Abstract
Building form and facade development for energy saving and generation are of great importance. Further development for natural ventilation purposes is also imperative as it is related to many issues that affect the quality of the living and working environment inside and around the buildings in outdoor and semi-outdoor spaces. In rapidly developing regions experiencing a warm and humid climate, like Saudi Arabia, mechanical cooling and ventilation are commonly used in residential and non-residential buildings. However, this was not the case in traditional structures, like the massive coral buildings of Jeddah, where cooling essentially depended on cross ventilation and heat storage in thermal mass. Further, the building forms in the traditional oriental city were optimized for natural ventilation on the macro- and micro-urban and room scales, respectively. Owing to the advancement in air-conditioning technology, conventional building design approaches tend to encourage sealed indoor spaces that rarely interact with the outdoor environment. Even in such harsh climates, during many months in a year, the outdoor temperature is remarkably low, allowing the utilization of natural ventilation within the rooms, as well as between building complexes and the surrounding spaces. This optimization process requires the integrated planning of many aspects, such as the facade, building form, as well as the intermediate threshold spaces between the indoor and outdoor spaces. Non-residential buildings in Saudi Arabia require a large amount of energy for operation. This is mainly due to the relatively high cooling demand caused by internal loads. A hybrid cooling system that incorporates mechanical and natural cooling and ventilation can be implemented for low-temperature days and nights. This paper presents a method for saving energy in a university faculty building, which is located in Jeddah. Models of the proposed solutions were analyzed using a computational fluid dynamics simulation tools, as well as the dynamic building simulation tool IDA-Indoor Climate and Energy (IDA-ICE) to assess user comfort and the level of reduction in energy demand.
Highlights
Providing a healthy living, working or education environment that promotes thermal and olfactory comfort is essential for the performance and satisfaction of the users
The basic simulation case relates to the conventional treatment of the ground floor
Cut for the northern building complex allows the north wind to flow through. While this opening provides increased air velocity at point (1) towards the other side over point (2), a very calm condition can still be noticed at point (3) along the urban canyon space that separates the right- and left-hand parallel complexes
Summary
Providing a healthy living, working or education environment that promotes thermal and olfactory comfort is essential for the performance and satisfaction of the users. Natural ventilation is a passive technique that helps remove foul air and moisture, as well as provide occupants with thermal comfort under certain conditions. It is a key factor in preventing the spread of airborne illnesses, while reducing the CO2 concentration in a space [1]. Natural ventilation requires little technical effort, maintenance, and above all, energy use [2,3]. Some risks, such as outdoor air pollution, noise, and dust may arise and must be prevented [4].
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