JOURNAL OF THERMOELASTICITY ISSN 2328-2401 (print) ISSN 2328-241X (Online)
VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html
Influence of Gravity Field and Rotation on a Generalized Thermoelastic Medium using a Dual-Phase-Lag Model Mohamed I. A. Othman, W. M. Hasona and Ebtesam E. M. Eraki
compatible with physical observations was introduced "by Biot
Abstract— In the present paper, The normal mode analysis
[1]". First, the equation of heat conduction of this theory does
is used to study the deformation of a rotating generalized
not contain any elastic terms. Second, the heat equation is of a
thermoelastic medium under the influence of gravity subjected
to
thermal
loading
in
the
context
parabolic type, predicting infinite speeds of propagation for
of
heat waves. The governing equations for Biot theory are
dual-phase-lag thermoelastic model. The exact expressions
coupled, eliminating the first paradox of the classical theory.
for the temperature, displacement components, and stress
However, both theories share the second shortcoming since the
components are given in the physical domain and
heat equation for the coupled theory is also parabolic.
illustrated graphically. These expressions are calculated
Thermoelasticity theories that predict a finite speed for the
numerically for the problem. Comparisons are made with
propagation of thermal signals have aroused much interest in
the results predicted by Lord-Shulman theory and
the last three decades. These theories are known as generalized
dual-phase-lag model in the presence and absence of
thermoelasticity theories. The first generalization of the
rotation as well as gravity.
thermo-elasticity theory is due to "Lord and Shulman [2]", who introduced the theory of generalized thermoelasticity with one
Keywords — (Thermoelasticity, generalized thermoelasticity, rotation, gravity, dual- phase-lag model, normal mode analysis
relaxation time by postulating a new law of heat conduction to replace the classical Fourier’ law. This law contains the heat flux vector as well as its time derivative. It contains also a new constant that acts as a relaxation time. The heat equation of this
I. INTRODUCTION
theory is of the wave-type, ensuring finite speeds of
The theory of coupled thermoelasticity to overcome the first shortcoming
in
the
classical
uncoupled
theory
propagation for heat and elastic waves. The remaining
of
governing equations for this theory, namely, the equations of
thermoelasticity where it predicts two phenomena not
motion and the constitutive relations remain the same as those for the coupled and the uncoupled theories. This theory was M. I. Othman, Department of Mathematics, Faculty of Science, P.O. Box 44519, Zagazig University, Zagazig, Egypt (Email:
[email protected]) W. M. Hasona, Department of Mathematics, Faculty of Science, P.O. Box 44519, Zagazig University, Zagazig, Egypt (Email:
[email protected]) Ebtesam E. Erakil, Department of Mathematics, Faculty of Science, P.O. Box 44519, Zagazig University, Zagazig, Egypt (Email:
[email protected])
extended "by Dhaliwal and Sherief [3]" to general anisotropic media in the presence of heat sources. A generalization of this inequality was proposed "by Green and Laws [4]". Another version of the constitutive equations was obtained "by Green and Lindsay [5]". The theory
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JOURNAL OF THERMOELASTICITY ISSN 2328-2401 (print) ISSN 2328-241X (Online)
VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html
of thermoelasticity without energy dissipation is another
conducting elastic half-space was presented "by Chand [11]".
generalized theory and was formulated "by Green and Naghdi
The effect of rotation on elastic waves has been studied "by
[6]". It includes the thermal displacement gradient among its
many authors [12-15]". The effect of rotation on different types
independent constitutive variables, and differs from the
of wave propagating in a thermoelastic medium was discussed
previous theories in that it does not accommodate dissipation of
"by Sharma and his co-workers [16-17]". The effect of rotation
thermal energy.
in a magneto-thermoelastic medium was discussed by "Othman
The dual-phase-lag (DPL) model, which describes the
and Song [18]". The effect of rotation on propagation of plane
interactions between phonons and electrons on the microscopic
waves in generalized thermoelasticity has been studied "by
level as retarding sources causing a delayed response on the
Singh and Tomer [19]". The effect of rotation on
macroscopic scale, was proposed "by Tzou [7,8]". For
two-dimensional problem of fiber-reinforced thermoelastic
macroscopic formulation, it would be convenient to use the
with one relaxation time was investigated "by Othman and said
DPL model for investigation of the micro-structural effect on
[20]".
the behavior of heat transfer. The physical meanings and the
In the classical theory of elasticity, the gravity effect is
applicability of the DPL model have been supported "by the
generally neglected. The effect of gravity in the problem of
experimental results [9]". The dual-phase-lag is such a
propagation of waves in solids, in particular on an elastic globe,
modification of the classical thermoelastic model in which the
was first studied "by Bromwich in [21]". Subsequently, an
Fourier's law is replaced by an approximation to a modified
investigation of the effect of gravity was considered "by Love
Fourier's law with two different time translations: a phase-lag
in [22]", who showed that the velocity of Rayleigh waves is
q and a phase-lag of temperature gradient .
increased to a significant extent by gravitational field when
of the heat flux
wavelengths are large. The effect of gravity on surface waves,
A Taylor series approximation of the modified Fourier's law,
on the propagation of waves in an elastic layer has been studied
together with the remaining field equations leads to a complete
"by De and Sengupta in [23-24]". Surface waves under the
system of equations describing a dual-phase-lag thermoelastic
influence of gravity in a non-homogeneous elastic solid
model. The model transmits thermoelastic disturbance in a
medium was investigated "by Das et al. [25]". Wave
wave-like manner if the approximation is linear with respect to
q and , and 0 ≤ < q
; or quadratic in
q
propagation in a non-homogeneous orthotropic elastic medium and linear in
under the influence of gravity was discussed "by Abd-Alla and
, with q > 0 and > 0. This theory is developed in a Ahmed [26]". The effects of rotation and gravity in generalized rational way to produce a fully consistent theory which is able
thermoelastic medium has been depicted "by Ailawalia and
to incorporate thermal pulse transmission in a very logical
Narah [27]". The influences of rotation, magnetic field, initial
manner.
stress and gravity on Rayleigh in a homogeneous orthotropic
Some researches in past have investigated different problems
elastic half space was studied "by Abd-Alla [28]". Recently,
of rotating media. The propagation of plane harmonic waves in
The effect of magnetic field and rotation of the 2-D problem of
a rotating elastic medium without a thermal field has been
a fiber-reinforced thermoelastic under three theories with
studied "by Schoenberg and Censor [10]". It was shown there
influence of gravity was discussed "by Othman and Lotfy
that the rotation causes the elastic medium to be depressive and
[29]".
of
The present paper is concerned with the investigations related
deformation, stresses and magnetic field in a uniformly
to the effect of gravity field and rotation on a generalized
rotating, homogeneous, isotropic, thermally and electrically
thermoelastic medium based on Dual-Phase-Lag model by
anisotropic.
An
investigation
on
the
distribution
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VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html
qi (x ,t q ) KT ,i (x ,t ).
applying the normal mode analysis. Also, the effects of rotation and gravity field on the physical quantities are discussed
Where
numerically and illustrated graphically.
(5)
q i is the heat flux vector. The model transmits
thermoelastic disturbances in a wave-like-manner if “equation (5)" is approximated by
II. FORMULATION OF THE PROBLEM AND BASIC EQUATIONS We consider a homogeneous generalized thermoelastic half-space rotating uniformly with an angular velocity
(1 q
)q i K (1 )T ,i . t t
Where
0 q .
(6)
Ω n, where n is a unit vector representing the direction Hence, we get the heat conduction equation in the context of of the axis of rotation. All quantities considered will be functions of the time variable
t and of the coordinates x
dual-phase-lag model in the form
and
K (1
z . The displacement equation of motion in the rotating frame
Moreover, if we put
has two additional terms (Schoenberg and Censor [10]): centripetal acceleration, Ω (Ω u) due to time varying motion only and Corioli's acceleration dynamic displacement vector
T e )T ,ii (1 q )( C E T 0 ). (7) t t t t
0 and q (the first relaxation
time), then the fundamental
2Ω u where the equations will be possible for the Lord and Shulman's theory.
is u (u , 0,w ) ,
and
Where
,
Ω (0, , 0) is the angular velocity. These terms do not distribution, We consider normal source acting at the plane surface of expansion,
generalized thermo-elastic half-space under the influence of
k
temperature,
gravity. The system of governing equations of a linear thermoelasticity
vector,
is the coefficient of linear thermal
is the thermal conductivity, T 0 is the reference
ij
is the components of the stress tensor,
, C E
ij
is
are the density and specific heat
Using the summation convection, we note that the second equation of motion in "equation (4)" is identically satisfied and (2)
the equations of motion under the influence of gravity become:
e T x x (8) w 2 g (u u 2 w ), x e T 2w ( ) z z (9) u 2 g (w w 2u ), x
The constitutive laws
2u ( ) (3)
Substituting "equation (3) into equation (1)", We obtain
[u i {Ω Ω u}i (2Ω u)i ].
displacement
phase-lag of temperature gradient.
(1)
The strain-displacement relation
u i , jj ( )u j ,ij T ,i
the
respectively, q is the phase-lag of the heat flux and is the
Equations of motion
ij 2e ij [e T ] ij .
is
the Kronecker delta,
with rotation and without body forces consists of:
e ij 12 (u i , j u j ,i ).
u
(3 2 )t , t
appear in non-rotating media.
ij , j [u i {Ω (Ω u)}i (2Ω u)i ].
are the lame's constants, T is the temperature
(4)
The Chandrasekaraiah and Tzou theory (DPL) is such a modified of classical thermoelasticity model in which the Fourier's law is replaced by an approximation of the equation
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JOURNAL OF THERMOELASTICITY ISSN 2328-2401 (print) ISSN 2328-241X (Online)
2 ) T t C E (1 q )T T 0 (1 q )e . t t
VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html Substituting "equations (19) and (20) in equations (16) - (18)",
K (1
we obtain
(10)
2 2 ) ( g 2 ) 0, (21) 2 t x t 2 1 (g 2 ) ( 2 2 2 2 ) 0, (22) x t t (1 )2 (1 q ) (1 q ) 2 . t t t t t (2
The constitutive relations can be written as
xx yy zz xz For
( 2 )u ,x w ,z T ,
(11)
e T ,
(12)
u ,x ( 2 )w ,z T ,
(13)
(u,z w ,x ), xy yz 0.
(14)
simplifications,
we
shall
use
the
(23)
following
The constitutive relations are
non-dimensional variables:
xx u ,x (1
c x i x i , u i 0 u i , c0 T 0
*
*
yy (1
T {t , q , } *{t , q , }, , ij ij , T 0 T0
zz (1
* , where * C E c 02 / K , (3 2 )t , 2 (15) c 0 ( 2 ) / and i, j 1,3.
xz
In terms of non-dimensional quantities defined in "equation
Where
1
2
2
2
2
2
2
2
)w ,z ,
(24)
) 2 ,
(25)
)u ,x w ,z ,
(26)
(u ,z w ,x ), xy yz 0.
2
2
and
(27)
2T 0 . K *
(15)", the above governing "equations (8) -(10)" reduce to (dropping the dashed for convenience)
III. THE SOLUATION OF THE PROBLEM
2 ( ) e u c 02 c 02 x x g
The solution of the considered physical variables can be decomposed in terms of normal mode analysis in the
w (u 2u 2w ), x
2 ( ) e w 2 c 0 c 02 z
[u ,w , e , , , , ij ](x , z , t )
(16)
u g (w 2w 2u ), z x 2T 0 (1 )2 (1 q ) (1 q )e . * t t K t We introduce the displacement potentials
following form
[u * ,w * , e * , * , * , * , ij* ](z ) exp(t iax ).
(17)
Where
is a complex constant,
number in the (18)
and
(x , z , t ) and
ij*
(28)
i 1 , a is the wave
x direction and u * ,w * , e * , * , * , *
are the amplitudes of the field quantities.
Using "equations (28), equations (21) - (27)" take the form
(x , z , t ) which are related to displacement components,
(D2 b1 ) * b2 * * 0,
(29)
we obtain
b3 * (D2 b4 ) * 0,
(30)
b5 (D2 a 2 ) * (D2 b6 ) * 0.
(31)
u ,x ,z , w ,z ,x
e 2 ,
u ,z w ,x 2 .
(19)
Where
(20)
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VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html 3
d , b1 a 2 2 2 , b2 iag 2 , dz b3 b2 2 , b4 a 2 2 ( 2 2 ), 1 1 , 2 2 , and b 6 a 2 . 2 1 q , b5 1 1
(z ) 2 jR je *
D=
xx* iau * (1 2
yy* (1
2
zz* ia (1
* xz
1
2
)Dw* * , 2
(32)
)(D2 a 2 ) * * ,
(33)
)u * Dw* * , 2
(Du iaw ),
2
Where
1 j
R j are some parameters and b5 (k j2 a 2 ) (k b6 ) 2 j
* xy
u * H1j R je
k j z
* yz
0.
w * H 2 j R j e
(35)
,
(42)
k j z
,
(43)
j 1
3
k j z
,
(44)
,
(45)
,
(46)
j 1
We get the following sixth order differential equation for
3
yy* H 4 j R j e
(z ) *
k j z
j 1
[D6 A D4 B D2 C ] * (z ) 0.
3
H 5 j R je
(36)
* zz
In a similar manner, we arrive to
[D6 A D4 B D2 C ]{ * (z ), * (z )} 0.
k j z
j 1
3
xz* H 6 j R j e
(37)
k j z
.
(47)
j 1
Where
Where
A b1 b 4 b5 b6 ,
H 1 j ia k j 2 j , H 2 j k j ia 2 j ,
B b1 (b4 b6 ) b4 (b5 b6 ) b2b3 a 2b5 ,
H 3 j iaH 1 j 1 j (1
C b1b4b6 b2b3b6 a 2b4b5.
H 4 j (1
"Equation (36)" can be factorized as
(D2 k 12 )(D2 k 22 )(D2 k 32 ) * (z ) 0. Where
b3 , j 1, 2,3. b4 k j2
j 1
(34)
* * and * between "equations (29) - (31)," xx H 3 j R j e
Eliminating
, 2 j
equations (32) - (35)" respectively, we obtain
3
*
(41)
Substituting from "equations (39) - (41) into equation (19) and
2
*
.
j 1
3
k j z
H6j
equation of "equation (38)". The solution of "equation (38)", which is bounded as
at
.
(39)
)( k j2 a 2 ) 1 j ,
2
2
) H 1 j k j H 2 j 1 j ,
(k j H 1 j iaH 2 j ),
j 1, 2,3.
in
order
to
determine
the
parameters
(1). Thermal boundary condition that the surface of the
In a similar manner, we get k j z
z 0
R j ( j 1, 2,3).
j 1
3
2
)k j H 2 j ,
In this section, we need to consider the boundary conditions
k j z
* (z ) 1jR j e
1
2
2
IV. THE BOUNDARY CONDITIONS OF THE PROBLEM
z , is given by 3
H 5 j ia (1
(38)
k j2 , ( j 1, 2,3) are the roots of the characteristic
* (z ) R j e
2
2
half-space subjected to thermal shock
.
(40)
(x , 0, t ) f (x , 0, t ) f * exp(t iax ).
j 1
16
(48)
JOURNAL OF THERMOELASTICITY ISSN 2328-2401 (print) ISSN 2328-241X (Online)
VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html
(2) A mechanical boundary condition that the surface of the
8954kg .m 3 , C E 383.1J .kg 1.k 1 ,
half-space is traction free
xx (x , 0, t ) xz (x , 0, t ) 0.
T 0 293K , a 1.5,
(49)
Where f ( x , t ) is an arbitrary function of x , t , and
f
*
f
*
1, 0.3, q 1.01,
0 i , 0 5, 0.9.
is a
The computations were carried out for a value of time t 0.1.
constant.
The numerical technique, outlined above, was used for the
Using the expressions of the variables considered into the above boundary conditions (48) and (49), we can obtain the
distribution of the real part of the temperature
following equations satisfied by the parameters:
displacement components
3
3
1 j R j f * ,
H
j 1 3
H j 1
6j
j 1
3j
xx , zz ,
R j 0,
and
xz
,
the
u,w and the stress components
for the problem. Here all variables are
taken in non-dimensional form. The results are shown in Figs.1-12. The graph shows the curves predicted by L-S theory
R j 0.
(50)
and DPL model. In these figures, the solid lines represent the solution in the dual-phase-lag model and dashed lines represent
Solving the above system of "equations in (50)", we get the parameters
R j ( j 1,2,3) defined as follows:
R1 1 ,
R2 2 ,
R3 3 .
the solution derived using the generalized Lord and Shulman theory. Due to the boundary conditions, the stress components
xx
(51)
and
xz based on both L-S theory and DPL model start
from zero and terminate at a zero value.
Where
11[H 32 H 63 H 33H 62 ]
Figures 1-6 show the comparisons between the displacement
12 [H 31H 63 H 33H 61 ]
components
13[H 31H 62 H 32 H 61 ],
components
xx , zz ,
0.5
for
1 f *[H 32 H 63 H 33H 62 ], 2 f *[H 31H 63 H 33H 61 ],
u,w the temperature , and the stress and
three
xz in the presence of rotation i.e. different
values
of
gravity
(g =0, 5, 9.8) i.e. in the absence and presence of gravity in
3 f *[H 31H 62 H 32 H 61 ].
the context of L-S theory and DPL model. Figure 1 depicts that the distribution of the horizontal
V. NUMERICAL RESULTS AND DISCUSSION
u, in the context of L-S theory and DPL model,
To illustrate the theoretical results obtained in the preceding
displacement
section, to compare these in the context of the Lord and
always begins from positive values for g =0, 5, 9.8. It
Shulman's theory L-S and the dual-phase-lag model DPL, and
shows that in the presence of gravity (i.e. g =5, 9.8 ), the
to study the effect of rotation and gravity on wave propagation,
values of
we now present some numerical results. For this purpose,
u based on both L-S theory and DPL model decrease
in the range
Copper is taken as the thermoelastic material for which we take
0 z 0.7 and increase in the range
the following values of the different physical constants
0.7 z 1.5. However, in the absence of gravity (i.e.
7.76 1010 N .m 2 ,
g =0 ), the values of u based on L-S theory and DPL model
3.86 1010 kg .m 1.s 2 ,
decrease in the ranges
K 386w .m 1.k 1 , t 1.78 105 k 1 ,
0 z 0.2 and 0.8 z 1.5,
while they increase in the range
17
0.2 z 0.8. The values of
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VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html
u based on L-S theory and DPL model converge to zero with distribution of xx is decreasing with the presence of gravity. increasing of the distance z at z 1.5 for g =0, 5, 9.8. The values of
We notice that the gravity acts to increase the magnitude of the real part of
xx
based on L-S theory and DPL model
converge to zero with increasing of the distance z
u and the values of the horizontal displacement u
at
z 1.5 for g =0, 5, 9.8.
based on the DPL model are large compared to the values based
Figure 5 exhibits that the distribution of the stress component
on the L-S theory for g =0, 5, 9.8. Figure 2 shows that based
zz
on L-S theory and DPL model, the values of the vertical
always begins from positive value (which is the same
w increase in the range 0 z 0.22 and point for the same value of g ) in the context of L-S theory and decrease in the range 0.22 z 1.5 for g =0, 5, 9.8. The DPL model for g =0, 5, 9.8. However, it decreases to a displacement
minimum value in the range
values of w converge to zero with increasing of the distance
0 z 0.3, then increases in
z at z 1.5 for g =0, 5, 9.8 in both L-S theory and DPL the range 0.3 z 1.5. In the context of L-S theory and model. Figure 3 demonstrates that the behavior of the temperature
based on both L-S theory and DPL model for the different values of
increase in the range
distance z at
z 1.5 for g =0, 5, 9.8.
xz
0 z 0.35 and
converge to zero with increasing of the
begins from zero in the context of L-S theory and DPL
model for g =0, 5, 9.8. In the context of both L-S theory and
0.35 z 1.5. However, based on the
DPL model, the values of
zz
Figure 6 depicts that the distribution of the stress component
g being similar. It shows that the values of based
on the L-S theory decrease in the range
DPL model,
DPL model and in the absence of gravity (i.e. g =0 ), the
decrease in the range values of
0 z 1.5. The values of the temperature converge to
xz
start with increasing to a maximum value in the
z 1.5 for range 0 z 0.12, then decrease in the range g =0, 5, 9.8. We notice that the gravity has no great effect 0.12 z 1.5. However, in the context of both L-S theory
zero with increasing of the distance z at
on the distribution of the temperature
and DPL model and in the presence of gravity (i.e.
.
g =5, 9.8 ), the values of xz start with decreasing in the
Figure 4 depicts that in the presence of gravity (i.e.
g =5, 9.8 .), the values of the stress component xx based on range 0 z 0.12, and then increase in the range both L-S theory and DPL model decrease in the range
0.12 z 1.5.
0 z 0.2 and increase in the range 0.2 z 1.5.
Figures 7-12 represent the comparisons between the
However, in the absence of gravity (i.e. g =0 ) the values of
displacement components
xx
stress components
based on both L-S theory and DPL model decrease in the
0 z 0.15
u,w, the temperature and the
xx , zz
and
xz
in the presence of
range
gravity i.e. g =9.8 for two different values of rotation
0.15 z 1.5. We notice that the values of the stress
( 0,1) i.e. in the absence and presence of rotation in the
range
component
xx
and
increase
in
the
context of L-S theory and DPL model.
based on the L-S theory are large compared to
Figure 7 depicts that the distribution of the horizontal
the values based on the DPL model for g =0, 5, 9.8 and the
displacement
18
u,
in the context of L-S theory and DPL model,
JOURNAL OF THERMOELASTICITY ISSN 2328-2401 (print) ISSN 2328-241X (Online) always begins from positive values for that the values of
u
VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html
0, 1. It shows DPL model, zz converge to zero with increasing of the
based on both L-S theory and DPL model
distance z at
z 1.5 for 0, 1.
0 z 1.5. We notice that the rotation Figure 12 depicts that the distribution of the stress component acts to decrease the magnitude of the real part of u and the xz begins from zero and satisfies the boundary condition at values of u based on DPL model are large compared to the decrease in the range
z 0 in the context of L-S theory and DPL model for
values based on the L-S theory.
0, 1. In the context of both L-S theory and DPL model,
Figure 8 shows that in the context of both L-S theory and DPL model, the values of
w start
with increasing to a maximum
the values of
0.2 z 1.5 for 0, 1. We also notice that the vertical
0.12 z 1.5.
w is increasing with the presence of rotation.
Figure 9 demonstrates that the distribution of the temperature
start with decreasing to a minimum value in
0 z 0.2, then decrease in the range the range 0 z 0.12, then increase in the range
value in the range
displacement
xz
VI. CONCLUSIONS According to the above results, we can conclude that:
begins from a positive value (which is the same point) for
0, 1, in the context of both L-S theory and DPL model. 1. We found that, the parameters q and have significant We notice that the behavior of the temperature different values of
effects on all the fields.
for two
2.
being similar.
The phenomenon of finite speeds of propagation is
Figure 10 depicts that the distribution of the stress component
manifested in all these figures.
xx
3.
begins from zero point and satisfies the boundary
thermoelastic medium in solids have been developed and
condition at z 0, in the context of L-S theory and DPL model for
utilized.
0,1. The values of xx , in the context of L-S 4. The value of all the physical quantities converges to zero with an increase in distance
theory and DPL model, start with decreasing to a minimum value in the range
the real part of
z
and
all
functions
are
0 z 0.2, then increase in the range continuous. 5.
0.2 z 1.5. We notice that the rotation acts to decrease
xx
and the values of
xx
The presence of rotation and gravity plays a significant
role in all the physical quantities except temperature. The
based on the L-S
amplitude of the physical quantities changes while
the
rotation and gravity increase. Therefore, the presence of
theory are large compared to the values based on the DPL model for
Analytical solutions based upon normal mode analysis for
0, 1.
rotation and influence of gravity in the current model is of
Figure 11 exhibits that the distribution of the stress component
significance.
zz
6.
All the physical quantities satisfy the boundary conditions.
7.
The comparison of different theories of thermoelasticity,
always begins from positive value (which is the same
point for the same value of and DPL model for
) in the context of L-S theory
0, 1. It shows that zz decreases to Tzou (DPL) model is carried out.
a minimum value in the range the range
i.e. Lord and Shulman theory and Chandrasekharaiah and
0 z 0.3, then increases in 8. Deformation of a body depends on the nature of the applied force as well as the type of boundary conditions.
0.3 z 1.5. In the context of L-S theory and
19
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xx
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0.6
0.2 DPL L-S
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DPL L-S
0.5
0.15
0.4 0.3
u
0.1
zz
g=5
g=0
0.05
0.2 g=0
g=5
g=9.8
0.1 0
0
-0.1
-0.05
0
0.5
1
1.5
-0.2
z
0
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1
1.5
z
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Fig. 5 Distribution of stress component
and presence of gravity presence of gravity
21
zz in the absence and
JOURNAL OF THERMOELASTICITY ISSN 2328-2401 (print) ISSN 2328-241X (Online)
VOL.1 NO. 4 December 2013 http://www.researchpub.org/journal/jot/jot.html
0.06
0.1 DPL L-S
g=0
0.04
DPL L-S
0.05
=0 0.02
0 g=5
xx
-0.05
xz
0
-0.02
-0.1
-0.04
-0.15 g=9.8
-0.06
-0.08
=1
-0.2
0
0.5
1
-0.25
1.5
0
0.5
z
1
1.5
z
Fig. 6 Distribution of stress component
xz in the absence and
Fig. 10 Distribution of stress component
presence of gravity
xx
in the absence
and presence of rotation
0.3
0.7 DPL L-S
0.25
DPL L-S
0.6 0.5
0.2
0.4
=0
0.3
u
zz
0.15
0.1
0.2
=0
0.1
=1
=1
0
0.05
-0.1 0 -0.2 -0.05
0
0.5
1
-0.3
1.5
0
0.5
z
1
1.5
z
Fig. 7 Horizontal displacement distribution u in the absence
Fig. 11 Distribution of stress component
and presence of rotation
zz in the absence
and presence of rotation
0.07
=1
DPL L-S
0.06
0.01 DPL L-S
0
=0
0.05
-0.01 -0.02 -0.03
0.03
xz
w
0.04
-0.04
=0
0.02 -0.05 0.01
-0.06 -0.07
0 -0.01
-0.08 0
0.5
1
=1
1.5 -0.09
z
0
0.5
1
1.5
z
Fig. 8 Vertical displacement distribution w in the absence and Fig. 12 Distribution of stress component
presence of rotation
and presence of rotation
22 0.3 DPL L-S
0.25
0.2
0.15
0.1
0.05
0
-0.05
0
0.5
1
1.5
z
Fig. 9 Temperature distribution
in the absence and presence
of rotation
22
xz in the absence
