ebcs6.F File Reference

#include "implicit_f.inc"
#include "param_c.inc"
#include "com08_c.inc"
#include "scr11_c.inc"

Go to the source code of this file.

Functions/Subroutines
subroutine	ebcs6 (nseg, iseg, segvar, a, v, x, liste, nod, irect, ro0, en0, p0, vo, po, la, ms, stifn, ebcs)

Function/Subroutine Documentation

ebcs6()

subroutine ebcs6	(	integer	nseg,
		integer, dimension(nseg)	iseg,
		type(t_segvar)	segvar,
			a,
			v,
			x,
		integer, dimension(nod)	liste,
		integer	nod,
		integer, dimension(4,nseg)	irect,
			ro0,
			en0,
			p0,
			vo,
			po,
			la,
			ms,
			stifn,
		type(t_ebcs_inip), intent(in)	ebcs )

Definition at line 31 of file ebcs6.F.

      USE ebcs_mod
      USE segvar_mod
C-----------------------------------------------
C Pression arret initiale imposee avec impedance
C-----------------------------------------------
C   I m p l i c i t   T y p e s
C-----------------------------------------------
#include      "implicit_f.inc"
C-----------------------------------------------
C   C o m m o n   B l o c k s
C-----------------------------------------------
#include      "param_c.inc"
#include      "com08_c.inc"
#include      "scr11_c.inc"
C-----------------------------------------------
C   D u m m y   A r g u m e n t s
C-----------------------------------------------
      INTEGER NSEG,NOD,ISEG(NSEG),LISTE(NOD),IRECT(4,NSEG)
      my_real
     .        a(3,*),x(3,*),v(3,*),la(3,nod),
     .        ro0(nseg),en0(nseg),p0(nod),vo(nod),po(nod),
     .        ms(*),stifn(*)
      TYPE(t_ebcs_inip), INTENT(IN) :: EBCS
      TYPE(t_segvar) :: SEGVAR
C-----------------------------------------------
C   L o c a l   V a r i a b l e s
C-----------------------------------------------
      INTEGER I,IS,KSEG,N1,N2,N3,N4,NG1,NG2,NG3,NG4,N
      my_real orient,rho,c,lcar,roc,alp,fac,
     .        x13,y13,z13,x24,y24,z24,nx,ny,nz,s,
     .        roou,enou,vmx,vmy,vmz,fluxi,fluxo,vn,pn,du,dp,p,dpdv
C-----------------------------------------------
      c=ebcs%c
      rho=ebcs%rho
      roc=rho*c
      lcar=ebcs%lcar
      alp=zero 
      IF (lcar > 0) alp=c*dt1/lcar
C Sauve densite et energie initiale
      IF(tt == 0)THEN
        DO is=1,nseg
          kseg=abs(iseg(is))
          ro0(is) = segvar%RHO(kseg)
          en0(is) = segvar%EINT(kseg)
        ENDDO            
      ENDIF
C SURFACE NORMALE NODALES
      DO i=1,nod
         la(1,i)=zero
         la(2,i)=zero
         la(3,i)=zero
      ENDDO
C
      DO is=1,nseg
        kseg=abs(iseg(is))
        orient=float(iseg(is)/kseg)
        n1=irect(1,is)
        n2=irect(2,is)
        n3=irect(3,is)
        n4=irect(4,is)
        IF(n4 == 0 .OR. n4 == n3) THEN
          fac=one_over_6*orient
                   n4=n3
        ELSE
          fac=one_over_8*orient
        ENDIF
c
        ng1=liste(n1)
        ng2=liste(n2)
        ng3=liste(n3)
        ng4=liste(n4)
        x13=x(1,ng3)-x(1,ng1)
        y13=x(2,ng3)-x(2,ng1)
        z13=x(3,ng3)-x(3,ng1)
        x24=x(1,ng4)-x(1,ng2)
        y24=x(2,ng4)-x(2,ng2)
        z24=x(3,ng4)-x(3,ng2)
c
        nx=(y13*z24-z13*y24)*fac
        ny=(z13*x24-x13*z24)*fac
        nz=(x13*y24-y13*x24)*fac
c
        la(1,n1)=la(1,n1)+nx
        la(2,n1)=la(2,n1)+ny
        la(3,n1)=la(3,n1)+nz
        la(1,n2)=la(1,n2)+nx
        la(2,n2)=la(2,n2)+ny
        la(3,n2)=la(3,n2)+nz
        la(1,n3)=la(1,n3)+nx
        la(2,n3)=la(2,n3)+ny
        la(3,n3)=la(3,n3)+nz 
C
        vmx=v(1,ng1)+v(1,ng2)+v(1,ng3)
        vmy=v(2,ng1)+v(2,ng2)+v(2,ng3)
        vmz=v(3,ng1)+v(3,ng2)+v(3,ng3)
        IF(n4/=n3) THEN
           la(1,n4)=la(1,n4)+nx
           la(2,n4)=la(2,n4)+ny
           la(3,n4)=la(3,n4)+nz
           vmx=vmx+v(1,ng4)
           vmy=vmy+v(2,ng4)
           vmz=vmz+v(3,ng4)
        ENDIF
C
c bilan masse et energie totale
c
        roou = segvar%RHO(kseg)
        enou = segvar%EINT(kseg)
C
        fluxo=(vmx*nx+vmy*ny+vmz*nz)*dt1
        fluxi=min(fluxo,zero)
        fluxo=max(fluxo,zero)
C
        dmf=dmf-fluxo*roou-fluxi*ro0(is)
        def=def-fluxo*enou-fluxi*en0(is)
C
C stockage densit  et  nergie entrante dans buffer facette
C
        segvar%RHO(kseg)=ro0(is)
        segvar%EINT(kseg)=en0(is)
 
      ENDDO
C
C calcul pression initiale nodale
C
      IF (tt == 0) THEN
        DO i=1,nod
          n=liste(i)
          s=la(1,i)**2+la(2,i)**2+la(3,i)**2
          vn=(v(1,n)*la(1,i)+v(2,n)*la(2,i)+v(3,n)*la(3,i))/sqrt(s)
c on memorise la pression d'arret
          p0(i)=p0(i)/s
          IF(vn<zero)p0(i)=p0(i)+half*rho*vn**2
c          write(6,*)'P nodale', P0(I) 
          vo(i)=vn
          po(i)=p0(i)
        ENDDO
      ENDIF
C
      DO i=1,nod
        n=liste(i)
        s=sqrt(la(1,i)**2+la(2,i)**2+la(3,i)**2)
        vn=(v(1,n)*la(1,i)+v(2,n)*la(2,i)+v(3,n)*la(3,i))/s
        dpdv=roc
c condition darret
        pn=p0(i)
        IF(vn<0)THEN
          pn=p0(i)-half*rho*vn**2
          dpdv=dpdv-rho*vn
        ENDIF
c frontiere silencieuse
        du=roc*(vn-vo(i))
        dp=alp*(pn-po(i))
        p=po(i)+dp+du
c        write(6,*)'calcul', P,P0(I)
c
        a(1,n)=a(1,n)-p*la(1,i)
        a(2,n)=a(2,n)-p*la(2,i)
        a(3,n)=a(3,n)-p*la(3,i)
        stifn(n)=stifn(n)+(two*(s*dpdv)**2)/ms(n)
C
        def=def-half*(po(i)+p)*dt1*vn*s
C
        vo(i)=vn
        po(i)=p
      ENDDO
c-----------
      RETURN