Material Properties of Granular Ice Layers Characterized Using a Rigid-Body-Penetration Method: Experiments and Modeling
Technical Paper
2019-01-2034
ISSN: 0148-7191, e-ISSN: 2688-3627
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English
Abstract
Accretion and shedding of ice layers is a serious problem for various engineering
applications. In particular, ice layers growing due to ice crystal impingement
on warm parts of an aircraft jet engine pose a severe hazard since they
seriously affect safe operation of an aircraft. The material properties, and in
the first place the strength of an ice layer, are crucial for the mechanisms
leading to, and taking place during, both accretion and shedding of an ice
layer. In the present study, the apparent yield strength of dry granular ice
layers is examined employing a novel rigid-body-penetration approach. Dynamic
projectile penetration into granular ice layers of varying porosity and ice
grain size is experimentally investigated for different projectile impact
velocities using a high-speed video system and post-processing of the captured
video data. The obtained data for the total penetration depth of the projectile
is used to calculate the apparent yield strength of the ice layer based on
theoretical modeling of the projectile dynamics during penetration. Finally, the
experimental method and theoretical modeling employed in the present study turn
out as a promising way for the characterization of ice layers under varying
circumstances such as generic wind tunnel icing experiments, enabling
correlation of phenomenological observations of ice accretion and shedding to
the material properties of the ice layer.
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Authors
Citation
Schremb, M., Malicevic, K., Reitter, L., Roisman, I. et al., "Material Properties of Granular Ice Layers Characterized Using a Rigid-Body-Penetration Method: Experiments and Modeling," SAE Technical Paper 2019-01-2034, 2019, https://doi.org/10.4271/2019-01-2034.Also In
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