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Fire Technology

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24-09-2018

Experimental Study on Fire Behaviors of Kerosene/Additive Blends

Authors: Xuehui Wang, Yaping He, Tiannian Zhou, Qinpei Chen, Chao Ding, Jian Wang

Published in: Fire Technology | Issue 6/2018

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Abstract

The widely used fuels in practical are blended fuel whose combustion characteristics is more complex than those of the single-component fuel in real fire scenarios. The fire behaviors of aviation kerosene/diethylene glycol dimethyl ether (DGM) blends (R-D) and aviation kerosene/ethanol (R-E) blends were studied using a cone calorimeter. The parameters of pool fires, including the ignition time, burning rate, fuel temperature, heat release rate and combustion yield, were investigated. Janssens’ method was adopted to analyze the ignition times of the two blends. Two types of representative burning processes for blended fuel pool fires were identified. For R-D blends, the burning process is similar to that for typical pure fuels. The process for R-E blends, however, is novel, having two obvious burning processes due to the appearance of an intermediate decay stage. The fuel exhaust mass fraction (approximately 15%) was found to be almost constant throughout the intermediate decay stage. The fuel temperature during the experiment indicated that the liquid surface boiling temperature of R-D blends ranges from 162°C to 200°C depending upon the composition of these blends. For R-E blends, the initial boiling temperature is affected by the ethanol ratio, while the boiling temperature in the second process is equal to the boiling temperature of pure RP-3 kerosene. When the ethanol ratio is lower than 40%, the initial boiling temperature of R-E blends is approximately 120°C; when the ethanol ratio is higher than 40%, the boiling temperature is equal to the boiling point of ethanol. A method for calculating the burning rate of each component in the burning processes of the two blends is put forward, with the results agreeing well with the interpretation of the two burning processes. The ratio of the combustion yield CO₂/CO and the carbon conversion ratio increase with the oxygenated fuel ratio, indicating that the combustion is more complete when oxygenated fuel is added. These results will be useful for fire hazard assessment and firefighting in terms of fuel storage and transportation.

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Hayasaka H (1997) Unsteady burning rates of small pool fires. Fire Saf Sci 5: 499–510CrossRef

Orloff L, De Ris J (1982) Froude modeling of pool fires. Symp (Int) Combust 19(1): 885–895CrossRef

Cetegen BM, Ahmed TA (1993) Experiments on the periodic instability of buoyant plumes and pool fires. Combust Flame 93(1): 157–184CrossRef

Fay JA (2006) Model of large pool fires. J Hazard Mater 136(2): 219–232MathSciNetCrossRef

Chatris JM et al (2001) Experimental study of burning rate in hydrocarbon pool fires. Combust Flame 126(1–2): 1373–1383CrossRef

Jiang C et al (2016) Experimental study of burning rate in large-scale rectangular pool fire. J Fire Sci 34(4): 323–334CrossRef

Fischer SJ, Hardouin-Duparc B, Grosshandler WL (1987) The structure and radiation of an ethanol pool fire. Combust Flame 70(3): 291–306CrossRef

Planas-Cuchi E, Casal J (1998) Flame temperature distribution in a pool-fire. J Hazard Mater 62(3): 231–241CrossRef

Demenezes E et al (2006) Addition of an azeotropic ETBE/ethanol mixture in eurosuper-type gasolines. Fuel 85(17–18): 2567–2577CrossRef

10.

Withers JW, Quesada-Pineda HJ, Smith RL (2017) Bioeconomy survey results regarding barriers to the United States advanced biofuel industry. BioResources 12(2): 2846–2863CrossRef

11.

Manin J et al (2014) Effects of oxygenated fuels on combustion and soot formation/oxidation processes. SAE Int J Fuels Lubr 7(2657): 704–717CrossRef

12.

Xu Y, Avedisian CT (2015) Combustion ofn-butanol, gasoline, andn-butanol/gasoline mixture droplets. Energy Fuels 29(5): 3467–3475CrossRef

13.

Imtenan S et al (2014) Impact of oxygenated additives to palm and jatropha biodiesel blends in the context of performance and emissions characteristics of a light-duty diesel engine. Energy Convers Manag 83: 149–158CrossRef

14.

Park W et al (2017) The effect of oxygenated fuel properties on diesel spray combustion and soot formation. Combust Flame 180: 276-283.CrossRef

15.

Barrios CC et al (2014) Effects of the addition of oxygenated fuels as additives on combustion characteristics and particle number and size distribution emissions of a TDI diesel engine. Fuel 132: 93–100CrossRef

16.

Kohse-Hoinghaus K et al (2010) Biofuel combustion chemistry: from ethanol to biodiesel. Angew Chem Int Ed Engl 49(21): 3572–3597CrossRef

17.

Shi K, Spindler K, Hahne E (2010) Heat transfer in nucleate boiling of R134a/R152a mixtures. Heat Mass Transf 46(10): 1137–1145CrossRef

18.

Gong M et al (2013) Visualization study on nucleate pool boiling of ethane, isobutane and their binary mixtures. Exp Therm Fluid Sci 51: 164–173CrossRef

19.

Li D et al (2009) Effects of dimethyl or diethyl carbonate as an additive on volatility and flash point of an aviation fuel. J Hazard Mater 161(2–3): 1193–201CrossRef

20.

Ding Y, Wang C, Lu S (2014) The effect of azeotropism on combustion characteristics of blended fuel pool fire. J Hazard Mater 271: 82–88CrossRef

21.

Ben Amara A, Kaoubi S, Starck L (2016) Toward an optimal formulation of alternative jet fuels: enhanced oxidation and thermal stability by the addition of cyclic molecules. Fuel 173: 98–105CrossRef

22.

Won SH et al (2016) Predicting the global combustion behaviors of petroleum-derived and alternative jet fuels by simple fuel property measurements. Fuel 168: 34–46CrossRef

23.

Pei X, Hou L (2016) Secondary flow and oxidation coking deposition of aviation fuel. Fuel 167: 68–74CrossRef

24.

Ghamari M, Ratner A (2016) Combustion characteristics of diesel and Jet-A droplets blended with polymeric additive. Fuel 178: 63–70CrossRef

25.

Zhang C et al (2016) Recent development in studies of alternative jet fuel combustion: Progress, challenges, and opportunities. Renew Sustain Energy Rev 54: 120–138CrossRef

26.

Dabbagh HA et al (2013) The influence of ester additives on the properties of gasoline. Fuel 104: 216–223CrossRef

27.

Liu H, Hu B, Jin C (2016) Effects of different alcohols additives on solubility of hydrous ethanol/diesel fuel blends. Fuel 184: 440–448CrossRef

28.

Rubino L, Thomson MJ (1999) The effect of oxygenated additives on soot precursor formation in a counterflow diffusion flame. SAE Technical Paper

29.

Hoon Song K et al (2003) Effects of oxygenated additives on aromatic species in fuel-rich, premixed ethane combustion: a modeling study. Combust Flame 135(3): 341–349CrossRef

30.

Beatrice C, Bertoli C, Giacomo ND (1998) New findings on combustion behavior of oxygenated synthetic diesel fuels. Combust Sci Technol 137(1–6): 31–50CrossRef

31.

Huang ZH et al (2006) Combustion and emission characteristics of a compression ignition engine fuelled with Diesel–dimethoxy methane blends. Energy Convers Manag 47(11–12): 1402–1415CrossRef

32.

Chiariello F et al (2014) Gaseous and particulate emissions of a micro gas turbine fuelled by straight vegetable oil–kerosene blends. Exp Therm Fluid Sci 56: 16–22CrossRef

33.

Mendez C, Parthasarathy R, Gollahalli S (2014) Performance and emission characteristics of butanol/Jet A blends in a gas turbine engine. Appl Energy 118: 135–140CrossRef

34.

Mendez C, Parthasarathy R, Gollahalli S (2012) Performance and emission characteristics of a small-scale gas turbine engine fueled with ethanol/Jet A blends. In: 50th AIAA Aerospace Sciences Meeting including the New Horizons Forum and Aerospace Exposition. p 522

35.

Ji J et al (2016) Experimental study on initial temperature influence on flame spread characteristics of diesel and gasoline–diesel blends. Fuel 178: 283–289CrossRef

36.

Baloo M et al (2016) Effects of pressure and temperature on laminar burning velocity and flame instability of iso-octane/methane fuel blend. Fuel 170: 235–244CrossRef

37.

Li X et al (2011) Convective heat transfer characteristics of China RP-3 aviation kerosene at supercritical pressure. Appl Therm Eng 31(14–15): 2360–2366CrossRef

38.

Demirbas A (2009) Emission characteristics of gasohol and diesohol. Energy Sour Part A Recovery Util Environ Effects 31(13): 1099–1104CrossRef

39.

Arul Mozhi Selvan V, Anand RB, Udayakumar M (2009) Combustion characteristics of diesohol using biodiesel as an additive in a direct injection compression ignition engine under various compression ratios. Energy Fuels 23(11): 5413–5422CrossRef

40.

Patra J et al (2015) Studies of combustion characteristics of kerosene ethanol blends in an axi-symmetric combustor. Fuel 144: 205–213CrossRef

41.

Arteconi A, Mazzarini A, Di Nicola G (2011) Emissions from ethers and organic carbonate fuel additives: a review. Water Air Soil Pollution 221(1–4): 405–423CrossRef

42.

Poling BE, Prausnitz JM, O’connell JP (2001) The properties of gases and liquids, vol 5. Mcgraw-hill, New York

43.

Pei X-Y, Hou L-Y (2016) Effect of dissolved oxygen concentration on coke deposition of kerosene. Fuel Process Technol 142: 86–91CrossRef

44.

Liu H et al (2011) Comparison of ethanol and butanol as additives in soybean biodiesel using a constant volume combustion chamber. Energy Fuels 25(4): 1837–1846CrossRef

45.

Wu N, Torero JL (1998) Enhanced burning of difficult to ignite/burn fuels including heavy oils. US Department of Commerce, National Institute of Standards and Technology, Maryland

46.

Wu N et al (1998) The effect of weathering on piloted ignition and flash point of a slick of oil. In: Arctic and marine oilspill program technical seminar. Ministry of supply and services, Canada

47.

Putorti A, Evans D, Tennyson E (1994) Ignition of weathered and emulsified oils. In: Arctic and marine oilspill program technical seminar. Ministry of supply and services, Canada

48.

Lawson D, Simms UD (1952) The ignition of wood by radiation. Br J Appl Phys 3(9): 288CrossRef

49.

Babrauskas V (2003) Ignition handbook, vol 98027. Fire Science Publishers, Issaquah

50.

Chen X et al (2014) Experimental study on ignition and combustion characteristics of typical oils. Fire Mater 38(3): 409–417CrossRef

51.

Chen B et al (2011) Initial fuel temperature effects on burning rate of pool fire. J Hazard Mater 188(1–3): 369–374CrossRef

52.

Liu J et al (2016) The burning behaviors of pool fire flames under low pressure. Fire Mater 40(2): 318–334CrossRef

53.

Zhang J et al (2012) Impacts of elevation on pool fire behavior in a closed compartment: a study based upon a distinct stratification phenomenon. J Fire Sci 31(2): 178–193CrossRef

Title: Experimental Study on Fire Behaviors of Kerosene/Additive Blends
Authors: Xuehui Wang
Yaping He
Tiannian Zhou
Qinpei Chen
Chao Ding
Jian Wang
Publication date: 24-09-2018
Publisher: Springer US
Published in: Fire Technology / Issue 6/2018
Print ISSN: 0015-2684
Electronic ISSN: 1572-8099
DOI: https://doi.org/10.1007/s10694-018-0776-1

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