Fire severity prediction analysis of a traditional libya house roofing materials: A case study

Authors

  • M. Mkharem Faculty of Engineering, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
  • N. M. Adam Faculty of Engineering, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
  • E.E. Supeni Faculty of Engineering, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
  • S. Mustapha Faculty of Engineering, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia

DOI:

https://doi.org/10.15282/jmes.11.3.2017.15.0266

Keywords:

Date palm tree; fire safety; fire propagation; calorimetric.

Abstract

Most recorded Libya house fire accidents are associated with the types of roofing materials used in the building of the traditional Libya houses, mainly from the date palm trees (DPT) parts. This research focuses on the fire characteristic properties of DPT building material based on four conducted laboratory experiments on the preprocessed known mass of leaves, trunk, and root samples collected across 40, 41, 80, and 81 years old trees, across different geographical location in Libya. The characterisation analyses result of calorific energy contribution of 4107.2 cal/gram from older DPT trunk samples, percentage weight loss reduction of -2.2 mg / ᵒC, at the highest temperature range of 727- 899 ᵒC from thermogravimetric test. The highest diffusivity rate of 0.138 mm2 /s also occurs at 99–100 ᵒC on the oldest trunk sample, and fire propagation index of 0.0463 was recorded with index performance of 32.3 ᵒC. These result analyses indicated high heat conductivity at a lower temperature, fast heat rate of propagation to support fire accident when in contact with fire flame, and high calorific load value for fire growth in traditional Libya houses. Useful information on rate of heat conductivity, fire propagation properties, and thermal behaviours of DPT for fire impact assessment analyses prediction in traditional Libya houses.

References

Black WZ. Smoke movement in elevator shafts during a high-rise structural fire. Fire Safety Journal. 2009;2009:168–82.

Yassine E, Mejdi J, Sophie D, Gwenaëlle T, Rachid S. Evaluation of date palm residues combustion in fixed bed laboratory reactor: A comparison with sawdust behaviour. Renewable Energy. 2014;2014:209e15.

ZHANG Q-s, WEI H-y. The Characteristic Fire Protection Design of Mountainous City and Hillside Building - Illustrated by the Example of Chongqing. Procedia Engineering. 2011;2011:701–9.

Tomoaki N, Takeyoshi T, Akihiko H. An evaluation method for the urban post-earthquake fire risk considering multiple scenarios of fire spread and evacuation. Fire Safety Journal. 2012;2012:167–80.

Jing X, Chongfu H. Fire risk analysis of residential buildings based on scenario clusters and its application in fire risk management. Fire Safety Journal. 2013;2013:72–8.

Donggoo S, Dongeun K, Bongchan K, Youngjin K. An experimental study on the combustibles investigation and fire growth rate for predicting initial fire behavior in building. Procedia Engineering. 2013;2013:671 – 9.

Martin F, Beom-Seon J, Yanlin J. A parametric study on the use of passive fire protection in FPSO topside module. Int J Nav Archit Ocean Eng. 2014;2014:826~39.

Anthony CYY, Guan HY, Bob A, Cook M. Fire scene investigation of an arson fire incident using computational fluid dynamics based fire simulation. Building Simulation. 2014;2014.

Brian YL, Sean PH, Mark W, Usman S. Modeling fire growth in a combustible corner. Fire Safety Journal. 2003;2003:771–96.

Mari-Louise P, Arne R, Maria W. Influence of window size on the energy balance of low energy houses. Energy and Buildings. 2006;2006:181–8.

Jonatan G, Haukur I, Anders L, Håkan F, Michael S. Performance-based design of road tunnel fire safety: Proposal of new Swedish framework. Case Studies in Fire Safety. 2014;2014:18–28.

LIU J, CHOW WK. Determination of fire load and heat release rate for high-rise residential buildings. Procedia Engineering. 2014;2014:491 – 7.

Dan Nortoft S, Lars Kollgaard V. Modelling low and heat transfer around a seated human body by computational liquid dynamics. Building and Environment. 2003;2003:753–62.

Lu¨ X-c, Yang J-g, Zhang W-g, Huang Z. Effect of cetane number improver on heat release rate and emissions of high speed diesel engine fueled with ethanol–diesel blend fuel. Fuel. 2004;2004:2013–20.

Alex B. An Overview of Design Fires for Building Compartments. Fire Technology. 2008:167–84.

Zhou B, Zhou X-m, Chao M-y. Fire protection of historic buildings: A case study of Group-living Yard in Tianjin. Journal of Cultural Heritage. 2012;2012:389–96.

Juan PH, Stephen W, José LT. Performance criteria for the fire safe use of thermal insulation in buildings. Construction and Building Materials. 2015;2015:285–97.

Gianluca DS, Mario F. Risk-based optimisation of fire safety egress provisions based on the LQI acceptance criterion. Reliability Engineering and System Safety. 2016;2016:339–50.

Xinfeng L, Xueqin Z, Bo L. Numerical simulation of dormitory building fire and personnel escape based on Pyrosim and Pathfinder. Journal of the Chinese Institute of Engineers. 2017;2017:2158-7299.

Hadjisophocleous G, Jia Q. Comparison of FDS Prediction of Smoke Movement in a 10-Storey Building with Experimental Data. Fire Technology. 2009;2009:163–77.

Donghyun R, Atila N. Transport of particulate and gaseous pollutants in the vicinity of a human body. Building and Environment. 2009;2009:1840–9.

Black WZ. COSMO—Software for designing smoke control systems in high-rise buildings. Fire Safety Journal. 2010;2010:337–48.

Yassine Em, Mejdi J, Sophie D, Gwenaelle T, Rachid S. Experimental investigation on gaseous emissions from the combustion of date palm residues in laboratory scale furnace. Bioresource Technology. 2013;2013:94–100.

Azhakesan A, Shields TJ, Silcock GWH. Developments on the Fire Propagation Test. . Fire Safety Science. 2012:349–60.

Azuin R, Zainal AA, Mohd Idrus MM. Safety and Health Factors Influencing Performance of Malaysian Low-Cost Housing: Structural Equation Modeling (SEM) Approach. Procedia - Social and Behavioral Sciences. 2014;2014:475 – 82.

Yuen ACY, Yeoh GH, Alexander R, Cook M. Fire scene reconstruction of a furnished compartment room in a house fire. Case Studies in Fire Safety. 2014;2014:29–35.

Ahmad A, Ahmad MH, Khalifa A-K. Characterization of treated date palm tree fiber as composite reinforcement. Composites: Part B. 2009;2009:601–6.

Shyam SS, Ashok KS, Bhesh RB. A new method of producing date powder granules: Physicochemical characteristics of powder. Journal of Food Engineering. 2008;2008:416–21.

Yang X, Chen S, Gao S, Li H, Shi Q. Construction of a rotating-bomb combustion calorimeter and measurement of thermal effects. Instrumentation Science & Technology. 2002;3:311–21.

Ines M-G, Samia B, Abir M, Sabine D, Hamadi A, Christophe B, et al. Effect of ultrafiltration process on physico-chemical, rheological, microstructure and thermal properties of syrups from male and female date palm saps. Food Chemistry. 2016;2016:175–82.

Alireza D, Sara MA, Mariam AA-M, Azman H, Mat UW. Mechanical and thermal properties of date palm leaf fiber reinforced recycled poly (ethylene terephthalate) composites. Materials and Design. 2013;2013:841–8.

Yassine Em, Mejdi J, Sophie D, Gwenaelle T, Rachid S. Study on the thermal behavior of different date palm residues: Characterization and devolatilization kinetics under inert and oxidative atmospheres. Energy. 2012;2012:702e9.

Hani HS, Ahmad H, Arshad AS, Farid NA. Pyrolysis and combustion kinetics of date palm biomass using thermogravimetric analysis. Bioresource Technology. 2012;2012:382–9.

Hamdy I, Mahmoud F, Hassan M, Sherif M. Characteristics of starch-based biodegradable composites reinforced with date palm and flax fibers. Carbohydrate Polymers. 2014;2014:11– 9.

Nehdi I, Omri S, Khalil MI, Al-Resayes SI. Characteristics and chemical composition of date palm (Phoenix canariensis) seeds and seed oil. Industrial Crops and Products. 2010;2010:360–5.

Khiari R, Mhenni MF, Belgacem MN, Mauret E. Chemical composition and pulping of date palm rachis and Posidonia oceanica –A comparison with other wood and non-wood fibre sources. Bioresource Technology. 2010;2010:775–80.

Boudjemaa A, Adel B, Abderrahim B, Laurent I, Magali F. Renewable materials to reduce building heat loss: Characterization of date palm wood. Energy and Buildings. 2011;2011.

Khadija MZ, Deepalekshmi P, Mariam AAA-M. Date palm fibre filled recycled ternary polymer blend composites with enhanced flame retardancy. Polymer testing. 2017;2017:341-8.

Keramat Jahromi M, Jafari A, Rafiee S, Mohtasebi SS. A survey on some physical properties of the Date Palm tree. Journal of Agricultural Technology 2007;2:317–22.

Mohamad RI, Zulkiflle L, Mohd Sapuan S, Mohd Zaki AR, Mohd Khairun AU, Akhtar R. IFSS, TG, FT-IR spectra of impregnated sugar palm (Arenga pinnata) fibres and mechanical properties of their composites. J Therm Anal Calorim. 2012;2012:1375–83.

Ishak MR, Sapuan SM, Leman Z, Rahman MZA, Anwar UMK. Characterization of sugar palm (Arenga pinnata) fibres. J Therm Anal Calorim. 2012;2012:981–9.

Downloads

Published

2017-09-30

How to Cite

[1]
M. Mkharem, N. M. Adam, E.E. Supeni, and S. Mustapha, “Fire severity prediction analysis of a traditional libya house roofing materials: A case study ”, J. Mech. Eng. Sci., vol. 11, no. 3, pp. 2952–2966, Sep. 2017.

Similar Articles

<< < 3 4 5 6 7 8 

You may also start an advanced similarity search for this article.