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      COMPUTATIONAL STUDY OF RAREFIED FLOW INSIDE A LID DRIVEN CAVITY USING A MIXED MODAL DISCONTINUOUS GALERKIN METHOD

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      https://www.riss.kr/link?id=A105614397

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      With the advancement of fabrication technology and miniaturization, fluid flows at micro- and nanoscales has received considerable attention. Flow characteristics in these systems significantly vary from those of macro- scale devices, due to geometric restrictions. In such cases, Navier-Stokes-Fourier(NSF) equations with no-slip condition may not be valid for studying gas flows inside a micro- cavity. This article therefore investigates the cavity flows using modified NSF equations with velocity slip and temperature jump conditions. In the present case, a monatomic gas is considered for modelling gas flows. To accurately predict the flow physics, mixed modal discontinuous Galerkin(DG) method is being developed. The flow characteristics of monatomic gas is studied by varying the Reynolds number(Re) and Knudsen number(Kn), respectively. Results obtained are compared with the previous results and are found to be in good agreement with them.
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      With the advancement of fabrication technology and miniaturization, fluid flows at micro- and nanoscales has received considerable attention. Flow characteristics in these systems significantly vary from those of macro- scale devices, due to geometric...

      With the advancement of fabrication technology and miniaturization, fluid flows at micro- and nanoscales has received considerable attention. Flow characteristics in these systems significantly vary from those of macro- scale devices, due to geometric restrictions. In such cases, Navier-Stokes-Fourier(NSF) equations with no-slip condition may not be valid for studying gas flows inside a micro- cavity. This article therefore investigates the cavity flows using modified NSF equations with velocity slip and temperature jump conditions. In the present case, a monatomic gas is considered for modelling gas flows. To accurately predict the flow physics, mixed modal discontinuous Galerkin(DG) method is being developed. The flow characteristics of monatomic gas is studied by varying the Reynolds number(Re) and Knudsen number(Kn), respectively. Results obtained are compared with the previous results and are found to be in good agreement with them.

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      참고문헌 (Reference)

      1 Gad-el-Hak, M., "The fluid mechanics of microdevices - The freeman scholar lecture" 121 : 5-33, 1999

      2 Naris, S., "The driven cavity flow over the whole range of the Knudsen number" 17 : 2005

      3 Cockburn, B., "The Runge-Kutta discontinuous Galerkin method for conservation laws V: multidimensional systems" 141 : 199-224, 1998

      4 Eskandari, M., "On the time relaxed Monte Carlo computations for the lid-driven cavity flow" 343 : 355-367, 2017

      5 Maxwell, J.C., "On stresses in rarefied gases arising from inequalities of temperature" 170 : 231-256, 1879

      6 Jie, D., "Navier-Stokes simulations of gas flow in mciro devices" 10 : 372-379, 2000

      7 Ismael, M.A., "Mixed convection in a lid-driven square cavity with partial slip" 8 : 47-61, 2014

      8 Karniadakis, M., "Microflows and Nanoflows: Fundamentals and Simulation" Springer-Verlag 2005

      9 John, B., "Investigation of heat and mass transfer in a lid-driven cavity under non-equilibrium flow conditions" 58 : 287-303, 2010

      10 Ghia, U., "High-Re solutions for incompressible flow using the Navier-Stokes equations and a multigrid method" 48 : 387-411, 1982

      1 Gad-el-Hak, M., "The fluid mechanics of microdevices - The freeman scholar lecture" 121 : 5-33, 1999

      2 Naris, S., "The driven cavity flow over the whole range of the Knudsen number" 17 : 2005

      3 Cockburn, B., "The Runge-Kutta discontinuous Galerkin method for conservation laws V: multidimensional systems" 141 : 199-224, 1998

      4 Eskandari, M., "On the time relaxed Monte Carlo computations for the lid-driven cavity flow" 343 : 355-367, 2017

      5 Maxwell, J.C., "On stresses in rarefied gases arising from inequalities of temperature" 170 : 231-256, 1879

      6 Jie, D., "Navier-Stokes simulations of gas flow in mciro devices" 10 : 372-379, 2000

      7 Ismael, M.A., "Mixed convection in a lid-driven square cavity with partial slip" 8 : 47-61, 2014

      8 Karniadakis, M., "Microflows and Nanoflows: Fundamentals and Simulation" Springer-Verlag 2005

      9 John, B., "Investigation of heat and mass transfer in a lid-driven cavity under non-equilibrium flow conditions" 58 : 287-303, 2010

      10 Ghia, U., "High-Re solutions for incompressible flow using the Navier-Stokes equations and a multigrid method" 48 : 387-411, 1982

      11 Shu, J.J., "Fluid velocity slip and temperature jump at a solid surface" 69 : 2017

      12 Mizzi, S., "Effects of rarefaction on cavity flow in the slip regime" 4 : 817-822, 2007

      13 Le, B.Q., "Discontinuous Finite Elements in Fluid Dynamics and Heat Transfer" Springer 2006

      14 Le, N.T.P., "A triangular discontinuous Galerkin method for non-newtonian implicit constitutive models of rarefied and microscale gases" 273 : 160-184, 2014

      15 Bassi, F., "A high-order accurate discontinuous finite element method for the numerical solution of the compressible Navier-Stokes equations" 131 : 267-279, 1997

      16 Myong, R.S., "A generalized hydrodynamic computational model for rarefied and microscale diatomic gas flows" 195 : 655-676, 2004

      17 Wang, P., "A comparative study of discrete velocity methods for low-speed rarefied gas flows" 161 : 33-46, 2018

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      2027 평가예정 재인증평가 신청대상 (재인증)
      2021-01-01 평가 등재학술지 유지 (재인증) KCI등재
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      2015-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2011-01-01 평가 등재 1차 FAIL (등재유지) KCI등재
      2009-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2006-01-01 평가 등재학술지 선정 (등재후보2차) KCI등재
      2005-06-16 학술지명변경 외국어명 : Jpurnal of Computatuonal Fluids Engineering -> Korean Society of Computatuonal Fluids Engineering KCI등재후보
      2005-01-01 평가 등재후보 1차 PASS (등재후보1차) KCI등재후보
      2004-01-01 평가 등재후보 1차 FAIL (등재후보1차) KCI등재후보
      2002-07-01 평가 등재후보학술지 선정 (신규평가) KCI등재후보
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      2016 0.2 0.2 0.19
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