181 lines
5.4 KiB
FortranFixed
181 lines
5.4 KiB
FortranFixed
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c J. Grogan, 2012
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c -------------------------------------------------------------------
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subroutine vusdfld(
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* nblock,nstatev,nfieldv,nprops,ndir,nshr,jElem,kIntPt,
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* kLayer,kSecPt,stepTime,totalTime,dt,cmname,coordMp,
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* direct,T,charLength,props,stateOld,stateNew,field)
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c
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include 'vaba_param.inc'
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c
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dimension jElem(nblock),stateNew(nblock,nstatev),
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* field(nblock,nfieldv),stateOld(nblock,nstatev),
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* charLength(nblock),rPEEQ(maxblk,1),
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* Stress(nblock*6),jData(nblock*6),
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* eigVal(nblock,3),coordMp(nblock,3)
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c -------------------------------------------------------------------
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c Common blocks store element status and random number assigment.
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common active(600000)
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common rnum(600000)
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integer active
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integer rnum
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c
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do k=1,nblock
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c -------------------------------------------------------------------
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c Update SDVs
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do i=1,7
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stateNew(k,i)=stateOld(k,i)
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enddo
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stateNew(k,11)=stateOld(k,11)
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c -------------------------------------------------------------------
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c Determine Characteristic Element Length
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damage=stateOld(k,8)
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randE=stateOld(k,9)
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activeE=stateOld(k,10)
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c -------------------------------------------------------------------
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c Check if element is on exposed surface.
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do i=2,7
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nNum=stateNew(k,i)
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if(nNum==0.)cycle
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if(active(nNum)==1)then
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activeE=1.
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if(rnum(nNum)*0.9547>randE)randE=rnum(nNum)*0.9547
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endif
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enddo
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c -------------------------------------------------------------------
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c Recover Corrosion Parameters
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ukinetic=0.05d0
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randE=1.d0
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if(activeE>0.99d0)then
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if(totaltime>1.5d0)then
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dam_inc=(ukinetic/charlength(k))*randE*dt
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damage=damage+dam_inc
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endif
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endif
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c -------------------------------------------------------------------
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c Remove Fully Damaged Elements
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if(damage>=0.999)then
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damage=1.d0
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stateNew(k,11)=0.d0
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active(statenew(k,1))=1.d0
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rnum(statenew(k,1))=randE
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endif
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c -------------------------------------------------------------------
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stateNew(k,8)=damage
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field(k,1)=damage
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stateNew(k,9)=randE
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stateNew(k,10)=activeE
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c -------------------------------------------------------------------
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end do
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return
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end subroutine vusdfld
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subroutine vuanisohyper_inv(nblock,nFiber,nInv,jElem,kIntPt,
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* kLayer,kSecPt,cmname,nstatev, nfieldv, nprops,props,tempOld,
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* tempNew,fieldOld,fieldNew,stateOld,sInvariant,zeta,uDev,duDi,
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* d2uDiDi,stateNew)
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c
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include 'vaba_param.inc'
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c
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dimension props(nprops),tempOld(nblock),
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* fieldOld(nblock,nfieldv),stateOld(nblock,nstatev),
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* tempNew(nblock), fieldNew(nblock,nfieldv),
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* stateNew(nblock,nstatev),sInvariant(nblock,nInv),
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* zeta(nblock,nFiber*(nFiber-1)/2),uDev(nblock),
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* duDi(nblock,nInv),d2uDiDi(nblock,nInv*(nInv+1)/2)
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c
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parameter(zero = 0.d0, one = 1.d0, two = 2.d0, three = 3.d0)
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common active(600000)
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common rnum(600000)
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integer active
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integer rnum
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c Material Properties
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u = props(1)
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rkap = props(2)
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rk1 = props(3)
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rk2 = props(4)
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rp = props(5)
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c
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c Loop Over Each Element
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do k = 1,nblock
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c Index Each Invariant according to Abaqus Convention
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i1 = 1
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i1i1 = 1
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i3 = 3
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i3i3 = 6
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i4 = 4
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i1i4 = 7
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i4i4 = 10
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i6 = 8
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i1i6 = 29
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i6i6 = 36
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c Get Values of each Invariant
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ri1 = sinvariant(k,i1)
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ri4 = sinvariant(k,i4)
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ri6 = sinvariant(k,i6)
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c Get Fibre Contributions to UDEV
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t = (one - rp) * (ri1 - three) * (ri1 - three)
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if(ri4>1.)then
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t1 = rk2 * (t + rp * (ri4 - one) * (ri4 - one))
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else
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t1=0.
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endif
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if(ri6>1.)then
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t2 = rk2 * (t + rp * (ri6 - one) * (ri6 - one))
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else
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t2=0.
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endif
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et1 = exp(t1)
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et2 = exp(t2)
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term1 = rk1 / (two * rk2)
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ufibres = term1 * (et1 + et2 - two)
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c Get UDEV
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udev(k) = u * (ri1 - three) + ufibres
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c Get dUdI1
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dt1di1 = rk2 * two * (one - rp) * (ri1 - three)
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dudi(k,i1) = term1 * dt1di1 * (et1 + et2) + u
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c Get dUdI4 and dUdI6
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if(ri4>1.)then
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dt1di4 = rk2 * two * rp * (ri4 - one)
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else
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dt1di4 = 0.
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endif
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if(ri6>1.)then
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dt2di6 = rk2 * two * rp * (ri6 - one)
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else
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dt2di6 = 0.
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endif
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dudi(k,i4) = term1 * dt1di4 * et1
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dudi(k,i6) = term1 * dt2di6 * et2
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c Get d2UdI1dI1
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d2t1di1di1 = rk2 * two * (one - rp)
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d2udidi(k,i1i1) = term1 * (d2t1di1di1 + dt1di1 * dt1di1)
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d2udidi(k,i1i1) = d2udidi(k,i1i1) * (et1 + et2)
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c Get d2UdI1dI4 and d2UdI4dI4
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d2udidi(k,i1i4) = term1 * dt1di4 * dt1di1 * et1
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d2t1di4di4 = rk2 * two * rp
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d2udidi(k,i4i4) = term1 * (dt1di4 * dt1di4 + d2t1di4di4)
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d2udidi(k,i4i4) = d2udidi(k,i4i4) * et1
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c Get d2UdI1dI6 and d2UdI6dI6
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d2udidi(k,i1i6) = term1 * dt2di6 * dt1di1 * et2
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d2t2di6di6 = rk2 * two * rp
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d2udidi(k,i6i6) = term1 * (dt2di6 * dt2di6 + d2t2di6di6)
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d2udidi(k,i6i6) = d2udidi(k,i6i6) * et2
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end do
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c For the compressible case
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if(rkap > zero) then
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do k = 1,nblock
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rj = sInvariant(k,i3)
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dudi(k,i3) = rkap * (rj-one)
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c duDi(k,i3) = (rkap/two) * (rj - one/rj)
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d2udidi(k,i3i3) = rkap
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c d2uDiDi(k,i3i3)= (rkap/two) * (one + one/ rj / rj)
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end do
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end if
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return
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end
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