On the Temperature Distribution in an Air-Ventilated Snow Layer,

Abstract

The problem of simultaneous heat and mass transfer in a homogeneous snow layer, with one side kept at its initial temperature and the other side with a step temperature increase, was solved for the case of constant through-flow conditions. An experimentally determined effective thermal conductivity function, i.e. Ke = 0.0014 + 0.58 G (where G is dry mass flow rate of air in g/sq cm-s), was employed in the solution. The computed nondimensional temperature distribution agreed quite well with experimental data taken under pseudo-steady state conditions with the exception of the temperature for the lowest flow rate used in the experiment. The pronounced nonlinearity of the temperature distribution was found to be a strong function of the flow rate. For sinusoidal variation of atmospheric pressure, the responding flow in the snow medium was also found to be sinusoidal. In conjunction with the diurnal temperature change, this variation facilitated the process of repeated sublimation and condensation in alternate directions and thereby produced a surface layer of approximately constant snow density. (Author)

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Document Details

Document Type
Technical Report
Publication Date
Mar 01, 1982
Accession Number
ADA115598

Entities

People

  • Yinchao Yen

Organizations

  • Cold Regions Research and Engineering Laboratory

Tags

Communities of Interest

  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Air Flow
  • Barometric Pressure
  • Coefficients
  • Cold Regions
  • Diffusion Coefficient
  • Equations
  • Flow Rate
  • Fluid Flow
  • Heat Energy
  • Heat Transfer
  • Heat Transmission
  • Latent Heat
  • Mass Transfer
  • Partial Pressure
  • Regions
  • Temperature Gradients
  • Thermal Conductivity

Readers

  • Fluid Dynamics.
  • Mathematics or Statistics
  • Thermal Physics or Thermal Science.