Your search keyword '"Danielle Cristina Camilo Magalhães"' showing total 12 results

1. Flow behavior and fracture of Al−Mg−Si alloy at cryogenic temperatures

Author

Andrea Madeira Kliauga, Vitor Luiz Sordi, and Danielle Cristina Camilo Magalhães

Subjects

010302 applied physics, Toughness, Materials science, Alloy, Metals and Alloys, 02 engineering and technology, Strain rate, engineering.material, 021001 nanoscience & nanotechnology, Geotechnical Engineering and Engineering Geology, Condensed Matter Physics, 01 natural sciences, Dimple, 0103 physical sciences, Ultimate tensile strength, Materials Chemistry, Fracture (geology), engineering, Elongation, Composite material, 0210 nano-technology, Dynamic strain aging

Abstract

The tensile and fracture behaviors of AA6061 alloy were investigated in order to provide quantitative data about this alloy at cryogenic temperatures. Specimens of AA6061 alloy were solution heat treated before tensile tests at 298, 173 and 77 K and tested at strain rates in the range from 0.1 to 0.0001 s−1. The results indicate the suppression of the Portevin−Le Chatelier (PLC) effect and dynamic strain aging (DSA) at 77 K. In contrast, at 298 K, a remarkable serrated flow, characteristic of the PLC effect, is observed. Furthermore, the tensile behavior at 77 K, compared with that observed at 173 and 298 K, shows a simultaneous increase in strength, uniform elongation, modulus of toughness, strain-hardening exponent and strain rate sensitivity, which is related to a decrease in the dynamic recovery rate at low temperature. These responses are reflected on the fracture morphology, since the dimple size decreases at 77 K, while the area covered by dimples increases. Comparisons of the Johnson−Cook model show that a good agreement can be obtained for tests at 173 and 77 K, in which DSA is suppressed.

Published

2021

2. Numerical simulation of cryogenic cyclic closed-die forging of Cu: hardness distribution, strain maps and microstructural stability

Author

Vitor Luiz Sordi, Danielle Cristina Camilo Magalhães, Maurizio Ferrante, Andrea Madeira Kliauga, Allana Lauren Pratti, and José Benaque Rubert

Subjects

lcsh:TN1-997, 010302 applied physics, Materials science, Computer simulation, Metals and Alloys, 02 engineering and technology, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Forging, Finite element method, Surfaces, Coatings and Films, Biomaterials, Condensed Matter::Materials Science, Transmission electron microscopy, 0103 physical sciences, Homogeneity (physics), Vickers hardness test, Ceramics and Composites, Composite material, Deformation (engineering), 0210 nano-technology, lcsh:Mining engineering. Metallurgy

Abstract

Cyclic closed-die forging (CCDF) appears to be an easy to operate deformation process, which imposes high levels of strain, even on difficult-to-deform materials. However, despite said potential advantages, the CCDF at cryogenic temperatures has not yet been investigated. Copper samples with dimensions of 10 mm × 10 mm × 20 mm were processed in up to six passes with interpass rotation, enabling the samples to return approximately to their initial dimensions after each pass. The intensity and homogeneity of plastic deformation was evaluated by mapping the Vickers hardness over the entire surface of the sample, and the resulting maps were compared with the strain and stress distribution estimated by FEM numerical simulation. The deformed microstructures were examined by optical and transmission electron microscopy. Cryogenic CCDF has proved to be effective in suppressing the recovery mechanisms of Cu samples, resulting in finer and more heterogeneous strains distribution than those deformed at room temperature. However, long-term observations by TEM have shown that these microstructures are inherently unstable, so that hardness decreases 50% after two years. Keywords: Copper, Cyclic closed-die forging, Numerical simulation, Cryogenic deformation, Microstructural stability

Published

2019

3. The Effect of Asymmetry on Strain Distribution, Microstructure and Texture of Multilayer Aluminum Composites Formed by Roll-Bonding

Author

Osvaldo Mitsuyuki Cintho, J. B. Rubert, Danielle Cristina Camilo Magalhães, Andrea Madeira Kliauga, and Vitor Luiz Sordi

Subjects

010302 applied physics, aluminum alloys, Materials science, lcsh:T, Materials Science (miscellaneous), Composite number, 02 engineering and technology, Flow stress, 021001 nanoscience & nanotechnology, Microstructure, strain distribution analysis, lcsh:Technology, 01 natural sciences, Roll bonding, Accumulative roll bonding, accumulative roll-bonding, 0103 physical sciences, Shear stress, Composite material, 0210 nano-technology, texture, asymmetry, Electron backscatter diffraction, Necking

Abstract

AA1050/AA7050 multilayered composite sheets with a proportion of 1:1 were produced by Accumulative Roll Bonding (ARB) and Asymmetric Accumulative Roll-Bonding (AARB), using up to 8 cycles and intermediate annealing treatments at 500°C. The main purpose was to produce one composite sheet with high strength and moderate ductility, taking advantage of the mechanical properties of these aluminum alloys. Microstructural features were investigated in order to evaluate the potential to achieve a refined microstructure and the development of structural patterns. The strain distributions as a function of friction and asymmetry were simulated by finite element analysis. Texture was evaluated by X-ray diffraction and electron backscatter diffraction. A continuous layer pattern was obtained by ARB, up to 6 cycles but after 8 cycles shear bands fragmented the harder layers. In the early AARB cycles, the bending and necking of the AA7050 layers yielded a wavy-pattern. The shear strain in the AARB process has a strong influence on achieving a wavy-pattern, more than the flow stress differences of the alloys in the composite. Shear texture increased with the degree of the layers’ discontinuity. Different sources of shear contributed to the formation of microstructural patterns: the shear due to asymmetry, the frictional shear at roll-sheet interface and at the central layer interface and the shear at the layers’ interface. In addition, the ARB process achieved a better interfacial adhesion at the middle interface and higher strength and elongation than the AARB process.

Published

2020

4. Asymmetric cryorolling of AA6061 Al alloy: Strain distribution, texture and age hardening behavior

Author

Danielle Cristina Camilo Magalhães, Andrea Madeira Kliauga, Vitor Luiz Sordi, and Maurizio Ferrante

Subjects

010302 applied physics, Materials science, Mechanical Engineering, Alloy, Recrystallization (metallurgy), 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Condensed Matter::Materials Science, Precipitation hardening, Mechanics of Materials, 0103 physical sciences, Ultimate tensile strength, engineering, Shear stress, General Materials Science, Deformation bands, Texture (crystalline), Composite material, 0210 nano-technology, Intensity (heat transfer)

Abstract

Asymmetric rolling combines direct compression and shear strain imposed by working rolls with different diameters or different rotations speeds. Processing at cryogenic temperatures may partially suppress dynamic recovery mechanisms, modifying the work-hardening rate and increasing the amount of accumulated strain. In this work, samples of AA6061 Al alloy were processed by asymmetric and conventional rolling, at room and cryogenic temperatures. The effects of asymmetric cryorolling were analyzed in terms of strain distribution, grain refinement, hardness, tensile strength and crystallographic texture after post-deformation heat treatments. Artificial aging after conventional rolling at room temperature proved to be more effective in increasing hardness and tensile strength, while the same heat treatment after asymmetric rolling at cryogenic temperature increased uniform elongation and reduced texture intensity. This behavior was associated with recovery and recrystallization phenomena after aging, which cause small dislocation-free grains to be generated inside deformation bands. This was observed directly by TEM and indirectly by texture analysis.

Published

2018

5. Plastic deformation of FCC alloys at cryogenic temperature: the effect of stacking-fault energy on microstructure and tensile behaviour

Author

Maurizio Ferrante, Danielle Cristina Camilo Magalhães, Vitor Luiz Sordi, and Andrea Madeira Kliauga

Subjects

010302 applied physics, Materials science, Mechanical Engineering, Alloy, Metallurgy, 02 engineering and technology, Slip (materials science), engineering.material, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Mechanics of Materials, Stacking-fault energy, 0103 physical sciences, Ultimate tensile strength, engineering, General Materials Science, Severe plastic deformation, Deformation (engineering), 0210 nano-technology, Crystal twinning

Abstract

The deformation behaviour of metals and alloys is significantly affected by both stacking-fault energy and processing temperature. By lowering the former, deformation twinning is favoured over dislocation slip, whilst cryogenic processing partially suppresses dynamic recovery. Three materials having different stacking-fault energies, that is, Al AA1050 (high), pure Cu (medium) and Cu–15Zn alloy (low) were rolled at room (RTR) and at cryogenic (CR) temperatures up to a true strain equal to 1.5. Annealed coarse-grained samples were tested in tension at room and cryogenic temperatures. The processed samples were characterized by optical and transmission electron microscopy, hardness measurements and room-temperature tensile tests. CR increases the tensile strength with respect to RTR for the three materials; elongation to failure is decreased for AA1050, whilst for Cu and Cu–15Zn the CR effectively increases the ductility. Cu–15Zn sample after CR exhibits a microstructure relatively heterogeneous, suggesting static recrystallization events in the temperature excursion from 77 to 298 K. Finally, it was concluded that cryogenic deformation increases strength, whilst low SFE increases the ability to absorb plastic deformation, an effect strongly increased at cryogenic temperatures. The present investigation gives some basis for the development of cryogenic severe plastic deformation processes.

Published

2017

6. Evolution of dislocation and stacking-fault densities for a Cu-0.7Cr-0.07Zr alloy during cryogenic tensile test: An in-situ synchrotron X-ray diffraction analysis

Author

Osvaldo Mitsuyuki Cintho, M.T. Izumi, Vitor Luiz Sordi, Andrea Madeira Kliauga, Pedro Henrique Fernandes Oliveira, and Danielle Cristina Camilo Magalhães

Subjects

010302 applied physics, Materials science, Mechanical Engineering, Twip, 02 engineering and technology, Flow stress, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Deformation mechanism, Mechanics of Materials, 0103 physical sciences, General Materials Science, Composite material, Deformation (engineering), Dislocation, 0210 nano-technology, Ductility, Tensile testing, Necking

Abstract

Processing at cryogenic temperatures is one of the ways of improving mechanical properties of copper alloys. However, such processing routes may result in unstable microstructures, which make it difficult to understand the deformation mechanisms controlling microstructure evolution during cryogenic deformation. In this study, the microstructure evolution of a Cu-0.7Cr-0.07Zr alloy was analyzed as a function of the flow behavior during tensile tests performed at 123 K and 298 K, through in-situ X-ray diffraction (XRD) experiments in a synchrotron source. The tensile behavior was analyzed in terms of the dynamic recovery rate using the Kocks-Mecking model, while the evolution of stacking-fault density, dislocation density and crystallite size during the tests was estimated by the modified Williamson-Hall method. Solution-treated and peak-aged conditions were tested to assess the influence of particles distribution. At 298 K, the strain-hardening rate was controlled by dislocation glide and the flow stress was affected mainly by particle strengthening. At 123 K, a simultaneous increase in strength and ductility was attributed to the twinning induced plasticity (TWIP) effect, promoted by precipitate interfaces acting as nuclei for stacking-faults, thus delaying necking and increasing the plasticity. Based on the evolution of dislocation and stacking-fault densities with increasing plastic strain, it was concluded that, at 123 K, mechanical twinning predominated at strain levels below 0.15, mainly for aged conditions, while dislocation glide between twin boundaries, and its accumulation, started after TWIP mechanism reached its saturation.

Published

2021

7. The role of shear strain during Accumulative Roll-Bonding of multilayered composite sheets: Pattern formation, microstructure and texture evolution

Author

Danielle Cristina Camilo Magalhães, Osvaldo Mitsuyuki Cintho, José Benaque Rubert, Andrea Madeira Kliauga, and Vitor Luiz Sordi

Subjects

010302 applied physics, Materials science, Waviness, Mechanical Engineering, Composite number, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, 01 natural sciences, Accumulative roll bonding, Grain growth, Shear (geology), Mechanics of Materials, 0103 physical sciences, Shear stress, General Materials Science, Composite material, 0210 nano-technology, Dissolution

Abstract

The present study was designed to determine the effect of shear strain on the macro- and microstructure and texture evolution in the AA1050/AA7050 Al multilayered composite sheets. The sheets were processed by Accumulative Roll-Bonding (ARB) and Asymmetric ARB (AARB) at 450 °C and 500 °C. The shear strain in the AARB process has a remarkable influence in achieving a macrostructural wavy-pattern, more than the flow behavior of the materials. For ARB, a flat-pattern with slight waviness was produced mainly due to flow incompatibility, as estimated by finite element simulation and observed by macrostructural analysis. In addition, friction at the surfaces and at the interfaces, and the strain distribution, together with the coarsening or dissolution of precipitates in the AA7050 layers have also influenced the shear banding and microstructure evolution in the sheets. A reduction in the texture intensity by AARB was observed. The grain refinement in the AA1050 layers was controlled by continuous dynamic recrystallization and static recovery during the thermo-mechanical cycles for both processing routes. The AA7050 layers presented a more complex grain refinement behavior that was influenced by dissolution of the η- and η′-phases, which was observed for both temperatures in the ARB. In contrast, the shear strain accelerated this dissolution kinetics and grain growth in the AA7050 layers of sheets processed by AARB.

Published

2020

8. Failure analysis of a titanium Coriolis mass flow meter: A case of hydrogen embrittlement

Author

Danielle Cristina Camilo Magalhães, G.S. Vacchi, I.G.R. Santos, Cristie Luis Kugelmeier, Carlos Alberto Della Rovere, R. Silva, and G.R. Campesan

Subjects

Materials science, Hydrogen, Mass flow meter, Hydride, Metallurgy, General Engineering, Titanium alloy, chemistry.chemical_element, 020101 civil engineering, 02 engineering and technology, Flow measurement, 0201 civil engineering, 020303 mechanical engineering & transports, 0203 mechanical engineering, chemistry, General Materials Science, Embrittlement, Hydrogen embrittlement, Titanium

Abstract

Titanium alloys are suitable for construction of the Coriolis mass flow meter due to their high strength to weight ratio, high thermal stability and excellent corrosion resistance. However, environments with high hydrogen content can be very harmful to titanium and its alloys, since this element may cause hydride formation and leads to hydrogen embrittlement. In this context, this paper reports on the analysis of a grade 9 titanium tube of a mass flow meter, which was performed using cyclohexanol (68%), water (2%) and Raney nickel catalyst (30%). After the active period, the flow meter was deactivated and left on standby for one year, and then reassembled on a production line, whereupon it failed prematurely. The failure was analyzed by OM, SEM, EDS, Vickers microhardness and XRD, whose results indicated that the cause was hydride embrittlement due to the chemical interaction between Raney nickel and the titanium tube during the deactivated period.

Published

2020

9. Microstructure evolution of multilayered composite sheets of AA1050/AA7050 Al alloys produced by Asymmetric Accumulative Roll-Bonding

Author

Vitor Luiz Sordi, Danielle Cristina Camilo Magalhães, and Andrea Madeira Kliauga

Subjects

010302 applied physics, Materials science, Mechanical Engineering, Composite number, Pattern formation, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, 01 natural sciences, Accumulative roll bonding, Mechanics of Materials, 0103 physical sciences, Shear stress, Hardening (metallurgy), General Materials Science, Composite material, 0210 nano-technology, Diffusion bonding, Necking

Abstract

In this investigation, AA1050/AA7050 multilayered composite sheets were produced by Asymmetric Accumulative Roll-Bonding (AARB) in order to evaluate microstructure evolution and the interfacial zone. The asymmetric rolls introduced an extra component of shear strain, which provided conditions for necking and/or rupture in the AA7050 layers during processing at 500 °C yielding a wavy-pattern. On the other hand, at 450 °C the continuity of layers was maintained. Thus, AARB parameters can be controlled to produce wavy- or flat-pattern structures in multilayered composites. The hardening of the AA7050 layers after processing at 450 °C was caused by overaging and grain refinement, whereas at 500 °C it was due to the precipitation of η’ and η-phases. The hardening of the AA1050 layers was attributed to grain refinement achieved from continuous dynamic recrystallization. In addition, diffusion bonding has a significant role in the formation of AA1050/AA7050 interfaces by the AARB process, as observed in the interdiffusion zone. Taken together, these findings provide insights into structural pattern formation and microstructural control in Al-based multilayered composites using the AARB process.

Published

2020

10. Microstructure, mechanical behavior and stress corrosion cracking susceptibility in ultrafine-grained Al-Cu alloy

Author

Danielle Cristina Camilo Magalhães, Diogo Pedrino Braga, Andrea Madeira Kliauga, Vitor Luiz Sordi, and Carlos Alberto Della Rovere

Subjects

010302 applied physics, Materials science, Mechanical Engineering, Alloy, chemistry.chemical_element, 02 engineering and technology, Strain rate, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, 01 natural sciences, Grain size, Corrosion, chemistry, Mechanics of Materials, Aluminium, 0103 physical sciences, Ultimate tensile strength, engineering, General Materials Science, Stress corrosion cracking, Composite material, 0210 nano-technology

Abstract

Equal-channel angular pressing (ECAP) is capable of improving the mechanical properties of many aluminum alloys by means of intense grain refinement. Meanwhile, a general relationship between grain size and stress corrosion cracking (SCC) resistance is not yet established, since the introduction of microstructural heterogeneities affects, in many ways, the localized corrosion susceptibility. This work evaluates the simultaneous impact of ECAP processing on microstructure, mechanical strength and SCC resistance of an Al-4wt.%Cu alloy, in comparison with a commercially pure aluminum. Microstructure was observed by optical and electronic microscopy, while mechanical response was evaluated by hardness measurements and tensile tests. SCC resistance was evaluated by slow strain rate tests and by constant load tests performed in an aqueous solution with 3.5 wt.% NaCl. ECAP promoted grain refinement, breakdown/redistribution of coarse secondary phase particles and contributed to reduce the local chemical heterogeneity. Consequently, mechanical properties and SCC resistance were simultaneously improved.

Published

2020

11. Microstructure, texture and interface integrity in sheets processed by Asymmetric Accumulative Roll-Bonding

Author

Danielle Cristina Camilo Magalhães, Renan Pereira de Godoi, Vitor Luiz Sordi, Raul Eduardo Bolmaro, M. Avalos, and Andrea Madeira Kliauga

Subjects

Materials science, 020502 materials, Mechanical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, Grain size, Accumulative roll bonding, 0205 materials engineering, Mechanics of Materials, Ultimate tensile strength, General Materials Science, Texture (crystalline), Composite material, Severe plastic deformation, 0210 nano-technology, Ductility, Electron backscatter diffraction

Abstract

Accumulative Roll-Bonding (ARB) and Asymmetric Rolling (AR) techniques were combined to produce ultrafine-grained aluminum sheets with the mechanical characteristics of a Severe Plastic Deformation (SPD) process. Temperature and number of bonding cycles were varied to promote grain refinement, texture randomization and high-quality sheet bonding. Finite element simulation for a single pass was performed to clarify the strain distribution differences between symmetric and asymmetric roll -bonding. The microstructure and crystallographic texture were measured by Electron Backscatter Diffraction (EBSD) and X-ray diffraction. Hardness and tensile tests characterized strain distribution and bonding efficiency. A fine grain structure with a mean grain size of 1.0 μm was achieved at 350 °C, whereas a coarser grain structure was obtained at 400 °C. The grain size and shape distribution were linked to enhancing the mechanical strength in a transversal direction. During repeated bonding cycles at both temperatures, extra shear in the interfacial region yielded favorable homogeneous strain distribution and a weak shear texture across the sheet. Rotated-cube orientation was the strongest component in both processing temperatures. To increase the interfacial strength, mainly on the last bond interface, an extra 50% reduction step was added. This improved the adhesion in the last bonding interface, and thus enhanced the ductility. These findings helped to provide a basis for determining the processing conditions for aluminum alloys.

Published

2020

12. The influence of Cryo-ECAP and aging on the microstructure and mechanical behavior of AA6061 Al alloy

Author

Danielle Cristina Camilo Magalhães, Vitor Luiz Sordi, Osvaldo Mitsuyuki Cintho, Marcio Ferreira Hupalo, Maurizio Ferrante, Carlos Alberto Della Rovere, and Andrea Madeira Kliauga

Subjects

Equiaxed crystals, Materials science, Precipitation (chemistry), 020502 materials, Mechanical Engineering, Alloy, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, Grain size, Precipitation hardening, 0205 materials engineering, Mechanics of Materials, engineering, General Materials Science, Grain boundary, Composite material, 0210 nano-technology, Ductility

Abstract

The combination of Equal-Channel Angular Pressing (ECAP) with cryogenic processing temperatures can be an efficient method to obtain very refined microstructures. However, there is a lack of research on the combination of these processes and the effects they have on microstructure and mechanical properties, particularly in precipitation hardened aluminum alloys. The present study describes the effects of cryogenic ECAP-processing and subsequent heat treatments on the microstructure and mechanical properties of AA6061 Al alloy. Samples in the solutionized state were processed by ECAP at 173 K (Cryo) and at room temperature (RT) up to an equivalent strain of 4.2. After Cryo-ECAP, the microstructure was very refined, with an average grain size close to 0.5 μm and strain concentrated within microscopic shear bands. EBSD analysis after Cryo-ECAP shows new fine equiaxed grains with a higher proportion of low-angle grain boundaries. The temperature of 173 K was effective in suppressing partially precipitation during ECAP, and made the process possible without extensive cracking. However, recovery mechanisms were not fully hindered, which undermined the strengthening effect of Cryo-ECAP. The yield stress was higher after RT-ECAP, while uniform elongation was improved by Cryo-ECAP plus T6 treatment, a result attributed to the higher fraction of low-angle grain boundaries observed in the microstructure. Finally, it was demonstrated that cryogenic processing is not in itself a guarantee of improvements in strength and ductility, in comparison with RT processing. Both recovery and precipitation processes dictated the feasibility of the process, the final microstructure and the mechanical response of the ECAP-processed AA6061 Al alloy.

Published

2019