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    Combustion and Evaporation of Deformable Fuel Droplets

    Source: ASME Journal of Heat and Mass Transfer:;2023:;volume( 145 ):;issue: 010::page 101006-1
    Author:
    Setiya, Meha
    ,
    Palmore Jr., John
    DOI: 10.1115/1.4062784
    Publisher: The American Society of Mechanical Engineers (ASME)
    Abstract: This study focuses on combustion and evaporation of an isolated freely deforming fuel droplet under convective flow. The droplet shape is modified by varying Weber number at moderate Reynolds numbers. A simplified chemical reaction mechanism is used for combustion modeling. The Direct Numerical Simulation (DNS) results show a net positive effect of Weber number on total evaporation rate (m˙) for both pure evaporation and combustion cases. The enhancement in m˙ for higher Weber number reaches up to 9% for combustion. A nonspherical envelope flame is observed which grows with time. The Damköhler number is higher than 1 for this flame type which leads to faster reaction rates in comparison to evaporation. Hence, the combustion process is seen to be unaffected by droplet shape. An additional comparison between 3-D and 2-D combustion results is performed to understand if 2-D studies can reflect the right physical aspects of this problem. It is found that local evaporation flux in 2-D is 42.5% lower due to lower temperature gradients near the droplet surface for the same inflow velocity. The deformation of droplet is significantly different in 2-D which affects the boundary layer development and the wake flow. This is seen to affect the flame shape at the downstream of droplet. Hence, the 2-D simulations do not recover the correct behaviors.
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      Combustion and Evaporation of Deformable Fuel Droplets

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    http://yetl.yabesh.ir/yetl1/handle/yetl/4294390
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    contributor authorSetiya, Meha
    contributor authorPalmore Jr., John
    date accessioned2023-11-29T18:47:59Z
    date available2023-11-29T18:47:59Z
    date copyright7/17/2023 12:00:00 AM
    date issued7/17/2023 12:00:00 AM
    date issued2023-07-17
    identifier issn2832-8450
    identifier otherht_145_10_101006.pdf
    identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4294390
    description abstractThis study focuses on combustion and evaporation of an isolated freely deforming fuel droplet under convective flow. The droplet shape is modified by varying Weber number at moderate Reynolds numbers. A simplified chemical reaction mechanism is used for combustion modeling. The Direct Numerical Simulation (DNS) results show a net positive effect of Weber number on total evaporation rate (m˙) for both pure evaporation and combustion cases. The enhancement in m˙ for higher Weber number reaches up to 9% for combustion. A nonspherical envelope flame is observed which grows with time. The Damköhler number is higher than 1 for this flame type which leads to faster reaction rates in comparison to evaporation. Hence, the combustion process is seen to be unaffected by droplet shape. An additional comparison between 3-D and 2-D combustion results is performed to understand if 2-D studies can reflect the right physical aspects of this problem. It is found that local evaporation flux in 2-D is 42.5% lower due to lower temperature gradients near the droplet surface for the same inflow velocity. The deformation of droplet is significantly different in 2-D which affects the boundary layer development and the wake flow. This is seen to affect the flame shape at the downstream of droplet. Hence, the 2-D simulations do not recover the correct behaviors.
    publisherThe American Society of Mechanical Engineers (ASME)
    titleCombustion and Evaporation of Deformable Fuel Droplets
    typeJournal Paper
    journal volume145
    journal issue10
    journal titleASME Journal of Heat and Mass Transfer
    identifier doi10.1115/1.4062784
    journal fristpage101006-1
    journal lastpage101006-11
    page11
    treeASME Journal of Heat and Mass Transfer:;2023:;volume( 145 ):;issue: 010
    contenttypeFulltext
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