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Flame lift-off

From Wikipedia, the free encyclopedia

Flame lift-off in oil fired pressure jet burners is an unwanted condition in which the flame and burner become separated. This condition is most commonly created by excessive combustion air and often results in the loss of flame as the photoelectric cell fails to register the light of the flame, this in turn results in a safety lockout of the control box.

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  • Lifted Diffusion Flame

Transcription

Other outcomes

Other outcomes may be experienced: –

  1. There may be delayed ignition as the oil spray is too far forward for the electrodes to ignite, only when the oil spray has filled the combustion chamber will the mixture ignite. In this condition it is likely that the excessive volume of unburnt oil will ignite with explosive ignition.
  2. The oil mixture will fail to ignite resulting in safety lockout of the control box.
  3. The oil mixture will ignite but may burn very inefficiently due to excessive air chilling of the oil particles to the point where complete combustion of the oil is not possible.

Flame lift-off height

A non-premixed jet flame has a tendency to lift off from the burner nozzle position when the jet velocity of the flame is over a critical value of .[1] With the increasing of the jet velocity, the lifted height will increase and when it's beyond certain critical height and the flame will be blown off.[2] Therefore, the stability of the lifted flame is an important parameter for basic combustor design. Scholefield and Garside's theory [3] claimed that the transition to turbulence is a prerequisite for the lifted diffusion flame stabilisation and the flame anchors at a point where the flow is turbulent. Gollahalli [4] argued that the flame will tend to stable at the position where the local flow velocity balance the normal flame propagation velocity. Navarro-Martinez and Kronenburg [5] have demonstrated that the excessive turbulent stretching at the nozzle leads to the lift-off and they also claimed that auto-ignition can be used to promote the flame stabilisation mechanism. Recently the observation from Kiran and Mishra's [6] visual experiment proved the flame lift-off height varies linearly with jet exit velocity. They presented a semi-empirical correlation between the normalized lift-off height to the nozzle exit diameter.

Where, : lift-off height

:diameter of the fuel tube

:fuel jet velocity

In addition to the velocity effect, The stoichiometric burning on the physical mechanism blowout has been investigated by Broadwell et al.[7] and Pitts.[8] According to their study on diffusion flame, the fresh air entrained by the vortices structure cools down and over dilutes the flame jet, which leads to the flame extinction.

References

  1. ^ Demare, David; Baillot, Françoise (2001-05-30). "The role of secondary instabilities in the stabilization of a nonpremixed lifted jet flame". Physics of Fluids. 13 (9): 2662–2670. doi:10.1063/1.1386935. ISSN 1070-6631.
  2. ^ Kiran, D.Y.; Mishra, D.P. (2007-07-01). "Experimental studies of flame stability and emission characteristics of simple LPG jet diffusion flame". Fuel. 86 (10–11): 1545–1551. doi:10.1016/j.fuel.2006.10.027. ISSN 0016-2361.
  3. ^ Scholefield, D.A.; Garside, J.E. (1948-01-01). "The structure and stability of diffusion flames". Symposium on Combustion and Flame, and Explosion Phenomena. 3 (1): 102–110. doi:10.1016/S1062-2896(49)80013-4. ISSN 1062-2896.
  4. ^ Gollahalli, S.R.; Savaş, Ö.; Huang, R.F.; Rodriquez Azara, J.L. (1988-01-01). "Structure of attached and lifted gas jet flames in hysteresis region". Symposium (International) on Combustion. 21 (1): 1463–1471. doi:10.1016/S0082-0784(88)80379-5. ISSN 0082-0784.
  5. ^ Navarro-Martinez, Salvador; Kronenburg, Andreas (2011-01-15). "Flame Stabilization Mechanisms in Lifted Flames". Flow, Turbulence and Combustion. 87 (2–3): 377–406. doi:10.1007/s10494-010-9320-1. ISSN 1386-6184. S2CID 121569571.
  6. ^ Kiran, D.Y.; Mishra, D.P. (2007-07-01). "Experimental studies of flame stability and emission characteristics of simple LPG jet diffusion flame". Fuel. 86 (10–11): 1545–1551. doi:10.1016/j.fuel.2006.10.027. ISSN 0016-2361.
  7. ^ Broadwell, James E.; Dahm, Werner J.A.; Mungal, M. Godfrey (1985-01-01). "Blowout of turbulent diffusion flames". Symposium (International) on Combustion. 20 (1): 303–310. doi:10.1016/S0082-0784(85)80515-4. ISSN 0082-0784.
  8. ^ Pitts, William M. (1989-01-01). "Assessment of theories for the behavior and blowout of lifted turbulent jet diffusion flames". Symposium (International) on Combustion. 22 (1): 809–816. doi:10.1016/S0082-0784(89)80090-6. ISSN 0082-0784.
This page was last edited on 16 October 2020, at 09:04
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