Micromechanical Modeling of the Elasto-Viscoplastic Behavior and Incompatibility Stresses of β-Ti Alloys

Near β titanium alloys can now compete with quasi-α or α/β titanium alloys for airframe forging applications. The body-centered cubic β-phase can represent up to 40% of the volume. However, the way that its elastic anisotropy impacts the mechanical behavior remains an open question. In the present work, an advanced elasto-viscoplastic self-consistent model is used to investigate the tensile behavior at different applied strain rates of a fully β-phase Ti alloy taken as a model material. The model considers crystalline anisotropic elasticity and plasticity. It is first shown that two sets of elastic constants taken from the literature can be used to well reproduce the experimental elasto-viscoplastic transition, but lead to scattered mechanical behaviors at the grain scale. Incompatibility stresses and strains are found to increase in magnitude with the elastic anisotropy factor. The highest local stresses are obtained toward the end of the elastic regime for grains oriented with their <111> direction parallel to the tensile axis. Finally, as a major result, it is shown that the elastic anisotropy of the β-phase can affect the distribution of slip activities. In contrast with the isotropic elastic case, it is predicted that {112} <111> slip systems become predominant at the onset of plastic deformation when elastic anisotropy is considered in the micromechanical model.

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Micromechanical modeling of architected piezoelectric foam with simplified boundary conditions for hydrophone applications

Journal of Intelligent Material Systems and Structures ◽

10.1177/1045389x20983912 ◽

2021 ◽

pp. 1045389X2098391

Author(s):

Kamran A Khan ◽

Hamad K Alarafati ◽

Muhammad Ali Khan

Keyword(s):

Boundary Conditions ◽

Elastic Anisotropy ◽

Mixed Boundary ◽

Piezoelectric Materials ◽

Micromechanical Model ◽

Mixed Boundary Conditions ◽

Analytical Models ◽

Micromechanical Modeling ◽

Generation Process ◽

Porous Microstructures

Architected piezoelectric materials with controlled porosity are of interest for applications such as hydrophones, miniature accelerometers, vibratory sensors, and contact microphones. Current analytical modeling approach cannot be readily applied to design architected periodic piezoelectric foams with tunable properties while exhibiting elastic anisotropy and piezoelectric activity. This study presents micromechanical-finite element (FE) models to characterize the electromechanical properties of architected piezoelectric foams. The microstructure with zero-dimension (3-0 foam, spherical porosity) and one-dimensional (3-1 foam, cylindrical porosity) connectivity were considered to analyze the effect of porosity connectivity on the performance of piezoelectric foam. 3D FE models of the 3-0 and 3-1 foams were developed and using the intrinsic symmetry of porous structures simplified mixed boundary conditions (MBCs) equivalent to periodic boundary conditions (PBC) were proposed. The proposed approach is simple and eliminates the need of tedious mesh generation process on opposite boundary faces on the micromechanical model of porous microstructures with PBCs. The results obtained from the proposed micromechanics-FE models were compared with those obtained by means of the analytical models based on micromechanics theories, and FE models with PBCs reported in the literature for both 3-0 and 3-1 type foams. An excellent agreement was observed. The computed effective elastic, piezoelectric and dielectric properties and corresponding figure of merit (FOM) revealed that piezoelectric foams with 3-0 connectivity exhibit enhanced hydrostatic FOM as compared to piezoelectric foams with 3-1 connectivity. It is concluded that spherical porosity is more suitable to hydrophone applications.

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Micromechanical Modeling of Viscoplastic Behavior of Laminated Polymer Composites With Thermal Residual Stress Effect

Journal of Engineering Materials and Technology ◽

10.1115/1.4033070 ◽

2016 ◽

Vol 138 (3) ◽

Cited By ~ 9

Author(s):

Qiang Chen ◽

Xuefeng Chen ◽

Zhi Zhai ◽

Xiaojun Zhu ◽

Zhibo Yang

Keyword(s):

Residual Stress ◽

Polymer Matrix Composites ◽

Micromechanical Model ◽

Thermal Residual Stress ◽

Micromechanical Modeling ◽

Multiscale Approach ◽

Stress Effect ◽

Accurate Analysis ◽

Rate Dependent ◽

Residual Stress Effect

In this paper, a multiscale approach has been developed for investigating the rate-dependent viscoplastic behavior of polymer matrix composites (PMCs) with thermal residual stress effect. The finite-volume direct averaging micromechanics (FVDAM), which effectively predicts nonlinear response of unidirectional fiber reinforced composites, is incorporated with improved Bodner–Partom model to describe the viscoplastic behavior of PMCs. The new micromechanical model is then implemented into the classical laminate theory, enabling efficient and accurate analysis of multidirectional PMCs. The proposed multiscale theory not only predicts effective thermomechanical viscoplastic response of PMCs but also provides local fluctuations of fields within composite microstructures. The deformation behaviors of several unidirectional and multidirectional PMCs with various fiber configurations are extensively simulated at different strain rates, which show a good agreement with the experimental data found from the literature. Influence of thermal residual stress on the viscoplastic behavior of PMCs is closely related to fiber orientation. In addition, the thermal residual stress effect cannot be neglected in order to accurately describe the rate-dependent viscoplastic behavior of PMCs.

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Effect of Porosity on Mechanical Properties of 3D Printed Polymers: Experiments and Micromechanical Modeling Based on X-Ray Computed Tomography Analysis

Polymers ◽

10.3390/polym11071154 ◽

2019 ◽

Vol 11 (7) ◽

pp. 1154 ◽

Cited By ~ 27

Author(s):

Wang ◽

Zhao ◽

Fuh ◽

Lee

Keyword(s):

Computed Tomography ◽

Mechanical Properties ◽

Additive Manufacturing ◽

Fused Deposition Modeling ◽

Micromechanical Model ◽

Micromechanical Modeling ◽

X Ray ◽

Fused Deposition ◽

3D Printed ◽

X Ray Computed

Additive manufacturing (commonly known as 3D printing) is defined as a family of technologies that deposit and consolidate materials to create a 3D object as opposed to subtractive manufacturing methodologies. Fused deposition modeling (FDM), one of the most popular additive manufacturing techniques, has demonstrated extensive applications in various industries such as medical prosthetics, automotive, and aeronautics. As a thermal process, FDM may introduce internal voids and pores into the fabricated thermoplastics, giving rise to potential reduction on the mechanical properties. This paper aims to investigate the effects of the microscopic pores on the mechanical properties of material fabricated by the FDM process via experiments and micromechanical modeling. More specifically, the three-dimensional microscopic details of the internal pores, such as size, shape, density, and spatial location were quantitatively characterized by X-ray computed tomography (XCT) and, subsequently, experiments were conducted to characterize the mechanical properties of the material. Based on the microscopic details of the pores characterized by XCT, a micromechanical model was proposed to predict the mechanical properties of the material as a function of the porosity (ratio of total volume of the pores over total volume of the material). The prediction results of the mechanical properties were found to be in agreement with the experimental data as well as the existing works. The proposed micromechanical model allows the future designers to predict the elastic properties of the 3D printed material based on the porosity from XCT results. This provides a possibility of saving the experimental cost on destructive testing.

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The Crystal Structure of the β’-Phase Including Ag in Al-Mg-Si-Ag Alloy

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.409.67 ◽

2011 ◽

Vol 409 ◽

pp. 67-70 ◽

Cited By ~ 3

Author(s):

Junya Nakamura ◽

Kenji Matsuda ◽

Tatsuo Sato ◽

Calin D. Marioara ◽

Sigmund J. Andersen ◽

...

Keyword(s):

Electron Microscopy ◽

Transmission Electron Microscopy ◽

Dark Field ◽

Unit Cell ◽

Atomic Column ◽

Direction Parallel ◽

Ag Addition ◽

Domain Structures ◽

Β Phase ◽

Transmission Electron

In the present work, b’ phase in alloys Al -1.0 mass% Mg2Si -0.5 mass% Ag (Ag-addition) and Al -1.0 mass% Mg2Si (base) was investigated by high resolution transmission electron microscopy (HRTEM) and selected area electron diffraction (SAED) to understand the effect of Ag addition. The b’ phase is rod-shape with the longest direction parallel to <001>Al. HRTEM images and SAED patterns obtained along the direction were similar for the b’ phase in both alloys. The unit cell of b’-phase in Ag-addition alloy is hexagonal with the same c-axis dimension as the Ag-free b’, but shorter a-axis. Ag was found in the composition of the rod-shaped precipitates in Ag-addition alloy by energy dispersive X-ray spectroscopy (EDS). In addition, the distribution of Ag was investigated by energy filtered mapping and high annular angular dark field scanning transmission electron microscopy (HAADF-STEM). The Ag-containing atomic column was observed in every b’ unit cell, and the unit cell symmetry is slightly changed as compared with the Ag-free b’. The Ag-containing b’ rods have complicated domain structures. The interfaces of these particles are enriched with Ag atoms that occupy the lattice positions in the Al matrix. The occupancy of the Ag-containing atomic columns seem to vary both inside particles, as well as at the interfaces.

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Surface Effect in a Metastable β Ti-Nb-Sn Alloy

Materials Science Forum ◽

10.4028/www.scientific.net/msf.1035.562 ◽

2021 ◽

Vol 1035 ◽

pp. 562-567

Author(s):

Li Chun Qi ◽

Wen Xiao Qu ◽

Yong Qi Zhu ◽

Qing Liu

Keyword(s):

Titanium Alloys ◽

Orientation Relationship ◽

Surface Effect ◽

Phase Region ◽

Martensite Phase ◽

The Other ◽

Β Phase ◽

Ω Phase

The phase compositions of surface and interior in Ti-32Nb-4Sn metastable b alloy were investigated. It was found that this alloy exhibits surface effect significantly different from the effects reported in Ti-10V-2Fe-3Al, Ti-22Nb-9Zr and the other titanium alloys. The surface of Ti-32Nb-4Sn specimen quenched from single b phase region was characterized by dominant b phase and a few of α″ and ω phase. While in the interior of the alloy, a large amount of α² martensite phase was observed in addition to b phase The orientation relationship between the α″ martensite and β phase is (110)β∥(002)α″, (020)β∥(022)α″ and [001]β∥[100]α″.

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Influence of Phases Stability on the Hydrogen Diffusion Coefficient in Ti-6Al-4V

Materials Science Forum ◽

10.4028/www.scientific.net/msf.986.33 ◽

2020 ◽

Vol 986 ◽

pp. 33-40

Author(s):

Mohammed Kasim Mohsun

Keyword(s):

Heat Treatment ◽

Diffusion Coefficient ◽

Titanium Alloys ◽

Hydrogen Diffusion ◽

Volume Fraction ◽

Substantial Effect ◽

Diffusion Annealing ◽

Hydrogen Treatment ◽

Β Phase ◽

Hydrogen Diffusion Coefficient

For a unique microstructure creation, thermo-hydrogen treatment (THT), using hydrogen as a temporary alloying element within the heat treatment, is applied. This advanced heat treatment requires reliable data about the hydrogen diffusion coefficient (DH) for understanding diffusion kinetics and its effect on the mechanical behavior of the resulted phases. In this research, three different homogeneous microstructures were established for the investigation using different homogenization parameters. After that, the concentration of hydrogen, charged in the half-length of thin titanium rods via electrochemical hydrogenation, is specified. Then, a diffusion annealing heat treatment was carried out at different temperatures, leading to hydrogen diffusion in the hydrogenated specimens. Furthermore, DH was systematically determined using two methods including the explicit finite difference method (EFDM) and Matano technique (MT). For this purpose, Abaqus software was employed for modeling the hydrogen gradient established in the specimens. Additionally, scanning electron microscopy (SEM) was used for the microstructure examination in order to specify the influence of different hydrogen concentrations on the hydrogenated specimens. The experimental outcomes reveal a substantial effect of the β phase stability and grains sizes of the β and α phases on the hydrogen diffusion. Correspondingly, the results confirm that DH was independent of the hydrogen concentration, and obeys an Arrhenius-type temperature dependence. Furthermore, hydrogen diffusion in the α+β titanium alloys Ti-6Al-4V was slower in comparison to the hydrogen diffusion in the metastable β titanium alloys Ti-10V-2Fe-3Al. In conclusion, it was observed that DH is influenced by the previously performed heat treatments that determine the resulted microstructure types, and a slight influence of the volume fraction of the α phase on DH was observed as well.

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An Overview on the Tribological Performance of Titanium Alloys with Surface Modifications for Biomedical Applications

Lubricants ◽

10.3390/lubricants7080065 ◽

2019 ◽

Vol 7 (8) ◽

pp. 65 ◽

Cited By ~ 2

Author(s):

Kaur ◽

Ghadirinejad ◽

Oskouei

Keyword(s):

Wear Resistance ◽

Corrosion Resistance ◽

Titanium Alloys ◽

Weight Ratio ◽

High Strength ◽

Surface Modifications ◽

Tribological Performance ◽

The Body ◽

High Wear Resistance ◽

Medical Implants

The need for metallic biomaterials will always remain high with their growing demand in joint replacement in the aging population. This creates need for the market and researchers to focus on the development and advancement of the biometals. Desirable characteristics such as excellent biocompatibility, high strength, comparable elastic modulus with bones, good corrosion resistance, and high wear resistance are the significant issues to address for medical implants, particularly load-bearing orthopedic implants. The widespread use of titanium alloys in biomedical implants create a big demand to identify and assess the behavior and performance of these alloys when used in the human body. Being the most commonly used metal alloy in the fabrication of medical implants, mainly because of its good biocompatibility and corrosion resistance together with its high strength to weight ratio, the tribological behavior of these alloys have always been an important subject for study. Titanium alloys with improved wear resistance will of course enhance the longevity of implants in the body. In this paper, tribological performance of titanium alloys (medical grades) is reviewed. Various methods of surface modifications employed for titanium alloys are also discussed in the context of wear behavior.

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Tool wear mechanisms in machining of three titanium alloys with increasing β-phase fraction

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/0954405414522796 ◽

2014 ◽

Vol 228 (9) ◽

pp. 1090-1103 ◽

Cited By ~ 8

Author(s):

Shashikant Joshi ◽

Pravin Pawar ◽

Asim Tewari ◽

Suhas S Joshi

Keyword(s):

Tool Wear ◽

Titanium Alloys ◽

Wear Mechanisms ◽

Phase Fraction ◽

Β Phase ◽

Tool Wear Mechanisms

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Determining the orientation of parent β grain from one α variant in titanium alloys

Journal of Applied Crystallography ◽

10.1107/s1600576718008592 ◽

2018 ◽

Vol 51 (4) ◽

pp. 1125-1132 ◽

Cited By ~ 5

Author(s):

Z. B. Zhao ◽

Q. J. Wang ◽

H. Wang ◽

J. R. Liu ◽

R. Yang

Keyword(s):

Titanium Alloys ◽

Habit Plane ◽

Electron Backscatter Diffraction ◽

Three Dimensional ◽

Dimensional Structure ◽

Plane Normal ◽

Β Phase ◽

Microstructural Morphology ◽

Backscatter Diffraction ◽

The Relationship

The relationship between the crystallographic orientation and habit plane normal of transformed α laths in titanium alloys is discussed according to the Burgers orientation relationship and the three-dimensional structure of the α lath. A new method (orientation–trace method) is developed to determine the orientation of the parent β phase using the orientation of the α lath, which was measured by electron backscatter diffraction, and the microstructural morphology of that α variant. This approach is validated in a near-α titanium alloy. Moreover, the habit plane normal direction of the transformed α lath can be obtained from the crystallographic orientations of the α lath itself and its parent β grain. The verification and the corresponding discussion show the reliability of this approach.

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