Your search keyword '"geometrical gradient"' showing total 5 results

1. Modelling and experimental investigation of geometrically graded shape memory alloys with parallel design configuration.

Author

Shariat, Bashir S., Liu, Yinong, and Bakhtiari, Sam

Subjects

*SHAPE memory alloys, *NICKEL-titanium alloys, *SHAPE memory effect, *MARTENSITIC transformations

Abstract

The shape memory effect and pseudoelastic effect of NiTi shape memory alloys occur within respectively a narrow temperature and stress window associated with its martensitic transformation. This renders difficulty in accurate and reliable control for actuation applications using these properties. One approach to improving controllability of an actuation component is to design a geometrically graded shape memory structure to create a nonuniform transformation field within the structure. This paper presents analytical modelling and experimental evaluation of geometrically graded NiTi structures with parallel design configuration. Closed-form solutions are obtained to describe the stress-strain relationship of such structures under tensile loading conditions, which can be used as an engineering tool for optimizing shape memory performances of such components. The geometrically graded structures exhibited partial stress gradient over stress-induced transformation. A maximum stress window of 420 MPa was achieved over transformation stage, giving enlarged stress interval for shape memory actuation control. Image 1 • Closed-form stress-strain relationships were obtained for optimizing shape memory performance. • Transformation propagation in parallel design configuration was perpendicular to the loading axis. • Geometrically graded NiTi demonstrated partial stress gradient over transformation. • Widened transformation stress window for actuation application was created. [ABSTRACT FROM AUTHOR]

Published

2019

2. Nonuniform transformation behaviour of NiTi in a discrete geometrical gradient design.

Author

Shariat, Bashir S., Bakhtiari, Reza, and Liu, Yinong

Subjects

*NICKEL-titanium alloys, *PHASE transitions, *SHAPE memory alloys, *METALS, *THERMOMECHANICAL treatment, *ELASTICITY

Abstract

Abstract Shape memory alloys exhibit unique thermomechanical properties, e.g., the shape memory effect and the pseudoelasticity. By proper geometrical gradient design, these alloys can be made to exhibit different and more intricate thermomechanical behaviour to enable innovative applications. This paper reports the design of geometrically gradient NiTi and characterisation of its complex and nonuniform transformation and deformation fields. The study investigated two designs, with one using multiple pseudoelastic NiTi strips of different lengths in parallel arrangement to create a discrete geometrical gradient in the direction perpendicular to the loading axis and the other a tapered plate to give a continuous length gradient in the lateral direction for comparison with the former. The geometrically gradient structures exhibited partial stress gradient during stress-induced transformation. A maximum stress window of 520 MPa was achieved, giving an expanded stress interval for shape memory actuation control. Finite element modelling was applied to characterise the deformation behaviour of such structures under tensile loading and to reveal the complex propagation of the stress-induced transformation in such structures. Graphical abstract Image 1 Highlights • Nonuniform transformation field was created in parallel geometrical gradient design. • Geometrically graded NiTi demonstrated partial stress gradient over transformation. • Widened transformation stress window for actuation application was created. • Transformation propagation in discrete design was perpendicular to the loading axis. [ABSTRACT FROM AUTHOR]

Published

2019

3. Complex transformation field created by geometrical gradient design of NiTi shape memory alloy.

Author

Bakhtiari, Reza, Shariat, Bashir S., Motazedian, Fakhrodin, Wu, Zhigang, Zhang, Junsong, Yang, Hong, and Liu, Yinong

Abstract

Owing to geometrical non-uniformity, geometrically graded shape memory alloy (SMA) structures by design have the ability to exhibit different and novel thermal and mechanical behaviors compared to geometrically uniform conventional SMAs. This paper reports a study of the pseudoelastic behavior of geometrically graded NiTi plates. This geometrical gradient creates partial stress gradient over stress-induced martensitic transformation, providing enlarged stress controlling interval for shape memory actuation. Finite element modeling framework has been established to predict the deformation behavior of such structures in tensile loading cycles, which was validated by experiments. The modeling results show that the transformation mostly propagates along the gradient direction as the loading level increases. [ABSTRACT FROM AUTHOR]

Published

2017

4. Oil droplet self-transportation on oleophobic surfaces

Author

Ali Shah, Ville Jokinen, Xuelin Tian, Robin H. A. Ras, Qi Hang Qin, Juan Li, Department of Materials Science and Engineering, Department of Applied Physics, Department of Electronics and Nanoengineering, Department of Chemistry and Materials Science, Aalto-yliopisto, and Aalto University

Subjects

endocrine system, Materials science, Surface Properties, microfludics, Microfluidics, microfluidics, Nanotechnology, 02 engineering and technology, Surface engineering, anisotropic surfaces, 010402 general chemistry, 01 natural sciences, complex mixtures, Time-Lapse Imaging, micro- and nanodevices, Surface tension, Physics::Fluid Dynamics, geometrical gradient, Fluidics, Texture (crystalline), ta216, oleophobic, Research Articles, oil droplet, wetting, Multidisciplinary, technology, industry, and agriculture, SciAdv r-articles, Mechanics, Materials Engineering, 021001 nanoscience & nanotechnology, eye diseases, 0104 chemical sciences, self-transportation, Models, Chemical, Oil droplet, Microscopy, Electron, Scanning, Undercut, Wetting, undercut structure, 0210 nano-technology, Hydrophobic and Hydrophilic Interactions, Oils, Research Article, anti-contamination

Abstract

Oleophobic surfaces capable of power-free self-transportation of oil droplets are designed., Directional liquid transportation is important for a variety of biological processes and technical applications. Although surface engineering through asymmetric chemical modification or geometrical patterning facilitates effective liquid manipulation and enables water droplet self-transportation on synthetic surfaces, self-transportation of oil droplets poses a major challenge because of their low surface tension. We report oil droplet self-transportation on oleophobic surfaces that are microtextured with radial arrays of undercut stripes. More significantly, we observe three modes of oil motion on various sample surfaces, namely, inward transportation, pinned, and outward spreading, which can be switched by the structure parameters, including stripe intersection angle and width. Accompanying theoretical modeling provides an in-depth mechanistic understanding of the structure–droplet motion relationship. Finally, we reveal how to optimize the texture parameters to maximize oil droplet self-transportation capability and demonstrate spontaneous droplet movement for liquids down to a surface tension of 22.4 mN/m. The surfaces presented here open up new avenues for power-free liquid transportation and oil contamination self-removal applications in various analytical and fluidic devices.

Published

2016

5. Oil droplet self-transportation on oleophobic surfaces.

Author

Li J, Qin QH, Shah A, Ras RH, Tian X, and Jokinen V

Subjects

Hydrophobic and Hydrophilic Interactions, Microscopy, Electron, Scanning, Models, Chemical, Surface Properties, Time-Lapse Imaging, Oils chemistry

Abstract

Directional liquid transportation is important for a variety of biological processes and technical applications. Although surface engineering through asymmetric chemical modification or geometrical patterning facilitates effective liquid manipulation and enables water droplet self-transportation on synthetic surfaces, self-transportation of oil droplets poses a major challenge because of their low surface tension. We report oil droplet self-transportation on oleophobic surfaces that are microtextured with radial arrays of undercut stripes. More significantly, we observe three modes of oil motion on various sample surfaces, namely, inward transportation, pinned, and outward spreading, which can be switched by the structure parameters, including stripe intersection angle and width. Accompanying theoretical modeling provides an in-depth mechanistic understanding of the structure-droplet motion relationship. Finally, we reveal how to optimize the texture parameters to maximize oil droplet self-transportation capability and demonstrate spontaneous droplet movement for liquids down to a surface tension of 22.4 mN/m. The surfaces presented here open up new avenues for power-free liquid transportation and oil contamination self-removal applications in various analytical and fluidic devices.

Published

2016