Scaling of Erosion Rate in Subsonic Jet Experiments and Apollo Lunar Module Landings

Small scale jet-induced erosion experiments are useful for identifying the scaling of erosion with respect to the various physical parameters (gravity, grain size, gas velocity, gas density, grain density, etc.), and because they provide a data set for benchmarking numerical flow codes. We have perf...

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Bibliographic Details
Published in:arXiv.org 2021-04
Main Authors: Metzger, Philip T, Lane, John E, Immer, Christopher D, Gamsky, Jacob N, Hauslein, Whitney, Li, Xiaoyi, Latta, Robert C, Donahue, Carly M
Format: Article
Language:English
Subjects:
Aerodynamics
Aircraft rockets
Boundary layers
Computational fluid dynamics
Experiments
Gas density
Gas flow
Grain size
Gravity
Lunar exploration
Lunar landing
Lunar Module
Lunar soil
Lunar surface
Mathematical models
Microgravity
Nozzles
Parameters
Physical properties
Planetary surfaces
Rocket exhaust
Sandblasting
Scaling
Soil dynamics
Soil erosion
Subsonic aircraft
Video
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Description
Summary:Small scale jet-induced erosion experiments are useful for identifying the scaling of erosion with respect to the various physical parameters (gravity, grain size, gas velocity, gas density, grain density, etc.), and because they provide a data set for benchmarking numerical flow codes. We have performed experiments varying the physical parameters listed above (e.g., gravity was varied in reduced gravity aircraft flights). In all these experiments, a subsonic jet of gas impinges vertically on a bed of sand or lunar soil simulant forming a localized scour hole beneath the jet. Videography captures the erosion and scour hole formation processes, and analysis of these videos post-test identifies the scaling of these processes. This has produced important new insights into the physics of erosion. Based on these insights, we have developed an erosion rate model that can be applied to generalized situations, such as the erosion of soil beneath a horizontal gas flow on a planetary surface. This is important to lunar exploration because the rate of erosion beneath the rocket exhaust plume of a landing spacecraft will determine the amount of sand-blasting damage that can be inflicted upon surrounding hardware. Although the rocket exhaust plume at the exit of the nozzle is supersonic, the boundary layer on the lunar surface where erosion occurs is subsonic. The model has been benchmarked through comparison with the Apollo landing videos, which show the blowing lunar soil, and computational fluid dynamics simulations of those landings.
ISSN:2331-8422
DOI:10.48550/arxiv.2104.10038