Theoretical and Experimental Research on Energy Distribution Models during Hypervelocity Impacts

This study presents a comprehensive analysis of energy distribution during hypervelocity impacts, based on theoretical insights and experimental data obtained from hypervelocity impact tests. We have developed an energy distribution model for hypervelocity impacts on semi-infinite aluminum targets....

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Bibliographic Details
Published in:Journal of physics. Conference series 2024-12, Vol.2891 (4), p.42018
Main Authors: Ming-Kai, Guo, Xing, Chen, Zhong-Hua, Cui, Zhi-Wen, Li, Gui-Long, Wang
Format: Article
Language:English
Subjects:
Damage assessment
Electromagnetic radiation
Energy
Energy dissipation
Energy distribution
Hypervelocity impact
Impact analysis
Impact tests
Impact velocity
Kinetic energy
Plastic deformation
Projectiles
Radiation
Radiation damage
Spalling
Target thickness
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Summary:This study presents a comprehensive analysis of energy distribution during hypervelocity impacts, based on theoretical insights and experimental data obtained from hypervelocity impact tests. We have developed an energy distribution model for hypervelocity impacts on semi-infinite aluminum targets. In our model, the kinetic energy of the projectile is categorized into four components: plastic deformation energy of the target plate, spalling energy of ejected debris, energy associated with temperature increase, and electromagnetic radiation energy. Our findings indicate that the majority of the projectile’s kinetic energy is converted into spalling and plastic deformation energies during the impact, with a smaller fraction being allocated to thermal and flash radiation energies. Notably, spalling energy constitutes 65% of the total kinetic energy dissipation, while plastic deformation accounts for 25%. Additionally, we have formulated an empirical model for flash radiation efficiency that takes into account the impact velocity and target thickness. This model is found to be in close agreement with our experimental outcomes, with an error margin maintained within 10%. The model developed in this paper holds significant implications for the development of space target damage assessment methodologies under over-the-horizon conditions.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/2891/4/042018