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Fortran 77 demo#
This program uses functions defined in demo_ftnlib.cpp to create an ideal gas mixture and print some of its properties.
For a C++ version of this program, see demo.cpp.
Replace this sample main program with your program
c This file is part of Cantera. See License.txt in the top-level directory or
c at https://cantera.org/license.txt for license and copyright information.
program demo
implicit double precision (a-h,o-z)
parameter (MAXSP = 20, MAXRXNS = 100)
double precision q(MAXRXNS), qf(MAXRXNS), qr(MAXRXNS)
double precision diff(MAXSP)
character*80 eq
character*20 name
c
write(*,*)
write(*,*) '******** Fortran 77 Test Program ********'
call newIdealGasMix('h2o2.yaml','ohmech','mixture-averaged')
t = 1200.0
p = 101325.0
call setState_TPX_String(t, p,
$ 'H2:2, O2:1, OH:0.01, H:0.01, O:0.01')
c
write(*,*) 'Initial state properties:'
write(*,10) temperature(), pressure(), density(),
$ enthalpy_mole(), entropy_mole(), cp_mole()
Compute the equilibrium state#
Hold the specific enthalpy and pressure constant.
call equilibrate('HP')
write(*,*) 'Equilibrium state properties:'
write(*,10) temperature(), pressure(), density(),
$ enthalpy_mole(), entropy_mole(), cp_mole()
10 format(//'Temperature: ',g14.5,' K'/
$ 'Pressure: ',g14.5,' Pa'/
$ 'Density: ',g14.5,' kg/m3'/
$ 'Molar Enthalpy:',g14.5,' J/kmol'/
$ 'Molar Entropy: ',g14.5,' J/kmol-K'/
$ 'Molar cp: ',g14.5,' J/kmol-K'//)
Reaction information#
irxns = nReactions()
c forward and reverse rates of progress should be equal
c in equilibrium states
call getFwdRatesOfProgress(qf)
call getRevRatesOfProgress(qr)
c net rates of progress should be zero in equilibrium states
call getNetRatesOfProgress(q)
c for each reaction, print the equation and the rates of progress
do i = 1,irxns
call getReactionEqn(i,eq)
write(*,20) eq,qf(i),qr(i),q(i)
20 format(a27,3e14.5,' kmol/m3/s')
end do
Transport properties#
dnu = viscosity()
dlam = thermalConductivity()
call getMixDiffCoeffs(diff)
write(*,30) dnu, dlam
30 format(//'Viscosity: ',g14.5,' Pa-s'/
$ 'Thermal conductivity: ',g14.5,' W/m/K'/)
write(*,*) 'Species ',
$ ' Diffusion Coefficient'
nsp = nSpecies()
do k = 1, nsp
call getSpeciesName(k, name)
write(*,40) name, diff(k)
40 format(' ',a20,e14.5,' m2/s')
end do
stop
end