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Cast Aluminum Alloys and Al-Based Nanocomposites with Enhanced Mechanical Properties at Room and High Temperature: Production and CharacterizationToschi, Stefania <1986> 22 April 2016 (has links)
The present PhD thesis summarizes the results of experimental activities carried out on the production and characterization of cast aluminum alloys and Al-based nanocomposites for room and high temperature applications. Two quaternary Al-Si-Cu-Mg alloys (A354 and C355) were studied, aiming to investigate the effect of chemical composition, solidification rate and heat treatment condition on the tensile and fatigue behavior at room and high temperature. Heat treatment optimization of A354 alloy was carried out. The overaging behavior of A354 and C355 alloys was compared to that of A356 (Al-Si-Mg) alloy, in order to evaluate the thermal stability of the alloys. As a result, the concurrent presence of Cu and Mg confers, by precipitation hardening, enhanced mechanical properties and higher thermal stability in comparison to the traditional Al-Si-Mg alloy. A preliminary study aimed to evaluate the effect of Molybdenum addition on A354 overaging response was also carried out. Enhanced mechanical properties after long-term overaging were registered in A354-0.3wt.%Mo alloy, in comparison to the base A354. Casting techniques for the production of Al-matrix composites were implemented at the laboratory scale. The stir-casting method assisted with ultrasonic treatment and in situ reactive casting were applied to produce Al2O3-A356 micro/nanocomposites and ZrB2-A356 composites, respectively. Friction Stir Process (FSP) was evaluated as possible solid state processing route to: (i) enhance Al2O3 nanoparticles distribution in a semisolid processed AA2024-based nanocomposite, and (ii) directly distribute Al2O3 nanoparticles into AA7075 alloy at the solid state. Experimental results highlighted difficulties in obtaining an even distribution of nanoparticles, by both liquid and semi-soli state routes, due to the low wettability of nano-sized ceramic reinforcement. The application of FSP led to enhanced nanoparticles distribution, mitigation of casting defects associated to nanoparticles addition (porosity, nanoparticles clusters) and microstructural homogenization, thus allowing to better exploit nanoparticles strengthening effect.
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Design and optimization of components and processes for plasma sources in advanced material treatmentsRotundo, Fabio <1983> 05 June 2012 (has links)
The research activities described in the present thesis have been oriented to the design and development of components and technological processes aimed at optimizing the performance of plasma sources in advanced in material treatments.
Consumables components for high definition plasma arc cutting (PAC) torches were studied and developed. Experimental activities have in particular focussed on the modifications of the emissive insert with respect to the standard electrode configuration, which comprises a press fit hafnium insert in a copper body holder, to improve its durability. Based on a deep analysis of both the scientific and patent literature, different solutions were proposed and tested. First, the behaviour of Hf cathodes when operating at high current levels (250A) in oxidizing atmosphere has been experimentally investigated optimizing, with respect to expected service life, the initial shape of the electrode emissive surface. Moreover, the microstructural modifications of the Hf insert in PAC electrodes were experimentally investigated during first cycles, in order to understand those phenomena occurring on and under the Hf emissive surface and involved in the electrode erosion process. Thereafter, the research activity focussed on producing, characterizing and testing prototypes of composite inserts, combining powders of a high thermal conductibility (Cu, Ag) and high thermionic emissivity (Hf, Zr) materials
The complexity of the thermal plasma torch environment required and integrated approach also involving physical modelling. Accordingly, a detailed line-by-line method was developed to compute the net emission coefficient of Ar plasmas at temperatures ranging from 3000 K to 25000 K and pressure ranging from 50 kPa to 200 kPa, for optically thin and partially autoabsorbed plasmas.
Finally, prototypal electrodes were studied and realized for a newly developed plasma source, based on the plasma needle concept and devoted to the generation of atmospheric pressure non-thermal plasmas for biomedical applications. / L’attività di ricerca svoltasi durante il Dottorato è stata orientata alla progettazione e allo sviluppo di componenti e processi tecnologici innovativi atti ad ottimizzare le prestazioni di sorgenti plasma nel trattamento avanzato di materiali.
Sono stati in particolare studiati e sviluppati consumabili di torce al plasma termico per il taglio di materiali metallici (PAC, plasma arc cutting), nell’ambito della cosiddetta alta definizione. L’attività di tipo sperimentale in ambito PAC si è concentrata sulla valutazione e realizzazione di modifiche dell’inserto emettitore, rispetto alla configurazione attuale di elettrodi standard, che prevede un inserto piatto in afnio (Hf) inserito per interferenza in un corpo elettrodo in rame (Cu). Le soluzioni proposte per l’attività di ricerca sono state basate su un’approfondita analisi bibliografica e brevettuale. Il comportamento di inserti in Hf operanti ad alte correnti (250A) in torce PAC è stato sperimentalmente analizzato, ottimizzando la forma iniziale della superficie emittente per incrementarne la vita utile. Sono inoltre state studiate le modificazioni microstrutturali dell’inserto emettitore al fine di comprendere i fenomeni coinvolti nel processo di erosione. Infine, l’attività di ricerca su elettrodi PAC si è concentrata sulla produzione, caratterizzazione e test di inserti compositi prototipali, realizzati unendo polveri ad alta conduttività termica (Cu, Ag) e polvere ad alta emissività termoionica (Hf, Zr).
La complessità del sistema torcia ha inoltre richiesto un approccio integrato, che affiancasse attività di simulazione modellistico-computazionale con le valutazioni sperimentali, di natura chimico-fisica e microstrutturale. È stato in questo senso implementato un modello per il calcolo del coefficiente di emissione netto (NEC) del plasma di Argon in funzione di temperatura (1000-25000 K) e pressione (50-200 kPa), per plasmi otticamente sottili o parzialmente auto-assorbiti.
Sono infine stati inoltre studiati e realizzati elettrodi prototipali per sorgenti di plasma non termico, finalizzate in particolare ad applicazioni biomedicali, nella configurazione detta plasma needle.
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Comportamento tribologico di materiali per componenti di interesse industriale: Failure analysis e prove tribologiche in laboratorio / Tribological behavior of materials for components of industrial interest: Failure analysis and tribological laboratory testMarconi, Alessandro <1984> 23 May 2014 (has links)
L’attività di ricerca della presente tesi di dottorato ha riguardato sistemi tribologici complessi di interesse industriale per i quali sono stati individuati, mediante failure analysis, i meccanismi di usura dominanti. Per ciascuno di essi sono state studiate soluzioni migliorative sulla base di prove tribologiche di laboratorio. Nella realizzazione di maglie per macchine movimentazione terra sono ampiamente utilizzati i tradizionali acciai da bonifica. La possibilità di utilizzare i nuovi microlegati a medio tenore di carbonio, consentirebbe una notevole semplificazione del ciclo produttivo e benefici in termini di costi. Una parte della tesi ha riguardato lo studio del comportamento tribologico di tali acciai. E’ stato anche affrontato lo studio tribologico di motori idraulici, con l’obiettivo di riuscire a migliorarne la resistenza ad usura e quindi la vita utile. Sono state eseguite prove a banco, per valutare i principali meccanismi di usura, e prove di laboratorio atte a riprodurre le reali condizioni di utilizzo, valutando tecniche di modificazione superficiale che fossero in grado di ridurre l’usura dei componenti. Sono state analizzate diverse tipologie di rivestimenti Thermal Spray in termini di modalità di deposizione (AFS-APS) e di leghe metalliche depositate (Ni,Mo,Cu/Al). Si sono infine caratterizzati contatti tribologici nel settore del packaging, dove l’utilizzo di acciai inox austenitici è in alcuni casi obbligatorio. L’acciaio inossidabile AISI 316L è ampiamente utilizzato in applicazioni in cui siano richieste elevate resistenze alla corrosione, tuttavia la bassa resistenza all’usura, ne limitano l’impiego in campo tribologico. In tale ambito, è stata analizzata una problematica tribologica relativa a macchine automatiche per il dosaggio di polveri farmaceutiche. Sono state studiate soluzioni alternative che hanno previsto sia la completa sostituzione dei materiali della coppia tribologica, sia l’individuazione di tecniche di modificazione superficiale innovative quali la cementazione a bassa temperatura anche seguita dalla deposizione di un rivestimento di carbonio amorfo idrogenato a-C:H / The research focused on complex tribological systems of industrial interest for which the dominant wear mechanisms have been identified, through failure analysis. Therefore alternative solutions were studied on the basis of tribological laboratory test. For the tracks of high power excavators are widely used conventional Q&T steels. The possibility of using the new microalloyed medium carbon steels, allow a considerable reduction of manufacturing costs. This section focused on the study of the tribological behavior of these steels. It was also addressed the tribological study of hydraulic motors, in order to improve the wear resistance and the durability of this motors. Bench tests were carried out to assess the main wear mechanisms, and tribological laboratory test were performed to reproduce the real conditions, evaluating surface modification techniques that were able to reduce the wear of the components. Various types of thermal spray coatings, in terms of deposition mode (AFS -APS ) and metal alloys used (Ni, Mo, Cu/Al), were analyzed. Tribological contacts were finally characterized in the packaging sector, where the use of austenitic stainless steel is required in many cases. The AISI 316L stainless steel is widely used in applications where high corrosion resistance are required, however, the low wear resistance, limit the use of this steel in the tribology field. In this context, a tribological issue has been analyzed related to automatic machines for dosing of pharmaceutical powders. Alternative solutions have been studied: the complete replacement of the materials of the tribological pair, and the identification of innovative surface modification techniques, such as low temperature carburizing followed by the deposition of hydrogenated amorphous carbon a-C:H coating(DLC)
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Deformation mechanisms in bulk nanostructured aluminum obtained after cryomilling and consolidation by spark plasma sinteringLonardelli, Ivan January 2010 (has links)
Bimodal bulk nanocristalline (nc)/ultrafine (UF) aluminum was produced after cryomilling and spark plasma sintering consolidation process. The samples obtainedwere plastically deformed in uniaxial compression. We show that there is a significant fraction of plastic strain (11%) that can be recovered after unloading. High-energy synchrotron X-ray diffraction experiments revealed that, there is a correlation between plastic strain recovery and microstructural evolution detected during in-situ loading-unloading experiments. Using a deconvolution approach, the nanostructured volume fraction (grain size below 100 nm) and the UF counterpart (grain size above 100-150 nm)were separated in terms of lattice strain, microstrain, crystallite size and crystallographic texture. During loading-unloading cycles we observe a lattice strain splitting between nc and UF volume fractions, a complete recovery of the peak broadening and a recovery of texture.
These intriguing phenomena were explained to be strictly correlated with the lattice strain splitting behavior which act as the driving force for dislocation recombination.
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Production of strengthened copper materials by Mechanical Milling-Mechanical Alloying and Spark Plasma SinteringCipolloni, Giulia January 2016 (has links)
Copper is widely used in many applications demanding high thermal and electrical conductivity, unfortunately its low hardness and wear resistance limit its performance. Work hardening has been proposed as a successful strengthening mechanism for the production of harder copper material, keeping the intrinsic conductivities. In this PhD thesis initially mechanical milling (MM) has been considered as suited strengthening technique due to the severe strain hardening and microstructural refinement induced by severe plastic deformation during the process. Then an enhanced hardening has been obtained by dispersion of a second harder phase in the copper matrix by mechanical alloying (MA), leading to the production of metal matrix composites (MMC). In this PhD thesis strain hardened and dispersion hardened copper materials have been sintered by Spark Plasma Sintering (SPS). Firstly the MM behaviour of Cu as function of milling time has been studied, it consists in three stages: flaking, welding and fracturing process. Since stearic acid has been added as process control agent (PCA), its decomposition has been analysed to limit the residual porosity in sintered samples. Several focused attempts have been made and the best results have been obtained by using a fine particle size, decreasing the heating rate and applying the SPS pressure once the decomposition of PCA was completed. However the presence of copper oxide and microstructure defects induced by the severe strain hardening hinder the densification. The residual porosity is responsible of a decrease of hardness in sintered sample and consequently to a limited wear resistance, to a decrease of thermal conductivity and to a loss of ductility. For the production of MMC a ceramic reinforcement (0.5wt% of TiB2) has been selected. Increasing milling time the dispersion of the hard phase among the matrix becomes more homogeneous and refinement of TiB2 is highlighted. The evolution of particle size and morphology during MA is similar to MM; also the densification mechanism during SPS are the same consisting in powder rearrangement, local and bulk deformation. The final density generally decreases by increasing milling time, by the way an increasing hardness confirms that strain hardening and dispersion hardening abundantly compensate the negative effect of porosity. Has been proved that the hard particles successfully enhanced sliding and abrasion wear meanwhile the copper matrix guarantees high thermal conductivity, satisfying the requirements.
Therefore considering the characteristics of the initial copper powder, promising results have been obtained for MMCs showing an increased hardness combined with a high wear resistance and a thermal conductivity comparable to atomized copper and much higher than the commercial Cu-Be alloy. On the other side mechanical milled samples exhibited some limits, but they allowed a deep understanding of the MM process of copper.
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Production of steel matrix composites by mechanical milling and spark plasma sinteringFedrizzi, Anna January 2013 (has links)
Hot work tool steels (HWTSs) are ferrous alloys for tooling application, particularly developed to meet high toughness and good hot hardness. Increasing hardness generally leads to a decrease in toughness, therefore metal matrix composite (MMC) coatings and functionally graded materials have been proposed as a good solution for improving wear resistance.
In this PhD thesis powder metallurgy has been applied for the production of particle reinforced HWTSs. Mechanical milling (MM) and mechanical alloying (MA) have been considered as suited techniques for the production of powders showing higher sinterability and finer microstructure. Spark plasma sintering (SPS) has been used for the consolidation. As reinforcement a harder high speed steel (HSS) and different ceramic powders (TiB2, TiC and TiN) have been selected.
The production of HWTS/HSS blends has highlighted the negative interaction on densification of the two components due to their different sintering kinetics. This interference can be minimised by selecting powders with smaller particles size. With this respect MM was proved to be a very useful method, which enhances sintering. Fully dense blends with good dispersion of the reinforcing particles can be sintered using small sized powders and setting the particle size ratio (PSR) smaller than 1.
For the production of MMCs the formation of aggregates has been overcome by MA which promotes a uniform dispersion of hard particles into the parent steel. Among the reinforcement considered in this work, TiB2 is not suitable because it reacts with steel depleting carbon and producing TiC and brittle Fe2B. HWTS composites with 20%vol of TiC can be fully densified by SPS at 1100 °C for 30 minutes and 60 MPa uniaxial pressure. On the other hand TiN-reinforced MMC shows high resistance to densification and fully dense materials could not be produced.
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Microstructure and mechanical properties of biomedical alloys produced by Rapid Manufacturing techniquesFacchini, Luca January 2010 (has links)
Rapid Manufacturing (RM) technologies as Electron Beam Melting (EBM) and Selective Laser Melting (SLM) are able to produce fully dense parts from pre-alloyed powders in a layer-wise way. Moreover, they are able to create tailored surfaces with interconnected porosity. Applied to biomedical prostheses, such porosity can favour cell adhesion and osteointegration.
The most important intrinsic characteristic of RM techniques is the large undercooling the parts undergo during the process. This undercooling results in peculiar, very fine, metastable microstructures, associated to peculiar mechanical behaviour. Metastable microstructures can change on post-melting operations, making the materials match the standard requirements and gain interesting properties.
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Production of a nanostructured copper by Spark Plasma SinteringDiouf, Saliou January 2013 (has links)
The aim of the present PhD work is the study of the production of a nanostructured copper by Spark Plasma Sintering. The nanostructured powder was produced by cryomilling an atomized powder, using a ball-to-powder ratio of 30:1 for 8h; it has a mean grain size of 19±2 nm and shows quite a high thermal stability, as shown by a DSC investigation. The influence of temperature, particle size, pressure on the densification and sintering mechanisms as well as that of heating rate and holding time on the structural evolution has been investigated. Particle rearrangement, local deformation, bulk deformation and sintering are the SPS mechanisms occurring successively during the sintering process of the atomized copper. These mechanisms are enhanced by the peculiar heating mechanism in SPS, and the surface overheating above the melting temperature in the contact regions has been demonstrated. In the cryomilled powder, sintering occurs at much lower temperature than in the atomized powder, due to effect of the high density of structural defects on the mass transport phenomena responsible for neck growth. The increase in heating rate tends to promote a bimodal grain size distribution (both nanomentric and ultrafine grains) while an increase in holding time increases grain size slightly. A promising combination of strength and ductility was measured on tensile specimens produced under selected conditions, and a dimpled fracture morphology was observed.
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Numerical simulation of fumes evacuation in steelmaking plantsLabiscsak, Laszlo January 2012 (has links)
Evacuation systems in steelmaking plants contribute to the security of the operators around the furnace and help to gain the emission levels stated in the environmental regulations, furthermore play a major role in the mass and heat balance of the factory. The aim of the dissertation is to study both primary and secondary emission capture systems of an electric arc furnace steelmaking plant by means of 3D computational thermal fluid dynamics calculations.
The overall performance of the post-combustion chamber, and consequently the primary line, is controlled by the size of the gap downstream the fourth hole of an electric are furnace. The impact of the opening coefficient (ratio between the gap area and the total area) on the post-combustion chamber performance has been investigated by means of a comprehensive 3D steady CFD simulation comprising radiative heat exchanges and detailed chemical reactions. It was found that there is not a unique value of the opening coefficient capable of optimizing all the relevant quantities of the evacuation process. A value of the opening coefficient in the range 0.40-0.52 appears advisable. The impact of the (mostly unknown) boundary conditions was also assessed and inefficiencies of the assumed post-combustion geometry have been highlighted.
The secondary line's capturing efficiency during the charging phase was simulated with both transient and steady-state solvers with different turbulent models, namely the standard k-e and the Large Eddy Simulation models. The results revealed that steady-state simulations provide sufficient information for designing and optimizing the geometry of the secondary capture system. The simulations also pointed out several geometries, which cause significant pressure drop and, as a result, diminish capturing ability of the canopy hood and the additional evacuation system. The boundary conditions were imposed with the help of experimental measurements in the simulated steelmaking factory.
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Mechanism of anisotropic shrinkage during sintering of metalli powdersTorresani, Elisa January 2016 (has links)
The anisotropic dimensional change on sintering of a prior cold compacted iron was investigated by dilatometry. Shrinkage is larger along the compaction direction than in the compaction plane. This phenomenon is very pronounced during the heating ramp in alpha phase and in particular below the Curie temperature, while in austenitic field is quite poor. The results of dilatometry tests were elaborated according to the shrinkage kinetics model of classical sintering theory, to calculate an effective diffusion coefficient along the two directions, which resulted higher for direction parallel to the compaction direction than perpendicular to it. In both directions, the effective diffusion coefficient is larger than that reported in the literature for pure iron, corresponding to an equilibrium density of structural defects. It also varies during the isothermal holding time. This discrepancy is attributed to the defectiveness introduced by cold compaction, that increases diffusivity through the activation of dislocation pipe mechanism, which is particularly intense below the Curie. This interpretation may also justify anisotropy of shrinkage due to the inhomogeneous deformation of interparticle contact regions that was measured with ISE method and EBSD analysis. The anisotropic shrinkage was also described through a modified micromechanical model proposed by the continuum mechanics approach, where the porous body is composed by aligned, elongated particles and elliptic pores, whose geometrical parameters were obtained through image analysis of SEM microhgraphs. The dislocation density calculated for different sintering temperatures was comparable to that measured experimentally. The effect of green density on anisotropy of shrinkage was investigated, too. Anisotropy tends to increase with green density, because of the larger plastic deformation introduced in the interparticle regions by the compaction pressure.
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