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Hyper-velocity Crater Size and Target Strength

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Abstract

IT has been shown1–3 that at ambient temperature the hyper-velocity force per unit area of crater surface can be related to the engineering ultimate tensile strength of a material by the expression d3 = mv2/4πS where d is the depth (or radius) of a hemispherical crater, m and v are the mass and velocity of the projectile, and S is the measured ultimate tensile strength of the target. Aluminium alloys were divided4 into two groups on the basis of their ultimate tensile strength at room temperature; those having a strength of 4 × 109 dynes/cm2 or larger were not corrected for relaxation while those with strengths of 3 × 109 dynes/cm2 and less were increased by 25 per cent to obtain agreement between the target strength and impact force per unit area. The relaxation correction is an all-embracing term which includes the correction for relaxation of the target material after release of the impact pressure and other effects such as the error in the determination of the strength of very ductile materials caused by necking during loading.

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References

  1. Rolsten, R. F., and Hunt, H. H., Amer. Inst. Aeronaut. and Astronaut. J., 1, 1893 (1963).

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  2. Rolsten, R. F., and Hunt, H. H., Spacecraft and Rockets, 351 (May–June, 1964).

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  3. Rolsten, R. F., Amer. Inst. Aeronaut. and Astronaut. J., 3, 11, 2149 (1965).

    Article  Google Scholar 

  4. Gehring, J. W., Fourth Hypervelocity Impact Symp., Eglin Air Force Base, Florida, 2, 29 (1960); Eichelberger, R. J., J. Amer. Rocket Soc., 1583 (October 1962).

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  5. Piacesi, R. (personal communication).

  6. Rolsten, R. F., and Schmitt, R. A., J. App. Phys., 34, 10, 3010 (1963).

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  7. Atkins, W. W., and Halperson, S. M. (personal communication).

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Authors and Affiliations

  1. 5141 Crest Road, Dayton, Ohio

    ROBERT F. ROLSTEN

  2. Air Force Materials Laboratory, Wright-Patterson Air Force Base, Ohio

    ALAN K. HOPKINS

  3. Research Institute, University of Dayton, Ohio

    HAROLD H. HUNT

Authors
  1. ROBERT F. ROLSTEN
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  2. ALAN K. HOPKINS
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  3. HAROLD H. HUNT
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ROLSTEN, R., HOPKINS, A. & HUNT, H. Hyper-velocity Crater Size and Target Strength. Nature 212, 495–497 (1966). https://doi.org/10.1038/212495b0

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