A comparative study of impulse-resistant metal sandwich plates

Xue, Zhenyu; Hutchinson, John W.

doi:10.1016/j.ijimpeng.2003.08.007

Cited by 467 publications

(279 citation statements)

References 7 publications

(11 reference statements)

Supporting

Mentioning

268

Contrasting

Unclassified

Order By: Relevance

“…Recent experiments have shown that the back face deflections of centrally loaded edge clamped sandwich panels can be significantly less than equivalent areal density solid plates subjected to the same loading [3][4][5][6][7][8]. Theoretical assessments indicate this beneficial effect arises from two phenomena: a reduction in the impulse acquired by the sandwich panel front face as a result of a fluid-structure interaction (FSI) effect [3,4,[8][9][10] and the higher flexural stiffness and strength of the sandwich.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Response of metallic pyramidal lattice core sandwich panels to high intensity impulsive loading in air

Dharmasena

Wadley

Williams³

et al. 2011

International Journal of Impact Engineering

Self Cite

120

View full text Add to dashboard Cite

Small scale explosive loading of sandwich panels with low relative density pyramidal lattice cores have been used to study the large scale bending and fracture response of a model sandwich panel system in which the core has little stretch resistance. The panels were made from a ductile stainless steel and the practical consequence of reducing the sandwich panel face sheet thickness to induce a recently predicted beneficial fluidstructure interaction (FSI) effect was investigated. The panel responses are compared to those of monolithic solid plates of equivalent areal density. The specific impulse imparted to the panels was varied from1.5 to 7.6 kPa.s by changing the standoff distance between the charge center and the front face of the panels. A decoupled finite element model has been used to computationally investigate the dynamic response of the panels.It predicts panel deformations well and is used to identify the deformation time sequence and the face sheet and core failure mechanisms. The study shows that efforts to use thin face sheets to exploit FSI benefits are constrained by dynamic fracture of the front face and that this failure mode is in part a consequence of the high strength of the inertially stabilized trusses. Even though the pyramidal lattice core offers little in-plane stretch resistance, and the FSI effect is negligible during loading by air, the sandwich panels are found to suffer slightly smaller back face deflections and transmit smaller vertical component forces to the supports compared to equivalent monolithic plates.

show abstract

Section: Introductionmentioning

confidence: 99%

“…After the beneficial FSI effect had been confirmed in water [2][3][4][5][6][7][8], numerous sandwich panel concepts for impulse and pressure mitigation have been explored [7][8][9][10][11][12][13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Response of metallic pyramidal lattice core sandwich panels to high intensity impulsive loading in air

Dharmasena

Wadley

Williams³

et al. 2011

International Journal of Impact Engineering

Self Cite

120

View full text Add to dashboard Cite

show abstract

“…Recently, attention has been paid to the potential use of sandwich plates in this protective role. Fleck and Deshpande [1] and Xue and Hutchinson [2] have argued that an underwater blast imparts a lower momentum to sandwich plates than monolithic plates of equal mass. The reduced momentum is associated with the earlier onset of cavitation in the water for sandwich plates with a light front face sheet and a deformable core.…”

Section: Introductionmentioning

confidence: 99%

Underwater blast response of free-standing sandwich plates with metallic lattice cores

McShane

Deshpande

Fleck

2010

International Journal of Impact Engineering

View full text Add to dashboard Cite

The underwater blast response of free standing sandwich plates with a square honeycomb core and a corrugated core has been measured. The total momentum imparted to the sandwich plate and the degree of core compaction are measured as a function of (i) core strength, (ii) mass of the front face sheet (that is, the wet face) and (iii) time constant of the blast pulse. Finite element calculations are performed in order to analyse the phases of fluid-structure interaction. The choice of core topology has a strong influence upon the dynamic compressive strength and upon the degree of core compression, but has only a minor effect upon the total momentum imparted to the sandwich. For both topologies, a reduction in the mass of the front (wet) face reduces the imparted momentum, but at the expense of increased core compression.Conversely, an increase in the time constant of the blast pulse results in lower core compression, but the performance advantage over a monolithic plate in terms of imparted momentum is reduced. The sandwich panel results are compared with analytical results for monolithic plates of mass equal to that of (i) the sandwich panel and (ii) the front face alone. (Case (i) represents a rigid core while (ii) represents a core of negligible strength.) For most conditions considered, the sandwich results lie between these limits reflecting the coupled nature of core deformation and fluidstructure interaction.

show abstract

“…A fundamental issue with the inherent brittleness of these systems is that although they perform well when the structures deform in their elastic regime, they tend to fail catastrophically when a specific level of impact momentum is reached [9]. In contrast, metals show a more benign transition at increased levels of impact momentum due their ability to deform plastically [11]. The chief disadvantage with metal alloys is their high density; this necessitates that the structures become very thin walled and buckling dominated structures at low areal densities.…”

Section: Introductionmentioning

confidence: 99%

Impact response of ductile self-reinforced composite corrugated sandwich beams

Schneider

Kazemahvazi

Russell

et al. 2016

Composites Part B: Engineering

View full text Add to dashboard Cite

Impact response of ductile self-reinforced composite corrugated sandwich beams. SrPET are manufactured and tested dynamically. The beams are subjected to impact loading at the mid-span using a metal foam projectile and the beam deflection is measured. For sandwich beams with a constant areal mass, beams with a high mass portion in the core webs outperform configurations with a high mass portion in the face sheets (given that the face sheets are thick enough to carry the transversal loads induced by the core webs). Reinforcing the face sheet -core web interface further improves the impact response. The strain rate sensitivity of SrPET has also been investigated. A three-dimensional finite element (FE) model has been developed to simulate the impact event and a good agreement is found with the measured response. It is found that corrugated sandwich beams made from SrPET has competitive impact performance compared to similar sandwich beams with equal mass and geometry out of aerospace grade aluminium and carbon fiber / high performance foam sandwich. Composites

show abstract

A comparative study of impulse-resistant metal sandwich plates

Cited by 467 publications

References 7 publications

Response of metallic pyramidal lattice core sandwich panels to high intensity impulsive loading in air

Response of metallic pyramidal lattice core sandwich panels to high intensity impulsive loading in air

Underwater blast response of free-standing sandwich plates with metallic lattice cores

Impact response of ductile self-reinforced composite corrugated sandwich beams

Contact Info

Product

Resources

About