Shape memory alloys (SMAs) are used in many applications as actuators. The main drawbacks that limit the use of the SMAs in the field of mechanical actuation are the low mechanical bandwidth (up to a few Hertzs) and the unsatisfactory stroke (several millimeters). This paper contributes to enhancing the performances of SMA actuators by proposing a new SMA helical spring with a hollow section. The hollow spring is modeled, then it is constructed, and finally it is tested in compression to compare its performances with those of a spring with a solid cross section of equal stiffness and strength. Emptied of the inefficient material from its center, the hollow spring features a lower mass (37% less) and an extremely lower cooling time (four times less) than its solid counterpart. These results demonstrate that helical springs with a hollow construction can be successfully exploited to build SMA actuators for higher operating frequencies and improved strokes.
Issue Section:
Research Papers
Keywords:
shape memory effects,
springs (mechanical),
spring design,
shape memory alloys,
thermomechanical characterization
Topics:
Springs
1.
Mani
, G.
, Feldman
, M. D.
, Patel
, D.
, and Agraval
, C. M.
, 2007, “Coronary Stents: A Materials Perspective
,” Biomaterials
0142-9612, 28
, pp. 1689
–1710
.2.
Eliades
, T.
, 2007, “Orthodontic Materials Research and Applications: Part 2. Current Status and Projected Future Developments in Materials and Biocompatibility
,” Am. J. Orthod. Dentofacial Orthop.
0889-5406, 131
, pp. 253
–262
.3.
Ma
, H.
, and Cho
, C.
, 2008, “Feasibility Study on a Superelastic SMA Damper With Re-Centring Capability
,” Mater. Sci. Eng., A
0921-5093, 473
, pp. 290
–296
.4.
Choi
, S. B.
, and Hwang
, J. H.
, 2000, “Structural Vibration Control Using Shape Memory Actuators
,” J. Sound Vib.
0022-460X, 231
, pp. 1168
–1174
.5.
Mavroidis
, D.
, Pfeiffer
, C.
, Mosley
, M.
, and Rutgers
, U.
, 2000, “Conventional Motors, Shape Memory Alloys and Electrorheological Fluids
,” The Topics on NDE (TONE) Series
, 1st ed., ASNT
, Columbus, OH
, Vol. 4
, pp. 189
–214
.6.
Reynaerts
, D.
, and Van Brussel
, H.
, 1998, “Design Aspects of Shape Memory Actuators
,” Mechatronics
0957-4158, 8
, pp. 635
–656
.7.
Elwaleed
, A. K.
, Mohamed
, N. A.
, Nor
, M. J. M.
, and Mustafa
, M. M.
, 2007, “A New Concept of a Linear Smart Actuator
,” Sens. Actuators, A
0924-4247, 135
, pp. 244
–249
.8.
Spinella
, I.
, and Dragoni
, E.
, 2009, “Design Equations for Binary Shape Memory Actuators Under Dissipative Forces
,” J. Mech. Eng. Sci.
0022-2542, 223
, pp. 531
–543
.9.
Spinella
, I.
, Sciré Mammano
, G.
, and Dragoni
, E.
, 2009, “Conceptual Design and Simulation of a Compact Shape Memory Actuator for Rotary Motion
,” J. Mater. Eng. Perform.
1059-9495, 18
, pp. 638
–648
.10.
Yang
, K.
, and Gu
, C.
, 2009, “A New Manipulator Based on ISMAAs and TWUSMs
,” ASME J. Mech. Des.
0161-8458, 131
, p. 114502
.11.
Luo
, Y.
, and Hutapea
, P.
, 2009, “Design of Bone Transport Device Using Smart Material Actuators
,” ASME J. Mech. Des.
0161-8458, 131
, p. 091005
.12.
Sreekumar
, M.
, Nagarajan
, T.
, and Singaperumal
, M.
, 2009, “Design of a Shape Memory Alloy Actuated Compliant Smart Structure: Elastica Approach
,” ASME J. Mech. Des.
0161-8458, 131
, p. 061008
.13.
Lan
, C.
, and Yang
, Y.
, 2009, “A Computational Design Method for a Shape Memory Alloy Wire Actuated Compliant Finger
,” ASME J. Mech. Des.
0161-8458, 131
, p. 021009
.14.
Georges
, T.
, Brailovski
, V.
, Morellon
, E.
, Coutu
, D.
, and Terriault
, P.
, 2009, “Design of Shape Memory Alloy Actuators for Morphing Laminar Wing With Flexible Extrados
,” ASME J. Mech. Des.
0161-8458, 131
, p. 091006
.15.
Banerjee
, A.
, Bhattacharya
, B.
, and Mallik
, A. K.
, 2010, “Optimum Discrete Location of Shape Memory Alloy Wire for Enhanced Actuation of a Compliant Link
,” ASME J. Mech. Des.
0161-8458, 132
, p. 021001
.16.
Spinella
, I.
, and Dragoni
, E.
, 2010, “Analysis and Design of Hollow Helical Springs for Shape Memory Actuators
,” J. Intell. Mater. Syst. Struct.
1045-389X, 21
, pp. 185
–199
.17.
Timoshenko
, S. P.
, and Gere
, J. M.
, 2009, Theory of Elastic Stability
, 2nd ed., Dover
, New York
.18.
Shigley
, J.
, Mischke
, C.
, and Brown
, T. H.
, 2006, Standard Handbook of Machine Design
, 3rd ed., McGraw-Hill
, New York
.19.
Wahl
, A. M.
, 1991, Mechanical Springs
, McGraw-Hill
, New York
.20.
Bagaria
, W. J.
, 2000, “Stress Analysis of Light Weight Closely Coiled Hollow Helical Springs
,” Annual Summary of the United States Naval Academy, www.usna.edu/AcResearch/2000SummaryPDFs/DivEngrWeapAerospaceEngrDept.pdfwww.usna.edu/AcResearch/2000SummaryPDFs/DivEngrWeapAerospaceEngrDept.pdf21.
Bagaria
, W. J.
, 2000, “Manufacturing and Testing of Light Weight Closely Coiled Hollow Helical Springs
,” Annual Summary of the United States Naval Academy, www.usna.edu/AcResearch/2000SummaryPDFs/DivEngrWeapAerospaceEngrDept.pdfwww.usna.edu/AcResearch/2000SummaryPDFs/DivEngrWeapAerospaceEngrDept.pdf22.
Gobbi
, M.
, and Mastinu
, G.
, 2001, “On the Optimal Design of Composite Material Tubular Helical spring
,” Meccanica
0025-6455, 36
, pp. 525
–553
.23.
Sokolnikoff
, I. S.
, 1983, Mathematical Theory of Elasticity
, 2nd ed., Krieger
, Malabar
.24.
Daly
, S.
, Ravichandran
, G.
, and Bhattacharya
, K.
, 2007, “Stress-Induced Martensitic Phase Transformation in Thin Sheets of Nitinol
,” Acta Mater.
1359-6454, 55
, pp. 3593
–3600
.25.
Uchil
, J.
, Mahesh
, K. K.
, and Ganesh Kumara
, K.
, 2001, “Calorimetric Study of the Effect of Linear Strain on the Shape Memory Properties of Nitinol
,” Physica B
0921-4526, 305
, pp. 1
–9
.26.
Bellini
, A.
, Colli
, M.
, and Dragoni
, E.
, 2009, “Mechatronic Design of a Shape Memory Alloy Actuator for Automotive Tumble Flaps: A Case Study
,” IEEE Trans. Ind. Electron.
0278-0046, 56
, pp. 2644
–2656
.Copyright © 2010
by American Society of Mechanical Engineers
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