Numerical Simulation of a Supersonic Flow Chemical Oxygen-Iodine Laser Solving Navier-Stokes Equations
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概要
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The reaction zone structure of asupersonic flow chemical oxygen-iodine laser(COIL)is simulated solving the two-dimensional Navier-Stokes squations in order to clarify the reaction zone structure and the effects of water vapor condensation precisely. A chemical kinetic model consisting of 10 chemical species and 21 chemical reactions is used to determine the chemical composition of the mixture. The liquid phase is modeled as a number of droplet classes. Each class contains only droplets of a certain range of sizes, which is approximated as one average size. The calculation shows that the I_2 gas injected into the singlet oxygen through a two-dimensional slit mixes very slowly and the small signal gain coefficient is high only in a narrow layer where the mole fraction of I(^2P_<1 / 2>)reaches a high value. Nonequilibrium condensation takes place during supersonic expansion, generating water droplets whose size much smaller than the wave length of COIL. Condensation reduces the small signal gain coefficient, since the temperature rise caused by latent heat suppresses the generation of I(^2P_<1 / 2>).
- 一般社団法人日本機械学会の論文
- 1997-02-15
著者
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Masuda Wataru
Faculty Of Engineering Nagaoka University Of Technology
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Satoh Miyako
Faculty Of Engineering Nagaoka University Of Technology
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FUJII Hiroo
Kanto Technical Institute, Kawasaki Heavy Industries, Ltd.
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ATSUTA Toshio
Kanto Technical Institute, Kawasaki Heavy Industries, Ltd.
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Fujii Hiroo
Kanto Technical Institute Kawasaki Heavy Industries Ltd.
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Atsuta Toshio
Kanto Technical Institute Kawasaki Heavy Industries Ltd.
関連論文
- Effects of Injection of Various Gases on the Gain Characteristics of a Supersonic Flow CO Chemical Laser
- Numerical Simulation of Supersonic Flow CO Chemical Laser Solving Navier-Stokes Equations
- Effects of Nozzle Contour on the Aerodynamic Characteristics of Underexpanded Annular Impinging Jets
- Effects of Water Vapor Condensation on the Performance of Supersonic Flow Chemical Oxygen-Iodine Laser
- Three-Dimensional Mixing / Reacting Zone Structure in a Supersonic Flow Chemical Oxygen-Iodine Laser
- Numerical Simulation for the Power of a Supersonic Flow CO Chemical Laser Using a Leaky Stream Tube Approach
- Numerical Simulation of a Supersonic Flow Chemical Oxygen-Iodine Laser Solving Navier-Stokes Equations
- Mixing and Reacting Zone Structure in a Supersonic Mixing Chemical Oxygen-Iodine Laser with Ramp Nozzle Array
- Characteristics of Radiation from a supersonic Flow Chemical Oxygen-Iodine Laser
- Effects of Wall Catalysis on the Reacting Zone Structure of a Supersonic Flow Chemical Oxygen-Iodine Laser
- Aerodynamic Characteristics of Underexpanded Coaxial Impinging Jets
- Numerical Analysis for the Power of a Supersonic Flow CO Chemical Laser
- Characteristics of Radiation from a Q-Switched Supersonic Flow Chemical Oxygen-Iodine Laser
- Numerical Analysis on the Reaction Zone Structure of a Supersonic Flow CO Chemical Laser
- Investigation on the Theoretical Modeling of a Supersonic Flow CO Chemical Laser
- Measurements of Small Signal Gain Coefficients of a Supersonic Flow CO Chemical Laser
- Numerical Simulation of an N_2O Downstream Mixing Gasdynamic Laser