def get_compatible_opencg_surfaces(opencg_surface):
if not isinstance(opencg_surface, opencg.Surface):
msg = 'Unable to create an OpenMOC Surface from {0} which ' \
'is not an OpenCG Surface'.format(opencg_surface)
raise ValueError(msg)
global OPENMOC_SURFACES
surface_id = opencg_surface._id
# If this Surface was already created, use it
if surface_id in OPENMOC_SURFACES:
return OPENMOC_SURFACES[surface_id]
# Create an OpenMOC Surface to represent this OpenCG Surface
name = opencg_surface._name
# Correct for OpenMOC's syntax for Surfaces dividing Cells
boundary = opencg_surface._boundary_type
if opencg_surface._type == 'z-squareprism':
x0 = opencg_surface._coeffs['x0']
y0 = opencg_surface._coeffs['y0']
R = opencg_surface._coeffs['R']
# Create a list of the four planes we need
left = opencg.XPlane(x0=x0 - R, name=name)
right = opencg.XPlane(x0=x0 + R, name=name)
bottom = opencg.YPlane(y0=y0 - R, name=name)
top = opencg.YPlane(y0=y0 + R, name=name)
# Set the boundary conditions for each Surface
left.setBoundaryType(boundary)
right.setBoundaryType(boundary)
bottom.setBoundaryType(boundary)
top.setBoundaryType(boundary)
surfaces = [left, right, bottom, top]
elif opencg_surface._type in [
'x-cylinder', 'y-cylinder', 'x-squareprism', 'y-squareprism'
]:
msg = 'Unable to create a compatible OpenMOC Surface from an OpenCG ' \
'Surface of type {0} since it is not compatible with OpenMOCs 2D ' \
'geometry formulation on the xy-plane'.format(opencg_surface._type)
raise ValueError(msg)
else:
msg = 'Unable to create a compatible OpenMOC Surface from an OpenCG ' \
'Surface of type {0} since it already a compatible ' \
'Surface type in OpenMOC'.format(opencg_surface._type)
raise ValueError(msg)
# Add the OpenMOC Surface(s) to the global collection of all OpenMOC Surfaces
OPENMOC_SURFACES[surface_id] = surfaces
# Add the OpenCG Surface to the global collection of all OpenCG Surfaces
OPENCG_SURFACES[surface_id] = opencg_surface
return surfaces
def get_compatible_opencg_surfaces(opencg_surface):
"""Generate OpenCG surfaces that are compatible with OpenMC equivalent to an
OpenCG surface that is not compatible. For example, this method may be used
to convert a ZSquarePrism OpenCG surface into a collection of equivalent
XPlane and YPlane OpenCG surfaces.
Parameters
----------
opencg_surface : opencg.Surface
OpenCG surface that is incompatible with OpenMC
Returns
-------
surfaces : list of opencg.Surface
Collection of surfaces equivalent to the original one but compatible
with OpenMC
"""
if not isinstance(opencg_surface, opencg.Surface):
msg = 'Unable to create an OpenMC Surface from "{0}" which ' \
'is not an OpenCG Surface'.format(opencg_surface)
raise ValueError(msg)
global OPENMC_SURFACES
surface_id = opencg_surface._id
# If this Surface was already created, use it
if surface_id in OPENMC_SURFACES:
return OPENMC_SURFACES[surface_id]
# Create an OpenMC Surface to represent this OpenCG Surface
name = opencg_surface._name
boundary = opencg_surface._boundary_type
if opencg_surface._type == 'x-squareprism':
y0 = opencg_surface._coeffs['y0']
z0 = opencg_surface._coeffs['z0']
R = opencg_surface._coeffs['R']
# Create a list of the four planes we need
left = opencg.YPlane(name=name, boundary=boundary, y0=y0 - R)
right = opencg.YPlane(name=name, boundary=boundary, y0=y0 + R)
bottom = opencg.ZPlane(name=name, boundary=boundary, z0=z0 - R)
top = opencg.ZPlane(name=name, boundary=boundary, z0=z0 + R)
surfaces = [left, right, bottom, top]
elif opencg_surface._type == 'y-squareprism':
x0 = opencg_surface._coeffs['x0']
z0 = opencg_surface._coeffs['z0']
R = opencg_surface._coeffs['R']
# Create a list of the four planes we need
left = opencg.XPlane(name=name, boundary=boundary, x0=x0 - R)
right = opencg.XPlane(name=name, boundary=boundary, x0=x0 + R)
bottom = opencg.ZPlane(name=name, boundary=boundary, z0=z0 - R)
top = opencg.ZPlane(name=name, boundary=boundary, z0=z0 + R)
surfaces = [left, right, bottom, top]
elif opencg_surface._type == 'z-squareprism':
x0 = opencg_surface._coeffs['x0']
y0 = opencg_surface._coeffs['y0']
R = opencg_surface._coeffs['R']
# Create a list of the four planes we need
left = opencg.XPlane(name=name, boundary=boundary, x0=x0 - R)
right = opencg.XPlane(name=name, boundary=boundary, x0=x0 + R)
bottom = opencg.YPlane(name=name, boundary=boundary, y0=y0 - R)
top = opencg.YPlane(name=name, boundary=boundary, y0=y0 + R)
surfaces = [left, right, bottom, top]
else:
msg = 'Unable to create a compatible OpenMC Surface an OpenCG ' \
'Surface of type "{0}" since it already a compatible ' \
'Surface type in OpenMC'.format(opencg_surface._type)
raise ValueError(msg)
# Add the OpenMC Surface(s) to the global collection of all OpenMC Surfaces
OPENMC_SURFACES[surface_id] = surfaces
# Add the OpenCG Surface to the global collection of all OpenCG Surfaces
OPENCG_SURFACES[surface_id] = opencg_surface
return surfaces
def get_opencg_surface(openmc_surface):
"""Return an OpenCG surface corresponding to an OpenMC surface.
Parameters
----------
openmc_surface : openmc.surface.Surface
OpenMC surface
Returns
-------
opencg_surface : opencg.Surface
Equivalent OpenCG surface
"""
if not isinstance(openmc_surface, openmc.Surface):
msg = 'Unable to create an OpenCG Surface from "{0}" ' \
'which is not an OpenMC Surface'.format(openmc_surface)
raise ValueError(msg)
global OPENCG_SURFACES
surface_id = openmc_surface._id
# If this Material was already created, use it
if surface_id in OPENCG_SURFACES:
return OPENCG_SURFACES[surface_id]
# Create an OpenCG Surface to represent this OpenMC Surface
name = openmc_surface._name
# Correct for OpenMC's syntax for Surfaces dividing Cells
boundary = openmc_surface._boundary_type
if boundary == 'transmission':
boundary = 'interface'
opencg_surface = None
if openmc_surface._type == 'plane':
A = openmc_surface._coeffs['A']
B = openmc_surface._coeffs['B']
C = openmc_surface._coeffs['C']
D = openmc_surface._coeffs['D']
opencg_surface = opencg.Plane(surface_id, name, boundary, A, B, C, D)
elif openmc_surface._type == 'x-plane':
x0 = openmc_surface._coeffs['x0']
opencg_surface = opencg.XPlane(surface_id, name, boundary, x0)
elif openmc_surface._type == 'y-plane':
y0 = openmc_surface._coeffs['y0']
opencg_surface = opencg.YPlane(surface_id, name, boundary, y0)
elif openmc_surface._type == 'z-plane':
z0 = openmc_surface._coeffs['z0']
opencg_surface = opencg.ZPlane(surface_id, name, boundary, z0)
elif openmc_surface._type == 'x-cylinder':
y0 = openmc_surface._coeffs['y0']
z0 = openmc_surface._coeffs['z0']
R = openmc_surface._coeffs['R']
opencg_surface = opencg.XCylinder(surface_id, name, boundary, y0, z0,
R)
elif openmc_surface._type == 'y-cylinder':
x0 = openmc_surface._coeffs['x0']
z0 = openmc_surface._coeffs['z0']
R = openmc_surface._coeffs['R']
opencg_surface = opencg.YCylinder(surface_id, name, boundary, x0, z0,
R)
elif openmc_surface._type == 'z-cylinder':
x0 = openmc_surface._coeffs['x0']
y0 = openmc_surface._coeffs['y0']
R = openmc_surface._coeffs['R']
opencg_surface = opencg.ZCylinder(surface_id, name, boundary, x0, y0,
R)
# Add the OpenMC Surface to the global collection of all OpenMC Surfaces
OPENMC_SURFACES[surface_id] = openmc_surface
# Add the OpenCG Surface to the global collection of all OpenCG Surfaces
OPENCG_SURFACES[surface_id] = opencg_surface
return opencg_surface
def get_compatible_opencg_surfaces(opencg_surface):
"""Generate OpenCG surfaces that are compatible with OpenMOC equivalent to
an OpenCG surface that is not compatible. For example, this method may be
used to convert a ZSquarePrism OpenCG surface into a collection of
equivalent XPlane and YPlane OpenCG surfaces.
Parameters
----------
opencg_surface : opencg.Surface
OpenCG surface that is incompatible with OpenMOC
Returns
-------
surfaces : list of opencg.Surface
Collection of surfaces equivalent to the original one but compatible
with OpenMOC
"""
cv.check_type('opencg_surface', opencg_surface, opencg.Surface)
global OPENMOC_SURFACES
surface_id = opencg_surface.id
# If this Surface was already created, use it
if surface_id in OPENMOC_SURFACES:
return OPENMOC_SURFACES[surface_id]
# Create an OpenMOC Surface to represent this OpenCG Surface
name = str(opencg_surface.name)
# Correct for OpenMOC's syntax for Surfaces dividing Cells
boundary = opencg_surface.boundary_type
if opencg_surface.type == 'x-squareprism':
y0 = opencg_surface.y0
z0 = opencg_surface.z0
R = opencg_surface.r
# Create a list of the four planes we need
min_y = opencg.YPlane(y0=y0 - R, name=name)
max_y = opencg.YPlane(y0=y0 + R, name=name)
min_z = opencg.ZPlane(z0=z0 - R, name=name)
max_z = opencg.ZPlane(z0=z0 + R, name=name)
# Set the boundary conditions for each Surface
min_y.boundary_type = boundary
max_y.boundary_type = boundary
min_z.boundary_type = boundary
max_z.boundary_type = boundary
surfaces = [min_y, max_y, min_z, max_z]
elif opencg_surface.type == 'y-squareprism':
x0 = opencg_surface.x0
z0 = opencg_surface.z0
R = opencg_surface.r
# Create a list of the four planes we need
min_x = opencg.XPlane(name=name, boundary=boundary, x0=x0 - R)
max_x = opencg.XPlane(name=name, boundary=boundary, x0=x0 + R)
min_z = opencg.ZPlane(name=name, boundary=boundary, z0=z0 - R)
max_z = opencg.ZPlane(name=name, boundary=boundary, z0=z0 + R)
# Set the boundary conditions for each Surface
min_x.boundary_type = boundary
max_x.boundary_type = boundary
min_z.boundary_type = boundary
max_z.boundary_type = boundary
surfaces = [min_x, max_x, min_z, max_z]
elif opencg_surface.type == 'z-squareprism':
x0 = opencg_surface.x0
y0 = opencg_surface.y0
R = opencg_surface.r
# Create a list of the four planes we need
min_x = opencg.XPlane(name=name, boundary=boundary, x0=x0 - R)
max_x = opencg.XPlane(name=name, boundary=boundary, x0=x0 + R)
min_y = opencg.YPlane(name=name, boundary=boundary, y0=y0 - R)
max_y = opencg.YPlane(name=name, boundary=boundary, y0=y0 + R)
# Set the boundary conditions for each Surface
min_x.boundary_type = boundary
max_x.boundary_type = boundary
min_y.boundary_type = boundary
max_y.boundary_type = boundary
surfaces = [min_x, max_x, min_y, max_y]
else:
msg = 'Unable to create a compatible OpenMOC Surface an OpenCG ' \
'Surface of type "{0}" since it already a compatible ' \
'Surface type in OpenMOC'.format(opencg_surface.type)
raise ValueError(msg)
# Add the OpenMOC Surface(s) to global collection of all OpenMOC Surfaces
OPENMOC_SURFACES[surface_id] = surfaces
# Add the OpenCG Surface to the global collection of all OpenCG Surfaces
OPENCG_SURFACES[surface_id] = opencg_surface
return surfaces
def get_opencg_surface(openmoc_surface):
"""Return an OpenCG surface corresponding to an OpenMOC surface.
Parameters
----------
openmc_surface : openmoc.Surface
OpenMOC surface
Returns
-------
opencg_surface : opencg.Surface
Equivalent OpenCG surface
"""
cv.check_type('openmoc_surface', openmoc_surface, openmoc.Surface)
global OPENCG_SURFACES
surface_id = openmoc_surface.getId()
# If this Surface was already created, use it
if surface_id in OPENCG_SURFACES:
return OPENCG_SURFACES[surface_id]
# Create an OpenCG Surface to represent this OpenMOC Surface
name = openmoc_surface.getName()
# Correct for OpenMOC's syntax for Surfaces dividing Cells
boundary = openmoc_surface.getBoundaryType()
if boundary == openmoc.VACUUM:
boundary = 'vacuum'
elif boundary == openmoc.REFLECTIVE:
boundary = 'reflective'
elif boundary == openmoc.BOUNDARY_NONE:
boundary = 'interface'
opencg_surface = None
surface_type = openmoc_surface.getSurfaceType()
if surface_type == openmoc.PLANE:
openmoc_surface = openmoc.castSurfaceToPlane(openmoc_surface)
A = openmoc_surface.getA()
B = openmoc_surface.getB()
C = openmoc_surface.getC()
D = openmoc_surface.getD()
opencg_surface = opencg.Plane(surface_id, name, boundary, A, B, C, D)
elif surface_type == openmoc.XPLANE:
openmoc_surface = openmoc.castSurfaceToXPlane(openmoc_surface)
x0 = openmoc_surface.getX()
opencg_surface = opencg.XPlane(surface_id, name, boundary, x0)
elif surface_type == openmoc.YPLANE:
openmoc_surface = openmoc.castSurfaceToYPlane(openmoc_surface)
y0 = openmoc_surface.getY()
opencg_surface = opencg.YPlane(surface_id, name, boundary, y0)
elif surface_type == openmoc.ZPLANE:
openmoc_surface = openmoc.castSurfaceToZPlane(openmoc_surface)
z0 = openmoc_surface.getZ()
opencg_surface = opencg.ZPlane(surface_id, name, boundary, z0)
elif surface_type == openmoc.ZCYLINDER:
openmoc_surface = openmoc.castSurfaceToZCylinder(openmoc_surface)
x0 = openmoc_surface.getX0()
y0 = openmoc_surface.getY0()
R = openmoc_surface.getRadius()
opencg_surface = opencg.ZCylinder(surface_id, name, boundary, x0, y0,
R)
# Add the OpenMOC Surface to the global collection of all OpenMOC Surfaces
OPENMOC_SURFACES[surface_id] = openmoc_surface
# Add the OpenCG Surface to the global collection of all OpenCG Surfaces
OPENCG_SURFACES[surface_id] = opencg_surface
return opencg_surface
def get_opencg_surface(openmc_surface):
"""Return an OpenCG surface corresponding to an OpenMC surface.
Parameters
----------
openmc_surface : openmc.surface.Surface
OpenMC surface
Returns
-------
opencg_surface : opencg.Surface
Equivalent OpenCG surface
"""
cv.check_type('openmc_surface', openmc_surface, openmc.Surface)
surface_id = openmc_surface.id
# If this Material was already created, use it
if surface_id in OPENCG_SURFACES:
return OPENCG_SURFACES[surface_id]
# Create an OpenCG Surface to represent this OpenMC Surface
name = openmc_surface.name
# Correct for OpenMC's syntax for Surfaces dividing Cells
boundary = openmc_surface.boundary_type
if boundary == 'transmission':
boundary = 'interface'
opencg_surface = None
if openmc_surface.type == 'plane':
A = openmc_surface.a
B = openmc_surface.b
C = openmc_surface.c
D = openmc_surface.d
opencg_surface = opencg.Plane(surface_id, name, boundary, A, B, C, D)
elif openmc_surface.type == 'x-plane':
x0 = openmc_surface.x0
opencg_surface = opencg.XPlane(surface_id, name, boundary, x0)
elif openmc_surface.type == 'y-plane':
y0 = openmc_surface.y0
opencg_surface = opencg.YPlane(surface_id, name, boundary, y0)
elif openmc_surface.type == 'z-plane':
z0 = openmc_surface.z0
opencg_surface = opencg.ZPlane(surface_id, name, boundary, z0)
elif openmc_surface.type == 'x-cylinder':
y0 = openmc_surface.y0
z0 = openmc_surface.z0
R = openmc_surface.r
opencg_surface = opencg.XCylinder(surface_id, name, boundary, y0, z0,
R)
elif openmc_surface.type == 'y-cylinder':
x0 = openmc_surface.x0
z0 = openmc_surface.z0
R = openmc_surface.r
opencg_surface = opencg.YCylinder(surface_id, name, boundary, x0, z0,
R)
elif openmc_surface.type == 'z-cylinder':
x0 = openmc_surface.x0
y0 = openmc_surface.y0
R = openmc_surface.r
opencg_surface = opencg.ZCylinder(surface_id, name, boundary, x0, y0,
R)
# Add the OpenMC Surface to the global collection of all OpenMC Surfaces
OPENMC_SURFACES[surface_id] = openmc_surface
# Add the OpenCG Surface to the global collection of all OpenCG Surfaces
OPENCG_SURFACES[surface_id] = opencg_surface
return opencg_surface
def get_opencg_surface(openmoc_surface):
if not isinstance(openmoc_surface, openmoc.Surface):
msg = 'Unable to create an OpenCG Surface from {0} ' \
'which is not an OpenMOC Surface'.format(openmoc_surface)
raise ValueError(msg)
global OPENCG_SURFACES
surface_id = openmoc_surface.getId()
# If this Surface was already created, use it
if surface_id in OPENCG_SURFACES:
return OPENCG_SURFACES[surface_id]
# Create an OpenCG Surface to represent this OpenMOC Surface
name = openmoc_surface.getName()
# Correct for OpenMOC's syntax for Surfaces dividing Cells
boundary = openmoc_surface.getBoundaryType()
if boundary == openmoc.VACUUM:
boundary = 'vacuum'
elif boundary == openmoc.REFLECTIVE:
boundary = 'reflective'
elif boundary == openmoc.BOUNDARY_NONE:
boundary = 'interface'
opencg_surface = None
surface_type = openmoc_surface.getSurfaceType()
if surface_type == openmoc.PLANE:
openmoc_surface = openmoc.castSurfaceToPlane(openmoc_surface)
A = openmoc_surface.getA()
B = openmoc_surface.getB()
C = openmoc_surface.getC()
opencg_surface = opencg.Plane(surface_id, name, boundary, A, B, 0, C)
elif surface_type == openmoc.XPLANE:
openmoc_surface = openmoc.castSurfaceToXPlane(openmoc_surface)
x0 = openmoc_surface.getX()
opencg_surface = opencg.XPlane(surface_id, name, boundary, x0)
elif surface_type == openmoc.YPLANE:
openmoc_surface = openmoc.castSurfaceToYPlane(openmoc_surface)
y0 = openmoc_surface.getY()
opencg_surface = opencg.YPlane(surface_id, name, boundary, y0)
elif surface_type == openmoc.ZPLANE:
openmoc_surface = openmoc.castSurfaceToZPlane(openmoc_surface)
z0 = openmoc_surface.getZ()
opencg_surface = opencg.ZPlane(surface_id, name, boundary, z0)
elif surface_type == openmoc.ZYCLINDER:
openmoc_surface = openmoc.castSurfaceToZCylinder(openmoc_surface)
x0 = openmoc_surface.getX0()
y0 = openmoc_surface.getY0()
R = openmoc_surface.getRadius()
opencg_surface = opencg.ZCylinder(surface_id, name, boundary, x0, y0,
R)
# Add the OpenMOC Surface to the global collection of all OpenMOC Surfaces
OPENMOC_SURFACES[surface_id] = openmoc_surface
# Add the OpenCG Surface to the global collection of all OpenCG Surfaces
OPENCG_SURFACES[surface_id] = opencg_surface
return opencg_surface
# Export to "materials.xml" materials_file.export_to_xml() # Get OpenCG versions of each OpenMC material to fill OpenCG Cells below opencg_fuel = openmc.opencg_compatible.get_opencg_material(fuel) opencg_clad = openmc.opencg_compatible.get_opencg_material(clad) opencg_water = openmc.opencg_compatible.get_opencg_material(water) ############################################################################### # Exporting to OpenMC geometry.xml File ############################################################################### # Create bounding surfaces min_x = opencg.XPlane(boundary='reflective', x0=0.0) max_x = opencg.XPlane(boundary='reflective', x0=5.0) min_y = opencg.YPlane(boundary='reflective', y0=0.0) max_y = opencg.YPlane(boundary='reflective', y0=10.0) min_z = opencg.ZPlane(boundary='reflective', z0=0.0) max_z = opencg.ZPlane(boundary='reflective', z0=10.0) # Create material interfacial surfaces left = opencg.XPlane(surface_id=1, boundary='interface', x0=2.0) right = opencg.XPlane(surface_id=2, boundary='interface', x0=2.4) # Create a Universe to encapsulate the 1D slab slab_universe = opencg.Universe(name='1D slab') # Create fuel Cell fuel_cell = opencg.Cell(name='fuel') fuel_cell.fill = opencg_fuel fuel_cell.add_surface(halfspace=+1, surface=min_x)
