if alldone: break
# set the gas object state to that of this reactor, in
# preparation for the simulation of the next reactor
# downstream, where this object will set the inlet conditions
gas = r.contents()
dist = n * rlen * 1.0e3 # distance in mm
# write the gas mole fractions and surface coverages
# vs. distance
writeCSV(f, [dist, r.temperature() - 273.15,
r.pressure() / OneAtm] + list(gas.moleFractions()) +
list(surf.coverages()))
f.close()
# make a reaction path diagram tracing carbon. This diagram will show
# the pathways by the carbon entering the bed in methane is convered
# into CO and CO2. The diagram will be specifically for the exit of
# the bed; if the pathways are desired at some interior point, then
# put this statement inside the above loop.
#
# To process this diagram, give the command on the command line
# after running this script:
# dot -Tps < carbon_pathways.dot > carbon_pathways.ps
# This will generate the diagram in Postscript.
element = 'C'
rxnpath.write(surf, element, 'carbon_pathways.dot')
# set the gas object state to that of this reactor, in
# preparation for the simulation of the next reactor
# downstream, where this object will set the inlet conditions
gas = r.contents()
dist = n*rlen * 1.0e3 # distance in mm
# write the gas mole fractions and surface coverages
# vs. distance
writeCSV(f, [dist, r.temperature() - 273.15,
r.pressure()/OneAtm] + list(gas.moleFractions())
+ list(surf.coverages()))
f.close()
# make a reaction path diagram tracing carbon. This diagram will show
# the pathways by the carbon entering the bed in methane is convered
# into CO and CO2. The diagram will be specifically for the exit of
# the bed; if the pathways are desired at some interior point, then
# put this statement inside the above loop.
#
# To process this diagram, give the command on the command line
# after running this script:
# dot -Tps < carbon_pathways.dot > carbon_pathways.ps
# This will generate the diagram in Postscript.
element = 'C'
rxnpath.write(surf, element, 'carbon_pathways.dot')
output_dir = 'd:/www/docs'
output_urldir = 'http://your.http.server/'
#-----------------------------------------------------------------------
# these lines can be replaced by any commands that generate
# an object of a class derived from class Kinetics (such as IdealGasMix)
# in some state.
gas = GRI30()
gas.setState_TPX(2500.0, OneAtm, 'CH4:0.4, O2:1, N2:3.76')
gas.equilibrate('TP')
gas.setTemperature(500.0)
#------------------------------------------------------------------------
d = rxnpath.PathDiagram(title = 'reaction path diagram following N',
bold_color = 'green')
element = 'N'
output_file = 'rxnpath2.dot'
url = output_urldir+'/'+output_file
rxnpath.write(gas, element, join(output_dir, output_file), d)
if len(opts) > 1 and opts[1] == "-view":
# graphics format. Must be one of png, svg, gif, or jpg
fmt = 'svg'
rxnpath.view(url, fmt)
# is within the document tree of your web server, and set output_url to
# the URL that accesses this directory.
output_dir = 'd:/www/docs'
output_urldir = 'http://your.http.server/'
#-----------------------------------------------------------------------
# these lines can be replaced by any commands that generate
# an object of a class derived from class Kinetics (such as IdealGasMix)
# in some state.
gas = GRI30()
gas.setState_TPX(2500.0, OneAtm, 'CH4:0.4, O2:1, N2:3.76')
gas.equilibrate('TP')
gas.setTemperature(500.0)
#------------------------------------------------------------------------
d = rxnpath.PathDiagram(title='reaction path diagram following N',
bold_color='green')
element = 'N'
output_file = 'rxnpath2.dot'
url = output_urldir + '/' + output_file
rxnpath.write(gas, element, join(output_dir, output_file), d)
if len(opts) > 1 and opts[1] == "-view":
# graphics format. Must be one of png, svg, gif, or jpg
fmt = 'svg'
rxnpath.view(url, fmt)
from Cantera import *
from Cantera import rxnpath
#-----------------------------------------------------------------------
# these lines can be replaced by any commands that generate
# an object of a class derived from class Kinetics (such as IdealGasMix)
# in some state.
gas = GRI30()
gas.setState_TPX(2500.0, OneAtm, 'CH4:0.4, O2:1, N2:3.76')
gas.equilibrate('TP')
gas.setTemperature(500.0)
#------------------------------------------------------------------------
d = rxnpath.PathDiagram(title = 'reaction path diagram following N',
bold_color = 'green')
element = 'N'
dot_file = 'rxnpath2.dot'
img_file = 'rxnpath2.png'
img_path = os.path.join(os.getcwd(), img_file)
rxnpath.write(gas, element, dot_file, d)
print "Wrote graphviz input file to '%s'." % os.path.join(os.getcwd(), dot_file)
os.system('dot %s -Tpng -o%s -Gdpi=200' % (dot_file, img_file))
print "Wrote graphviz output file to '%s'." % img_path
if len(sys.argv) > 1 and sys.argv[1] == "-view":
rxnpath.view('file:///' + img_path)
from Cantera import rxnpath
#-----------------------------------------------------------------------
# these lines can be replaced by any commands that generate
# an object of a class derived from class Kinetics (such as IdealGasMix)
# in some state.
gas = GRI30()
gas.setState_TPX(2500.0, OneAtm, 'CH4:0.4, O2:1, N2:3.76')
gas.equilibrate('TP')
gas.setTemperature(500.0)
#------------------------------------------------------------------------
d = rxnpath.PathDiagram(title='reaction path diagram following N',
bold_color='green')
element = 'N'
dot_file = 'rxnpath2.dot'
img_file = 'rxnpath2.png'
img_path = os.path.join(os.getcwd(), img_file)
rxnpath.write(gas, element, dot_file, d)
print "Wrote graphviz input file to '%s'." % os.path.join(
os.getcwd(), dot_file)
os.system('dot %s -Tpng -o%s -Gdpi=200' % (dot_file, img_file))
print "Wrote graphviz output file to '%s'." % img_path
if len(sys.argv) > 1 and sys.argv[1] == "-view":
rxnpath.view('file:///' + img_path)
