E
Esmail M. Saber
Researcher at London South Bank University
Publications - 22
Citations - 414
Esmail M. Saber is an academic researcher from London South Bank University. The author has contributed to research in topics: Radiant cooling & Air conditioning. The author has an hindex of 9, co-authored 21 publications receiving 306 citations. Previous affiliations of Esmail M. Saber include ETH Zurich & National University of Singapore.
Papers
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PV (photovoltaics) performance evaluation and simulation-based energy yield prediction for tropical buildings
TL;DR: In this paper, the performance of different solar cell types is evaluated for the tropical weather of Singapore, where on-site measured data of PV systems implemented in a zero-energy building in Singapore, is analyzed.
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A review of high temperature cooling systems in tropical buildings
TL;DR: In this paper, the authors reviewed and summarized the recent published papers on applications of high temperature cooling systems in tropical buildings and discussed the reported outcomes and conclusions from these studies to get a better understanding on overall performance of the systems which are designed based on this concept.
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Thermal comfort and IAQ analysis of a decentralized DOAS system coupled with radiant cooling for the tropics
Esmail M. Saber,Rupesh Iyengar,Matthias Mast,Forrest Meggers,Kwok Wai Tham,Hansjürg Leibundgut +5 more
TL;DR: In this paper, the performance of a decentralized dedicated outdoor air system combined with a radiant cooling system (decentralized DOAS-RCS) was evaluated in terms of occupant thermal comfort and indoor air quality for the tropical context.
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Stuck in a stack—Temperature measurements of the microclimate around split type condensing units in a high rise building in Singapore
Marcel Bruelisauer,Forrest Meggers,Esmail M. Saber,Esmail M. Saber,Cheng Li,Cheng Li,Hansjürg Leibundgut +6 more
TL;DR: In this paper, the authors present the first field measurements from a 24-storey building in Singapore and found that the temperatures in the void space increased continuously along the height of the building by 10−13 °C, showing a significant stack effect from the rejected heat from condensing units.
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Evaluating and adapting low exergy systems with decentralized ventilation for tropical climates
TL;DR: In this article, a decentralized air supply prototype was developed and initially tested at the ETH Zurich, then installed in a building laboratory that was shipped to Singapore-ETH Centre, and it was modeled and evaluated in collaboration with the National University of Singapore.