- Email: [email protected]
Non-linear mechanical behaviour of oriented polypropylene
J. Me&. Phys. Solids, 1963, Vol. II. pp. 217 to 229. Pergamon PressLtd. Printedin Great Britain.
NON-LINEAR
MECHANICAL
ORIENTED By
I. 3%. Brown
BEHAVIOUR
OF
POLYPROPYLENE* WARD-~
University,
and E. T. Providence,
ONAT R.I.
(Receiued Sfh March, 1963)
THIS paper is concerned with the study of isothermal extensional deformations of an oriented polypropylene monofilament under time-dependent loading. The monofilament has been subjected to various loading programmes, each containing a number of loading steps. It is found that the monofilament exhibits non-linear memory dependent behaviour. The question of mathematical representation of the observed non-linear behaviour is considered. It is assumed that the elongaCon at a given time is a non-linear functional of the stress-rate history to which the filament has been subjected prior to this instance. It is then shown that the experimental results can be represented, with reasonable accuracy, by approximating this functional by the sum of a linear It is seen that the loading programmes employed in the and third order hereditary functional. study provide substantial information for the construction of the kernels defming the two functionals.
1.
INTRODUCTION
IN GENE~~AL, amorphous polymers in the temperature range of the glass-rubber transit,ion display linear viscoelastic behaviour at low strain levels (- l per cent) (FERRY 1961). This is also true for crystalline polymers within a similar but usually lower range of strain levels [e.g. polythene (KOLSKY 1960)]. For such materials there are many comprehensive studies of viscoelastic behaviour. A good example of this type of investigation is the work on pofyisobutylene reported by MARVIN (1954). In materials of high molecular orientation such as fibres, on the other hand, it is well known that the viscoelastic behaviour can be non-linear. In view of the complexity of the situat.ion a variety of different types of measurements have been made with such materials and the results have, in general, been represented either by empirical power laws relating stress and strain with time (PEIRCE 1923; PRESS and MARK 1943) or by postulating specific non-linear behaviour in terms of mechanical models with non-linear springs and ‘ activated dashpots ’ (HALSEY, WHITE and EYKING 1945). An alternative approach, proposed by Leaderman, was to attempt to derive a modified Boltzmann superposition principle (LEADERMAN 1943,
1961).
*The work reported in this paper was supported in part by Material Hewarch Program, Advanced Research Projects Agency, Department of Defense. ton secondmentto the Division of Applied Mathematics,Brown University from I.C.I. Ltd., Fibres Division, Harrogate, England. 217
I. M. WARD and E. ‘I’. ONAT
218
The
present
deformations loading.
paper
is concerned
of an oriented
The monofilament
with
the
polypropylene
study
of isothermal
monofilament
has been subjected
under
to various
extensional
time-dependent
loading
programmes;
each containing a number of loading steps, and the resulting time dependent elongations have been measured. The discussion of experimental results given in Section 4 shows that the monofilament exhibits non-linear memory-dependent mechanical behaviour. The question of a rational mathematical representation of the observed non-linear
behaviour
is considered
in Section
5.
It is assumed in this section that
the elongation at a given time is a non-linear functional of the stress-rate history to which the filament has been subjected prior to this instance. It is then shown that
the experimental
approximating functional. substantial
results
this functional
can be represented
with
reasonable
accuracy
by
by the sum of a linear and a third order hereditary
It is seen that the loading programmes information for the construction of
employed in the study provide the kernels defining the two
functions. 2.
In this section and the response
LINEAR
VISCOELASTIC
the loading
programmes
of a linear
viscoelastic
BEI~AVIOUH
employed solid
in the study
to these loading
discussed. As will be seen later, this discussion is of importance the non-linear nature of the material considered. There elastic
exist
several
behaviour
for
mathematical
representations
in bringing of linear
is out
visco-
example,
GROSS (1953) and KOLSKY (1959)]. We here with the integral representation appropriate to the uniaxial
shall be concerned stressing
equivalent
[see,
are described programmes
considered
in this paper :
e(t)
= --m
where e (t) is the elongation is the time dependent
uniaxial
I
J(t
-
T)?&
(per unit length)
of the specimen
at time t and (J (T) This represen-
stress, and J is the creep compliance.
tation can be considered to arise as a consequence of the Boltzmann superposition principle. It may also be noted that according to (2.1) the strain is a linear, continuous
hereditary
functional
Let e, (t, u,,) denote programme
of the stress history.
the strain response
U(T)==O, For a linear viscoelastic
(T(7) = ~7~= const.,
7<0; material
in a creep test defined
it follows
by the loading
7 > 0.
(2.2)
from (2.1) and (2.2) that
ec(t, ao)= J (1)uo.
(2.3)
We note from (2.3) that for a linear material the creep compliance e,/a, is independent of go and is given by the function J (t). A creep and rerooery test is characterized by the loading programme (Fig. la) C = 0, The following
7 < 0;
expression
(5=oo,
is denoted
o
u=o, response
T
(2.4)
Non-linear
mechanical 6
=
behaviour
6 (t, oO) -
where e (2, oo, 2,) is the elongation test (2.4)
of oriented
t >
e (t, oo, Q,
measured
219
polypropylene L
(2.5)
for t > t, in the creep and recovery
and e, (t, uo) is the creep elongation
which
would
be obtained
in the
creep test (2.2) (see Fig. la).
RESPONSE
TIME
FIG.
la.
Creep and recovery
(t)
programme.
KT,,.
LOADING PROGRAMM~
I
I
I
I
I
MME
, EXTENS,ON RESPONSE
0 FIG. lb.
Creep programme
For a linear viscoelastic
for superposition of two identical loads.
solid (2.1), (2.3) and (2.5) yield e, = J (t -
A third type of test employed (Fig.
lb)
(t)
11
tl) oo.
(2.6)
in the paper may be called a two step loading test
: lJ = 0,
7 (0;
We define the additional
(5 = (To, 0 < 7 < t,; creep response
e,’ = e’ (4 uo, 4) -
u = 2uo,
7 > t,.
(2.7)
as ec (t, uo),
t > t,,
where e’ is the elongation measured after the application of the second loading and e, has the previously defined meaning (Fig. lb). It is obvious that for a linear solid %’ == J (t -
tl) us.
(2.3) step of
(2.9)
I. M.
220
WORD
and
II:.
In Section j?, the measured creep, recovery material
considered
and f2.9) predicted
in the paper
T.
ON.\T
and additional
a.rc compared
with
creep responsc~ uf the
the responses (2.3),
(2.6)
by the linear theory.
A single monofilament of pol~prop~leue of dismetcr 3.7~ :, l(+ cnl was u~l in the csljcrime&s. This monofilament possessed a high dcgrce of molrcular orierttation and was fairly highly crystalline. Before making quantitatirc x~~casurements of creep and rrco\-try under various loading eonditions, a conditioning procedure was undertaken [SW hx~xn~l.w (1943)]. Tlic saniple was subjected to successive creep and rccovcry cycles, each cycle consisting of application of the load of 587 g for 2 hr 35 min (the maximum load and thr nlarinlutn period of loading for all the experiments reported here) follow-cd by a rcrorery 1:criod of 21 hr 25 min. The total cycle is then the convcnicnt period of onr da\-. This coI~ditioning procedure has two major ef’fccts on the crccl~ ant1 rccovcry tteha\+our. First, subsequent creep and recovery rcsponscs uudcr a given load arc then identical, i.e. the sample has lost its “ long-time memory ” and now only rcmcrubcrs loads applied in its immcdiatc past history. Secondly, aftor the conditioning proccdurc the dcformntion produced by any loading programme is almost complctcly recovcrablc provided that the recover>- period is at least eight times the period during which loads are applied. The response during the conditioning procedure is shown in Fig. 2. This diagram shows the creep and recovery bchaviour in ehronological order on a linear scale, with dotted gaps indicating portions where very slow rcrovery is taking place.
-. 2% EXTENSION
APPROXIMATE
FIG. 2.
Extensional
TIME
SCALE
(I IJNIT
creep and recovery of polyprolyvlcnc load of 587 $.
7
IO4 SECS)
initial cycling
under maximum
The defamation of the sample was mrasurrtl using a travclling mirroscope, the vernier scale of which could he read to ICY3 cm the sample length being 30.2 cm. The maximum &formation produced was about 0.7 cm, corresponding to about 2 per rent extension. After con~tioning the sample, an initial sure-ey was made of creep for several Icvt~IsoZ load. At least two sets of measurements WWF made al each lcvcl of load and the load leveis were chosen in a random order. These preliminary experiments wcrc followed by creep and rccoverv tests at various load intensities. The response to two step loading was also investigated, initial application of 281 g being followed by a further 281 g nftcr a spccificd tilne interval. The conditioning cycles and preliminary mcasurcmcnts wcrc not made in a tcnq)craturc controlled atmosphere, although measurements of the temperature were made during each run. A’ maximum variation of 4°F was observed between diffcrcnt runs, and the data showtd a small but significant dependence on temperature, the general pattern of hchaviour remaining unaffected. Subsequent measurements were therefore undcrtakcn in a room where the temperature was controlled to 73°F j, l”F, and only results obtained at temperatures falling within this range are used In drawing up the diagrams which analyse the non-linear behariour in detail (Fig. 4 d seq. below).
Non-linear rnechartical beheviouz of oriented ~oiypropy~ene
+,A“’
w+----1% EXTENSION
~&_-_
------~-~_-I@
TiME
---__a--_.,_--I
IO”
(SECS)
FIG. 4. Creep eorrtpliancecurves for different kvels of toad o.
w
Creep eompliances obtained from the experimtnts ~o~~d~~~tedunder five di&rcnt load levels are shown in Fig. 4 on a logarithmic time scale. It is see11from this figure that, except for short. times (t N 10~ set) and for only low intensities of loading (oO =: 67.6 and 12943 g), the creep complinnces do not coincide. This ohser\-ation is in contradiction
with the predictiort (2.3) of the lirtcar theory and it indica.tes
that the material considered is non-linear. The non-linear nature of the material may be mu& strikinglp risible by plotting e, (1, ao)/uoagniust “O for various fixed valncs oft (Fig. 5). According to the linear theory, each srrvh curve shoultl be a horizontal
i
cl
9300
;nx 0v
3000 1000 300 i 40 15 00
TIME IN SECS i
/’
i
‘1
a”
Non-linear
mechanical
behaviour
of oriented
polypropylene
223
LOAD LEVELS
~__
I
I
I
102 TIME
IO" (SECS)
FIG. 6. Comparison of recovery curves for different levels of loads (time of loading 9.3 x lo3 set).
5r
x A
TIME IN SECS
i
+ q 0
1000 300 100 40 I5
k 9
-
8 I
0. 10
I 100
I 200
I 300
I 400 LOAD
I 500 (G MS)co
I 600
FIG. ‘7. Recovery compliance e, (t - t,)/u,, against load q, (time of loading 9.3 x IO3 set) for various times (set).
I
I. 111. WARM
22-t creep
and recovery
and E. ‘J?.
ONAT
curves in Fig. 3 should coincide for a given intensity
of load.
A4s the figure shows, this is not the case except, for the low load int,ensities. It is interesting to observe that. the short-time recovery or ‘ instal~tat~e~)~~srecovery ' as it is sometimes termed is larger than the init.ial creep response. This effect increases with increasing applied load, as illustrated in Fig. 11 where the difference
between
the creep and reco\-cry’ cvmpliances
for
15 SW is plotted
against
the
load aO. Recovery respect&elf.
fompiinnces
and
~745~
IWSIIS
5*
curves are given in Figs. G and 7
The prediction of the linear theory co~~~erl~i~~grecta\-cry can be contrasted with the obserred behaviour in a manner similar to that employed in the above discussion of creep data. The effect of the time of loading
i, on the IWO\-cry bchaviour
has also been
studied and the results of these studies are given in Figs. x and 9.
i .
i
102
l-ME
(SECS)
The additional creep response is plotted For purposes of comparison the corresponding shown in this figure. The figure provides yet since cc’ (t - tl) does not coincide with e, (t)
103
.___._~~_.__-_
I
104
as a function of t - t, in Fig. 10. creep and recovery curves are also another indication of non-linearity as the linear theory predicts.
Non-linear
5.
mechanical
behaviour
of oriented
225
polypropylene
MATHEMATICAL DESCRIPTION OF OBSERVED BEEIAVIOWR
The results obtained
for the extensional
pylene
are clearly
at variance
elastic
behaviour
discussed
creep and recovery
of oriented polypro-
with the three simple implications of linear viscoin Section 2. The material considered is non-linear
and the relation (2.1) is not adequate for the mathematical observed memory dependent non-linear behaviour.
description
of the
0.3
Id TIME
lk.
I
I
I
IO'
IO
04
(SECS)
Comparison of creep and recovery curves for load of 281 g with additional creep due to addition of 281 g after 3000 see and IO00 sec.
10.
3000 sees
In the development behaviour
we adopt
of the specimen
q
of an adequate
the following
1000 sees fI
description of the observed non-linear We assume that the elongation
point of view.
at time t depends on all the previous values of the rate of loading In other words the elongation is assumed
to which the specimen has been subjected. to be a function
of the history
of rate of loading.
(5.1) It is well-knowl~ represented
that if the functional
by the Boltzmann
F is l~r~~~rand continuous
integral
(2.1) which
constitutes
then it can be the basis of the
theory of linear viscoelasticity. FrCchet has shown [see VOLTERRA and PiaBs (1936); also NAKADA (1960), GREEN and RIVLIN (1957)] that, where F is continuous and aon-linear, the functional F can be represented manner
:
to any desired
degree of accuracy
in the following
t
e (t) =
t
+ --m
s
J, (t -
TV) y
&I 1
t
ss . . .
-co
JN (t -
rl, . . . , t -
lb (71) TN) T. 1
‘a (T.v) & 1 . . . dTN . . dw
(5.2)
I. M. WARD and E. T. ONAT
226
where it is assumed, without loss of generality, symmetric functions of their arguments. An
interpretation
given loading The integrand individual elongation.
of this represetltation
that the kernels J,, . . . , JN are
can be obtained
by
considering
a
programme (z (7) as a superposition of finitesimal loading steps. of the first term in (5.2) can then be interpreted as representing the
and independent contribution of the loading step da (TV) to the final The integrand of the second term, on the other hand, can be thought
as representing
the joit~l contribution
to the final elongation, According programme
of the loading
to (5.2)
the time
dependent
of the creep test (2.2) is given ec (4 4
=
steps
du (TV) and
drr (TJ
etc. elongation
produced
by
the loading
by the expression
J, (0 m. + J, (4 t) go2+ . . . + JN (4 . . . , t) o.N.
W-9
Let us now recall that each curve in Fig. 5 describes the experimentally observed dependence of e, (t, u~‘)/G~on CT~for a fixed t. Moreover, let us observe that each curve in Fig. 5 can be represented, with reasonable accuracy, by an equation of the type ec/uo =- c1 + c2 uo2
(5.4)
where cI and cs are constants. This observation suggests; together with (5.3), that in a first attempt
at describ-
ing the present test results, only the first and third terms may be retained expression
(5.2).
e (t) =
Accordingly
J, (t -
we confine our attention
T& $
to the following
in the
functional
d~~ 1
s
The creep elongation
predicted
by (5.5) for the loading
programme
defined
by
(2.2) is
e, (t, a,,) = For the recovery integration,
3, (t) o. + J, (t, t, t) oo3.
test defined by the loading programme
(5.6)
(2.4), (5.6) yields by simple
and for t > t,,
e 0, go, tll =
J, (Qgo - JI (t - G) m. + [J, (6 6 t) - 3J, (t, t, t - 4)
+ 3J, (t, t -
t,, t -
We obtain the recovery response tracting (5.7) from (5.6) :
F,. = J, (t -
tl) u. -+ J, (t -
5,) -. J, (t (defined
t,, t -
+ 3 [J, (t, t, t If we now let S denote
in Fig. la),
t,, t -
t,)] a,$.
predicted
(5.7)
by (5.5), by sub-
tl) uo3
tl) - J, (t, t -
the time difference
help of (5.4) in the following
t,, t - t,, t -
t -
t,, t -
t,)] LQ,~.
(5.3)
t,, (5.8) can be written with the
form :
e, (S, o‘s, tl) = e, (S, ran) + 3 [J, (S + t,, S + t,, S) -
J, (S --t t,, S, S,)] uo3.
(5.9)
Non-linear mechanical behaviour of oriented polypropylene
227
We now want to show that the experimental recovery behaviour can be adequately described by (5.9). For this purpose we consider the difference A = e, -
ec = 3 [J,
(S + 1,, S + ti, S) -
and enquire first whether the experimentally for fixed S and t, obeys the cubic law (5.10).
2
APPLIED
J, (S + t,, S, S) ] oas,
(5.10)
observed dependence of A on a,, In Fig. 11 experimental values of
LOAD
(GM)
5 ilI
FIG. 11.
Additional
elastic recovery, i.e. difference between 15 see creep compliance as a function of applied load.
and recovery
A/U@ are plotted against o. for the, case of S = 15 see and t, = 9.3 x lo3 sec. Fig. 11 shows that, to a reasonable degree of approximation, the resulting experimental curve of A/u, against CQ,is a parabola as predicted by (5.10). Similar curves can be constructed from Fig. 13 for other values of S with the same afirmative results, It is clear that A depends on both S and t, as well as on a,,. Experimental information concerning this dependence is available in Figs. 3, 8 and 9. It will be noted that the time dependence of A is related to two functions of time. In fact, the comparison of the creep and recovery tests provide information for the experimental determination of the expression
J, (S + t,, S + t,, 8) - J, (8 + t,, 8, 8). The tests in Figs. 8 and 9 contain information on the dependence of the above expression on t,. For instance they show that this expression decreases with decreasing t,. We next consider the two-step loading programme defined by (2.7) and determine the elongation predicted by (5.5) for t > t, : e’ (4 00, G) =
J, (t) “0 + J, (t - 2,) co + [J, (t, t, t) + 3J, (t, t, t - t,) t%(t,t-tt,,t-t,)+J,(t-tt,,t-tl,t-tt,)]q,3.
(5.11)
The additional creep response as defined in Fig. lb is therefore given by eC’ 6% gal G) = ec 6% go) + 3 [J, where, as before, S denotes t -
(8 + t,, S + 4,s) + J, (S + t,, 8, NJ (ro3, (5.12) t,.
I. nr.
228 Comparison
and E. T. %acr
WAnD
of (5.12) with (5.9) shows that e,’ (S, o,,, tl) -
e, (S, oO, t) =
The test results shown in Fig. 10 indicate,
6J3
(S
+
t,,
S,
5”)
uo3.
in view of (5.13), that
(5.13) J,
(S+tl,
S,
S)
>
0
which is not surprising. We have shown that the present test results can be described,
with reasonable
accuracy, by the functional (5.5). We have also established, with the help of (5.6) (5.9) and (5.13), that the creep, creep and recovery and two-step loading tests provide, J,
(t
J3
(71,
in principle, +
t,,
t, t).
full
However,
information a ‘ complete
on J, (t), J, (t, ’ experimental
t, t),
J,
(t
+
t,,
determination
t +
will require the performance of other types of tests. 72, 73) It will be noted that in principle it might also be possible to obtain
experimental
data by including
we might have included
To test the advantages whether
other terms in the expression
the second
of alternative
t,,
t)
and
of the kernel
(5.2).
a fit to the
In particular
term
representations,
even terms in (5.2) should be included
be desirable to make more comprehensive sive as well as extensional deformation.
and in particular
to decide
as well as the odd terms, it would
experimentations
to include
comprcs-
Before closing this section, we want to enquire whether a simpler representation of non-linear behaviour suggested by LEBDERMAN (1943) is adequate for the present
material.
Leaderman’s
representation
has the form
where I< is the elasticity modulus of the material and K and.fare empirical functions of time and stress, respect.ively. It will be noticed that (5.14)constitutes a generalization of the Boltzmann’s superposition principle (2.1). For the creep test performed
under constant
stress oO (5.14)
yields
(5.15) where it is assumed
that *f(9) = 0.
For the recovery
e (t)= I< @)f(qJ - K (t- &)f(uJ, and hence,
test w-e obtain
from
(5.14) (5.16)
t > t,,
in view of (5.15),
(5.17)
er(J‘, go,&) = 2 + K (W.f(qJ, t > h. It is seen from
(5.15)and (5.17)that, according ep (S, uo, tl) -
As Fig. 3 and earlier discussions
indicate
to Leaderman’s
representation,
ec (S, uo) = 9.
(5.18)is clearly
(5.15) at variance
with ex-
Non-linear
mechanical
behaviour
of oriented
~OIy~ror~ylene
‘JZD
perimental evidence. It would seem, therefore, that Leadermnn’s representation is inadequate for the present mater&l. ACKNOWLEDGMENT The authors are indebted the course of this work.
to Professor
H. Kolsky
for his advice and encouragement
during
REFEREXCES FERRY, J. D. GREEN, A. K. and RIVLI~, R. S. Gnoss, B. G., WnrIX, H. J. and ;‘:YRING, H. KOLSKE’, H.
1961
V~~eoelast~c P,ropertiesof Po~~9~ers (Wiley, New York).
1957
AT&. Rat. Mech. 1, 1.
1953
HALSEY
1954 1960 1923 1943
Text. Ztes. 15, 295. The Mwhanical Testirzg of ZZigh Poly9ners. Progress in Non-Destructive Testing, Vol. 2. (Heywood, London). International Symposiu9n 092 Stress Wave Propagution Materials (Interscience, New York). Elastic and Creep Praperties of Filamentous and Other ZQh Polymers (The Textile Foundation, Washington, H.C.). Large Longitudinal Retarded Elastic Defo~~~at~on of Z&bberlike Natwal Polymers. Presented at the Thirty Second Annual Meeting of the American Society of Rheology, Madison. Proc. Second Int. Cmg. Rheol., p. 156. J. Phys. Sac. Japan 15, 2280. J. Text. Inst. 14 T, 390. Rayon Text. Mon. 24, 207, 339, 405.
1936
Theorie Generale des Ponctionnelles,
1945 1959 1960
LEADEI~XIAN,H.
1943 1961
MARVIN, R. S. NAKADA, 0. PEIRCE, F. T. PRESS, J. J. and MARK, H. VOLTERRA, V. and l’fR&S, J.
p. 61 (Gauthier-Villars).
NON-LINEAR
MECHANICAL
ORIENTED By
I. 3%. Brown
BEHAVIOUR
OF
POLYPROPYLENE* WARD-~
University,
and E. T. Providence,
ONAT R.I.
(Receiued Sfh March, 1963)
THIS paper is concerned with the study of isothermal extensional deformations of an oriented polypropylene monofilament under time-dependent loading. The monofilament has been subjected to various loading programmes, each containing a number of loading steps. It is found that the monofilament exhibits non-linear memory dependent behaviour. The question of mathematical representation of the observed non-linear behaviour is considered. It is assumed that the elongaCon at a given time is a non-linear functional of the stress-rate history to which the filament has been subjected prior to this instance. It is then shown that the experimental results can be represented, with reasonable accuracy, by approximating this functional by the sum of a linear It is seen that the loading programmes employed in the and third order hereditary functional. study provide substantial information for the construction of the kernels defming the two functionals.
1.
INTRODUCTION
IN GENE~~AL, amorphous polymers in the temperature range of the glass-rubber transit,ion display linear viscoelastic behaviour at low strain levels (- l per cent) (FERRY 1961). This is also true for crystalline polymers within a similar but usually lower range of strain levels [e.g. polythene (KOLSKY 1960)]. For such materials there are many comprehensive studies of viscoelastic behaviour. A good example of this type of investigation is the work on pofyisobutylene reported by MARVIN (1954). In materials of high molecular orientation such as fibres, on the other hand, it is well known that the viscoelastic behaviour can be non-linear. In view of the complexity of the situat.ion a variety of different types of measurements have been made with such materials and the results have, in general, been represented either by empirical power laws relating stress and strain with time (PEIRCE 1923; PRESS and MARK 1943) or by postulating specific non-linear behaviour in terms of mechanical models with non-linear springs and ‘ activated dashpots ’ (HALSEY, WHITE and EYKING 1945). An alternative approach, proposed by Leaderman, was to attempt to derive a modified Boltzmann superposition principle (LEADERMAN 1943,
1961).
*The work reported in this paper was supported in part by Material Hewarch Program, Advanced Research Projects Agency, Department of Defense. ton secondmentto the Division of Applied Mathematics,Brown University from I.C.I. Ltd., Fibres Division, Harrogate, England. 217
I. M. WARD and E. ‘I’. ONAT
218
The
present
deformations loading.
paper
is concerned
of an oriented
The monofilament
with
the
polypropylene
study
of isothermal
monofilament
has been subjected
under
to various
extensional
time-dependent
loading
programmes;
each containing a number of loading steps, and the resulting time dependent elongations have been measured. The discussion of experimental results given in Section 4 shows that the monofilament exhibits non-linear memory-dependent mechanical behaviour. The question of a rational mathematical representation of the observed non-linear
behaviour
is considered
in Section
5.
It is assumed in this section that
the elongation at a given time is a non-linear functional of the stress-rate history to which the filament has been subjected prior to this instance. It is then shown that
the experimental
approximating functional. substantial
results
this functional
can be represented
with
reasonable
accuracy
by
by the sum of a linear and a third order hereditary
It is seen that the loading programmes information for the construction of
employed in the study provide the kernels defining the two
functions. 2.
In this section and the response
LINEAR
VISCOELASTIC
the loading
programmes
of a linear
viscoelastic
BEI~AVIOUH
employed solid
in the study
to these loading
discussed. As will be seen later, this discussion is of importance the non-linear nature of the material considered. There elastic
exist
several
behaviour
for
mathematical
representations
in bringing of linear
is out
visco-
example,
GROSS (1953) and KOLSKY (1959)]. We here with the integral representation appropriate to the uniaxial
shall be concerned stressing
equivalent
[see,
are described programmes
considered
in this paper :
e(t)
= --m
where e (t) is the elongation is the time dependent
uniaxial
I
J(t
-
T)?&
(per unit length)
of the specimen
at time t and (J (T) This represen-
stress, and J is the creep compliance.
tation can be considered to arise as a consequence of the Boltzmann superposition principle. It may also be noted that according to (2.1) the strain is a linear, continuous
hereditary
functional
Let e, (t, u,,) denote programme
of the stress history.
the strain response
U(T)==O, For a linear viscoelastic
(T(7) = ~7~= const.,
7<0; material
in a creep test defined
it follows
by the loading
7 > 0.
(2.2)
from (2.1) and (2.2) that
ec(t, ao)= J (1)uo.
(2.3)
We note from (2.3) that for a linear material the creep compliance e,/a, is independent of go and is given by the function J (t). A creep and rerooery test is characterized by the loading programme (Fig. la) C = 0, The following
7 < 0;
expression
(5=oo,
is denoted
o
u=o, response
T
(2.4)
Non-linear
mechanical 6
=
behaviour
6 (t, oO) -
where e (2, oo, 2,) is the elongation test (2.4)
of oriented
t >
e (t, oo, Q,
measured
219
polypropylene L
(2.5)
for t > t, in the creep and recovery
and e, (t, uo) is the creep elongation
which
would
be obtained
in the
creep test (2.2) (see Fig. la).
RESPONSE
TIME
FIG.
la.
Creep and recovery
(t)
programme.
KT,,.
LOADING PROGRAMM~
I
I
I
I
I
MME
, EXTENS,ON RESPONSE
0 FIG. lb.
Creep programme
For a linear viscoelastic
for superposition of two identical loads.
solid (2.1), (2.3) and (2.5) yield e, = J (t -
A third type of test employed (Fig.
lb)
(t)
11
tl) oo.
(2.6)
in the paper may be called a two step loading test
: lJ = 0,
7 (0;
We define the additional
(5 = (To, 0 < 7 < t,; creep response
e,’ = e’ (4 uo, 4) -
u = 2uo,
7 > t,.
(2.7)
as ec (t, uo),
t > t,,
where e’ is the elongation measured after the application of the second loading and e, has the previously defined meaning (Fig. lb). It is obvious that for a linear solid %’ == J (t -
tl) us.
(2.3) step of
(2.9)
I. M.
220
WORD
and
II:.
In Section j?, the measured creep, recovery material
considered
and f2.9) predicted
in the paper
T.
ON.\T
and additional
a.rc compared
with
creep responsc~ uf the
the responses (2.3),
(2.6)
by the linear theory.
A single monofilament of pol~prop~leue of dismetcr 3.7~ :, l(+ cnl was u~l in the csljcrime&s. This monofilament possessed a high dcgrce of molrcular orierttation and was fairly highly crystalline. Before making quantitatirc x~~casurements of creep and rrco\-try under various loading eonditions, a conditioning procedure was undertaken [SW hx~xn~l.w (1943)]. Tlic saniple was subjected to successive creep and rccovcry cycles, each cycle consisting of application of the load of 587 g for 2 hr 35 min (the maximum load and thr nlarinlutn period of loading for all the experiments reported here) follow-cd by a rcrorery 1:criod of 21 hr 25 min. The total cycle is then the convcnicnt period of onr da\-. This coI~ditioning procedure has two major ef’fccts on the crccl~ ant1 rccovcry tteha\+our. First, subsequent creep and recovery rcsponscs uudcr a given load arc then identical, i.e. the sample has lost its “ long-time memory ” and now only rcmcrubcrs loads applied in its immcdiatc past history. Secondly, aftor the conditioning proccdurc the dcformntion produced by any loading programme is almost complctcly recovcrablc provided that the recover>- period is at least eight times the period during which loads are applied. The response during the conditioning procedure is shown in Fig. 2. This diagram shows the creep and recovery bchaviour in ehronological order on a linear scale, with dotted gaps indicating portions where very slow rcrovery is taking place.
-. 2% EXTENSION
APPROXIMATE
FIG. 2.
Extensional
TIME
SCALE
(I IJNIT
creep and recovery of polyprolyvlcnc load of 587 $.
7
IO4 SECS)
initial cycling
under maximum
The defamation of the sample was mrasurrtl using a travclling mirroscope, the vernier scale of which could he read to ICY3 cm the sample length being 30.2 cm. The maximum &formation produced was about 0.7 cm, corresponding to about 2 per rent extension. After con~tioning the sample, an initial sure-ey was made of creep for several Icvt~IsoZ load. At least two sets of measurements WWF made al each lcvcl of load and the load leveis were chosen in a random order. These preliminary experiments wcrc followed by creep and rccoverv tests at various load intensities. The response to two step loading was also investigated, initial application of 281 g being followed by a further 281 g nftcr a spccificd tilne interval. The conditioning cycles and preliminary mcasurcmcnts wcrc not made in a tcnq)craturc controlled atmosphere, although measurements of the temperature were made during each run. A’ maximum variation of 4°F was observed between diffcrcnt runs, and the data showtd a small but significant dependence on temperature, the general pattern of hchaviour remaining unaffected. Subsequent measurements were therefore undcrtakcn in a room where the temperature was controlled to 73°F j, l”F, and only results obtained at temperatures falling within this range are used In drawing up the diagrams which analyse the non-linear behariour in detail (Fig. 4 d seq. below).
Non-linear rnechartical beheviouz of oriented ~oiypropy~ene
+,A“’
w+----1% EXTENSION
~&_-_
------~-~_-I@
TiME
---__a--_.,_--I
IO”
(SECS)
FIG. 4. Creep eorrtpliancecurves for different kvels of toad o.
w
Creep eompliances obtained from the experimtnts ~o~~d~~~tedunder five di&rcnt load levels are shown in Fig. 4 on a logarithmic time scale. It is see11from this figure that, except for short. times (t N 10~ set) and for only low intensities of loading (oO =: 67.6 and 12943 g), the creep complinnces do not coincide. This ohser\-ation is in contradiction
with the predictiort (2.3) of the lirtcar theory and it indica.tes
that the material considered is non-linear. The non-linear nature of the material may be mu& strikinglp risible by plotting e, (1, ao)/uoagniust “O for various fixed valncs oft (Fig. 5). According to the linear theory, each srrvh curve shoultl be a horizontal
i
cl
9300
;nx 0v
3000 1000 300 i 40 15 00
TIME IN SECS i
/’
i
‘1
a”
Non-linear
mechanical
behaviour
of oriented
polypropylene
223
LOAD LEVELS
~__
I
I
I
102 TIME
IO" (SECS)
FIG. 6. Comparison of recovery curves for different levels of loads (time of loading 9.3 x lo3 set).
5r
x A
TIME IN SECS
i
+ q 0
1000 300 100 40 I5
k 9
-
8 I
0. 10
I 100
I 200
I 300
I 400 LOAD
I 500 (G MS)co
I 600
FIG. ‘7. Recovery compliance e, (t - t,)/u,, against load q, (time of loading 9.3 x IO3 set) for various times (set).
I
I. 111. WARM
22-t creep
and recovery
and E. ‘J?.
ONAT
curves in Fig. 3 should coincide for a given intensity
of load.
A4s the figure shows, this is not the case except, for the low load int,ensities. It is interesting to observe that. the short-time recovery or ‘ instal~tat~e~)~~srecovery ' as it is sometimes termed is larger than the init.ial creep response. This effect increases with increasing applied load, as illustrated in Fig. 11 where the difference
between
the creep and reco\-cry’ cvmpliances
for
15 SW is plotted
against
the
load aO. Recovery respect&elf.
fompiinnces
and
~745~
IWSIIS
5*
curves are given in Figs. G and 7
The prediction of the linear theory co~~~erl~i~~grecta\-cry can be contrasted with the obserred behaviour in a manner similar to that employed in the above discussion of creep data. The effect of the time of loading
i, on the IWO\-cry bchaviour
has also been
studied and the results of these studies are given in Figs. x and 9.
i .
i
102
l-ME
(SECS)
The additional creep response is plotted For purposes of comparison the corresponding shown in this figure. The figure provides yet since cc’ (t - tl) does not coincide with e, (t)
103
.___._~~_.__-_
I
104
as a function of t - t, in Fig. 10. creep and recovery curves are also another indication of non-linearity as the linear theory predicts.
Non-linear
5.
mechanical
behaviour
of oriented
225
polypropylene
MATHEMATICAL DESCRIPTION OF OBSERVED BEEIAVIOWR
The results obtained
for the extensional
pylene
are clearly
at variance
elastic
behaviour
discussed
creep and recovery
of oriented polypro-
with the three simple implications of linear viscoin Section 2. The material considered is non-linear
and the relation (2.1) is not adequate for the mathematical observed memory dependent non-linear behaviour.
description
of the
0.3
Id TIME
lk.
I
I
I
IO'
IO
04
(SECS)
Comparison of creep and recovery curves for load of 281 g with additional creep due to addition of 281 g after 3000 see and IO00 sec.
10.
3000 sees
In the development behaviour
we adopt
of the specimen
q
of an adequate
the following
1000 sees fI
description of the observed non-linear We assume that the elongation
point of view.
at time t depends on all the previous values of the rate of loading In other words the elongation is assumed
to which the specimen has been subjected. to be a function
of the history
of rate of loading.
(5.1) It is well-knowl~ represented
that if the functional
by the Boltzmann
F is l~r~~~rand continuous
integral
(2.1) which
constitutes
then it can be the basis of the
theory of linear viscoelasticity. FrCchet has shown [see VOLTERRA and PiaBs (1936); also NAKADA (1960), GREEN and RIVLIN (1957)] that, where F is continuous and aon-linear, the functional F can be represented manner
:
to any desired
degree of accuracy
in the following
t
e (t) =
t
+ --m
s
J, (t -
TV) y
&I 1
t
ss . . .
-co
JN (t -
rl, . . . , t -
lb (71) TN) T. 1
‘a (T.v) & 1 . . . dTN . . dw
(5.2)
I. M. WARD and E. T. ONAT
226
where it is assumed, without loss of generality, symmetric functions of their arguments. An
interpretation
given loading The integrand individual elongation.
of this represetltation
that the kernels J,, . . . , JN are
can be obtained
by
considering
a
programme (z (7) as a superposition of finitesimal loading steps. of the first term in (5.2) can then be interpreted as representing the
and independent contribution of the loading step da (TV) to the final The integrand of the second term, on the other hand, can be thought
as representing
the joit~l contribution
to the final elongation, According programme
of the loading
to (5.2)
the time
dependent
of the creep test (2.2) is given ec (4 4
=
steps
du (TV) and
drr (TJ
etc. elongation
produced
by
the loading
by the expression
J, (0 m. + J, (4 t) go2+ . . . + JN (4 . . . , t) o.N.
W-9
Let us now recall that each curve in Fig. 5 describes the experimentally observed dependence of e, (t, u~‘)/G~on CT~for a fixed t. Moreover, let us observe that each curve in Fig. 5 can be represented, with reasonable accuracy, by an equation of the type ec/uo =- c1 + c2 uo2
(5.4)
where cI and cs are constants. This observation suggests; together with (5.3), that in a first attempt
at describ-
ing the present test results, only the first and third terms may be retained expression
(5.2).
e (t) =
Accordingly
J, (t -
we confine our attention
T& $
to the following
in the
functional
d~~ 1
s
The creep elongation
predicted
by (5.5) for the loading
programme
defined
by
(2.2) is
e, (t, a,,) = For the recovery integration,
3, (t) o. + J, (t, t, t) oo3.
test defined by the loading programme
(5.6)
(2.4), (5.6) yields by simple
and for t > t,,
e 0, go, tll =
J, (Qgo - JI (t - G) m. + [J, (6 6 t) - 3J, (t, t, t - 4)
+ 3J, (t, t -
t,, t -
We obtain the recovery response tracting (5.7) from (5.6) :
F,. = J, (t -
tl) u. -+ J, (t -
5,) -. J, (t (defined
t,, t -
+ 3 [J, (t, t, t If we now let S denote
in Fig. la),
t,, t -
t,)] a,$.
predicted
(5.7)
by (5.5), by sub-
tl) uo3
tl) - J, (t, t -
the time difference
help of (5.4) in the following
t,, t - t,, t -
t -
t,, t -
t,)] LQ,~.
(5.3)
t,, (5.8) can be written with the
form :
e, (S, o‘s, tl) = e, (S, ran) + 3 [J, (S + t,, S + t,, S) -
J, (S --t t,, S, S,)] uo3.
(5.9)
Non-linear mechanical behaviour of oriented polypropylene
227
We now want to show that the experimental recovery behaviour can be adequately described by (5.9). For this purpose we consider the difference A = e, -
ec = 3 [J,
(S + 1,, S + ti, S) -
and enquire first whether the experimentally for fixed S and t, obeys the cubic law (5.10).
2
APPLIED
J, (S + t,, S, S) ] oas,
(5.10)
observed dependence of A on a,, In Fig. 11 experimental values of
LOAD
(GM)
5 ilI
FIG. 11.
Additional
elastic recovery, i.e. difference between 15 see creep compliance as a function of applied load.
and recovery
A/U@ are plotted against o. for the, case of S = 15 see and t, = 9.3 x lo3 sec. Fig. 11 shows that, to a reasonable degree of approximation, the resulting experimental curve of A/u, against CQ,is a parabola as predicted by (5.10). Similar curves can be constructed from Fig. 13 for other values of S with the same afirmative results, It is clear that A depends on both S and t, as well as on a,,. Experimental information concerning this dependence is available in Figs. 3, 8 and 9. It will be noted that the time dependence of A is related to two functions of time. In fact, the comparison of the creep and recovery tests provide information for the experimental determination of the expression
J, (S + t,, S + t,, 8) - J, (8 + t,, 8, 8). The tests in Figs. 8 and 9 contain information on the dependence of the above expression on t,. For instance they show that this expression decreases with decreasing t,. We next consider the two-step loading programme defined by (2.7) and determine the elongation predicted by (5.5) for t > t, : e’ (4 00, G) =
J, (t) “0 + J, (t - 2,) co + [J, (t, t, t) + 3J, (t, t, t - t,) t%(t,t-tt,,t-t,)+J,(t-tt,,t-tl,t-tt,)]q,3.
(5.11)
The additional creep response as defined in Fig. lb is therefore given by eC’ 6% gal G) = ec 6% go) + 3 [J, where, as before, S denotes t -
(8 + t,, S + 4,s) + J, (S + t,, 8, NJ (ro3, (5.12) t,.
I. nr.
228 Comparison
and E. T. %acr
WAnD
of (5.12) with (5.9) shows that e,’ (S, o,,, tl) -
e, (S, oO, t) =
The test results shown in Fig. 10 indicate,
6J3
(S
+
t,,
S,
5”)
uo3.
in view of (5.13), that
(5.13) J,
(S+tl,
S,
S)
>
0
which is not surprising. We have shown that the present test results can be described,
with reasonable
accuracy, by the functional (5.5). We have also established, with the help of (5.6) (5.9) and (5.13), that the creep, creep and recovery and two-step loading tests provide, J,
(t
J3
(71,
in principle, +
t,,
t, t).
full
However,
information a ‘ complete
on J, (t), J, (t, ’ experimental
t, t),
J,
(t
+
t,,
determination
t +
will require the performance of other types of tests. 72, 73) It will be noted that in principle it might also be possible to obtain
experimental
data by including
we might have included
To test the advantages whether
other terms in the expression
the second
of alternative
t,,
t)
and
of the kernel
(5.2).
a fit to the
In particular
term
representations,
even terms in (5.2) should be included
be desirable to make more comprehensive sive as well as extensional deformation.
and in particular
to decide
as well as the odd terms, it would
experimentations
to include
comprcs-
Before closing this section, we want to enquire whether a simpler representation of non-linear behaviour suggested by LEBDERMAN (1943) is adequate for the present
material.
Leaderman’s
representation
has the form
where I< is the elasticity modulus of the material and K and.fare empirical functions of time and stress, respect.ively. It will be noticed that (5.14)constitutes a generalization of the Boltzmann’s superposition principle (2.1). For the creep test performed
under constant
stress oO (5.14)
yields
(5.15) where it is assumed
that *f(9) = 0.
For the recovery
e (t)= I< @)f(qJ - K (t- &)f(uJ, and hence,
test w-e obtain
from
(5.14) (5.16)
t > t,,
in view of (5.15),
(5.17)
er(J‘, go,&) = 2 + K (W.f(qJ, t > h. It is seen from
(5.15)and (5.17)that, according ep (S, uo, tl) -
As Fig. 3 and earlier discussions
indicate
to Leaderman’s
representation,
ec (S, uo) = 9.
(5.18)is clearly
(5.15) at variance
with ex-
Non-linear
mechanical
behaviour
of oriented
~OIy~ror~ylene
‘JZD
perimental evidence. It would seem, therefore, that Leadermnn’s representation is inadequate for the present mater&l. ACKNOWLEDGMENT The authors are indebted the course of this work.
to Professor
H. Kolsky
for his advice and encouragement
during
REFEREXCES FERRY, J. D. GREEN, A. K. and RIVLI~, R. S. Gnoss, B. G., WnrIX, H. J. and ;‘:YRING, H. KOLSKE’, H.
1961
V~~eoelast~c P,ropertiesof Po~~9~ers (Wiley, New York).
1957
AT&. Rat. Mech. 1, 1.
1953
HALSEY
1954 1960 1923 1943
Text. Ztes. 15, 295. The Mwhanical Testirzg of ZZigh Poly9ners. Progress in Non-Destructive Testing, Vol. 2. (Heywood, London). International Symposiu9n 092 Stress Wave Propagution Materials (Interscience, New York). Elastic and Creep Praperties of Filamentous and Other ZQh Polymers (The Textile Foundation, Washington, H.C.). Large Longitudinal Retarded Elastic Defo~~~at~on of Z&bberlike Natwal Polymers. Presented at the Thirty Second Annual Meeting of the American Society of Rheology, Madison. Proc. Second Int. Cmg. Rheol., p. 156. J. Phys. Sac. Japan 15, 2280. J. Text. Inst. 14 T, 390. Rayon Text. Mon. 24, 207, 339, 405.
1936
Theorie Generale des Ponctionnelles,
1945 1959 1960
LEADEI~XIAN,H.
1943 1961
MARVIN, R. S. NAKADA, 0. PEIRCE, F. T. PRESS, J. J. and MARK, H. VOLTERRA, V. and l’fR&S, J.
p. 61 (Gauthier-Villars).