f_arr_full = np.zeros(
(len(l_wire_list), len(exp_list), len(T_cracker_list), 6))
for n_lw, l_wire in enumerate(l_wire_list):
for n_phi, phi_exp in enumerate(exp_list):
for n_T, T_cracker in enumerate(T_cracker_list):
run_name = "lw_{}_phi_{}_Tc_{}".format(l_wire, phi_exp, T_cracker)
wire = Wire()
wire = wire.load(top_dir + "results\\" + run_name)
wire.plot_heat_flow(top_dir + "plots\\" +
"heat_flow/log_{}".format(run_name),
log_y=True)
i = wire.n_wire_elements // 2
elem = [
wire.f_el(i),
wire.f_conduction(i),
wire.f_rad(i),
wire.f_beam(i),
wire.f_beam_gas(i),
wire.f_bb(i)
]
f_arr_full[n_lw, n_phi, n_T] = elem
# Plot scaling of Heat flow with temperature with various
if True:
for n_lw, l_wire in enumerate(l_wire_list):
for n_phi, phi_exp in enumerate(exp_list):
fig = plt.figure(0, figsize=(8, 6.5))
ax1 = plt.gca()
label_list = [
r"$F_{el}$", r"$F_{conduction}$", r"$F_{rad}$", r"$F_{beam}$",
r"$F_{beam gas}$", r"$F_{bb cracker}$"
1000 * ((i + 0.5) * wire.l_segment - (wire.l_wire / 2))
for i in range(wire.n_wire_elements)
]
t_lst = wire.record_dict["time"]
f_el_arr = np.zeros((record_steps + 1, wire.n_wire_elements))
f_conduction_arr = np.zeros((record_steps + 1, wire.n_wire_elements))
f_rad_arr = np.zeros((record_steps + 1, wire.n_wire_elements))
f_beam_arr = np.zeros((record_steps + 1, wire.n_wire_elements))
for i, time in enumerate(wire.record_dict["time"]):
wire.T_distribution = wire.record_dict["T_distribution"][i]
f_el_arr[i] = [wire.f_el(j) for j in range(wire.n_wire_elements)]
f_conduction_arr[i] = [
wire.f_conduction(j) for j in range(wire.n_wire_elements)
]
f_rad_arr[i] = [wire.f_rad(j) for j in range(wire.n_wire_elements)]
f_beam_arr[i] = [wire.f_beam(j) for j in range(wire.n_wire_elements)]
#Heat flow in ohmic heating lead up
t_lst_0 = wire_no_beam.record_dict["time"]
f_el_arr_0 = np.zeros((record_steps + 1, wire.n_wire_elements))
f_conduction_arr_0 = np.zeros((record_steps + 1, wire.n_wire_elements))
f_rad_arr_0 = np.zeros((record_steps + 1, wire.n_wire_elements))
f_beam_arr_0 = np.zeros((record_steps + 1, wire.n_wire_elements))
for i, time in enumerate(wire_no_beam.record_dict["time"]):
wire_no_beam.T_distribution = wire_no_beam.record_dict["T_distribution"][i]
f_el_arr_0[i] = [wire_no_beam.f_el(j) for j in range(wire.n_wire_elements)]
f_conduction_arr_0[i] = [
wire_no_beam.f_conduction(j) for j in range(wire.n_wire_elements)
]
f_rad_arr_0[i] = [
T_avg = T_avg_arr[n_d, n_p] = np.average(
wire.record_dict["T_distribution"][-1])
if True:
# Calculate endstate of heat flow
x_lst = [
1000 * ((i + 0.5) * wire.l_segment - (wire.l_wire / 2))
for i in range(wire.n_wire_elements)
]
wire.T_distribution = wire.record_dict["T_distribution"][-1]
f_el_arr = [wire.f_el(j) for j in range(wire.n_wire_elements)]
f_conduction_arr = [
wire.f_conduction(j) for j in range(wire.n_wire_elements)
]
f_rad_arr = [
wire.f_rad(j) for j in range(wire.n_wire_elements)
]
f_beam_arr = [
wire.f_beam(j) for j in range(wire.n_wire_elements)
]
# Plot endstate of heat flow
fig = plt.figure(0, figsize=(8, 6.5))
ax1 = plt.gca()
ax1.plot(x_lst, f_el_arr, "-", label=r"$F_{el}$")
ax1.plot(x_lst,
f_conduction_arr,
"-",
label=r"$F_{conduction}$")
ax1.plot(x_lst, f_rad_arr, "-", label=r"$F_{rad}$")
f_arr_full = np.zeros((len(l_wire_list), len(exp_list), len(T_cracker_list)
, 6 ))
for n_lw, l_wire in enumerate(l_wire_list):
for n_phi, phi_exp in enumerate(exp_list):
for n_T, T_cracker in enumerate(T_cracker_list):
run_name = "lw_{}_phi_{}_Tc_{}".format(l_wire,phi_exp,
T_cracker)
wire = Wire()
wire = wire.load(top_dir + "results\\" + run_name)
wire.plot_heat_flow(top_dir + "plots\\"
+ "heat_flow/log_{}".format(run_name)
, log_y = True)
i = wire.n_wire_elements // 2
elem = [wire.f_el(i), wire.f_conduction(i), wire.f_rad(i)
, wire.f_beam(i), wire.f_beam_gas(i), wire.f_bb(i)]
f_arr_full[n_lw, n_phi, n_T] = elem
# Plot scaling of Heat flow with temperature with various
if True:
for n_lw, l_wire in enumerate(l_wire_list):
for n_phi, phi_exp in enumerate(exp_list):
fig = plt.figure(0, figsize=(8,6.5))
ax1=plt.gca()
label_list = [r"$F_{el}$", r"$F_{conduction}$", r"$F_{rad}$"
, r"$F_{beam}$", r"$F_{beam gas}$"
, r"$F_{bb cracker}$"]
color_list = ["C0", "C1", "C2", "C3", "C4", "C5"]
for n_f in [3,4,5]: # f_beam, f_beam_gas, f_bb
T_lst = T_cracker_list
