Elaboration de matériaux composites à matric Titane et à nano-renforts TiC et TiB par différents procédés de métallurgie des poudres : frittage par hydruration/dehydruration et déformation plastique sévère (Equal Channel Angular Pressing (ECAP)) / Processing of titanium-based composite materials with nanosized TiC and TiB reinforcements using different powder metallurgy processes : hydrogenation/dehydrogenation sintering, and severe plastic deformation (Equal Channel Angular Pressing ECAP)

Bardet, Matthieu

18 March 2014

Les composites à matrice Titane avec des renforts nanométriques présente des améliorations intéressantes quant aux propriétés mécaniques, sans affecter la ductilitédu matériau. Ce travail de thèse se concentre sur l’élaboration et la caractérisation dematériaux composites de Titane obtenus par deux différents procédés de métallurgie despoudres : La densification par déformation plastique sévère utilisant l’ECAP (Equal ChannelAngular Pressing) et les procédés de frittage par hydrogénation/déshydrogénation (HDH).L’ECAP est un procédé de densification rapide utilisant la déformation plastique desmatériaux, se faisant à relativement basse température. Les procédés HDH utilisent ladéshydrogénation du titane comme un levier sur les mécanismes de frittage. Les différentsnano-renforts utilisés dans ces travaux sont les particules sphériques de TiC et les aiguillesde TiB. Cette étude montre l’influence de la nature et de la forme des renforts, ainsi que duprocédé de métallurgie des poudres utilisé, sur les propriétés et la microstructure final desmatériaux denses. / Titanium based composites using nano-sized reinforcements are goodcandidates for the improvement in mechanical properties without affecting ductility. Thisstudy is dedicated to fabrication and characterisation of Ti-based composites using twodifferent powder metallurgy processes: Densification using severe plastic deformation viaEqual Channel Angular Pressing (ECAP) and Hydrogenation/Dehydrogenation (HDH)sintering processes (pressureless sintering and hot pressing).ECAP is a fast process basedon a severe plastic deformation of material at relatively low temperature. HDH processes usethe dehydrogenation of Ti as a leverage of the sintering. The different nanosizedreinforcements used in this study are the TiC spherical particles and the whisker shaped TiB.This study shows the influence of either the reinforcement nature and type, and the powdermetallurgy processes used, on the final microstructure and properties of the dense materials.

Déformation plastique sévère

ECAP

Hydruration

Déshydruration

Composites

Titane

Nano-renforts

EBSD

Microstructures

Severe Plastic Deformation

ECAP

Hydrogenation

Dehydrogenation

Composites

Titanium

Nanoreinforcements

EBSD

Microstructures

620.118

Struktura a mechanické vlastnosti materiálů na bázi hořčíku zpracovaných metodou HPT / Structure and mechanical properties of magnesium materials processed by HPT

Poloprudský, Jakub

January 2019

This thesis is focused on processing of pure magnesium by high pressure torsion method (HPT). This process belongs to the group of intensive plastic deformation methods (SPD). SPD methods are in the centre of scientific interest for several decades. Theoretical part of this thesis puts an effort to summarize basic knowledge and principles of SPD methods with extra focus on method HPT. As theoretical part continues magnesium as technical material is presented. Influence of SPD on use and properties of pure magnesium is then presented. This trend is further developed in effort to describe the effect of individual HPT process variables on the properties of pure magnesium and its alloys. Focus of practical part of this thesis is in influence of number of revolutions. Samples were processed at 1/8, 1/4, 1/2, 1, 4 and 8 turns at room temperature. Speed of process was 1rpm and applied pressure was 6 GPa. The structure of commercially pure magnesium prepared by casting and moulding were observed with focus on differences caused by input material. The structure was observed by both light microscopy and back scattered electron diffraction (EBSD), focusing on structure development, grain size and grain orientation. Compared to other works on similar topic, the emphasis here is on observing the microhardness on the vertical edge of the sample. The hardness shows a steep increase right after 1/8 of a turn. With increasing number of turns gradual homogenization of microhardness is presented accompanied by slight decrease in microhardness. No trend in microhardness relative to the distance from anvil has occurred. Structure observed with EBSD shows a bimodal character with larger grains oriented in the same direction. The three-point bending test didn’t end up as expected, and the approach to evaluation of magnesium-based HPT needs to be re-evaluated for future work. A three-point bending test was designed for the initial assessment of the basic mechanical properties of the material.

Teplotní stabilita Mg-slitiny AZ91 připravené pomocí intenzivní plastické deformace / Thermal stability of Mg-alloy AZ91 prepared by severe plastic deformation

Štěpánek, Roman

January 2012

This thesis dealt with thermal stability of magnesium alloy AZ91 prepared by severe plastic deformation, which leeds to fine grained structure. This structure is characterised by its inherent instability and this thesis tries to find out the value of critical temperature and rate of this instability, which manifests as grain coarsening.

Mechanické vlastnosti hořčíkové slitiny AZ91E připravené metodou ECAP / Mechanical properties of magnesium alloy AZ91E prepared by ECAP method

Darida, Jiří

January 2016

This thesis deals with mechanical and fatigue properties of magnesium alloy AZ91 processed by EX-ECAP method. This method involves the application of extrusion followed by equal-channel angular pressing. To obtain basic mechanical characteristics, the tensile test were carried out at room and elevated temperatures. Further the fatigue tests were performed and obtained data were used to compile S-N curve. The work also includes metallographics analysis of microstructure and fractographic analysis of fracture surfaces of tensile and fatigue test specimens.

Studium mikrostruktury ultrajemnozrnných kovových materiálů metodou pozitronové anihilace / Studium mikrostruktury ultrajemnozrnných kovových materiálů metodou pozitronové anihilace

Barnovská, Zuzana

January 2011

In the presented thesis we study the changes in distribution of the size of vacancy clusters in metals processed by severe plastic deformation, so called ul- tra fine grained materials. We use a modern non-destructive method of positron annihilation spectroscopy, which is one of the few methods that allow us to inves- tigate point defects like vacancies with sizes of a few ˚A. The obtained spectra of positrons annihilating in the samples enable us to determine changes of vacancy cluster sizes depending on temperature or severity of the deformation applied on the samples. 1

Fázové transformace v ultra-jemnozrnných slitinách titanu / Phase transformations in ultra-fine grained titanium alloys

Bartha, Kristina

January 2019

Title: Phase transformations in ultra-fine grained titanium alloys Author: Kristína Bartha Department: Department of Physics of Materials Supervisor of the doctoral thesis: PhDr. RNDr. Josef Stráský, Ph.D., Department of Physics of Materials Abstract: Ti15Mo alloy in a metastable β solution treated condition was processed by high pressure torsion (HPT) and equal channel angular pressing (ECAP). The microstructure after HPT is severely deformed and ultra-fine grained, while ECAP deformation results in rather coarse-grained structure with shear bands containing high density of lattice defects. Two types of thermal treatments - isothermal annealing and linear heating - were carried out for the solution treated condition and both deformed materials. Wide spectrum of experimental techniques was employed to elucidate the differences in phase transformations, especially in α phase precipitation, occurring in deformed and non-deformed material upon thermal treatment. It was shown that the α phase precipitation is accelerated in the deformed materials due to a high density of lattice defects, which provide a dense net of preferred sites for nucleation and also fast diffusion paths necessary for accelerated growth. The enhanced precipitation of the α phase in deformed materials also affects the stability of the ω...

Mechanické a fyzikální vlastnosti hořčíkových slitin připravených metodou rotačního kování / Mechanical and physical properties of magnesium alloys prepared by rotary swaging

Škraban, Tomáš

January 2020

in english For their positive influence on mechanical and physical properties of the material, methods of severe plastic deformation are popular for quite some time today. Rotary swaging is one of them. With its simplicity and productivity, it has the potential for industrial use. It is a radial swaging of rods or tubes, which results in decreasing of their diameter. Influence of this method is researched on extruded rods made of magnesium alloy AZ31. Experiments are made on five samples of different degree of swaging (different diameter). This allows to research gradual evolution of properties during the swaging. Results show significant positive influence on grain size (and microstructure in general) of originally extruded rod. During swaging there is an evolution of material texture and increase in strength.

Hochumgeformte Leichtmetallverbundwerkstoffe und deren festigkeitsbestimmende Faktoren

Marr, Tom

29 January 2014

Da in der Natur die Festigkeit der Stoffe bzw. Werkstoffe mit deren Massendichte korreliert [1], bieten sich dem Werkstoffingenieur zwei Möglichkeiten das genannte Ziel zu erreichen: Entweder er reduziert die effektive Dichte bereits sehr fester Werkstoffe durch konstruktive bzw. geometrische Optimierungen, oder es gelingt sehr leichte Werkstoffe mit deutlich gesteigerter Festigkeit herzustellen. Die erstgenannte Verfahrensweise stellt zu großen Teilen ein konstruktives bzw. fertigungstechnisches Problem dar. Von werkstoffwissenschaftlichem Interesse ist deshalb nur die zweite Möglichkeit. Dabei sollen sämtliche derzeit bekannte festigkeitssteigernde Faktoren und möglicherweise auch deren Synergien genutzt werden um einen hochfesten Leichtbauwerkstoff herzustellen. Dazu muss gleichzeitig ein neuartiges Hochumformverfahren für Leichtmetallverbundwerkstoffe erarbeitet werden, das diesen Anforderungen entspricht und eine dafür geeignete Werkstoffkombination gefunden werden. Konventionelle Verfahren zur Hochumformung erlauben häufig nur unter erheblichem Mehraufwand die Verarbeitung von Verbundwerkstoffen, weshalb die Hochumformung von Leichtmetallverbundwerkstoffen zur Festigkeitssteigerung in der Literatur praktisch keine Rolle spielt. Deshalb soll in dieser Arbeit das Umformverfahren Rundkneten zur Anwendung kommen, das die Hochumformung auch sehr heterogener Werkstoffe erlaubt. Darüber hinaus wird eine zusätzliche positive Wirkung auf die Festigkeit durch eingebaute Grenzflächen auf den Gesamtverbund erwartet. Wie sich im Laufe der Arbeit heraus stellte, eignet sich das verwendete Verfahren nicht ausschließlich zur Festigkeitssteigerung von Verbundwerkstoffen. Durch die sehr regelmäßige und fraktale Anordnung der Komponenten im Gesamtverbund ergaben sich auch einige Anknüpfungspunkte, die weit über die Eignung im Sinne eines Leichtbauwerkstoffes hinaus gehen. Aus diesem Grund liegt der Schwerpunkt der Arbeit zwar auf der mechanischen Charakterisierung der hergestellten Verbunde, in Kapitel 6 werden aber auch weitere Nutzungsmöglichkeiten diskutiert. Die gewählte Materialkombination Titan-Aluminium ist als Beispiel zu verstehen. Prinzipiell ist das vorgestellte Verfahren auf viele weitere Materialkombinationen anwendbar, solange grundlegende umformtechnische Regeln beachtet werden. [1] Ashby, M. F.: Materials Selection in Mechanical Design. Heidelberg: Spektrum Akademischer Verlag, 2006. 648 S.

info:eu-repo/classification/ddc/620

ddc:620

Development of High-Performance Aluminum Conductors: A Study of Additive and Process Influence on Electrical Performance

Nittala, Aditya

24 May 2022

No description available.

Materials Science

Mechanical Engineering

aluminum

graphene

electrical conductivity

temperature coefficient of resistance

TCR

AA1100

AA3003

AA6101

aluminum graphene composites

severe plastic deformation

hot extrusion

shear assisted processing and extrusion

Studium mikrostruktury a mechanických vlastností jemnozrnných hořčíkových slitin připravených intenzivní plastickou deformací / Microstructure and mechanical properties study of the finegrained magnesium alloys processed by severe plastic deformation

Šašek, Stanislav

January 2021

Two magnesium alloys (Mg-4Y-4Gd-2Ca and Mg-2Y-2Gd-1Ca) with high ignition tem- perature were successfully processed by extrusion. Mg-2Y-2Gd-1Ca alloy was addition- ally processed by equal channel angular pressing (ECAP) to achieve ultrafine-grained microstructure. The effect of extrusion parameters on fraction of recrystallized grains, grain size, and texture was revealed by EBSD analysis. The presence of Mg2Ca, REH2 and Mg5RE secondary phases was proven by SEM and TEM. Microstructural condition including distribution and morphology of secondary phase par- ticles directly affected the mechanical properties. Yield tensile stress exceeding 200 MPa was achieved in each condition. Large non-recrystallized grains with strong {10̄10} tex- ture resulted in a significant anisotropy in mechanical properties. Processing by ECAP led to a homogeneous microstructure with a mean grain size below 1 µm. ECAP condition showed superior mechanical properties with a low anisotropy. The developed and analysed microstructural condition resulted in favourable mechanical properties. The studied alloys are therefore promising for the application in aerospace industry. 1