Strength of Sandwich Panels Loaded in In-plane Compression

Lindström, Anders

January 2007

The use of composite materials in vehicle structures could reduce the weight and thereby the fuel consumption of vehicles. As the road safety of the vehicles must be ensured, it is vital that the energy absorbing capability of the composite materials are similar to or better than the commonly used steel structures. The high specific bending stiffness of sandwich structures can with advantage be used in vehicles, provided that the structural behaviour during a crash situation is well understood and possible to predict. The purpose of this thesis is to identify and if possible to describe the failure initiation and progression in in-plane compression loaded sandwich panels. An experimental study on in-plane compression loaded sandwich panels with two different material concepts was conducted. Digital speckle photography (DSP) was used to record the displacement field of one outer face-sheet surface during compression. The sandwich panels with glass fibre preimpregnated face-sheets and a polymer foam core failed due to disintegration of the face-sheets from the core, whereas the sandwich panels with sheet molding compound face-sheets and a balsa core failed in progressive end-crushing. A simple semi-empirical model was developed to describe the structural response before and after initial failure. The postfailure behaviour of in-plane compression loaded sandwich panels was studied by considering the structural behaviour of sandwich panels with edge debonds. A parametrical finite element model was used to determine the influence of different material and geometrical properties on the buckling and postbuckling failure loads. The postbuckling failure modes studied were debond crack propagation and face-sheet failure. It could be concluded that the postbuckling failure modes were mainly determined by the ratio between the fracture toughness of the face-core interface and the bending stiffness of the face-sheets. / QC 20101111

sandwich

in-plane compression

energy absorption

debond

postbuckling

Mechanical Engineering

Maskinteknik

Ultimate Strength of Clamped Steel-Elastomer Sandwich Panels under Combined In-plane Compression and Lateral Pressure

Zhou, Feng

21 February 2008

An efficient interaction formula and a semi-analytical method are developed for calculating the ultimate strength of steel-elastomer sandwich panels under combined in-plane compression and lateral pressure. By using the Galerkin method and extending the semi-analytical method to clamped sandwich panels, the governing equations of sandwich panels have been solved by the Galerkin method. The material nonlinearity is treated by iteration and a three-dimensional mesh. For the load case of pure lateral pressure, the ultimate strength from the semi-analytical method is similar to that from hinge line theory and finite element analysis (FEA). However, the semi-analytical method requires about as much computation as FEA, and it is therefore not suitable for design. Finite element modeling and nonlinear analysis are performed to calculate the ultimate strength of sandwich panels under combined load. The results agree with experimental results. This verifies the accuracy of the current finite element model. The verified finite element model is used to obtain the results for a large set of sandwich panels with various dimensions and load combinations. The FEA results for pure lateral pressure load cases are used to derive a correction factor for the hinge line formula. Statistical analysis confirms that the generalized hinge line formula gives accurate values of ultimate strength of sandwich panels under pure lateral pressure. Except for the pressure-only FEA data points, the other FEA data points are corrected so as not to count the in-plane load carried by the elastomer core. Based on the corrected FEA data points, a general expression is developed for an interaction equation. The resulting equation has a bias of -0.003 and a standard deviation of 0.029. Since the radius of the interaction curve is close to 1, this standard deviation is of the order of 3%, which shows that the ultimate strength given by the equation is very close to the FEA results. The interaction equation is so simple that the ultimate strength of clamped sandwich panels under combined in-plane compression and lateral pressure can be easily calculated. / Ph. D.

Lateral Pressure

In-plane Compression

Ultimate Strength

Steel-Elastomer

Sandwich Panels

Strength of Sandwich Panels Loaded in In-plane Compression

Lindström, Anders

January 2007

<p>The use of composite materials in vehicle structures could reduce the weight and thereby the fuel consumption of vehicles.</p><p>As the road safety of the vehicles must be ensured, it is vital that the energy absorbing capability of the composite materials are similar to or better than the commonly used steel structures. The high specific bending stiffness of sandwich structures can with advantage be used in vehicles, provided that the structural behaviour during a crash situation is well understood and possible to predict. The purpose of this thesis is to identify and if possible to describe the failure initiation and progression in in-plane compression loaded sandwich panels.</p><p>An experimental study on in-plane compression loaded sandwich panels with two different material concepts was conducted. Digital speckle photography (DSP) was used to record the displacement field of one outer face-sheet surface during compression. The sandwich panels with glass fibre preimpregnated face-sheets and a polymer foam core failed due to disintegration of the face-sheets from the core, whereas the sandwich panels with sheet molding compound face-sheets and a balsa core failed in progressive end-crushing. A simple semi-empirical model was developed to describe the structural response before and after initial failure.</p><p>The postfailure behaviour of in-plane compression loaded sandwich panels was studied by considering the structural behaviour of sandwich panels with edge debonds. A parametrical finite element model was used to determine the influence of different material and geometrical properties on the buckling and postbuckling failure loads. The postbuckling failure modes studied were debond crack propagation and face-sheet failure. It could be concluded that the postbuckling failure modes were mainly determined by the ratio between the fracture toughness of the face-core interface and the bending stiffness of the face-sheets.</p>

sandwich

in-plane compression

energy absorption

debond

postbuckling

Engineering mechanics

Teknisk mekanik

Damage resistance and tolerance investigation of carbon/epoxy skinned honeycomb sandwich panels

Hill, Michelle Denise

January 2007

This thesis documents the findings of a three year experimental investigation into the impact damage resistance and damage tolerance of composite honeycomb sandwich panels. The primary area of work focuses on the performance of sandwich panels under quasi-static and low-velocity impact loading with hemispherical and flat-ended indenters. The damage resistance is characterised in terms of damage mechanisms and energy absorption. The effects of varying the skin and core materials, skin thickness, core density, panel boundary conditions and indenter shape on the transverse strength and energy absorption of a sandwich panel have been examined. Damage mechanisms are found to include delamination of the impacted skin, core crushing, limited skin-core de bonding and top skin fibre fracture at high loads. In terms of panel construction the skin thickness is found to dominate the panel strength and energy absorption with core density having a lesser influence. Of the external factors considered the indenter noseshape has the largest effect on both failure load and associated damage area. An overview of existing analytical prediction methods is also included and the most significant theories applied and compared with the experimental results from this study. The secondary area of work expands the understanding obtained from the damage resistance study and assesses the ability of a sandwich panel to withstand in-plane compressive loading after sustaining low-velocity impact damage. The importance of the core material is investigated by comparing the compression-after-impact strength of both monolithic carbon-fibre laminates and sandwich panels with either an aluminium or nomex honeycomb core. The in-plane compressive strength of an 8 ply skinned honeycomb sandwich panel is found to be double that of a 16 ply monolithic laminate, with the type of honeycomb also influencing the compressive failure mechanisms and residual compressive strength. It is concluded that under in-plane loading the stabilising effect of the core opposes the de-stabilising effect of any impact damage.

629.1341

In-plane Compressive Response of Sandwich Panels

Lindström, Anders

January 2009

The high specific bending stiffness of sandwich structures can with advantage be used in vehicles to reduce their weight and thereby potentially also their fuel consumption. However, the structure must not only meet the in-service requirements but also provide sufficient protection of the vehicle passengers in a crash situation. The in-plane compressive response of sandwich panels is investigated in this thesis, with the objective to develop a methodology capable of determining if the structural response is likely to be favourable in an energy absorption perspective. Experiments were conducted to identify possible initial failure and collapse modes. The initial failure modes of sandwich panels compressed quasi-statically in the in-plane direction were identified as global buckling, local buckling (wrinkling) and face sheet fracture. Global buckling promotes continued folding of the structure when compressed beyond failure initiation. Face sheet fracture and wrinkling can promote collapse in the form of unstable debond crack growth, stable end-crushing or ductile in-plane shear collapse. Both the unstable debond crack propagation and the stable end-crushing are related to debond crack propagation, whereas the ductile in-plane shear mode is related to microbuckling of the face sheets. The collapse behaviour of sandwich configurations initially failing due to wrinkling or face sheet fracture was investigated, using a finite element model. The model was used to determine if the panels were likely to collapse in unstable debond propagation or in a more stable end-crushing mode, promoting high energy absorption. The collapse behaviour is mainly governed by the relation between the fracture toughness of the core and the bending stiffness and strength of the face sheets. The model was successfully used to design sandwich panels for different collapse behaviour. The proposed method could therefore be used in the design process of sandwich panels subjected to in-plane compressive loads.During a crash situation the accelerations on passengers must be kept below life threatening levels. The extreme peak loads in the structure must therefore be limited. This can be achieved by different kind of triggering features.Panels with either chamfered face sheets or with grooves on the loaded edges were investigated in this thesis. The peak load was reduced with panels incorporating either of the two triggering features. Another positive effect was that the plateau load following failure initiation was increased by the triggers. This clearly illustrates that triggers can be used to promote favourable response in sandwich panels. Vehicles are harmful to the environment not only during in-serve use, but during their entire life-cycle. By use of renewable materials the impact on the environment can be reduced. The in-plane compressive response of bio-based sandwich panels was therefore investigated. Panels with hemp fibre laminates showed potential for high energy absorption and panels with a balsa wood core behaved particular well. The ductile in-plane shear collapse mode of these panels resulted in the highest energy absorption of all investigated sandwich configurations. / QC 20100728

Sandwich

Finite Element Analysis (FEA)

Fracture

In-plane compression

Other engineering mechanics

Övrig teknisk mekanik

Structural and vibration physics

Struktur- och vibrationsfysik

Experimental impact damage resistance and tolerance study of symmetrical and unsymmetrical composite sandwich panels

Nash, Peter

January 2016

This thesis presents the work of an experimental investigation into the impact damage resistance and damage tolerance for symmetrical and unsymmetrical composite honeycomb sandwich panels through in-plane compression. The primary aim of this research is to examine the impact damage resistance of various types of primarily carbon/epoxy skinned sandwich panels with varying skin thickness, skin lay-up, skin material, sandwich asymmetry and core density and investigate the residual in-plane compressive strengths of these panels with a specific focus on how the core of the sandwich contributes to the in-plane compressive behaviour. This aim is supported by four specifically constructed preconditions introduced into panels to provide an additional physical insight into the loading-bearing compression mechanisms. Impact damage was introduced into the panels over a range of IKEs via an instrumented drop-weight impact test rig with a hemi-spherical nosed impactor. The damage resistance in terms of the onset and propagation of various dominant damage mechanisms was characterised using damage extent in both impacted skin and core, absorbed energy and dent depth. Primary damage mechanisms were found to be impacted skin delamination and core crushing, regardless of skin and core combinations and at high energies, the impacted skin was fractured. In rare cases, interfacial skin/core debonding was found to occur. Significant increases in damage resistance were observed when skin thickness and core density were increased. The reduction trends of the residual in-plane compressive strengths of all the panels were evaluated using IKE, delamination and crushed core extents and dent depth. The majority of impact damaged panels were found to fail in the mid-section and suffered an initial decline in their residual compressive strengths. Thicker skinned and higher density core panels maintained their residual strength over a larger impact energy range. Final CAI strength reductions were observed in all panels when fibre fracture in the impacted skin was present after impact. Thinner skinned panels had a greater compressive strength over the thicker skinned panels, and panel asymmetry in thin symmetrical panels appeared to result in an improving damage tolerance trend as IKE was increased due to that the impact damage balanced the in-plane compressive resistance in the skins with respect to the pre-existing neutral plane shift due to the uneven skin thickness.

629.134

Charakterisierung der Prozesskraftkomponenten beim mehrdimensionalen Umformen von Karton durch Ziehen

Lenske, Alexander

22 December 2023

Gegenstand dieser Arbeit ist die Entwicklung einer Methode zur Charakterisierung der komplexen Belastungssituation beim Tiefziehen mit unmittelbarer Kompression von Karton innerhalb geeigneter Ersatzversuche und deren Validierung mit Hilfe eines empirischen Models. Das Tiefziehen mit unmittelbarer Kompression stellt eine Möglichkeitzur Herstellung von dreidimensionalen Hohlkörpern mit hohem Umformgrad aus naturfaserbasierten, flächigen Halbzeugen mit geringem Vorfertigungsgrad dar.Aufbauend auf der Darstellung und Abgrenzung des Umformverfahrens werden relevante Prozessgrößen und deren Charakterisierung durch geeignete Ersatzversuche aus dem Stand der Wissenschaft recherchiert und bewertet. Zudem werden Möglichkeiten erörtert, die Ergebnisse der Ersatzversuche mit den Daten aus dem Umformverfahren zu vergleichen. Aus den technischen und wissenschaftlichen Defiziten ergibt sich die Zielsetzung und weitere Vorgehensweise dieser Arbeit.Zur Lösung der Problemstellung werden den identifizierten Prozessgrößen geeignete Ersatzversuche aus dem Stand der Technik zugeordnet bzw. neue Ersatzversuche entwickelt und im Rahmen eines modularen Versuchsstandes technisch umgesetzt. Zur Vorbereitung der experimentellen Analyse der ausgewählten Ersatzversuche werden Referenzversuche mit dem Umformverfahren innerhalb festgelegter Parametergrenzen durchgeführt. Bei der anschließenden Durchführung der Ersatzversuche wird vor allem die Verlässlichkeit der Ergebnisse berücksichtigt, indem die Anzahl der Versuche jeder Versuchsreihe an die Ergebnisauswertung angepasst wird.Durch die Modifikation des Umformverfahrens können die Ergebnisse der Ersatzversuche innerhalb eines stufenweise komplexer werdendes, empirischen Modelsmit denen des Referenzversuchs verglichen und bewertet werden. Die Charakterisierung der Prozesskraftkomponenten wird für vier faserbasierte Materialien durchgeführt,die teilweise mit einer polymeren Funktionsschicht ausgestattetsind.Abschließend werden die Ergebnisse dieser Arbeit zusammengefasst dargestellt und daraus folgende Forschungsansätze abgeleitet. / The purpose of this thesis is to present a newly developed method to investigate thecomplexload situation during the deep-drawing of paperboard within suitable substitute tests and its validation withinan empirical model.Deep drawing with direct compression represents analternativefor the production of three-dimensional traysfrom natural, fiber-based materials with a low degree of prefabrication.Based on the definition and description of the deep-drawing process within the literature, relevant process forces and associated substitute tests are identifiedand discussed. In addition, approachesare discussed to compare the results of the substitute tests with the data from the deep-drawingprocess. The objective and further procedure of this thesisresults from the technical and scientific deficits.The approach of this thesisis it to present a new, modular testing rig based on the substitute test which were chosen from the literature or were newly developed.In preparation ofthe experimental analysis of the selected substitutetests, reference tests are carried out with the forming process within specified parameter limits. In the subsequent implementation of the substitutetests, the reliability of the results is consideredabove all by adapting the number of tests in each test series parallel to the evaluation of the results. By modifying the forming process, the results of the substitute tests can be compared and evaluated with those of the reference test within an empirical model that becomes progressively more complex. The characterization of the process force components iscarried out for four fiber-based materials, some of which are equipped with a polymer functional layer.Finally, the results of this work are summarized,and the following research approaches are derived from them.

info:eu-repo/classification/ddc/679

ddc:679