Alaa Alaidroos scite author profile

In this paper, passive cooling strategies have been investigated to evaluate their effectiveness in reducing cooling thermal loads and air conditioning energy consumption for residential buildings in Kingdom of Saudi Arabia (KSA). Specifically, three passive cooling techniques have been evaluated including natural ventilation, downdraft evaporative cooling, and earth tube cooling. These passive cooling systems are applied to a prototypical KSA residential villa model with an improved building envelope. The analysis has been carried using detailed simulation tool for several cities representing different climate conditions throughout KSA. The impact of the passive cooling systems is evaluated on both energy consumption and electrical peak demand for residential villas with and without improved building envelope for five cities, representatives of various climate conditions in KSA. It is found that both natural ventilation and evaporative cooling provide a significant reduction in cooling energy use and electrical peak demand for the prototypical villa located in dry KSA climates such as that of Riyadh and Tabuk. Natural ventilation alone has reduced the cooling energy end-use by 22%, while the evaporative cooling system has resulted in 64% savings in cooling energy end-use. Moreover, the natural ventilation is found to have a high potential in all KSA climates, while evaporative cooling can be suitable only in hot and dry climates such as Riyadh and Tabuk. Finally, the analysis showed that natural ventilation provided the lowest electrical peak demand when applied into the improved envelope residential buildings in all five cities in KSA.

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Experimental validation of a numerical model for ventilated wall cavity with spray evaporative cooling systems for hot and dry climates

Alaidroos

Krarti

2016

Energy and Buildings

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Evaluation of the performance of demand control ventilation system for school buildings located in the hot climate of Saudi Arabia

et al. 2021

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Optimized controls for ventilated wall cavities with spray evaporative cooling systems

Alaidroos

Krarti

2017

Energy and Buildings

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Are Historical Buildings More Adaptive to Minimize the Risks of Airborne Transmission of Viruses and Public Health? A Study of the Hazzazi House in Jeddah (Saudi Arabia)

Alaidroos

Almaimani

Baik

et al. 2021

IJERPH

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The coronavirus (COVID-19) pandemic has brought immense challenges to the natural and built environment to develop an antivirus-enabled model for reducing potential risks of spreading the virus at varied scales such as buildings, neighborhoods, and cities. Spatial configurations of structures may hinder or assist the spread of viruses in the built environment. In this study, we have hypothesized that suitable air ventilation in historic buildings may enhance the built environment to combat the spreading of infectious viruses. To provide such quantitative shreds of evidence, we have generated and estimated an integrated model to summarize obtained information by considering natural ventilation, wind speed, inflow and outflow, wind direction, and forecasting the associated risks of airborne disease transmission in a historical building (i.e., the Hazzazi House in particular). Intrinsically, the results have demonstrated that the effectiveness of natural ventilation has directly influenced reducing the risks of transmitting airborne infectious viruses for the selected heritage building in Jeddah (Saudi Arabia). The adopted methods in this research may be useful to understand the potentials of conserving old heritage buildings. Consequently, the results demonstrate that natural air ventilation systems are critical to combat the spread of infectious diseases in the pandemic.

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Numerical modeling of ventilated wall cavities with spray evaporative cooling system

Alaidroos

Krarti

2016

Energy and Buildings

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Alaa Alaidroos

Optimal design of residential building envelope systems in the Kingdom of Saudi Arabia

Macro-economic benefit analysis of large scale building energy efficiency programs in Qatar

Evaluation of Passive Cooling Systems for Residential Buildings in the Kingdom of Saudi Arabia

Experimental validation of a numerical model for ventilated wall cavity with spray evaporative cooling systems for hot and dry climates

Evaluation of the performance of demand control ventilation system for school buildings located in the hot climate of Saudi Arabia

Optimized controls for ventilated wall cavities with spray evaporative cooling systems

Are Historical Buildings More Adaptive to Minimize the Risks of Airborne Transmission of Viruses and Public Health? A Study of the Hazzazi House in Jeddah (Saudi Arabia)

Numerical modeling of ventilated wall cavities with spray evaporative cooling system

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