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A theory of tube sinking
MECH. RES. COMM.
A THEORY
OF
Vol.2,
TUBE
233-238,
1975.
Pergamon Press.
Printed in USA.
SINKING
N. Cristescu University of Bucharest, Romania (Received 5 May 1975; accepted as ready for print 28 July 1975)
1.
Introduction
The theory considered here assumes that the procass of tube sinking (decrease of its outer diameter) through a conical die will be accompanied by a reduction of the wall thickness. A land of die as well as a mandrel will also be considered (see Fig.1 where the notations are selfexplanatory). The geometry of the process is similar to the one assumed by Avitzur [1] Ch.12 : in the region II the material is deforming plastically,and the velocity field in spherical coordinates is •
v-
-vfr
2 cos0 ~
,
v 0 = v~ = o .
(1.1)
In the regions I and III the material is assumed to be rigid and moving with the velocity -v o and -vf respectively. Other obvious geometrical relations are tf
Rof
Vo
R2 if
(1.2)
2 Rof
1
It is also assumed that at the spherical surface ~ the velocity has a tangential discontinuity v t = -vfsin@ . Sim~'larly at ro the tangential discontinuity of the velocity is v t = VoSin6 If the length of the land of die is L, the mandrel will be in contact with the inner surface of the tube along a cylindrical surface of the length L +Z~L where
V2 I L o %f
cos (~" ~ i) sin2 ~
Rif~2
(.I - ~ j
•
(1.3)
. . . . . . . . . . .
A Bingham type constitutive equation ly as it was done for the drawing of constitutive equation with (1.1) one stress along ~I and ~2 which in turn Scientific Communication
233
will be used here similarbars [2]. Combining this can obtain the shearing can be used to estimate
234
N. C R I S T E S C U
Vol.2, N o . 5 / 6
r4
the power consumed at the surf ac~s L I and I 2. The drawing stress will be obtained from the theorem of power expended apolied to the volume of the tube comprised between the limits xf and x o. 2. The dErawing stress Using a similar procedure as in [2] the rate-of-work dissipated in domain II due to viscoplastic deformation is obtained as = 2 ~ v f R 2 f ( l n R°f~o)f (o(,o~i)+ 2?Tvf~Rof
g ( e ~ i)
(2.1)
where f (°~'c(i)= 2 ~
1_^ [cos,~c0s2~+ I 1 ln(cosc(+~cos2o(+ ~ ) sin"(XL "~ + "~
- c°sC(i~ c°s2~i + 1-W
_
1-~
g(~,oq) : y s~n~[-~ is the mean yield stress and ~ the viscosity coefficient. The friction law which is used along ~3 is a generalization for the visco-plastic model of the so-called "coostant friction factor" which is taken in the form ~ = m I ~ s where II s is the second invariant of the stress deviator and m a constant friction coefficient. It has been shown for the drawing of bars [2] that this law and the Coulomb law are leading to practically the same results. The dissipated rate-of-work due to friction along ~3 is then W~3=-2SmvfR2fcoto(
In ROfRo +
~+1
,(2.3)
In a similar way the dissipated rate-of-work due to friction along ~4 is
w~4 =
~n
~ vf2~RofT
(2.4)
where n is the constant friction coefficient (n=m or n#m), and along ~6
w•Q
~ -n ~~ vf2~ Rif (L + A L )
•
(2.5)
Vol.2, No.5/6
235
THEORY OF TUBE SINKING
Along the surfaces ~5' ~ and F'8 we have wr5, wc7 = Wrs. o. The power consumed at ~I and ~2 can be computed following a procedure given in [5]: --v~of 2{ I P(~'
~vf q(~'~i ) } + off
T'f(%,]~
" 2~ VfRof 2 II p(~,o(i) WF2=
(2.6)
}
where
1 [cos~ff 2. 1~ - ~ ~sin~ [ 2 ~ T
cos~. "'
1
2223in(2V11(11cos~+1)
_1__ 2_~ ln(2~11(qlcos~i+l)+22cos~(i) ) J
q(~,0(i) =
coso( + ~
cos~i-
cos~ i
(2.7)
The power of the applied stress is
(oZT~/
1 -
] ~T~
(2.8)
and the power of the back tension
2[
(2.9)
All these formulae introduced in the theorem of power expended yields
+Nq(~'qi)
+" 0
Rif L + ~n I~of +~-F-(
Rof
~
g(~,O(i ) + 2P(~,C(f) +
~ cot0( In
[I_
(2.1o)
where ~vf
(2.11)
236
N. CRISTESCU
is the dimensionless
Vol.2, No. 5/6
"speed effectiveness
parameter"
(see [2]).
~]quation (2.10) gives the drawing stress as a function drawing speed, reduction, tion coefficient influence
wall thickness,
semicone
angle, fric-
and length of the land of die. By N the speed
is introduced in (2.11). Thus this
influence depends
not on the working speed alone, but essentially here the measure
of :
of ths rate dependence
to a lesser degree, N depends
on ~
which is
of the material considered;
on the mean yield stress and Rof too.
3. ,i~amples In order to show the influence meters
of the previously mentioned para-
on the drawing stress some numerical examples were computed
for a certain sort of aluminium.
The constants used are: ~
= 16
kg r~ -2 , 6-xb= 0, m = n = 0.Ol~, L = 2 ram, Rof = 15 mm. To obtain various wall thicknesses was varied.
in (2.10), Rof was kept constant
It was thought that the results are more suE;gestive
if instead of the total drawing force stress,
and Rif
a dimensionless
is used. Very low speeds N = 0.149 and N = 0.3
or the relative
drawing force defined (i.e. N ~ O ) angle
(Ri/Ro = 0.2 and 0.8)
10'~ a~d 4 ~
where -=
by F = ~ / ( 2 ~ R 2 o f ~ )
of tl~e dimensionless
o~ is shown in Fig.2
thicknesses
1oo
and two reductions
1
drawing
have been compared with
• The variation
force with the semicone
Full lines correspond
~
-
i
--J
drawing
for two wall in area r =
•
to N=O, broken lines to N=0.149,
and dotted
lines to N=0.3. The minimum points on these curves correspond to the optimum semicone
an~:le O~opt; this angle is obviously depen-
dent on N and the thickness. cant for ~igher reductions dimensionless same values
The speed influence
is more signifi-
and thicker tubes. The variation of the
drawing force with the wall thickness for o( =6 ° and
of r and N as above, is shown on Fig.3. Thus the
"speed influence" is more si~:nificant for thicker tubes and bigger reductions. values
of O~
The maximum possible and wall thickness
reduction
in area for various
is shown on Fi~j.4, for N=O and
N=0.149 and for several wall thicknesses
(Ri/Ro = 0.1; 0.5 ; 0.7;
Vol.2, No.5/6
237
THEORY OF TUBE SINKING
0.9). Points wh.ic~ are under the curves shown are possible reduc tions. The curves have been obtained from the condition O-xf= (see [2]). The computatioos have been done starting from a certain value of o( on. For a given ol the 1~ximum reduction is for thin tubes much smaller than for thick tubes, mainly due to the significant increase of the internal dissipation. There is, however, a certain increase due to the velocity discontinuity and to friction too. The speed influence is for small oL negligible but increases significantly with o~ . References 1. B.Avitzur, ~;etal Forming Processes and Analysis, ~icGraw Hill Book Comp., New ~ork (1968) 2~ N. Cristescu, Int.J.~ecb.Sci., 17, #25 (1975) 9. ~. Cristescu,
(to be published)
--~I ~ L ~ - -
, J7
a \
_ Vo
I & • R~¢ &¢
t
I" zp
-
-.o--41
0
Fig.1
zo
Geometry of tube sinking
238
N. CRISTESCU
Vol.2, No.516
F U.8
--.°oo. ~ "'"°...o..
p~o
Q6
~q
~<~,.~, "~ak., °(=6° ~ ~ .
02
~[ ~
I0 ................""22"22-,TZ j
i
I
I
I
O.Z
O,~
~6
0.8
l.O
RiCo Fig.2 Variation of dimensionless
Fig.5 Variation of dimension-
drawing force with cC for various
less drawing force with thick-
drawing speeds ,tube thicknesses
ness of tube wall for r=I0%o and
and reductions in area
r=40% and three drawing speeds
f
o
Fig.4 Maximum possible reduction as function of o~ for various wall thicknesses and two drawing speeds
A THEORY
OF
Vol.2,
TUBE
233-238,
1975.
Pergamon Press.
Printed in USA.
SINKING
N. Cristescu University of Bucharest, Romania (Received 5 May 1975; accepted as ready for print 28 July 1975)
1.
Introduction
The theory considered here assumes that the procass of tube sinking (decrease of its outer diameter) through a conical die will be accompanied by a reduction of the wall thickness. A land of die as well as a mandrel will also be considered (see Fig.1 where the notations are selfexplanatory). The geometry of the process is similar to the one assumed by Avitzur [1] Ch.12 : in the region II the material is deforming plastically,and the velocity field in spherical coordinates is •
v-
-vfr
2 cos0 ~
,
v 0 = v~ = o .
(1.1)
In the regions I and III the material is assumed to be rigid and moving with the velocity -v o and -vf respectively. Other obvious geometrical relations are tf
Rof
Vo
R2 if
(1.2)
2 Rof
1
It is also assumed that at the spherical surface ~ the velocity has a tangential discontinuity v t = -vfsin@ . Sim~'larly at ro the tangential discontinuity of the velocity is v t = VoSin6 If the length of the land of die is L, the mandrel will be in contact with the inner surface of the tube along a cylindrical surface of the length L +Z~L where
V2 I L o %f
cos (~" ~ i) sin2 ~
Rif~2
(.I - ~ j
•
(1.3)
. . . . . . . . . . .
A Bingham type constitutive equation ly as it was done for the drawing of constitutive equation with (1.1) one stress along ~I and ~2 which in turn Scientific Communication
233
will be used here similarbars [2]. Combining this can obtain the shearing can be used to estimate
234
N. C R I S T E S C U
Vol.2, N o . 5 / 6
r4
the power consumed at the surf ac~s L I and I 2. The drawing stress will be obtained from the theorem of power expended apolied to the volume of the tube comprised between the limits xf and x o. 2. The dErawing stress Using a similar procedure as in [2] the rate-of-work dissipated in domain II due to viscoplastic deformation is obtained as = 2 ~ v f R 2 f ( l n R°f~o)f (o(,o~i)+ 2?Tvf~Rof
g ( e ~ i)
(2.1)
where f (°~'c(i)= 2 ~
1_^ [cos,~c0s2~+ I 1 ln(cosc(+~cos2o(+ ~ ) sin"(XL "~ + "~
- c°sC(i~ c°s2~i + 1-W
_
1-~
g(~,oq) : y s~n~[-~ is the mean yield stress and ~ the viscosity coefficient. The friction law which is used along ~3 is a generalization for the visco-plastic model of the so-called "coostant friction factor" which is taken in the form ~ = m I ~ s where II s is the second invariant of the stress deviator and m a constant friction coefficient. It has been shown for the drawing of bars [2] that this law and the Coulomb law are leading to practically the same results. The dissipated rate-of-work due to friction along ~3 is then W~3=-2SmvfR2fcoto(
In ROfRo +
~+1
,(2.3)
In a similar way the dissipated rate-of-work due to friction along ~4 is
w~4 =
~n
~ vf2~RofT
(2.4)
where n is the constant friction coefficient (n=m or n#m), and along ~6
w•Q
~ -n ~~ vf2~ Rif (L + A L )
•
(2.5)
Vol.2, No.5/6
235
THEORY OF TUBE SINKING
Along the surfaces ~5' ~ and F'8 we have wr5, wc7 = Wrs. o. The power consumed at ~I and ~2 can be computed following a procedure given in [5]: --v~of 2{ I P(~'
~vf q(~'~i ) } + off
T'f(%,]~
" 2~ VfRof 2 II p(~,o(i) WF2=
(2.6)
}
where
1 [cos~ff 2. 1~ - ~ ~sin~ [ 2 ~ T
cos~. "'
1
2223in(2V11(11cos~+1)
_1__ 2_~ ln(2~11(qlcos~i+l)+22cos~(i) ) J
q(~,0(i) =
coso( + ~
cos~i-
cos~ i
(2.7)
The power of the applied stress is
(oZT~/
1 -
] ~T~
(2.8)
and the power of the back tension
2[
(2.9)
All these formulae introduced in the theorem of power expended yields
+Nq(~'qi)
+" 0
Rif L + ~n I~of +~-F-(
Rof
~
g(~,O(i ) + 2P(~,C(f) +
~ cot0( In
[I_
(2.1o)
where ~vf
(2.11)
236
N. CRISTESCU
is the dimensionless
Vol.2, No. 5/6
"speed effectiveness
parameter"
(see [2]).
~]quation (2.10) gives the drawing stress as a function drawing speed, reduction, tion coefficient influence
wall thickness,
semicone
angle, fric-
and length of the land of die. By N the speed
is introduced in (2.11). Thus this
influence depends
not on the working speed alone, but essentially here the measure
of :
of ths rate dependence
to a lesser degree, N depends
on ~
which is
of the material considered;
on the mean yield stress and Rof too.
3. ,i~amples In order to show the influence meters
of the previously mentioned para-
on the drawing stress some numerical examples were computed
for a certain sort of aluminium.
The constants used are: ~
= 16
kg r~ -2 , 6-xb= 0, m = n = 0.Ol~, L = 2 ram, Rof = 15 mm. To obtain various wall thicknesses was varied.
in (2.10), Rof was kept constant
It was thought that the results are more suE;gestive
if instead of the total drawing force stress,
and Rif
a dimensionless
is used. Very low speeds N = 0.149 and N = 0.3
or the relative
drawing force defined (i.e. N ~ O ) angle
(Ri/Ro = 0.2 and 0.8)
10'~ a~d 4 ~
where -=
by F = ~ / ( 2 ~ R 2 o f ~ )
of tl~e dimensionless
o~ is shown in Fig.2
thicknesses
1oo
and two reductions
1
drawing
have been compared with
• The variation
force with the semicone
Full lines correspond
~
-
i
--J
drawing
for two wall in area r =
•
to N=O, broken lines to N=0.149,
and dotted
lines to N=0.3. The minimum points on these curves correspond to the optimum semicone
an~:le O~opt; this angle is obviously depen-
dent on N and the thickness. cant for ~igher reductions dimensionless same values
The speed influence
is more signifi-
and thicker tubes. The variation of the
drawing force with the wall thickness for o( =6 ° and
of r and N as above, is shown on Fig.3. Thus the
"speed influence" is more si~:nificant for thicker tubes and bigger reductions. values
of O~
The maximum possible and wall thickness
reduction
in area for various
is shown on Fi~j.4, for N=O and
N=0.149 and for several wall thicknesses
(Ri/Ro = 0.1; 0.5 ; 0.7;
Vol.2, No.5/6
237
THEORY OF TUBE SINKING
0.9). Points wh.ic~ are under the curves shown are possible reduc tions. The curves have been obtained from the condition O-xf= (see [2]). The computatioos have been done starting from a certain value of o( on. For a given ol the 1~ximum reduction is for thin tubes much smaller than for thick tubes, mainly due to the significant increase of the internal dissipation. There is, however, a certain increase due to the velocity discontinuity and to friction too. The speed influence is for small oL negligible but increases significantly with o~ . References 1. B.Avitzur, ~;etal Forming Processes and Analysis, ~icGraw Hill Book Comp., New ~ork (1968) 2~ N. Cristescu, Int.J.~ecb.Sci., 17, #25 (1975) 9. ~. Cristescu,
(to be published)
--~I ~ L ~ - -
, J7
a \
_ Vo
I & • R~¢ &¢
t
I" zp
-
-.o--41
0
Fig.1
zo
Geometry of tube sinking
238
N. CRISTESCU
Vol.2, No.516
F U.8
--.°oo. ~ "'"°...o..
p~o
Q6
~q
~<~,.~, "~ak., °(=6° ~ ~ .
02
~[ ~
I0 ................""22"22-,TZ j
i
I
I
I
O.Z
O,~
~6
0.8
l.O
RiCo Fig.2 Variation of dimensionless
Fig.5 Variation of dimension-
drawing force with cC for various
less drawing force with thick-
drawing speeds ,tube thicknesses
ness of tube wall for r=I0%o and
and reductions in area
r=40% and three drawing speeds
f
o
Fig.4 Maximum possible reduction as function of o~ for various wall thicknesses and two drawing speeds