Einfluss fertigungsbedingter Imperfektionen auf die Schwingfestigkeit von FKV-Schalenstrukturen in Sandwichbauweise

Nielow, Dustin

11 April 2022

Rotorblätter von Windenergieanlagen (WEA) weisen häufig lange vor dem Erreichen der prognostizierten Lebensdauer von 20 bis 30 Jahren Risse in der Blattschale auf. Die Folge sind aufwendige Reparaturen am installierten und schwer zugänglichen Rotorblatt und der kostenintensive Nutzungsausfall durch den Stillstand der WEA. Als mögliche Initiatoren für die Schäden in der Blattschale der Rotorblätter gelten fertigungsbedingte Imperfektionen. Für die Untersuchung des Einflusses dieser Imperfektionen auf das Ermüdungsverhalten der Rotorblätter wurde an der BAM (Bundesanstalt für Materialforschung und -prüfung) ein Prüfstand für statische und zyklische Versuche von Schalensegmenten im intermediate scale entwickelt und betrieben. Die untersuchten Schalensegmente in Sandwichbauweise sind der Rotorblattschale von WEA im Hinblick auf die Strukturmechanik, die Halbzeuge, den Laminataufbau und dem eingesetzten Fertigungsverfahren ähnlich. Als Imperfektionen wurden verschiedenen Variationen von Lagenstößen in die Hautlagen und Schaumstöße mit Breitenvariation in den Stützkern reproduzierbar eingebracht. Die Überwachung des Schädigungszustandes während der Schwingversuche unter realistischen Lastszenarien erfolgt über eine kombinierte in situ Schädigungsüberwachung mittels passiver Thermografie und Felddehnungsmessung. Mit den durchgeführten Schwingversuchen, der begleitenden Überwachung des Schädigungszustandes sowie dem validierten FEM-Modell ließen sich die Schadensinitiation und die signifikante Reduktion der Lebensdauer durch die eingebrachten Imperfektionen zweifelsfrei nachweisen. Die abgeleiteten Designregeln liefern für die Ingenieurpraxis wichtige Konstruktionshinweise und unterstützen die betriebssichere Auslegung von gekrümmten Sandwichkonstruktionen wie beispielsweise WEA-Rotorblätter.:1 Einleitung 1.1 Motivation 1.2 Zielsetzung 2 Stand der Technik 2.1 Grundlagen FKV-Werkstoffe 2.2 Rotorblätter von Windenergieanlagen 2.2.1 Rotorblattfertigung im SCRIMP-Verfahren 2.2.2 Typische fertigungsbedingte Imperfektionen im Rotorblatt 2.2.3 Lasten am Rotorblatt 2.2.4 Rotorblattprüfung und Komponentenversuche 2.3. Schalentheorie von monolithischen und Sandwichstrukturen 2.3.1 Analytische Betrachtung orthotroper Schalen 2.3.2 Versagensverhalten von Sandwichstrukturen unter Druckbelastung 2.3.3 Analytische Beschreibung des Stabilitätsversagens von Sandwichstrukturen 2.4 Strukturverhalten von Sandwichstrukturen unter statischen und zyklischen Lasten 2.5 Versagenskriterium für monolithisches Laminat nach Puck 2.6 Ermüdungsverhalten monolithischer Winkel-Mehrschichtverbunde 2.7 Materialcharakterisierung der GFK-Decklagen 2.7.1 Statische Materialkennwerte der GFK-Decklagen 2.7.2 Schwingversuche zur Ermittlung der Wöhlerkurve der GFK-Decklagen 2.7.3 Lineare Schädigungsakkumulation zur Berechnung der Schadensbeiträge 2.7.4 Schädigungsmechanismen bei statischer Schub-Zug-Beanspruchung 2.7.5 Im RHV-Schwingversuch erfasste Schädigungsmechanismen 2.8 In situ Überwachung des Schädigungszustandes mittels zerstörungsfreier Prüfung 2.8.1 In situ Überwachung - Optische Felddehnungsmessung 2.8.2 In situ Überwachung – passive Thermografie 3 Versuchsplanung 3.1 Schalenprüfstand für Substrukturen-Versuche 3.1.1 Anforderungen an den Schalenprüfstand 3.1.2 Konstruktion und Umsetzung 3.1.3 Integrierte Zustandsüberwachung 3.2 Der Schalenprüfkörper für Substrukturen-Versuche 3.2.1 Schalenprüfkörper – Auslegung 3.2.2 Schalenprüfkörper - Fertigungsverfahren 3.2.3 Schalenprüfkörper - Eingebrachte Imperfektionen 4 Statische und zyklische Versuche an Schalenprüfkörpern 4.1 Statische Versuche an Schalenprüfkörpern 4.1.1 Mit der Felddehnungsmessung detektierte Prüfkörperverformung 4.1.2 Detektierte Z-Verschiebung mittels Felddehnungsmessung 4.1.3 Diskussion der detektierten Verformung des Schalenprüfkörpers 4.1.4 Fazit – statische Druckversuche an Sandwichschalen 4.2 Numerische Abbildung des Schalenprüfkörpers 4.2.1 Nichtlineare Stabilitätsanalyse - Schalenprüfkörper ohne Imperfektion 4.2.2 Validierung des im FEM-Schalenmodell modellierten komplexen Verformungsverhaltens unter statischer Axiallast 4.2.3 FEA – laminatschichtweise Analyse der Anstrengung (Zfb, Puck) 4.2.4 Diskussion FEM-Schalenmodell 4.3 Schwingversuche an Schalenprüfkörpern 4.3.1 Referenzprüfkörper – Einstufen-Schwingversuch 4.3.2 Referenzprüfkörper – Zweistufen-Schwingversuch 4.3.3 Referenzprüfkörper - lokaler Steifigkeitsabfall im Mehrstufen-Schwingversuch 4.3.4 Referenzprüfkörper: Fazit der Ein- und Mehrstufen-Schwingversuche 4.3.5 Zweistufen-Schwingversuche an Prüfkörpern mit Imperfektionen 4.3.6 Im Mehrstufen-Schwingversuch erreichte Lastspielzahlen 4.3.7 Nachweis der Schadensinitiierung - Ansatz zur erweiterten Auswertung der passiven Thermografie 5 Diskussion der Ergebnisse 5.1 Diskussion der statischen Schalenversuche 5.2 Diskussion der Schwingversuche von Schalenprüfköpern 5.2.1 Schadensakkumulationsprozess der Sandwich-Schalenprüfkörper unter Zug-Druck-Wechsellast 5.2.2 Lastspielzahlen: Vergleich Material- und Substrukturen-Versuche 5.2.3 Anstrengung: Vergleich Material- und Substrukturen-Versuche 5.2.4 Angewendete ZfP-Verfahren: Sichtprüfung, passive Thermografie und Felddehnungsmessung 5.3 Diskussion der Skalierung auf die Blattschale realer Rotorblätter 6 Ausblick 7 Zusammenfassung Literaturverzeichnis Abbildungsverzeichnis Tabellenverzeichnis Anhang

info:eu-repo/classification/ddc/620

ddc:620

[en] ANTICORROSIVE ORGANIC COATING NANOFILLED WITH REDUCED GRAPHENE OXIDE IN CO2 ENVIRONMENT / [pt] REVESTIMENTO ORGÂNICO ANTICORROSIVO NANO ADITIVADO COM ÓXIDO DE GRAFENO REDUZIDO EM AMBIENTE DE CO2

ANANIAS ALEXANDRE EMMERICK

14 June 2023

[pt] Esta pesquisa avaliou a resistência a corrosão de revestimentos de base em resina epóxi, reforçada com 0,1% wt e 0,5% wt de óxido de grafeno reduzido (rGO), aplicado sobre um substrato em aço carbono AISI 1020. Como teste de corrosão foi aplicado testes de imersão em solução com 3,0% wt de NaCl saturadas com CO2, em um vaso de pressão a 70 bar na temperatura de 40 ᵒC, por 528 h. Os revestimentos foram avaliados por teste de aderência (Pull Off), microdureza (Dureza Shore D) e caracterizado por Microscopia Eletrônica de Varredura (MEV) quanto a qualidade de ancoragem do revestimento ao substrato, porosidade e espessura, para a análise de existência de pites na superfície do substrato metálicos foi utilizada microscopia ótica (MO). Os resultados obtidos evidenciaram que os revestimentos nas três condições, como recebido, aditivados com 0,1% wt e 0,5% de rGO tiveram a mesma eficiência na proteção do substrato metálico, todos igualmente, evitaram a formação de pites nas condições de testes propostas. Para adição de 0,1% wt de rGO ocorreu refinamento dos poros e a adição de 0,5% wt promoveu drástica redução da densidade de poros. A adição do rGO não influenciou na Dureza Shore D dos revestimentos. Para pré teste de corrosão, o revestimento com 0,1% wt de rGO obteve maior densidade de poros e menor valor de dureza, seguido pelo 0,0% wt e posterior 0,5% wt de rGO. Para pós testes de corrosão a ordem é invertida. Os resultados pós testes de corrosão indicaram que a porosidade possibilitou a permeação da solução nos revestimentos, e está relacionada com as bolhas e empolamentos, que influenciaram na dureza. A adição de 0,1% wt e 0,5% wt de rGO não influenciou na ancoragem dos revestimentos, obtendo boa acomodação nas irregularidades da superfície metálica do substrato. / [en] This research evaluated the corrosion resistance of an epoxy resin-based coat, reinforced with 0.1 and 0.5 wt% of reduced graphene oxide (rGO), applied to AISI 1020 carbon steel. Immersion tests in aqueous solution with 3.0 wt% NaCl saturated with CO2, in a pressurized cell at 70 bar at 40⁰C, for 528 h. The coating was evaluated by Pull-Off Test, microhardness (Shore D hardness), and Scanning Electron Microscopy (SEM). The quality of the coating anchoring to the substrate, porosity, and thickness was evaluated. The presence of pits on the surface of the metallic substrate was assessed by Optical Microscopy (OM). The results obtained indicated that the addition of rGO contributed to greater corrosion resistance and provided better structural integrity to the coating. The results obtained showed that the coatings under the three conditions, as received and 0.1 and 0.5wt% rGO additions had the same efficiency in protecting the metallic substrate, avoiding pitting. Pore refinement occurred for 0.1wt % rGO, and the addition of 0.5wt% promoted a drastic reduction in pore density. The addition of rGO did not influence on the Shore D Hardness of the coatings. For a precorrosion test, the coating with 0.1wt% of rGO obtained higher pore density and lower hardness value, followed by 0 wt% and later 0.5 wt% of rGO. For the post corrosion test, the order is reversed. The results of the post corrosion test indicated that the porosity allowed the permeation of the solution in the coatings and is related to the bubbles and blistering, which influenced the hardness. The addition of 0.1 and 0.5 wt% or rGO did not affect the coating anchoring, obtaining reasonable accommodation in the irregularities of the substrate metallic surface.

[pt] REVESTIMENTO

[pt] REFINO DE POROS

[pt] RESINA EPOXI NOVOLAC

[pt] OXIDO DE GRAFENO REDUZIDO

[pt] CORROSAO POR CO2

[pt] GRAFENO

[pt] NANOCOMPOSITOS

[en] COATING

[en] PORE REFINING

[en] NOVOLAC EPOXY RESIN

[en] REDUCED GRAPHENE OXIDE

[en] CO2 CORROSION

[en] GRAPHENE

[en] NANOCOMPOSITES

Novel phosphorus containing poly(arylene ethers) as flame retardant additives and as reactant in organic synthesis

Satpathi, Hirak

13 August 2015

Due to their outstanding properties, poly(arylene ethers) are useful as toughness modifiers in epoxy resins (EP). Furthermore, these polymers show rather low intrinsic fire risks. According to recent research it has been incorporated that poly(arylene ether phosphine oxides) [PAEPO’s] can further improve the fire behavior. Increasing phosphorous content of the PAEPO can influence the fire behavior too. Fire retardants containing phosphorus – regardless of whether an additive or reactive approach is used – show different mechanisms in the condensed and gas phase. In the present study PSU Control (BPA based polysulfone) with four different PAEPO’s and their corresponding blends with an EP were investigated. All poly(arylene ether phosphine oxides) were synthesized by nucleophilic aromatic polycondensation. The polymers obtained covered a wide range of weight average molar masses (6,000 – 150,000 g/mol) as determined by size exclusion chromatography with multi-angle light scattering detection (MALLS). FTIR, NMR spectroscopy and MALDI-TOF revealed formation of the desired polymer structure of the linear poly(arylene ethers). All polymers were easily soluble in common organic solvents, thus enabling processing from solution.The pyrolysis and the fire retardancy mechanisms of the polymers and blends with epoxy resin (EP) were tackled by means of a comprehensive thermal analysis (thermogravimetry (TG), TG-evolved gas analysis) and fire tests [PCFC, limiting oxygen index (LOI), UL-94, cone calorimeter]. The Mitsunobu reaction of Dimethyl-5-hydroxyisophthalate and a long chain semifluorinated alcohol requires triphenyl phosphine as a reactant. Identical, in some case higher yield was obtained in the usual conditions, with triphenyl phosphine and with trivalent phosphorus containing polymers, which was prepared in solvent free bulk (melt) polymerization technique from trivalent phosphorus monomer and a silylated diphenol in presence of CsF. Purification and the recovery of the final product which is always a big challenge in case of Mitsunobu reaction, was far more easier using polymer compared to triphenyl phosphine. During polymerization there was a possibility to have polymer having repeating unit containing both trivalent phosphorus and phosphine oxide. The trivalent phosphorus content of the polymer can be varied using different molar concentration of CsF.

Trivalent phosphorus containing polymers

Mitsunobu Reaction

Melt polycondensation

Epoxy Resin

Thermogravimetry

Limiting oxygen index [LOI]

UL 94

Cone calorimeter

Trivalent phosphorus containing polymers

Mitsunobu Reaction

Melt polycondensation

Epoxy Resin

Thermogravimetry

Limiting oxygen index [LOI]

UL 94

Cone calorimeter

ddc:540

rvk:VN 5907

Manufacturing and experimental investigation of green composite materials / Κατασκευή και μελέτη σύνθετων υλικών φιλικών προς το περιβάλλον

Κουτσομητοπούλου, Αναστασία

30 April 2014

The aim of the present thesis is to explore sustainable low cost environmentally friendly composite materials. It is a step by step experimental research. Firstly, taking under consideration the so far commercial available non-organic materials used as reinforcement and the petroleum based resins used as matrices, composite materials were fabricated and mechanically characterized. Different components in micro- and nano- scale were combined. Afterwards, the non-organic materials used as reinforcements were substituted by different types of non conventional natural-based fillers. The fillers (corn starch and olive pit granules) were in powder form, derived from agricultural local resources and additionally flax fabric used to produce laminated composites. All the semi-green epoxy composites were characterized by means of three-point bending testing. Moreover, the manufactured composites were induced in several sources of damage and their residual properties were extensively investigated. More precisely, the effect of the strain-rate and low velocity impact as well as of thermal fatigue, on the mechanical properties of the olive pit and the flax fabric reinforced resin was studied. Since, conventional and semi-green composite materials were fabricated and experimentally investigated, the final objective of the present thesis was to produce novel green composites materials by substituting the petroleum-based epoxy resin with a biodegradable derived from natural resources biopolyester. In order to accomplish this target, polylactic acid (PLA) was combined with olive pits in powder form at different concentrations. Olive pits, is almost unknown non-traditional filler to composites, obtained during the oil extraction process. It is a raw material characterized by its low cost and its abundance, since it consists a waste product of the olive oil industry. In order to successfully accomplish this part of research, experiments were taken place in France at the CMGD (Centre des Matériaux de Grande Diffusion) Institute of the École Nationale Supérieure des Mines d’ Alés, under the guidance of Prof. A. Bergeret within the framework of research cooperation with the main supervisor of this thesis, Prof. G. Papanicolaou. The most important feature of the present green composites is their satisfactory mechanical and thermal performance in combination with their complete biodegradability. The PLA/olive pit composites could be applied to various components with moderate strength such as automotive interiors, interior building applications, durable goods, serviceware and food packaging material The aim of this part of the study was to investigate the effect of three types of olive pit powder at different weights fractions on the physical and mechanical properties of polylactide (PLA) matrix composites. For the preparation of the powder, two different grinding procedures were applied, producing three types of olive pit powder. Various measurements were accomplished to determine characteristics such as the density and the size distribution and the shape of the powder. Different PLA/ olive pits powder composites were manufactured by extrusion and injection molding. A comparative study between the different composites was made in order to investigate the matrix-filler interactions, occurring between the PLA and olive pit granules and their overall physical, mechanical and thermomechanical properties were investigated by means of TGA, FT-IR, DSC, SEM, flexural and uni-axial tensile testing. Finally, theoretical predictive models were applied in most of the composite materials manufactured in the present work. These models making use of minimal number of experimental results can satisfactorily predict the residual properties of damaged materials, irrespectively of the type of the material investigated and the damage source. Namely, the Modulus Predictive Model (ΜPM), the Residual Properties Model (RPM) and the Residual Strength after Impact Model (RSIM), have been successfully applied. A big number of interesting conclusions have been derived from the present work. However, a general conclusion is that a totally green composite with useful properties and applications is a promising target for the humanity and the planet survivability. / Σκοπός της παρούσας διδακτορικής διατριβής είναι η κατασκευή και μελέτη συνθέτων υλικών χαμηλού κόστους ενισχυμένων με φυσικά υλικά, φιλικά προς το περιβάλλον. Η επίτευξη αυτού του στόχου πραγματοποιήθηκε σταδιακά. Αρχικά, πραγματοποιήθηκε μια εκτεταμένη μελέτη διαφορετικών συνθέτων υλικών τα οποία ήταν εξ’ ολοκλήρου κατασκευασμένα από ανόργανα και συνθετικά υλικά. Γι’ αυτό το σκοπό κατασκευάστηκαν και μελετήθηκαν οι μηχανικές ιδιότητες συνθέτων υλικών που έχουν ως μήτρα μια εμπορικά διαθέσιμη πετροχημική εποξειδική ρητίνη. Η εποξειδική ρητίνη ενισχύθηκε με ανόργανα υλικά σε μικρο- (συμπαγή και κενά σφαιρίδια γυαλίου) και νανο- (νανοσωλήνες άνθρακα πολλαπλού τοιχώματος) διαστάσεις. Στη συνέχεια, βασιζόμενη στο ήδη υπάρχον επιστημονικό υπόβαθρο, καθώς η μεταπτυχιακή μου εργασία ειδίκευσης ήταν στο ίδιο ερευνητικό πεδίο με το αντικείμενο της διδακτορικής μου διατριβής, γίνεται προσπάθεια περαιτέρω εξέλιξης της έρευνας που σχετίζεται με την μελέτη και κατασκευή συνθέτων φιλικών προς το περιβάλλον. Ως εκ τούτου, το επόμενο στάδιο της πειραματικής μελέτης στα πλαίσια εκπόνησης της διατριβής αυτής, ήταν η κατασκευή και χαρακτηρισμός, ως προς την μηχανική τους συμπεριφορά, συνθέτων υλικών πολυμερικής εποξειδικής μήτρας ενισχυμένης με διαφορετικού τύπου φυσικές ενισχύσεις και περιεκτικότητες. Οι φυσικές ενισχύσεις που επιλέχθηκαν να μελετηθούν ήταν τόσο σε μορφή κόκκων και μικρο-ινών, όσο και σε μορφή υφάσματος. Τα εγκλείσματα που χρησιμοποιήθηκαν ήταν σκόνη από κόκκους ελαιοπυρήνα και σκόνη αμύλου καλαμποκιού. Στα σύνθετα υλικά ενισχυμένα με κόκκους ελαιοπυρήνα, έγινε μελέτη της επίδρασης των διαφορετικών ρυθμών παραμόρφωσης στις μηχανικές τους ιδιότητες, ενώ στα σύνθετα υλικά ενισχυμένα με την σκόνη αμύλου μελετήθηκαν εκτενώς οι στατικές μηχανικές τους ιδιότητες. Επιπλέον, κατασκευάστηκαν πολύστρωτα σύνθετα υλικά χρησιμοποιώντας για τις διάφορες στρώσεις ύφασμα από ίνες λιναριού. Τα πολύστρωτα σύνθετα υλικά χαρακτηρίστηκαν ως προς τις μηχανικές τους ιδιότητες, υποβλήθηκαν σε θερμική κόπωση και υπέστησαν κρούση χαμηλής ενέργεια. Οι εναπομένουσες μηχανικές ιδιότητες των υλικών αυτών μελετήθηκαν τόσο πειραματικά όσο και θεωρητικά. Ο απώτερος στόχος αυτής της διδακτορικής διατριβής ήταν να γίνει η δυνατή η κατασκευή συνθέτων υλικών τα οποία να είναι πλήρως βιοδιασπώμενα και φιλικά προς το περιβάλλον. Για το σκοπό αυτό, το τρίτο και τελευταίο στάδιο της έρευνας που διεξήχθη στα πλαίσια της παρούσας διατριβής, ήταν η κατασκευή εξολοκλήρου φυσικών συνθέτων υλικών έχοντας ως μήτρα ένα βιοδιασπώμενο πολυεστέρα φυτικής προέλευσης, το πολύ (γαλακτικό οξύ), ενισχυμένο με σκόνη από κόκκους ελαιοπυρήνα. Ο ξηρός ελαιοπυρήνας που χρησιμοποιήθηκε, αποτελεί μέρος των αποβλήτων που προκύπτουν από την διαδικασία παραγωγής ελαιολάδου. Ο ελαιοπυρήνας σε αυτή την μορφή έχοντας μηδαμινό κόστος απαντάται σε εξαιρετικά μεγάλες ποσότητες και σε σημαντικό ποσοστό εναποτίθεται στους περιβάλλοντα χώρους των μονάδων παραγωγής του ελαιολάδου. Η ερευνητική εργασία που σχετίζεται με αυτό το αντικείμενο του διδακτορικού έλαβε χώρα στην Γαλλία στο École Nationale Supérieure des Mines d’ Alés, στο ερευνητικό ινστιτούτο CMGD (Centre des Matériaux de Grande Diffusion) υπό την επίβλεψη της καθηγήτριας A. Bergeret, στα πλαίσια ερευνητικής συνεργασίας του επιβλέποντα καθηγητή Γ. Παπανικολάου και της ερευνητικής του ομάδας. Τα πειράματα που διεξήχθησαν στο ερευνητικό ινστιτούτο CMGD, περιελάμβαναν αρχικά την προετοιμασία των κόκκων του ελαιοπυρήνα στην κατάλληλη μορφή για να είναι δυνατή η χρησιμοποίησή τους ως ενισχυτικό υλικό. Έγινε κονιορτοποίηση των κόκκων από την οποία προέκυψαν δύο τύπου σκονών που διέφεραν ως προς την διασπορά του μεγέθους των κόκκων, ενώ μια τρίτη σκόνη ελαιοπυρήνα είχε ήδη προετοιμαστεί με διαφορετική μέθοδο κονιορτοποίησης στο τμήμα Επιστήμης των Υλικών του Πανεπιστήμιου Πατρών. Έγινε εκτενής χαρακτηρισμός των φυσικών και μορφολογικών ιδιοτήτων όλων των σκονών ελαιοπυρήνα που χρησιμοποιήθηκαν για την κατασκευή των συνθέτων υλικών με μήτρα το PLA. Προσδιορίστηκαν διαφορετικού τύπου πυκνότητες και η διασπορά του μεγέθους των κόκκων. Έγινε θερμική ανάλυση με δοκιμή θερμοζυγού (TGA), μορφολογικός χαρακτηρισμός με χρήση ηλετρονικού μικροσκοπίου σάρωσης (SEM) καθώς και χαρακτηρισμός με φασματοσκοπία υπερύθρου με μετασχηματισμό Fourier (FT IR) και ακτίνων-Χ. Αφού ολοκληρώθηκε ο χαρακτηρισμός των ιδιοτήτων της ενισχυτικής φάσης, στη συνέχεια κατασκευάστηκαν σύνθετα υλικά μήτρας PLA ενισχυμένα με τους κόκκους ελαιοπυρήνα σε διαφορετικές περιεκτικότητες. Η προετοιμασία των σύνθετων αυτών υλικών πραγματοποιήθηκε σε δύο στάδια. Αρχικά έγινε μια πρώτη μορφοποίηση με εξώθηση (extrusion). Τα σύνθετα υλικά που προέκυψαν από την εξώθηση που ήταν στη μορφή δισκίων (pellets) χαρακτηρίστηκαν και αυτά με διάφορες τεχνικές (WAXD, DSC, TGA). Τα σύνθετα υλικά υπό μορφή δισκίων για να αποκτήσουν την τελική τους μορφή ως δοκίμια κατάλληλα για μηχανικές δοκιμές κατά τα πρότυπα ISO 527, μορφοποιήθηκαν με έγχυση (Injection molding). Τα σύνθετα υλικά στην τελική τους μορφή χαρακτηρίστηκαν με διάφορες τεχνικές (WAXD, DSC, TGA), έγινε χαρακτηρισμός των μηχανικών τους ιδιοτήτων και μορφολογική παρατήρηση των επιφανειών τους ύστερα από την μηχανική τους αστοχία (SEM). Τέλος, σε πολλά από τα σύνθετα υλικά που κατασκευάστηκαν και μελετήθηκαν πειραματικά, εφαρμόστηκαν διαφορετικά ημιεμπειρικά μοντέλα ανάλυσης και πρόβλεψης της μηχανικής τους συμπεριφοράς. Στο κυρίως κείμενο της διδακτορικής διατριβής, περιγράφεται σε ξεχωριστό κεφάλαιο το σύνολο των θεωρητικών μοντέλων που εφαρμόστηκαν στα πειραματικά αποτελέσματα. Στα επιμέρους κεφάλαια που παρουσιάζονται και αναλύονται τα πειραματικά αποτελέσματα, παρατίθενται η σύγκρισή τους με τις αντίστοιχες προβλέψεις που πρόεκυψαν από την εφαρμογή των θεωρητικών μοντέλων. Από τη σύγκριση αυτή παρατηρούμε ότι τα θεωρητικά μοντέλα που εφαρμόστηκαν που είναι το μοντέλο πρόβλεψης του μέτρου ελαστικότητας κοκκωδών υλικών, ΜPM (Modulus Predictive Model), το μοντέλο πρόβλεψης της υποβάθμισης ιδιοτήτων ύστερα από διαφορετικές είδους καταπονήσεις (θερμική κόπωση, κρούση χαμηλής ενέργειας και του ρυθμού παραμόρφωσης σε κάμψη τριών σημείων), RPM (Residual Properties Model) και το μοντέλο πρόβλεψης της υποβάθμισης της αντοχής των υλικών ύστερα από κρούση, Residual Strength after Impact Model (RSIM), έδωσαν ικανοποιητικές προβλέψεις για την μεταβολή των ιδιοτήτων κάνοντας χρήση ελάχιστων μόνο πειραματικών σημείων. Στην παρούσα διατριβή συνδυάστηκαν δύο διαφορετικού τύπου πολυμερικές ρητίνες με πληθώρα ενισχυτικών υλικών για την κατασκευή και μελέτη της μηχανικής τους συμπεριφοράς, τόσο πειραματικά όσο και θεωρητικά με την εφαρμογή ημιεμπειρικών μοντέλων πρόβλεψης και ανάλυσης. Για την κατασκευή των δοκιμίων, ανάλογα με τον τύπο του υλικού της μήτρας και της ενίσχυσης, εφαρμόστηκαν διαφορετικές τεχνικές και σύνθετες πειραματικές διαδικασίες. Ενώ, για την μελέτη των μηχανικών, θερμομηχανικών και μορφολογικών τους ιδιοτήτων εφαρμόστηκε σημαντικός αριθμός διαφορετικών τεχνικών χαρακτηρισμού.

Green composites

Biodegredable polymers

Epoxy resin

Polylactic acid (PLA)

Olive pits

Olive husks

Starch

CNT

Flax

Glass beads

Syntactic foam

Extrusion

Injection molding

Mechanical properties

TGA

DSC

XRD

DMA

FT-IR

Particulates

620.118

Βιοδιασπώμενα υλικά

Εποξεική ρητίνη

Πολυ-γαλακτικό οξύ

Κοκκώδη σύνθετα

Σκόνη ελαιοπυρήνα

Σκόνη αμύλου

Σφαιρίδια γυαλιού

Νανοσωλήνες άνθρακα

Μηχανικές ιδιότητες

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.

Návrh kompozitní objímky rotoru vysokootáčkového rotačního stroje / Design of the composite rotor sleeve of a high speed rotary machine

Pavlík, Ondřej

January 2018

The diploma thesis focuses on manufacturing carbon fiber and epoxy composite material using filament winding method. Material properties of manufactured composite are ap-proximated using analytical and numerical homogenization models. Calculated material properties are applied to design and evaluate reserve factor of retaining sleeve for high speed brushless permanent magnet synchronous motor. Margin of safety of designed rotor is evaluated using composite failure criteria. Test stand for both static and dynamic testing is designed, static test stand is manufactured and assembled. Static strength test is carried out.

Novel phosphorus containing poly(arylene ethers) as flame retardant additives and as reactant in organic synthesis

Satpathi, Hirak

08 June 2015

Due to their outstanding properties, poly(arylene ethers) are useful as toughness modifiers in epoxy resins (EP). Furthermore, these polymers show rather low intrinsic fire risks. According to recent research it has been incorporated that poly(arylene ether phosphine oxides) [PAEPO’s] can further improve the fire behavior. Increasing phosphorous content of the PAEPO can influence the fire behavior too. Fire retardants containing phosphorus – regardless of whether an additive or reactive approach is used – show different mechanisms in the condensed and gas phase. In the present study PSU Control (BPA based polysulfone) with four different PAEPO’s and their corresponding blends with an EP were investigated. All poly(arylene ether phosphine oxides) were synthesized by nucleophilic aromatic polycondensation. The polymers obtained covered a wide range of weight average molar masses (6,000 – 150,000 g/mol) as determined by size exclusion chromatography with multi-angle light scattering detection (MALLS). FTIR, NMR spectroscopy and MALDI-TOF revealed formation of the desired polymer structure of the linear poly(arylene ethers). All polymers were easily soluble in common organic solvents, thus enabling processing from solution.The pyrolysis and the fire retardancy mechanisms of the polymers and blends with epoxy resin (EP) were tackled by means of a comprehensive thermal analysis (thermogravimetry (TG), TG-evolved gas analysis) and fire tests [PCFC, limiting oxygen index (LOI), UL-94, cone calorimeter]. The Mitsunobu reaction of Dimethyl-5-hydroxyisophthalate and a long chain semifluorinated alcohol requires triphenyl phosphine as a reactant. Identical, in some case higher yield was obtained in the usual conditions, with triphenyl phosphine and with trivalent phosphorus containing polymers, which was prepared in solvent free bulk (melt) polymerization technique from trivalent phosphorus monomer and a silylated diphenol in presence of CsF. Purification and the recovery of the final product which is always a big challenge in case of Mitsunobu reaction, was far more easier using polymer compared to triphenyl phosphine. During polymerization there was a possibility to have polymer having repeating unit containing both trivalent phosphorus and phosphine oxide. The trivalent phosphorus content of the polymer can be varied using different molar concentration of CsF.

info:eu-repo/classification/ddc/540

ddc:540

Synthesis and Characterization of Strain Sensitive Multi-walled Carbon Nanotubes/Epoxy based Nanocomposites

Sanli, Abdulkadir

03 April 2018

Among various nanofillers, carbon nanotubes (CNTs) have attracted a significant attention due to their excellent physical properties. Incorporation of a very low amount of CNTs in polymer matrices enhances mechanical, thermal and optical properties of conductive polymer nanocomposites (CPNs) tremendously. For mechanical sensors, the piezoresistive property of CNTs/polymer nanocomposites exhibits a great potential for the realization of stable, sensitive, tunable and cost-effective strain sensors. Achieving homogeneous CNTs dispersion within the polymer matrices, understanding their complex piezoresistivity and conduction mechanisms, as well as the response of the nanocomposites under humidity and temperature effects, is highly required for the realization of piezoresistive CNTs/polymer based nanocomposites. This research primarily aims to synthesize and characterize CNTs/polymer based strain sensitive nanocomposites, which are cost-effective, applicable on both rigid and flexible substrates and require a non-complex fabrication process. A comprehensive understanding of the complex conduction and piezoresistive mechanisms of CNTs/polymer nanocomposites and their responses under humidity and temperature effects is another purpose of this thesis. For this purpose, synthesis and complex electromechanical characterization of multiwalled carbon nanotubes (MWCNTs)/epoxy nanocomposites are realized. In order to realize strain sensors for the strain range up to 1 % the use of epoxy is focused due to its good adhesion, dimensional stability, and good mechanical properties. The nanocomposites with up to 1 wt.% MWCNTs are synthesized by a non-complex direct mixing method and the final nanocomposites are deposited on flexible Kapton and rigid FR4 substrates and their corresponding morphological, electrical, electromechanical, as well as the response of the nanocomposite under humidity and temperature influences, are examined. The deformation over the sensor area is tested by digital image correlation (DIC) under quasi-static uniaxial tension. Quantitative piezoresistive characterization is performed by electrochemical impedance spectroscopy (EIS) over a wide range of frequencies. Further, dispersion quality of MWCNTs in the epoxy polymer matrix is monitored by scanning electron microscopy (SEM). Additionally, in order to tailor the piezoresistivity of the strain sensor, an R-C equivalent circuit is derived based on the impedance responses and the corresponding parameters are extracted from the applied strain. Obtained SEM images confirm that MWCNTs/epoxy nanocomposites with different MWCNTs concentrations have a good homogeneity and dispersion. Atomic force microscopy (AFM) analysis show that the samples have relatively good surface topography and fairly homogeneous CNTs networks. Higher sensitivity is achieved in particular at the concentrations close to the percolation threshold. A non-linear piezoresistive behavior is observed at low MWCNTs concentrations due to the dominance of tunneling effect. The strain sensitive nanocomposites deposited on FR4 substrates present high-performance strain sensing properties, including high sensitivity, good stability, and durability after cyclic loading and unloading. In addition, MWCNTs/epoxy nanocomposites show quite a small creep, low hysteresis under cyclic tensile and compressive loadings and fast response and recovery times. Nanocomposites provide an opportunity to measure 2-D strain in one position including amplitude and direction for complex configuration of structures in real-time systems or products. In contrast to present solutions for multi-directional strain sensing, MWCNTs/epoxy based nanocomposites give promising results in terms of durability, easy-processability, and tunable piezoresistivity. Unlike commercially-available approaches for crack/damage identification, MWCNTs/epoxy nanocomposites are capable of detecting the applied crack directly over a certain area. From the humidity influence, it has been found that resistance of nanocomposites increases with the increase of humidity exposure due to swelling of the polymer. Temperature investigations show that MWCNTs/epoxy nanocomposites give negative temperature coefficient (NTC) response due to thermal activation of charge carriers and the temperature sensitivity increases with the increase of filler concentration. The proposed approach can be further developed by combining differently fabricated sensors for realizing a compact structural health monitoring system or multi-functional sensor, where pressure, strain, temperature, and humidity can be monitored simultaneously. / Unter den verschiedenen Nanofillern haben CNTs aufgrund ihrer hervorragenden physikalischen Eigenschaften eine bedeutende Aufmerksamkeit erregt. Die Einarbeitung einer sehr geringen Menge an CNTs in Polymermatrizen verbessert die mechanischen, thermischen und optischen Eigenschaften von CPNs enorm. Für mechanische Sensoren bietet die piezoresistive Eigenschaft von CNTs/Polymer-Nanokompositen ein großes Potenzial zur Realisierung stabiler, empfindlicher, abstimmbarer und kostengünstiger Dehnungssensoren. Die Erzielung einer homogenen CNT-Dispersion innerhalb der Polymermatrizen, das Verständnis ihrer komplexen Piezoresistivitäts- und Leitungsmechanismen sowie die Reaktion der Nanokomposite unter Feuchte- und Temperatureinflüssen ist für die Realisierung piezoresistiver CNTs/Polymer-basierter Nanokomposite unerlässlich. Diese Arbeit zielt darauf ab, CNTs/polymerbasierte dehnungsempfindliche Nanokomposite herzustellen und zu charakterisieren. Diese Nanokompositen sollen kostengünstig, sowohl auf starren als auch auf flexiblen Substraten anwendbar sein und ein nicht komplexes Herstellungsverfahren erfordern. Ein umfassendes Verständnis der komplexen leitungs- und piezoresistive Mechanismen von CNTs/ Polymer-Nanokompositen und deren Reaktionen unter Feuchtigkeits- und Temperatureinflüssen ist ein weiteres Ziel dieser Arbeit. Zu diesem Zweck werden Synthese und komplexe elektromechanische Charakterisierung von MWCNTs/epoxy nanocomposites realisiert. Um Dehnungssensoren für den Dehnungsbereich bis zu 1 % realisieren zu können, wird der Einsatz von Epoxy aufgrund seiner guten Haftung, Dimensionsstabilität und guten mechanischen Eigenschaften fokussiert. Zufällig verteilte MWCNTs mit bis zu 1 wt.% MWCNTs-Konzentration ist durch ein direktes Mischen synthetisiert und die Nanokomposite werden auf flexiblen Kapton und starren FR4 Substraten durch Siebdruck appliziert und anschließend deren morphologische, elektrische, elektromechanische sowie die Reaktion des Nanocomposits unter Feuchtigkeits- und Temperatureinflüssen untersucht. Die Verformung über den Sensorbereich wird duch die Digital Image Correlation (DIC) Methode unter quasi-statischer uniaxialer Spannung getestet. Die quantitative piezoresistive Charakterisierung wird mit elektrische Impedanzspektroskopie (EIS) in einem breitem Frquenzspektrum durchgeführt. Ferner wird die Dispersionsqualität von MWCNTs in der Epoxidepolymermatrix durch Scanning Electron Microscopy (SEM) überprüft. Zusätzlich ist, um die Piezoresistivität des Dehnungssensors abzustimmen, eine RC-Äquivalenzschaltung auf der Grundlage der Impedanzantworten abgeleitet und die entsprechenden Parameter unter Belastung extrahiert. Erhaltene SEM-Bilder bestätigen, dass MWCNTs/Epoxide-Nanokomposite mit unterschiedlichen MWCNTs-Konzentrationen eine gute Homogenität und Dispersion aufweisen. Die atomic force microscopy (AFM) Untersuchung zeigt, dass die Proben relativ gute Oberflächentopographie und ziemlich homogene CNT-Netzwerke aufweisen. Eine höhere Empfindlichkeit wird insbesondere bei den Konzentrationen nahe der Perkolationsschwelle erreicht. Eine nichtlineare Piezoresistivität wird bei niedrigen MWCNTs Konzentrationen aufgrund der Dominanz des Tunnelwirkungseffekts beobachtet. Die auf FR4-Substraten applizierten dehnungsempfindlichen Nanokomposite weisen ausgezeichnete Dehnungsmessungseigenschaften einschließlich hohe Empfindlichkeit, gute Stabilität und Haltbarkeit nach zyklischer Be- und Entlastung auf. Darüber hinaus zeigen MWCNTs/Epoxide-Nanokomposite ein geringes Kriechen, eine kleine Hysterese unter zyklischen Zug- und Druckbelastungen, sowie schnelle Reaktionsund Wiederherstellungszeiten. Nanokomposite bieten die Möglichkeit, 2-D-Dehnungen in einer Position einschließlich Amplitude und Richtung innerhalb einer Materialstruktur in Echtzeitsystemen oder Produkten zu messen. Im Gegensatz zu aktuellen Lösungen für die multi-direktionale Dehnungsmessung, bieten die MWCNTs/Epoxide-Nanokomposite vielversprechende Ergebnisse in Bezug auf Langlebigkeit, leichte Verarbeitung und einstellbare Piezoresistivität. Im Unterschied zu kommerziell verfügbaren Ansätzen wird festgestellt, dassMWCNTs/Epoxide-Nanokomposite zur Riss-/Schadenserkennung in der Lage sind, den angelegten Riss direkt über einen bestimmten Bereich zu detektieren. Aus dem Einfluss der Feuchtigkeit hat sich herausgestellt, dass die Resistenz von Nanokompositen mit zunehmender Feuchtigkeitsbelastung durch Quellung des Polymers zunimmt. Temperaturuntersuchungen zeigen, dass MWCNTs/Epoxide-Nanokomposite aufgrund der thermischen Aktivierung von Ladungsträgern auf Temperatureinflüsse reagieren und die Temperaturempfindlichkeit mit der Erhöhung der Füllstoffkonzentration zunimmt. Der vorgeschlagene Ansatz kann durch die Kombination unterschiedlich hergestellte Sensoren zur Realisierung eines kompakten zur Überwachung des Zustands von Strukturen oder von multifunktionalen Sensoren weiterentwickelt werden, bei denen gleichzeitig Druck, Dehnung, Temperatur und Feuchtigkeit überwacht werden können.

info:eu-repo/classification/ddc/542

ddc:542

info:eu-repo/classification/ddc/600

ddc:600

Vývoj speciálních sanačních hmot na beton pro extrémní namáhání s využitím druhotných surovin / DEVELOPMENT OF SPECIAL REHABILITATION MATERIALS FOR CONCRETE FOR EXTREME STRESS WITH USE OF SECONDARY RAW MATERIALS

Hodul, Jakub

January 2019

The doctoral thesis deals with finding the use of some waste and secondary raw materials in the production of special polymer remediation materials for concrete, which could be applied even in constructions, where extreme mechanical and chemical load is occurred. The aim of this doctoral thesis is experimental examination of the possibility of using selected types of waste, including hazardous waste which represent the highest risk to environment, and secondary raw materials as a substitute for the currently used primary fillers in order to reduce the ecological footprint of the product itself. Some types of secondary raw materials, such as filter fly ash contaminated by flue gas denitrification process, are no longer used as a concrete admixture or partial cement substitution due to unwanted release of toxic ammonia (NH3). Mainly for this reason, the thesis deals with the progressive utilization of such types of secondary raw materials as well as with another currently unused waste into polymeric patching, grouting and anchoring materials while preserving or improving the final properties compared to reference materials using only primary raw materials. The result of this thesis is to find out suitable formulations for efficient preparation of special polymeric remediation materials for concrete containing waste and secondary raw materials as fillers. The partial aim of the thesis and a the scientific contribution is an observation of the developed materials internal structure using a modern device, CT tomography, an influence of the filler type on the long-term durability, and last but not least the observation of the rate of pollutants incorporation, found in hazardous waste, into the polymeric matric with the aid of EDX and FTIR analysis.