def run_reference_simulation(d, solver):
tube = receiver.Tube(ro, ro - ri, h, nr, nt, nz)
tube.set_times(times)
if d == 1:
tube.make_1D(0, 0)
elif d == 2:
tube.make_2D(0)
R, T, Z = tube.mesh
X = R * np.cos(T)
Y = R * np.sin(T)
Ts = temperature(times, X, Y,
Z).reshape((len(times), ) + tube.dim[:tube.ndim])
tube.add_results("temperature", Ts)
tube.set_pressure_bc(receiver.PressureBC(times, pressure(times)))
solver.setup_tube(tube)
state_n = solver.init_state(tube, mat)
for i in range(1, len(tube.times)):
state_np1 = solver.solve(tube, i, state_n, 0.0)
solver.dump_state(tube, i, state_np1)
state_n = state_np1
return tube
def setUp(self):
self.ro = 5
self.ri = 4.5
self.h = 2.5
self.nr = 10
self.nt = 20
self.nz = 5
self.E = 150000.0
self.nu = 0.35
self.tube = receiver.Tube(self.ro, self.ro - self.ri, self.h, self.nr,
self.nt, self.nz)
self.times = np.array([0, 1])
self.tube.set_times(self.times)
self.tube.set_pressure_bc(
receiver.PressureBC(self.times, self.times / 50.0))
self.mat = parse.parse_xml(
os.path.join(os.path.dirname(__file__), "moose-verification",
"model.xml"),
"creeping",
)
self.d = 0.25
self.solver = structural.PythonTubeSolver(verbose=False)
def setUp(self):
self.ro = 5
self.ri = 4.5
self.h = 2.5
self.nr = 10
self.nt = 20
self.nz = 5
self.E = 150000.0
self.nu = 0.35
self.tube = receiver.Tube(self.ro, self.ro - self.ri, self.h, self.nr,
self.nt, self.nz)
self.times = np.array([0, 1])
self.tube.set_times(self.times)
self.tube.set_pressure_bc(
receiver.PressureBC(self.times, self.times * 0))
self.emodel = elasticity.IsotropicLinearElasticModel(
self.E, "youngs", self.nu, "poissons")
self.mat = models.SmallStrainElasticity(self.emodel)
self.d = 0.25
self.force_exact = (np.pi * (self.ro**2.0 - self.ri**2.0) * self.E *
self.d / self.h)
self.stiffness_exact = (np.pi * (self.ro**2.0 - self.ri**2.0) *
self.E / self.h)
self.solver = structural.PythonTubeSolver(verbose=False)
def make_tube(self, dim, nr=15, nt=30, nz=5):
tube = receiver.Tube(self.ro, self.ro - self.ri, self.h, nr, nt, nz)
if dim == 1:
tube.make_1D(self.h / 2, 0)
elif dim == 2:
tube.make_2D(self.h / 2)
times = np.array([0, 1])
tube.set_times(times)
R, _, _ = tube.mesh
Ts = np.zeros((2, ) + R.shape[:dim])
Ts[1] = self.T(R)
tube.add_results("temperature", Ts)
if self.p != 0:
tube.set_pressure_bc(receiver.PressureBC(times, times * self.p))
return tube
def gen_tube(k, tforce, tube_length, tube_ri, E, alpha, nr=5):
emodel = elasticity.IsotropicLinearElasticModel(E, "youngs", 0.25,
"poissons")
mmodel = models.SmallStrainElasticity(emodel, alpha=alpha)
solver = structural.PythonTubeSolver(atol=1.0e-4)
ro = np.sqrt(tube_length * k / (np.pi * E) + tube_ri**2.0)
A = np.pi * (ro**2.0 - tube_ri**2.0)
tube = receiver.Tube(ro, ro - tube_ri, tube_length, nr, 1, 1)
tube.set_times(np.array([0, 1.0]))
tube.make_1D(tube_length / 2.0, 0)
dT = tforce / (E * alpha * A)
temp = np.zeros((2, nr))
temp[1] = dT
tube.add_results("temperature", temp)
tube.set_pressure_bc(
receiver.PressureBC(np.array([0, 1]), np.array([0, 0])))
return spring.TubeSpring(tube, solver, mmodel)
def valid_pressure_bc():
return receiver.PressureBC(times, np.zeros((len(times), )))
# Various meshes needed to define the boundary conditions
# 1) A mesh over the times and height (for the fluid temperatures)
time_h, z_h = np.meshgrid(times, np.linspace(0,height,nz), indexing='ij')
# 2) A surface mesh over the outer surface (for the flux)
time_s, theta_s, z_s = np.meshgrid(times, np.linspace(0,2*np.pi,nt+1)[:nt],
np.linspace(0,height,nz), indexing = 'ij')
# Setup each tube in turn and assign it to the correct panel
# Tube 0
tube_0 = receiver.Tube(r_outer, thickness, height, nr, nt, nz, T0 = T_base)
tube_0.set_times(times)
tube_0.set_bc(receiver.ConvectiveBC(r_outer-thickness,
height, nz, times, fluid_temp(time_h,z_h)), "inner")
tube_0.set_bc(receiver.HeatFluxBC(r_outer, height,
nt, nz, times, h_flux(time_s, theta_s, z_s) * h_tube_0), "outer")
tube_0.set_pressure_bc(receiver.PressureBC(times, pressure(times)))
# Tube 1
tube_1 = receiver.Tube(r_outer, thickness, height, nr, nt, nz, T0 = T_base)
tube_1.set_times(times)
tube_1.set_bc(receiver.ConvectiveBC(r_outer-thickness,
height, nz, times, fluid_temp(time_h,z_h)), "inner")
tube_1.set_bc(receiver.HeatFluxBC(r_outer, height,
nt, nz, times, h_flux(time_s, theta_s, z_s) * h_tube_1), "outer")
tube_1.set_pressure_bc(receiver.PressureBC(times, pressure(times)))
# Tube 2
tube_2 = receiver.Tube(r_outer, thickness, height, nr, nt, nz, T0 = T_base)
tube_2.set_times(times)
tube_2.set_bc(receiver.ConvectiveBC(r_outer-thickness,
height, nz, times, fluid_temp(time_h,z_h)), "inner")
