回転対向流双子火炎における圧力および輻射熱損失の影響  [in Japanese] Effect of Elavated-Pressure and Radiative Heat Loss on Rotating Counterflow Twin Flame  [in Japanese]

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Author(s)

    • 上道 茜 UEMICHI Akane
    • 東京大学大学院工学系研究科機械工学専攻 Department of Mechanical Engineering, The Univertisy of Tokyo
    • 大崎 靖雄 OSAKI Yasuo
    • 筑波大学大学院システム情報工学研究科構造エネルギー工学専攻 Department of Engineering Mechanics and Energy, University of Tsukuba
    • 西岡 牧人 NISHIOKA Makihito
    • 筑波大学大学院システム情報工学研究科構造エネルギー工学専攻 Department of Engineering Mechanics and Energy, University of Tsukuba

Abstract

<p>The effects of elevated-pressure on rotating counterflow twin flame were numerically investigated. The range of pressure is from 1 to 8 atm. We performed numerical simulations with and without radiative heat loss. The loss was evaluated by using an optically thin model, which does not consider reabsorption of radiative energy. Without radiation, the leanest extinction limits reached ultralean conditions; the higher the pressure is, the leaner the extinction limits are. On the other hand, with radiative heat loss, the leanest extinction limits are shifted to richer condition as the pressure becomes higher; above 2 atm, the leanest extinction limits cannot reach ultralean condition. The response curves of the flame temperature to the equivalence ratio are distorted when radiative heat loss is considered. Under high pressure, the flame thickness is thinner and the heat release rate is enhanced mainly because of the increase of gaseous density in the both cases of with and without radiation heat loss. However, the temperature behind the flame zone much decreases due to the radiative heat loss in the high pressure case. This is because of increments of partial pressures of the radiative species and the length of the residence time of fluid in the backflow region of burned gas.</p>

Journal

  • Journal of the Combustion Society of Japan

    Journal of the Combustion Society of Japan 57(179), 60-70, 2015

    Combustion Society of Japan

Codes

  • NII Article ID (NAID)
    130006320783
  • NII NACSIS-CAT ID (NCID)
    AA11658490
  • Text Lang
    JPN
  • ISSN
    1347-1864
  • NDL Article ID
    026101285
  • NDL Call No.
    Z17-645
  • Data Source
    NDL  J-STAGE 
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