Heat release and flame propagation in prefabricated modular unit with GFRP composite facades

Tuan Duc Ngo; Quynh Thuy Nguyen; Phuong Tran

doi:10.1007/s12273-016-0294-3

AI Chat Paper

Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.

Chat more with AI

| Sign up

Browse by Subject

Search for peer-reviewed journals with full access.

Journals A - Z

About Us

Discover the SciOpen Platform and Achieve Your Research Goals with Ease.

About Us

Publish with Us

Support

Journals A - Z

About Us

Publish with Us

Support

Article Link

Cite

EndNote(RIS) BibTeX

Collect

Submit Manuscript

Show Outline

Outline

Show full outline

Hide outline

Outline

Show full outline

Hide outline

Research Article

Heat release and flame propagation in prefabricated modular unit with GFRP composite facades

Tuan Duc Ngo, Quynh Thuy Nguyen, Phuong Tran(

)

Department of Infrastructure Engineering, the University of Melbourne, Melbourne, Parkville, VIC, 3010, Australia

Show Author Information

Abstract

Prefabrication of modular residential and office units involves rapid manufacturing various building components off-site from different choices of materials, and transportation to construction site for the complete assembly. While this prefabrication manufacturing process could reduce construction costs, time and waste by using lightweight composite modules (LCM), significant challenge is associated with fire performance of an office modular unit using the modular units. This work aims at investigating the fire performance of a modular office unit using the LCM in terms of heat release rate and temperature history and compared with the traditional office unit model using glazing facade. The heat release and flame propagations in a selected prefabricated modular office unit are simulated with computational fluid dynamic (CFD) taking into account the complexity of the materials systems and the influences of the facade. The numerical procedure combining pyrolysis analysis of the composite sandwiches and the fire dynamic simulation of the combustion process is developed. The computational model is validated with thermal responses obtained from the cone calorimetry experiments. Kinetic parameters obtained from the TGA tests and pyrolysis analysis are used as inputs for the models measuring the fire growth index and total heat release. A multilayer sandwich composite material model is proposed to simulate the thermal responses and combustion processes of the prefabricated unit envelop. Temperatures at critical locations of the units are captured and compared with the standard fire curve to reveal the significant improvement in the fire performance of the office modular unit utilising GFRP composite.

Keywords

building facade heat release rate fire GFRP prefabricated modular building

References

AS1530.4-2005 (2005). Australian Standard. Methods for tests on building materials, components and structures. Part 4: Fire-resistance test of elements of construction. Council of Standards Australia.

F Ceroni, M Pecce, A Bilotta, E Nigro (2012). Bond behavior of FRP NSM systems in concrete elements. Composites Part B: Engineering, 43: 99-109.

Crossref Google Scholar

W-k Chow (2013). Air pumping action of a plume in a room fire. Building Simulation, 6: 95-102.

Crossref Google Scholar

EU Chowdhury, LA Bisby, MF Green, VKR Kodur (2007). Investigation of insulated FRP-wrapped reinforced concrete columns in fire. Fire Safety Journal, 42: 452-460.

Crossref Google Scholar

JR Correia, FA Branco, JG Ferreira, Y Bai, T Keller (2010). Fire protection systems for building floors made of pultruded GFRP profiles: Part 1: Experimental investigations. Composites Part B: Engineering, 41: 617-629.

Crossref Google Scholar

S Dembele, RAF Rosario, JX Wen (2012). Thermal breakage of window glass in room fires conditions—Analysis of some important parameters. Building and Environment, 54: 61-70.

Crossref Google Scholar

Department of Treasury and Finance (2008). Office Buildings Standards. Melbourne: Government Services Group.

Y Dong, D Bhattacharyya (2014). Holistic approach and development on propylene (PP)/clay nanocomposites from processing, material characterization to numerical modeling. In: Y Dong (ed), Nanostructures: Properties, Production Methods and Applications, pp. 305-350. New York: Nova Science Publishers.

Google Scholar

ND Duc, PH Cong, VM Anh, VD Quang, P Tran, ND Tuan, NH Thinh (2015). Mechanical and thermal stability of eccentrically stiffened functionally graded conical shell panels resting on elastic foundations and in thermal environment. Composite Structures, 132: 597-609.

Crossref Google Scholar

A Ghazlan, TD Ngo, P Tran (2015). Influence of interfacial geometry on the energy absorption capacity and load sharing mechanisms of nacreous composite shells. Composite Structures, 132: 299-309.

Crossref Google Scholar

ISO 9705-1 (2013). ISO 9705-1:2013 Reaction to Fire Tests—Room corner Test for Wall and Ceiling Lining Products—Part 1: Test Method for Small Room Configuration.

R Harish, K Venkatasubbaiah (2014). Large eddy simulation of thermal plume behavior in horizontally partitioned dual enclosure. Building Simulation, 8: 137-148.

Crossref Google Scholar

G Imbalzano, P Tran, TD Ngo, PVS Lee (2015). Three-dimensional modelling of auxetic sandwich panels for localised impact resistance. Journal of Sandwich Structures and Materials, doi: .

Crossref Google Scholar

G Imbalzano, P Tran, TD Ngo, PVS Lee (2016). A numerical study of auxetic composite panels under blast loadings. Composite Structures, 135: 339-352.

Crossref Google Scholar

RM Lawson, RG Ogden, R Bergin (2012). Application of modular construction in high-rise buildings. Journal of Architectural Engineering, 18: 148-154.

Crossref Google Scholar

H Li, C Richards, J Watson (2014). High-performance glass fiber development for composite applications. International Journal of Applied Glass Science, 5: 65-81.

Crossref Google Scholar

T-H Liou (2003). Pyrolysis kinetics of electronic packaging material in a nitrogen atmosphere. Journal of Hazardous Materials, 103: 107-123.

Crossref Google Scholar

Y-L Liu, G-H. Hsiue, C-W Lan, Y-S Chiu (1997). Phosphorus-containing epoxy for flame retardance: IV. Kinetics and mechanism of thermal degradation. Polymer Degradation and Stability, 56: 291-299.

Crossref Google Scholar

K McGrattan, S Hostikka, J Floyd, H Baum, R Rehm (2010). Fire Dynamics Simulator (Version 5) Technical Reference Guide. NIST Special Publication. Washington DC: National Institute of Standards and Technology.

TD Ngo, QT Nguyen, TP Nguyen, P Tran (2016). Effect of nanoclay on thermomechanical properties of epoxy/glass fibre composites. Arabian Journal for Science and Engineering, 41: 1251-1261.

Crossref Google Scholar

QT Nguyen, TD Ngo, P Mendis, P Tran (2013). Composite materials for next generation building facade systems. Civil Engineering and Architecture, 1(3): 88-95.

Crossref Google Scholar

QT Nguyen, TD Ngo, P Tran, P Mendis, D Bhattacharyya (2015). Influences of clay and manufacturing on fire resistance of organoclay/thermoset nanocomposites. Composites Part A: Applied Science and Manufacturing, 74: 26-37.

Crossref Google Scholar

QT Nguyen, P Tran, TD Ngo, PA Tran, P Mendis (2014). Experimental and computational investigations on fire resistance of GFRP composite for building facade. Composites Part B: Engineering, 62: 218-229.

Crossref Google Scholar

S Pavlidou, CD Papaspyrides (2008). A review on polymer-layered silicate nanocomposites. Progress in Polymer Science, 33: 1119-1198.

Crossref Google Scholar

A Subasinghe, D Bhattacharyya (2014). Performance of different intumescent ammonium polyphosphate flame retardants in PP/kenaf fibre composites. Composites Part A: Applied Science and Manufacturing, 65: 91-99.

Crossref Google Scholar

MGM van der Heijden, MGLC Loomans, AD Lemaire, JLM Hensen (2013). Fire safety assessment of semi-open car parks based on validated CFD simulations. Building Simulation, 6: 385-394.

Crossref Google Scholar

M Zarzecki, JG Quintiere, RE Lyon, T Rossmann, FJ Diez (2013). The effect of pressure and oxygen concentration on the combustion of PMMA. Combustion and Flame, 160: 1519-1530.

Crossref Google Scholar

Building Simulation

Volume 9 Issue 5,
October 2016

Pages 607-616

DOI: 10.1007/s12273-016-0294-3

Cite this article:

Ngo TD, Nguyen QT, Tran P. Heat release and flame propagation in prefabricated modular unit with GFRP composite facades. Building Simulation, 2016, 9(5): 607-616. https://doi.org/10.1007/s12273-016-0294-3

542

Views

Crossref

N/A

Web of Science

Scopus

CSCD

Google Scholar
Citation

Altmetrics

Received: 16 November 2015

Revised: 08 April 2016

Accepted: 11 April 2016

Published: 10 May 2016