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Flame downwash length evolution of non-premixed gaseous fuel jets in cross-flow: Experiments and a new correlation

Author

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  • Shang, Fengju
  • Hu, Longhua
  • Sun, Xiepeng
  • Wang, Qiang
  • Palacios, Adriana

Abstract

Flame downwash behavior (flame pulled by the wake flow and attached to the leeward side of the nozzle) of gaseous fuel jets in cross-flow is of much practical importance in the design of burners as well as industrial flare, and thus important for energy conversion and conservation; however, the studies are still very limited. The critical condition (i.e., critical cross-flow air speed) for flame downwash occurrence as well as the evolution of flame downwash length for various fuel jet exit velocities has not been quantified yet. In this work, the flame downwash length evolution of non-premixed jets for different pipe nozzle diameters at various fuel discharge velocities and cross-flow air speeds as well as the critical condition under which the flame downwash occurs have been quantified comprehensively. Pipe nozzles with inner diameters of 8, 10, 13 and 15mm were employed in the experiments, using propane as the fuel and with fuel jet velocities ranging between 0.38 and 2.42m/s. The experimental results showed that the flame downwash length increased with increasing cross-flow air speed for a given fuel jet exit velocity. It was also found that, with increasing cross-flow air speed, the downwash length increased more rapidly for the higher fuel jet exit velocity than that for the lower fuel jet velocity. The critical cross-flow air speed, when flame downwash occurs, was found to be little dependent on the nozzle diameter but increase with the fuel jet exit velocity following a linear relationship. A new correlation for flame downwash length was proposed based on physically the coupling effects due to the competition of the fuel jet momentum to the cross-flow momentum and the total fuel mass supply. The proposed correlation was shown to well characterize the flame downwash length in terms of nozzle inner diameters, dimensionless fuel mass flow rates and the jet momentum ratio. The findings of this work provide basic knowledge and have potential practical applications for burner design and flare implementation, which allow predictions to be made regarding the possible threat and the establishment of the necessary safety length for the stack to prevent the damage for reducing the potential risk.

Suggested Citation

  • Shang, Fengju & Hu, Longhua & Sun, Xiepeng & Wang, Qiang & Palacios, Adriana, 2017. "Flame downwash length evolution of non-premixed gaseous fuel jets in cross-flow: Experiments and a new correlation," Applied Energy, Elsevier, vol. 198(C), pages 99-107.
  • Handle: RePEc:eee:appene:v:198:y:2017:i:c:p:99-107
    DOI: 10.1016/j.apenergy.2017.04.043
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    References listed on IDEAS

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    1. Choy, Y.S. & Zhen, H.S. & Leung, C.W. & Li, H.B., 2012. "Pollutant emission and noise radiation from open and impinging inverse diffusion flames," Applied Energy, Elsevier, vol. 91(1), pages 82-89.
    2. Porzio, Giacomo Filippo & Nastasi, Gianluca & Colla, Valentina & Vannucci, Marco & Branca, Teresa Annunziata, 2014. "Comparison of multi-objective optimization techniques applied to off-gas management within an integrated steelwork," Applied Energy, Elsevier, vol. 136(C), pages 1085-1097.
    3. Huang, X.Q. & Leung, C.W. & Chan, C.K. & Probert, S.D., 2006. "Thermal characteristics of a premixed impinging circular laminar-flame jet with induced swirl," Applied Energy, Elsevier, vol. 83(4), pages 401-411, April.
    4. Lawal, Mohammed S. & Fairweather, Michael & Gogolek, Peter & Ingham, Derek B. & Ma, Lin & Pourkashanian, Mohamed & Williams, Alan, 2013. "CFD predictions of wake-stabilised jet flames in a cross-flow," Energy, Elsevier, vol. 53(C), pages 259-269.
    5. Lee, Woo Jin & Shin, Hyun Dong, 2003. "Visual characteristics, including lift-off, of the jet flames in a cross-flow high-temperature burner," Applied Energy, Elsevier, vol. 76(1-3), pages 257-266, September.
    6. Akbari, M.H. & Riahi, P. & Roohi, R., 2009. "Lean flammability limits for stable performance with a porous burner," Applied Energy, Elsevier, vol. 86(12), pages 2635-2643, December.
    7. Rashwan, Sherif S. & Ibrahim, Abdelmaged H. & Abou-Arab, Tharwat W. & Nemitallah, Medhat A. & Habib, Mohamed A., 2016. "Experimental investigation of partially premixed methane–air and methane–oxygen flames stabilized over a perforated-plate burner," Applied Energy, Elsevier, vol. 169(C), pages 126-137.
    8. Zhen, H.S. & Choy, Y.S. & Leung, C.W. & Cheung, C.S., 2011. "Effects of nozzle length on flame and emission behaviors of multi-fuel-jet inverse diffusion flame burner," Applied Energy, Elsevier, vol. 88(9), pages 2917-2924.
    9. Terracciano, Anthony Carmine & Vasu, Subith S. & Orlovskaya, Nina, 2016. "Design and development of a porous heterogeneous combustor for efficient heat production by combustion of liquid and gaseous fuels," Applied Energy, Elsevier, vol. 179(C), pages 228-236.
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    1. Zhang, Xiaolei & Hu, Longhua & Delichatsios, Michael A. & Zhang, Jianping, 2019. "Experimental study on flame morphologic characteristics of wall attached non-premixed buoyancy driven turbulent flames," Applied Energy, Elsevier, vol. 254(C).
    2. Wang, Qiang & Tang, Fei & Zhou, Zheng & Liu, Huan & Palacios, Adriana, 2017. "Flame height of axisymmetric gaseous fuel jets restricted by parallel sidewalls: Experiments and theoretical analysis," Applied Energy, Elsevier, vol. 208(C), pages 1519-1526.
    3. Li, Xin & Hu, Longhua & Shang, Fengju, 2018. "Flame downwash transition and its maximum length with increasing fuel supply of non-premixed jet in cross flow," Energy, Elsevier, vol. 164(C), pages 298-305.
    4. Sun, Xiepeng & Zhang, Xiaolei & Lv, Jiang & Chen, Xiaotao & Hu, Longhua, 2023. "Experimental study on the buoyant turbulent diffusion flame height of various intermittent levels," Applied Energy, Elsevier, vol. 351(C).

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