3D CFD Simulation Analysis and Experimental Investigation of the Performance-based Smoke Management System Designs of a Building with Large Space

Yeh, Tsung-Chyn

08 August 2006

The existing local fire code ¡§Standard for Installation of Fire Protection Facilities in Classified Areas¡¨ is prescriptive in nature and suitable for buildings, which can be well compartmented. It also described the minimum requirement for specific system designs such as fire and smoke compartmentation, mechanical smoke extraction rate, etc. on item 188. In this reserch, the concourse level encountered large spaces and is the vital part for passengers¡¦ movement, either under normal condition or in emergency cases. Therefore, a performance-based fire engineering design has been exercised which is also allowed in local fire code subject to approval from the authorities having jurisdiction. First, a comparative study of the code compliances should be addressed, with the alternative design options supported by 3D CFD simulation. The FDS (Fire Dynamic Simulation) program was utilized for this reserch for 3D CFD simulation. It is developed by the National Institute of Standards and Technology (NIST) of U.S.. FDS is a computational fluid dynamics (CFD) model of fire-driven fluid flow. The software solves numerically a form of the Navier-Stokes equations appropriate for thermally-driven flow with an emphasis on smoke and heat transport from fires. Secondly, it is decided that a full-scale hot smoke test should be conducted to validate the smoke management system performances under the as-built conditions. It can be summarized that, following the NFPA 92B N-percentage Criteria, both test 1 and test 2 results indicated that the hot smoke tests are successful, in validating that a sufficient smoke clear height can be maintained for safe evacuation should a 5 MW t-squared fast fire occurred at the concourse level. Finally, following the NFPA 130 and NFPA 92B as the design guides, the performance-based fire safety engineering design conducted in concourse level, is successful through 3D CFD simulations and full-scale hot smoke test. A smoke¡Vfree escape route can be maintained for a period of time much longer than needed for the worst case fire scenario which warrants a safe evacuation in case of a 5 MW fire occurred on concourse level.

Performance-based Fire Safety Design

3D CFD Simulation

Full-scale Hot Smoke Test