Fire Performance of Phase Change Material Enhanced Plasterboard

Sustainable construction materials are increasingly being used to reduce the carbon footprint of modern buildings. These materials have the potential to change the fire dynamics of compartments by altering the compartment energy balance however there is little quantitative understanding of how these...

Full description

Saved in:
Bibliographic Details
Published in:Fire technology 2018, Vol.54 (1), p.117-134
Main Authors: McLaggan, M. S., Hadden, R. M., Gillie, M.
Format: Article
Language:English
Subjects:
Carbon footprint
Characterization and Evaluation of Materials
Civil Engineering
Classical Mechanics
Compartments
Construction materials
Design criteria
Drywall
Energy balance
Energy conservation
Engineering
Environmental impact
Green buildings
Heat
Heat flux
Heat release rate
Heat transfer
Loads (forces)
Phase change materials
Physics
Sustainable materials
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Sustainable construction materials are increasingly being used to reduce the carbon footprint of modern buildings. These materials have the potential to change the fire dynamics of compartments by altering the compartment energy balance however there is little quantitative understanding of how these materials behave in the event of a real fire. The changes in fire dynamics may be due to increased fuel load in a compartment, reduced time to failure or promotion of flame spread. The objective of this research is to quantify how Phase Change Materials (PCMs) perform in realistic fire scenarios. It was found that a plasterboard product containing microencapsulated PCMs will behave similarly to a charring solid and have the potential to contribute significant fuel to a compartment fire but that they maintain integrity for the duration of flaming period. The critical heat flux for this product was determined in the cone calorimeter to be 17.5 ± 2.5 kW m −2 , the peak heat release rate and mass loss rate ranged from 60.2 kW m −2 to 107 kW m −2 and 1.88 g s −1  m −2 to 8.47 g s −1  m −2 respectively for exposures between 20 kW m −2 and 70 kW m −2 . Sample orientation was found to increase the peak heat release rate by up to 25%, whilst having little to no effect on the mass loss rate. These parameters, in addition to the in-depth temperature evolution and ignition properties, can be used as design criteria for balancing energy savings with quantified fire performance.
ISSN:0015-2684
1572-8099
DOI:10.1007/s10694-017-0675-x