Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

50, 3, pp. 855-869, Warsaw 2012

50th Anniversary of JTAM

PERFORMANCE AND DESIGN OF PRECISION-CAST SHAPE

MEMORY ALLOY BRAIN SPATULA

Hisaaki Tobushi, Kento Mitsui, Kohei Takeda

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

e-mail: tobushi@aitech.ac.jp

Kazuhiro Kitamura

Aichi University of Education, Department of Technology Education, Kariya, Japan

Yukiharu Yoshimi

Yoshimi Inc., Obu, Japan

Inorder todevelopabrainspatulamadeofa shapememoryalloy (SMA), thispaperdiscusses
the bending characteristics of a newbrain spatula precision-cast in aTiNi SMA.The results
obtained can be summed up as follows. (1) With respect to an SMA-brain spatula having
the same length andwidth as the existing typemade of copper, if the new cast SMA spatula
is 1.2 times as great in thickness as the existing copper spatula, or if a conventionally rolled
SMA spatula is 1.3 times as great, the SMA instrument will offer the same bending rigidity
andwithstand almost as great a bending force as the copper one. (2)Expressing the bending
fatigue life of the copper or SMA in the region of low-cycle fatigue as a power function of the
maximum bending strain, the fatigue life of the SMA is longer than that of the copper. For
both the cast and the rolled SMAs, the fatigue life is longer under pulsating-plane bending
than under alternating plane bending.

Key words: shape memory alloy, brain spatula, bending

1. Introduction

The shapememory effect (SME) and superelasticity (SE) are characteristic behaviors of a shape
memory alloy (SMA). A strain of several percent can be recovered by heating in the case of the
SMEorunloading in the case of SE.Thesebehaviors occurdue to themartensitic transformation
(MT) and its reverse transformation. The large recovery stress and great amounts of energy
dissipation and storage associated with theMT are effectively exploited in an SMA (Funakubo,
1987; Duerig et al., 1990; Saburi, 2000; Chu and Zhao, 2002; Otsuka and Wayman, 1998). The
development of applications for SMAs as intelligent materials has therefore attracted worldwide
attention. SMAs are now in use across wide fields of industry, electrical manufacturing, and
medical and leisure technologies, to name only a few.
A brain spatula or brain retractor is an instrument used in surgery to hold a brain incision

open while a deep cerebral tumor is operated on. A schematic image of how this is done is
shown in Fig. 1. As shown, the spatula is used in a bent form, fitting the shape and depth of the
individual brain. After the operation, the spatula is struck with a miniature hammer to return
it to its original flat form, after which it is sterilized by heating and is then ready for reuse. The
usual material for brain spatulas hitherto has been copper, but owing to the irrecoverable loss
of evenness that develops on the copper surface after each use, in practice the instrument has
to be disposed of after being used only a few times. If an SMA material is used instead, the
original flat shape can be restored automatically and precisely through the working of the SME
during the sterilization heating in the autoclave. This not only saves time and dispenses with



856 H. Tobushi et al.

the need for hammering, but also means that the unevenness left from plastic deformation is
much reduced so that the spatula can be reused over and over.

Fig. 1. Illustration of a brain spatula in surgical use

The instruments treated in this study have been recently developed and are precision-cast
in a lost-wax process of the self-combustion high-temperature synthesis method (Yoshimi et
al., 2008). The brain spatula needs to form itself into unique shapes according to the brain
configurations of individual patients and, as canbe seen fromthe examples inFig. 2, the spatulas
themselves also come in intricate forms that are a challenge to create in theTiNi SMAmaterial.
The precision casting technique makes it much easier for these tools to bemanufactured.

Fig. 2. Examples of precision-cast TiNi SMA brain spatulas; (a) whole rake-type brain spatula against
a centimeter scale, (b) tip of the rake-type brain spatula, (c) batch of brain spatulas just after

precision casting

The conditions required of a brain spatula are, first, that it can be bent to any desired shape
to fit the brain being operated on and, second, that it should have sufficient rigidity to be able
to keep the brain incision open during the operation. These requirements can be specified in
terms of the bendingdeformation properties of the instrument, including its bending rigidity. To



Performance and design of precision-cast shape memory alloy... 857

evaluate the reliability of abrain spatula fromthepoint of viewof safety, the fatigue properties of
thematerial are crucial, and to investigate these, the spatula has to be subjected to cyclic plane
bending. This paper is the first reported study of the plane bending properties of a TiNi SMA
considered as the material for a brain spatula.

For the present study, in pursuit of the development of the SMAbrain spatula, tension tests
were conducted to examine stress-strain relations in three materials: the newly introduced cast
TiNi SMA, a TiNi SMA of the conventional rolled type, and copper of the type used in brain
spatulas up until now. The shape and dimension requirements of an SMA brain spatula were
investigated on the basis of the bending deformation properties of a strip cantilever. Further, an
investigation was also conducted into the fatigue properties of thematerials, which is a question
of extreme importance for the practicalities of their cyclic use.

2. Experimental method

2.1. Materials and specimens

The materials used in the experiment were a new-type cast Ti-49.7at%Ni SMA, a conven-
tional rolled Ti-50.0at%Ni SMA, and copper as used in brain spatulas hitherto. The new cast
SMA was produced by precision casting using a lost-wax process from a self-combustion high-
temperature synthesismethod (Yoshimi et al., 2008). Samples of the cast and rolled SMAswere
shape-memorized by fixing them in a flat plane for 40min at a furnace temperature of 753Kand
then quenching them inwater. The starting andfinishing temperatures for theMTof the SMAs,
Ms and Mf, and those for the reverse transformation, As and Af, were obtained from theDSC
(differential scanning calorimetric) tests. The values obtained were Ms = 326K, Mf = 312K,
As = 342K, Af = 365K for the rolled SMA and Ms = 358K, Mf = 283K, As = 314K,
Af = 386K for the cast SMA. The specimens used in the tension tests were the uniform rec-
tangular bars with a thickness t=1.0mm, width w =1.2mm and length l= 160mm for the
rolled and cast SMAs, with corresponding values of t= 1.0mm, w = 8.5mm and l =140mm
for the copper. In the fatigue tests, all specimens were bars with dimensions of t = 1.0mm,
w=1.2mm and l=80mm.

2.2. Experimental apparatus

An SMA characteristic-testing machine was used for the tension test (Tobushi et al., 1992).
The testingmachinewas composed of a tension control for loading andunloading and a heating-
cooling device to control temperature. Displacements of the specimen were measured using an
extensometer with a gauge length of 50mm.

Fig. 3. Experimental apparatus for alternating-plane bending fatigue test; 1O specimen, 2O grip,
3
O speed controller, 4O cycle counter, 5Omotor, 6O power source, 7O crank 1, 8O crank 2, 9O bearing



858 H. Tobushi et al.

Amachine for the testing of alternating-plane bending fatigue (Furuichi et al., 2003), for use
in the fatigue tests, is shown inFig. 3. In the fatigue testing, themaximumbending strain occurs
in the central part of the specimen 1O, and the tensile and compressive bending strains occur
alternately. Usewas alsomade in the fatigue tests of amachine for the testing of pulsating-plane
bending fatigue (Tobushi et al., 2001). In the alternating- andpulsating-plane bending tests, the
maximum bending strain on the surface of the specimen was selected and the number of cycles
to failure was obtained under a constant frequency. A scanning electron microscope (SEM)was
used to observe the fracture surface of the specimen.

2.3. Experimental procedure

The tension tests were carried out under a constant strain rate in air at room temperature
below the Mf point of the SMA bars. Since the yielding of the SMA occurs under low stress in
the M-phase, the SMA-brain spatula can be bent with a very small force. In the case of SMA
bars in the M-phase, a residual strain appears after unloading. SMA bars showing the residual
strainwere heated up to temperatures above the Af point under no load. In this heating process
of the SMA bars, the residual strain was found to diminish due to the reverse transformation
between the As and Af points.

The tests for alternating- andpulsating-plane bending fatiguewere carried out in air at room
temperature. Every specimen fractured in the central part of its length between the grips, which
is where the bending strain reaches its maximum value. The maximum bending strain εm on
the surface of the specimen was obtained from the radius of curvature at the point of fracture.
The frequency f was found to be 8.33Hz (500cpm) and 3.33Hz (200cpm), respectively.

3. Deformation properties of materials used for brain spatula

3.1. Tensile deformation properties

The stress-strain curves of the copper, the rolled and the cast SMAs obtained from the
tension test under a strain rate of dε/dt = 2 · 10−4 s−1 are shown in Fig. 4. As can be seen
in Fig. 4, a linear elastic deformation occurs in the initial loading stage and yielding occurs
thereafter. The modulus of elasticity E determined from the slope of the initial stress-strain

Fig. 4. Tensile stress-strain curves for copper, rolled SMA and cast SMA asmaterials for brain spatulas

curve is 40GPa for the rolled SMA, 54GPa for the cast SMA and 95GPa for the copper.
Approximating the elastic and yield regions of the stress-strain curves to two straight lines,
the yield stress σM was determined from the intersection of these lines. This gave a value of
68MPa for the rolled SMA, 168MPa for the cast SMA and 240MPa for the copper. In the
case of the copper, the deformation seen at strain levels of above 0.2% occurs due to plastic



Performance and design of precision-cast shape memory alloy... 859

deformation with dislocations. For example, in the unloading process from a strain of 4%, there
is a strain recovery of 0.25% corresponding to the elastic deformation, leaving the residual strain
as permanent strain. In the cases of the SMAs, however, since thematerial is in theM-phase at
room temperature below the Mf point, yielding occurs due to rearrangements in theM-phase.
In the unloading process from the same strain of 4%, there is a strain recovery of 0.6% for the
rolled, and 0.8% for the cast SMA, leaving the residual strains of 3.4% and 3.2% respectively
after unloading.

Fig. 5. Strain-temperature curves for the rolled and cast SMA in tension, with unloading followed by
heating without loading

The relationships between strain and temperature for the cast and rolled SMAs, obtained
from tension testswith unloading followed by heating in the absence of load, are shown inFig. 5.
The symbols As:C, As:R, Af:C and Af:R in Fig. 5 represent the starting and finishing tempe-
ratures for the reverse-transformation in the cases of the cast and rolled SMAs, respectively. In
the heating process under no load, strain begins to recover gradually around As and disappears
altogether around Af. The SME behind this strain recovery occurs as a result of the reverse
transformation from theM-phase to the parent (austenite) phase.

3.2. Comparison of characteristic values for deformation

Table 1 sets out the values of the modulus of elasticity E, the yield stress σM, the yield
strain εM and the hardeningmodulus k for the copper, the rolled and the cast SMAsmaterials,
as obtained from the tension tests. As can be seen, both themodulus of elasticity and the yield
stress are lower for the rolled and the cast SMAs than for the copper. These differences account
for the residence to bendingdeformation in the SMAmaterials, and also for the bending rigidity
which allows the brain incision to be held open in a particular shape during the operation. In
the next section, the bending deformation properties of brain spatulas made of these materials
will be discussed.

4. Bending characteristics of copper and SMA brain spatulas

In order to design an SMA brain spatula, it is important to evaluate the force required for
bending of the spatula in operational use and the bending rigidity required for brain incision to
be held open during the operation.With a focus on these two bendingdeformation properties in
spatulasmade of copper and SMA, the required specifications for an SMAbrain spatula will be
clarified.Conceiving of the existing type of brain spatula as a bendable cantilevermade of a strip
of material with a uniform rectangular cross-section, the length of the strip can be expressed
by l, the width of the cross-section by w and the thickness by t.



860 H. Tobushi et al.

Table 1. Values of modulus of elasticity, yield stress, yield strain and hardening modulus for
copper, rolled SMA and cast SMAs

Materials Copper
Rolled SMA Cast SMA
(M-phase) (M-phase)

Modulus of elasticity
95 40 54

E [GPa]

Yield stress
240 68 168

σM [MPa]

Yield strain
0.25 0.17 0.34

εM [%]

Hardening modulus
0 2.6 2.5

k [GPa]

4.1. Bending rigidity required to hold the brain spatula in its bent form

In order to maintain the chosen displacement in the part of the brain that is opened during
the operation, it is required that the brain spatula should remain stable in its bent form (see
Fig. 1). This requirement can be quantified in terms of the maximum permitted deflection in a
cantilever made of the specifiedmaterials. Let us consider, in particular, the conditions required
in each case for obtaining the samemaximum deflection ymax in response to the same force F
applied at the top of the cantilever. The maximum deflection of the cantilever ymax can be
expressed using the secondmoment of area Iz =wt

3/12 from the theory of elasticity as follows

ymax =
Fl3

3EIz
=
4Fl3

Ewt3
(4.1)

Assuming that this maximumdeflection ymax in strips subjected to the same force F coincides
for the copper and SMAmaterials, the following equation is obtained

ymax =
4Fl3Cu

ECuwCut
3
Cu

=
4Fl3SMA

ESMAwSMAt
3
SMA

(4.2)

From the practical point of view of a brain operation, the width w and the length l of an
SMA brain spatula are expected to offer the same values as for a conventional spatula made
of copper. Therefore, it is appropriate to assume that the length and width dimensions of both
kinds of spatula will coincide, leaving only the thickness t to differ. The thickness for the SMA
spatula tSMA can be found from Eq. (4.2) as follows

tSMA = tCu
3

√

ECu
ESMA

(4.3)

If the values for the modulus of elasticity shown for the copper and SMA materials in Table 1
are now substituted in Eq. (4.3), the bending rigidities of the three types of spatulas will be
found to coincide when the rolled SMA spatula has a thickness of 1.3 times, and the cast SMA
spatula a thickness of 1.2 times that of the copper spatula. These are the conditions, in other
words, in which the same deflection and bending rigidity can be obtained from the SMA brain
spatulas as from the copper one.

4.2. Force required to bend brain spatula

In a brain operation, the surgeon has to bend the spatula to fit the exact shape and depth of
the part of the brain being opened. The force required to bend the brain spatula is evaluated as



Performance and design of precision-cast shape memory alloy... 861

the force applied at the top of the cantilever to obtain the requiredmaximumbending strain.As
shown in Fig. 6a, the yield (transformed) regions of the strip during bending occur at the inner
and outer surfaces of the cantilever. A schematic stress-strain diagram and the distributions of
bending strains and stresses in the strip are shown in Figs. 6b, and 7, respectively. In Fig. 6b, it
is assumed that the yielding region can be expressed by the linear hardening with a hardening
modulus k while the yield stress and yield strain are expressed by σM and εM, respectively. In
these figures, the maximum bending stress and strain are denoted by σm and εm, respectively.
It is assumed that the yield stress σM is the same in tension as in compression.

Fig. 6. (a) Elastic and transformed regions of the specimen in bending; (b) stress-strain diagram

Fig. 7. Bending strain (a) and stress (b) distribution in the specimen

Let us first consider the bending moment Me required to produce the elastic region of the
strip in bending. The thickness of the elastic region tM is tM =(εM/εm)t. Since the maximum
bending stress in the elastic region σmax is the sameas the yield stress σM, the bendingmoment
required for the elastic region Me is Me = σMZ, where Z denotes the section modulus and
Z =wt2M/6. Accordingly, the bendingmoment Me for the elastic region is

Me =
σMwt

2

6

(εM
εm

)2

(4.4)

Next, let us turn our attention to the bendingmoment My required to create the yield (transfor-
med) region of the strip. The center of the yield region yc from the neutral axis z is calculated
as

yc =
tc
2
=
t

4

(

1+
εM
εm

)

(4.5)

The area Ay of the yield region in the tension side of the cross section is

Ay =
wt

2

(

1−
εM
εm

)

(4.6)

Considering the stress distribution in the yield region and the symmetric match between the
tension and compression sides, the bending moment My required to create the yield region is
obtained as follows



862 H. Tobushi et al.

My =
1

2
(σM +σm)Aytc =

1

8
[2σM +k(εm−εM)]wt

2
[

1−
(εM
εm

)2]

(4.7)

The total bending moment M required to bend the brain spatula is the sum of the bending
moment Me for the elastic region and the bendingmoment My for the yield region

M =Me+My =
wt2

24

{

2σM
[

3−
(εM
εm

)2]

+3k(εm−εM)
[

1−
(εM
εm

)2]}

(4.8)

Since the bendingmoment M =Fl, the force required is

F =
wt2

24l

{

2σM
[

3−
(εM
εm

)2]

+3k(εm−εM)
[

1−
(εM
εm

)2]}

(4.9)

The condition that the forces required to benda copper spatulawith k=0and an SMAspatula
coincide can be expressed as follows

F =
σMCuwCut

2
Cu

12lCu

[

3−
(εMCu
εmCu

)2]

(4.10)

=
wSMAt

2
SMA

24lSMA

{

2σMSMA
[

3−
(εMSMA
εmSMA

)2]

+3kSMA(εmSMA−εMSMA)
[

1−
(εMSMA
εmSMA

)2]}

If the length l, thewidth w and themaximumbending strain εm of both spatulas coincide only
the thickness to differ, the thickness of the SMA brain spatula is

tSMA = tCu

√

√

√

√

√

√

√

2σMCu
[

3−
(

εMCu
εm

)2]

2σMSMA
[

3−
(

εMSMA
εm

)2]

+3kSMA(εm−εMSMA)
[

1−
(

εMSMA
εm

)2]
(4.11)

The yield stress σM, the yield strain εM and the hardeningmodulus k for the three types of
materials are shown inTable 1.Using these values, the thickness of the SMAbrain spatula tSMA
can be obtained fromEq. (4.11). The calculated relations between the thickness ratio tSMA/tCu
and themaximum bending strain εm are shown in Fig. 8. If thematerial of the thickness tSMA

Fig. 8. Relationship between the thickness ratio tSMA/tCu and the maximum bending strain εm
calculated fromEq. (4.11)

shown in this figure is used, an SMA spatula can be bent by the same force as that required for
a conventional copper spatula. As can also be seen fromFig. 8, themaximumbending strain εm
exerts very little effect on the ratio of tSMA to tCu except in an area of small εm values close to
the yield strain εM. When the thicknesses of the rolled and cast SMA spatulas are 1.85 times
and1.20 times that of the copper spatula, respectively, the SMAspatula can bebentbyapplying
the same force as with an existing copper spatula.



Performance and design of precision-cast shape memory alloy... 863

4.3. Shape of SMA brain spatula

Thediscussion in Sections 4.1 and4.2will havemade clear that if the length and thewidthof
a rolled SMAbrain spatula are the same as those of the existing copper typewhile the thickness
is 1.3 times as large, the rolled SMA spatula is capable of the same bending rigidity and can be
easily bent using a smaller force than required for the copper one. Similarly, if the thickness of
the cast SMA spatula is 1.2 times that of the copper one, the cast SMA spatula is capable of
the same bending rigidity and can be bent by the same force as an existing copper one.

5. Bending fatigue properties

5.1. Fatigue life in alternating-plane bending

Figure 9 shows the relationship between the maximum bending strain εm and the number
of cycles to failure Nf for the rolled SMA, the cast SMA and the copper one, as obtained from
the alternating-plane bending fatigue test. For all threematerials, the larger the εm, the smaller
the Nf. It can also be seen that the fatigue life of the rolled SMA is 100 times longer than that of
the copper, and that the fatigue life of the cast SMA is also 100 times longer that of the copper
in the region where εm is small and 10 times longer in the region where it is large. The fatigue
life of the copper is several hundredcycles at εm =1%,which is almost the sameas the low-cycle
fatigue life of normalmetals (Shigley andMischke, 1989). In the case of copper, the yield strain is
causedby slip in the crystals andplastic deformation occurs repeatedly, resulting in short fatigue
life. In the SMAs, the yield strain is not caused by permanent slip but by a recoverable rearran-
gement of theM-phase, which accounts for the long fatigue life. In the case of the cast SMA, as
already observed in Fig. 4, stress increases with an increase in strain, and this in turn results in
the shortening of the fatigue life with an increase in themaximumbending strain. The influence
of the frequency on the fatigue life of the threematerials is not clear for f =3.33Hz and8.33Hz.
For the case of a TiNi SMA wire, it has been found that the lower the frequency, the longer
the fatigue life (Tobushi et al., 2000). This being so, the frequency of an SMA brain spatula in
practical use should be lower than this range between 3.33Hz and 8.33Hz. In practice, therefore,
the actual fatigue life of the material in use will be longer than that obtained in the present
study.

Fig. 9. Fatigue life curves for copper, rolled SMA and cast SMA under alternating-plane bending

In the low-cycle fatigue region of Fig. 9, the fatigue life curves of all three materials tested
can be approximated by straight lines. Since the relationship between εm and Nf can also be
expressed by a straight line on the logarithmic graph, the relationship can be expressed by a



864 H. Tobushi et al.

power function similar to the fatigue life for TiNi SMAwires and tubes (Matsui et al., 2004) as
follows

εmN
β
f
=α (5.1)

where αdenotes εm at Nf =1and β denotes the slopeof the logεm−logNf curve, respectively.
The results calculated fromEq. (5.1) with values of β=0.58 and α=0.25 for copper, β=0.41
and α= 0.67 for the rolled SMA and β = 0.14 and α= 0.05 for the cast SMA are shown by
solid lines in Fig. 9. As can be seen, these calculated results generally match up well with the
inclinations obtained by testing.

5.2. Fatigue life in pulsating-plane bending

Figure 10 shows the relationship between maximum bending strain εm and the number of
cycles to failure Nf for the rolled SMA, the cast SMA and the copper one, as obtained from
the pulsating-plane bending fatigue test. Here too, the larger the εm, the smaller the Nf for all
three materials. The fatigue life of the rolled SMA is 100 times longer than that of the copper,
and that of the cast SMA is 40 times longer. The fatigue life of the copper is two thousand cycles
at εm = 2%. Again as observed in Fig. 4, the yield stress is higher for the cast SMA than for
the rolled SMA, resulting in shorter fatigue life.

Fig. 10. Fatigue-life curves for copper, rolled SMA and cast SMA used for brain spatula under
pulsating-plane bending

As in Fig. 9, the fatigue life curves of all three materials in the low-cycle fatigue region can
be approximated by straight lines, meaning that the relationship can be expressed by a power
function of Eq. (5.1). The calculated results from Eq. (5.1) with β = 0.35 and α = 0.26 for
copper, β = 0.26 and α = 0.43 for the rolled SMA and β = 0.29 and α = 0.49 for the cast
SMAare shown by the solid lines in Fig. 10. As can be seen, these calculated results again show
a good overall match with the test inclinations.

5.3. Comparison of fatigue life

The relationships between the maximum bending strain εm and the number of cycles to
failure Nf obtained from the alternating- and pulsating-plane bending fatigue tests are brought
together in Fig. 11 for the rolled, and in Fig. 12 for the cast SMA. In both cases, the fatigue
life is shorter in alternating-plane bending than in pulsating-plane bending. Since the amount
of work dissipated in each cycle is greater in the case of alternating-plane bending, a longer
fatigue life can be obtained for an SMA brain spatula in use by fixing the bending direction to
result in pulsating bending. The influence of the dissipatedwork Wd on the difference in fatigue
life between the cases of alternating- and pulsating-plane bending can be explained as follows.
The stress-strain relations and the amount of work dissipated Wd at each cycle of pulsating-



Performance and design of precision-cast shape memory alloy... 865

or alternating-plane bending are shown, respectively, in diagrams (a) and (b) in Fig. 13, where
it is assumed that the yielding region is expressed by the linear hardening with a hardening
modulus k and that the yield stress σM is constant under cyclic deformation and has the same
value under tension and compression. The area enclosed by the hysteresis loop gives a measure
of the work dissipated Wd per unit volume in each cycle.

Fig. 11. Relationship between the maximum bending strain and number of cycles to failure for the
rolled SMA under alternating-plane and pulsating-plane bending

Fig. 12. Relationship between the maximum bending strain and number of cycles to failure for the cast
SMA under alternating-plane and pulsating-plane bending

Fig. 13. Stress-strain diagram and dissipated work Wd in the initial cycle under pulsating-plane
bending (a) and alternating-plane bending (b)

Thework dissipated in N =2 is expressed by the following equation for the pulsating-plane
bending

Wd =
(

1−
k

E

)[

σM
(

2−
k

E

)

+k
(

1−
k

E

)(

εm−
σM
E

)][(

1−
k

E

)(

εm−
σM
E

)

−
σM
E

]

(5.2)



866 H. Tobushi et al.

while the work dissipated for the same cycle of alternating-plane bending is

Wd =4
E−k

E+k

(

εm−
σM +kεm
E+k

)

(σM +kεm) (5.3)

where E and εm represent the elastic modulus and themaximum bending strain in each cycle,
respectively. It can be seen from Eqs. (5.2) and (5.3) that Wd increases in proportion to both
σM and εm. The quantitative relationship between the fatigue life Nf and dissipated work Wd
obtained fromEqs. (5.2) and (5.3) is shown in Fig. 14 for the rolled, and in Fig. 15 for the cast
SMA. In both cases, the relationship between Nf and Wd can be matched approximately by
a single straight line taking in both the alternating- and the pulsating-plane bending. In other
words, the unified relationship between the fatigue life Nf and dissipated work Wd under both
alternating- and pulsating-plane bending can be expressed by the same power function

WdN
λ
f =µ (5.4)

where µ and λ denote Wd in Nf =1 and the slope of the logWd− logNf curves, respectively.
Results calculated from this equation are shown by the solid lines in Fig. 14, with values of
λ= 0.45 and µ= 408MJ/m3, for the rolled SMA and in Fig. 15, with values of λ= 0.29 and
µ=88MJ/m3, for the cast SMA.As can be seen, the solid lines show a good overall matchwith
the test results. In the case of the rolled SMA in Fig. 14, the range 2 ·103 ¬Nf ¬ 5 ·10

4, in the
number of cycles to failure represents the fatigue life under alternating-plane bending, while the
range 2 ·104 ¬Nf ¬ 1 ·10

6 represents that under pulsating-plane bending. The corresponding
ranges for the cast SMA in Fig. 15 are 1 · 101 ¬ Nf ¬ 3 · 10

4 cycles under alternating-plane
bending and 1 ·104 ¬Nf ¬ 1 ·10

6 cycles under pulsating-plane bending. For the cast SMA, the
value of Wd ismuch larger under alternating-plane bending thanunder pulsating-plane bending.
That is why the fatigue life of a cast SMA is shorter under alternating-plane bending for a large
maximum bending strain εm. To sum up, as already mentioned above, the unified relationship
between Wd and Nf is of great usefulness for evaluating the fatigue life of a rolled SMA or a
cast SMA under conditions of either alternating- or pulsating-plane bending.

Fig. 14. Relationship between the dissipated work Wd and number of cycles to failure for the rolled
SMA under alternating-plane and pulsating-plane bending

5.4. Temperature rise under cyclic bending

The surface portion of the specimen is subjected to the effects of dissipated work in each
cycle as discussed in Section 5.3. Therefore, the temperature of the specimen can be expected
to increase under cyclic bending. The surface temperature in the central part of a rolled SMA
strip was measured using a thermocouple under conditions of alternating-plane bending at a
frequency of f =3.33Hz. The relationship between the incremental temperature rise ∆T and



Performance and design of precision-cast shape memory alloy... 867

Fig. 15. Relationship between the dissipated work Wd and number of cycles to failure for the cast SMA
under alternating-plane and pulsating-plane bending

Fig. 16. Relationships between the incremental temperature rise and time for the rolled SMA at two
different maximum bending strains, under alternating-plane bending at f =3.33Hz

Fig. 17. Relationships between the temperature rise saturation points andmaximum bending strains,
for the rolled and cast SMAs under alternating-plane bending at at f =3.33Hz

time is shown in Fig. 16. In the first 20 seconds or so, the temperature increases rapidly, but
once the amount of heat generated comes to match the amount released a saturation level is
reached for ∆T .

The relationship between the saturation point for the temperature rise ∆Ts and the maxi-
mumbending strain εm is shown inFig. 17 for the rolled and the cast SMAsat f =3.33Hz.The
saturation point increases in proportion to the rise in εm. The value of ∆Ts is a little higher for
the cast than for the rolled SMA, rising to around 30K at εm =3%. The yield stress σM also
increases with temperature, at a rate of 5MPa/K in the case of a TiNi SMA. For ∆T =30K,
this gives a yield stress increase of 150MPa.This explainswhy the fatigue damage is large under
alternating-plane bending for a large εm. In practical use in a brain spatula, the frequency will
be low and the temperature rise only small, resulting in a much longer fatigue life than that
obtained in the present study.



868 H. Tobushi et al.

6. Conclusions

In order to develop the SMA-brain spatula, themechanical characteristics of theTiNi cast- and
rolled-SMAs and the copper one used for the brain spatula were compared based on the tensile
deformation properties, and the characteristics of the SMA-brain spatula were discussed. The
fatigue properties of these materials were also investigated by pulsating- and alternating-plane
bending fatigue tests. The results obtained can be summarized as follows.

(1) Based on the yield stress and themodulus of elasticity of the copper and the TiNi SMAs,
the bending deformation properties of the SMA-brain spatulawere estimated by assuming
the condition to use the brain spatula as the bending of the strip cantilever.With respect
to the SMA-brain spatula for the same length and width as the existing copper one, if
the thickness of the conventional rolled-SMA spatula is 1.3 times as large as that of the
existing copper-brain spatula, the SMA spatula can hold the same bending rigidity and
can be bent by a smaller force than the existing copper one. If the thickness of the new
cast-SMA spatula is 1.2 times as large as that of the existing-copper spatula, the SMA
spatula can hold the same bending rigidity and can be bent by the same force as the
existing copper one.

(2) With respect to the alternating- and pulsating-plane bending fatigue, the fatigue life of
both the copper and the SMAs in the region of low-cycle fatigue is expressed by a power
function of the maximum bending strain. The fatigue life of the conventional rolled SMA
and the new cast SMA is longer than that of the existing copper. The fatigue life of the
rolled SMA is longer than that of the cast SMA. The fatigue life of the new cast and
rolled SMAs in the pulsating-plane bending is longer than that in the alternating-plane
bending. The fatigue life of the rolled SMA and cast SMA for alternating- and pulsating-
plane bendings can be expressed by the unified relationship with a power function of the
dissipated work.

(3) The abovementioned characteristics of the SMA-brain spatula obtained in this studywill
be substantially applied to the development not only for the brain spatula but also for
other retractors and instruments used in other surgery operations.

Acknowledgment

The experimentalwork of this studywas carried outwith the assistance of students inAichi Institute

of Technology, to whom the authors wish to express their gratitude. The samples of the existing copper-

brain spatula were supplied byMizuhoCo., Ltd., to whom the authorswish to express their gratefulness.

The authors also wish to extend their thanks to the Basic Research (C) of Grant-in-Aid of Scientific

Research supportedbyJapanSociety forPromotionof Sciences and theProgramofSupport forAdvanced

Corporate Networking supported by Chubu Bureau, Ministry of Economy, Trade and Industry, METI

for their financial support.

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Performance and design of precision-cast shape memory alloy... 869

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Konstrukcja i właściwości użytkowe odlewanej szpatułki chirurgicznej wykonanej ze stopu

z pamięcią kształtu

Streszczenie

W pracy opisano problem projektowania szpatułki używanej w chirurgii mózgu, wykonanej ze stopu
z pamięcią kształtu (SMA). Przedyskutowano charakterystyki zginania nowej szpatułki wykonanej z pre-
cyzyjnie odlewanego stopu TiNi.Wyniki badań podsumowano w następujący sposób: (1) w porównaniu
do konwencjonalnych, miedzianych szpatułek o tej samej długości i szerokości, jeśli odlewana szpatułka
SMA jest 1.2 raza grubsza od miedzianej, lub 1.3 raza, gdy wykonana została przez walcowanie, instru-
ment ten będzie posiadał taką samą sztywność giętną i wytrzyma niemalże to samo obciążenie zginające,
jak w przypadku narzędzia miedzianego; (2) wyrażając wytrzymałość zmęczeniową szpatułki miedzianej
w rejonie niskocyklicznych obciążeń jako funkcję potęgową maksymalnego odkształcenia przy zginaniu,
stwierdzono, że szpatułki SMA wykazują dłuższą żywotność od konwencjonalnych.W obydwu przypad-
kach – odlewanej i walcowanej szpatułki SMA – wytrzymałość zmęczeniowa jest większa dla płaskiego
jednostronnego zginania od wytrzymałości przy zginaniu przemiennym.

Manuscript received January 30, 2012; accepted for print February 12, 2012