Jtam.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

49, 3, pp. 927-943, Warsaw 2011

NOVEL SHAPE MEMORY ACTUATORS

Hisaaki Tobushi, Kouji Miyamoto,

Yasuhiko Nishimura, Kento Mitsui

Aichi Institute of Technology, Department of Mechanical Engineering, Toyota, Japan

e-mail: tobushi@aitech.ac.jp

Inorder todevelopnovel shapememoryactuators, the torsionaldeforma-
tionof a shapememoryalloy (SMA) tapeandtheactuatormodelsdriven
by the tapewere investigated.The shapememory composite (SMC)belt
composed of SMA tapes and a shapememory polymer (SMP)was fabri-
cated, and the three-way bending characteristics were also investigated.
The results obtained can be summarized as follows. In the SMA tape
subjected to torsion, the martensitic transformation appears along the
edge of the tape due to elongation of the edge of the tape and grows
to the central part. The fatigue life in both the pulsating torsion and
alternating torsion is expressed by a unified relationship of the dissipa-
ted work in each cycle. Based on the two-waymotion of an opening and
closing door model and a solar-powered active blind model driven by
two kinds of SMA tape, it is confirmed that the two-way rotary driving
actuator with a small and simple mechanism can be developed by using
torsion of the SMA-tape. The SMC belt laminated with the SMP tape
and SMA tapes was fabricated.The three-waybendingmovement of the
SMCbelt was achieved during heating and cooling based on the charac-
teristics of the SMA tapes and the SMP tape. The active SMC actuator
with various three-dimentionalmovements canbe developedbyapplying
the three-way properties of the SMC.

Key words: shape memory alloy, shape memory polymer, composite,
actuator, two-way, three-way, tape

1. Introduction

In the recent years, intelligent materials having functions of sensing, judging
and working have attracted worldwide attention. One of the main materials
which have activated the research on the intelligent materials is the shape
memory alloy (SMA) (Funakubo, 1987;OtsukaandWayman, 1998). Themain



928 H. Tobushi et al.

characteristics of SMAare the shapememory effect (SME) and superelasticity
(SE). Thanks to these characteristics, SMAs are used in the driving elements
of actuators, heat engines and robots. The SME and SE appear as the result
of a martensitic transformation (MT).

The deformation properties of the SME and SE depend strongly on tem-
perature and stress. In a recent study using the torsional deformation of a
TiNi SMA tube, twist in the blades of rotor aircraft was investigated in order
to improve the flight performance (Mabe et al., 2004, 2007). Because of the
adaptable thermal response of SMA elements, thin wires and tapes are widely
used in practical applications. In practical applications making use of SMA-
tapes, the torsional deformation can be obtained simply by grippingboth ends
without any mechanical process. If the characteristics of SE are exploited, a
high performance of energy storage can be achieved similar to that of a torsion
bar. In this way of using torsional characteristics of SMA-tapes, simple and
small actuators can bedeveloped.The authors investigated therefore the basic
deformation properties of an SMA-tape in torsion (Tobushi et al., 2008, 2009).

The shape memory polymer (SMP) has been also practically used. In
SMPs, the elastic modulus and the yield stress are high at temperatures be-
low the glass transition temperature Tg and low at temperatures above Tg. If
SMPs are deformed at temperatures above Tg and cooled down to temperatu-
res below Tg by holding the deformed shape constant, the deformed shape is
fixed andSMPs can carry large load. If the shape-fixed SMPelement is heated
up to temperatures above Tg under no load, the original shape is recovered.
The shape memory property appears based on the glass transition in which
the characteristics of molecular motion vary depending on the variation in
temperature. Among the SMPs, the polyurethane SMP has been practically
used.

In order to use new and higher functions by combining the excellent qu-
alities of both the SMA and the SMP, the development of a shape memory
composite (SMC) with the SMA and SMP is expected (Sterzl et al., 2003;
Manzo and Garcia, 2007; Browne et al., 2009; Tobushi et al., 2006, 2010).

In the present paper, in order to develop rotary actuators driven by SMA
tapes, the torsional deformation properties of TiNi SMA tapes are investi-
gated. The two-way motions of an opening and closing door model and a
solar-powered active blindmodel driven by SMAtapes are demonstrated.The
fabrication andmechanical properties of the SMCbelt which shows the three-
way bending motion depending on temperature variation are investigated.
Based on the three-way characteristics of the SMC belt, the SMC actuators
with three-dimensional movement are also discussed.



Novel shape memory actuators 929

2. Rotary actuator driven by SMA tape

2.1. Material

Thematerials used in the experiment were Ti-50.18at%Ni SMA tapewith
a thickness of t = 0.25mm and a width of w = 5mm. The specimen was
a uniform flat tape of length L = 60mm. The gauge length of the specimen
was l=40mm.The transformation temperatures obtained from theDSC test
were Ms =304K, Mf =266K, As =319K and Af =359K.

2.2. Torsional deformation and fatigue properties of SMA tape

2.2.1. Twisted state

The photographs of the twisted SMA tape are shown in Fig.1 for each
angle of twist. The left side shows the fixed end and the right side the twi-
sted end. The crossover point of the upper and lower surfaces of the SMA
tape propagates from the twisting end at the angle of twist per unit length
θ =39.3rad·m−1 (total angle of twist φ= π/2) and reaches the central part
of the specimen at θ = 78.5rad·m−1 (φ = π). We note that both edges of
the tape are elongated by twisting since both ends are axially fixed. There-
fore, tensile stress is induced along both edges, and the stress state becomes
different from the simple shear andmuch more complex.

Fig. 1. Photographs of the twisted SMA tape at each angle of twist

2.2.2. Observation of martensitic transformation by thermography

The thermomechanical characteristics of SMA appear due to theMT and
the reverse transformation.The exothermic reaction and endothermic reaction



930 H. Tobushi et al.

occur based on the MT and the reverse transformation, respectively. In the
DSC test, the transformation temperatures are determined by measuring the
heat change owing to these reactions. In the case of SE due to the stress-
inducedMT, temperature increases or decreases in the loading and unloading
processes, respectively. The initiation and growth processes of theMT can be
therefore analyzed by measuring temperature on the surface of the material.
The infrared thermography to measure the temperature distribution on the
whole surfaceof thematerial canbeapplied to thisobjective.TheMTbehavior
of SMA can be analyzed by the thermography (Pieczyska et al., 2006).
The temperature distribution on the surface of the SMAtape at each angle

of twist during the torsional deformation obtained by the infrared thermogra-
phy is shown in Fig.2. In Fig.2, the upper side in each case shows the twisting
part and the lower side shows the fixedpart.Themaximumtemperature Tmax
on the surface of the specimen appears along the edge of the tape, and the
exothermic MT occurs in this part and grows toward the central part of the
specimen. The temperature rise along the edge of the tape starts at the angle
of twist per unit length θ=26.2rad·m−1. This angle of twist per unit length
corresponds to the tensile strain at the edge of the tape of 0.3% and coincides
with the MT starting condition. The maximum temperature of the specimen
occurs along the edge of the tape and the high temperature region propagates
toward the central part with an increase in the angle of twist. Therefore, the
MT grows preferentially based on the elongation along the edge of the tape.

Fig. 2. Thermograms showing temperature distribution on the surface of the SMA
tape appeared due to the phase transformation under torsion

2.2.3. Torsional deformation

Therelationshipsbetween the torque M andangle of twist prunit length θ
obtained by the pulsating torsion test and the alternating torsion test for the
maximumangle θm =78.5rad·m

−1 are shown inFigs.3a and 3b, respectively.



Novel shape memory actuators 931

In the case of the pulsating torsion, the curve between M and θ is expressed
almost by a straight line in the first loading process. In the unloading process,
the initial slope of the curve is steep, and thereafter becomes to be the plateau
stage. In the reloading process, the initial curve is almost parallel to the first
loading curve, and thereafter the slope of the curve becomes steep. In the
case of the alternating torsion, the twisting in the reverse direction to the
first twisting direction was carried out. The reverse loading and unloading
curves are almost similar to the first loading and unloading curves except for
the early stage. That is, the first and reloading curves are closely symmetric
with respect to the origin. In the reloading process, the initial slope of the
unloading curve is steep and the plateau stage appears thereafter. The point
at the end of the reloading curve almost coincides with the point at which the
first unloading started, showing the return-pointmemory in the pulsating and
alternating torsion.

Fig. 3. Relationship between the torque M and angle of twist per unit length θ
obtained by the pulsating and alternating torsion tests for the maximum angle

θ
m
=78.5rad·m−1

The area surrounded by the hysteris loop of the torque-angle curve of
twist shown in Fig.3 expresses the dissipated work per unit length Wd. The
dissipatedwork Wd increases inproportion to themaximumangle of twist θm.
The value of Wd in the alternating torsion is larger than that in the pulsating
torsion by 3.5 times. Wd is very small if θm is smaller than a certain value in
both alternating and pulsating torsion.

2.2.4. Torsional fatigue properties

The relations between the maximum angle of twist per unit length θm
and the number of cycles to failure Nf obtained from the torsion fatigue test
are shown in Fig.4. The number of cycles to failure Nf decreases with an
increase in the maximum angle of twist per unit length θm. This relation is



932 H. Tobushi et al.

approximated by a straight line on the logarithmic graph. The fatigue life
curve seems therefore to be expressible in an equation similar to that for TiNi
SMAwires under bending. This can be seen in Eq. (2.1)

θmN
β
f
=α (2.1)

where α and β represent θm in Nf =1 and the slope of the logθm− logNf
curve, respectively. The calculated results obtained fromEq. (2.1) for β=0.1,
α = 265rad·m−1 in pulsating torsion and for β = 0.13, α = 310rad·m−1 in
alternating torsion are shown by the solid lines in Fig.4. As can be seen, the
fatigue life curves are well matched by the solid calculation lines. Comparing
the fatigue life of alternating torsion and pulsating torsion, the number of
cycles to failure Nf for alternating torsion is smaller than that for pulsating
torsion by 1/5.

Fig. 4. Relationship between the maximum angle of twist per unit length and the
number of cycles to failure

The relationship between the dissipatedwork Wd and thenumber of cycles
to failure Nf is shown inFig.5. The relationships for the pulsating torsion and
the alternating torsion are located almost on the same line. The fatigue life in
both the pulsating torsion and the alternating torsion is therefore expressedby
a unified relationship. The relationship between Nf and Wd can be expressed
by a power function in Eq. (2.2)

WdN
λ
f =µ (2.2)

where µ and λ represent Wd at Nf =1 and the slope of the logWd− logNf
curve, respectively. The calculated result by Eq. (2.2) for λ = 0.382 and
µ=9J/m is shownby the solid line in Fig.5. As can be seen, the overall incli-
nations are approximated by the solid line. Thedissipatedwork corresponding



Novel shape memory actuators 933

to the fatigue limit may exist at 0.04-0.05J/m. If the dissipated work in each
cycle is smaller than 0.04-0.05J/m, the fatigue damage is slight, resulting in
long fatigue life.

Fig. 5. Relationship between dissipatad work per unit length and number of cycles
to failure

2.3. Two-way opening and closing door model

Photographs of the rotarymovement of an opening and closing doormodel
using an SMA tape which shows the SME and an SEA tape which shows SE
at RT under heating and cooling are shown in Fig.6. The SMA tape is the
same as the specimen used in the torsion test. The SEA tape with a thickness
of t=0.25mm and a width of w=2.5mm was a TiNi SEA tape which was
heat-treated tomemorize a flat plane. In the initial state at RT, the SEA tape
was mounted to be in a flat plane and the SMA tape was mounted at the
total angle of twist φ=π/2. The SMA tapewas heated by joule heat through
electric current. As can be seen in Fig.6, the door is closed in the initial state,
since torque of SEA tape MSEA is larger than that of the SMA tape MSMA.
Since the recovery torque appearsbyheating theSMAtape and the relation of
the torque changes into MSMA >MSEA, the SMA tape recovers the flat plane
and, therefore, the door is opened. When the SMA tape is cooled thereafter,
the relation of torque varies again into MSMA < MSEA. Therefore, the SEA
tape recovers the flat plane, resulting in closing the door. Thus, if two kinds of
SMA tapes which show the SME and SE are used, a two-way rotary driving
element with a small and simple mechanism can be developed.



934 H. Tobushi et al.

Fig. 6. Photographs of two-way rotarymovement of a door driven by the SMA tape
and SEA tape during heating and cooling

2.4. Solar-powered active blind model

A new rotary actuator model in which the axes of an SMA tape and an
SEA tape are arranged in parallel is demonstrated.
The structure of a two-way actuator for opening and closing a blind driven

by the SMAtape andSEAtape through sunlight, the photograph of the solar-
powered active blind and the photographs of two-way motion of the actuator
are shown in Figs. 7, 8 and 9, respectively. Both the SMA tape and the SEA
tape were the same as those used in the door model. In the initial state, the
SEA tape was mounted to be in a flat plane and the SMA tape was mounted
at the total angle of twist φ=π/2.

Fig. 7. Structure of the solar-powered active blind

The SMA tape was heated by sunlight through a Fresnel lens. Since the
recovery torque appears in the SMA tape by heating the tape, the blind is



Novel shape memory actuators 935

Fig. 8. Photograph of the solar-powered active blind

Fig. 9. Photographs of two-waymotion for the opening and closing of the blind
driven by sunlight through the SMA tape and SEA tape

closed through a crank and a lever. When the sunlight is shut out, the SMA
tape is cooledandtheSEAtape recovers theflatplane, resulting in theopening
of the blind. Thus, if two kinds of SMA tapes which show the SME and SE
are used, the two-way rotary actuator driven by sunlight can be developed.



936 H. Tobushi et al.

3. Three-way active shape memory composite actuator

3.1. Material

With respect to the SMA, two kinds of polycrystalline SMAtapes showing
the SMEand SE at room temperature were used. The SMA tape showing the
SME was a TiNi alloy tape with a width of 5mm and a thickness of 0.3mm
produced by Furukawa Techno Materials Co. The SEA tape showing the SE
was aTiNi alloy tape with awidth of 2.5mmand a thickness of 0.25mmpro-
duced by Yoshimi Inc. In the shape memory processing, each SMA tape was
set along the inside of a fixing ring with an inner diameter of 16mm and was
heat-treated tomemorize the round shapewith an outside diameter of 16mm.
The temperatures As and Af of the SMA tape were 324K and 342K, and
these of the SEA tapewere 287K and 309K, respectively. TheR-phase trans-
formation start and finish temperatures Rs and Rf of the SMA tape were
322K and 309K, respectively.

With respect to the SMP, a polyurethane SMP sheet (MM6520) produced
by SMPTechnologies Inc. was used. The thickness was 0.25mm and the glass
transition temperature Tg was 338K.

3.2. Structure of SMC belt

The SMC belt with a length of 60mm, a width of 10mm and a thickness
of 1.03mm was fabricated by using two kinds of SMA tapes and three SMP
tapes. In the fabricated SMC belt, the SMP tapes were used as a matrix and
the SMA tapes as a fiber. The length of the SMA tape and the SEA tape was
50mm. Two kinds of SMA tapes were located in the central part of the SMC
belt. The structure of the SMC belt is shown in Fig.10.

3.3. Fabrication of SMC belt

At first, two incisions were given to one SMP tape and two kinds of SMA
tapes (SMA tape and SEA tape) were passed through these incisions. In this
process, the SMA tape and SEA tape were arranged facing in the opposite
directions for the memorized round shape as shown in Fig.11. The SMP tape
passed through two kinds of SMA tapes was sandwiched between two SMP
tapes from the upper and lower sides. The combined material was set in the
mold for fabricating the SMC belt. The upper and lower molds were fastened
through the bolts by a compressive stress of 7.46MPa. The mold was held
in the furnace at 448K for 60min followed by cooling in air. The SMC belt
withoutbubbles andgaps among thematerials couldbe fabricatedunder these



Novel shape memory actuators 937

Fig. 10. Structure of the SMC belt composed of the SMA, SEA and SMP tape

Fig. 11. Arrangements of the SMA, SEA and SMP tapes to laminate the SMC belt

conditons. In order to protect the projection of the edge by the recovery force
of the SMAtapes, both edges of the SMAtapeswere connected by a thin steel
clamp.

3.4. Three-way actuation

The photographs of the three-way bendingmotion of the fabricated SMC
belt during heating and cooling are shown in Fig.12. The heating and cooling
were carried out between 293K and 365K. In Fig.12, the symbols As,SEA,
Af,SEA, As,SMA, Af,SMA and Tg represent the reverse-transformation start
and finish temperatures of the SEA tape and the SMA tape and the glass
transition temperature of the SMP tape, respectively. At 293K 1O, the force
induced in the SEA tape is high, and therefore the SMC belt bends in the



938 H. Tobushi et al.

direction of the shape-memorized round shape of the SEA tape. If the SMC
belt is heated 1O- 2O, the SMP becomes soft and the SMC belt bends further
in the samedirection at temperatures around Tg 2O. If the SMCbelt is heated
up above Tg 1O- 3O, the SMPbecomes easier to deform and the recovery force
in the SMA tape increases at temperatures above Af,SMA (Lin et al., 1995),
and therefore the SMC belt bends in the direction of the shape-memorized
round shape of the SMA tape 3O. If the SMC belt is cooled thereafter 3O- 4O,
the recovery force in the SMA tape decreases and the recovery force in the
SEA tape becomes higher. Therefore, the SMCbelt bends again to its original
shape 4O.

Fig. 12. Photograph of the three-way bending deformation of the SMC belt during
heating and cooling

3.5. Movement in three-point bending

The three-way movement was measured by the three-point bending test.
At first, the initial bent-form SMC belt was set on the supports of the three-
point bending test machine. After setting the SMC belt, the point of the
punchcontacted slightly the center of theSMCbelt.Keeping the slight contact
conditionwith the contact load lower than 0.1N, the SMCbeltwas heated and
cooled, and the displacement at the center of the SEC belt was measured.

The relationship between the displacement and temperature obtained by
the three-point bending test is shown in Fig.13. Rs,SMA and Rf,SMA denote
the R-phase transformation start andfinish temperatures of theSMAtape, re-
spectively. The symbols 1O- 4O correspond to the deformed states 1O- 4O shown



Novel shape memory actuators 939

in Fig.12. It should be noticed that if the deflection of the SMCbelt increases,
the center of the SMC belt moves downward and the displacement decreases
to the negative side. In the heating process 1O- 2O, the deflection of the SMC
belt increases, since the SMP exists in the glass transition region 2O and the
SMP becomes soft. In the heating process 2O- 3O, the deflection of the SMC
belt decreases, since the internal bendingmoment of the SMA tape increases
at temperatures around Af,SMA due to the reverse transformation of the SMA
tape. In the cooling process 3O- 4O, the deflection of the SMC belt increases
gradually with a decrease in temperature since the internal bending moment
of the SMA tape decreases due to the R-phase transformation and, therefore,
the internal bending moment of the SEA tape becomes higher than that of
other elements.

Fig. 13. Relationship between the displacement and temperature of the SMC belt
obtained by the three-point bending test

3.6. Recovery force in three-point bending

In the three-point bending test with heating and cooling for the recovery
force, the center of the SMC belt was put in the punch, and the position was
held constant. Keeping the position of the center and two supports constant,
the SMC belt was heated and cooled.
The relationship between the recovery force and temperature obtained by

the three-point bending test for the SMC belt is shown in Fig.14. The beha-
vior of the recovery force is different between the heating process and cooling
process, and the curve describes a large hysteresis loop. In the heating process,
the recovery force of the SMCbelt decreases at temperatures around Tg of the
SMP 2O. The recovery force starts to increase at temperatures around Af,SMA
of the SMA tape. Since the recovery force of the SMA tape becomes stron-
ger than that of the SEA tape at temperatures around Af,SMA, the recovery



940 H. Tobushi et al.

force of the SMC belt appears. In the cooling process, the recovery force of
the SMC belt decreases gradually. The recovery force of the SMA tape decre-
ases due to the R-phase transformation at temperatures between Rs,SMA and
Rf,SMA (Lin et al., 1995), and the recovery force of the SMC belt decreases
correspondingly.

Fig. 14. Relationship between the recovery force and temperature of the SMC belt
obtained by the three-point bending test

3.7. SMC actuator with three-dimensional movement

Thethree-waybendingmovement inaplanewas obtainedbythe fabricated
SMCbelt. In the SMCbelt, the SMAtape andSEAtapewere arranged in the
same direction and laminated with the SMP tape. If both tapes are arranged
in different directions and sandwiched between SMP sheets, the SMC sheet
moves not only in a plane but also moves in various planes during heating
and cooling. Therefore, the SMC actuator with three-dimensional movement
can be developed by applying the three-way properties of SMC with various
combinations of the SMA, SEA and SMP elements. The three-dimensional
movement properties of the SMC actuator depend on the memorized shapes,
configurations, volume fractions and phase transformation temperatures of
each element.

4. Conclusions

In order to develop the rotary driving element with SMA tape, the torsional
deformation properties and actuator models driven by a TiNi SMA tapewere
investigated. The SMC belt composed of two kinds of SMAs and SMP was



Novel shape memory actuators 941

fabricated, and the three-way movement and recovery force in bending were
also investigated. The results obtained can be summarized as follows.

• In the SMAtape subjected to torsion, theMTappears along the edge of
the tapedue toelongation of the edgeof the tapeandgrows to thecentral
part. The fatigue life in both the pulsating torsion and the alternating
torsion is expressed by the unified relationship of the dissipated work in
each cycle.

• Based on the two-waymotion of the opening and closing doormodel and
the solar-powered active blindmodel driven by two kinds of SMA tape,
it is confirmed that the two-way rotary driving actuator with a small
and simple mechanism can be developed by using torsion of the SMA
tapes.

• TheSMCbeltwas fabricated by laminating theSMPtape and twokinds
of SMA tapes arranged facing in the opposite directions for the shape-
memorized round shape. The three-way bendingmovement of SMCbelt
was achieved during heating and cooling based on the characteristics
of the SMA tapes and the SMP tape. The active SMC actuator with
various three-dimensional movements can be developed by applying the
three-way properties of the SMC.

Acknowledgements

The experimental work for this study was carried out with the assistance of stu-

dents in Aichi Institute of Technology, to whom the authors wish to express their

gratitude. The authors are also grateful to the administrators of Scientific Research

(C) (General) in Grant-in-Aid for Scientific Research by the Japan Society for the

Promotion of Science and The Naito ResearchGrant for financial support.

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Nowe aktuatory z elementami z pamięcią kształtu

Streszczenie

W pracy zajęto się aktuatorami nowego typu, w których zastosowano stop z pa-
mięcią kształtu (SMA) w postaci skręcającej się taśmy SMAwywołującej ruch aktu-
atora. Opracowano kompozytowy pas (SMC) z taśm SMA oraz polimeru wykazują-
cego efekt pamięci kształtu (SMP) oraz zbadano charakterystyki takiego kompozytu
przy zginaniu trójosiowym.Rezultaty badań pokazały, że taśma SMApoddana skrę-
caniu doznaje przemianymartenzytycznejwzdłuż krawędzi z powodu jej wydłużania,



Novel shape memory actuators 943

która stopniowo przechodzi do środkowej części taśmy. Problemwytrzymałości zmę-
czeniowej taśmy obciążonej jednokierunkowym i naprzemiennym skręcaniem opisano
ujednoliconym wyrażeniem określającym pracę dyssypacji na każdy cykl obciążenia.
Zbadano model aktuatora dwustronnego działania do otwierania i zamykania drzwi
oraz do sterowania przesłony zasilanej energią słoneczną. Potwierdzono skuteczność
torsyjnegoaktuatoraSMAprzyutrzymaniuprostotykonstrukcji takiegomechanizmu.
Przeanalizowano przestrzenny ruch kompozytowego pasa SMC indukowanego ogrze-
waniem i chłodzeniem w zależności od charakterystyk taśm SMA i SMP. Pokazano,
że dzięki właściwościom kompozytu SMC różnych w trzech kierunkach, uzyskanie
zdolności ruchowej aktuatora w przestrzeni (3D) jest możliwe.

Manuscript received January 14, 2011; accepted for print March 3, 2011