Modelling of Shape Memory Alloy Negator Springs for Long-Stroke Constant-Force Actuators

Andrea Spaggiari; Eugenio Dragoni

doi:10.4028/www.scientific.net/AST.78.52

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Functional Fatigue of NiTi Shape Memory Wires under Assorted Loading Conditions
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Transformation Behavior of Shape Memory Alloys in Multiaxial Stress State
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Modelling of Shape Memory Alloy Negator Springs for Long-Stroke Constant-Force Actuators
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Design and Simulation of a Magnetic Shape Memory (MSM) Alloy Energy Harvester
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Phase Field Dynamic Modelling of Shape Memory Alloys Based on Isogeometric Analysis
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Effect of Repeated Heat-Treatment under Constrained Strain on Mechanical Properties of Ti-Ni Shape Memory Alloy
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Digital Image-Based Method for Quality Control of Residual Bending Deformation in Slender Pseudoelastic NiTi Devices
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HomeAdvances in Science and TechnologyAdvances in Science and Technology Vol. 78Modelling of Shape Memory Alloy Negator Springs...

Modelling of Shape Memory Alloy Negator Springs for Long-Stroke Constant-Force Actuators

Abstract:

The paper deals with the analytical modelling of a shape memory alloy Negator spring. Negator springs are spiral springs made of strip metal wound on the flat with an inherent curvature such that, in repose, each coil wraps tightly on its inner neighbour. This configuration allows a constant force mechanical response and very long strokes, limited mainly from the total length of the spring. The authors investigate the behaviour of the spring made of a shape memory alloy (SMA). The intrinsic characteristic of SMA is to have two different elastic moduli at different temperatures. This difference can be exploited in order to have a net actuation force for the entire very long stroke, overcoming the two major drawbacks of the SMA actuators, short strokes and output force which varies linearly during the travel.

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Periodical:

Advances in Science and Technology (Volume 78)

Pages:

52-57

DOI:

https://doi.org/10.4028/www.scientific.net/AST.78.52

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Online since:

September 2012

Authors:

Andrea Spaggiari, Eugenio Dragoni

Keywords:

Constant Force Negator Spring, Long Stroke Actuator, Shape Memory Alloy (SMA)

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References

[1] H. Funakubo, Shape Memory Alloys, Gordon and Breach Science Publishers, New York, (1986).

Google Scholar

[2] A. Nespoli et al., The high potential of shape memory alloys in developing miniature mechanical devices: A review on shape memory alloy mini-actuators, Sens. Actuators, A, 158(1), (2010) 149-160.

DOI: 10.1016/j.sna.2009.12.020

Google Scholar

[3] J.G. Jenuwin and A. Midha, Synthesis of Single-Input and Multiple-Output Port Mechanisms with Springs for Specified Energy Absorption, J. Mech. Des. 116(3), (1994) 937-943.

DOI: 10.1115/1.2919473

Google Scholar

[4] F.A. Votta Jr and PA Lansdale, The theory and design of Long Deflection Constant Force Spring Elements, Transactions of the ASME, 74 (1952) 439-50.

DOI: 10.1115/1.4015809

Google Scholar

[5] A.M. Wahl Mechanical Springs, Second edition, McGraw-Hill, New York, (1963).

Google Scholar

[6] G. Scirè Mammano and E. Dragoni, Increasing stroke and output force of linear shape memory actuators by elastic compensation, Mechatronics 21(3), (2011) 570-580.

DOI: 10.1016/j.mechatronics.2011.02.005

Google Scholar

[7] V.I. Feodosiev, Selected Problems and Questions in Strength of Materials, MIR Publishers, Moscow, (1977).

Google Scholar