Subloading
The Modified Extended 3D Subloading Surface (Hashiguchi) Model
The subloading surface framework provides a very versatile approach to model cyclic behaviour.
It is highly recommended to try it out.
References
- 10.1007/978-3-030-93138-4
- 10.1007/s11831-023-10022-1
- 10.1007/s11831-022-09880-y
Prof. Koichi Hashiguchi has published a large amount of papers on this topic.
To find more references, please refer to the monograph and the references therein.
Theory
Refer to the corresponding section
in Constitutive Modelling Cookbook
for theory, formulation and implementation details.
Syntax
| Text Only |
|---|
| material Subloading (1) (2) (3) (4) (5) (6) (7) (8) (9) (10) (11) (12) (13) (14) (15) [16]
# (1) int, unique material tag
# (2) double, elastic modulus
# (3) double, poisson's ratio
# (4) double, isotropic initial stress, \sigma^i
# (5) double, isotropic linear hardening modulus, k_{iso}
# (6) double, isotropic saturation stress, \sigma^s
# (7) double, isotropic saturation rate, m^s_{iso}
# (8) double, kinematic initial stress, a^i
# (9) double, kinematic linear hardening modulus, k_{kin}
# (10) double, kinematic saturation stress, a^s
# (11) double, kinematic saturation rate, m^s_{kin}
# (12) double, yield ratio evolution rate, u
# (13) double, kinematic hardening rate, b
# (14) double, elastic core evolution rate, c_e
# (15) double, elastic core size, z_e
# [16] double, density, default: 0.0
|
History Layout
| location |
parameter |
initial_history(0) |
iteration counter |
initial_history(1) |
accumulated plastic strain \(q\) |
initial_history(2) |
normal yield ratio \(z\) |
initial_history(3:8) |
normalised back stress \(\mathbf{\alpha}\) |
initial_history(9:14) |
normalised elastic core \(\mathbf{d}\) |
Example
See this example.