Content  Turbulent Validation  Thermal Validation  Simple Model Test  Plans for Next Period.

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Presentation transcript:

Content  Turbulent Validation  Thermal Validation  Simple Model Test  Plans for Next Period

Turbulent ValidationTurbulent Validation Comparison of normalized mean angular momentum proﬁles between present simulation (Re=8000) and the experiment of Smith & Townsend (1982). u θ Azimuthal Velocity R 1 Radius of Inner Cylinder R 2 Radius of Outer Cylinder U 0 Tangential Velocity of Inner Cylinder r Distance from Centre Axis

Boundary ConditionsBoundary Conditions R 1 = m R 2 = m Ω = rad/s (Re=17295) Height = 1.80 m End walls are free surfaces k- epsilon and k- omega were chosen to compare Measure points are located along the mid-height of the gap Mesh Density Axial = Circle = Radial =

Comparing with Experiment Data  Picture

Possible Reasons for Difference  Flow time interval is not enough ΔT epsilon =27.68s ΔT omega =20.48s  Sampling frequency f experiment =10kHz f simulation =200Hz  Mesh density Tip: 文章名称 used k-epsilon as the turbulent model

Thermal ValidationThermal Validation K eq = -h*r*ln(R 1 /R 2 )/k Re = Ω* (R 1 -R 2 )*R 1 /ν h Convective Heat Transfer Coefficient R 1 Radius of Inner Cylinder R 2 Radius of Outer Cylinder K Thermal Conductivity ν Kinematic Viscosity r Distance from Centre Axis Fluid is air

Boundary ConditionsBoundary Conditions K eq = -h*r*ln(R 1 /R 2 )/k Re = Ω* (R 1 -R 2 )*R 1 /ν R 1 = cm R 2 = cm Height = Gr= 1000 ΔT= K Ti = 293K To= K End walls are fixed and insulated Re=[ ] Ω=[ ] rad/s Since for η=0.565 Re c = 70, All the three cases are in laminar mode. Mesh Density Axial = Circle = Radial =

Comparing with Experiment Data Re 2 h(w/m 2 k)k eq Experiment DataResidue e e e-03

Possible Reasons for Difference  Boundary condition set-up ideal gas, pressure based, real apparatus error (axial temperature gradient, end walls effect)  Wrong understanding of the experiment

Simple Model TestSimple Model Test R 1 = mm R 2 = 97.5 mm Height = 140 mm Q=4 L/min V in = m/s T in = 308K T out = 551K Ω= rad/s End walls are fixed and insulated Measure points are located in the vertical lines close to the inner cylinder. Since for η=0.975 Re c = , In this case Re= So, it is in laminar mode.

Plans for Next PeriodPlans for Next Period  Keep running both of the turbulent cases  Finish the thermal validation  Couette flow validation  More validation of the thermal part (optional)  Finish simple model test  Check geometry related paper