• Title of article

    A ballistic limit equation for hypervelocity impacts on composite honeycomb sandwich panel satellite structures Original Research Article

  • Author/Authors

    S. Ryan، نويسنده , , F. Schaefer، نويسنده , , R. Destefanis، نويسنده , , M. Lambert، نويسنده ,

  • Issue Information
    دوهفته نامه با شماره پیاپی سال 2008
  • Pages
    15
  • From page
    1152
  • To page
    1166
  • Abstract
    During a recent experimental test campaign performed in the framework of ESA Contract 16721, the ballistic performance of multiple satellite-representative Carbon Fibre Reinforced Plastic (CFRP)/Aluminium honeycomb sandwich panel structural configurations (GOCE, Radarsat-2, Herschel/Planck, BeppoSax) was investigated using the two-stage light-gas guns at EMI. The experimental results were used to develop and validate a new empirical Ballistic Limit Equation (BLE), which was derived from an existing Whipple-shield BLE. This new BLE provided a good level of accuracy in predicting the ballistic performance of stand-alone sandwich panel structures. Additionally, the equation is capable of predicting the ballistic limit of a thin Al plate located at a standoff behind the sandwich panel structure. This thin plate is the representative of internal satellite systems, e.g. an Al electronic box cover, a wall of a metallic vessel, etc. Good agreement was achieved with both the experimental test campaign results and additional test data from the literature for the vast majority of set-ups investigated. For some experiments, the ballistic limit was conservatively predicted, a result attributed to shortcomings in correctly accounting for the presence of high surface density multi-layer insulation on the outer facesheet. Four existing BLEs commonly applied for application with stand-alone sandwich panels were reviewed using the new impact test data. It was found that a number of these common approaches provided non-conservative predictions for sandwich panels with CFRP facesheets.
  • Keywords
    Ballistic limit equation , Hypervelocity impact , Space debris , Composites , CFRP , Damage laws
  • Journal title
    Advances in Space Research
  • Serial Year
    2008
  • Journal title
    Advances in Space Research
  • Record number

    1132065