Abstract
The mechanical behavior of different types of polycrystalline materials shows many common features in the ductile inelastic flow regime. It is typically controlled by dislocations motion, which involves the competitive action of hardening and recovery processes that induces a strong dependency upon mechanical history. The object of this paper is to show how a constitutive model, named SUVIC, can be used to describe and predict in a unified manner the inelastic response of various types of materials. For that purpose, the authors use laboratory test results obtained on alkali halides (NaCl) and on metallic alloys (Inconel 738LC and A508 steel) at different homologous temperatures.
Issue Section:
Technical Papers
Keywords:
viscoplasticity,
work hardening,
dislocation motion,
recovery-creep,
plastic flow,
internal stresses,
stress relaxation,
alkali metal halides,
alloy steel,
chromium alloys,
nickel alloys,
sodium compounds,
superalloys,
Constitutive Equations,
Relaxation,
Viscoplasticity,
Plasticity,
Creep,
Metal Alloys,
Alkali Halides
1.
Frost, H. J., and Ashby, M. F., 1982, Deformation mechanism
maps-The plasticity and creep of metals and ceramics, Pergamon
Press.
2.
Poirier, J. P., 1985, Creep of crystals-High temperature
deformation processes in metals, ceramics and minerals, Cambridge
University Press, Cambridge.
3.
Aubertin
,
M.
,
Gill
, D.
E.
, and
Ladanyi
,
B.
,
1991
, “A unified viscoplastic model for the
inelastic flow of alkali halides
,” Mech.
Mater.
, 11
, pp.
63
–82
.4.
Miller, A. K., (ed.) 1987, Unified Constitutive Equations
for Creep and Plasticity, Elsevier Applied Science,
Amsterdam.
5.
Krauz A. S., and Krausz, K., (eds.) 1996, Unified
Constitutive Laws of Plastic Deformation, Academic Press, San
Diego.
6.
Aubertin, M., 1996, “On the physical origin and modeling of kinetic
and isotropic hardening of salt,” Proc. 3rd Conf. on the Mechanical
Behavior of Salt, Paris, 1993, Trans. Tech. Pub.,
Clausthal-Zellerfeld, pp. 3–17.
7.
Aubertin
,
M.
,
Julien
, M.
R.
,
Servant
,
S.
, and
Gill
, D.
E.
, 1999
,
“A rate dependent model for the ductile behavior of salt
rocks
,” Can. Geotech. J.
,
36
, pp.
660
–674
.8.
Aubertin
,
M.
,
Yahya
, O. M.
L.
, and
Julien
, M.
R.
, 1999
,
“Modeling mixed hardening of alkali halides with a modified
viscoplastic model
,” Int. J. Plast.
,
15
, pp.
1067
–1088
.9.
Yahya
, O. M.
L.
,
Aubertin
,
M.
, and
Julien
,
M.
,
2000
, “A unified representation of plasticity,
creep and relaxation behavior of rocksalt
,” Int. J.
Rock Mech. Min. Sci.
, 37
, pp.
787
–800
.10.
Julien, M. R., 1999, “Une mode´lisation constitutive et nume´rique
du comportement me´canique du sel gemme,” Ph.D. thesis, Ecole Polytechnique de
Montre´al.
11.
Aubertin
,
M.
,
Gill
, D.
E.
, and
Ladanyi
,
B.
,
1991b
, “An internal variable model for the creep
of rocksalt
,” Rock Mechanics and Rock
Engineering
, 24
, pp.
81
–97
.12.
Aubertin
,
M.
, and
Simon
,
R.
,
1997
, “A damage initiation criterion for low
porosity rocks
,” Int. J. Rock Mech. Min.
Sci.
, 34
,
3
–4
.13.
Aubertin, M., Julien, M. R., and Li, L. 1998b, “The semi-brittle
behavior of low porosity rocks,” Keynote lecture, Proc. NARMS’98, 3rd
North American Rock Mechanics Symposium, Cancun, Mexico, Vol. 2,
pp. 65–90.
14.
Senseny
, P.
E.
,
Brodsky
, N.
S.
, and De
Vries
, K.
L.
, 1993
,
“Parameter evaluation for a unified constitutive
model
,” ASME J. Eng. Mater. Technol.
,
115
, pp.
157
–162
.15.
Pilvin, P., 1988, “Approaches multie´chelles pour la pre´vision du
comportement ane´lastique des me´taux,” Ph.D. thesis, Universite´ Paris VI,
France.
16.
Cailletaud, G., and Pilvin, P., 1994, “Identification and inverse
problems related to material behavior,” Inverse Problems in Engineering
Mechanics, Bui, Tanaka et al. eds., Balkema, Rotterdam, pp.
79–86.
17.
Ziebs, J., Meersmann, J., and Kuhn, H. J., 1992, “Effects of
proportional and nonproportional straining sequences on hardening/softening
behavior of IN738 LC at elevated temperatures,” Proc. Int. Seminar, Mecamat,
Cachan, France, pp. 224–255.
18.
Yahya, O. M. L., 1997, “Approche locale de la rupture fragile
intergranulaire de l’acier 16MND5,” Ph.D. thesis, Ecole des Mines de Paris,
France.
19.
Yahya
, O. M.
L.
,
Borit
,
F.
,
Piques
,
R.
, and
Pineau
,
A.
,
1997
, “Statistical modeling of intergranular
brittle fracture in a low alloy steel
,” Fatigue
Fract. Eng. Mater. Struct.
, 21
, pp.
1485
–1502
.20.
Evans
, R.
W.
, and
Harrison
, G.
F.
, 1976
,
“The development of a universal equation for secondary creep
rates in pure metals and engineering alloys
,” Met.
Sci.
, 10
, pp.
307
–313
.21.
Benallal
,
A.
, and
Marquis
,
D.
,
1987
, “Constitutive equations describing
non-proportional cyclic elasto-viscoplasticity
,”
ASME J. Eng. Mater. Technol.
, 109
, pp.
326
–336
.22.
Chaboche
,
J.
,
1989
, “Constitutive equations for cyclic
plasticity and cyclic viscoplasticity
,” Int. J.
Plast.
, 5
, pp.
247
–302
.23.
Chaboche
, J.
L.
, and
Nouailhas
,
D.
,
1989
, “A unified constitutive model for cyclic
viscoplasticity and its application to various stainless
steels
,” ASME J. Eng. Mater. Technol.
,
111
, pp.
424
–430
.24.
Chaboche, J. L., 1996, “Unified Cyclic Viscoplastic Constitutive
Equations: Development, Capabilities and Thermodynamic Framework,”
Unified Constitutive laws of Plastic Deformation, A. S.
Krausz and K. Krausz, eds., pp. 1–68, Academic Press, San
Diego.
25.
Argon
, A.
S.
, and
Battacharya
, A.
K.
, 1987
,
“Primary creep in nickel: experiments and
theory
,” Acta Metall.
, 35
,
pp. 1499
–1514
.26.
Miller
, A.
K.
, 1976
,
“An inelastic constitutive model for monotonic, cyclic and
creep deformation: Part I-Equations development and analytical
procedures
,” ASME J. Eng. Mater. Technol.
,
98
, pp.
97
–105
.27.
Freed
, A.
D.
, and
Walker
, K.
P.
, 1995
,
“Viscoplastic model development with an eye toward
characterization
,” ASME J. Eng. Mater.
Technol.
, 117
, pp.
8
–13
.28.
Raj, S. V., Iskovitz, I. S., and Freed, A. D., 1996 “Modeling the
role of dislocation substructure during class M and exponential creep,”
Unified Constitutive laws of Plastic Deformation, A S.
Krausz and K. Krausz, eds., Academic Press, San Diego, pp.
343–439.
29.
Brown
, A.
M.
, and
Ashby
, M.
F.
, 1980
,
“On the power-law creep equation
,”
Scr. Metall.
, 14
, pp.
1297
–1302
.Copyright © 2002
by ASME
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