical Saudi Arabian villa. A computational model of a spray PDEC tower was developed in IES-VE software and calibrated against field data. Then, an actual Saudi villa was monitored, modelled, and validated before a PDEC tower was digitally integrated into the villa. Finally, the villa and its PDEC digital twin were used to conduct a series of parametric analyses to determine the PDEC performance in different rooms and cooling energy consumption in the villa as functions of wind speed and direction. The research found that, counterintuitively, higher wind speeds reduced the effectiveness of the PDEC system to cool rooms in the villa and that wind direction also played a role in the degree of cooling experienced in different villa spaces. In the summer season, the results indicated that the total villa energy consumption was approximately 32,415 kWh in the base case, with cooling energy representing 88% of the total energy used (28,337 kWh). The integration of the PDEC tower resulted in a reduction of approximately 22% in cooling energy consumption, from 28,337 kWh to 22,032 kWh, while the PDEC was operational continuously throughout the day. •Saudi house monitored in summer; data collected via site visits & data loggers for environmental data.•Villa & PDEC tower modelled in IES-VE software, validated using building details, monitoring data.•PDEC tower virtually incorporated into villa model to assess thermal performance, wind effect & energy use.•Research found high wind speeds reduced effectiveness of PDEC system to cool rooms, wind direction played a role as well.
ISSN:0360-1323
1873-684X
DOI:10.1016/j.buildenv.2023.110497