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Sensitivity analysis of proposed natural ventilation IEQ designs for archetypal open-plan office layouts in a temperate climate

journal contribution
posted on 20.08.2020 by Thomas Corbett, Eftychia Spentzou, Mahroo Eftekhari
Designing naturally ventilated deep, open-plan offices could improve occupants’ thermal comfort and productivity and ensure energy reductions; however, this can be challenging when relying on façade only openings. This research examines the ventilation performance sensitivity of atria, innovative façade openings and interior layouts of open-plan offices, in order to identify optimal typologies. Different building typologies are developed through a combination of various atria designs and configurations, with the effective use of highaspect-ratio (HAR) openings with a similar dimension to that of the floor-to-ceiling height, in either a mid-level vertical (MLV) or high-level horizontal (HLH) orientation. Steady-state computational fluid dynamics (CFD) simulations are performed to predict internal air flow and temperature distribution in a moderate climate and water-bath modelling (WBM) experiments to validate the computational models. Results showed that MLV provide superior cooling potential (up to 2.5oC reductions) and higher ventilations rates; despite, increasing thermal gradients. Unobstructed atria with a horizontal profile similar to that of the building footprint also performed well. Overall, façade opening design was shown to be the most influential design parameter. This research has presented guidance based on reliable results to better equip building designers and architects in the design of successful naturally ventilated deep, open-plan offices.

History

School

  • Architecture, Building and Civil Engineering

Published in

Advances in Building Energy Research

Publisher

Taylor & Francis

Version

AM (Accepted Manuscript)

Publisher statement

This is an Accepted Manuscript of an article published by Taylor & Francis in Advances in Building Energy Research on 2 Sept 2020, available online: https://doi.org/10.1080/17512549.2020.1813197

Acceptance date

15/08/2020

Publication date

2020-09-02

ISSN

1751-2549

eISSN

1756-2201

Language

en

Depositor

Dr Efi Spentzou Deposit date: 17 August 2020

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