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constitutive_Microstructure() computes now twin "plop" volumes from the given microstructure. 

Mattex.dat has 2 parameters for deformation twinning:
- average grain size
- average twin stack thickness
This commit is contained in:
Luc Hantcherli 2007-12-07 15:12:43 +00:00
parent 44d6235777
commit d0f6c81d66
2 changed files with 46 additions and 17 deletions
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32
trunk/constitutive_dislo.f90
View File

@ -53,6 +53,8 @@ real(pReal), dimension(:) , allocatable :: material_rho0
real(pReal), dimension(:) , allocatable :: material_bg
real(pReal), dimension(:) , allocatable :: material_Qedge
real(pReal), dimension(:) , allocatable :: material_tau0
real(pReal), dimension(:) , allocatable :: material_GrainSize
real(pReal), dimension(:) , allocatable :: material_StackSize
real(pReal), dimension(:) , allocatable :: material_c1
real(pReal), dimension(:) , allocatable :: material_c2
real(pReal), dimension(:) , allocatable :: material_c3
@ -103,6 +105,7 @@ real(pReal), dimension(:) , allocatable :: constitutive_rho_m
real(pReal), dimension(:) , allocatable :: constitutive_rho_f
real(pReal), dimension(:) , allocatable :: constitutive_rho_p
real(pReal), dimension(:) , allocatable :: constitutive_g0_slip
real(pReal), dimension(:) , allocatable :: constitutive_twin_volume
!************************************
!* Interaction matrices *
@ -320,6 +323,10 @@ do while(.true.)
material_Qedge(section)=IO_floatValue(line,positions,2)
case ('tau0')
material_tau0(section)=IO_floatValue(line,positions,2)
case ('grain_size')
material_GrainSize(section)=IO_floatValue(line,positions,2)
case ('stack_size')
material_StackSize(section)=IO_floatValue(line,positions,2)
case ('c1')
material_c1(section)=IO_floatValue(line,positions,2)
case ('c2')
@ -482,6 +489,8 @@ allocate(material_SlipIntCoeff(crystal_MaxMaxNslipOfStructure,material_maxN))
allocate(material_bg(material_maxN)) ; material_bg=0.0_pReal
allocate(material_Qedge(material_maxN)) ; material_Qedge=0.0_pReal
allocate(material_tau0(material_maxN)) ; material_tau0=0.0_pReal
allocate(material_GrainSize(material_maxN)) ; material_GrainSize=0.0_pReal
allocate(material_StackSize(material_maxN)) ; material_StackSize=0.0_pReal
allocate(material_c1(material_maxN)) ; material_c1=0.0_pReal
allocate(material_c2(material_maxN)) ; material_c2=0.0_pReal
allocate(material_c3(material_maxN)) ; material_c3=0.0_pReal
@ -669,6 +678,7 @@ allocate(constitutive_passing_stress(material_maxNslip)) ; constitutive_passi
allocate(constitutive_jump_width(material_maxNslip)) ; constitutive_jump_width=0.0_pReal
allocate(constitutive_activation_volume(material_maxNslip)) ; constitutive_activation_volume=0.0_pReal
allocate(constitutive_g0_slip(material_maxNslip)) ; constitutive_g0_slip=0.0_pReal
allocate(constitutive_twin_volume(material_maxNtwin)) ; constitutive_twin_volume=0.0_pReal
!* Assignment of all grains in all IPs of all cp-elements
do e=1,mesh_NcpElems
@ -821,18 +831,20 @@ subroutine constitutive_Microstructure(state,Tp,ipc,ip,el)
!* - el : current element *
!*********************************************************************
use prec, only: pReal,pInt
use math, only: pi
use crystal, only: crystal_TwinIntType
implicit none
!* Definition of variables
integer(pInt) ipc,ip,el
integer(pInt) matID,i
real(pReal) Tp
integer(pInt) matID,i,j
real(pReal) Tp,inv_intertwin_length,twin_mfp
real(pReal), dimension(constitutive_Nstatevars(ipc,ip,el)) :: state
!* Get the material-ID from the triplet(ipc,ip,el)
matID = constitutive_matID(ipc,ip,el)
!* Quantities derivated from state
!* Quantities derivated from state - slip
constitutive_rho_f=matmul(constitutive_Pforest (1:material_Nslip(matID),1:material_Nslip(matID),matID),state)
constitutive_rho_p=matmul(constitutive_Pparallel(1:material_Nslip(matID),1:material_Nslip(matID),matID),state)
do i=1,material_Nslip(matID)
@ -848,6 +860,20 @@ do i=1,material_Nslip(matID)
(Kb*Tp))
enddo
!* Quantities derivated from state - twin
do i=1,material_Ntwin(matID)
!* Inverse of the average distance between 2 twins of the same familly
inv_intertwin_length=0.0_pReal
do j=1,material_Ntwin(matID)
inv_intertwin_length=inv_intertwin_length+(crystal_TwinIntType(i,j,material_CrystalStructure(matID))*&
state((material_Nslip(matID)+j)))/(2.0_pReal*material_StackSize(matID)*&
(1.0_pReal-(1-sum(state((material_Nslip(matID)+1):(material_Nslip(matID)+material_Ntwin(matID)))))))
enddo
twin_mfp=(1.0_pReal)/((1.0_pReal/material_GrainSize(matID))+inv_intertwin_length)
constitutive_twin_volume(i)=(pi/6.0_pReal)*material_StackSize(matID)*twin_mfp**2.0_pReal
enddo
return
end subroutine

31
trunk/mattex.mpie
View File

@ -1,24 +1,24 @@
<materials>
[Aluminium]
crystal_structure 1
Nslip 12
Ntwin 0
crystal_structure 1
Nslip 12
Ntwin 0
## Elastic constants
# Unit in [Pa]
C11 106.75e9
C12 60.41e9
C44 28.34e9
C11 106.75e9
C12 60.41e9
C44 28.34e9
## Parameters for phenomenological modeling
# Unit in [Pa]
s0_slip 31.0e6
gdot0_slip 0.001
n_slip 20
h0 75.0e6
s_sat 63.0e6
w0 2.25
s0_slip 31.0e6
gdot0_slip 0.001
n_slip 20
h0 75.0e6
s_sat 63.0e6
w0 2.25
# Self and latent hardening coefficients
hardening_coefficients 1.0 1.4
hardening_coefficients 1.0 1.4
## Parameters for dislocation-based modeling
# Initial dislocation density [m]²
@ -40,7 +40,10 @@ c4 0.05
# Athermal annihilation adjustment
c5 10.0
# Dislocation interaction coefficients
interaction_coefficients 1.0 2.2 3.0 1.6 3.8 4.5
interaction_coefficients 1.0 2.2 3.0 1.6 3.8 4.5
# Twin parameters: grain size, average size of stacks of twins [m]
grain_size 1.5e-5
stack_size 5.0e-8
<textures>
[cube SX]