Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3% strain |
Fig. 4 Results of strain controlled cyclic load tests showing the
stabilised hysteresis loops for cross-weld samples and base metal
samples tested at (a) ±1% strain, (b) ±2% strain and (c) 0-3%
strain |
Table 1. Tensile properties of S355 G10+M from literature [20] and
calibrated parameters for the cyclic deformation obtained in this study.
Mixed kinematic (Ck (MPa), γk and
isotropic (Q∞ (MPa), b) model parameters
fitted to stabilised hysteresis loops (refer Fig. 4) for S355 G10+M
obtained from cyclic load test. Ck is the
plasticity modulus, γk the rate of change in
Ck with increase in the applied plastic strain.
Similarly, is the change in yield surface with increasing equivalent
plastic strain and the rate of change is controlled by the parameter
b. |
Table 1. Tensile properties of S355 G10+M from literature
[20] and calibrated parameters for the cyclic deformation obtained
in this study. Mixed kinematic (Ck (MPa),
γk and isotropic (Q∞ (MPa),
b) model parameters fitted to stabilised hysteresis loops (refer
Fig. 4) for S355 G10+M obtained from cyclic load test.
Ck is the plasticity modulus, γk
the rate of change in Ck with increase in the
applied plastic strain. Similarly, is the change in yield surface with
increasing equivalent plastic strain and the rate of change is
controlled by the parameter b. |
Table 1. Tensile properties of
S355 G10+M from literature [20] and calibrated parameters for the
cyclic deformation obtained in this study. Mixed kinematic
(Ck (MPa), γk and isotropic
(Q∞ (MPa), b) model parameters fitted to
stabilised hysteresis loops (refer Fig. 4) for S355 G10+M obtained from
cyclic load test. Ck is the plasticity modulus,
γk the rate of change in Ck with
increase in the applied plastic strain. Similarly, is the change in
yield surface with increasing equivalent plastic strain and the rate of
change is controlled by the parameter b. |
Table 1. Tensile
properties of S355 G10+M from literature [20] and calibrated
parameters for the cyclic deformation obtained in this study. Mixed
kinematic (Ck (MPa), γk and
isotropic (Q∞ (MPa), b) model parameters
fitted to stabilised hysteresis loops (refer Fig. 4) for S355 G10+M
obtained from cyclic load test. Ck is the
plasticity modulus, γk the rate of change in
Ck with increase in the applied plastic strain.
Similarly, is the change in yield surface with increasing equivalent
plastic strain and the rate of change is controlled by the parameter
b. |
Table 1. Tensile properties of S355 G10+M from literature
[20] and calibrated parameters for the cyclic deformation obtained
in this study. Mixed kinematic (Ck (MPa),
γk and isotropic (Q∞ (MPa),
b) model parameters fitted to stabilised hysteresis loops (refer
Fig. 4) for S355 G10+M obtained from cyclic load test.
Ck is the plasticity modulus, γk
the rate of change in Ck with increase in the
applied plastic strain. Similarly, is the change in yield surface with
increasing equivalent plastic strain and the rate of change is
controlled by the parameter b. |
Table 1. Tensile properties of
S355 G10+M from literature [20] and calibrated parameters for the
cyclic deformation obtained in this study. Mixed kinematic
(Ck (MPa), γk and isotropic
(Q∞ (MPa), b) model parameters fitted to
stabilised hysteresis loops (refer Fig. 4) for S355 G10+M obtained from
cyclic load test. Ck is the plasticity modulus,
γk the rate of change in Ck with
increase in the applied plastic strain. Similarly, is the change in
yield surface with increasing equivalent plastic strain and the rate of
change is controlled by the parameter b. |
Table 1. Tensile
properties of S355 G10+M from literature [20] and calibrated
parameters for the cyclic deformation obtained in this study. Mixed
kinematic (Ck (MPa), γk and
isotropic (Q∞ (MPa), b) model parameters
fitted to stabilised hysteresis loops (refer Fig. 4) for S355 G10+M
obtained from cyclic load test. Ck is the
plasticity modulus, γk the rate of change in
Ck with increase in the applied plastic strain.
Similarly, is the change in yield surface with increasing equivalent
plastic strain and the rate of change is controlled by the parameter
b. |
Table 1. Tensile properties of S355 G10+M from literature
[20] and calibrated parameters for the cyclic deformation obtained
in this study. Mixed kinematic (Ck (MPa),
γk and isotropic (Q∞ (MPa),
b) model parameters fitted to stabilised hysteresis loops (refer
Fig. 4) for S355 G10+M obtained from cyclic load test.
Ck is the plasticity modulus, γk
the rate of change in Ck with increase in the
applied plastic strain. Similarly, is the change in yield surface with
increasing equivalent plastic strain and the rate of change is
controlled by the parameter b. |
Table 1. Tensile properties of
S355 G10+M from literature [20] and calibrated parameters for the
cyclic deformation obtained in this study. Mixed kinematic
(Ck (MPa), γk and isotropic
(Q∞ (MPa), b) model parameters fitted to
stabilised hysteresis loops (refer Fig. 4) for S355 G10+M obtained from
cyclic load test. Ck is the plasticity modulus,
γk the rate of change in Ck with
increase in the applied plastic strain. Similarly, is the change in
yield surface with increasing equivalent plastic strain and the rate of
change is controlled by the parameter b. |
Table 1. Tensile
properties of S355 G10+M from literature [20] and calibrated
parameters for the cyclic deformation obtained in this study. Mixed
kinematic (Ck (MPa), γk and
isotropic (Q∞ (MPa), b) model parameters
fitted to stabilised hysteresis loops (refer Fig. 4) for S355 G10+M
obtained from cyclic load test. Ck is the
plasticity modulus, γk the rate of change in
Ck with increase in the applied plastic strain.
Similarly, is the change in yield surface with increasing equivalent
plastic strain and the rate of change is controlled by the parameter
b. |
Table 1. Tensile properties of S355 G10+M from literature
[20] and calibrated parameters for the cyclic deformation obtained
in this study. Mixed kinematic (Ck (MPa),
γk and isotropic (Q∞ (MPa),
b) model parameters fitted to stabilised hysteresis loops (refer
Fig. 4) for S355 G10+M obtained from cyclic load test.
Ck is the plasticity modulus, γk
the rate of change in Ck with increase in the
applied plastic strain. Similarly, is the change in yield surface with
increasing equivalent plastic strain and the rate of change is
controlled by the parameter b. |
Table 1. Tensile properties of
S355 G10+M from literature [20] and calibrated parameters for the
cyclic deformation obtained in this study. Mixed kinematic
(Ck (MPa), γk and isotropic
(Q∞ (MPa), b) model parameters fitted to
stabilised hysteresis loops (refer Fig. 4) for S355 G10+M obtained from
cyclic load test. Ck is the plasticity modulus,
γk the rate of change in Ck with
increase in the applied plastic strain. Similarly, is the change in
yield surface with increasing equivalent plastic strain and the rate of
change is controlled by the parameter b. |
Table 1. Tensile
properties of S355 G10+M from literature [20] and calibrated
parameters for the cyclic deformation obtained in this study. Mixed
kinematic (Ck (MPa), γk and
isotropic (Q∞ (MPa), b) model parameters
fitted to stabilised hysteresis loops (refer Fig. 4) for S355 G10+M
obtained from cyclic load test. Ck is the
plasticity modulus, γk the rate of change in
Ck with increase in the applied plastic strain.
Similarly, is the change in yield surface with increasing equivalent
plastic strain and the rate of change is controlled by the parameter
b. |