import numpy as np import matplotlib.pyplot as plt from datetime import datetime begin_time = datetime.now() from models.sun import sun_angles_analytical from models.sun import sun_angles_astropy from models.drag import drag, c_d from models.simple_atmosphere import T_air, p_air, rho_air from input.user_input import * from input.natural_constants import * from astropy.time import Time import astropy.units as u from models.thermal import AirMass # t: simulation time (0 .. t_max) in [s] # utc = Time(start_utc) + t * u.second # current time (UTC) lat = start_lat # deg lon = start_lon # deg date = Time('2020-12-13 12:00:00.000') # INITIALISATION t = 0 h = start_height utc = Time(start_utc) v_z = 0 p_gas = p_air(h) T_gas = T_air(h) T_film = T_gas t_list = [] h_list = [] while t <= t_end and h >= 0: t_list.append(t) h_list.append(h) rho_gas = p_gas/(R_gas * T_gas) # calculate gas density through ideal(!) gas equation V_b = m_gas/rho_gas # calculate balloon volume from current gas mass and gas density if V_b > V_design: V_b = V_design m_gas = V_design * rho_gas else: pass m_gross = m_pl + m_film m_tot = m_pl + m_film + m_gas m_virt = m_tot + c_virt * rho_air(h) * V_b d_b = 1.383 * V_b ** (1/3) # calculate diameter of balloon from its volume L_goreB = 1.914 * V_b ** (1/3) h_b = 0.748 * d_b A_surf = 4.94 * V_b ** (2/3) A_surf1 = 4.94 * V_design ** (2/3) * (1 - np.cos(np.pi * L_goreB/L_goreDesign)) A_eff = 0.65 * A_surf + 0.35 * A_surf1 A_top = np.pi/4 * d_b ** 2 D = drag(c_d, rho_air(h), d_b, v_z) # calculate drag force I = g * V_b * (rho_air(h) - rho_gas) # calculate gross inflation W = g * m_gross # calculate weight (force) F = I - W - D * np.sign(v_z) v_zrel = v_z AZ, ELV = sun_angles_analytical(lat, lon, utc) A_proj = A_top * (0.9125 + 0.0875 * np.cos(np.pi - 2 * np.deg2rad(ELV))) # CALCULATIONS FOR THERMAL MODEL if ELV >= -(180 / np.pi * np.arccos(R_E / (R_E + h))): tau_atm = 0.5 * (np.exp(-0.65 * AirMass(p_air(h), p_0, ELV, h)) + np.exp(-0.095 * AirMass(p_air(h), p_0, ELV, h))) tau_atmIR = 1.716 - 0.5 * (np.exp(-0.65 * p_air(h) / p_0) + np.exp(-0.095 * p_air(h) / p_0)) else: tau_atm = 0 tau_atmIR = 0 doy = int(utc.doy) MA = (357.52911 + 0.98560028 * (utc.jd - 2451545)) % 360 # in degree, reference: see folder "literature" TA = MA + 2 * e * np.sin(np.deg2rad(MA)) + 5 / 4 * e ** 2 * np.sin(np.deg2rad(2 * MA)) I_Sun = 1367.5 * ((1 + e * np.cos(np.deg2rad(TA))) / (1 - e ** 2)) ** 2 I_SunZ = I_Sun * tau_atm q_sun = I_SunZ q_IRground = epsilon_ground * sigma * T_ground ** 4 q_IREarth = q_IRground * tau_atmIR if ELV <= 0: q_Albedo = 0 else: q_Albedo = Albedo * I_Sun * np.sin(np.deg2rad(ELV)) my_air = (1.458 * 10 ** -6 * T_air(h) ** 1.5) / (T_air(h) + 110.4) my_gas = 1.895 * 10 ** -5 * (T_gas / 273.15) ** 0.647 k_air = 0.0241 * (T_air(h) / 273.15) ** 0.9 k_gas = 0.144 * (T_gas / 273.15) ** 0.7 Pr_air = 0.804 - 3.25 * 10 ** (-4) * T_air(h) Pr_gas = 0.729 - 1.6 * 10 ** (-4) * T_gas Gr_air = (rho_air(h) ** 2 * g * np.abs(T_film - T_air(h)) * d_b ** 3) / (T_air(h) * my_air ** 2) Nu_air = 2 + 0.45 * (Gr_air * Pr_air) ** 0.25 HC_free = Nu_air * k_air / d_b Re = np.abs(v_zrel) * d_b * rho_air(h) / my_air HC_forced = k_air / d_b * (2 + 0.41 * Re ** 0.55) HC_internal = 0.13 * k_gas * ((rho_gas ** 2 * g * np.abs(T_film - T_gas) * Pr_gas) / (T_gas * my_air ** 2)) ** ( 1 / 3) HC_external = np.maximum(HC_free, HC_forced) HalfConeAngle = np.arcsin(R_E / (R_E + h)) ViewFactor = (1 - np.cos(HalfConeAngle)) / 2 Q_Sun = alpha_VIS * A_proj * q_sun * (1 + tau_VIS / (1 - r_VIS)) Q_Albedo = alpha_VIS * A_surf * q_Albedo * ViewFactor * (1 + tau_VIS / (1 - r_VIS)) Q_IREarth = alpha_IR * A_surf * q_IREarth * ViewFactor * (1 + tau_IR / (1 - r_IR)) Q_IRfilm = sigma * epsilon * alpha_IR * A_surf * T_film ** 4 * 1 / (1 - r_IR) Q_IRout = sigma * epsilon * A_surf * T_film ** 4 * (1 * tau_IR / (1 - r_IR)) Q_ConvExt = HC_external * A_eff * (T_air(h) - T_film) Q_ConvInt = HC_internal * A_eff * (T_film - T_gas) RoC = -v_z dT_gas = (Q_ConvInt / (gamma * m_gas * c_v) - (gamma - 1) / gamma * rho_air(h) * g / (rho_gas * R_gas) * RoC) * dt dT_film = ((Q_Sun + Q_Albedo + Q_IREarth + Q_IRfilm + Q_ConvExt - Q_ConvInt - Q_IRout) / (c_f * m_film)) * dt ### dv_z = F/m_virt * dt # velocity increment v_z += dv_z * dt # velocity differential h += v_z * dt # altitude differential p_gas = p_air(h) T_gas = T_gas + dT_gas * dt T_film = T_film + dT_film * dt t += dt # time increment utc = Time(start_utc) + t * u.second plt.plot(t_list, h_list) plt.show()