Nickel titanium and nickel titanium hafnium shape memory alloy thin films

Rao, Jeff; Roberts, Tracey; Lawson, K.J.; Nicholls, John

doi:10.1016/j.surfcoat.2009.12.025

Cited by 21 publications

(6 citation statements)

References 26 publications

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“…Nitinol has fundamental limitation in terms of thermodynamic efficiency [18], however efforts to miniaturize [19], [20], [21] and give microstructure [22], [23], [24] to Nitinol makes it a feasible method of actuation for scaling, as opposed to magnetic or electrostatic actuation methods which have fundamental challenges at very small scales. The choice of Nitinol also drives many of the design decisions such as the mechanical design of the cell, spring selection for a return force for the one-way SMA spring coils, and cell interconnects and mating, which are addressed in the following.…”

Section: Cell Contractile Elementmentioning

confidence: 99%

Simple, scalable active cells for articulated robot structures

Swensen

Nawroj

Pounds

et al. 2014

2014 IEEE International Conference on Robotics and Automation (ICRA)

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The proposed research effort explores the development of active cells -simple contractile electromechanical units that can be used as the material basis for larger articulable structures. Each cell, which might be considered a "muscle unit", consists of a contractile Nitinol SMA core with conductive terminals. Large numbers of these cells might be combined and externally powered to change phase, contracting to either articulate with a large strain or increase the stiffness of the ensemble, depending on the cell design. Unlike traditional work in modular robotics, the approach presented here focuses on cells that have a simplistic design and function, are inexpensive to fabricate, and are eventually scalable to sub-millimeter sizes, working towards our vision of robot structures that can be custom-fabricated from large numbers of general cell units, similar to biological structures.

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Section: Cell Contractile Elementmentioning

confidence: 99%

Simple, scalable active cells for articulated robot structures

Swensen

Nawroj

Pounds

et al. 2014

2014 IEEE International Conference on Robotics and Automation (ICRA)

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“…The choice of SMA Nitinol as the primary method of actuation, coupled with the goal of a minimalist approach to engineering the structure of the active cells, sets forth specific design challenges. Nitinol has fundamental limitation in terms of thermodynamic efficiency [20]; however several efforts in both miniaturization [21][22][23] and micro-machining or laser etching [24][25][26] has shown Nitinol to be feasible for making scalable actuators, as opposed to magnetic or electrostatic actuation methods that have fundamental challenges at very small scales. The choice of Nitinol also drives many of the design decisions, such as the mechanical design of the cell, spring selection for a return force for the one-way SMA spring coils, and cell interconnects and mating, which are addressed in the following.…”

Section: Cell Contractile Elementmentioning

confidence: 99%

Active cells for redundant and configurable articulated structures

Swensen¹,

Nawroj²,

Pounds³

et al. 2014

Smart Mater. Struct.

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The proposed research effort explores the development of active cells-simple contractile electro-mechanical units that can be used as the material basis for larger articulable structures. Each cell, which might be considered a 'muscle unit,' consists of a contractile Nitinol Shape Memory Alloy (SMA) core with conductive terminals. Large numbers of these cells might be combined and externally powered to change phase, contracting to either articulate with a large strain or increase the stiffness of the ensemble, depending on the cell design. Unlike traditional work in modular robotics, the approach presented here focuses on cells that have a simplistic design and function, are inexpensive to fabricate, and are eventually scalable to sub-millimeter sizes, working toward our vision of articulated and robotic structures that can be customfabricated from large numbers of general cell units, similar to biological structures. In this paper, we present the design of the active cells and demonstrate their usage with three articulated structures built with them.

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“…Another benefit of the micro-system technology approach is that samples from different alloys can be fabricated and structured with almost identical process parameters, without the need of cold or hot work or forging which often lead to difficulties in the processing of brittle materials. Thus, beside extensive work on binary NiTi [13][14][15][16][17][18], sputtered films from NiTiCu [19][20][21][22], NiTiHf [23][24][25], NiTiPd [5,[26][27][28][29][30], and NiTiZr [23,31] have been investigated. Like NiTiCu bulk material, sputtered NiTiCu films reveal excellent functional stability during cyclic loading.…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Characterization of Freestanding NiTi Based Thin Film Materials for Shape Memory Micro-actuator Applications

Bechtold¹,

Chluba²,

Zamponi

et al. 2019

Shap. Mem. Superelasticity

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Thin film shape memory actuators fabricated by micro-system technology processes are of particular interest in micro-actuator applications due to their high work output, large displacements, and a comparably easy and compact system setup. Micro-system technology processes allow to deposit and structure ultra-precise parts from a wide range of alloys, among them alloys that are difficult to process with conventional fabrication techniques. However, sputtered NiTi based thin films are seldom deposited with thicknesses [ 10 lm, which limits their range of application as well as makes the handling of freestanding films difficult. In this work, freestanding NiTi, NiTiCu, and NiTiHf shape memory structures were fabricated by means of sputtering, lithography, and wet etching, with a process that allows for thicknesses up to 80 lm. Their high cycle actuation behavior and microstructure were characterized. NiTiCu actuators show an excellent cyclic stability, resulting in high fatigue lives of [ 10 8 cycles at 1.5% strain, even for stresses as high as 550 MPa. A distinct martensite/austenite interface is observed during transformation, in contrast to NiTi exhibiting a rather homogeneous transformation during heating and cooling throughout the sample volume. Sputtered NiTiHf actuators tested in air can reach fatigue lives as high as 1.5 9 10 6 cycles at 1% strain. Keywords NiTi Á NiTiHf Á Mechanical behavior Á Shape memory films Á Thermal cycling This article is an invited submission to Shape Memory and Superelasticity selected from presentations at the Shape Memory and Superelastic Technology Conference and Exposition (SMST2019) held May 13-17, 2019 at The Bodensee Forum in Konstanz, Germany, and has been expanded from the original presentation.

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Nickel titanium and nickel titanium hafnium shape memory alloy thin films

Cited by 21 publications

References 26 publications

Simple, scalable active cells for articulated robot structures

Simple, scalable active cells for articulated robot structures

Active cells for redundant and configurable articulated structures

Fabrication and Characterization of Freestanding NiTi Based Thin Film Materials for Shape Memory Micro-actuator Applications

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