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Boundary integral formulation of plate bending problems
MECHANICS RESEARCH COMMUNICATIONS
0093-6413/84 $3.00 + .00
Vol. 11(4),245-251, 1984. Printed in the USA
Copyright (c) 1984 Pergamon Press Ltd.
BOUNDARY INTEGRAL FORMULATION OF PLATE BENDING PROBLEMS N. Kamiya and Y. Sawaki Department of Mechanical Engineering, Mie University Kamihamacho, Tsu 514 Japan
(Received 26 March 1984; accepted for p~nt 20 April 1984) Introduction The field equation governing deflection of thin elastic plates of constant thickness under the conventional assumption after Kirchhoff and Love is represented by the two-dimensional inhomogeneous biharmonic differential equation. The inhomogeneous term occurs from specified distribution of lateral load. The above-mentioned biharmonic differential equation together with the associated boundary conditions can be formulated as integral equations which are conveniently employed to analyze numerically the elastic bending of arbitrary boundary conditions using the so-called Boundary Element Method. The boundary element method or more generally the integral equation method, the authors believe, is highly convenient and elegant when the formulation can be achieved on the boundary alone. In general, such smart formulation is possible only for linear, homogeneous differential equations, and therefore the integral equation ruling the plate bending problem involves one domain integral of the inhomogeneous load term. The present study concerns an attempt at transformation of the domain integral into the corresponding boundary integral. The method relies on the well-known integral theorems due to Gauss or Green and is mathematically rigorous. Distributed lateral loads expressed in terms of a power series of the coordinates including constant, linear and quadratic variations are illustrated. Since higher order variations can be treated similarly, problems with arbitrary load distribution are formulated as the perfect "boundary" integral equation. Consequently, discretization and numerical calculation over the domain are wiped out thoroughly and utility of the boundary element method for the plate bending analysis is emphasized in the extreme. 245
246
N. KAMIYA and Y, SAWAKI
Integral Equation Consider
Formulation
a thin elastic plate of arbitrary profile
by a smooth curve ?S
(FIG. 1).
surrounded
S and n denote the domain
occupied by the plate and the unit outward normal on the boundary. Let the plate be supported appropriately rigid body displacements. of thin elastic plates, following biharmonic
to prevent
trivial
Obeying the Kirchhoff-Love
assumption
deflection w of the plate satisfies
differential
the
equation:
V4w = p/D
(l)
where p and D stand for lateral bending rigidity of the plate. the inhomogeneous
load distribution
and constant
The right hand side of Eq.
term in the differential
equation,
(I) is
which is
denoted by ¢ in what follows. The boundary-value equation
problem constructed by the differential
(i) and related boundary conditions
the following
two integral
equations
is transformed
for the smooth boundary
1 I ~S {K[v(X, Y)]w(Y) 1 w(X) = I klJ(x)v(x, X)dS - ~2 ~ S . . . . . ~V
Unit Outward Normal: 8
-_
oi
x2'Y2
~ k
//~ D°main: S / ~ B o u n d a r y
Boundary:
0
~S
m- Xl , Yl
FIG. 1 Notations
Point: X
into [1-3]
BOUNDARY INTEGRALS FOR PLATE BENDING
~ v(x, X)dS - ~ ~xfskb(x ) i f s{3 x[v(X, Y)]w(Y)
~-q(X) =
1
~
~
shear
represented
~nxBn (X, Y)M[w(Y)]
~
w h e r e q, M a n d K a r e effective
247
slope,
force
(X, Y)K[w(Y)]}ds
normal bending
on t h e b o u n d a r y
moment and K i r c h h o f f
respectively,
which are
as follows;
q = ~3w
(4) r-232~. _2 3 2
M : - D [ V 2 - ( I - ~ ) ~n2T~- ~
32
2nln2~2)]
nz~-~-
(n~
~ ~- -~-~) ~ K = D{(1-V)~--~ [nln2(~-~-
In the above equations
~ denotes
term related to discontinuity to Eqs.
(3)
(2) and
-
(5)
n~)~_~._, ox,ox22]
Poisson ratio.
v~± 3n }
(6)
Each additional
of twisting moment must be added
(3) for the nonsmooth boundary
function v(x, y) appearing
_
in Eqs.
(2) and
[2, 3].
The
(3) is the fundamental
solution to the original biharmonic equation
v(~,
y)
1 r21og r
= - 8-9
where r represents
(~ ar21og r, a =
(7)
1
- ~-9 )
the distance between two arbitrary points x
and
It has been known that, are formulated
since the integral equations
(2) and
(3)
in terms of the four boundary quantities w, q, M
and K, two of them are specified by the boundary condition and the remaining
t~o are unknown, most bending problems
solved systematically One may mention,
using Eqs.
however,
(2) and
can be
(3).
that besides boundary discretization
the domain S occupied by the plate must be discretized
into
248
N. KAMIYA and Y. SAWAKI
a set of appropriate
internal
domain integrals sides of Eqs.
appearing
(2) and
on the boundary discretization efficient Complete
If the such integrals
integrals,
numerical
any more and becomes
Boundary
Integral
easier,
can be
computation based
element method does not require
from the practical
The following
in order to compute the two
in each first term of the right hand
(3).
replaced by the boundary
cells
tedius
domain
simpler and more
point of view.
Formulation
two domain integral
remain
in Eqs.
(2) and
(3):
Bl(X ) = [ ',[J(x)v(x, X) dS
~r B2(X) = ~-~ / ~ ( x ) v ( x , S
B2(X)
(9
(lO
X) dS
~
can be estimated
simply through differentiation
on the specified point X on the boundary, enough to consider only BI(X) plate bending problems, of lateral
load,
that is, concentrated
For a finite number of concentrated expressed
and therefore
for the present.
we conventionally
of BI(X)
As practical
encounter
two types
and distributed
lateral
it is
loads, ~(x)
loads. is
as m
~(x)
=
£ qJ(zJ)6(x j=l
where m concentrated at x = z j.
(11)
- zj)
loads of each intensity ~(z j) are acting
Then Eq.
(9) becomes
m
B~(X) = z
BI(X)
and B2(X)
(12)
vo(zJ)v(z j, x)
j-=1
~
~
can be computed without performing
any integral
calculations. As the second problem, lateral
load which
we consider
is thought
arbitrarily
distributed
to be represented by a power series
BOUNDARY INTEGRALS FOR PLATE BENDING
of the coordinates.
In order
procedure,
an inhomogeneous
we suppose
up to q u a d r a t i c
to explain
249
the t r a n s f o r m a t i o n
term r e p r e s e n t e d
by
terms:
~b(x)~ = ~o + @ k X k + 4~£XkX£
(13)
where 40, 4k,1 4kz2 ( k , £ = 1,2) are constant. For t h e r e p e a t e d i n d i c e s , we obey t h e c o n v e n t i o n a l summation c o n v e n t i o n r u l e within the two-dimensional space. In t h e p r e s e n t c a s e , t h e domain i n t e g r a l BI(X) becomes
(14)
B,(X) = a I [40 + ~ x k + 4~LXkX~)r21°g r ds ~
With
respect
following
S
to the function
identities
hold
r21og
r, we notice
in the t w o - d i m e n s i o n a l
that
the
space:
2r ~ i r21og r = V T6 (log r - ~ ) r ~ = V23~
3•
r~log r = V 2
Applying of Eq.
the second (15),
Green
+
a
frj
identity
[
(log r -
{[40
J 3S r
first
(log r - g1 )
(14)
in c o n s i d e r a t i o n
to give
)V2(4 ° + 4~Xkl + 4~£XkX£)dS
z 'h 2 ~ X ) ~ r~ 1 + 4kXk + ~kZ~k ~ Tff [7g ( l o g r - ~ )]
(log
r -
term on the right
transformed,
to Eq.
we have
BI(X)~ = a
The
(15)
finally,
hand
[40 +
side
of Eq.
(16) (16) can be further
250
N. KAMIYA and Y. SAWAKI
BI(X- ) = f 3S (@0T0 + *kTk 1 1 + *~£T~£) ds
(17)
where 3F1(r) T° = a _ ~n
~Fl(r) Tki = a[Xk
nkF i (r)]
~n
2 = a[XkX ~ Tk£
8FI (r) 3n
(Xznk + Xknz)F i (r) + 6k£
r~ Fl(r)
(18)
~F2 (r) ] ~n
1
= i-6 (log
r - ~ )
(19) _
F2(r)
Equation
(17)
r 6
5
288 (log r - ~- )
is f o r m u l a t e d
as a consequence,
two
as complete
integral
equations
system of s i m u l t a n e o u s
"boundary
this
formulation,
complete
for n u m e r i c a l order
terms
term,
similar
boundary
calculation
are i n c l u d e d
" bo un da ry " (2) and
" integral
procedure
equations.
and, a
Using
discretization
Even though higher
in the e x p r e s s i o n
replacement
(3) become
only b o u n d a r y
is sufficient.
integral
of the i n h o m o g e n e o u s
is available
repeatedly.
Application As an i l l u s t r a t i o n
of the b o u n d a r y
thorough
integral
problem plate
boundary
of thin elastic
subjected
linearly
element
formulation
plates, and
using
for the linear
we consider
to the d i s t r i b u t e d
in the x I d i r e c t i o n
analysis
lateral
is u n i f o r m
a clamped
the
bending elliptic
load w hi ch varies in the x 2
direction. Figure axis
2 shows
distributions
of the ellipse.
of the d e f l e c t i o n
The minor
along
axis does not yi el d
the major deflection
BOUNDARY INTEGRALS FOR PLATE BENDING
in this example.
251
Small circles obtained by 48 piecewise
constant boundary elements agree well with the existing rigorous analytical solution
[4].
We emphasize again that the bending analysis of constant thickness elastic thin plates can be proceeded successfully by only boundary discretization with the help of the boundary element method.
(× lO-3 ) 5 BEM
o
4
Analytical
3 C~
1 I
I
I
I
I
I
0,5
1.0
1,5
Xl/b
FIG. 2 Clamped ellipse ( a/b = 3/2 ) References I. S. Bergman and M. Schiffer, Kernel Functions and Elliptic Differential Equations in Mathematical Physics, Academic Press, New York (1953). 2. G. P. Bezine, Mech. Res. Comm., S, 197 (1978). 3. M. Stern, Int. J. Solids Struct., 15, 769 (1979). 4. S. P. Timoshenko and S. Woinowsky-K-{ieger, Theory of Plates and Shells, 2nd ed., McGraw-Hill, New York, Toronto London (1959).
0093-6413/84 $3.00 + .00
Vol. 11(4),245-251, 1984. Printed in the USA
Copyright (c) 1984 Pergamon Press Ltd.
BOUNDARY INTEGRAL FORMULATION OF PLATE BENDING PROBLEMS N. Kamiya and Y. Sawaki Department of Mechanical Engineering, Mie University Kamihamacho, Tsu 514 Japan
(Received 26 March 1984; accepted for p~nt 20 April 1984) Introduction The field equation governing deflection of thin elastic plates of constant thickness under the conventional assumption after Kirchhoff and Love is represented by the two-dimensional inhomogeneous biharmonic differential equation. The inhomogeneous term occurs from specified distribution of lateral load. The above-mentioned biharmonic differential equation together with the associated boundary conditions can be formulated as integral equations which are conveniently employed to analyze numerically the elastic bending of arbitrary boundary conditions using the so-called Boundary Element Method. The boundary element method or more generally the integral equation method, the authors believe, is highly convenient and elegant when the formulation can be achieved on the boundary alone. In general, such smart formulation is possible only for linear, homogeneous differential equations, and therefore the integral equation ruling the plate bending problem involves one domain integral of the inhomogeneous load term. The present study concerns an attempt at transformation of the domain integral into the corresponding boundary integral. The method relies on the well-known integral theorems due to Gauss or Green and is mathematically rigorous. Distributed lateral loads expressed in terms of a power series of the coordinates including constant, linear and quadratic variations are illustrated. Since higher order variations can be treated similarly, problems with arbitrary load distribution are formulated as the perfect "boundary" integral equation. Consequently, discretization and numerical calculation over the domain are wiped out thoroughly and utility of the boundary element method for the plate bending analysis is emphasized in the extreme. 245
246
N. KAMIYA and Y, SAWAKI
Integral Equation Consider
Formulation
a thin elastic plate of arbitrary profile
by a smooth curve ?S
(FIG. 1).
surrounded
S and n denote the domain
occupied by the plate and the unit outward normal on the boundary. Let the plate be supported appropriately rigid body displacements. of thin elastic plates, following biharmonic
to prevent
trivial
Obeying the Kirchhoff-Love
assumption
deflection w of the plate satisfies
differential
the
equation:
V4w = p/D
(l)
where p and D stand for lateral bending rigidity of the plate. the inhomogeneous
load distribution
and constant
The right hand side of Eq.
term in the differential
equation,
(I) is
which is
denoted by ¢ in what follows. The boundary-value equation
problem constructed by the differential
(i) and related boundary conditions
the following
two integral
equations
is transformed
for the smooth boundary
1 I ~S {K[v(X, Y)]w(Y) 1 w(X) = I klJ(x)v(x, X)dS - ~2 ~ S . . . . . ~V
Unit Outward Normal: 8
-_
oi
x2'Y2
~ k
//~ D°main: S / ~ B o u n d a r y
Boundary:
0
~S
m- Xl , Yl
FIG. 1 Notations
Point: X
into [1-3]
BOUNDARY INTEGRALS FOR PLATE BENDING
~ v(x, X)dS - ~ ~xfskb(x ) i f s{3 x[v(X, Y)]w(Y)
~-q(X) =
1
~
~
shear
represented
~nxBn (X, Y)M[w(Y)]
~
w h e r e q, M a n d K a r e effective
247
slope,
force
(X, Y)K[w(Y)]}ds
normal bending
on t h e b o u n d a r y
moment and K i r c h h o f f
respectively,
which are
as follows;
q = ~3w
(4) r-232~. _2 3 2
M : - D [ V 2 - ( I - ~ ) ~n2T~- ~
32
2nln2~2)]
nz~-~-
(n~
~ ~- -~-~) ~ K = D{(1-V)~--~ [nln2(~-~-
In the above equations
~ denotes
term related to discontinuity to Eqs.
(3)
(2) and
-
(5)
n~)~_~._, ox,ox22]
Poisson ratio.
v~± 3n }
(6)
Each additional
of twisting moment must be added
(3) for the nonsmooth boundary
function v(x, y) appearing
_
in Eqs.
(2) and
[2, 3].
The
(3) is the fundamental
solution to the original biharmonic equation
v(~,
y)
1 r21og r
= - 8-9
where r represents
(~ ar21og r, a =
(7)
1
- ~-9 )
the distance between two arbitrary points x
and
It has been known that, are formulated
since the integral equations
(2) and
(3)
in terms of the four boundary quantities w, q, M
and K, two of them are specified by the boundary condition and the remaining
t~o are unknown, most bending problems
solved systematically One may mention,
using Eqs.
however,
(2) and
can be
(3).
that besides boundary discretization
the domain S occupied by the plate must be discretized
into
248
N. KAMIYA and Y. SAWAKI
a set of appropriate
internal
domain integrals sides of Eqs.
appearing
(2) and
on the boundary discretization efficient Complete
If the such integrals
integrals,
numerical
any more and becomes
Boundary
Integral
easier,
can be
computation based
element method does not require
from the practical
The following
in order to compute the two
in each first term of the right hand
(3).
replaced by the boundary
cells
tedius
domain
simpler and more
point of view.
Formulation
two domain integral
remain
in Eqs.
(2) and
(3):
Bl(X ) = [ ',[J(x)v(x, X) dS
~r B2(X) = ~-~ / ~ ( x ) v ( x , S
B2(X)
(9
(lO
X) dS
~
can be estimated
simply through differentiation
on the specified point X on the boundary, enough to consider only BI(X) plate bending problems, of lateral
load,
that is, concentrated
For a finite number of concentrated expressed
and therefore
for the present.
we conventionally
of BI(X)
As practical
encounter
two types
and distributed
lateral
it is
loads, ~(x)
loads. is
as m
~(x)
=
£ qJ(zJ)6(x j=l
where m concentrated at x = z j.
(11)
- zj)
loads of each intensity ~(z j) are acting
Then Eq.
(9) becomes
m
B~(X) = z
BI(X)
and B2(X)
(12)
vo(zJ)v(z j, x)
j-=1
~
~
can be computed without performing
any integral
calculations. As the second problem, lateral
load which
we consider
is thought
arbitrarily
distributed
to be represented by a power series
BOUNDARY INTEGRALS FOR PLATE BENDING
of the coordinates.
In order
procedure,
an inhomogeneous
we suppose
up to q u a d r a t i c
to explain
249
the t r a n s f o r m a t i o n
term r e p r e s e n t e d
by
terms:
~b(x)~ = ~o + @ k X k + 4~£XkX£
(13)
where 40, 4k,1 4kz2 ( k , £ = 1,2) are constant. For t h e r e p e a t e d i n d i c e s , we obey t h e c o n v e n t i o n a l summation c o n v e n t i o n r u l e within the two-dimensional space. In t h e p r e s e n t c a s e , t h e domain i n t e g r a l BI(X) becomes
(14)
B,(X) = a I [40 + ~ x k + 4~LXkX~)r21°g r ds ~
With
respect
following
S
to the function
identities
hold
r21og
r, we notice
in the t w o - d i m e n s i o n a l
that
the
space:
2r ~ i r21og r = V T6 (log r - ~ ) r ~ = V23~
3•
r~log r = V 2
Applying of Eq.
the second (15),
Green
+
a
frj
identity
[
(log r -
{[40
J 3S r
first
(log r - g1 )
(14)
in c o n s i d e r a t i o n
to give
)V2(4 ° + 4~Xkl + 4~£XkX£)dS
z 'h 2 ~ X ) ~ r~ 1 + 4kXk + ~kZ~k ~ Tff [7g ( l o g r - ~ )]
(log
r -
term on the right
transformed,
to Eq.
we have
BI(X)~ = a
The
(15)
finally,
hand
[40 +
side
of Eq.
(16) (16) can be further
250
N. KAMIYA and Y. SAWAKI
BI(X- ) = f 3S (@0T0 + *kTk 1 1 + *~£T~£) ds
(17)
where 3F1(r) T° = a _ ~n
~Fl(r) Tki = a[Xk
nkF i (r)]
~n
2 = a[XkX ~ Tk£
8FI (r) 3n
(Xznk + Xknz)F i (r) + 6k£
r~ Fl(r)
(18)
~F2 (r) ] ~n
1
= i-6 (log
r - ~ )
(19) _
F2(r)
Equation
(17)
r 6
5
288 (log r - ~- )
is f o r m u l a t e d
as a consequence,
two
as complete
integral
equations
system of s i m u l t a n e o u s
"boundary
this
formulation,
complete
for n u m e r i c a l order
terms
term,
similar
boundary
calculation
are i n c l u d e d
" bo un da ry " (2) and
" integral
procedure
equations.
and, a
Using
discretization
Even though higher
in the e x p r e s s i o n
replacement
(3) become
only b o u n d a r y
is sufficient.
integral
of the i n h o m o g e n e o u s
is available
repeatedly.
Application As an i l l u s t r a t i o n
of the b o u n d a r y
thorough
integral
problem plate
boundary
of thin elastic
subjected
linearly
element
formulation
plates, and
using
for the linear
we consider
to the d i s t r i b u t e d
in the x I d i r e c t i o n
analysis
lateral
is u n i f o r m
a clamped
the
bending elliptic
load w hi ch varies in the x 2
direction. Figure axis
2 shows
distributions
of the ellipse.
of the d e f l e c t i o n
The minor
along
axis does not yi el d
the major deflection
BOUNDARY INTEGRALS FOR PLATE BENDING
in this example.
251
Small circles obtained by 48 piecewise
constant boundary elements agree well with the existing rigorous analytical solution
[4].
We emphasize again that the bending analysis of constant thickness elastic thin plates can be proceeded successfully by only boundary discretization with the help of the boundary element method.
(× lO-3 ) 5 BEM
o
4
Analytical
3 C~
1 I
I
I
I
I
I
0,5
1.0
1,5
Xl/b
FIG. 2 Clamped ellipse ( a/b = 3/2 ) References I. S. Bergman and M. Schiffer, Kernel Functions and Elliptic Differential Equations in Mathematical Physics, Academic Press, New York (1953). 2. G. P. Bezine, Mech. Res. Comm., S, 197 (1978). 3. M. Stern, Int. J. Solids Struct., 15, 769 (1979). 4. S. P. Timoshenko and S. Woinowsky-K-{ieger, Theory of Plates and Shells, 2nd ed., McGraw-Hill, New York, Toronto London (1959).