Geometrically nonlinear vibrations of laminated shallow shells with layers of variable thickness are studied.
Nonlinear equations of motion for shells based on the first order shear deformation and classical shells theories
are considered. In order to solve this problem we use the numerically-analytical method proposed in work [1].
Accordingly to this approach the initial problem is reduced to consequences of some linear problems including
linear vibrations problem, special elasticity ones and nonlinear system of ordinary differential equations in
time. The linear problems are solved by the variational Ritz’ method and Bubnov-Galerkin procedure combined
with the R-functions theory [2]. To construct the basic functions that satisfy all boundary conditions in case of
simply-supported shells we propose new solutions structures. The proposed method is used to solve both test
problems and new ones

Kurpa, Lidiya

Shmatko, T.

Electronic National Technical University &quot;Kharkiv Polytechnic Institute&quot; Institutional Repository (eNTUKhPIIR)

277 Proceedings of the 4th  International Conference on Nonlinear Dynamics ND-KhPI2013 June 19-22, 2013, Sevastopol, Ukraine Investigation of Geometrically Nonlinear Vibrations of Laminated Shallow Shells with Layers of Variable Thickness by Meshless Approach Lidiya Kurpa1* ,Tatiana Shmatko1 Abstract Geometrically nonlinear vibrations of laminated shallow shells with layers of variable thickness are studied.Nonlinear equations of motion for shells based on the first order shear deformation and classical shells theories are considered. In order to solve this problem we use the numerically-analytical method proposed in work [1]. Accordingly to this approach the initial problem is reduced to consequences of some linear problems including linear vibrations problem, special elasticity ones and nonlinear system of ordinary differential equations in time. The linear problems are solved by the variational Ritz’ method and Bubnov-Galerkin procedure combined with the R-functions theory [2]. To construct the basic functions that satisfy all boundary conditions in case of simply-supported shells we propose new solutions structures. The proposed method is used to solve both test problems and new ones.  Keywords R-functions method, laminated shallow shells, nonlinear vibration, variable thickness 1 NTU “KhPI”, Kharkiv, Ukraine , * Corresponding author: kurpa@kpi.kharkov.ua Introduction Extensive literature reviews on nonlinear vibrations of plates and open shallow shells have been given by many scientists [1-3]. A huge number of publications is devoted to this issue. But virtually no studies that have investigated multilayer shallow shells with layers of varying thickness. In this paper we attempt to develop an algorithm for solving this class of problems. Proposed algorithm applies meshless discretization. It is based on combination of the classical approaches and modern constructive tools of the R-functions theory [8]. Application of R-functions theory allows studying geometrically nonlinear dynamic response of the laminated shallow shells and plates with complex shape and different boundary conditions. We present also new types of structure formulas that allow to construct appropriate system of basic functions. These basic functions satisfy exactly all boundary conditions. 1. Mathematical Formulation Laminated shallow shells of an arbitrary plan form with radii of curvature yx RR , which consist of M layers of the variable thickness / 0yxhi , are considered. Assume that the plane of 1x O 2xcoincides with the mid-surface of the shallow shell. The shell theories used in the present Lidiya Kurpa ,Tatiana Shmatko278 investigation are shear deformable theory (FSDT) and the classical shell theory (CST). According to these theories we assume that the tangent displacements are linear functions of coordinate z and the transverse displacement w is a constant along the thickness of the shell. Let us recall that the CST adopts Kirchhoff’s hypothesis. But FSDT is based on hypothesis of straight line. This means that the normal to the mid-surface remains straight line after deformation, but not necessary normal to the mid surface. In the abbreviated form the nonlinear stress strain relations can be written as follows: 8 9 4 5 8 9D AF                                                                    (1) where 8 9 8 9yx QQMMMNNNF ,,,,,,, 122211122211 , 4 5,,,.*+++-)][000][][0][][SDKKCA8 9 8 91323122211122211 ,,,,,,, DDLLLDDDD  , 211 ,21, xxx wRwu ~~D , 222 ,21, yyy wRwv ~~Dyxxy wwvu ,,,,12 ~~D , ##%!""$ xxx Ruw 	1D ,13 , ##%!""$ yyy Rvw 	1D ,23 , / 0 xxxx w,11 1, 11	L  , / 0 yyyy w,1,22 11	L  , / 0 xyxyyx w,12),,(12 1		1L Here u, v and w are the displacements at the mid-surface, x	 and y	 are the rotations about the y- and x-axes respectively and MN, , Q are the stress, moment and the transverse shear resultants.  Matrices 4 5C , 4 5D and 4 5K have the following form: 4 5,,,.*+++-)662616262212161211CCCCCCCCCC ,  4 5,,,.*+++-)662616262212161211DDDDDDDDDD4 5,.*+-)55544544SSSSS ,  ) *+ ,) *- .+ ,+ ,- .K K KK K K KK K K11 12 1612 22 2616 26 66Since the laminate consists of a number of variable thickness lamina, the elements of the constitutive matrices 4 5A , 4 5C , 4 5K , 4 5D , 4 5S are expressed as [2,7]: / 0 / 0 / 0/ 0/ 0/ 0/ 0/ 0 / 0/ 0/ 0/ 0/ 0/ 05,4,,,6,2,1,,,,1,,,,,1,,212,,11FF~~jidzBkyxSjidzzzByxDyxKyxCMmyxhyxhmijiijMmyxhyxhmijijijijmmmm            (2) In the expressions (2) values / 0mijB are stiffness coefficients of the m-th layer; ik ( 5,4i ) are shear correction factors. Further we assume that 6/554  kk , that is 5445 SS  . Indicator 1 is the tracing constant which takes values 1 and 0 for the FSDT and CST respectively. It should be noted that problem about nonlinear vibrations of shallow shells with symmetric layers is essentially simple than relative problem for nonsymmetrical layers. This is explained by the fact that factors ijK vanish and matrix A takes the form: Lidiya Kurpa ,Tatiana Shmatko279 4 5,,,.*+++-)][000][000][SDCAIn this paper we will only consider symmetric cross-ply and angle-ply laminated shallow shells.  2. Method of solution We will apply the method proposed in works [7]. According to this approach the first step is study of linear problem in order to find the natural frequencies and eigenfunctions 8 9 8 9Tcycxcccc wvuU )()()()()()( ,,,, 		 that satisfy the given boundary conditions. Solution of linear problems for laminated shells with variable thickness we will fulfill by RFM [8]. Note that we will not ignore inertia forces solving linear problem. Since linear vibrations are harmonic ones, then this problem may be reduced to variational problem about finding minimum of the following functional                                                        maxmax ТПJ  (3) where maxП ,  maxТ are strain and kinetic energies relatively. These energies are defined by the following expressions:  4FF~~~~~~ 121222221111121222221111max 21LLLDDD MMMNNNU / 05  dQQ yx 2313 DD1                 / 0 / 0/ 0/ 0/ 0FF##%!""$ ##%!""$ ~~~~ dyxhwvuyxhyxT yxL 2232222max 12,,,2		1CIn order to find extreme of the functional (3) we will use method by Ritz. The system of basic functions we will build by R-functions theory. That is why first we construct the corresponding solutions structures [6-8], which satisfy the given boundary conditions.  3. Solutions structures for different boundary conditions Below we present solutions structure for some boundary conditions for case of the classical theory.  Clamped edge. Solution structure is known for this case and may be found in references [6-8]. Solution structures have more bulky form for other boundary conditions. Below we present some ofthem.  Movable simply supported edge. Let us consider the following boundary conditions:  0,0  nMw                                                             (4) 0,0  nn TN (5) It is possible to prove that the following structures satisfy all boundary conditions (4-5): 4 511)(121)(222212  TPTPPPDv vv4 521)(211)(122111  TPTPPPDu uu              / 0 / 0/ 0 23331113223311221123 22)(2TBTTDBDDBBBw Lidiya Kurpa ,Tatiana Shmatko 280 Here 2332)(1 PCPCPu , 4334)(2 PCPCPu2121)(1 PCCPPv , 1441)(2 PCPCPv , 1331 PCPCP              / 0 / 0 / 0 / 0 / 0326266122163111 ))(2(3  yyxyxx CCCCCC ~~             / 0 / 0 / 0 / 0/ 0 / 031221626211663162 )2()2(  yyxyxx CCCCCCC / 0 / 0 / 0 / 0/ 0 / 0322226266123163 3)2(  yyxyxx CCCCCC ~~/ 0 / 0 / 0 / 0/ 0 / 032626612216263124 )2()2(  yyxyxx CCCCCCC / 0 / 0 / 0 / 0/ 0 / 036622621266113161 )(  yyxyxx CCCCCCP ~~/ 0 / 0 / 0 / 0/ 0 / 031621266112263662 )(  yyxyxx CCCCCCP / 0 / 0 / 0 / 0/ 0 / 032626622122163663 )(  yyxyxx CCCCCCP / 0 / 0 / 0 / 0/ 0 / 036621626622123264 )(  xxxyxx CCCCCCP / 0 / 0 / 0 / 0 / 0/ 0/ 0 / 042232622661231641114)2(24yyxyxyxxDDDDDDB/ 0 / 0 / 0 / 0/ 0 / 0/ 0/ 0/ 0 / 042632622122226163661211416223)2(yyxyxyxxDDDDDDDDDDB~~/ 0 / 0 / 0 / 0/ 0 / 0/ 0/ 0/ 0 / 0412326162266221132616412324)(2yyxyxyxxDDDDDDDDDBThe function ),( yx satisfies the following conditions: / 0 / 0 / 0 0,,,,0, IWyxyxyx  Hence / 0 0, yx is equation of the domain boundary. To build this function we will apply R-functions theory worked out by V.L.Rvachev  [8]. The differential operators ),(),,( yxfTyxfD mm are defined as [8]: / 0 ffyxfD myyxxmm JJ  ),(),( ,   / 0 fyxfT mxyyxm  ),(Note that boundary condition will be satisfied at any choice of the indefinite components 321 ,,  . Immovable simply supported edge. The boundary conditions of the immovable simply supported edge are described as  0,0,0,0  nMwvu (6) We can prove that the following structures of solution satisfy boundary conditions (6) 1u , 2v ,/ 0 / 0/ 0 23331113223311221123 22)(2TBTTDBDDBBBw In order to obtain the basic functions we will expand the indefinite components in series on some complete system of functions (power or trigonometric polynomial, splines or others).  Lidiya Kurpa ,Tatiana Shmatko 281 Like previous case we can obtain appropriate structures for case of the first order of the shear deformable theory.  4. Method of solving nonlinear problem Let us present unknown functions in the following form: / 0 / 0nicii yxwtyw1)( , ,     / 0 / 0nicxiix yxty1)( ,	1	 ,     / 0 / 0nicyiiy yxty1)( ,	1	/ 0 / 0 ninjijjinicii uyyyxutyu1 11)( , , / 0 / 0 ninjijjinicii vyyyxvtyv1 11)( ,                    (7) where / 0tyk are unknown functions in time, ),()( yxw ci ,/ 0/ 0yxu ci , , / 0/ 0yxv ci , , ),()( yxcxi	 , ),()( yxcyi	are components of the i-th eigenfunctions of linear vibration problem. Functions ijij vu , must be solutions of the following system [6-7] / 0/ 0/ 0/ 0jiijijjiijijwwNlvLuLwwNlvLuL,,222221211211Obtained system is solved by RFM. Substituting the expressions (7) for functions yxwvu 		 ,,,, in initial system of equation of motion and applying procedure by Bubnov-Galerkin we get nonlinear system of ordinary differential equations in unknown functions / 0ty j : / 0 / 0 / 0 / 0 / 0 / 0 / 0 Ftytytytytytytyninknllkijiklninkkijikjjj~1 1 11 1~~   62 / 0nj ,1            (8) Expressions for coefficients jikljikj 62 ,, are found and expressed through double integrals of known functions. In order to solve the obtained system (8) we will apply method by Runge-Kutta. 5. Numerical results The developed approach is validated on some tested problems and will be applied to solve new ones. Problem. Consider three-layers clamped shallow shell with square planform of side а and thickness ah 01.0 . Suppose that the face layers are isotropic, but middle layer is orthotropic with the following mechanical constants: ,029.0/,077.0/,25.0/ 0120201  EGEEEE .24.01 ?Here 0E is elastic modulus for isotropic layers, Poisson’s ratio for isotropic layers 3.00 ?and density of all layers is taken by the same 0CC  . As middle surface we take the plane 0z . Assume that thickness of layers varies linearly, but the general thickness is a constant and defined as: .31hhss Equations of surfaces which bound the inner layer maybe written as (Fig.1): Lidiya Kurpa ,Tatiana Shmatko282 / 0 / 0#%!"$ #%!"$  maxmhzmaxmhz 212,212Figure 1. Surface bounding the inner layer In the given case rigid coefficients are expressed by the following relations: / 0 / 0 / 0##%!""$ #%!"$  maxmEEEhyxCij 21, 010 ,  / 0 / 0 / 0##%!""$ #%!"$ 301032112, maxmEEEhyxDijTable 1. Comparison of the values for three layers square clamped plate i7 Meth. 0m 250.m 50.m17 RFM 0.886 1.023 1.057 [4] 0.88 1.02 1.06 27 RFM 3.608 4.259 4.369 [4] 3.60 4.25 4.35 37 RFM 3.781 4.264 4.429 [4] 3.80 4.26 4.40 The values of non-dimensional frequencies / 0 / 03,2,1,/ 2022 ihEa oii C7 obtained by proposed method are presented in the Table 1. In paper [4] the similar results were obtained for plates. Comparison of received results with available confirms the validation of proposed method. In the Tables 2 we present values of non-dimensional frequencies 2002 / hEaii C7  for cylindrical and spherical shells with square planform. Table2. Effect of parameter m on values of non-dimensional frequencies  of the clamped cylindrical and spherical shells Cylindrical shells( 2501 .k , 02 k ) Spherical shells ( 2501 .k , 02 k .25) i7 0m 25.0m 5.0m 0m 25.0m 5.0m17 18.2872 19.527 19.836 24.382 26.836 27.562 27 20.633 22.042 22.392 26.941 28.918 28.992 37 25.275 26.996 27.382 28.023 29.078 29.565 47 30.983 32.813 33.269 34.422 36.524 37.027 Lidiya Kurpa ,Tatiana Shmatko283 The backbone curves were also obtained for clamped and simply supported spherical and cylindrical panels. 6. Conclusion Numerically-analytical approach for investigation of nonlinear vibration of shallow shells with layers of variable thickness is developed. New solution structures satisfying all boundary conditions corresponding movable and immovable simply supported edge are proposed for shells with symmetrical layers. The present approach has advantage of being suitable for considering different types of the boundary conditions in domains of arbitrary shape. 7. References [1] Amabili M. Nonlinear Vibrations and Stability of Shells and Plates, Cambridge: Cambridge University Press, 2008. [2] Ambartsumyan S.A. The general theory of anisotropic shells, Moscow: Nauka, 1974. [3] Awrejcewicz J., Kurpa L, Shmatko T. Large amplitude free vibration of orthotropic shallow shells of complex shapes with variable thickness. Latin American Journal of Solds and Structure (10): 147-160, 2013. [4] Budak V.D., Grigorenko A.Ya., Puzyrev S.V. Free Vibrations of Rectangular Orthotropic Shallow Shells with Varying Thickness. J. Int. Applied Mechanics 43(6): 670-682, 2007. [5] Kurpa L., Pilgun G., Amabili M. Nonlinear Vibrations of Shallow Shells with Complex Boundary:R-FunctionsMethod and Experiments. J. Sound and Vibration (306): 580-600, 2007. [6] Kurpa L.V. R-functions Method for Solving Linear Problems of Bending and Vibrations of Shallow Shells, Kharkiv: Kharkiv NTU Press, 2009. [7] Kurpa L.V. Nonlinear Free Vibrations of Multilayer Shallow Shells with a Symmetric Structure and Complicated Form of the Plan. J. Mathem.Sciences 162(1): 85-98, 2009. [8] Rvachev, V.L. Theory of R-functions and some of its Applications, Kiev: NaukaDumka, 1982. 

Investigation of Geometrically Nonlinear Vibrations of Laminated Shallow Shells with Layers of Variable Thickness by Meshless Approach

Shmatko, Tatiana

Library of National Technical University "Kharkiv Polytechnic Institute"

277 
Proceedings of the 4th  International Conference on Nonlinear Dynamics 
ND-KhPI2013 
June 19-22, 2013, Sevastopol, Ukraine 
Investigation of Geometrically Nonlinear 
Vibrations of Laminated Shallow Shells with 
Layers of Variable Thickness by Meshless 
Approach 
Lidiya Kurpa1* ,Tatiana Shmatko1 
Abstract 
Geometrically nonlinear vibrations of laminated shallow shells with layers of variable thickness are studied.
Nonlinear equations of motion for shells based on the first order shear deformation and classical shells theories 
are considered. In order to solve this problem we use the numerically-analytical method proposed in work [1]. 
Accordingly to this approach the initial problem is reduced to consequences of some linear problems including 
linear vibrations problem, special elasticity ones and nonlinear system of ordinary differential equations in 
time. The linear problems are solved by the variational Ritz’ method and Bubnov-Galerkin procedure combined 
with the R-functions theory [2]. To construct the basic functions that satisfy all boundary conditions in case of 
simply-supported shells we propose new solutions structures. The proposed method is used to solve both test 
problems and new ones.  
Keywords 
R-functions method, laminated shallow shells, nonlinear vibration, variable thickness 
1 NTU “KhPI”, Kharkiv, Ukraine , 
* Corresponding author: kurpa@kpi.kharkov.ua 
Introduction 
Extensive literature reviews on nonlinear vibrations of plates and open shallow shells have been 
given by many scientists [1-3]. A huge number of publications is devoted to this issue. But virtually 
no studies that have investigated multilayer shallow shells with layers of varying thickness. In this 
paper we attempt to develop an algorithm for solving this class of problems. Proposed algorithm 
applies meshless discretization. It is based on combination of the classical approaches and modern 
constructive tools of the R-functions theory [8]. Application of R-functions theory allows studying 
geometrically nonlinear dynamic response of the laminated shallow shells and plates with complex 
shape and different boundary conditions. We present also new types of structure formulas that allow 
to construct appropriate system of basic functions. These basic functions satisfy exactly all boundary 
conditions. 
1. Mathematical Formulation 
Laminated shallow shells of an arbitrary plan form with radii of curvature yx RR , which consist 
of M layers of the variable thickness / 0yxhi , are considered. Assume that the plane of 1x O 2x
coincides with the mid-surface of the shallow shell. The shell theories used in the present 
Lidiya Kurpa ,Tatiana Shmatko
278 
investigation are shear deformable theory (FSDT) and the classical shell theory (CST). According to 
these theories we assume that the tangent displacements are linear functions of coordinate z and the 
transverse displacement w is a constant along the thickness of the shell. Let us recall that the CST 
adopts Kirchhoff’s hypothesis. But FSDT is based on hypothesis of straight line. This means that the 
normal to the mid-surface remains straight line after deformation, but not necessary normal to the mid 
surface. In the abbreviated form the nonlinear stress strain relations can be written as follows: 
8 9 4 5 8 9D AF                                                                    (1) 
where 
8 9 8 9yx QQMMMNNNF ,,,,,,, 122211122211 , 4 5
,
,
,
.
*
+
+
+
-
)

][00
0][][
0][][
S
DK
KC
A
8 9 8 91323122211122211 ,,,,,,, DDLLLDDDD  , 
2
11 ,2
1, x
x
x wR
wu ~~D , 222 ,2
1, y
y
y wR
wv ~~D
yxxy wwvu ,,,,12 ~~D , 
#
#
%
!
"
"
$
 

x
xx R
uw 	1D ,13 , 
#
#
%
!
"
"
$
 

y
yy R
vw 	1D ,23 , 
/ 0 xxxx w,11 1, 11	L  , / 0 yyyy w,1,22 11	L  , / 0 xyxyyx w,12),,(12 1		1L 
Here u, v and w are the displacements at the mid-surface, x	 and y	 are the rotations about 
the y- and x-axes respectively and MN, , Q are the stress, moment and the transverse shear resultants.  
Matrices 4 5C , 4 5D and 4 5K have the following form: 
4 5
,
,
,
.
*
+
+
+
-
)

662616
262212
161211
CCC
CCC
CCC
C ,  4 5
,
,
,
.
*
+
+
+
-
)

662616
262212
161211
DDD
DDD
DDD
D
4 5
,
.
*
+
-
)

5554
4544
SS
SS
S ,  
) *
+ ,

) *
- .
+ ,
+ ,
- .
K K K
K K K K
K K K
11 12 16
12 22 26
16 26 66
Since the laminate consists of a number of variable thickness lamina, the elements of the 
constitutive matrices 4 5A , 4 5C , 4 5K , 4 5D , 4 5S are expressed as [2,7]: 
/ 0 / 0 / 0/ 0
/ 0
/ 0
/ 0
/ 0 / 0
/ 0
/ 0
/ 0
/ 0
/ 05,4,,,
6,2,1,,,,1,,,,,
1
,
,
2
1
2
,
,
1
1



F

F




jidzBkyxS
jidzzzByxDyxKyxC
M
m
yxh
yxh
m
ijiij
M
m
yxh
yxh
m
ijijijij
m
m
m
m            (2) 
In the expressions (2) values / 0mijB are stiffness coefficients of the m-th layer; ik ( 5,4i ) are 
shear correction factors. Further we assume that 6/554  kk , that is 5445 SS  . Indicator 1 is the 
tracing constant which takes values 1 and 0 for the FSDT and CST respectively. It should be noted 
that problem about nonlinear vibrations of shallow shells with symmetric layers is essentially simple 
than relative problem for nonsymmetrical layers. This is explained by the fact that factors ijK vanish 
and matrix A takes the form: 
Lidiya Kurpa ,Tatiana Shmatko
279 
4 5
,
,
,
.
*
+
+
+
-
)

][00
0][0
00][
S
D
C
A
In this paper we will only consider symmetric cross-ply and angle-ply laminated shallow shells.  
2. Method of solution 
We will apply the method proposed in works [7]. According to this approach the first step is 
study of linear problem in order to find the natural frequencies and eigenfunctions 
8 9 8 9
Tc
y
c
x
cccc wvuU )()()()()()( ,,,, 		 that satisfy the given boundary conditions. Solution of linear 
problems for laminated shells with variable thickness we will fulfill by RFM [8]. Note that we will 
not ignore inertia forces solving linear problem. Since linear vibrations are harmonic ones, then this 
problem may be reduced to variational problem about finding minimum of the following functional   
                                                     maxmax ТПJ  (3) 
where maxП ,  maxТ are strain and kinetic energies relatively. These energies are defined by the 
following expressions:  
4
FF

~~~~~~ 121222221111121222221111max 2
1
LLLDDD MMMNNNU / 05  dQQ yx 2313 DD1
                 / 0 / 0/ 0
/ 0
/ 0
FF


#
#
%
!
"
"
$
 
#
#
%
!
"
"
$
 
~~~~

 dyxhwvuyxhyxT yx
L 22
3
222
2
max 12
,,,
2
		1C
In order to find extreme of the functional (3) we will use method by Ritz. The system of basic 
functions we will build by R-functions theory. That is why first we construct the corresponding 
solutions structures [6-8], which satisfy the given boundary conditions.  
3. Solutions structures for different boundary conditions 
Below we present solutions structure for some boundary conditions for case of the classical 
theory.  
Clamped edge. Solution structure is known for this case and may be found in references [6-8]. 
Solution structures have more bulky form for other boundary conditions. Below we present some of
them.  
Movable simply supported edge. Let us consider the following boundary conditions:  
0,0  nMw                                                             (4) 
0,0  nn TN (5) 
It is possible to prove that the following structures satisfy all boundary conditions (4-5): 
4 511
)(
121
)(
222212 

 TPTP
P
PDv vv



4 521
)(
211
)(
122111 

 TPTP
P
PDu uu


              
/ 0 / 0/ 0


 2333111322331122
1
1
2
3 22)(2
TBTTDBDDB
B
B
w 


Lidiya Kurpa ,Tatiana Shmatko 
280 
Here 
2332
)(
1 PCPCP
u
 , 4334
)(
2 PCPCP
u

2121
)(
1 PCCPP
v
 , 1441
)(
2 PCPCP
v
 , 1331 PCPCP 
             / 0 / 0 / 0 / 0 / 0326
2
6612
2
16
3
111 ))(2(3  yyxyxx CCCCCC ~~
             / 0 / 0 / 0 / 0/ 0 / 0312
2
1626
2
1166
3
162 )2()2(  yyxyxx CCCCCCC 
/ 0 / 0 / 0 / 0/ 0 / 0
3
22
2
26
2
6612
3
163 3)2(  yyxyxx CCCCCC ~~
/ 0 / 0 / 0 / 0/ 0 / 0
3
26
2
6612
2
1626
3
124 )2()2(  yyxyxx CCCCCCC 
/ 0 / 0 / 0 / 0/ 0 / 0
3
66
2
26
2
126611
3
161 )(  yyxyxx CCCCCCP ~~
/ 0 / 0 / 0 / 0/ 0 / 0
3
16
2
126611
2
26
3
662 )(  yyxyxx CCCCCCP 
/ 0 / 0 / 0 / 0/ 0 / 0
3
26
2
662212
2
16
3
663 )(  yyxyxx CCCCCCP 
/ 0 / 0 / 0 / 0/ 0 / 0
3
66
2
16
2
662212
3
264 )(  xxxyxx CCCCCCP 
/ 0 / 0 / 0 / 0 / 0
/ 0/ 0 / 0
4
22
3
26
22
6612
3
16
4
111
4
)2(24


yyx
yxyxx
DD
DDDDB


/ 0 / 0 / 0 / 0/ 0 / 0
/ 0/ 0/ 0 / 0
4
26
3
262212
22
2616
3
661211
4
162
2
3)2(


yyx
yxyxx
DDDD
DDDDDDB


/ 0 / 0 / 0 / 0/ 0 / 0
/ 0/ 0/ 0 / 0
4
12
3
2616
22
662211
3
2616
4
123
2
4)(2


yyx
yxyxx
DDD
DDDDDDB


The function ),( yx satisfies the following conditions: 
/ 0 / 0 / 0 0,,,,0, IW

yxyxyx  
Hence / 0 0, yx is equation of the domain boundary. To build this function we will apply R-
functions theory worked out by V.L.Rvachev  [8]. 
The differential operators ),(),,( yxfTyxfD mm are defined as [8]: 
/ 0 ffyxfD myyxx
m
m JJ  ),(),( ,
   
/ 0 fyxfT mxyyxm  ),(
Note that boundary condition will be satisfied at any choice of the indefinite components 
321 ,,  . 
Immovable simply supported edge. The boundary conditions of the immovable simply 
supported edge are described as  
0,0,0,0  nMwvu (6) 
We can prove that the following structures of solution satisfy boundary conditions (6) 
1u , 2v ,
/ 0 / 0/ 0


 2333111322331122
1
1
2
3 22)(2
TBTTDBDDB
B
B
w 


In order to obtain the basic functions we will expand the indefinite components in series on 
some complete system of functions (power or trigonometric polynomial, splines or others).  
Lidiya Kurpa ,Tatiana Shmatko 
281 
Like previous case we can obtain appropriate structures for case of the first order of the shear 
deformable theory.  
4. Method of solving nonlinear problem 
Let us present unknown functions in the following form: 
/ 0 / 0



n
i
c
ii yxwtyw
1
)( , ,     / 0 / 0



n
i
c
xiix yxty
1
)( ,	1	 ,     / 0 / 0



n
i
c
yiiy yxty
1
)( ,	1	
/ 0 / 0

 

n
i
n
j
ijji
n
i
c
ii uyyyxutyu
1 11
)( , , / 0 / 0

 

n
i
n
j
ijji
n
i
c
ii vyyyxvtyv
1 11
)( ,                    (7) 
where / 0tyk are unknown functions in time, ),(
)( yxw ci ,
/ 0
/ 0yxu ci , , 
/ 0
/ 0yxv ci , , ),(
)( yxcxi	 , ),(
)( yxcyi	
are components of the i-th eigenfunctions of linear vibration problem. Functions ijij vu , must be 
solutions of the following system [6-7] 
/ 0
/ 0
/ 0
/ 0








jiijij
jiijij
wwNlvLuL
wwNlvLuL
,
,
2
22221
2
11211
Obtained system is solved by RFM. Substituting the expressions (7) for functions 
yxwvu 		 ,,,, in initial system of equation of motion and applying procedure by Bubnov-Galerkin 
we get nonlinear system of ordinary differential equations in unknown functions / 0ty j : 
/ 0 / 0 / 0 / 0 / 0 / 0 / 0 Ftytytytytytyty
n
i
n
k
n
l
lkijikl
n
i
n
k
kijikjjj
~
1 1 11 1
~~


   
62 / 0nj ,1            (8) 
Expressions for coefficients jikljikj 62 ,, are found and expressed through double integrals of 
known functions. In order to solve the obtained system (8) we will apply method by Runge-Kutta. 
5. Numerical results 
The developed approach is validated on some tested problems and will be applied to solve new 
ones. 
Problem. Consider three-layers clamped shallow shell with square planform of side а and 
thickness ah 01.0 . Suppose that the face layers are isotropic, but middle layer is orthotropic with 
the following mechanical constants: 
,029.0/,077.0/,25.0/ 0120201  EGEEEE .24.01 ?
Here 0E is elastic modulus for isotropic layers, Poisson’s ratio for isotropic layers 3.00 ?
and density of all layers is taken by the same 0CC  . As middle surface we take the plane 0z . 
Assume that thickness of layers varies linearly, but the general thickness is a constant and defined as: 
.
3
1
hh
s
s 


Equations of surfaces which bound the inner layer maybe written as (Fig.1): 
Lidiya Kurpa ,Tatiana Shmatko
282 
/ 0 / 0
#
%
!
"
$
 

#
%
!
"
$
 
 m
a
xmhzm
a
xmhz 21
2
,21
2
Figure 1. Surface bounding the inner layer 
In the given case rigid coefficients are expressed by the following relations: 
/ 0 / 0 / 0
#
#
%
!
"
"
$
 
#
%
!
"
$
 
 m
a
xmEEEhyxCij 21, 010 ,  
/ 0 / 0 / 0
#
#
%
!
"
"
$
 
#
%
!
"
$
 

3
010
3
21
12
, m
a
xmEEEhyxDij
Table 1. Comparison of the values for three layers square clamped plate 
i7 Meth. 0m 250.m 50.m
17 RFM 0.886 1.023 1.057 
[4] 0.88 1.02 1.06 
27 RFM 3.608 4.259 4.369 
[4] 3.60 4.25 4.35 
37 RFM 3.781 4.264 4.429 
[4] 3.80 4.26 4.40 
The values of non-dimensional frequencies / 0 / 03,2,1,/ 20
22
 ihEa oii C7 obtained by 
proposed method are presented in the Table 1. In paper [4] the similar results were obtained for plates. 
Comparison of received results with available confirms the validation of proposed method. In the 
Tables 2 we present values of non-dimensional frequencies 200
2 / hEaii C7  for cylindrical and 
spherical shells with square planform. 
Table2. Effect of parameter m on values of non-dimensional frequencies  
of the clamped cylindrical and spherical shells 
Cylindrical shells( 2501 .k , 02 k ) Spherical shells ( 2501 .k , 02 k .25) 
i7 0m 25.0m 5.0m 0m 25.0m 5.0m
17 18.287
2 
19.5
27 
19.836 24.382 26.836 27.562 
27 20.633 22.0
42 
22.392 26.941 28.918 28.992 
37 25.275 26.9
96 
27.382 28.023 29.078 29.565 
47 30.983 32.8
13 
33.269 34.422 36.524 37.027 
Lidiya Kurpa ,Tatiana Shmatko
283 
The backbone curves were also obtained for clamped and simply supported spherical and 
cylindrical panels. 
6. Conclusion 
Numerically-analytical approach for investigation of nonlinear vibration of shallow shells with 
layers of variable thickness is developed. New solution structures satisfying all boundary conditions 
corresponding movable and immovable simply supported edge are proposed for shells with 
symmetrical layers. The present approach has advantage of being suitable for considering different 
types of the boundary conditions in domains of arbitrary shape. 
7. References 
[1] Amabili M. Nonlinear Vibrations and Stability of Shells and Plates, Cambridge: Cambridge 
University Press, 2008. 
[2] Ambartsumyan S.A. The general theory of anisotropic shells, Moscow: Nauka, 1974. 
[3] Awrejcewicz J., Kurpa L, Shmatko T. Large amplitude free vibration of orthotropic shallow shells 
of complex shapes with variable thickness. Latin American Journal of Solds and Structure (10): 147-
160, 2013. 
[4] Budak V.D., Grigorenko A.Ya., Puzyrev S.V. Free Vibrations of Rectangular Orthotropic Shallow 
Shells with Varying Thickness. J. Int. Applied Mechanics 43(6): 670-682, 2007. 
[5] Kurpa L., Pilgun G., Amabili M. Nonlinear Vibrations of Shallow Shells with Complex 
Boundary:R-FunctionsMethod and Experiments. J. Sound and Vibration (306): 580-600, 2007. 
[6] Kurpa L.V. R-functions Method for Solving Linear Problems of Bending and Vibrations of 
Shallow Shells, Kharkiv: Kharkiv NTU Press, 2009. 
[7] Kurpa L.V. Nonlinear Free Vibrations of Multilayer Shallow Shells with a Symmetric Structure 
and Complicated Form of the Plan. J. Mathem.Sciences 162(1): 85-98, 2009. 
[8] Rvachev, V.L. Theory of R-functions and some of its Applications, Kiev: NaukaDumka, 1982. 


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Investigation of Geometrically Nonlinear Vibrations of Laminated Shallow Shells with Layers of Variable Thickness by Meshless Approach

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Investigation of Geometrically Nonlinear Vibrations of Laminated Shallow Shells with Layers of Variable Thickness by Meshless Approach

Abstract

Similar works

Full text

Available Versions

Electronic National Technical University &quot;Kharkiv Polytechnic Institute&quot; Institutional Repository (eNTUKhPIIR)

Library of National Technical University "Kharkiv Polytechnic Institute"

Electronic National Technical University "Kharkiv Polytechnic Institute" Institutional Repository (eNTUKhPIIR)