Modification chimique des extractibles de bois : application à la protection du bois et des matériaux métalliques / Chemical modification of wood extractives : Application to the protection of wood and metal materials

Sahmim, Wissem

20 December 2018

Dans ce cadre de cette thèse, nous nous intéressons à la conception, à la synthèse et à la caractérisation des propriétés physicochimiques de dérivés lipophiles d’extractibles du bois. Nous avons ainsi envisagé de modifier la structure de trois flavonoïdes dont la ressource est importante à partir de différentes essences de bois : la catéchine, le mesquitol et la naringénine pour incorporer des fonctionnalités supplémentaires. Les applications visées ici concernent principalement la protection des matériaux, en l’occurrence le bois et les métaux corrodables. En ce qui concerne la préservation du bois, il semble possible d’envisager différentes stratégies pour inhiber l’action de dégradation des champignons sur le bois. L’imprégnation des composés antioxydant tels que les polyphénols dans le bois, seuls ou en association avec un biocide pour agir en synergie, permet de limiter les effets des radicaux ou autres oxydants utilisés et générés par les pourritures, L’objectif de la modification structurale est ici d’augmenter leur hydrophobie pour limiter leur lessivage en cas d’utilisation du matériau en conditions extérieures. La deuxième application visée est la protection des matériaux métalliques. En effet, l’utilisation des produits antioxydants naturels comme inhibiteur de corrosion permet de substituer les inhibiteurs inorganiques ou les molécules organiques d’origine pétrochimique (polyamines, Imidazole…), car leur production est coûteuse et elles sont issues de ressources non renouvelables. Le greffage d’une chaîne hydrocarbonée hydrophobe sur des polyphénols ayant des propriétés antioxydantes permet d’obtenir un film protecteur sur le matériau / Within the framework of this thesis, we are interested in the design, synthesis and characterization of the physicochemical properties of lipophilic derivatives of wood extractives. We have thus considered modifying the structure of three flavonoids whose resource is important from different wood species: catechin, mesquitol and naringenin to incorporate additional functionalities. The applications reported here mainly deal with the protection of materials like wood and corrodible metals. With respect to wood preservation, it seems possible to consider different strategies to inhibit the wood degradation related to fungi on wood. Impregnation of antioxidant compounds such as lipophilic polyphenols on wood can limit the effects of radicals or other oxidants used and generated by rots. The second intended application is the protection of metallic materials. Indeed, the use of natural antioxidants as a corrosion inhibitor replace inorganic inhibitors or organic molecules (polyamines, imidazole...), because their production is expensive and toxic. The grafting of a hydrophobic hydrocarbon chain on polyphenols which have antioxidant properties allows the formation of protective films on the material

Extractibles du bois

Antioxydant

Dérivés lipophiles

Polyphénols

Métaux corrodables

Antioxydant

Catechin

Hydrophobic hydrocarbon chain

Wood extractives

Impregnation

Protection of materials

674.8

660.283 04

Quantitative methods to characterize the impregnation of a glass multifilament yarn by a cementitious matrix

Aljewifi, Hana, Fiorio, Bruno, Gallias, Jean-Louis

03 June 2009

This paper focuses on two experimental methods that give indicators linked to the impregnation level of the yarn / matrix interface, in the case of Textile Reinforced Concrete (TRC). These methods have been tested on three different glass yarns laid in a cementitious matrix, with three different impregnation levels resulting from the manufacturing process. The first method (comparative mercury intrusion porosity test) is based on the evaluation by mercury intrusion porosity of the pores volume associated to the porosity inside and near the yarn. The second method (flow test) consists in measuring the flow rate of water along the yarn, with imposed flow conditions. The physical parameters measured by these two methods are both related to the pore size and to the porosity of the yarn / matrix interface. The results of the two methods are discussed and drawn in parallel to a qualitative characterization of the yarn matrix interface made by scanning electron microscopy. As a result, the connection between the results of the two methods and the SEM characterization is studied. It is shown how these methods can participate to characterize the yarn impregnation. Limitations of the methods are also discussed.

info:eu-repo/classification/ddc/620

ddc:620

Étude pilote de l'impact sanitaire des émissions de la décharge de Mbeubeuss (Dakar, Sénégal) sur la population riveraine / Pilot study of the health impact of emissions from Mbeubeuss landfill (Dakar, Senegal), on the neighboring population

Cabral, Mathilde

06 December 2012

Cette enquête épidémiologique porte sur l'impact sanitaire de la décharge de Mbeubeuss, réceptacle de l'ensemble des déchets ménagers et industriels de Dakar (Sénégal), sur la population résidant à proximité. Les déchets, stockés sans être recouverts, sont source de pollution atmosphérique et des sols, notamment par le plomb et le cadmium. Les répercussions sanitaires sont d'autant plus préoccupantes que de nombreux riverains de cette décharge sont directement ou indirectement exposés. L'objectif de cette étude était de déterminer, après caractérisation chimique des échantillons de sol et de particules atmosphériques, l'imprégnation de la population (enfants et adultes) à ces deux métaux et de rechercher leur éventuel impact sur la fonction rénale. Nos résultats ont mis en évidence des teneurs atmosphériques et telluriques en plomb et en cadmium plus élevées sur le site de la décharge (teneurs 20 à 80 fois plus élevées que celles de la zone témoin). L'imprégnation saturnine, déterminée au travers des plombémies, plomburies et des marqueurs biologiques d'effet (PPZ, AlaU), de même que les teneurs sanguines et urinaires en cadmium étaient significativement plus importantes chez les individus résidant au voisinage de la décharge. La production excessive d'espèces réactives de l'oxygène induite par cette imprégnation s'est traduit par une diminution du système de défenses antioxydantes (SOD, GPx, Sélénium, GSH) et une peroxydation lipidique (MDA) accrue chez les sujets exposés. En outre, les variations de certains des marqueurs sensibles et spécifiques de néphrotoxicité (concentrations urinaires élevées en protéines totales, en RBP et en CC16 ; et augmentation des activités GSTα et LDH) suggèrent l'apparition de signes discrets et précoces d'altération de la fonction rénale chez les individus résidant à proximité de la décharge. L'exposition aux émissions de la décharge de Mbeubeuss constitue donc une véritable source de risques pour l'environnement et la santé des populations environnantes. Cette étude pourrait sans doute contribuer à conscientiser les acteurs de la santé sur les risques liés à cette décharge et à placer ces problèmes environnementaux, qui constituent un nouveau défi pour les pays pauvres, au cœur des futurs programmes de développement. / This case-control study dealt with adverse health effects on the population living near Mbeubeuss landfill in Dakar (Senegal). All household and industrial waste arising from Dakar are stored in this open landfill without being covered and are therefore possible sources of air pollution and soil contamination by heavy metals, especially Pb and Cd. Health impacts are of particular concern since many of the neighboring residents of this discharge are directly or indirectly exposed. The objective of this study was to determine Pb and Cd concentrations in both environment and humans, and to evaluate possible renal function alteration within the adult and child populations. Our results showed that lead and cadmium concentrations of soils and atmosphere were higher in the landfill (20 to 80 times) than those of the control area. The lead impregnation, evaluated through the blood and urine lead levals, and the biomarkers of exposure (PPZ, ALAU) as well as blood and urine cadmiums levels, were significantly higher in the subjects neighboring the landfill. Excessive production of reactive oxygen species induced by the metal impregnation conducted in exposed subjects to a decrease in antioxidant defense system (SOD, GPx, Selenium, GSH) and an increase in lipid peroxidation (MDA). Moreover, changes in several sensitive and specific markers of nephrotoxicity (high urinary concentrations of total protein, RBP and CC16, as well as GSTα and increased activities) suggested the occurence of discrete and early signs of impaired renal function for the landfill neighboring population. Exposure to emissions from the Mbeubeuss landfill is therefore a source of risk for the environment and the health of people who live and/or work within it. This study could undoubtedly help to raise awareness of landfill-related health risks amoung stakeholders, and to place these environmental problems, wich constitute a new challenge for poor countries, at the heart of future development programs.

Impact sanitaire

Imprégnation au Pb et au Cd

Stress oxydant

Néphrotoxicité

Décharge de Mbeubeuss

Health impact

Impregnation with Pb and Cd

Oxidative stress

Nephrotoxicity

Discharge of Mbeubeuss

Improvement of Oil Palm Wood Properties Using Bioresin

Erwinsyah, Erwinsyah

05 May 2008

Die ausWestafrika stammende Ölpalme (Elaeis guineensis Jacq) ist zur populärsten Kulturpflanze in Südostasien geworden. Als Haupterzeugnisse dieser Pflanze gelten die Öle der Früchte und der Fruchtkerne. Die weltweite Nachfrage nach diesen beiden Haupterzeugnissen nimmt sehr rasch zu. Ursache hierfür ist die breite Anwendungspalette dieser Pflanzenöle, wie z.B. Bratöl, ölbasierte Chemikalien und ölbasierte Nahrungsmittel, Kosmetika, Waschmittel, Biobrennstoff usw. Indonesien und Malaysia sind die Hauptproduzenten und Hauptlieferanten solcher Produkte und decken über 85% des weltweiten Bedarfs. Mit Extensivierung der Ölpalmplantagen sehen sich die Erzeugerländer zunehmend mit ernstzunehmenden Umweltprobleme konfrontiert, da nach Erreichen der wirtschaftlichen Lebenspanne (Umtriebszeit) von 25 Jahren große Mengen an festen, biologischen Abfallstoffe bei der Neubegründung der Bestände anfallen. So sollen z.B. im Jahre 2010 laut Vorhersagen mehr als 20 Mill. Kubikmeter Ölpalmen- Holz jährlich anfallen... / Oil palm (Elaeis guineensis Jacq) becomes the most popular crop, especially in Southeast Asia, than its origin,West Africa. World demand of two main products from this crop (e.g. crude palm oil and palm kernel oil) increases very rapidly, due to very wide ranges use of these vegetable oils for industrial purposes, such as fried oil, oleo-chemical and -food, cosmetics, detergent, biofuel and etc. Indonesia and Malaysia are the main producers and supplying more than 85% of world consumption. On the other hand, due to the economic life span of this popular crop (25 years), the producer countries have been facing a serious environmental problems concerning to the solid biowaste handling of oil palm industry, particularly the oil palm trunk after replanting activity. Starting 2010, it is predicted that more than 20 millions cubic meter biomass from oil palm trunk available annually...

info:eu-repo/classification/ddc/580

ddc:580

An Investigation Into the SiO2 Impregnation of Spruce Wood Under Vacuum Conditions for Engineering Applications

Lemaire-Paul, Mathieu

27 October 2022

Wood is a widely used construction material that has many advantageous properties, and some drawbacks. These drawbacks are mainly associated with the porous vascular structure of wood that makes it a high water-absorbent material. In addition, wood’s properties alter substantially with respect to the moisture content. Amongst the treatment techniques that limit the water uptake capacity of wood, vacuum-aided impregnation has exhibited promising results. However, little research has explored the effect of key parameters (such as the vacuum pressure) on the effectiveness of the impregnation. This study aims to optimize the performance of SiO2 impregnation of spruce wood under vacuum pressures. The main objective of this research is to overcome wood’s weakness by reducing its water uptake capacity through a vacuum-aided impregnation technique and study its effect on the physico-mechanical properties of wood under dry and saturated conditions. The study was conducted in two parts. In the first part, wood samples underwent impregnation under atmospheric and three vacuum pressures. Density measurements, water uptake tests, microscopy examination, thermogravimetric analysis, and dynamic mechanical analysis were conducted on non-treated and SiO2-treated samples. Quantitative and qualitative analyses demonstrated that SiO2 impregnation performed under -90 kPa was able to effectively enhance the wood’s properties compared to the other conditions. The SiO2 impregnation under high vacuum pressure demonstrated an effective increase in the density of the wood and achieved a significant reduction in the water uptake capacity. The analysis of the wood’s viscoelastic properties revealed that SiO2 impregnation under atmospheric and vacuum conditions triggered two different reinforcing mechanisms: a solid film, causing stick-slip oscillation, and particle diffusion, causing particle-particle and particle-lumen wall friction, respectively. For the second part, characterization methods such as Impact test, DMA, SEM, EDS, Porosity, and SAXS tests were conducted on non-treated and -90 kPa treated spruce wood samples in dry, saturated, and submerged states in order to reveal the synergistic effect of the SiO2 impregnation pressure and water uptake on the wood’s properties. The results showed that high vacuum impregnation pressure has a significant positive reinforcing effect on the wood’s properties. It increased the impact resistance of wood in dry and saturated conditions. A high vacuum impregnation was able to overcome the softening effect of water and caused a significant increase in the Storage modulus by strengthening the wood’s vascular structure, which accordingly increased the wood’s capacity to absorb energy. High vacuum impregnation was also able to counteract the plasticizing effect of water and significantly increased the Loss modulus by increasing the internal friction in the wood with the diffusion of the nanoparticles in the wood’s cell walls and vascular structure. This phenomenon increased the wood's capacity to absorb and dissipate energy under dry and submerged conditions.

Spruce Wood

SiO2 Nanoparticles

Vacuum-Aided Impregnation

Dynamic Mechanical Analysis

Water Uptake

Sustainability

Wood Fibers

Synergistic Effect

Submerged Viscoelastic Properties

Impact Properties

SEM

Electrochemical Characterisation of LiFePO4-Coated Carbon Fibres: A Comparative Electrochemical Analysis of Three Coating Methods / Elektrokemisk karakterisering av LiFePO4-belagda kolfibrer: en jämförande elektrokemisk analys av tre beläggningsmetoder

Szecsödy, Julia

January 2023

Kolfiber CF kan användas som positiv elektrod i strukturella batterier om de beläggs med ett aktivt material, såsom litiumjärnfosfat LFP. Fördelen med att använda kolfibrer som elektroder är att de samtidigt kan bära mekanisk belastning och lagra elektrisk energi. Det finns flera tekniker för att belägga kolfibrerna. I denna rapport kommer en jämförelse att göras av fibrer som belagts med elektroforetisk deponering, sprutbeläggning och pulverimpregnering. Elektrokemisk karakterisering kommer att avgöra och utvärdera prestandan hos dessa tre tekniker. Cellerna som monterades med sprutbeläggda och pulverimpregnerade prover visade de högsta kapaciteterna, 141 mAh/g vid C/10 respektive 139 mAh/g vid C/14. Vidare testning utfördes på de pulverimpregnerade proverna för att studera elektriska egenskaper och beteende, såsom elektrokemisk impedansspektroskopi EIS, cyklisk voltammetri CV och långtids-cykling. Svepelektronmikroskop SEM analys genomfördes för att observera ytmorfologin och förstå hur de elektrokemiska testerna kan påverka fibrernas yta. / Carbon Fibres (CF) can be used as the positive electrode in structural batteries if they are coated with an active material such as Lithium Iron Phosphate Oxide (LFP). The advantage of using carbon fibres as electrodes is that they simultaneously can carry the mechanical load and store electrical energy. There are several techniques to coat the carbon fibres. In this report, a comparison will be made on fibres coated using electrophoretic deposition, spray coating and powder impregnation. Electrochemical characterisation will determine and evaluate the performance of these three techniques. Cells assembled with spray-coated and powder-impregnated samples delivered the highest capacities, 141 mAh/g at C/10 and 139 mAh/g at C/14, respectively. Further testing was conducted on the powder-impregnated samples to study the electrical properties and behaviour, such as Electrochemical Impedance Spectroscopy (EIS), Cyclic Voltammetry (CV) and long-term cycling. Scanning Electron Microscopy (SEM) analysis was performed to see the surface morphology and understand how electrochemical testing can affect the surface of the fibres.

Structural battery composite

Carbon fibres

Lithium-ion battery

Electrophoretic deposition

Spray coating

Powder impregnation

Strukturella batteri kompositer

Kolfiber

Litiumjon batteri

Elektroforetisk beläggning

Sprutbeläggning

Pulverimpregnering

Chemical Engineering

Kemiteknik

Effects of Accelerated Aging on SiO₂-Treated Wood Samples

Beuthe, Callisto Ariadne

18 December 2023

Wood is a viscoelastic composite material that has been historically prominent in the construction of buildings and continues to see widespread use. When used for exterior applications, wood is exposed to dynamic environmental conditions and can degrade if left untreated. Previous research by Lemaire-Paul et al. (2022) has proven that vacuum impregnation of the wood cell structure with a silica (SiO₂) nanoparticle colloid under a vacuum pressure of -90 kPa can enhance the viscoelastic properties, increase the density, and reduce the water uptake of white spruce wood. However, the behaviour of SiO₂-treated wood under different environmental conditions over time has yet to be fully explored. This research aims to examine the durability and performance of SiO₂-treated spruce wood samples subjected to accelerated aging conditions under high temperature and humidity as well as freeze-thaw cycling. Spruce wood samples were treated with 40% SiO₂ nanoparticle colloid under a vacuum pressure of -90 kPa. One set was placed in a hydrolytic aging chamber at 90°C and 80% RH. Another set was placed in a freeze-thaw cycling chamber that cycled from 25°C to -18°C and back at a rate of 6 cycles per day. The samples were removed at regular intervals and thermogravimetric analysis, dynamic mechanical analysis, tensiometry, X-Ray diffraction, and scanning electron microscopy were performed. When compared to the results obtained from a set of non-treated samples, it was found that the SiO₂-treated samples exhibited lower water uptake values that stabilized over time, as well as a lower rate of decrease in peak cellulose degradation temperatures under hydrolytic aging and a slight increase in peak cellulose degradation temperature over time under freeze-thaw aging. The effects of both aging conditions on the viscoelastic properties of the samples were also found to be insignificant. Both types of samples under both types of aging also exhibited an increase in crystallinity over time. These results indicate that the durability and properties of wood can be improved through nano-SiO₂ impregnation as the material remains relatively stable when subjected to high temperature and humidity conditions as well as freeze-thaw cycling over time.

Spruce wood

Wood fibers

Accelerated aging

Hydrolytic aging

Freeze-thaw aging

Silica nanoparticles

Vacuum impregnation

Viscoelastic properties

Water uptake

Thermal degradation

Scanning electron microscopy

X-ray diffraction

Mineral-impregnated carbon fiber (MCF) reinforcements based on geopolymer

Zhao, Jitong

29 February 2024

Carbon concrete composites (C³) hold promise as a material class for constructing lightweight, durable, and sustainable structures. State-of-the-art carbon fiber-reinforced polymer (CFRP) reinforcement comprises infinite multifilament bundles embedded in a polymeric matrix, en-suring adequate load transfer and process robustness, yet it undergoes considerable degrada-tion under elevated temperatures or harsh service conditions. Instead, the success of mineral-impregnated carbon fibers (MCFs) stems from their structural flexibility, inherent heat re-sistance, and outstanding compatibility with cementitious substrates. Geopolymers (GPs) have recently emerged as a viable coating alternative due to a unique combination of many advantages, e.g., sustainability, source diversity, long early-age processing time, synthesis by controlled low-temperature activation and a wide range of temperature resistance. This work aims to develop and test fast-setting MCF composites and associated processing technologies, which hold significant importance for industrial applications and structural fire safety. As a result of the novelty of mineral impregnation technology, challenges regarding the process chain and mixture must be mastered to explore the full material potential before the technology is translated to key markets. The introductory chapter offers a comprehensive review of fiber-reinforced geopolymer (FRG) systems in response to temperature influences. The concept development is grounded in a systematic investigation of several interrelated, critical processing aspects of GP impregnation, focusing on processing quality and strength evolution. This investigation is conducted alongside an automated and continuous impregna-tion technology. Findings from numerous experiments revealed that targeted thermal curing profoundly influ-enced the mechanical properties and microstructure of the GP matrices and resulting MCFs. Hereby, rapid setting and high early-age strength of MCF, comparable to conventional CFRPs, were achieved within the first several hours of heat curing. The ability of aluminosili-cate particles to penetrate a dense fiber bundle was studied by applying fly ash (FA) with a systematically varied particle size distribution. Thereby, the max. particle size close to the same range of diameter of individual filament proved to be the most efficient, improving both the mechanical performance of MCF and its bond to concrete. Furthermore, an experimental campaign on the role of fiber sizing agents in processing quality and final composite perfor-mance was conducted. The respective impregnation quality and quantity were comprehen-sively explained by varied yarn spreading behavior and wettability, resulting in apparent dif-ferences in filament-matrix morphology and mechanical performance of MCF. To achieve high shape stability, packing density, and tailor-bond characteristics, the effect of surface pro-filing and prototypical winding technology on MCF was investigated. Finally, the bond quality of the MCF was validated through yarn pull-out tests in GP concrete at elevated temperatures and compared with available CFRP. These tests generated parame-ters related to bond behavior, which were then used to construct a three-dimensional numeri-cal model. Based on proper parametric calibrations, good agreement between numerical and experimental characterizations was achieved to predict the material's performance for future applications.:1 Introduction 1 1.1 Motivation 1 1.2 Objectives of the thesis 5 1.3 Thesis structure 7 2 Publications 11 2.1 A review of the role of elevated temperatures on the mechanical properties of fiber-reinforced geopolymer (FRG) composites 12 2.2 Development and testing of fast curing, mineral-impregnated carbon fiber (MCF) reinforcements based on metakaolin-made geopolymers 37 2.3 Mineral-impregnated carbon-fiber (MCF) composites made with differently sized fly-ash geopolymers for durable light weight and high temperature applications. 50 2.4 Role of sizing agent on the microstructure morphology and mechanical properties of mineral-impregnated carbon-fiber (MCF) reinforcement made with geopolymers 66 2.5 Effect of surface profiling on the mechanical properties and bond behaviour of mineral-impregnated, carbon-fibre (MCF) reinforcement based on geopolymer 80 2.6 Temperature-dependent pull-out behavior of geopolymer concrete reinforced with polymer- or mineral-impregnated carbon fiber composites: an experimental and numerical study. 94 3 Summary and Outlook 108 3.1 Summary of the research work 108 3.2 Outlook 113 References 119 Appendix A IV Appendix B VI / Der Verbundwerkstoff Carbonbeton ist eine vielversprechende Materialklasse für den Bau von leichtgewichtigen, langlebigen und nachhaltigen Strukturen. Hochmoderne Bewehrungen aus Carbonfaser-verstärkte Kunststoffen (CFK) werden durch die Imprägnierung von Endlos-faserbündeln mit einer Polymermatrix hergestellt, was ausreichende Lastübertragungskapazi-tät und Prozessrobustheit gewährleistet, und jedoch durch hohe Temperaturen oder raue Um-gebungen erheblich zerstört wird. Stattdessen resultiert der Erfolg mineralimprägnierter Car-bonfasern (MCFs) aus ihrer strukturellen Flexibilität, inhärenten Wärmebeständigkeit und hervorragenden Kompatibilität mit zementären Substraten. Geopolymere (GPs) haben sich kürzlich als praktikable Beschichtungsalternative herausgestellt, aufgrund einer einzigartigen Kombination vieler Vorteile, wie Nachhaltigkeit, Quellenvielfalt, ausreichendes Verarbei-tungsfenster, Synthese durch kontrollierte thermische Aktivierung bei niedrigen Temperatu-ren und Hitzebeständigkeit. Die vorliegende Arbeit zielt auf die Entwicklung und Erprobung schnell abbindender MCF-Verbundwerkstoffe und zugehöriger Verarbeitungstechnologien ab, was für industrielle An-wendungen und den baulichen Brandschutz von großer Bedeutung ist. Aufgrund der Neuar-tigkeit der mineralischen Imprägnierungstechnologie müssen Herausforderungen in Bezug auf die Prozesskette und Mischung gemeistert werden, um das volle Materialpotenzial zu erkunden, bevor die Technologie auf Schlüsselmärkte übertragen wird. Dementsprechend gibt das einleitende Kapitel einen umfassenden Überblick über faserverstärkte Geopolymer (FRG)-Systeme unter Temperatureinwirkung. Das Entwicklungskonzept baut auf einer sy-stematischen Untersuchung mehrerer zusammenhängender, wichtiger Verarbeitungsaspekte der GP-Imprägnierung in Bezug auf Verarbeitungsqualität und Festigkeitsentwicklung von der Mikro- bis zur Makroskala und in Verbindung mit einer automatisierten und kontinuierli-chen Fertigungstechnologie auf. Ergebnisse zahlreicher Experimente zeigten, dass gezielte Wärmehärtung die mechanischen Eigenschaften und Mikrostruktur der GP-Matrizen und resultierenden MCFs nachhaltig be-einflußt. Hierdurch wurde eine schnelle Aushärtung und hohe Festigkeit von MCF innerhalb der ersten Stunden der Wärmebehandlung erreicht, und zwar vergleichbar mit konventionel-len CFRPs. Die Eindringfähigkeit von Aluminosilikatpartikeln in ein dichtes Faserbündel wurde durch die Anwendung von Flugasche (FA) mit systematisch variierter Partikelgrößen-verteilung untersucht. Dabei erwies sich die maximale Partikelgröße, die nahe dem Durch-messer einzelner Filamente liegt, als am effizientesten. Sie verbesserte sowohl die mechani-sche Leistung von MCF als auch seine Bindung an Beton. Darüber hinaus wurde eine expe-rimentelle Kampagne zur Rolle der Faserschlichte auf die Verarbeitungsqualität und die end-gültige Verbundleistung durchgeführt. Die jeweilige Imprägnierungsqualität wurde umfas-send durch ein unterschiedliches Spreizungsverhalten und Benetzbarkeit des Garns erklärt, was zu deutlichen Unterschieden in der Filament-Matrix-Verteilung und mechanischen Ei-genschaften von MCF führte. Zur Verbesserung der Formstabilität, Packungsdichte und ge-zielten Abstimmung der Verbundeigenschaften im Beton wurde der Effekt der Oberflächen-profilierung und prototypischen Wickeltechnik auf MCF untersucht. Schließlich wurde die Verbundqualität der MCF durch den Garnauszugversuch in GP-Beton bei erhöhten Temperaturen validiert und mit einer verfügbaren CFK-Bewehrung verglichen. Diese Tests generierten auf das Verbundverhalten bezogene Parameter, die dann zur Formu-lierung eines dreidimensionalen numerischen Modells verwendet wurden. Durch angemesse-ne parametrische Kalibrierungen wurde eine gute Übereinstimmung zwischen numerischen und experimentellen Charakterisierungen erreicht, um die Leistung des Materials für zukünf-tige Anwendungen vorherzusagen.:1 Introduction 1 1.1 Motivation 1 1.2 Objectives of the thesis 5 1.3 Thesis structure 7 2 Publications 11 2.1 A review of the role of elevated temperatures on the mechanical properties of fiber-reinforced geopolymer (FRG) composites 12 2.2 Development and testing of fast curing, mineral-impregnated carbon fiber (MCF) reinforcements based on metakaolin-made geopolymers 37 2.3 Mineral-impregnated carbon-fiber (MCF) composites made with differently sized fly-ash geopolymers for durable light weight and high temperature applications. 50 2.4 Role of sizing agent on the microstructure morphology and mechanical properties of mineral-impregnated carbon-fiber (MCF) reinforcement made with geopolymers 66 2.5 Effect of surface profiling on the mechanical properties and bond behaviour of mineral-impregnated, carbon-fibre (MCF) reinforcement based on geopolymer 80 2.6 Temperature-dependent pull-out behavior of geopolymer concrete reinforced with polymer- or mineral-impregnated carbon fiber composites: an experimental and numerical study. 94 3 Summary and Outlook 108 3.1 Summary of the research work 108 3.2 Outlook 113 References 119 Appendix A IV Appendix B VI

info:eu-repo/classification/ddc/620

ddc:620

Development and testing of fast curing, mineral-impregnated carbon fiber (MCF) reinforcements based on metakaolin-made geopolymers

Zhao, Jitong, Liebscher, Marco, Michel, Albert, Junger, Dominik, Trindade, Ana Carolina Constâncio, Silva, Fláviode Andrade, Mechtcherine, Viktor

28 November 2022

Mineralisch getränkte Carbonfasern (MCF) stellen eine vielversprechende Alternative zu herkömmlichen Stahlbewehrung in Beton dar. Für eine effiziente industrielle Herstellung von MCF muss eine ausreichende Verarbeitungszeit für die Imprägniersuspension gewährleistet sein. In der vorliegenden Untersuchung wurde zu diesem Zweck ein aus Metakaolin hergestelltes Geopolymer (GP) entwickelt und getestet. Die Tränkung von Carbonfasergarnen wurde kontinuierlich und automatisiert durchgeführt. Anschließend wurden die MCF bei 75 °C wärmebehandelt, um die Reaktionsprozesse zu beschleunigen. Die mechanische Leistung von MCF nahm im Verlauf des Aushärtungsprozesses von 2 auf 8 Stunden allmählich zu, was auf das größere Ausmaß der Geopolymerisation zurückzuführen ist. Bei einer solchen verlängerten Aushärtung zeigten thermogravimetrische und mikroskopische Analysen zwar eine stärkere 'reagierte' Mikrostruktur, aber auch einen höheren Gehalt an Hohlräumen. Nach 8-stündigen Erhitzen erreichten die Zugfestigkeit und der Young-Modul von MCF 2960 MPa bzw. 259 GPa, bezogen auf die Garnquerschnittsfläche.:Abstract Schlagwörter 1. Einleitung 2. Experimentelles Programm 2.1. Materialien 2.2. Herstellung von MCF 2.3. Testen der Geopolymermatrix 2.4. Mechanische Prüfung von MCF 2.5. Morphologische Charakterisierung 3. Ergebnisse und Diskussion 3.1. Charakterisierung der Geopolymermatrix 3.2. Hergestellte MCF mit Geopolymer und Wärmebehandlung bei 75 °C. 3.3. Chemische und morphologische Analyse 4. Schlussfolgerung Erklärung des konkurrierenden Interesses Literaturen / Mineral-impregnated, carbon fiber composites (MCF) are a promising alternative to conventional concrete reinforcements. For the efficient industrial production of MCF, sufficient processing time for the impregnation suspension must be ensured. In the present investigation, a metakaolin-made geopolymer (GP) has been developed and tested for this purpose. The impregnation of carbon-fiber yarns was performed continuously and automated. Subsequently, the MCF were heat-treated at 75 °C to accelerate the reaction processes. The mechanical performance of MCF gradually increased in the advancement of the curing process from 2 to 8 h, which is attributed to the greater extent of geopolymerization. In such extended curing, thermogravimetric and microscopic analysis showed indeed a more “reacted” microstructure but also a higher content of voids. After heating for 8 h, the tensile strength and Young's modulus of MCF reached 2960 MPa and 259 GPa, respectively, when related to the yarn cross-sectional area.:Abstract Schlagwörter 1. Einleitung 2. Experimentelles Programm 2.1. Materialien 2.2. Herstellung von MCF 2.3. Testen der Geopolymermatrix 2.4. Mechanische Prüfung von MCF 2.5. Morphologische Charakterisierung 3. Ergebnisse und Diskussion 3.1. Charakterisierung der Geopolymermatrix 3.2. Hergestellte MCF mit Geopolymer und Wärmebehandlung bei 75 °C. 3.3. Chemische und morphologische Analyse 4. Schlussfolgerung Erklärung des konkurrierenden Interesses Literaturen

info:eu-repo/classification/ddc/690

ddc:690

The development of alternative cathodes for high temperature solid oxide electrolysis cells

Yue, Xiangling

January 2013

This study mainly explores the development of alternative cathode materials for the electrochemical reduction of CO₂ by high temperature solid oxide electrolysis cells (HTSOECs), which operate in the reverse manner of solid oxide fuel cells (SOFCs). The conventional Ni-yttria stabilized zirconia (YSZ) cermets cathode suffered from coke formation, whereas the perovskite-type (La, Sr)(Cr, Mn)O₃ (LSCM) oxide material displayed excellent carbon resistance. Initial CO₂ electrolysis performance tests from different cathode materials prepared by screen-printing showed that LSCM based cathode performed poorer than Ni-YSZ cermets, due to non-optimized microstructure. Efforts were made on microstructure modification of LSCM based cathodes by means of various fabrication methods. Among the LSCM/YSZ graded cathode, extra catalyst (including Pd, Ni, CeO₂, and Pt) aided LSCM/GDC (Gd₀.₁Ce₀.₉O₁.₉₅) cathode, LSCM impregnated YSZ cathode, and GDC impregnated LSCM cathode, the GDC impregnated LSCM cathode, with porous LSCM as backbone for finely dispersed GDC nanoparticles, was found to possess the desired microstructure for CO₂ splitting reaction via SOEC. Incorporating of 0.5wt% Pd into GDC impregnated LSCM cathode gave rise to an Rp of 0.24 Ω cm² at open circuit voltage (OCV) at 900°C in CO₂-CO 70-30 mixture, comparable with the Ni/YSZ cermet cathode operated in the identical conditions. Meanwhile, the cathode kinetics and possible mechanisms of the electrochemical reduction of CO₂ were studied, and factors including CO₂/CO composition, operation temperature and potential were taken into account. The current-to-chemical efficiency of CO₂ electrolysis was evaluated with gas chromatography (GC). The high performance Pd and GDC co-impregnated LSCM cathode was also applied for CO₂ electrolysis without protective CO gas in feed. This cathode also displayed superb performance towards CO₂ electrochemical reduction under SOEC operation condition in CO₂/N₂ mixtures, though it had OCV as low as 0.12V at 900°C. The LSCM/GDC set of SOEC cathode materials were investigated in the application of steam electrolysis and H₂O-CO₂ co-electrolysis as well. For the former, adequate supply of steam was essential to avoid the appearance of S-shaped I-V curves and limited steam transport. The 0.5wt% Pd and GDC co-infiltrated LSCM material has been found to be a versatile cathode with high performance and good durability in SOEC operations.

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