Global ETD Search

731	Μελέτη των συνθηκών ανοδίωσης για την παραγωγή μεμβρανών πορώδους αλουμίνας με ελεγχόμενα χαρακτηριστικά Χριστουλάκη, Αναστασία 06 November 2014 (has links) Στην παρούσα εργασία μελετάται πειραματικά η ανάπτυξη μεμβρανών πορώδους αλουμίνας με ελεγχόμενο πάχος, διάμετρο πόρου, σε ηλεκτρολύτη οξαλικού οξέος συγκεντρώσεως 0.3Μ με εφαρμοζόμενη τάση 40V και 50V. Για την κατανόηση του μηχανισμού της δημιουργίας των μεμβρανών πορώδους αλουμίνας γίνεται μια βιβλιογραφική παρουσίαση των μοντέλων ανάπτυξης της. Από τα πειράματα προκύπτει ότι ο ρυθμός ανάπτυξης του πάχους της μεμβράνης ακολουθεί τον νόμο του Faraday με απόδοση που εξαρτάται από την τάση ανοδίωσης. Τέλος υπολογίζεται η ενέργεια ενεργοποίησης για την αντίδραση του σχηματισμού της πορώδους αλουμίνας. Η ενέργεια ενεργοποίησης που αφορά την αντίδραση του αλουμινίου με τον ηλεκτρολύτη. / Ιn the present study, the synthesis of porous alumina membranes with controlled thickness and pore diameter is investigated. More specifically, the experimental condition under study was oxalic acid 0.3M under an applied voltage of 40V and 50V. In order to understand the growth mechanism of the porous alumina membrane formation, a bibliographic view of the growth models is presented. The experiments result in the conclusion that the thickness growth rate of the porous alumina membrane obeys the Faraday law for electrolysis with an efficiency being dependent on the anodization applied voltage. Finally, the activation energy for the porous alumina formation concerning the reaction of aluminum with the electrolyte, is calculated. Πορώδης αλουμίνα Ανοδίωση Απόδοση ρεύματος Αριθμός μεταφοράς 620.116 Porous alumina Anodization Thickness growth rate Activation energy Current efficiency Transport number
732	Simultaneous production of methanol and dimethylether from synthesis gas / Ταυτόχρονη παραγωγή μεθανόλης και διμεθυλαιθέρα από αέριο σύνθεσης Akarmazyan, Siranush 16 January 2015 (has links) Dimethylether is a non-toxic liquefied gas, which is projected to become one of the fundamental chemical feedstock in the future. Dimethylether can be produced from syngas via a two-step (indirect) process that involves synthesis of methanol by hydrogenation of CO/CO2 over a copper based catalyst and subsequent dehydration of methanol to DME over an acidic catalyst. Alternatively, DME can be produced in an one-step (direct) process using a hybrid (bifunctional) catalyst system that permits both methanol synthesis and dehydration in a single process unit. In the present research work the production of DME has been studied by applying both the indirect and direct processes. Firstly, the methanol synthesis and methanol dehydration reactions involved in the indirect process have been studied separately. Afterwards, these two reactions have been combined in the direct DME production process by using a hybrid catalyst comprising a methanol synthesis and a methanol dehydration component. The methanol synthesis by CO2 hydrogenation has been investigated over commercial and home-made CuO/ZnO/Al2O3 catalysts with the aim to identify optimal experimental conditions (CO2:H2 ratio, flow rate, temperature) that could be then used in the direct conversion of CO2/H2 mixtures into methanol/DME. Obtained results reveal that the conversion of CO2 and the yields of reaction products (CH3OH and CO) increase when the concentration of H2 in the feed and the reaction contact time are increased. It was found that both Cu+/Cu0 species are important for the conversion of CO2/H2, although the presence of Cuo seems to be more important for selectivity/yield of methanol. The stability of the CuO/ZnO/Al2O3 catalyst has been also investigated. It was observed that the main reason for the deactivation of catalyst is the water produced via the methanol synthesis and reverse water gas shift reactions. However, the catalytic activity and products selectivity were recovered slowly to their original levels after applying a regeneration procedure, indicating that deactivation by water is reversible. The dehydration of methanol to dimethylether (DME) has been investigated over a range of catalysts including alumina, silica-alumina and zeolites with different physicochemical characteristics. The effects of temperature and the presence of water vapour in the feed on catalytic performance have been studied in detail. The reactivity of catalysts has been evaluated by determining the reaction rates per gram of catalyst per acid site (total: Brönsted+Lewis) and per Brönsted/Lewis mole ratio. In addition, the reaction mechanism has been investigated over a selected catalyst, with the use of transient-MS and in situ DRIFTS techniques. Results obtained for alumina catalysts show that the catalytic activity and selectivity are determined to a large extent by the textural properties, degree of crystallinity and total amount of acid sites of catalysts. In particular, the methanol conversion curve shifts toward lower reaction temperatures with an increase of specific surface area. However, the enhanced catalytic activity of high-SSA samples cannot be attributed solely to the higher amount of surface acid sites, implying that the reaction rate is determined to a large extent from other parameters, such as textural properties and degree of crystallinity. Results of mechanistic studies indicate that interaction of methanol with the Al2O3 surface results in the formation of two kinds of methoxy groups of different adsorption strength. Evidence is provided that DME evolution is associated with methoxy species that are weakly adsorbed on the Al2O3 surface, whereas more strongly held species decompose to yield surface formate and, eventually, CH4 and CO in the gas phase. Results obtained over zeolite catalysts show that catalytic performance depends on the topology of zeolites due to differences in micropore structure and Si/Al ratio as well as on the number, strength and nature of active acid sites. The activity of zeolite catalysts for the methanol dehydration to DME follows the order ZSM-5 > Ferrierite > Mordenite ~ Beta ~ USY > H-Y. The strong Brönsted acid sites of ZSM-5 zeolites with relatively high Si/Al ratio represent the most active sites in methanol dehydration to DME reaction. However, the overall reactivity of the ZSM-5 zeolites is also affected by the balance of the Brönsted to Lewis acid sites. The activity of Beta and USY zeolites is determined by both Lewis and Brönsted acid sites. The moderate/low reactivity of Ferrierite, Mordenite and H-Y zeolite are determined by the abundant Brönsted acid sites of relatively weak/moderate strength. The direct CO2 hydrogenation to methanol/DME has been investigated using admixed catalysts comprising a methanol synthesis (commercial copper based catalyst: CZA1) and a methanol dehydration component (different alumia/zeolite catalysts: γ-Al2O3, ZSM-5, W/γ-Al2O3, USY(6), Ferrierite(10)). It has been revealed that the conversion of CO2 is always lower than the corresponding equilibrium values predicted by thermodynamics, indicating operation in the kinetic regime. The nature of the methanol dehydration component of the admixed catalysts was found to be important for both CO2 conversion and methanol dehydration. In particular, DME selectivity/yield, depends strongly on the nature of acid sites (both Lewis and Brönsted) as well as the textural (meso/macro porosity) and topological properties of methanol dehydration component of the admixed catalysts. The yield of DME obtained at a temperature of 250oC decreases following the order CZA1/ZSM-5, CZA1/USY(6) > CZA1/Ferrierite(10) > CZA1/ W/γ-Al2O3 >> CZA1/γ-Al2O3. The long-term stability experiments conducted over selected bifunctional catalytic systems revealed that the catalysts deactivate with time-on-stream, mainly due to water produced via methanol synthesis, methanol dehydration and reverse water gas shift reactions. In case of the CZA1/ZSM-5 admixed catalyst the catalytic activity and products selectivity were almost recovered after regeneration indicating that deactivation by water is reversible. / -- Carbon dioxide Dimethyl ether Methanol Alumina Zeolites Copper-based catalysts Bifunctional catalysts 662.669 2 Διοξείδιο του άνθρακα Μεθανόλη Οξείδιο του αργιλίου Ζεόλιθοι
733	Μελέτη διεπιφανειακών φαινομένων με την μέθοδο διέγερσης επιφανειακών πλασμονίων Κουτσιούμπας, Αλέξανδρος 26 June 2009 (has links) Αντικείμενο της παρούσας διδακτορικής διατριβής αποτελεί η ανάπτυξη της πειραματικής Μεθόδου Διέγερσης Επιφανειακών Πλασμονίων (Surface Plasmon Resoanance, SPR) για τη μελέτη διεπιφανειακών φαινομένων και ειδικότερα των ιδιοτήτων ισορροπίας και της κινητικής της προσρόφησης πολυμερών και ολιγομερών στη διεπιφάνεια υγρού / στερεού. Στα πλαίσια της διατριβής, κατασκευάσθηκε εξ’ αρχής πειραματική διάταξη συντονισμού επιφανειακών πλασμονίων, η οποία χρησιμοποιήθηκε για την μελέτη του φαινομένου της προσρόφησης. Παράλληλα αναπτύχθηκε θεωρητικό υπόδειγμα και υπολογιστικά εργαλεία ανάλυσης των πειραματικών μετρήσεων. Με τη χρήση της πειραματικής διάταξης μελετήθηκε η διαδικασία της προσρόφησης γραμμικών και αστεροειδών πολυμερών στη διεπιφάνεια υγρού / στερεού όπως επίσης και τασιενεργών ολιγομερών τα οποία σχηματίζουν Αυτό-οργανούμενα Μονομοριακά Στρώματα (Self Assembled Monolayers) σε επιφάνειες οξειδίου του αλουμινίου. Επιπλέον διερευνήθηκε η επίδραση της αρχιτεκτονικής των πολυμερικών αλυσίδων σε σχέση με την ικανότητά τους να αυτο-οργανώνονται σε στρώματα πολυμερικών ψηκτρών (polymer brushes). Τα πειραματικά αποτελέσματα συγκρίνονται με μετρήσεις οι οποίες έγιναν με τη μέθοδο ανάκλασης νετρονίων. Για την κατανόηση των μικροσκοπικών μηχανισμών που υπεισέρχονται κατά την αυτό-οργάνωση των πολυμερών, γίνεται χρήση θεωρητικών υποδειγμάτων κλίμακας και υπολογιστικών προσομοιώσεων Monte Carlo. Περαιτέρω, μέσω της χρήσης λεπτών στρωμάτων νανο-πορώδους αλουμίνας, προτείνεται μια νέα παραλλαγή της μεθόδου διέγερσης επιφανειακών πλασμονίων η οποία όπως αποδεικνύεται, αυξάνει την ευαισθησία της μεθόδου κατά μια τάξη μεγέθους, στην περίπτωση της ανίχνευσης της προσρόφησης ολιγομερών. Η διατριβή παρουσιάζει ολοκληρωμένα τη χρήση της μεθόδου διέγερσης επιφανειακών πλασμονίων για την αναλυτική μελέτη της προσρόφησης μορίων σε επιφάνειες. Η επέκταση της μεθόδου με τη χρήση νανο-δομημένων υλικών ανοίγει τον δρόμο για πλειάδα νέων εφαρμογών στο πεδίο της ανίχνευσης προσροφημένων μορίων από διαλύματα ιδιαίτερα χαμηλών συγκεντρώσεων. / The objective of the present PhD thesis is the development of the experimental Surface Plasmon Resonance (SPR) method, for the study of interfacial phenomena such as the equilibrium properties and kinetics of polymer and oligomer adsorption at the liquid / solid interface. For the purposes of this work a custom-made experimental apparatus has been build and used for the acquisition of SPR experimental results. A theoretical model and various computational tools were also developed for the analysis of the experimental data. With the aid of this apparatus, the adsorption process of linear and star-like polymers at the liquid / solid interface was studied together with the self-assembly of functional oligomer monolayers on alumina surfaces. In addition, the effect of different chain structure (molecular architecture) on the formation of polymer brush layers was investigated. The experimental results are compared with measurements by neutron reflectivity experiments. For the investigation of the microscopic mechanisms that are involved in the polymer self-assembly, scaling theoretical calculations and Monte Carlo computer simulations were performed. Furthermore, by the use of thin nano-porous alumina films, a new variation of the SPR method is proposed. It is demonstrated, that this improved method is characterized by over one order of magnitude higher sensitivity in the case of the detection of adsorbed oligomers. The present thesis describes in detail the use of the SPR method for the analytical study of molecular adsorption on surfaces. The improvement of the SPR technique by the use of nano-structured materials opens new prospects for many new applications in the field of molecular detection in very dilute solutions. Προσρόφηση Πολυμερή Πολυμερικές ψήκτρες Προσομοίωση Πορώδης αλουμίνα Οπτικός ανιχνευτής Αστεροειδή πολυμερή 541.335 Surface plasmons Adsorption Polymers Polymer brushes Simulation Porous alumina Optical sensor Star polymers
734	Design, improvement, and testing of a thermal-electrical analysis application of a multiple beta-tube AMTEC converter Pavlenko, Ilia V. 30 September 2004 (has links) A new design AMTEC converter model was developed, and its effectiveness as a design tool was evaluated. To develop the model, requirements of the model were defined, several new design models were successively developed, and finally an optimal new design model was developed. The model was created within Sinda/Fluint, with its graphical interface, Thermal Desktop, a software package that can be used to conduct complex thermal and fluid analyses. Performance predictions were then correlated and compared with actual performance data from the Road Runner II AMTEC converter. Predicted performance results were within 10% of actual performance data for all operating conditions analyzed. This accuracy tended to increase within operating ranges that would be more likely encountered in AMTEC applications. Performance predictions and parametric design studies were then performed on a proposed new design converter model with a variety of annular condenser heights and with potassium as a working fluid to evaluate the effects of various design modifications. Results clearly indicated the effects of the converter design modifications on the converter's power and efficiency, thus simplifying the design optimization process. With the close correlation to actual data and the design information obtained from parametric studies, it was determined that the model could serve as an effective tool for the design of AMTEC converters. AMTEC BASE Beta-Alumina Solid Electrolyte AMTEC converter AMTEC converter application AMTEC converter simulation AMTEC thermal-electrical analysis
735	Directing macromolecular assemblies by tailored surface functionalizations of nanoporous alumina Lazzara, Thomas Dominic 16 May 2011 (has links) No description available. 000 Allgemeines Wissenschaft Chemistry nanopores optical waveguide spectroscopy surface chemistry silanes layer-by-layer lipid membranes pore-spanning membranes macromolecules alumina 35.00
736	Electrical Insulating Properties of Poly(Ethylene-co-Butyl Acrylate) Filled with Alumina Nanoparticles Jäverberg, Nadejda January 2013 (has links) In this work the electrical insulating properties of the nanocomposite materials based on poly(ethylene-co-butyl acrylate) filled with alumina nanoparticles are studied. The dielectric properties chosen for the evaluation are the dielectric permittivity and loss as well as the breakdown strength and the pre-breakdown currents. The reason for choosing these particular properties is partly due to the importance of these for the general electrical applications and partly due to the uncertainties involved for these particular properties of the nanocomposite materials. The importance of moisture absorption for the dielectric properties is outlined in this work. All measurements were performed in both dry conditions and after conditioning of the materials in humid environment until saturation. The data for moisture absorption was taken from the water absorption study performed at the Department of Fibre and Polymer Technology, KTH. The dielectric spectroscopy in frequency domain was employed for measuring dielectric permittivity and loss. Havriliak-Negami approximation was used for characterization of the measurement data and at the same time ensuring the fulfillment of the Kramers-Kronig relations. Results from the dielectric spectroscopy study in dry conditions suggest that dielectric spectroscopy can be used for evaluating nanoparticle dispersion in the host matrix, based on correlation between the morphology data obtained from SEM investigation and the scatter in the dielectric loss. The dielectric spectroscopy study performed on the nanocomposites after conditioning in humid environment showed that absorbed moisture has a distinct impact on the dielectric loss. Especially pronounced is its’ influence on the frequency behavior, when the dielectric loss peaks are shifted towards higher frequencies with increased moisture content. The nanocomposite materials characterized by higher specific surface area generally exhibit higher dielectric losses. Surface functionalization of the nanoparticles does not seem to have much influence on the dielectric loss in dry conditions. After conditioning in humid environment, however, the surface modification was shown to have a significant impact. Temperature is another significant factor for the frequency behavior of the dielectric loss: it was found that the studied nanocomposites can be characterized by Arrhenius activation. The breakdown strength and pre-breakdown currents study outlined the influence of moisture as well. The study indicated that surface treatment of the nanoparticles can enhance properties of the nanocomposite materials, namely aminopropyltriethoxy silane was an especially successful choice: • The highest breakdown strength was determined by the study for NDA6 material formulation in dry conditions. • After conditioning in humid environment the NDA6 material continued showing the best breakdown strength among the nanocomposite mate rials, as well as this value was close to the breakdown strength of the reference unfilled material. This study confirms the existence of the optimal nanofiller content or rather optimal specific surface area of the dispersed nanoparticles in the host matrix. The latter is supported by the comparison between the nanocomposites based on nanoparticles with two different specific surface areas, which shows that the dielectric properties worsen, i.e. the dielectric losses increase and the influence of absorbed moisture on the breakdown strength becomes more pronounced, for nanomaterials with larger specific surface area. The pre-breakdown currents were found to follow space-charge limited conduction mechanism reasonably well. The following conduction regimes were identified: constant region (likely due to measurement difficulties at low field strengths), Ohm’s regime, trap-filled-limit regime and trapfree dielectric regime. The breakdown usually occurred either during the trap-filled-limit regime, when the current increased dramatically for the small change in electric field, or during the trapfree dielectric regime. The threshold values between different conduction regimes seem to correlate well with the oxidation induction times (OIT), which in turn depend on the total specific surface area. The pre-breakdown currents tend to be highest for the materials filled with the untreated nanoparticles. Increased absorbed moisture content causes higher pre-breakdown currents for the nanocomposite materials, while for the reference unfilled material the pre-breakdown currents do not show such tendency. Generally it can be said that the repeatability in the measured data is higher for the nanocomposite materials in comparison to the unfilled host material, as was demonstrated by both dielectric spectroscopy and breakdown studies. / <p>QC 20130207</p> nanocomposites poly(ethylene-co-butyl acrylate) EBA alumina dielectric permittivity absorbed water humidity temperature dielectric spectroscopy breakdown strength pre-breakdown current
737	Gecko Adhesion and Gecko-Inspired Dry Adhesives: From Fundamentals to Characterization and Fabrication Aspects Izadi, Hadi 19 February 2014 (has links) This study focuses on fabrication of dry adhesives mimicking gecko adhesion. We also look into the origin of the supreme adhesion of geckos, which have inspired the fabrication of fibrillar dry adhesives during the last decade or so. In principle, the superior material properties of ??-keratin (the main material comprising the fibrillar feature on gecko toe pads) along with the hierarchical high aspect-ratio fibrillar structure of geckos??? foot pad have enabled geckos to stick readily and rapidly to almost any surface in both dry and wet conditions. In this research, non-sticky fluoropolymer (Teflon AF) resembling ??-keratin rigidity and having an extremely low surface energy and dielectric constant was applied to fabricate a novel dry adhesive consisting of extremely high aspect-ratio nanopillars (200 nm in diameter) terminated with a fluffy top nanolayer. Both the nanopillars and the terminating layer were fabricated concurrently by replica-molding using a nanoporous anodic aluminum oxide membrane as the mold. In particular, upon infiltration of Teflon AF melt into the anodic aluminum oxide nanopores, the polymer melt fingered over the pore walls. The fingerlike structure formed during infiltration, subsequently collapsed after removal of the mold, developing a unique sheet-like nanostructure on top of the base nanopillars. Concurrent fabrication of the terminating nanostructure helps the fabrication of extremely high aspect-ratio (27.5???225) nanopillars which, up to an aspect-ratio of 185, neither collapse at the tip nor bundle. In order to fabricate nanopillars of different topographical properties, in our first approach, the height of the nanopillars as well as the size and density of the terminating nanostructure are carefully controlled by adjusting the processing temperature. Following that, a novel replica-molding technique for fabrication of bi-level Teflon AF nanopillars is reported. The developed technique relies on the concurrent heating and cooling of the Teflon AF melt which filled vertically-aligned alumina nanochannels. Unlike conventional polymer infiltration methods which consist of filling the mold by only heating the polymer above its glass transition temperature, in our novel method, the polymer melt is also simultaneously cooled down during the infiltration process. Concurrent cooling of the Teflon AF melt allows control over the interfacial instabilities of the polymer thin film, which forms ahead of the polymer melt upon its infiltration into the alumina nanochannels. Doing so, the geometrical properties of the subsequently developed peculiar fluffy nanostructure ??? after removal of the mold ??? on top of the extremely high aspect-ratio Teflon AF nanopillars (~25 ??m tall) are modified. In this project, we have also shown that the adhesion of the fabricated dry adhesives for the most part arises from electrostatic interactions of the applied polymer. In other words, Teflon AF, having an exceptional potential for developing electric charges at its surface upon contact with other materials via the so-called contact electrification phenomenon, can develop significant electrostatic interactions at its surface upon contact. In the current thesis, tribological results were discussed in detail to clarify the contribution of the structural properties of the fabricated dry adhesives toward their remarkable adhesion and friction forces generated via contact electrification. Nanopillars of specific geometrical properties have achieved remarkable adhesion and friction strengths, up to ~2.1 N/cm2 and 17 N/cm2, respectively (up to ~2.1 and 1.7 times larger than those of a gecko toe pad). It is commonly accepted that the adhesive performance of other synthetic bio-inspired dry adhesives is due to the formation of van der Waals interactions at the tip or side of the dry adhesives fibrils with the substrate they are brought into contact with. However, what has been usually neglected in this connection is that electrostatic interactions may also be developed at the contact between any two materials via the familiar contact electrification phenomenon. Although contact electrification is common and can have a large influence on interfacial interaction forces, its impact on adhesive properties of synthetic dry adhesives has been overlooked. Our results on adhesion of bi-level Teflon AF nanopillars, which can generate strong adhesion forces relying on electrostatic interactions arising from contact electrification, have brought to light again the idea that charging the surface of dry adhesives, specifically polymeric ones, can play a very crucial role in their adhesive behavior. From this perspective, the main reasons that have caused this lack of attention to this concept and the possible contributions of contact electrification to interfacial interactions of polymeric dry adhesives, other than bi-level Teflon AF nanopillars, are also thoroughly discussed in this thesis. Besides synthetic fibrillar dry adhesives, the possibility of the occurrence of contact electrification and its contribution to the supreme dry adhesion of geckos have also been overlooked for several decades. In this research, by the simultaneous measurement of electric charges and adhesion forces that gecko toe pads develop on two distinct substrates (a sticky and a non-sticky one), we have shown that the toe pads generate significantly large amounts of electric charge on both substrates. More importantly, we have found that there is a direct correlation between the contact electrification-driven electrostatic forces and the measured adhesion forces. Otherwise stated, we have shown that what makes the difference that geckos stick strongly to one surface and not to the other are the electrostatic interactions arising from contact electrification, and not van der Waals interactions, which have been considered as the prime source of adhesion of geckos for many years. Gecko adhesion Gecko-inspired adhesive Teflon AF Fingering Instability Alumina membrane nanopillars Surface charging Contact electrification Dry adhesion van der waals Electrostatic
738	The influence of composition, processing and temperature on the Young's modulus of elasticity of carbon-bonded refractories Werner, Jörn 11 December 2014 (has links) (PDF) Thermal shock resistance is a key property of refractory materials. Its determination and prediction is essential for the design of structural refractories as well as lining materials. Young’s modulus of elasticity (E) is a crucial parameter for the calculation of thermal shock resistance. For all investigated carbon-bonded alumina composition a significant increase of E was observed. This increase was attributed to a mismatch of the coefficient of thermal expansion of the composite constituents. Besides others, the graphite content as well as the maximum alumina particle size were identified as crucial factors influencing E(T). Furthermore, the influence of the porosity on E was shown and existing models were fitted to the experimental data for future predictions of E. Finally a metal melt filter structure was investigated to investigate the relationship between its strut Young’s modulus and the structures’ E at high temperatures. Further research should address the filter topic since it was uncertain how to find the normal modes of those structures. Feuerfeste Werkstoffe Elastizität Hochtemperatur Kohlenstoffgebunden Aluminiumoxid Werkstoffprüfung Refractories elasticity high temperature carbon bonded alumina ddc:660 Feuerfester Stoff Hochtemperatur Aluminiumoxide Kohlenstoff Elastizität
739	Investigation Of The Effects Of Temperature On Physical And Mechanical Properties Of Monolithic Refractory Made With Pozzolanic Materials Morel, Bayram Murat 01 November 2005 (has links) (PDF) In recent years, scientific studies are carried out to find new refractory material. Having good mechanical properties under very high temperatures, refractories are widely used in industries like iron, steel, glass, cement and pottery. Researches are focused on monolithic refractory making because of their superior properties comparing to conventional firebrick refractories. Providing a mono-block body, having no joints makes the monolithic refractories more durable at elevated temperatures. Easier production and installation are two main points that people are choosing monolithic refractories, thus an economy is made. In this study, for monolithic refractory production, high alumina cement was used as binding material. It is known that the increase in alumina (Al2O3) content increases the high temperature resistance, so that crushed firebrick, having 85% Al2O3 was used as aggregate. Pozzolanic materials, which are silica fume, fly ash, ground granulated firebrick and ground granulated blast furnace slag, were added to improve physical and mechanical properties of mortar. With the addition of steel fibres, change in compressive strength and flexural strength was observed.Superplasticizer was used to understand its behaviour under high temperatures. Portland cement containing mortars were also prepared to make comparison with high alumina cement containing specimens. Specimens were prepared in 5x5x5 cm and 4x4x16 cm prisms. They were cured for one day at curing room, then heated to 105&deg / C and then heated to 1100&deg / C. Weight, size and ultrasound velocity change, compressive strength and flexural strength tests were done to determine physical and mechanical properties of the monolithic refractories, before and after heating. Heated and non-heated specimens were pulverized for microstructural investigation with X-Ray diffraction (XRD) method. Using high alumina cement with 50 &ndash / 60 % granulated blast furnace slag or granulated firebrick, by the weight of cement, and crushed firebrick as aggregate, a satisfactory monolithic refractory material was made. It was observed that, mechanical properties were decreased at the Portland cement used mortars after several times of heating and cooling cycles. Also, it was determined that the microstructure of the high alumina cement containing mortars did not deteriorate much at 1100&deg / C, as long as there was no change observed from the results.
740	Síntese de membranas de alumina anódica porosa sobre substratos metálicos obtidos por evaporação térmica / Synthesis of porous anodic alumina membranes on metal substrates obtained by thermal evaporation Garcia, Uanderson Mezavila 14 March 2017 (has links) Submitted by Milena Rubi (milenarubi@ufscar.br) on 2017-08-16T17:29:07Z No. of bitstreams: 1 GARCIA_Uanderson_2017.pdf: 25453924 bytes, checksum: 4c34f46362e91f9eb2f88106f805d7f3 (MD5) / Approved for entry into archive by Milena Rubi (milenarubi@ufscar.br) on 2017-08-16T17:29:17Z (GMT) No. of bitstreams: 1 GARCIA_Uanderson_2017.pdf: 25453924 bytes, checksum: 4c34f46362e91f9eb2f88106f805d7f3 (MD5) / Approved for entry into archive by Milena Rubi (milenarubi@ufscar.br) on 2017-08-16T17:29:23Z (GMT) No. of bitstreams: 1 GARCIA_Uanderson_2017.pdf: 25453924 bytes, checksum: 4c34f46362e91f9eb2f88106f805d7f3 (MD5) / Made available in DSpace on 2017-08-16T17:29:30Z (GMT). No. of bitstreams: 1 GARCIA_Uanderson_2017.pdf: 25453924 bytes, checksum: 4c34f46362e91f9eb2f88106f805d7f3 (MD5) Previous issue date: 2017-03-14 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / This work covers the investigation and synthesis of nanometric structures of Porous Anodic Alumina PAA, produced from low purity substrates, in aim to obtain selfsustained membranes. The Hard Anodization (HA) and Mild Anodization (MA) processes were used under special conditions through those found in literature. The analyses of results were based in comparing the AAP produced under the same conditions except the applied potential that was different depending on the MA or HA. HA process had its time halved in order to investigate the oxide growth rate and to calibrate the conditions of anodized membrane synthesis over the glass samples. This work also covers the construction of a resistive thermal evaporation PVD system capable of evaporating metals with melting points below 800°C. Through the deposition of successive layers it was possible to obtain metallic films of aluminum with thicknesses above 10 µm, enabling conditions of synthesis of porous anodic alumina on substrates produced by thermal resistive evaporation. The result of membrane synthesis on low purity aluminum substrates was complement to the synthesis of membranes obtained in aluminum evaporated in glass substrates, since the thickness of each deposited film is low if compared to the thickness of the AAP layer. Therefore, it was necessary to make several Al depositions on the same samples, to obtain an aluminum film that was able to support an oxide layer of anodic alumina and with the same characteristics of those obtained by the process of MA. All anodized samples were characterized by scanning electron microscopy, including samples made from metalized aluminum. The micrography obtained from the low purity aluminum membranes were treated by ImageJ software allowing the morphological analysis. AAP membranes obtained from technical Al substrate depicted the formation of branched pore channels, a result of instabilities in applied electric field during Anodization and presence of different alloying elements in the Al substrate. The metalized aluminum film had a larger thickness in the samples positioned in the middle of the sample holder possibly due to different temperature gradients of filament depending on the position of Al pellets. / Este trabalho aborda a síntese e investigação de estruturas nanométricas de Alumina Anódica Porosa AAP produzidas a partir de substratos de baixa pureza, com a finalidade da obtenção de membranas auto-suportadas. Foram utilizados os processos de Hard Anodization (HA) e Mild Anodization (MA). Para efeito comparativo entre os processos foram mantidas todas as condições variando apenas o potencial aplicado. Posteriormente para HA o tempo experimental foi reduzido pela metade a fim de investigar a velocidade no crescimento do óxido e condições de anodização de membranas sobre as amostras de vidro. Este trabalho também abrange a construção de um sistema Phisical Vapor Deposition (PVD) por evaporação térmica resistiva, capaz de evaporar metais com pontos de fusão abaixo de 800°C. Através da deposição de sucessivas camadas foi possível a obtenção de filmes metálicos de Alumínio com espessuras acima de 10 µm, possibilitando condições de síntese de alumina anódica porosa sobre substratos produzidos por evaporação térmica resistiva. O resultado da síntese de membranas em substratos de Al de baixa pureza foi complementar à síntese das membranas obtidas em alumínio evaporado em substratos de vidro, pois a espessura de cada filme depositado é baixa se comparados a espessura da camada de AAP. Portanto, houve a necessidade de várias deposições sobre as mesmas amostras, para se obter o filme de alumínio que fosse capaz de suportar uma camada de alumina anódica porosa resistente e que se aproximasse das características das obtidas pelo processo de MA. Todas as amostras anodizadas foram caracterizadas por microscopia eletrônica de varredura, inclusive as amostras produzidas a partir do alumínio metalizado. As micrografias obtidas a partir das membranas de alumínio de baixa pureza foram tratadas pelo software ImageJ, possibilitando a análise morfológica das mesmas. As membranas de AAP de baixa pureza possuem poros com ramificações transversais, são provocadas pelos desvios do campo elétrico aplicado, além da possibilidade de formação de outros tipos de óxidos. O filme de alumínio metalizado teve maior espessura nas amostras posicionadas na parte central do porta amostra, isso pode estar relacionado com o aquecimento do filamento que ocorre da região central para as extremidades. / 2010/10813-0 Óxido de alumínio Eletroquímica Nanotecnologia Alumina anódica porosa PVD Evaporação de alumínio Aluminum oxide Electrochemistry Nanotechnology Mild anodization Hard anodization Thermal resistive evaporation

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