Thermal characterization and comparison of different advanced composites for tooling applications

Valilla, Jorge

January 2019

The aim of this study if to give a comparison between different kind of high composite laminates (thin ply and conventional thickness plates) for tooling applications. The study mainly deals with the thermal behaviour of these materials after certain amount of time of exposure, and how this can affect the mechanical properties. This approach was chosen since thermal properties are of the biggest challenges when creating reliable parts to make tools.The study also serves as a deeper insight into the thin-ply laminates, how they work and give further characterization, since these are still novel technologies which have not reach the highest potential.The project was carried out within the Polymer and Composite division at Luleå University of Technology and is part of ongoing work of the Eureka platform (TOOLS) in collaboration with Airbus Spain as well as other institutes such as Swerea SICOMP Ab, Corebon Ab, Loiretech Mauves, Rise Acreo Ab and Lund University.

Composite Science and Engineering

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Tensile testing of 3D reinforced composites

Gonzales Eizaguirre, Maite

January 2011

No description available.

Composite Science and Engineering

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Novel Safety Requirements and Crash Test Standards for Light- Weight Urban Vehicles

Egertz, David

January 2011

In recent years the interest for smaller, cheaper and more energy efficient vehicles hasincreased significantly. These vehicles are intended to be used in urban areas, where theactual need of large heavy cars is generally minor. The travelled distance is on average lessthan 56km during a day and most often there is only one person travelling in the vehicle. Manyof the established car manufacturers have recently started to take interest into this marketsegment, but the majority of these small vehicles are still manufactured by smaller companiesat a low cost and with little or no research done on vehicle traffic safety. This may be becausethere are still no legal requirements on crash testing of this type of vehicles.This report will examine road safety for Urban Light-weight Vehicle (ULV) to find criticalcrash scenarios from which future crash testing methods for urban vehicles can be derived.The term ULV is specific to this report and is the title for all engine powered three- and fourwheeledvehicles categorized by the European Commission. Other attributes than the wheelgeometry is engine power and the vehicles unladen mass. The maximum allowed weight for athree-wheeled ULV is 1 000kg and 400kg for a four-wheeled one.By studying current crash test methods used in Europe by Euro NCAP it has beenconcluded that these tests are a good way of assessing car safety. For light-weight urbanvehicles it has been concluded that some of these tests need to be changed and that some newtest scenarios should be added when assessing road safety. The main reasons for this is linkedto that vehicle’s with a weight difference of more than 150kg cannot be compared withcurrent test methods, and that crash tests are performed with crash objects with similar orequal mass in current safety assessment programs. This correlates poorly to the trafficsituation for light-weight urban vehicles since it would most likely collide with a far heaviervehicle than itself in an accident event.To verify the actual traffic situation in urban areas, accident statistics have beenexamined closely. The research has shown that there are large differences between rural andurban areas. For instance; 66% of all severe and fatal traffic accident occurs in rural areaseven though they are less populated. Even the distribution of accident categories has showndifferent in rural and urban areas. The United Nations Economic Commission for Europe(UNECE) has defined accident categories in their database which is widely used within theEuropean Union. By comparing each accident category’s occurrence, injury and fatality rate,the most critical urban accident categories were found in the following order. 1. Collision due to crossing or turning 2. Vehicle and pedestrian collision 3. Rear-end collision 4. Single-vehicle accident 5. Other collisions 6. Head-on collision Statistics also show that of all fatally injured crash victims in urban trafficapproximately; one third is travelling by car; one third by motorcycle, moped or pedal-cycle;and one third are pedestrians. This means that unprotected road travelers correspond to twothirds of all fatal urban traffic accidents, a fact that has to be taken into account in future crashtesting of urban vehicles. With all the information gathered a total of four new crash testscenarios for light-weight urban vehicles have been presented: • Vehicle-to-vehicle side impact at 40km/h with a 1 300kg striking vehicle to evaluate theoccupant protection level of the light-weight vehicle. • Vehicle-to-motorcycle side impact at 40km/h with motorcycle rider protection evaluation. • Pedestrian protection assessment at 40km/h over the whole vehicle front and roof area. • Rigid barrier impact at 40km/h corresponding to an urban single vehicle accident with aroad side object or a collision with a heavier or similar sized vehicle.

Composite Science and Engineering

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Sandwich to Single Skin Laminate : A study of tapered transitions subjected to shear load

Lundell, Anders

January 2011

Any geometrical change and material transition renders a weak point accumulating stress concentrations in structural members. This research focuses on the transition between a sandwich panel and a single skin laminate, a setup commonly seen in yachts today. The need for different material layouts over a yacht’s complete structure leaves theses transitions inevitable. While the sandwich provides a strong and stiff, yet lightweight solution, the single skin is far more compliant and stronger when subjected to localised loads. The project included applying both finite element modelling and practical testing of the studied transition. Combining a computer based evaluation method with physical testing shortened production time and helped to focus the research on problematic areas of the design. Part of the project was also to highlight differences with these methods, their shortcomings and benefits, as well as how they can be used together as an effective way of research. The studied setups combined of three tapers including one to one, three to one, four and a half to one ratios and two different core thickness of the sandwich panel. Theses where partly modelled and tested in four point bending in a series of three load cases. Ranging from a shear load dominated to a much more mixed loading case including bending moment, the shear strength of the core could be seen as a reoccurring weak point of the structure. Results from modelling support earlier research on the benefits of a longer taper, lowering the stress concentrations at the tip of the transition, thus lowering the risk of further delamination. The practical testing indicated how the compression of the taper increased the shear strength of the core, making the taper far stronger than anticipated, leaving the uncompressed core material as the weakest point and the majority of times the source of failure. Successful in locating the critical element in the construction new difficulties with theconstruction could also be detected. The influence of the asymmetric laminate used, could be shown to affect the stress distributions but leaves more to be researched on how the laminates and core work together over the taper. The results and conclusions show that more work on this subject is needed, the complexity of the problem still needs tackled by decreasing the numbers of variables to reach a more general how tapers behave depending on the materials in use.

Composite Science and Engineering

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FE Analysis of a LAS-937 upper interface during combined compression loading

Sjölander, Jens

January 2011

A Finite Element Analysis of a load test of the LAS-937 adapter has been made to check if there is any risk that the aluminuim in the upper interface of the adapter yields. The analysis was done in ABAQUS CAE. The reason for doing the analysis is that the adapter was measured to be oval after the load-test. Several different analysises were run to check how sensitive the model was to a higher load or lower yield strength in the alumium. It was found that the resulting stresses in the FE-model interface is not high enough to explain the ovality of the the interface. Even with the higher load or lower yield strength properties the deformations in the FE-model were not as high as the measured ovality.

Composite Science and Engineering

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3D printing of ceramic composites with improved mechanical strength

Yuchen, Liu

January 2023

AbstractCeramic materials have a wide range of applications in many fields, but their fragility limits theiruse in high strength and high stress environments. Therefore, by combining ceramic materialswith reinforcing agents, their mechanical properties can be improved. In this study, a reinforcingmaterial (PMMA) suitable for combining with ceramics was selected and compounded usingpolymer infiltration techniques. Models were first designed and modelled using computer-aideddesign software, then printed using an appropriate 3D printing process (stereolithography) andraw material ratios to ensure that the desired porous ceramic structure was obtained. Themechanical properties of the composites were assessed by conducting mechanical tests on theprepared samples. It was observed that the polymer composite samples exhibited higher strengthand toughness compared to pure porous ceramic materials. This is due to the presence ofreinforced PMMA, which fully fills the pores of the scaffold and forms a strong matrix, thusenhancing the stiffness of the scaffold. The differences in mechanical properties of samples withdifferent structures and different porosity were also compared in order to screen for the mostsuitable porous ceramic scaffolds. The results of this study show that the mechanical propertiesof ceramic composites can be significantly improved by manufacturing them through a 3D printingprocess. This material with improved mechanical strength has potential for a wide range ofapplications in areas such as aerospace, automotive engineering and medical devices. Futureresearch could further explore the combination of different reinforcing materials and differentporous structures to obtain even higher performance ceramic composites.

Composite Science and Engineering

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Optimization of composite materials in 2D

Graf Brolund, Åke, Beccau, Edvin

January 2023

Composites are a useful type of material due to their ability to be created for specific applications. On the other hand composites often leads to a challenging optimization problem. Since composites often consists of more than two constituent materials it can be challenging to distribute the constituent materials in order to fulfill a certain mechanical property. The goal of this report is to construct an algorithm to optimize mechanical properties for a composite. The geometry of the composite is a 2-dimensional square with a pre-crack. The mechanical properties that the algoritm seeks to optimize is toughness and minimized stress in the crack tip. The results shows that the algoritm can be used in order to redistribute the constituent materials in order to improve a mechanical property.

Composite Science and Engineering

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Fiber/matrix interface crack propagation in polymeric unidirectional composite

Zhuang, Linqi

January 2016

Fiber/matrix interface cracking plays an important role in determining the final failure of unidirectional composites. In the present study, energy release rate (ERR) for fiber/matrix interface debond growth originated from fiber break in unidirectional composite is calculated using 5-cylinders axisymmetric and 3-D FEM models with hexagonal fiber arrangement. In the model the debonded fiber is central in the hexagonal unit which is surrounded by effective composite. The effect of neighboring fibers focusing on local fiber clustering on the ERR is analyzed by varying the distance between fibers in the unit. Two different scenarios are considered, one is the steady-state debond where debond are long and thus there is no interaction between debond tip and fiber break; the other case is when debond are relatively short when debond tip interacts with fiber break. The steady-state ERR is calculated from potential energy difference between a unit in the bonded region far away from the debond front and a unit in the debonded region far behind the debond front. The ERR for different modes of crack propagation is obtained from a FEM model containing a long debond by analyzing the stress at the debond front. For very short debonds, the ERR was calculated by both the J integral and the Virtual crack closure technique (VCCT).For steady-state debond growth, results show that in mechanical axial tensile loading fracture Mode II is dominating, it has strong angular dependence (effect of closest fibers) but the average ERR is not sensitive to the local fiber clustering. In thermal loading the Mode III is dominating and the average ERR is highly dependent on the distance to neighboring fibers. For short debod growth, results show that the debond growth is Mode II dominated and that the ERR strongly depends on the angular coordinate. The local fiber clustering has larger effect on the angular variation for shorter debonds and the effect increases with larger local fiber volume fraction. Finally, the ERR values from 5-cylinder axisymmetric model could be considered as upper bound for the 3-D hexagonal model.

Composite Science and Engineering

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A novel composite material from recycled constituents

Szpieg, Magdalena

January 2009

The increasing industrial use of carbon fibre in e.g. aircraft and wind turbines calls for strategies for their recovery and possible reuse. In additional, tremendous amount of energy is needed to be able to manufacture pristine carbon fibres. The work that has been done was to manufacture engineering composite material made from recyclates. Processing scrap from PURE® was extensively studied in terms of its stability and process ability as a thermoplastic matrix material. In a second study polypropylene scrap material was reprocessed into a film by press forming and introduced into a stack of carbon fibre preforms made from recycled carbon fibres recovered via a pyrolysis process from aircraft structures. The preform stack was heated and the composite material was manufactured by press forming.A challenging issue in this work was to achieve the desired distribution of the recovered carbon fibres in the fibre preforms. It is well known that dispersion of reinforcement is of immense importance for quality and performance of the composite materials. Here, a paper making method is employed to distribute the recovered carbon fibres randomly in the plane. The quality of the manufactured novel, fully recycled, composite material regarding void content and consolidation was controlled by extensive microscopy. The resulting composite material was analysed in terms of its mechanical performance including elastic modulus, Poisson's ratio, strength and strain to failure as well as its creep resistance.

Composite Science and Engineering

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Fracture mechanics analysis of damage initiation and evolution in fiber reinforced composites

Pupurs, Andrejs

January 2009

When a unidirectional (UD) fiber reinforced polymer composite is loaded in fiber direction in quasi-static or in a high stress cyclic tension-tension regime, many fiber breaks may occur in random positions already during the load increase in the first cycle. This is because fiber strain to failure in UD composites is lower than the polymer matrix strain to failure.In cyclic loading with constant amplitude we usually assume that fibers do not experience fatigue. Therefore the next step in damage evolution with increasing number of cycles may be development of interface cracks (debonds) growing along the fiber/matrix interface.Fracture mechanics concepts are applied and Mode II strain energy release rate GII related to debond crack growth along the fiber/matrix interface is used for damage evolution analysis.In Paper I analytical solution for Mode II energy release rate GII is found and parametric analysis performed in the self-similar debond crack propagation region. For short fiber/matrix debond cracks the self-similarity condition is not valid - due to interaction with fiber crack, GII is magnified. Thus in Paper II, numerical FEM simulations in combination with virtual crack closure technique are used in order to calculate GII for short debond cracks. The findings from GII analysis for self-similar and short debond cracks are summarized in simple expressions and then used in simulations of fiber/matrix interface debond crack growth in tension-tension fatigue using Paris law.In Paper III, debond growth in single fiber (SF) composites subjected to tension-tension fatigue is analyzed. Using the same procedure as for UD composites, first, an analytical solution for Mode II energy release rate GII is obtained for self-similar crack growth region. Then FEM calculations are performed in order to obtain GII magnification profiles for short debond cracks. For SF composites it was additionally found out that equal GII magnification profiles are obtained no matter if purely mechanical, purely thermal or combined mechanical and thermal load is applied to the composite. Thus for SF composites even simpler expressions can be used for simulations of debond growth using Paris law relation.

Composite Science and Engineering

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