Dynamic analysis of FRP laminated and sandwich plates

Meunier, Marion

January 2001

No description available.

668.4

Fibre reinforced plastic; PVC foam core

Dynamic Response of Foam-Core Composite Sandwich Panels Under Pressure Pulse Loading

Chapagain, Pradeep

17 August 2011

No description available.

Mechanical Engineering

Foam core sandwich panel

Dynamic Response of Foam-Core Sandwich Beams Under Uniform Pressure Pulse Load

Stelkic, Suzana

21 December 2011

No description available.

Engineering

Materials Science

Mechanical Engineering

foam-core sandwich beams

sandwich beams

uniform pressure pulse

Failure of Sandwich Structures with Sub-Interface Damage

Shipsha, Andrey

January 2001

No description available.

sandwich structure

foam core

fatigue

crack growth

stress intensity factor

fatigue threshold

fracture toughness

damage tolerance

impact damage

crushed core

bridging

fracture analysis

point-stress criterion

Failure of Sandwich Structures with Sub-Interface Damage

Shipsha, Andrey

January 2001

No description available.

sandwich structure

foam core

fatigue

crack growth

stress intensity factor

fatigue threshold

fracture toughness

damage tolerance

impact damage

crushed core

bridging

fracture analysis

point-stress criterion

Návrh monokoku formulového vozidla / Formula Car Monocoque Design

Žídek, Tomáš

January 2014

The diploma thesis describes the design of a carbon fiber monocoque Formula Student car according to current rules. The first part is focused on construction solutions of frames used in Formula Student cars. Following is a summary of the important rules for constructing composite monocoque. Subsequently are described composite materials and their properties. The main part of the thesis deals with the structural design of the CAD program and a computational model to simulate the load case in FEM program. The obtained results from the analysis of the monocoque are compared with the values allowed by the rules of Formula Student. In conclusion of this thesis is evaluated the proposed composite monocoque.

Behaviour and Design of Sandwich Panels Subject to Local Buckling and Flexural Wrinkling Effects

Pokharel, Narayan

January 2003

Sandwich panels comprise a thick, light-weight plastic foam such as polyurethane, polystyrene or mineral wool sandwiched between two relatively thin steel faces. One or both steel faces may be flat, lightly profiled or fully profiled. Until recently sandwich panel construction in Australia has been limited to cold-storage buildings due to the lack of design methods and data. However, in recent times, its use has increased significantly due to their widespread structural applications in building systems. Structural sandwich panels generally used in Australia comprise of polystyrene foam core and thinner (0.42 mm) and high strength (minimum yield stress of 550 MPa and reduced ductility) steel faces bonded together using separate adhesives. Sandwich panels exhibit various types of buckling behaviour depending on the types of faces used. Three types of buckling modes can be observed which are local buckling of plate elements of fully profiled faces, flexural wrinkling of flat and lightly profiled faces and mixed mode buckling of lightly profiled faces due to the interaction of local buckling and flexural wrinkling. To study the structural performance and develop appropriate design rules for sandwich panels, all these buckling failure modes have to be investigated thoroughly. A well established analytical solution exists for the design of flat faced sandwich panels, however, the design solutions for local buckling of fully profiled sandwich panels and mixed mode buckling of lightly profiled sandwich panels are not adequate. Therefore an extensive research program was undertaken to investigate the local buckling behaviour of fully profiled sandwich panels and the mixed mode buckling behaviour of lightly profiled sandwich panels. The first phase of this research was based on a series of laboratory experiments and numerical analyses of 50 foam-supported steel plate elements to study the local buckling behaviour of fully profiled sandwich panels made of thin steel faces and polystyrene foam core covering a wide range of b/t ratios. The current European design standard recommends the use of a modified effective width approach to include the local buckling effects in design. However, the experimental and numerical results revealed that this design method can predict reasonable strength for sandwich panels with low b/t ratios (< 100), but it predicts unconservative strengths for panels with slender plates (high b/t ratios). The use of sandwich panels with high b/t ratios is very common in practical design due to the increasing use of thinner and high strength steel plates. Therefore an improved design rule was developed based on the numerical results that can be used for fully profiled sandwich panels with any practical b/t ratio up to 600. The new improved design rule was validated using six full-scale experiments of profiled sandwich panels and hence can be used to develop safe and economical design solutions. The second phase of this research was based on a series of laboratory experiments and numerical analyses on lightly profiled sandwich panels to study the mixed mode buckling behaviour due to the interaction of local buckling and flexural wrinkling. The current wrinkling formula, which is a simple modification of the methods utilized for flat panels, does not consider the possible interaction between these two buckling modes. As the rib depth and width of flat plates between the ribs increase, flat plate buckling can occur leading to the failure of the entire panel due to the interaction between local buckling and wrinkling modes. Experimental and numerical results from this research confirmed that the current wrinkling formula for lightly profiled sandwich panels based on the elastic half-space method is inadequate in its present form. Hence an improved equation was developed based on validated finite element analysis results to take into account the interaction of the two buckling modes. This new interactive buckling formula can be used to determine the true value of interactive buckling stress for safe and economical design of lightly profiled sandwich panels. This thesis presents the details of experimental investigations and finite element analyses conducted to study the local buckling behaviour of fully profiled sandwich panels and the mixed mode buckling behaviour of lightly profiled sandwich panels. It includes development and validation of suitable numerical and experimental models, and the results. Current design rules are reviewed and new improved design rules are developed based on the results from this research.

Sandwich panels

fully profiled faces

lightly profiled faces

foam core

local buckling

flexural wrinkling

interactive buckling

slender plates

effective width

rib depth

flat plate width

experimental investigation

finite element analysis

A Constitutive Model for Crushable Polymer Foams Used in Sandwich Panels: Theory and FEA Application

Tong, Xiaolong

25 August 2020

No description available.

Mechanical Engineering

Materials Science

Mechanics

Elastic

Plastic

Viscoelastic

Damage

Constitutive Model

FEA

VUMAT

Polymer foam

Crushable foam

Divinycell H100

Sandwich structure

Foam core

Blast load

Anisotropic

Tsai-Wu

Computational

Return mapping algorithm

Newton Raphson Iteration

The Effectiveness of Damage Arrestment Devices in Delaying Fastener-Hole Interaction Failures in Carbon Fiber Polyurethane Foam Composite Sandwich Panels Subjected to Static and Dynamic Loading Under Increased Temperatures

Surano, Dominic E

01 December 2010

A study was conducted to investigate simple, cost-effective manufacturing techniques to delay skin-core delamination, micro-buckling and bearing stress failures resulting from fastener-hole interactions. Composite sandwich panels, with and without damage arrestment devices (DADs), were subjected to monotonic compression at a rate of 5mm per second, and compression-compression fatigue at 50% yield at an amplitude of 65%, under temperatures of 75, 100, 125, 150, 175, and 200 °F. The sandwiches tested were composed of two-layer cross-weave carbon fiber facesheets, a polyurethane foam core, and an epoxy film adhesive to join the two materials. The most successful method to delay the aforementioned failures involved milling rectangular slots in the foam core perpendicular to the holes and adding three additional layers of carbon fiber cross-weave. For the monotonic cases, the ultimate load increases were 97, 87, 100, 131, 96, and 119% for each of the respective temperatures listed above with a negligible weight increase. For the fatigue cases, the number of cycles for each test case was nearly identical. This still represents a large improvement because the yield used in the loading condition for the specimens with DADs was 97% greater than the specimens without DADs. The experimental results were compared with a finite element model (FEM) built in Abaqus/CAE. The numeric and experimental results showed a strong correlation. All test specimens were manufactured and tested in the California Polytechnic State University Aerospace/Composites Laboratory.

Sandwich Composites

Skin-Core Delamination

Micro-Buckling

Bearing Stress

Fasteners

Rivets

Bolts

Foam-Core

Crack Propagation

Fracture Mechanics

Compression

Compression-Compression Fatigue

Damage Arrestment

Temperature

Thermal Environment

Structures and Materials