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ASTM Selected Technical Papers
Thermomechanical Fatigue Behavior of Materials: Second Volume
By
MJ Verrilli
MJ Verrilli
1
Symposium co-chairman and co-editor
;
NASA Lewis Research Center
,
Cleveland, Ohio
.
Search for other works by this author on:
MG Castelli
MG Castelli
2
Symposium co-chairman and co-editor
;
NYMA, Inc., NASA LeRC Group
,
Brook Park, Ohio
.
Search for other works by this author on:
ISBN-10:
0-8031-2001-X
ISBN:
978-0-8031-2001-3
No. of Pages:
385
Publisher:
ASTM International
Publication date:
1996

Specific forms for both the Gibb's and complementary dissipation potentials are chosen such that a complete (i.e., fully associative) potential based multiaxial, nonisothermal unified viscoplastic model is obtained. This model possess one tensorial internal state variable (that is, associated with dislocation substructure) and an evolutionary law that has nonlinear kinematic hardening and both thermal and strain induced recovery mechanisms. A unique aspect of the present model is the inclusion of nonlinear hardening through the use of a compliance operator, derived from the Gibb's potential, in the evolution law for the back stress. This nonlinear tensorial operator is significant in that it allows both the flow and evolutionary laws to be fully associative (and therefore easily integrated), greatly influences the multiaxial response under non-proportional loading paths, and in the case of nonisothermal histories, introduces an instantaneous thermal softening mechanism proportional to the rate of change in temperature. In addition to this nonlinear compliance operator, a new consistent, potential preserving, internal strain unloading criterion has been introduced to prevent abnormalities in the predicted stress-strain curves, which are present with nonlinear hardening formulations, during unloading and reversed loading of the external variables. The specific model proposed is characterized for a representative titanium alloy commonly used as the matrix material in SiC fiber reinforced composites, i.e., TIMETAL 21S. Verification of the proposed model is shown using ”specialized” non-standard isothermal and thermomechanical deformation tests.

1.
Arnold
,
S.M.
; and
Saleeb
,
A.F.
:
On the Thermodynamic Framework of Generalized Coupled Thermoelastic Viscoplastic - Damage Modeling
,
Int. Jnl. of Plasticity
, Vol.
10
, No.
3
,
1994
, pp 263–278.
2.
Saleeb
,
A.F.
and
Wilt
,
T.E.
:
Analysis of the Anisotropic Viscoplastic-Damage Response of Composite Laminates-Continuum Basis and Computational Algorithms
,
Int. Jnl. Num. Meth. Engng.
, Vol.
36
,
1993
, pp. 1629–1660.
3.
Arnold
,
S.M.
,
Saleeb
,
A.F.
, and
Wilt
,
T.E.
:
A Modeling Investigation of Thermal and Strain Induced Recovery and Nonlinear Hardening in Potential Based Viscoplasticity
,
Jnl. of Engng. Materials and Technology
, Vol.
117
, No.
2
,
1995
, pp. 157–167.
4.
Saleeb
,
A.E.
,
Seif
,
Y.
, and
Arnold
,
S.M.
:
Fully-Associative Viscoplasticity with Anisotropic and Nonlinear Kinematic Hardening
, submitted
Int. Jnl. of Plasticity
,
1995
.
5.
Arnold
,
S.M.
;
Saleeb
,
A.F.
, and
Castelli
,
M.G.
:
A Fully Associative, Nonlinear Kinematic, Unified Viscoplastic Model for Titanium Based Matrices
,
Life Prediction Methodology for Titanium Matrix Composites
, ASTM STP 1253,
Johnson
,
W.S.
,
Larsen
,
J. M.
, and
Cox
,
B.N.
Eds.,
American Society for Testing and Materials
,
Philadelphia
,
1995
. NASA TM-106609,
1994
.
6.
Spencer
,
A.J.M.
:
Continuum Physics
, Vol.
1
,
Eringen
A.C.
, Ed.,
Academic Press
.,
London
,
1971
, p. 240.
7.
Lemaitre
,
J.
; and
Chaboche
,
J.L.
:
Mechanics of Solid Materials
,
Cambridge University. Press
,
New York
,
1990
.
8.
Orowan
,
E.
:
Causes and Effects of Internal Stresses, Internal Stresses and Fatigue of Metals
,
Proceedings
of the Symposium on Internal Stresses and Fatigue in Metals,
Detroit Mich.
, Eds.,
Rassweiler
G.M.
and
Grvise
W.L.
,
Elsevier Publishing
,
1959
.
9.
Robinson
,
D.N.
; and
Swindeman
,
R.W.
:
Unified Creep-Plasticity Constitutive Equations for 2 1/4 Cr-1Mo Steel at Elevated Temperature
, ORNL TM-8444,
1982
.
10.
Miller
,
A.K.
, Ed.:
Unified Constitutive Equations for Plastic Deformation and Creep of Engineering Alloys
,
Elsevier Applied Science
,
New York
,
1987
.
11.
Freed
,
A.D.
;
Chaboche
,
J.L.
; and
Walker
,
K.P.
:
A Viscoplastic Theory with Thermodynamic Considerations
,
Acta Mech
 0001-5970, Vol.
90
,
1991
, pp. 155–174.
12.
Neu
,
R.W.
;
Nonisothermal Material Parameters for the Bodner-Partom Model
, MD-Vol.
43
, Material Parameter Estimation for Modern Constitutive Equations, Eds,
Bertram
L.A.
,
Brown
S. B.
, and
Freed
A. D.
,
1993
, pp. 211–226.
13.
Sherwood
,
J. A.
and
Quimby
,
H.M.
; “
Micromechanical Modeling of Damage Growth in Titanium Based Metal-Matrix Composites
”, to appear Comp. Struc,
1995
.
14.
Castelli
,
M.G.
,
Arnold
,
S.M.
, and
Saleeb
,
A.F.
:
Specialized Deformation Tests for the Characterization of a Viscoplastic Model: Application to a Titanium Alloy
, NASA TM-106268,
1995
.
15.
Ashbaugh
,
N.E.
, and
Khobaib
,
M.
: Unpublished Data,
University of Dayton Resesrch Institute
,
Dayton, Ohio
.
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