Recent research has established the effectiveness of sandwich structures with metallic cellular cores for blast mitigation. The choice of core architecture can enhance sandwich performance, dissipating energy through plastic core compression and exploiting fluid-structure interaction effects to reduce the momentum imparted to the structure by the blast. In this paper we describe the first analysis of a novel sandwich panel core concept for blast mitigation: the Stacked Folded Core. The core consists of an alternating stacked sequence of folded sheets in the Miura (double-corrugated) pattern, with the stack oriented such that the folding kinematics define the out-of plane compressive strength of the core. It offers a number of distinct characteristics compared to existing cellular cores. (i) The kinematics of collapse of the core by a distinctive folding mechanism give it unique mechanical properties, including strong anisotropy. (ii) The fold pattern and stacking arrangement is extremely versatile, offering exceptional freedom to tailor the mechanical properties of the core. This includes freedom to grade the core properties through progressive changes in the fold pattern. (iii) Continuous manufacturing processes have been established for the Miura folded sheets which make up the core. The design is therefore potentially more straightforward and economical to manufacture than other metallic cellular materials. In this first investigation of the Stacked Folded Core, finite element analysis is used to investigate its characteristics under both quasi-static and dynamic loading. A dynamic analysis of an impulsively loaded sandwich beam with a stacked folded core reveals the versatility of the concept for blast mitigation. By altering the fold pattern alone, the durations of key phases of the dynamic 1 sandwich response (core compression, beam bending) can be controlled. By altering both fold pattern and sheet thickness in the core, the same is achieved without altering the density of the core or the mass distribution of the sandwich beam.
[1]
S. Nemat-Nasser,et al.
Thermomechanical response of HSLA-65 steel plates: experiments and modeling
,
2005
.
[2]
H. Wadley,et al.
Compressive behavior of age hardenable tetrahedral lattice truss structures made from aluminium
,
2004,
Acta Materialia.
[3]
Zhenyu Xue,et al.
A comparative study of impulse-resistant metal sandwich plates
,
2004
.
[5]
Vikram Deshpande,et al.
The response of clamped sandwich plates with metallic foam cores to simulated blast loading
,
2006
.
[6]
Koryo Miura,et al.
The Science of Miura-Ori: A Review
,
2009
.
[7]
Yves Klett,et al.
Designing Technical Tessellations
,
2011
.
[8]
Koryo Miura.
Zeta-Core Sandwich-Its Concept and Realization
,
1972
.
[9]
Vikram Deshpande,et al.
The Underwater Blast Resistance of Metallic Sandwich Beams With Prismatic Lattice Cores
,
2007
.
[10]
Arthur Lebée,et al.
Transverse shear stiffness of a chevron folded core used in sandwich construction
,
2010
.
[11]
Vikram Deshpande,et al.
The impulsive response of sandwich beams: analytical and numerical investigation of regimes of behaviour
,
2006
.
[12]
N. Fleck,et al.
High strain rate compressive behaviour of aluminium alloy foams
,
2000
.
[13]
R. Lakes.
Foam Structures with a Negative Poisson's Ratio
,
1987,
Science.
[14]
Vikram Deshpande,et al.
Dynamic buckling of an inclined strut
,
2012
.
[15]
David R Hayhurst,et al.
The response of metallic sandwich panels to water blast
,
2007
.
[16]
Dynamic Compressive Response of Stainless-Steel Square
,
2008
.