Shape memory alloys (SMAs) are metals that undergo a change in crystalline structure within a relatively narrow temperature range. A phase transformation from martensite to austenite can induce relatively large changes in the overall dimensions of the SMA. Hence, SMAs can be employed as mechanical actuators. Consider an SMA rod that is initially D i = 2 mm in diameter, L i = 40 mm long, and at a uniform temperature of T i = 320 K . The specific heat of the SMA varies significantly with changes in the crystalline phase. hence cvaries with the temperature of the material. For a particular SMA, this relationship is well described by c = 500 J/kg ⋅ K + 3630 J/kg ⋅ K × e ( − 0.808 K − 1 × | T − 336 K | ) . density and thermal conductivity of the SMA material are ρ = 8900 kg/m 3 and k = 23 W/m ⋅ K, respectively. The SMA rod is exposed to a hot gas characterized by T ∞ = 350 K , h = 250 W/m 2 ⋅ K . Plot the rod temperature versus time for 0 ≤ t ≤ 60 s for the cases of variable and constant ( c = 500 J/kg ⋅ K ) specific heats. Determine the time needed for the rod temperature to experience 95 % of its maximum temperature change. Hint: Neglect the change in the dimensions of the SMA rod when calculating the thermal response of the rod.
Shape memory alloys (SMAs) are metals that undergo a change in crystalline structure within a relatively narrow temperature range. A phase transformation from martensite to austenite can induce relatively large changes in the overall dimensions of the SMA. Hence, SMAs can be employed as mechanical actuators. Consider an SMA rod that is initially D i = 2 mm in diameter, L i = 40 mm long, and at a uniform temperature of T i = 320 K . The specific heat of the SMA varies significantly with changes in the crystalline phase. hence cvaries with the temperature of the material. For a particular SMA, this relationship is well described by c = 500 J/kg ⋅ K + 3630 J/kg ⋅ K × e ( − 0.808 K − 1 × | T − 336 K | ) . density and thermal conductivity of the SMA material are ρ = 8900 kg/m 3 and k = 23 W/m ⋅ K, respectively. The SMA rod is exposed to a hot gas characterized by T ∞ = 350 K , h = 250 W/m 2 ⋅ K . Plot the rod temperature versus time for 0 ≤ t ≤ 60 s for the cases of variable and constant ( c = 500 J/kg ⋅ K ) specific heats. Determine the time needed for the rod temperature to experience 95 % of its maximum temperature change. Hint: Neglect the change in the dimensions of the SMA rod when calculating the thermal response of the rod.
Solution Summary: The author plots the time required for the rod to reach 95% of the maximum possible temperature change for variable and constant specific heats.
Shape memory alloys (SMAs) are metals that undergo a change in crystalline structure within a relatively narrow temperature range. A phase transformation from martensite to austenite can induce relatively large changes in the overall dimensions of the SMA. Hence, SMAs can be employed as mechanical actuators. Consider an SMA rod that is initially
D
i
=
2
mm
in diameter,
L
i
=
40
mm
long, and at a uniform temperature of
T
i
=
320
K
.
The specific heat of the SMA varies significantly with changes in the crystalline phase. hence cvaries with the temperature of the material. For a particular SMA, this relationship is well described by
c
=
500
J/kg
⋅
K
+
3630
J/kg
⋅
K
×
e
(
−
0.808
K
−
1
×
|
T
−
336
K
|
)
.
density and thermal conductivity of the SMA material are
ρ
=
8900
kg/m
3
and
k
=
23
W/m
⋅
K,
respectively. The SMA rod is exposed to a hot gas characterized by
T
∞
=
350
K
,
h
=
250
W/m
2
⋅
K
.
Plot the rod temperature versus time for
0
≤
t
≤
60
s
for the cases of variable and constant
(
c
=
500
J/kg
⋅
K
)
specific heats. Determine the time needed for the rod temperature to experience
95
%
of its maximum temperature change. Hint: Neglect the change in the dimensions of the SMA rod when calculating the thermal response of the rod.
Branch of science that deals with the stationary and moving bodies under the influence of forces.
DO NOT COPY SOLUTION
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