Liquid Argon in a Large Tank --- Some Thermodynamic Calculations Zhijing Tang November 4, 2004.

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Presentation transcript:

Liquid Argon in a Large Tank --- Some Thermodynamic Calculations Zhijing Tang November 4, 2004

Questions Heat leak Heat leak from chimney Convection flow Temperature distribution Force on wire Flow from surface downward

Liquid Argon in Big Tank Diameter 40 m, Height 30 m, Volume m 3. Heat leak cause evaporation of 0.05% per day. Properties of liquid argon  Density  = 1393 kg/m 3  Boiling point T B = 87.3 K  Latent heat of evaporation h B = 161 kJ/kg  Viscosity  = 0.26e-3 N-s/m 2  Thermal conductivity k = 128 w/m-K  Heat capacity c = 1117 J/kg-K  Temperature coefficient of density  = kg/m 3 -K

Heat Leak Evaporation 0.05%(37699) = m 3 /day = 0.218e-3m 3 /s (0.218e-3 m 3 /s)(1393 kg/m 3 )(161e3 J/kg) = w Assume all evaporation occurs at surface  Surface temperature = T B = 87.3 K Assume all leak through bottom and side  Bottom surface 1257 m2  Side surface 3770 m2  Heat leak q = 48930/( ) = w/m2

Heat Leak Through Chimney Neglect Convection Thermal conductance R=kA/L  SS tube R 1 = W/K  Argon gas R 2 = 2.6e-3 W/K  R 1 >> R 2  R 1 + R 2 = W/K   T = = 195 K  Heat leak = 39 W Compare with w (0.08%)

Finite Element Model

From finite element model results we have following conclusions: The convection flow is quite significant, with maximum velocity of more than 8 cm/s. The temperature in the tank is quite uniform, with the maximum temperature difference of 0.04 K.

Drag Force

Displacement of wire

Flow from surface downward

Vertical Flow