Experiment assessment of the ballistic response of composite pyramidal lattice truss structures

Abstract Sandwich panels with lattice cores have attracted significant interest as multifunctional structures. The lattices consist of 3D repeating unit cells constructed from plates or trusses oriented to efficiently support applied stresses. These systems show promise for supporting structural loads and mitigating the blast effects of explosions. Here, a preliminary study has been conducted to investigate the ballistic behavior of a model lattice and to explore the effect of filling the lattices void spaces with polymers and ceramics. A sheet folding and brazing method has been used to fabricate pyramidal lattice truss structures from 304 stainless steel. The impact response of the various panels was assessed after impact by spherical, 12 mm diameter, 6.9 g projectiles with an incident, zero obliquity velocity of ∼600 m/s. Empty lattice sandwich panels with an areal density of 27.7 kg m−2 do not prevent the perforation of the sandwich panel. The impact with proximal face sheet reduced the projectile velocity to ∼450 m/s (by about 25%). Interactions with the lattice trusses and the distal face sheet further slowed the projectile resulting in an exit velocity at the distal face sheet of ∼360 m/s. The projectiles energy was dissipated by face sheet plastic dishing and fracture by petaling, and by truss plastic deformation. Infiltration of the lattice with polyurethane elastomers further reduced the projectile exit velocity. The strength of the effect depended upon the modulus of the polymer (and therefore its glass transition temperature, Tg). Only high modulus (high Tg) elastomers fully arrested the projectile. The energy of the projectile in this case was dissipated by a combination of face sheet stretching and polymer deformation and fracture. Low modulus elastomers reduced the projectile exit velocity by about 45% (to ∼250 m/s) and also resulted in resealing of the projectile path within the sandwich panel core. The incorporation of ballistic fabric within the polymer infiltrated systems had little effect on the ballistic resistance. A hybrid sample containing metal encased Al2O3 prism inserts provided the greatest resistance to penetration. In this case the projectiles were arrested within a sphere diameter of the sample front surface. Several of these hybrid systems offer promise as multifunctional, ballistic resistant, load-bearing structures.

[1]  A. M. Eleiche,et al.  Experimental investigation of the ballistic resistance of steel-fiberglass reinforced polyester laminated plates , 1996 .

[2]  B. K. Fink,et al.  Aluminum foam integral armor: a new dimension in armor design , 2001 .

[3]  N. K. Naik,et al.  Composite structures under ballistic impact , 2004 .

[4]  Norman A. Fleck,et al.  Fabrication and structural performance of periodic cellular metal sandwich structures , 2003 .

[5]  Gabi Ben-Dor,et al.  On the ballistic resistance of multi-layered targets with air gaps , 1998 .

[6]  G. Ravichandran,et al.  Penetration resistance of laminated ceramic/polymer structures , 2003 .

[7]  H. Wadley Cellular Metals Manufacturing , 2002 .

[8]  Norman A. Fleck,et al.  Kagome plate structures for actuation , 2003 .

[9]  Stephan Bless,et al.  Penetration of semi-infinite AD995 alumina targets by tungsten long rod penetrators from 1.5 to 3.5 km/s , 1995 .

[10]  D. Dunand,et al.  Processing and structure of open-celled amorphous metal foams , 2005 .

[11]  Werner Goldsmith,et al.  The mechanics of penetration of projectiles into targets , 1978 .

[12]  H. Wadley,et al.  Compressive behavior of age hardenable tetrahedral lattice truss structures made from aluminium , 2004, Acta Materialia.

[13]  Haydn N. G. Wadley,et al.  Cellular metal lattices with hollow trusses , 2005 .

[14]  H. Hodson,et al.  Fluid-flow and endwall heat-transfer characteristics of an ultralight lattice-frame material , 2004 .

[15]  A. Evans,et al.  Measurement and Simulation of the Performance of a Lightweight Metallic Sandwich Structure With a Tetrahedral Truss Core , 2004 .

[16]  M. Ashby,et al.  Metal Foams: A Design Guide , 2000 .

[17]  Douglas T. Queheillalt,et al.  Synthesis of stochastic open cell Ni-based foams , 2004 .

[18]  Haydn N. G. Wadley,et al.  Compressive response of multilayered pyramidal lattices during underwater shock loading , 2008 .

[19]  N. Fleck,et al.  The response of clamped sandwich beams subjected to shock loading , 2006 .

[20]  Anthony G. Evans,et al.  Lightweight Materials and Structures , 2001 .

[21]  Vikram Deshpande,et al.  The response of clamped sandwich plates with metallic foam cores to simulated blast loading , 2006 .

[22]  Werner Goldsmith,et al.  Axial perforation of aluminum honeycombs by projectiles , 1995 .

[23]  T. Lu,et al.  On the design of two-dimensional cellular metals for combined heat dissipation and structural load capacity , 2001 .

[24]  Aleksandar Donev,et al.  Energy-efficient actuation in infinite lattice structures , 2003 .

[25]  M. Langseth,et al.  Close-range blast loading of aluminium foam panels , 2002 .

[26]  H. Wadley Multifunctional periodic cellular metals , 2006, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[27]  Haydn N. G. Wadley,et al.  On the performance of truss panels with Kagomé cores , 2003 .

[28]  W. Goldsmith,et al.  Penetration of laminated Kevlar by projectiles. I : Experimental investigation , 1992 .

[29]  Vikram Deshpande,et al.  The response of clamped sandwich plates with lattice cores subjected to shock loading , 2006 .

[30]  Werner Goldsmith,et al.  Normal projectile penetration and perforation of layered targets , 1988 .

[31]  M. Ashby,et al.  The topological design of multifunctional cellular metals , 2001 .

[32]  Norman A. Fleck,et al.  Performance of metallic honeycomb-core sandwich beams under shock loading , 2006 .

[33]  A. G. Evansa,et al.  Analysis and interpretation of a test for characterizing the response of sandwich panels to water blast , 2007 .

[34]  Michael F. Ashby,et al.  Multifunctionality of cellular metal systems , 1998 .

[35]  Douglas T. Queheillalt,et al.  The effects of topology upon fluid-flow and heat-transfer within cellular copper structures , 2004 .

[36]  B. J. Baxter,et al.  A study of fragmentation in the ballistic impact of ceramics , 1994 .

[37]  John W. Hutchinson,et al.  Optimal truss plates , 2001 .