d_wire = d * 10**-6, emissivity = 0.3, l_wire=l_wire*10**-2, beam_shape="Flat", l_beam = l_beam* 10**-2, T_cracker = T_cracker,T_atoms = T_cracker, phi_beam= (A_beam/ 10**-4) * 10**phi_exp, # Normalized to cm**2 T_base=wire_no_beam.record_dict["T_distribution"][-1] ) wire.simulate(n_steps=n_steps, record_steps=record_steps, time_step=time_step) run_name = "lw_{}_phi_{}_Tc_{}".format(l_wire,phi_exp, T_cracker) os.makedirs(plot_dir + "signal/", exist_ok=True) os.makedirs(plot_dir + "R_over_t/", exist_ok=True) wire.plot_signal(plot_dir + "signal/{}".format(run_name)) wire.plot_R_over_t(plot_dir + "R_over_t/{}".format(run_name)) os.makedirs(plot_dir + "heat_flow/", exist_ok=True) wire.plot_heat_flow(plot_dir + "heat_flow/{}".format(run_name)) wire.save(results_dir + "{}".format(run_name)) time_after = time() run_time = time_after - time_before print("finished run: " + run_name + "time required: " + "{0:.2f} minutes".format(run_time/60)) print("total time elapsed: {0:.2f} minutes".format( (time() - start_time)/60.0))
T_base=None ### ) # Run the Simulation n_steps = 20000 record_steps = 1000 time_step = 0.001 wire_no_beam.simulate(n_steps=n_steps, record_steps=record_steps, time_step=time_step) # simulate with beam on wire = Wire(n_wire_elements=100, k_heat_conductivity=174, i_current=(d / 5)**2 * i_current, d_wire=d * 10**-6, emissivity=0.3, l_wire=5.45 * 10**-2, beam_shape="Gaussian", sigma_beam=6 * 10**-3, phi_beam=10**16, T_base=wire_no_beam.record_dict["T_distribution"][-1]) wire.simulate(n_steps=n_steps, record_steps=record_steps, time_step=time_step) wire.plot_signal(top_dir + "plots/d_wire_{}".format(d)) wire.plot_R_over_t(top_dir + "plots/R_over_t_{}um".format(d)) wire.save(top_dir + "d_wire_{}".format(d))