Tragverhalten von Textilbeton mit Kurzfasern

Brameshuber, Wolfgang, Hinzen, Marcus

02 December 2011

Das Tragverhalten von Textilbeton kann durch den Einsatz von Kurzfasern erheblich verbessert werden. Untersuchungen zeigen eine Anhebung der Erstrisslast, ein dehnungsverfestigendes Verhalten, eine Verfeinerung des Rissbildes sowie eine Anhebung der maximalen Tragfähigkeit. Unklar sind bisher noch die genauen Mechanismen, die eine gezielte Einstellung des Tragverhaltens ermöglichen. Der Beitrag fasst die Untersuchungen zu den einzelnen Bereichen der Spannungs- ehnungslinie von Textilbeton mit Kurzfasern zusammen und versucht möglichst allgemeingültige Zusammenhänge darzustellen. Dabei werden die Erhöhung der Erstrisslast, die Rissüberbrückung und die Auswirkungen auf das Gesamttragverhalten betrachtet. Abschließend wird das zyklische Biegetragverhalten von Textilbeton mit Kurzfasern im gerissenen Zustand dargestellt. / The load bearing behaviour of textile reinforced concrete can be significantly improved by the addition of short fibres. Investigations show an increase of the first crack strength, a strain-hardening behaviour, a better crack pattern distribution as well as an increase of the load carrying capacity. However, the exact mechanisms leading to this behaviour are not yet known such that a prediction of the load bearing behaviour is not possible. This paper summarises the investigations on the different parts of the stress-strain curve of textile reinforced concrete with short fibres and tries to describe general relationships. In this context the increase of the first crack stress, the crack bridging behaviour and the influence on the load-bearing behaviour in general are considered. Finally, the dynamic flexural behaviour of textile reinforced concrete with short fibres in state II is presented.

Textilbeton

Kurzfasern

Rissbildung

zyklisches Tragverhalten

Zugfestigkeit

Textile reinforced concrete

Short fibres

Crack pattern

cyclic behavior

Tensile strength

ddc:690

rvk:ZI 7100

Tragverhalten von Textilbeton mit Kurzfasern

Brameshuber, Wolfgang, Hinzen, Marcus

January 2011

Das Tragverhalten von Textilbeton kann durch den Einsatz von Kurzfasern erheblich verbessert werden. Untersuchungen zeigen eine Anhebung der Erstrisslast, ein dehnungsverfestigendes Verhalten, eine Verfeinerung des Rissbildes sowie eine Anhebung der maximalen Tragfähigkeit. Unklar sind bisher noch die genauen Mechanismen, die eine gezielte Einstellung des Tragverhaltens ermöglichen. Der Beitrag fasst die Untersuchungen zu den einzelnen Bereichen der Spannungs- ehnungslinie von Textilbeton mit Kurzfasern zusammen und versucht möglichst allgemeingültige Zusammenhänge darzustellen. Dabei werden die Erhöhung der Erstrisslast, die Rissüberbrückung und die Auswirkungen auf das Gesamttragverhalten betrachtet. Abschließend wird das zyklische Biegetragverhalten von Textilbeton mit Kurzfasern im gerissenen Zustand dargestellt. / The load bearing behaviour of textile reinforced concrete can be significantly improved by the addition of short fibres. Investigations show an increase of the first crack strength, a strain-hardening behaviour, a better crack pattern distribution as well as an increase of the load carrying capacity. However, the exact mechanisms leading to this behaviour are not yet known such that a prediction of the load bearing behaviour is not possible. This paper summarises the investigations on the different parts of the stress-strain curve of textile reinforced concrete with short fibres and tries to describe general relationships. In this context the increase of the first crack stress, the crack bridging behaviour and the influence on the load-bearing behaviour in general are considered. Finally, the dynamic flexural behaviour of textile reinforced concrete with short fibres in state II is presented.

info:eu-repo/classification/ddc/690

ddc:690

Energy Efficient Composites for Automotive Industry.

Rojas, Mariana

January 2021

Hybrid composites play a key role in sustainable development. For many years, carbon fibres in an epoxy matrix have been an attractive option for many structural applications because of their higher specific mechanical properties mostly. However, recycling and sustainability are some of the composite shortcomings; and in that context, natural fibres have gained popularity.  The present study aimed to design and manufacture short carbon/flax hybrid composites. Two different arrangements were chosen: random and layers configuration. Resin Transfer Moulding (RTM) was used to fabricate these hybrid composites. Mechanical tests and optical microscopy technique were conducted to understand the effect of the interaction of these two different reinforcements. Mechanical tests showed a remarkable difference between the hybrid configurations under flexural loadings. Furthermore, outstanding property values were observed in the hybrid configurations compared to single fibre composites. The resultant materials have seemed an attractive combination of fibres with a remarkable balance between mechanical performance and eco-friendliness.

Hybrid composites

Short fibres

Carbon fibres

Flax fibres

Manufacturing

Resin Transfer Moulding (RTM)

Vacuum infusion

Tensile tests

Flexural tests

Composite Science and Engineering

Kompositmaterial och -teknik

Contribution à la compréhension de la fonctionnalisation mécanique de surface des composites à matrice thermoplastique (PEEK) destinés à l'assemblage par collage

Ourahmoune, Reda El Hak

20 December 2012

L’assemblage des matériaux composites thermoplastiques tel que le PEEK est l’une des problématiques majeure de l’industrie aéronautique. Actuellement, différentes techniques sont développées pour assurer l’assemblage structural de ces matériaux, tels que : le soudage, le rivetage, le boulonnage et le collage. Les enjeux industriels majeurs sont principalement, à l’heure actuelle, la conception des structures simplifiées au maximum afin de réduire les coûts de production et la réduction des consommations énergétiques. A cet effet, l’industrie aéronautique fait fréquemment appel à l’assemblage par collage en raison de nombreux avantages qu’il offre (gain de poids, distribution régulière des contraintes, absence de trous) par rapport aux autres techniques existantes. Le PEEK (PolyEtherEtherKetone), est un matériau polymère semi-cristallin thermoplastique, à hautes performances. Ce matériau est souvent utilise dans l’industrie aéronautique principalement renforce par des fibres de carbone ou de verre. Cependant, du fait du niveau élevé de sa résistance chimique l’assemblage par collage du PEEK et de ses composites nécessitent des traitements de surfaces appropries et optimises. Or, afin d’obtenir un system collé à haute performance, la problématique scientifique et technique doit être concentrée sur la jonction entre les éléments à assembler. En effet, la qualité de cette jonction est de la plus haute importance car elle doit permettre un transfert optimal des contraintes thermomécaniques lorsque l’assemblage est soumis a ses conditions d'usage. Cette étude concerne donc, l’amélioration des propriétés mécaniques (monotones et cycliques) de l’assemblage par collage PEEK/PEEK. Dans cette optique, un traitement de surface simple de mise en œuvre est proposé. Ce traitement est le sablage, qui permet la modification topographique (morphologique) de surface. La compréhension des différents phénomènes d’interaction aux interfaces intervenant dans l’amélioration du comportement mécanique du joint de colle et qui s’inscrit dans la triptyque : « Rhéologie, Physico-chimie et topographie », est l’enjeu scientifique majeur dans cette thèse. Dans un premier temps, l’influence des paramètres du traitement tels que le temps de projection, la taille des particules, sur la morphologie de surface de différents matériaux à base de PEEK a été analysée, permettant ainsi d’établir la corrélation entre les paramètres morphologiques et les mécanismes de modification topographique de surface intervenant pendant le traitement de surface. L’un des facteurs clefs pour la compréhension des mécanismes d’interaction entre l’adhésif liquide et le substrat solide est la mouillabilité. L’analyse du comportement au mouillage en fonction des différents paramètres du traitement a été réalisée. La mouillabilité des surfaces traitées est fortement affectée par la rugosité de surface créée après ce traitement. La relation entre les paramètres morphologiques et la mouillabilité a été discutée. Enfin, l’influence des paramètres du traitement par sablage sur le comportement mécanique monotone et à long terme (essais de fatigue) sur la résistance du joint colle a été étudié à l’aide d’essais de cisaillement sur éprouvettes à simple recouvrement. Ceci a conduit, à la proposition de paramètres morphologiques surfaciques spécifiques pour l’optimisation du comportement mécanique du joint de colle des matériaux composites à matrice PEEK. / One of most problematic in the aeronautical industries is the structural joining of the high performance thermoplastic composites like PEEK composites. Actually, a lot of technologies are used for joining thermoplastic composites like welding, bolting, riveting, fastening and adhesive bonding. Due to the various advantages that characterize the adhesive bonding method, such an uniform stress distribution along the joint, weight‐light and cost reduction, makes this technique more desirable to join thermoplastic composites materials compared to the other joining techniques. PEEK (PolyEtherEtherKetone) is a semi‐crystalline thermoplastic material with high performance. This material is wildly used in aeronautical industries, principally, reinforced with carbon of glass fibres. However, its high chemical resistance makes the adhesive bonding of PEEK and its composites difficult and therefore an appropriate and optimised surface treatment is necessary. In the aim to obtain a bonded system with high performance, scientific and technical problematic should be focussed on the junction between adherents. Indeed, the quality of this junction is of utmost importance because it must allow optimum transfer of thermomechanical stresses when the assembly is subject to its terms of use. Though, at this time it is well known that thermoplastic composite materials are difficult to bond with‐out surface treatment. This study, therefore, relates to the improvement of mechanical properties (monotonic and cyclic) of the adhesive bonding system PEEK / PEEK. In this context, a surface treatment, easy to implement, is proposed. This surface treatment is sandblasting, which enables surface topographic (morphological) modifications. Understanding of various phenomena of interfaces interaction involved in the improvement of the mechanical behavior of the adhesive joint and is part of the triptych "Rheology, Physico‐chemistry and topography" is the major scientific challenge in this thesis. Initially, the influence of processing parameters such as the projection time, the particle size on surface morphology of various materials based on PEEK was analysed, thus allowing establishing the correlation between morphological parameters and modification mechanisms involved during surface treatment surface. One of the key factors for understanding the mechanisms of interaction between the liquid adhesive and the solid substrate is wettability. The analysis of the wetting behavior as a function of various parameters of the treatment was performed. The wettability of treated surfaces is strongly affected by surface roughness created after this treatment. The relationship between morphological parameters and wettability was discussed. Finally, the influence of sandblasting processing parameters on the mechanical behavior in monotoning and long‐term (fatigue tests) of the adhesive joint strength was studied, using single lap shear tests specimens. This has led to the proposal of specific surface morphological parameters for the optimization of the mechanical behavior of the adhesive joint of PEEK and its composites.

PEEK

Composites à fibres discontinues

Composites quasi-isotropes

Sablage

Rugosité

Paramètres morphologiques

Mouillabilité

Collage

Essai à simple recouvrement

Essai de fatigue

Énergie dissipée

PEEK

Short fibres reinforced composites

Quasi-isotropic composites

Roughness sandblasting

Morphological parameters

Wettability

Adhesive bonding

Single lap shear test

Fatigue test

Dissipated energy

The Influence of Fibre Processing and Treatments on Hemp Fibre/Epoxy and Hemp Fibre/PLA Composites

Islam, Mohammad Saiful

January 2008

In recent years, due to growing environmental awareness, considerable attention has been given to the development and production of natural fibre reinforced polymer (both thermoset and thermoplastic) composites. The main objective of this study was to reinforce epoxy and polylactic acid (PLA) with hemp fibre to produce improved composites by optimising the fibre treatment methods, composite processing methods, and fibre/matrix interfacial bonding. An investigation was conducted to obtain a suitable fibre alkali treatment method to: (i) remove non-cellulosic fibre components such as lignin (sensitive to ultra violet (UV) radiation) and hemicelluloses (sensitive to moisture) to improve long term composites stability (ii) roughen fibre surface to obtain mechanical interlocking with matrices (iii)expose cellulose hydroxyl groups to obtain hydrogen and covalent bonding with matrices (iv) separate the fibres from their fibre bundles to make the fibre surface available for bonding with matrices (v) retain tensile strength by keeping fibre damage to a minimum level and (vi) increase crystalline cellulose by better packing of cellulose chains to enhance the thermal stability of the fibres. An empirical model was developed for fibre tensile strength (TS) obtained with different treatment conditions (different sodium hydroxide (NaOH) and sodium sulphite (Na2SO3) concentrations, treatment temperatures, and digestion times) by a partial factorial design. Upon analysis of the alkali fibre treatments by single fibre tensile testing (SFTT), scanning electron microscopy (SEM), zeta potential measurements, differential thermal analysis/thermogravimetric analysis (DTA/TGA), wide angle X-ray diffraction (WAXRD), lignin analysis and Fourier transform infrared (FTIR) spectroscopy, a treatment consisting of 5 wt% NaOH and 2 wt% Na2SO3 concentrations, with a treatment temperature of 120oC and a digestion time of 60 minutes, was found to give the best combination of the required properties. This alkali treatment produced fibres with an average TS and Young's modulus (YM) of 463 MPa and 33 GPa respectively. The fibres obtained with the optimised alkali treatment were further treated with acetic anhydride and phenyltrimethoxy silane. However, acetylated and silane treated fibres were not found to give overall performance improvement. Cure kinetics of the neat epoxy (NE) and 40 wt% untreated fibre/epoxy (UTFE) composites were studied and it was found that the addition of fibres into epoxy resin increased the reaction rate and decreased the curing time. An increase in the nucleophilic activity of the amine groups in the presence of fibres is believed to have increased the reaction rate of the fibre/epoxy resin system and hence reduced the activation energies compared to NE. The highest interfacial shear strength (IFSS) value for alkali treated fibre/epoxy (ATFE) samples was 5.2 MPa which was larger than the highest value of 2.7 MPa for UTFE samples supporting that there was a stronger interface between alkali treated fibre and epoxy resin. The best fibre/epoxy bonding was found for an epoxy to curing agent ratio of 1:1 (E1C1) followed by epoxy to curing agent ratios of 1:1.2 (E1C1.2), 1: 0.8 (E1C0.8), and finally for 1:0.6 (E1C0.6). Long and short fibre reinforced epoxy composites were produced with various processing conditions using vacuum bag and compression moulding. A 65 wt% untreated long fibre/epoxy (UTLFE) composite produced by compression moulding at 70oC with a TS of 165 MPa, YM of 17 GPa, flexural strength of 180 MPa, flexural modulus of 10.1 GPa, impact energy (IE) of 14.5 kJ/m2, and fracture toughness (KIc) of 5 MPa.m1/2 was found to be the best in contrast to the trend of increased IFSS for ATFE samples. This is considered to be due to stress concentration as a result of increased fibre/fibre contact with the increased fibre content in the ATFE composites compared to the UTFE composites. Hygrothermal ageing of 65 wt% untreated and alkali treated long and short fibre/epoxy composites (produced by curing at 70oC) showed that long fibre/epoxy composites were more resistant than short fibre/epoxy composites and ATFE composites were more resistant than UTFE composites towards hygrothermal ageing environments as revealed from diffusion coefficients and tensile, flexural, impact, fracture toughness, SEM, TGA, and WAXRD test results. Accelerated ageing of 65 wt% UTLFE and alkali treated long fibre/epoxy (ATLFE) composites (produced by curing at 70oC) showed that ATLFE composites were more resistant than UTLFE composites towards hygrothermal ageing environments as revealed from tensile, flexural, impact, KIc, SEM, TGA, WAXRD, FTIR test results. IFSS obtained with untreated fibre/PLA (UFPLA) and alkali treated fibre/PLA (ATPLA) samples showed that ATPLA samples had greater IFSS than that of UFPLA samples. The increase in the formation of hydrogen bonding and mechanical interlocking of the alkali treated fibres with PLA could be responsible for the increased IFSS for ATPLA system compared to UFPLA system. Long and short fibre reinforced PLA composites were also produced with various processing conditions using compression moulding. A 32 wt% alkali treated long fibre PLA composite produced by film stacking with a TS of 83 MPa, YM of 11 GPa, flexural strength of 143 MPa, flexural modulus of 6.5 GPa, IE of 9 kJ/m2, and KIc of 3 MPa.m1/2 was found to be the best. This could be due to the better bonding of the alkali treated fibres with PLA. The mechanical properties of this composite have been found to be the best compared to the available literature. Hygrothermal and accelerated ageing of 32 wt% untreated and alkali treated long fibre/PLA composites ATPLA composites were more resistant than UFPLA composites towards hygrothermal and accelerated ageing environments as revealed from diffusion coefficients and tensile, flexural, impact, KIc, SEM, differential scanning calorimetry (DSC), WAXRD, and FTIR results. Increased potential hydrogen bond formation and mechanical interlocking of the alkali treated fibres with PLA could be responsible for the increased resistance of the ATPLA composites. Based on the present study, it can be said that the performance of natural fibre composites largely depend on fibre properties (e.g. length and orientation), matrix properties (e.g. cure kinetics and crystallinity), fibre treatment and processing methods, and composite processing methods.

Hemp Fibre

Epoxy Resin

Poly(lactic acid)

Interfacial Shear Strength

Fracture Toughness

Impact Energy

Tensile Properties

Flexural Properties

Accelerated Ageing

Hygrothermal Ageing

Experimental Design

Cure Kinetics

Dynamic Sheet Forming

Long and Short Fibres

Untreated Fibre

Alkali Treated Fibre

Silane Treated Fibre

Acetylated Fibre

Zeta Potential

Differential Scanning Calorimetry

X-ray Diffraction

Infrared Spectra.