def setUp(self): self.test_shape = paramak.BlanketConstantThicknessArcV( inner_lower_point=(300, -200), inner_mid_point=(500, 0), inner_upper_point=(300, 200), thickness=20, )
def test_BlanketConstantThickness_creation(self): """creates blanket from parametric shape and checks a solid is created""" test_shape = paramak.BlanketConstantThicknessArcV( inner_lower_point=(300,-200), inner_mid_point=(500,0), inner_upper_point=(300,200), thickness=20, rotation_angle = 180 ) assert test_shape.solid is not None assert test_shape.volume > 1000
def test_BlanketConstantThickness_creation(self): """creates a blanket using the BlanketConstantThicknessArcV parametric component and checks that a cadquery solid is created""" test_shape = paramak.BlanketConstantThicknessArcV( inner_lower_point=(300, -200), inner_mid_point=(500, 0), inner_upper_point=(300, 200), thickness=20, rotation_angle=180, ) assert test_shape.solid is not None assert test_shape.volume > 1000
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 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.BlanketConstantThicknessFP( plasma=plasma, thickness=100, stop_angle=90, start_angle=-90, offset_from_plasma=30, rotation_angle=180, stp_filename='blanket_constant_thickness_outboard_plasma.stp') all_components.append(component) component = paramak.BlanketConstantThicknessFP( plasma=plasma, thickness=100, stop_angle=90, start_angle=250, offset_from_plasma=30, rotation_angle=180, stp_filename='blanket_constant_thickness_inboard_plasma.stp') all_components.append(component) component = paramak.BlanketConstantThicknessFP( plasma=plasma, thickness=100, stop_angle=250, start_angle=-90, offset_from_plasma=30, rotation_angle=180, stp_filename='blanket_constant_thickness_plasma.stp') all_components.append(component) component = paramak.ToroidalFieldCoilCoatHanger( horizontal_start_point=(200, 500), horizontal_length=400, vertical_start_point=(700, 50), vertical_length=500, thickness=50, distance=50, stp_filename='toroidal_field_coil_coat_hanger.stp', number_of_coils=5) all_components.append(component) component = paramak.CenterColumnShieldCylinder( inner_radius=80, outer_radius=100, height=300, rotation_angle=rot_angle, stp_filename='center_column_shield_cylinder.stp') all_components.append(component) component = 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(component) component = 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(component) component = 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(component) component = 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(component) component = 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(component) # # component = paramak.DivertorBlock( # major_radius = 800, # minor_radius = 400, # triangularity = 1.2, # elongation = 0.9, # thickness = 50, # offset_from_plasma = 20, # start # ) 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) 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) 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( inner_upper_point=(100, 700), inner_mid_point=(800, 0), inner_lower_point=(100, -700), thickness=150, distance=60, stp_filename='tf_coil_rectangle.stp', number_of_coils=6) all_components.append(component) component = paramak.ITERtypeDivertor( # default parameters rotation_angle=rot_angle, stp_filename='ITER_type_divertor.stp') all_components.append(component) return all_components
def create_components(self): shapes_or_components = [] plasma = paramak.Plasma(major_radius=self.major_radius, minor_radius=self.minor_radius, elongation=self.elongation, triangularity=self.triangularity, rotation_angle=self.rotation_angle) plasma.create_solid() shapes_or_components.append(plasma) # this is the radial build sequence, where one componet stops and another starts inner_bore_start_radius = 0 inner_bore_end_radius = inner_bore_start_radius + self.inner_bore_radial_thickness inboard_tf_coils_start_radius = inner_bore_end_radius inboard_tf_coils_end_radius = inboard_tf_coils_start_radius + self.inboard_tf_leg_radial_thickness center_column_shield_start_radius = inboard_tf_coils_end_radius center_column_shield_end_radius = center_column_shield_start_radius + self.center_column_shield_radial_thickness divertor_start_radius = center_column_shield_end_radius divertor_end_radius = center_column_shield_end_radius + self.divertor_radial_thickness firstwall_start_radius = center_column_shield_end_radius \ + self.inner_plasma_gap_radial_thickness \ + self.plasma_radial_thickness \ + self.outer_plasma_gap_radial_thickness firstwall_end_radius = firstwall_start_radius + self.firstwall_radial_thickness blanket_start_radius = firstwall_end_radius blanket_end_radius = blanket_start_radius + self.blanket_radial_thickness blanket_read_wall_start_radius = blanket_end_radius blanket_read_wall_end_radius = blanket_read_wall_start_radius + self.blanket_rear_wall_radial_thickness #this is the vertical build sequence, componets build on each other in a similar manner to the radial build divertor_start_height = plasma.high_point[ 1] + self.outer_plasma_gap_radial_thickness # make it the same hight as fw, blanket, rw divertor_end_height = divertor_start_height + self.firstwall_radial_thickness + self.blanket_radial_thickness + self.blanket_rear_wall_radial_thickness firstwall_start_height = divertor_start_height firstwall_end_height = firstwall_start_height + self.firstwall_radial_thickness blanket_start_height = firstwall_end_height blanket_end_height = blanket_start_height + self.blanket_radial_thickness blanket_rear_wall_start_height = blanket_end_height blanket_rear_wall_end_height = blanket_rear_wall_start_height + self.blanket_rear_wall_radial_thickness tf_coil_height = blanket_rear_wall_end_height center_column_shield_height = blanket_rear_wall_end_height * 2 if self.pf_coil_vertical_thicknesses != None and self.pf_coil_radial_thicknesses != None and self.pf_coil_to_rear_blanket_radial_gap != None: number_of_pf_coils = len(self.pf_coil_vertical_thicknesses) y_position_step = (2 * (blanket_rear_wall_end_height + self.pf_coil_to_rear_blanket_radial_gap)) / ( number_of_pf_coils + 1) pf_coils_y_values = [] pf_coils_x_values = [] # adds in coils with equal spacing strategy, should be updated to allow user positions for i in range(number_of_pf_coils): y_value = blanket_rear_wall_end_height + self.pf_coil_to_rear_blanket_radial_gap - y_position_step * ( i + 1) x_value = blanket_read_wall_end_radius + self.pf_coil_to_rear_blanket_radial_gap + \ 0.5*self.pf_coil_radial_thicknesses[i] pf_coils_y_values.append(y_value) pf_coils_x_values.append(x_value) pf_coil_start_radius = blanket_read_wall_end_radius + self.pf_coil_to_rear_blanket_radial_gap pf_coil_end_radius = pf_coil_start_radius + max( self.pf_coil_radial_thicknesses) if self.pf_coil_to_tf_coil_radial_gap != None and self.tf_coil_radial_thickness != None: tf_coil_start_radius = pf_coil_end_radius + self.pf_coil_to_rear_blanket_radial_gap tf_coil_end_radius = tf_coil_start_radius + self.tf_coil_radial_thickness if self.rotation_angle < 360: max_high = 3 * center_column_shield_height max_width = 3 * blanket_read_wall_end_radius cutting_slice = paramak.RotateStraightShape( points=[ (0, max_high), (max_width, max_high), (max_width, -max_high), (0, -max_high), ], rotation_angle=360 - self.rotation_angle, azimuth_placement_angle=360 - self.rotation_angle) else: cutting_slice = None # shapes_or_components.append(inboard_tf_coils) inboard_tf_coils = paramak.CenterColumnShieldCylinder( height=tf_coil_height * 2, inner_radius=inboard_tf_coils_start_radius, outer_radius=inboard_tf_coils_end_radius, rotation_angle=self.rotation_angle, # color=centre_column_color, stp_filename="inboard_tf_coils.stp", name="inboard_tf_coils", material_tag="inboard_tf_coils_mat", ) shapes_or_components.append(inboard_tf_coils) center_column_shield = paramak.CenterColumnShieldCylinder( height=center_column_shield_height, inner_radius=center_column_shield_start_radius, outer_radius=center_column_shield_end_radius, rotation_angle=self.rotation_angle, # color=centre_column_color, stp_filename="center_column_shield.stp", name="center_column_shield", material_tag="center_column_shield_mat", ) shapes_or_components.append(center_column_shield) space_for_divertor = plasma.high_point[ 0] - center_column_shield_end_radius #add blanket if the divertor doesn't take up all the space if space_for_divertor > self.divertor_radial_thickness: print( 'making extra blanket as there is space between the divertor and existing blanket' ) extra_blanket_upper = paramak.RotateStraightShape( points=[ (divertor_end_radius, blanket_start_height), (divertor_end_radius, blanket_end_height), (plasma.high_point[0], blanket_end_height), (plasma.high_point[0], blanket_start_height), ], rotation_angle=self.rotation_angle, stp_filename='extra_blanket_upper.stp', name='extra_blanket_upper', material_tag='blanket_mat') shapes_or_components.append(extra_blanket_upper) extra_firstwall_upper = paramak.RotateStraightShape( points=[ (divertor_end_radius, firstwall_start_height), (divertor_end_radius, firstwall_end_height), (plasma.high_point[0], firstwall_end_height), (plasma.high_point[0], firstwall_start_height), ], rotation_angle=self.rotation_angle, stp_filename='extra_firstwall_upper.stp', name='extra_firstwall_upper', material_tag='firstwall_mat') shapes_or_components.append(extra_firstwall_upper) extra_blanket_rear_wall_upper = paramak.RotateStraightShape( points=[ (divertor_end_radius, blanket_rear_wall_start_height), (divertor_end_radius, blanket_rear_wall_end_height), (plasma.high_point[0], blanket_rear_wall_end_height), (plasma.high_point[0], blanket_rear_wall_start_height), ], rotation_angle=self.rotation_angle, stp_filename='extra_blanket_rear_wall_upper.stp', name='extra_blanket_rear_wall_upper', material_tag='blanket_rear_wall_mat') shapes_or_components.append(extra_blanket_rear_wall_upper) extra_blanket_lower = paramak.RotateStraightShape( points=[ (divertor_end_radius, -blanket_start_height), (divertor_end_radius, -blanket_end_height), (plasma.high_point[0], -blanket_end_height), (plasma.high_point[0], -blanket_start_height), ], rotation_angle=self.rotation_angle, stp_filename='extra_blanket_lower.stp', name='extra_blanket_lower', material_tag='blanket_mat') shapes_or_components.append(extra_blanket_lower) extra_firstwall_lower = paramak.RotateStraightShape( points=[ (divertor_end_radius, -firstwall_start_height), (divertor_end_radius, -firstwall_end_height), (plasma.high_point[0], -firstwall_end_height), (plasma.high_point[0], -firstwall_start_height), ], rotation_angle=self.rotation_angle, stp_filename='extra_firstwall_lower.stp', name='extra_firstwall_lower', material_tag='firstwall_mat') shapes_or_components.append(extra_firstwall_lower) extra_blanket_rear_wall_lower = paramak.RotateStraightShape( points=[ (divertor_end_radius, -blanket_rear_wall_start_height), (divertor_end_radius, -blanket_rear_wall_end_height), (plasma.high_point[0], -blanket_rear_wall_end_height), (plasma.high_point[0], -blanket_rear_wall_start_height), ], rotation_angle=self.rotation_angle, stp_filename='extra_blanket_rear_wall_lower.stp', name='extra_blanket_rear_wall_lower', material_tag='blanket_rear_wall_mat') shapes_or_components.append(extra_blanket_rear_wall_lower) divertor_upper_part = paramak.RotateStraightShape( points=[ (divertor_start_radius, divertor_end_height), (divertor_start_radius, divertor_start_height), (divertor_end_radius, divertor_start_height), (divertor_end_radius, divertor_end_height), ], stp_filename='divertor_upper.stp', name='divertor_upper', rotation_angle=self.rotation_angle, material_tag='divertor_mat') shapes_or_components.append(divertor_upper_part) # negative signs used as this is in the negative side of the Z axis divertor_lower_part = paramak.RotateStraightShape( points=[ (divertor_start_radius, -divertor_end_height), (divertor_start_radius, -divertor_start_height), (divertor_end_radius, -divertor_start_height), (divertor_end_radius, -divertor_end_height), ], stp_filename='divertor_lower.stp', name='divertor_lower', rotation_angle=self.rotation_angle, material_tag='divertor_mat') shapes_or_components.append(divertor_lower_part) # curve divertor arround if it is larger than the horitonal space provided elif self.divertor_radial_thickness > space_for_divertor: length_of_curved_section = self.divertor_radial_thickness - space_for_divertor center_point, radius = paramak.utils.find_center_point_of_circle( point1=(firstwall_start_radius, 0), point2=(plasma.high_point[0], firstwall_start_height), point3=(plasma.low_point[0], -firstwall_start_height)) circumference = 2. * math.pi * radius rotation_angle = (length_of_curved_section * 2 * math.pi) / circumference new_point_x1, new_point_y1 = paramak.utils.rotate( center_point, (plasma.high_point[0], firstwall_start_height), -rotation_angle / 2.) new_point_x2, new_point_y2 = paramak.utils.rotate( center_point, (plasma.high_point[0], firstwall_start_height), -rotation_angle) new_point_x3, new_point_y3 = paramak.utils.rotate( center_point, (plasma.high_point[0], blanket_rear_wall_end_height), -rotation_angle) new_point_x4, new_point_y4 = paramak.utils.rotate( center_point, (plasma.high_point[0], blanket_rear_wall_end_height), -rotation_angle / 2.) divertor_upper_part = paramak.RotateMixedShape( points=[ (divertor_start_radius, divertor_end_height, 'straight'), (divertor_start_radius, divertor_start_height, 'straight'), (divertor_start_radius + space_for_divertor, divertor_start_height, 'circle'), (new_point_x1, new_point_y1, 'circle'), (new_point_x2, new_point_y2, 'straight'), (new_point_x3, new_point_y3, 'circle'), (new_point_x4, new_point_y4, 'circle'), (divertor_start_radius + space_for_divertor, divertor_end_height, 'straight'), ], stp_filename='divertor_upper.stp', name='divertor_upper', rotation_angle=self.rotation_angle, material_tag='divertor_mat') shapes_or_components.append(divertor_upper_part) # negative signs used as this is in the negative side of the Z axis divertor_lower_part = paramak.RotateMixedShape( points=[ (divertor_start_radius, -divertor_end_height, 'straight'), (divertor_start_radius, -divertor_start_height, 'straight'), (divertor_start_radius + space_for_divertor, -divertor_start_height, 'circle'), (new_point_x1, -new_point_y1, 'circle'), (new_point_x2, -new_point_y2, 'straight'), (new_point_x3, -new_point_y3, 'circle'), (new_point_x4, -new_point_y4, 'circle'), (divertor_start_radius + space_for_divertor, -divertor_end_height, 'straight'), ], stp_filename='divertor_lower.stp', name='divertor_lower', rotation_angle=self.rotation_angle, material_tag='divertor_mat') shapes_or_components.append(divertor_lower_part) elif self.divertor_radial_thickness == space_for_divertor: divertor_upper_part = paramak.RotateMixedShape( points=[ (divertor_start_radius, divertor_end_height, 'straight'), (divertor_start_radius, divertor_start_height, 'straight'), (divertor_start_radius + space_for_divertor, divertor_start_height, 'straight'), (divertor_start_radius + space_for_divertor, divertor_end_height, 'straight'), ], stp_filename='divertor_upper.stp', name='divertor_upper', rotation_angle=self.rotation_angle, material_tag='divertor_mat') shapes_or_components.append(divertor_upper_part) # negative signs used as this is in the negative side of the Z axis divertor_lower_part = paramak.RotateMixedShape( points=[ (divertor_start_radius, -divertor_end_height, 'straight'), (divertor_start_radius, -divertor_start_height, 'straight'), (divertor_start_radius + space_for_divertor, -divertor_start_height, 'straight'), (divertor_start_radius + space_for_divertor, -divertor_end_height, 'straight'), ], stp_filename='divertor_lower.stp', name='divertor_lower', rotation_angle=self.rotation_angle, material_tag='divertor_mat') shapes_or_components.append(divertor_lower_part) firstwall = paramak.BlanketConstantThicknessArcV( inner_mid_point=(firstwall_start_radius, 0), inner_upper_point=(plasma.high_point[0], firstwall_start_height), inner_lower_point=(plasma.low_point[0], -firstwall_start_height), thickness=self.firstwall_radial_thickness, rotation_angle=self.rotation_angle, stp_filename='firstwall.stp', name='firstwall', material_tag='firstwall_mat', cut=[divertor_lower_part, divertor_upper_part]) shapes_or_components.append(firstwall) blanket = paramak.BlanketConstantThicknessArcV( inner_mid_point=(blanket_start_radius, 0), inner_upper_point=(plasma.high_point[0], blanket_start_height), inner_lower_point=(plasma.low_point[0], -blanket_start_height), thickness=self.blanket_radial_thickness, rotation_angle=self.rotation_angle, stp_filename='blanket.stp', name='blanket', material_tag='blanket_mat', cut=[divertor_lower_part, divertor_upper_part]) shapes_or_components.append(blanket) blanket_rear_casing = paramak.BlanketConstantThicknessArcV( inner_mid_point=(blanket_read_wall_start_radius, 0), inner_upper_point=(plasma.high_point[0], blanket_rear_wall_start_height), inner_lower_point=(plasma.low_point[0], -blanket_rear_wall_start_height), thickness=self.blanket_rear_wall_radial_thickness, rotation_angle=self.rotation_angle, stp_filename='blanket_rear_wall.stp', name='blanket_rear_wall', material_tag='blanket_rear_wall_mat', cut=[divertor_lower_part, divertor_upper_part]) shapes_or_components.append(blanket_rear_casing) if self.pf_coil_vertical_thicknesses != None and self.pf_coil_radial_thicknesses != None and self.pf_coil_to_rear_blanket_radial_gap != None: for i, (rt, vt, y_value, x_value) in enumerate( zip( self.pf_coil_radial_thicknesses, self.pf_coil_vertical_thicknesses, pf_coils_y_values, pf_coils_x_values, )): pf_coil = paramak.PoloidalFieldCoil( width=rt, height=vt, center_point=(x_value, y_value), rotation_angle=self.rotation_angle, stp_filename='pf_coil_' + str(i) + '.stp', name='pf_coil', material_tag='pf_coil_mat') shapes_or_components.append(pf_coil) if self.pf_coil_to_tf_coil_radial_gap != None and self.tf_coil_radial_thickness != None: tf_coil = paramak.ToroidalFieldCoilRectangle( inner_upper_point=(inboard_tf_coils_start_radius, tf_coil_height), inner_lower_point=(inboard_tf_coils_start_radius, -tf_coil_height), inner_mid_point=(tf_coil_start_radius, 0), thickness=self.tf_coil_radial_thickness, number_of_coils=self.number_of_tf_coils, distance=self.tf_coil_poloidal_thickness, cut=cutting_slice) shapes_or_components.append(tf_coil) self.shapes_and_components = shapes_or_components