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Pressure of a die on an elastic layer of finite thickness
OF A DIE ON AN ELASTIC OF FINITE TRICKNESS
PRESSURE
(0 DAVLENII
SHTAMPA
PMM Vo1.23, I. I.
NA SLOI No.3,
VOROVICH
KONECWNOI pp.
1959,
and
1u.A.
LAYER
TOLSHCAINY)
445-455
USTINOV
(Rostov-on-Don) (Received
This
article
considers
on an elastic
layer
in terms of
tained
dimensionless dies the
diameter
of of
of
2.
Statement
h rest
on a rigid
layer.
of
contact.
problem.
loaded by a force P along its of contact
1958)
pressure
of
Solution
to
an axisymmetric this
problem
obtained of
layer
adequately is
of
the
ob-
described
order
of
the
l
Lt an elastic layer of finite foundation. An axially-symnetrical
axis
die
is
in powers of h-l, where h is the The cases of plane and parabolic
thickness
frictionless
Let the surface
the
The solution
when the
of
of
series
the
in detail. surface
June
thickness.
asymptotic
stress the
problem
finite
thickness
are studied state
the of
if
of symnetry,
between the die
acts on this
and layer
thickness die,
layer
be defined
(Fig.l). in
cylindrical coordinates by the equation z = #&I. The boundary of this surface is assumed to be a circle of unit radius. ‘Ihe plane xy will be located on the rigid foundation, and the z-axis will be directed along the axis of the die.
l
After
this
article
was submitted
for
tion of the authors that another [ 11 considers the axially-symmetric on a layer applicable, ever, its integral
of
finite
thickness.
generally use involves with
printing,
subsequent
of
came to
the
atten-
The solution given in [ 11 will be any dimensionless thickness h. Howevaluation of a certain Fredholm
for speaking, the numerical numerical
finding
respect the asymptotic formulas presented since in numerous cases they give directly characteristics
it
paper, written by Lebedev and Ufliand problem of a plane circular die
the problem.
637
of
quadratures.
In this
in this work are important, all the fundamental
638
I.I.
Yorouich
and
Ustinov
Iu.A.
1
Fig.
Assune that the pressure between the die and layer is a known function From [ 21 , which considers equilibrium of an elastic layer subjected
q(p 1.
to the action relations:
of known forces
on its
boundary,
sqqj-
O”Q(Y)
ul=w-$
22 (74 Jo
we obtain
the following
(1.1)
(7P)d7
0 T’pz
=Tp*f2
O” Q(Y) igpqs
23
w
Jl(7P)7d7
(1.2)
Jo (7~) 7d7
(1.3)
0
Qz=
I:I --2~~($) -
~4
W
0
W =--
-(h
+
z$?-
‘B
y(h+z)Q (7)
Q(r)J,(yp)
Jo (7P) 7d7 +
2’m,
T,, = (h - Z) 1 Q (7) e-u(h-z)Jl(yp) ra d7 -
e-d”-z)]Q(7)
i[e-~V+L
Jdyp)d7\ I
ye-y(h+
(h J $1 e-y(hSzK? (7) JI (7~) 7” d7 (1.5) 0
0
=
(1 S4)
0
0
zL
I)
ydy -
Q
(7)
Jo (7~) 7d7 - ~c--y(h+zi
Q(7)JO(7~) 7d7
-
(1.6)
0
-
(h
-
z)
re-y(h+
Q (y) Jo (7~) Tad7 - (h + 2) r eeY(“+‘) Q (7) JO(7~) rad7 0
0
Q(7) =
jP(P)Jo(7P)P&
Q (P) = 01
A (7h) = 2yh + sh 27)~
ifl
p>i
(1.7) (1.8)
Pressure
22
of
(yz) =
a die
on an elastic
layer
of
finite
e--h [7ha (7h) sh 7z + b (7~) (7~ ch 72 -
thic&ness
v
639
sh 7~)]
(1.9)
za (72) = e--yh [ylza (7h) sh yz + b (72) 72 ch 721
(1.10)
x4 (72) = e-Yh l7ha (y/z)ch 72 + b (7h) (72 sh 72 -
a ($2) = e--Yhch y/zFor any function boundary conditions:
Q(y),
formulas
W = Tpz= 0 In order and die,
to fulfill
the function
2712,
for
(1.1)
z=o,
must satisfy
w=6-y(p) Q, = 0 Here S is
b (7h) = e--yh sh 71~+
satisfy
Tpz = 0
for
the displacement
of contact
the following
(1.12)
the following
(1.13)
2= h
between the layer relations:
forO,(p<1,
z=h
(1.14)
for f
2=k
(1.15)
of the die due to force
Gnsidering relations (l.l), and (1.13) will be satisfied if
(1.11)
2yh
to (1.4)
tm, more conditions Q(y)
ch 7z)]
P.
(1.41 and (1.71, we conclude that Q(y) is determined from equations:
(1.14)
lx3
s
ch (2yh) -
0
1
A (yh)
Q (7) J0 (7P) d7 = c 1s --p(p)1
(c=&)
YQ (7) Jo (7P) 7d7 = 9
0
P
[U.W
(1.17)
(1 < PI
Thus the problem of die pressure on an elastic layer may be reduced to solving the paired integral equations (1.161 and (1.17). 2. Redrrction of problem to Fredholm integrals. Method of solution. It is proved in I31 that formulas TQ (YIJO (7P) d7 = g (P) (9 G P G I),
YQ (7) Jo (7P) 7d7 = 9
0
0
are equivalent
provided
(1 < P)
to
that q(p)
is
a continuous
function
on the interval
[O,ll
,
(2.1)
640
I.I.
For Q(y)
we obtain
Vorovich
and
from (1.16)
Iu.A.
Ustinov
and (1.17)
(O<'pGl)
i44(r)JO(7P)d7=C[6-~(P)l+~~(r)D(2lh)Jo(7P)d~
(2.3)
0
0 co
(TP)vh = 0
pr)Jo
Here
1 + 2yh -
B(27h) = Equating
(2.1)
- (2.5)
(2.6)
may be simplified
(2.4)
(1
,-=uh
(2.5)
2yh + sh 2yh
we conclude
that Q(y)
satisfies
the following
equation:
Equation
by utilizing
1
s
=-
$i+dy Y
0
From (2.7)
the following
formula is
the well-known
sin ~4 u
easily
relation
(2.7)
obtained:
~c~s~S~~Q(?)BOJ,(TP)~~+ 0
0 cell
Q(r)B
y"g; +3s\
(2yh)Jo(yyu)drdy du =
0 00 001
=-
2 IL ss
cos
uu cos
TUB (2yh)Q (7)dy du
(2.8)
00
In addition,
it
is clear
that given the relation
(2.9) (2.8) and (2.9) will
simplify
equation
(2.6)
to
Pressure
of
a die
on
an
elastic layer
of
finite
cosaucosyuB(2yh)Q(~)dy
641
thickness
du
(2.10)
00 let the operator A (Q)
be given by cos au cos yuB (2yh)Q (7)dy du
A(Q) =+i\
(2.11)
00 It is clear that A holds in the domain of functions C[O, -1, i.e. in the domain of continuous and bounded (on the semiaxis) functions with the norm IIQ II = SUP I Q I
(2.12)
(OSaCr=)
We will show that A is a fully continuous operator. let IR) be some multitude bounded in C[O, ml. We will establish that the multitude (A(R) 1 is compact in this domain. To establish this it is sufficient to prove that (A(R) 1 is uniformly bounded in C[O,m] and uniformly continuous on 10, ml. ‘Ihe first condition is clearly evident from (2.11) if we consider that
Y(B 2yh )dy < oo
(2.13)
0
Further we have
lA[I?(a+L)]-A~[~(a)]l<$~\[cos(a+L)u-cosau]
x
x ( cos 7~ [ B (2&;, R ( drdu
(2.14) (2.15)
From (2.14) we easily obtain
IA[R(a+h)]-A[R(a)](<
qlnuihl~juB(2yb)dldu=~n~B(2~~~)d~ 0 0
0
(2.13) and (2.15) establish the uniform continuity on[O, -1. ?herefore this shows that A is a fully continuous operator in C[O,=l. Accordingly, in order to prove that equation (2.10) is a solution it must be shown that from the relation
D(a)=0
642
I.I.
Vorovich
Ustinov
and Iu.A.
where
D(a)=
Icl~-~c[cosaS~dy+S~y~(u~~a~~~audydu] 0
it
follows ive will
that Q(a) prove
I
first
0 in view of equation that if
D(a)
8 = 0, Specifically,
(2.16) 00
equation
D(a)
I
(2.10).
E 0 then it
follows (2.17)
‘p (9) = 0 0 is equivalent
to
[6 - ‘p(y)] sin au dudy = 0 If a = 0 is
substituted
into
(2.18)
(2.18)
we obtain
sy [8 1
(2.19)
cp(y)] dy = 0
ovi=j2
As in the definition of 6 on the surface of contact 6 - +(p) > 0, so from equation (2.19) we obtain S - 4(y) E 0 on the surface of contact. Furthermore, if equation (2.10) had a non- trivial solution Q’(a) for 3 0, then formulas (1.1) to (1.6) with Q” substituted for Q, would always give the regular (at infinity) solution by the theory of elasticity for a layer with the boundary conditions given by (1.13), (1.15) and in addition with
D(a)
w=o,
if
o
(2.20)
1
0 over the entire layer, Under these conditions w = I will result in Q(a) I 0. ‘Iheref%e=e”$aLion (2. lo), which defines problem, always has a unique solution. Assuming that c+(y) is
a twice continuously
differentiable
which our
function
on
IO,11 ( we have 1 2 -x
sin a
a c [ 6 --cosa
5 0
-+++
dy + 5 j y’p‘“v”G; 00
au dydu] =
(2.21)
Pressure
a die
of
on an elastic
layer
of
finite
643
thickness
eO1
1scos au cos yuB
Q (7) dy du =
(Zyh)
(2.22)
0 0
= a?
r 1 B (2yh) Q (7) sin au sin yu dydu
TB (2yh) Q (7) COST dr+ $
0
0
ESymeans of following
(2.21)
and (2.22)
equation
(2.10)
may be written
in the
form:
vF=$
0 29’ (yu) + uy*qf (p)
dydu] + ;
p+
YB (2yh) Q (7) cos 7 dy + 0
(2.23)
+~~j~B(2yh)Q(y)sinausin7ud~du] On the right-hand first
and third
transforms plane. I.
side of
member will
(2.23)
in the second and fourth
Consequently ‘lhe shape of
the Fourier-Bessel
be irregular
we will
member will
consider
the die is
transforms
in the
for p = 1. ‘lbe Fourier-Bessel be regular
the following
such that
the surface
the boundary of the die (Fig. 2). In this rived directly from equation (2.10).
over the entire
twr, cases: of contact
case the solution
extends
to
must be de-
P
& Fig.
II.
lhe
surface
of contact
X
2.
remains within
the boundary of the die,
in
which case we must have +1
c
s 0
and equation
&/ - YQ(Y) - Q’(Y) Ya + vi-yy'
(2.23)
becomes:
~W~h)QOcodr =0
(2.24)
0
I.I.
644
Vorovich
and Iu.A.
Ustinov
(2.25)
Solving(2.25)
q(p ) and the corresponding
for Q we can obtain
force
P
from
TQ (7) Jo(7~) r
q (P) =
dy
(2.26)
0
From (2.24)
3.
we then obtain 8,
the displacement
Solution of problem. Equation (2.10)
following
of the die .
may be written
in the
form:
QW=Qd4+4Q) Here
if
A(Q) is given by (2.111,
(3.1)
and
It is clear that A(Q) is a convergent operator in the domain C[ 0, h is large enough. In fact, from (2.11) we obtain !jAll<+[~ From (3.3)
will
it
equation
(3.1)
Similarly,
operator
can be easily
mations already
(3.3)
(2yh)dy
can be shown by me’ms of simple calculations
be a convergent
if
h > 4/n = 1.27. As will
solved
-1 ,
that A(Q)
be shown below,
by the method of successive
approxi-
when h = 2.
equation
(2.25)
may be written
in the following
Q(a)= Q&4 + K(Q)
where Q,, =
55 %
2Y29’ 'Y;y_uT'
(yu)
form: (3.4)
dydu
(3.5)
00
K(Q) =~.~57B(21h)Q(7)sinbu Simple numerical a convergent
operator
calcu:aLions
using (3.6) when h > 0.97. We will
sinyududy
(34
show that K(Q) will also be show later that (3.4) may be
Pressure
easily
of
solved
4.
a die
on an elastic
by successive
layer
approximations
Plane cylindrical die.
In this
finite
of
already
thickness
645
when h = 1.5.
case
‘p(P)=*0 and the solution
assumes the following
Solving
(4.2) Q&z)
(4.1)
to the problem should be based on equation form in view of
by successive
(2.101,
which
(4.1):
approximations
yields:
= +Sy
G-3)
Q1 (a) = Qo(a) + g
\ ~cos ay cos g
B(u)
“‘“y(;~~)dudy
(4.4)
00 lrnlrn
x B (u) B (v) “‘*;;;h2h’. du dv dy dx etc. ive
Passing
from
Q(a) to q(p) by means of (2.26)
app~ximations
are obtained
(4.5)
the following
success-
for q(p): 2c8
Qo(P) = nV7q3
(4.6)
4B(P) = QlfP)+ co
2c8 +
SCWYi
s
*
co
1
B (u) cos g
f4.8)
du[ cos z cl
dz [B (v) “; 1”:hh2h, cos g
dv +
0
I
sin g
du \ cos z 0
ds.~B(v) 0
siny(~~~’ cos GdD
646
1.1.
Vorovich
and Xu.A.
Ustinov
sin (Y I%
x ~O~~dv~~os~dv~B~~~
cos
y/zh
ZY xdr
(4.9)
0
0
To simplify their use, (4.6) to (4.9) may be expressed in an asymptotic form for large values of h. 'Ibisleads to the following approximate formulas: (4.10) 0.755 1+T+!gI+09gL
2c8 “l/t-p*
%(fJl=
q2(P)=sv;)
[
*[l+“~+!+*!!+!$!L --P
0.763
_~s+a(G!$E+__+~_
...I
0.755 ~+T+y+qz+*!L!$_T_
2cS QS w = 1Efi
o$)+ppr$+oT)+
0.237
I (4.13)
_,2(~+~+3+_o~)+,4(~+%.$)+...]
2c8 -
94(P) = P2
-
qb(P)=
(4.12)
II 1;
%fl-pa
0.755 h ;
0~~0 ~_~~~+~_~-
1.012 __+“~+?$LA!~)+p(~+o?_)+
. ..I
(4.14)
(
2~[1+0~+*~+*~+0~+~_0~_ xfl-p*
(4.15)
_pq?g5+!!$!?_+5p.i!g)+p4(?~+~)+...]
2c8 Qa (P) = XVI--P* _-
1) I
0.755 h
p;o
py
pg+“!?._
0.342 r+
Pressur.e
of
a die
on an elastic
layer
of
finite thickness
647
Exmnination of formulas (4.10) to (4.16) indicates that in transition from asymptotic expansion q, to asymptotic eqansion q,+ 1 the coefficients of hak(R = 0, 1, . . . . n) remain identical. This leads us to conclude that the first n terms in the asymptotic expansion q, coincide exactly with the first n terms in the expansion of q in asymptotic series. In accordance with formulas (4.10) to (4.16), the following approximations are obtained for the force P acting on the die: P,=
4cs
(4.17)
PI = 4c6 1+ [ p*=4cs
09
0.337
-T+F+...]
l+~+O~-TC
(4.18) 0.337
p,=4c~1+~+0!J+~~--T;i-_ [
0.508 -ha+o$+O$+ 0.508
*..](4.19)
0.348 h6 +
F
+
0.074 he +
p6=4cfj
. - $4.20)
0.074 -hb +
. .-
0.110 h6
. . .
l+!J~+~!?__+!?$-~~--~[
+
1 1 1
-. - (4.21) (4.22)
(4.23)
The accuracy of expansions (4.10) to (4.16) and (4.17) to (4.23) improves with increasing values of h. For example, for h = 1.5 the difference between fifth and sixth approximation of P is only 2 per cent, which indicates that formula (4.23) gives good approximation for h > 1.5.
Fig.
3.
Fig.
4.
Similar analysis of formulas (4.10) to (4.16) shows that for h = 1.7 the difference between fifth and sixth approximations of the stress under
648
I.I.
Vorowich
the die is
again 2 per cent.
mation for
h > 1.7.
On the basis
of
formulas
and 1u.A.
Therefore
(4.10)
analyze the effect of thickness due to the loaded die.
of
Vstinov
formula (4.15)
gives
to (4.16)
and (4.17)
the layer
on the stress
good approxi-
to (4.23)
we may
distribution
Fig. 3 shows the variation of q(p, h) given by formula (4.15). illustrates the force of penetration P for different values of h. 5.
Parabolic die. Let us now assume that $6)
is given
(5.1)
Since the surface r#(p) is smooth in this case, equation (2.25) be used to determine Q. Substituting (5.11 into (2.251 we obtain
case formula
(2.24)
4
by
cfM=z$
In this
Fig.
must
yields:
cp--g+$2($3(u)cos~du= 0
(5.3)
0 Recall
that the boundary radius
of
the surface
of contact
was assumed
as unity. ‘lhe results
of successive
approximations
for
the pressure
under the
die q(p ) are the following:
It can be easily corrective
terms of
recognized
that
the order
of h-”
further
approximations
will
contain
and higher.
For the force P which will result in penetration 6 consistent the given loading conditions we obtain the following relations:
with
Pressure
of
a die
on
an
elastic
layer
of
finite
thickness
649
Formulas (5.4) to (5.7) are recommended when h > 1.5. If we omit the requirement that the boundary radius of contact surface be unity, formula (5.7) assumes the form: P,==g[l
+0.337(+0.342($+ + 0.037(G)'-0.23O(;y
0.114(;~+ +
l
.-1
where a is the radius of the boundary of contact surface, and H is the thickness of the layer.
Fig.
Fig.
5.
7.
Fig.
Fig.
6.
8.
From (5.3), (5.5), and (5.8) the following formulas can be obtained:
650
Vorouich
and
0.114 c;)”
+
I.I.
a -=--
H
2
0.113 ($7
+
-0.504
@>”
6 =- “R”[h)”
4cH a, (/ mar = xN [H +
-0.225
0.225 (s)”
=
fkre
trate q(p)
4, the
x %
is
on the thickness
($)‘-
-0.0126
3PR(m -
1)
**l
0.197 ($>” +
@)7
+
0.013 (3)”
(599) . . .]
+
l
l
. ]
7
under the die.
by (5.9),
+
‘1.
8/u
the maximum pressure
ependence given
-0.,04(~)~
-0.098
6;)”
0
Ustinov
0.025 &)’
($y
-0,018
a
Iu.A.
and Fig.
Figs.
5, 6, 7 illus-
8 shows the depentlence of
h.
In conclusion it should be noted that equations (4.2) and (5.21, define Q(a) and which we-e shown to be Fredholm integrals, pennit numerical integration for any value of )1.
which
BIBLIOGRAPHY 1.
Lebedev, N.N. and Ufliand, 1a.S.) Osesimmetrichnaia zadacha dlia uprugogo sloia (Axially-symmetric an elastic
2.
Lur’ e,
PMM Vol.
A. I. , Prostranstvennye
dimensional
3.
layer).
Sneddon, Literature
I. N.,
Problems
22,
No.
zadochi of
the
Preobratovoniia Publishing House,
Theory Fur *e
3,
for
1958.
teorii of
kontaktnaia contact problem
uprtihosty
Elasticity).
(Fourier
(Thrce-
GITTL,
Transforrs).
1955. Foreign
1955.
Translated
by
R.L.
PRESSURE
(0 DAVLENII
SHTAMPA
PMM Vo1.23, I. I.
NA SLOI No.3,
VOROVICH
KONECWNOI pp.
1959,
and
1u.A.
LAYER
TOLSHCAINY)
445-455
USTINOV
(Rostov-on-Don) (Received
This
article
considers
on an elastic
layer
in terms of
tained
dimensionless dies the
diameter
of of
of
2.
Statement
h rest
on a rigid
layer.
of
contact.
problem.
loaded by a force P along its of contact
1958)
pressure
of
Solution
to
an axisymmetric this
problem
obtained of
layer
adequately is
of
the
ob-
described
order
of
the
l
Lt an elastic layer of finite foundation. An axially-symnetrical
axis
die
is
in powers of h-l, where h is the The cases of plane and parabolic
thickness
frictionless
Let the surface
the
The solution
when the
of
of
series
the
in detail. surface
June
thickness.
asymptotic
stress the
problem
finite
thickness
are studied state
the of
if
of symnetry,
between the die
acts on this
and layer
thickness die,
layer
be defined
(Fig.l). in
cylindrical coordinates by the equation z = #&I. The boundary of this surface is assumed to be a circle of unit radius. ‘Ihe plane xy will be located on the rigid foundation, and the z-axis will be directed along the axis of the die.
l
After
this
article
was submitted
for
tion of the authors that another [ 11 considers the axially-symmetric on a layer applicable, ever, its integral
of
finite
thickness.
generally use involves with
printing,
subsequent
of
came to
the
atten-
The solution given in [ 11 will be any dimensionless thickness h. Howevaluation of a certain Fredholm
for speaking, the numerical numerical
finding
respect the asymptotic formulas presented since in numerous cases they give directly characteristics
it
paper, written by Lebedev and Ufliand problem of a plane circular die
the problem.
637
of
quadratures.
In this
in this work are important, all the fundamental
638
I.I.
Yorouich
and
Ustinov
Iu.A.
1
Fig.
Assune that the pressure between the die and layer is a known function From [ 21 , which considers equilibrium of an elastic layer subjected
q(p 1.
to the action relations:
of known forces
on its
boundary,
sqqj-
O”Q(Y)
ul=w-$
22 (74 Jo
we obtain
the following
(1.1)
(7P)d7
0 T’pz
=Tp*f2
O” Q(Y) igpqs
23
w
Jl(7P)7d7
(1.2)
Jo (7~) 7d7
(1.3)
0
Qz=
I:I --2~~($) -
~4
W
0
W =--
-(h
+
z$?-
‘B
y(h+z)Q (7)
Q(r)J,(yp)
Jo (7P) 7d7 +
2’m,
T,, = (h - Z) 1 Q (7) e-u(h-z)Jl(yp) ra d7 -
e-d”-z)]Q(7)
i[e-~V+L
Jdyp)d7\ I
ye-y(h+
(h J $1 e-y(hSzK? (7) JI (7~) 7” d7 (1.5) 0
0
=
(1 S4)
0
0
zL
I)
ydy -
Q
(7)
Jo (7~) 7d7 - ~c--y(h+zi
Q(7)JO(7~) 7d7
-
(1.6)
0
-
(h
-
z)
re-y(h+
Q (y) Jo (7~) Tad7 - (h + 2) r eeY(“+‘) Q (7) JO(7~) rad7 0
0
Q(7) =
jP(P)Jo(7P)P&
Q (P) = 01
A (7h) = 2yh + sh 27)~
ifl
p>i
(1.7) (1.8)
Pressure
22
of
(yz) =
a die
on an elastic
layer
of
finite
e--h [7ha (7h) sh 7z + b (7~) (7~ ch 72 -
thic&ness
v
639
sh 7~)]
(1.9)
za (72) = e--yh [ylza (7h) sh yz + b (72) 72 ch 721
(1.10)
x4 (72) = e-Yh l7ha (y/z)ch 72 + b (7h) (72 sh 72 -
a ($2) = e--Yhch y/zFor any function boundary conditions:
Q(y),
formulas
W = Tpz= 0 In order and die,
to fulfill
the function
2712,
for
(1.1)
z=o,
must satisfy
w=6-y(p) Q, = 0 Here S is
b (7h) = e--yh sh 71~+
satisfy
Tpz = 0
for
the displacement
of contact
the following
(1.12)
the following
(1.13)
2= h
between the layer relations:
forO,(p<1,
z=h
(1.14)
for f
2=k
(1.15)
of the die due to force
Gnsidering relations (l.l), and (1.13) will be satisfied if
(1.11)
2yh
to (1.4)
tm, more conditions Q(y)
ch 7z)]
P.
(1.41 and (1.71, we conclude that Q(y) is determined from equations:
(1.14)
lx3
s
ch (2yh) -
0
1
A (yh)
Q (7) J0 (7P) d7 = c 1s --p(p)1
(c=&)
YQ (7) Jo (7P) 7d7 = 9
0
P
[U.W
(1.17)
(1 < PI
Thus the problem of die pressure on an elastic layer may be reduced to solving the paired integral equations (1.161 and (1.17). 2. Redrrction of problem to Fredholm integrals. Method of solution. It is proved in I31 that formulas TQ (YIJO (7P) d7 = g (P) (9 G P G I),
YQ (7) Jo (7P) 7d7 = 9
0
0
are equivalent
provided
(1 < P)
to
that q(p)
is
a continuous
function
on the interval
[O,ll
,
(2.1)
640
I.I.
For Q(y)
we obtain
Vorovich
and
from (1.16)
Iu.A.
Ustinov
and (1.17)
(O<'pGl)
i44(r)JO(7P)d7=C[6-~(P)l+~~(r)D(2lh)Jo(7P)d~
(2.3)
0
0 co
(TP)vh = 0
pr)Jo
Here
1 + 2yh -
B(27h) = Equating
(2.1)
- (2.5)
(2.6)
may be simplified
(2.4)
(1
,-=uh
(2.5)
2yh + sh 2yh
we conclude
that Q(y)
satisfies
the following
equation:
Equation
by utilizing
1
s
=-
$i+dy Y
0
From (2.7)
the following
formula is
the well-known
sin ~4 u
easily
relation
(2.7)
obtained:
~c~s~S~~Q(?)BOJ,(TP)~~+ 0
0 cell
Q(r)B
y"g; +3s\
(2yh)Jo(yyu)drdy du =
0 00 001
=-
2 IL ss
cos
uu cos
TUB (2yh)Q (7)dy du
(2.8)
00
In addition,
it
is clear
that given the relation
(2.9) (2.8) and (2.9) will
simplify
equation
(2.6)
to
Pressure
of
a die
on
an
elastic layer
of
finite
cosaucosyuB(2yh)Q(~)dy
641
thickness
du
(2.10)
00 let the operator A (Q)
be given by cos au cos yuB (2yh)Q (7)dy du
A(Q) =+i\
(2.11)
00 It is clear that A holds in the domain of functions C[O, -1, i.e. in the domain of continuous and bounded (on the semiaxis) functions with the norm IIQ II = SUP I Q I
(2.12)
(OSaCr=)
We will show that A is a fully continuous operator. let IR) be some multitude bounded in C[O, ml. We will establish that the multitude (A(R) 1 is compact in this domain. To establish this it is sufficient to prove that (A(R) 1 is uniformly bounded in C[O,m] and uniformly continuous on 10, ml. ‘Ihe first condition is clearly evident from (2.11) if we consider that
Y(B 2yh )dy < oo
(2.13)
0
Further we have
lA[I?(a+L)]-A~[~(a)]l<$~\[cos(a+L)u-cosau]
x
x ( cos 7~ [ B (2&;, R ( drdu
(2.14) (2.15)
From (2.14) we easily obtain
IA[R(a+h)]-A[R(a)](<
qlnuihl~juB(2yb)dldu=~n~B(2~~~)d~ 0 0
0
(2.13) and (2.15) establish the uniform continuity on[O, -1. ?herefore this shows that A is a fully continuous operator in C[O,=l. Accordingly, in order to prove that equation (2.10) is a solution it must be shown that from the relation
D(a)=0
642
I.I.
Vorovich
Ustinov
and Iu.A.
where
D(a)=
Icl~-~c[cosaS~dy+S~y~(u~~a~~~audydu] 0
it
follows ive will
that Q(a) prove
I
first
0 in view of equation that if
D(a)
8 = 0, Specifically,
(2.16) 00
equation
D(a)
I
(2.10).
E 0 then it
follows (2.17)
‘p (9) = 0 0 is equivalent
to
[6 - ‘p(y)] sin au dudy = 0 If a = 0 is
substituted
into
(2.18)
(2.18)
we obtain
sy [8 1
(2.19)
cp(y)] dy = 0
ovi=j2
As in the definition of 6 on the surface of contact 6 - +(p) > 0, so from equation (2.19) we obtain S - 4(y) E 0 on the surface of contact. Furthermore, if equation (2.10) had a non- trivial solution Q’(a) for 3 0, then formulas (1.1) to (1.6) with Q” substituted for Q, would always give the regular (at infinity) solution by the theory of elasticity for a layer with the boundary conditions given by (1.13), (1.15) and in addition with
D(a)
w=o,
if
o
(2.20)
1
0 over the entire layer, Under these conditions w = I will result in Q(a) I 0. ‘Iheref%e=e”$aLion (2. lo), which defines problem, always has a unique solution. Assuming that c+(y) is
a twice continuously
differentiable
which our
function
on
IO,11 ( we have 1 2 -x
sin a
a c [ 6 --cosa
5 0
-+++
dy + 5 j y’p‘“v”G; 00
au dydu] =
(2.21)
Pressure
a die
of
on an elastic
layer
of
finite
643
thickness
eO1
1scos au cos yuB
Q (7) dy du =
(Zyh)
(2.22)
0 0
= a?
r 1 B (2yh) Q (7) sin au sin yu dydu
TB (2yh) Q (7) COST dr+ $
0
0
ESymeans of following
(2.21)
and (2.22)
equation
(2.10)
may be written
in the
form:
vF=$
0 29’ (yu) + uy*qf (p)
dydu] + ;
p+
YB (2yh) Q (7) cos 7 dy + 0
(2.23)
+~~j~B(2yh)Q(y)sinausin7ud~du] On the right-hand first
and third
transforms plane. I.
side of
member will
(2.23)
in the second and fourth
Consequently ‘lhe shape of
the Fourier-Bessel
be irregular
we will
member will
consider
the die is
transforms
in the
for p = 1. ‘lbe Fourier-Bessel be regular
the following
such that
the surface
the boundary of the die (Fig. 2). In this rived directly from equation (2.10).
over the entire
twr, cases: of contact
case the solution
extends
to
must be de-
P
& Fig.
II.
lhe
surface
of contact
X
2.
remains within
the boundary of the die,
in
which case we must have +1
c
s 0
and equation
&/ - YQ(Y) - Q’(Y) Ya + vi-yy'
(2.23)
becomes:
~W~h)QOcodr =0
(2.24)
0
I.I.
644
Vorovich
and Iu.A.
Ustinov
(2.25)
Solving(2.25)
q(p ) and the corresponding
for Q we can obtain
force
P
from
TQ (7) Jo(7~) r
q (P) =
dy
(2.26)
0
From (2.24)
3.
we then obtain 8,
the displacement
Solution of problem. Equation (2.10)
following
of the die .
may be written
in the
form:
QW=Qd4+4Q) Here
if
A(Q) is given by (2.111,
(3.1)
and
It is clear that A(Q) is a convergent operator in the domain C[ 0, h is large enough. In fact, from (2.11) we obtain !jAll<+[~ From (3.3)
will
it
equation
(3.1)
Similarly,
operator
can be easily
mations already
(3.3)
(2yh)dy
can be shown by me’ms of simple calculations
be a convergent
if
h > 4/n = 1.27. As will
solved
-1 ,
that A(Q)
be shown below,
by the method of successive
approxi-
when h = 2.
equation
(2.25)
may be written
in the following
Q(a)= Q&4 + K(Q)
where Q,, =
55 %
2Y29’ 'Y;y_uT'
(yu)
form: (3.4)
dydu
(3.5)
00
K(Q) =~.~57B(21h)Q(7)sinbu Simple numerical a convergent
operator
calcu:aLions
using (3.6) when h > 0.97. We will
sinyududy
(34
show that K(Q) will also be show later that (3.4) may be
Pressure
easily
of
solved
4.
a die
on an elastic
by successive
layer
approximations
Plane cylindrical die.
In this
finite
of
already
thickness
645
when h = 1.5.
case
‘p(P)=*0 and the solution
assumes the following
Solving
(4.2) Q&z)
(4.1)
to the problem should be based on equation form in view of
by successive
(2.101,
which
(4.1):
approximations
yields:
= +Sy
G-3)
Q1 (a) = Qo(a) + g
\ ~cos ay cos g
B(u)
“‘“y(;~~)dudy
(4.4)
00 lrnlrn
x B (u) B (v) “‘*;;;h2h’. du dv dy dx etc. ive
Passing
from
Q(a) to q(p) by means of (2.26)
app~ximations
are obtained
(4.5)
the following
success-
for q(p): 2c8
Qo(P) = nV7q3
(4.6)
4B(P) = QlfP)+ co
2c8 +
SCWYi
s
*
co
1
B (u) cos g
f4.8)
du[ cos z cl
dz [B (v) “; 1”:hh2h, cos g
dv +
0
I
sin g
du \ cos z 0
ds.~B(v) 0
siny(~~~’ cos GdD
646
1.1.
Vorovich
and Xu.A.
Ustinov
sin (Y I%
x ~O~~dv~~os~dv~B~~~
cos
y/zh
ZY xdr
(4.9)
0
0
To simplify their use, (4.6) to (4.9) may be expressed in an asymptotic form for large values of h. 'Ibisleads to the following approximate formulas: (4.10) 0.755 1+T+!gI+09gL
2c8 “l/t-p*
%(fJl=
q2(P)=sv;)
[
*[l+“~+!+*!!+!$!L --P
0.763
_~s+a(G!$E+__+~_
...I
0.755 ~+T+y+qz+*!L!$_T_
2cS QS w = 1Efi
o$)+ppr$+oT)+
0.237
I (4.13)
_,2(~+~+3+_o~)+,4(~+%.$)+...]
2c8 -
94(P) = P2
-
qb(P)=
(4.12)
II 1;
%fl-pa
0.755 h ;
0~~0 ~_~~~+~_~-
1.012 __+“~+?$LA!~)+p(~+o?_)+
. ..I
(4.14)
(
2~[1+0~+*~+*~+0~+~_0~_ xfl-p*
(4.15)
_pq?g5+!!$!?_+5p.i!g)+p4(?~+~)+...]
2c8 Qa (P) = XVI--P* _-
1) I
0.755 h
p;o
py
pg+“!?._
0.342 r+
Pressur.e
of
a die
on an elastic
layer
of
finite thickness
647
Exmnination of formulas (4.10) to (4.16) indicates that in transition from asymptotic expansion q, to asymptotic eqansion q,+ 1 the coefficients of hak(R = 0, 1, . . . . n) remain identical. This leads us to conclude that the first n terms in the asymptotic expansion q, coincide exactly with the first n terms in the expansion of q in asymptotic series. In accordance with formulas (4.10) to (4.16), the following approximations are obtained for the force P acting on the die: P,=
4cs
(4.17)
PI = 4c6 1+ [ p*=4cs
09
0.337
-T+F+...]
l+~+O~-TC
(4.18) 0.337
p,=4c~1+~+0!J+~~--T;i-_ [
0.508 -ha+o$+O$+ 0.508
*..](4.19)
0.348 h6 +
F
+
0.074 he +
p6=4cfj
. - $4.20)
0.074 -hb +
. .-
0.110 h6
. . .
l+!J~+~!?__+!?$-~~--~[
+
1 1 1
-. - (4.21) (4.22)
(4.23)
The accuracy of expansions (4.10) to (4.16) and (4.17) to (4.23) improves with increasing values of h. For example, for h = 1.5 the difference between fifth and sixth approximation of P is only 2 per cent, which indicates that formula (4.23) gives good approximation for h > 1.5.
Fig.
3.
Fig.
4.
Similar analysis of formulas (4.10) to (4.16) shows that for h = 1.7 the difference between fifth and sixth approximations of the stress under
648
I.I.
Vorowich
the die is
again 2 per cent.
mation for
h > 1.7.
On the basis
of
formulas
and 1u.A.
Therefore
(4.10)
analyze the effect of thickness due to the loaded die.
of
Vstinov
formula (4.15)
gives
to (4.16)
and (4.17)
the layer
on the stress
good approxi-
to (4.23)
we may
distribution
Fig. 3 shows the variation of q(p, h) given by formula (4.15). illustrates the force of penetration P for different values of h. 5.
Parabolic die. Let us now assume that $6)
is given
(5.1)
Since the surface r#(p) is smooth in this case, equation (2.25) be used to determine Q. Substituting (5.11 into (2.251 we obtain
case formula
(2.24)
4
by
cfM=z$
In this
Fig.
must
yields:
cp--g+$2($3(u)cos~du= 0
(5.3)
0 Recall
that the boundary radius
of
the surface
of contact
was assumed
as unity. ‘lhe results
of successive
approximations
for
the pressure
under the
die q(p ) are the following:
It can be easily corrective
terms of
recognized
that
the order
of h-”
further
approximations
will
contain
and higher.
For the force P which will result in penetration 6 consistent the given loading conditions we obtain the following relations:
with
Pressure
of
a die
on
an
elastic
layer
of
finite
thickness
649
Formulas (5.4) to (5.7) are recommended when h > 1.5. If we omit the requirement that the boundary radius of contact surface be unity, formula (5.7) assumes the form: P,==g[l
+0.337(+0.342($+ + 0.037(G)'-0.23O(;y
0.114(;~+ +
l
.-1
where a is the radius of the boundary of contact surface, and H is the thickness of the layer.
Fig.
Fig.
5.
7.
Fig.
Fig.
6.
8.
From (5.3), (5.5), and (5.8) the following formulas can be obtained:
650
Vorouich
and
0.114 c;)”
+
I.I.
a -=--
H
2
0.113 ($7
+
-0.504
@>”
6 =- “R”[h)”
4cH a, (/ mar = xN [H +
-0.225
0.225 (s)”
=
fkre
trate q(p)
4, the
x %
is
on the thickness
($)‘-
-0.0126
3PR(m -
1)
**l
0.197 ($>” +
@)7
+
0.013 (3)”
(599) . . .]
+
l
l
. ]
7
under the die.
by (5.9),
+
‘1.
8/u
the maximum pressure
ependence given
-0.,04(~)~
-0.098
6;)”
0
Ustinov
0.025 &)’
($y
-0,018
a
Iu.A.
and Fig.
Figs.
5, 6, 7 illus-
8 shows the depentlence of
h.
In conclusion it should be noted that equations (4.2) and (5.21, define Q(a) and which we-e shown to be Fredholm integrals, pennit numerical integration for any value of )1.
which
BIBLIOGRAPHY 1.
Lebedev, N.N. and Ufliand, 1a.S.) Osesimmetrichnaia zadacha dlia uprugogo sloia (Axially-symmetric an elastic
2.
Lur’ e,
PMM Vol.
A. I. , Prostranstvennye
dimensional
3.
layer).
Sneddon, Literature
I. N.,
Problems
22,
No.
zadochi of
the
Preobratovoniia Publishing House,
Theory Fur *e
3,
for
1958.
teorii of
kontaktnaia contact problem
uprtihosty
Elasticity).
(Fourier
(Thrce-
GITTL,
Transforrs).
1955. Foreign
1955.
Translated
by
R.L.