Overview of Icing Physics Relevant to Scaling



FAA In-flight Icing / Ground De-icing International Conference & Exhibition
Authors Abstract
An understanding of icing physics is required for the development of both scaling methods and ice-accretion prediction codes. This paper gives an overview of our present understanding of the important physical processes and the associated similarity parameters that determine the shape of Appendix C ice accretions.
For many years it has been recognized that ice accretion processes depend on flow effects over the model, on droplet trajectories, on the rate of water collection and time of exposure, and, for glaze ice, on a heat balance. For scaling applications, equations describing these events have been based on analyses at the stagnation line of the model and have resulted in the identification of several non-dimensional similarity parameters. The parameters include the modified inertia parameter of the water drop, the accumulation parameter and the freezing fraction. Other parameters dealing with the leading-edge heat balance have also been used for convenience. By equating scale expressions for these parameters to the values to be simulated a set of equations is produced which can be solved for the scale test conditions. Studies in the past few years have shown that at least one parameter in addition to those mentioned above is needed to describe surface-water effects, and some of the traditional parameters may not be as significant as once thought. Insight into the importance of each parameter, and the physical processes it represents, can be made by viewing whether ice shapes change, and the extent of the change, when each parameter is varied. Experimental evidence is presented to establish the importance of each of the traditionally-used parameters and to identify the possible form of a new similarity parameter to be used for scaling.
Meta TagsDetails
Anderson, D., and Tsao, J., "Overview of Icing Physics Relevant to Scaling," SAE Technical Paper 2003-01-2130, 2003, https://doi.org/10.4271/2003-01-2130.
Additional Details
Jun 16, 2003
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Content Type
Technical Paper