def _make_blankets_layers(self):
super()._make_blankets_layers()
azimuth_placement_angles = np.linspace(
0, 360, self.number_of_blanket_segments, endpoint=False)
thin_cutter = paramak.BlanketCutterStar(
distance=self.gap_between_blankets,
azimuth_placement_angle=azimuth_placement_angles)
thick_cutter = paramak.BlanketCutterStar(
distance=self.gap_between_blankets +
2 * self.firstwall_radial_thickness,
azimuth_placement_angle=azimuth_placement_angles)
self._blanket.cut = [self._center_column_cutter, thick_cutter]
if self.blanket_fillet_radius != 0:
# tried firstwall start radius here already
x = self.major_radius + 1
front_face_b = self._blanket.solid.faces(
cq.NearestToPointSelector((0, x, 0)))
front_edge_b = front_face_b.edges(
cq.NearestToPointSelector((0, x, 0)))
front_edge_length_b = front_edge_b.val().Length()
self._blanket.solid = self._blanket.solid.edges(
paramak.EdgeLengthSelector(front_edge_length_b)).fillet(
self.blanket_fillet_radius)
self._firstwall.thickness += self.blanket_radial_thickness
self._firstwall.cut = [
self._center_column_cutter,
thin_cutter,
self._blanket]
# TODO this segfaults at the moment but works as an opperation on the
# reactor after construction in jupyter
# tried different x values and (0, x, 0)
# noticed that it much quicker as a post process so perhaps some
# unwanted looping is happening
# if self.blanket_fillet_radius != 0:
# x = self.major_radius # tried firstwall start radius here already
# front_face = \
# self._firstwall.solid.faces(
# cq.NearestToPointSelector((x, 0, 0)))
# print('found front face')
# front_edge = front_face.edges(
# cq.NearestToPointSelector((x, 0, 0)))
# print('found front edge')
# front_edge_length = front_edge.val().Length()
# print('found front edge length', front_edge_length)
# self._firstwall.solid = self._firstwall.solid.edges(
# paramak.EdgeLengthSelector(front_edge_length)).fillet(self.blanket_fillet_radius)
# print('finished')
return [self._firstwall, self._blanket, self._blanket_rear_wall]
def main():
rot_angle = 180
all_components = []
plasma = paramak.Plasma(
# default parameters
rotation_angle=rot_angle,
stp_filename="plasma_shape.stp",
)
all_components.append(plasma)
component = paramak.BlanketFP(
plasma=plasma,
thickness=100,
stop_angle=90,
start_angle=-90,
offset_from_plasma=30,
rotation_angle=rot_angle,
stp_filename="blanket_constant_thickness_outboard_plasma.stp",
)
all_components.append(component)
component = paramak.BlanketCutterStar(height=2000,
width=2000,
distance=100)
all_components.append(component)
component = paramak.BlanketFP(
plasma=plasma,
thickness=100,
stop_angle=90,
start_angle=250,
offset_from_plasma=30,
rotation_angle=rot_angle,
stp_filename="blanket_constant_thickness_inboard_plasma.stp",
)
all_components.append(component)
component = paramak.BlanketFP(
plasma=plasma,
thickness=100,
stop_angle=250,
start_angle=-90,
offset_from_plasma=30,
rotation_angle=rot_angle,
stp_filename="blanket_constant_thickness_plasma.stp",
)
all_components.append(component)
CenterColumnShieldCylinder = paramak.CenterColumnShieldCylinder(
inner_radius=80,
outer_radius=100,
height=300,
rotation_angle=rot_angle,
stp_filename="center_column_shield_cylinder.stp",
)
all_components.append(CenterColumnShieldCylinder)
component = paramak.InboardFirstwallFCCS(
central_column_shield=CenterColumnShieldCylinder,
thickness=50,
rotation_angle=rot_angle,
stp_filename="firstwall_from_center_column_shield_cylinder.stp",
)
all_components.append(component)
CenterColumnShieldHyperbola = paramak.CenterColumnShieldHyperbola(
inner_radius=50,
mid_radius=75,
outer_radius=100,
height=300,
rotation_angle=rot_angle,
stp_filename="center_column_shield_hyperbola.stp",
)
all_components.append(CenterColumnShieldHyperbola)
component = paramak.InboardFirstwallFCCS(
central_column_shield=CenterColumnShieldHyperbola,
thickness=50,
rotation_angle=rot_angle,
stp_filename="firstwall_from_center_column_shield_hyperbola.stp",
)
all_components.append(component)
CenterColumnShieldCircular = paramak.CenterColumnShieldCircular(
inner_radius=50,
mid_radius=75,
outer_radius=100,
height=300,
rotation_angle=rot_angle,
stp_filename="center_column_shield_circular.stp",
)
all_components.append(CenterColumnShieldCircular)
component = paramak.InboardFirstwallFCCS(
central_column_shield=CenterColumnShieldCircular,
thickness=50,
rotation_angle=rot_angle,
stp_filename="firstwall_from_center_column_shield_circular.stp",
)
all_components.append(component)
CenterColumnShieldFlatTopHyperbola = paramak.CenterColumnShieldFlatTopHyperbola(
inner_radius=50,
mid_radius=75,
outer_radius=100,
arc_height=220,
height=300,
rotation_angle=rot_angle,
stp_filename="center_column_shield_flat_top_hyperbola.stp",
)
all_components.append(CenterColumnShieldFlatTopHyperbola)
component = paramak.InboardFirstwallFCCS(
central_column_shield=CenterColumnShieldFlatTopHyperbola,
thickness=50,
rotation_angle=rot_angle,
stp_filename=
"firstwall_from_center_column_shield_flat_top_hyperbola.stp",
)
all_components.append(component)
CenterColumnShieldFlatTopCircular = paramak.CenterColumnShieldFlatTopCircular(
inner_radius=50,
mid_radius=75,
outer_radius=100,
arc_height=220,
height=300,
rotation_angle=rot_angle,
stp_filename="center_column_shield_flat_top_Circular.stp",
)
all_components.append(CenterColumnShieldFlatTopCircular)
component = paramak.InboardFirstwallFCCS(
central_column_shield=CenterColumnShieldFlatTopCircular,
thickness=50,
rotation_angle=rot_angle,
stp_filename=
"firstwall_from_center_column_shield_flat_top_Circular.stp",
)
all_components.append(component)
CenterColumnShieldPlasmaHyperbola = paramak.CenterColumnShieldPlasmaHyperbola(
inner_radius=150,
mid_offset=50,
edge_offset=40,
height=800,
rotation_angle=rot_angle,
stp_filename="center_column_shield_plasma_hyperbola.stp",
)
all_components.append(CenterColumnShieldPlasmaHyperbola)
component = paramak.InboardFirstwallFCCS(
central_column_shield=CenterColumnShieldPlasmaHyperbola,
thickness=50,
rotation_angle=rot_angle,
stp_filename="firstwall_from_center_column_shield_plasma_hyperbola.stp",
)
all_components.append(component)
component = paramak.InnerTfCoilsCircular(
inner_radius=25,
outer_radius=100,
number_of_coils=10,
gap_size=5,
height=300,
stp_filename="inner_tf_coils_circular.stp",
)
all_components.append(component)
component = paramak.InnerTfCoilsFlat(
inner_radius=25,
outer_radius=100,
number_of_coils=10,
gap_size=5,
height=300,
stp_filename="inner_tf_coils_flat.stp",
)
all_components.append(component)
# this makes 4 pf coil cases
pf_coil_set = paramak.PoloidalFieldCoilCaseSet(
heights=[10, 10, 20, 20],
widths=[10, 10, 20, 40],
casing_thicknesses=[5, 5, 10, 10],
center_points=[(100, 100), (100, 150), (50, 200), (50, 50)],
rotation_angle=rot_angle,
stp_filename="pf_coil_case_set.stp")
all_components.append(pf_coil_set)
# this makes 4 pf coils
pf_coil_set = paramak.PoloidalFieldCoilSet(heights=[10, 10, 20, 20],
widths=[10, 10, 20, 40],
center_points=[(100, 100),
(100, 150),
(50, 200),
(50, 50)],
rotation_angle=rot_angle,
stp_filename="pf_coil_set.stp")
all_components.append(pf_coil_set)
# this makes 4 pf coil cases for the 4 pf coils made above
component = paramak.PoloidalFieldCoilCaseSetFC(
pf_coils=pf_coil_set,
casing_thicknesses=[5, 5, 10, 10],
rotation_angle=rot_angle,
stp_filename="pf_coil_cases_set.stp")
all_components.append(component)
# this makes 1 pf coils
pf_coil = paramak.PoloidalFieldCoil(center_point=(100, 100),
height=20,
width=20,
rotation_angle=rot_angle,
stp_filename="poloidal_field_coil.stp")
all_components.append(pf_coil)
# this makes one PF coil case for the provided pf coil
component = paramak.PoloidalFieldCoilCaseSetFC(
pf_coils=[pf_coil],
casing_thicknesses=[10],
rotation_angle=rot_angle,
stp_filename="pf_coil_cases_set_fc.stp")
all_components.append(component)
component = paramak.PoloidalFieldCoilCaseFC(
pf_coil=pf_coil,
casing_thickness=10,
rotation_angle=rot_angle,
stp_filename="poloidal_field_coil_case_fc.stp",
)
all_components.append(component)
component = paramak.PoloidalFieldCoilCase(
center_point=(100, 100),
coil_height=20,
coil_width=20,
casing_thickness=10,
rotation_angle=rot_angle,
stp_filename="poloidal_field_coil_case.stp",
)
all_components.append(component)
component = paramak.BlanketConstantThicknessArcV(
inner_lower_point=(300, -200),
inner_mid_point=(500, 0),
inner_upper_point=(300, 200),
thickness=100,
rotation_angle=rot_angle,
stp_filename="blanket_arc_v.stp",
)
all_components.append(component)
component = paramak.BlanketConstantThicknessArcH(
inner_lower_point=(300, -200),
inner_mid_point=(400, 0),
inner_upper_point=(300, 200),
thickness=100,
rotation_angle=rot_angle,
stp_filename="blanket_arc_h.stp",
)
all_components.append(component)
component = paramak.ToroidalFieldCoilRectangle(
horizontal_start_point=(100, 700),
vertical_mid_point=(800, 0),
thickness=150,
distance=60,
stp_filename="tf_coil_rectangle.stp",
number_of_coils=1,
)
all_components.append(component)
component = paramak.ToroidalFieldCoilCoatHanger(
horizontal_start_point=(200, 500),
horizontal_length=400,
vertical_mid_point=(700, 50),
vertical_length=500,
thickness=50,
distance=50,
stp_filename="toroidal_field_coil_coat_hanger.stp",
number_of_coils=1,
)
all_components.append(component)
component = paramak.ToroidalFieldCoilTripleArc(
R1=80,
h=200,
radii=(70, 100),
coverages=(60, 60),
thickness=30,
distance=30,
number_of_coils=1,
stp_filename="toroidal_field_coil_triple_arc.stp")
all_components.append(component)
magnet = paramak.ToroidalFieldCoilPrincetonD(
R1=80,
R2=300,
thickness=30,
distance=30,
number_of_coils=1,
stp_filename="toroidal_field_coil_princeton_d.stp")
all_components.append(magnet)
component = paramak.ITERtypeDivertor(
# default parameters
rotation_angle=rot_angle,
stp_filename="ITER_type_divertor.stp",
)
all_components.append(component)
component = paramak.PortCutterRotated(center_point=(450, 0),
polar_coverage_angle=20,
rotation_angle=10,
polar_placement_angle=45,
azimuth_placement_angle=0)
all_components.append(component)
component = paramak.PortCutterRectangular(
distance=3,
z_pos=0,
height=0.2,
width=0.4,
fillet_radius=0.02,
azimuth_placement_angle=[0, 45, 90, 180])
all_components.append(component)
component = paramak.PortCutterCircular(
distance=3,
z_pos=0.25,
radius=0.1,
# azimuth_placement_angle=[0, 45, 90, 180], # TODO: fix issue #548
azimuth_placement_angle=[0, 45, 90],
)
all_components.append(component)
component = paramak.VacuumVessel(height=2,
inner_radius=1,
thickness=0.2,
rotation_angle=270)
all_components.append(component)
component = paramak.CoolantChannelRingStraight(
height=200,
channel_radius=10,
ring_radius=70,
number_of_coolant_channels=8,
workplane="XY",
rotation_axis="Z",
stp_filename="coolant_channel_ring_straight.stp",
)
all_components.append(component)
component = paramak.CoolantChannelRingCurved(
height=200,
channel_radius=10,
ring_radius=70,
mid_offset=-20,
number_of_coolant_channels=8,
workplane="XY",
path_workplane="XZ",
stp_filename="coolant_channel_ring_curved.stp",
force_cross_section=True)
all_components.append(component)
component = paramak.RotatedIsoscelesTriangle(
height=20,
base_length=15,
pivot_angle=0,
pivot_point=(100, 50),
rotation_angle=70,
workplane='XY',
stp_filename='rotated_isosceles_triangle.stp')
all_components.append(component)
component = paramak.RotatedTrapezoid(length_1=10,
length_2=20,
length_3=30,
pivot_angle=0,
pivot_point=(100, 50),
rotation_angle=45,
stp_filename='rotated_trapezoid.stp')
all_components.append(component)
component = paramak.PoloidalSegments(number_of_segments=5,
center_point=(400, 50))
all_components.append(component)
component = paramak.TFCoilCasing(magnet=magnet,
inner_offset=10,
outer_offset=15,
vertical_section_offset=20,
distance=40)
all_components.append(component)
component = paramak.HexagonPin(length_of_side=5,
distance=10,
center_point=(10, 20))
all_components.append(component)
return all_components
def setUp(self):
self.test_shape = paramak.BlanketCutterStar(distance=100)
def main(number_of_sections=8, gap_size=15, central_block_width=200):
number_of_segments = 8
gap_size = 15.
central_block_width = 200
offset = (360 / number_of_segments) / 2
# a plasma shape is made and used by the BlanketFP, which builds around
# the plasma
plasma = paramak.Plasma(elongation=1.59,
triangularity=0.33,
major_radius=910,
minor_radius=290)
plasma.solid
# this makes a cutter shape that is used to make the blanket bananna
# segment that has parallel sides
parallel_outboard_gaps_outer = paramak.BlanketCutterParallels(
thickness=gap_size,
azimuth_placement_angle=np.linspace(0,
360,
number_of_segments,
endpoint=False),
gap_size=central_block_width)
# this makes a gap that seperates the inboard and outboard blanket
inboard_to_outboard_gaps = paramak.ExtrudeStraightShape(
points=[
(plasma.high_point[0] - (0.5 * gap_size), plasma.high_point[1]),
(plasma.high_point[0] - (0.5 * gap_size),
plasma.high_point[1] + 1000),
(plasma.high_point[0] + (0.5 * gap_size),
plasma.high_point[1] + 1000),
(plasma.high_point[0] + (0.5 * gap_size), plasma.high_point[1]),
],
distance=math.tan(math.radians(360 / (2 * number_of_segments))) *
plasma.high_point[0] * 2,
azimuth_placement_angle=np.linspace(0,
360,
number_of_segments,
endpoint=False))
# this makes the regular gaps (non parallel) gaps on the outboard blanket
outboard_gaps = paramak.BlanketCutterStar(
distance=gap_size,
azimuth_placement_angle=np.linspace(0 + offset,
360 + offset,
number_of_segments,
endpoint=False))
# makes the outboard blanket with cuts for all the segmentation
outboard_blanket = paramak.BlanketFP(plasma=plasma,
thickness=100,
stop_angle=90,
start_angle=-60,
offset_from_plasma=30,
rotation_angle=360,
cut=[
outboard_gaps,
parallel_outboard_gaps_outer,
inboard_to_outboard_gaps
])
# this makes the regular gaps on the outboard blanket
inboard_gaps = paramak.BlanketCutterStar(
distance=gap_size,
azimuth_placement_angle=np.linspace(0,
360,
number_of_segments * 2,
endpoint=False))
# makes the inboard blanket with cuts for all the segmentation
inboard_blanket = paramak.BlanketFP(
plasma=plasma,
thickness=100,
stop_angle=90,
start_angle=260,
offset_from_plasma=30,
rotation_angle=360,
cut=[inboard_gaps, inboard_to_outboard_gaps],
union=outboard_blanket)
# saves the blanket as an stp file
inboard_blanket.export_stp('blanket.stp')