Exemplo n.º 1
0
def protected_steel():
    from sfeprapy.func.temperature_steel_section import protected_steel_eurocode as steel
    from sfeprapy.func.temperature_fires import standard_fire_iso834 as fire
    from sfeprapy.dat.steel_carbon import Thermal
    import matplotlib.pyplot as plt
    import numpy as np

    steel_prop = Thermal()
    c = steel_prop.c()
    rho = 7850
    t, T = fire(np.arange(0, 10080, 60), 20 + 273.15)

    for d_p in np.arange(0.001, 0.2 + 0.02, 0.02):
        t_s, T_s, d = steel(time=t,
                            temperature_ambient=T,
                            rho_steel=rho,
                            c_steel_T=c,
                            area_steel_section=0.017,
                            k_protection=0.2,
                            rho_protection=800,
                            c_protection=1700,
                            thickness_protection=d_p,
                            perimeter_protected=2.14)
        plt.plot(t_s, T_s, label="d_p={:5.3f}".format(d_p))

    plt.legend(loc=1)
    plt.show()
Exemplo n.º 2
0
def travelling_fire():
    from sfeprapy.func.temperature_fires import travelling_fire as fire

    time, temperature, data = fire(T_0=293.15,
                                   q_fd=900e6,
                                   RHRf=0.15e6,
                                   l=150,
                                   w=17.4,
                                   s=0.012,
                                   h_s=3.5,
                                   l_s=105,
                                   time_step=1200,
                                   time_ubound=22080)

    benchmark_time = [
        0, 1200, 2400, 3600, 4800, 6000, 7200, 8400, 9600, 10800, 12000, 13200,
        14400, 15600, 16800, 18000, 19200, 20400, 21600, 22800
    ]
    benchmark_temperature = [
        293, 374, 428, 481, 534, 592, 643, 722, 870, 1288, 1323, 1071, 773,
        592, 454, 293, 293, 293, 293, 293
    ]

    # Load data

    # Calculate least square against the referenced data
    x1 = time
    y1 = temperature
    x2 = benchmark_time
    y2 = benchmark_temperature

    print('Check least squares < 10: {}'.format(
        least_square(x1, y1, x2, y2) < 10))
Exemplo n.º 3
0
def iso834():
    import pandas as pd
    from sfeprapy.func.temperature_fires import standard_fire_iso834 as fire
    import numpy as np
    t = np.arange(0, 30*60, 5)
    res = {}
    res["TIME"], res["TEMPERATURE"] = fire(t, 273.15)
    res["TEMPERATURE"] -= 273.15
    df = pd.DataFrame(res)
    df.to_csv("out.csv", index=False)
Exemplo n.º 4
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def t_square():
    import pandas as pd
    import numpy as np
    from sfeprapy.func.temperature_fires import t_square as fire

    growth = "fast"
    cap_time = 300

    dict_res = dict()
    dict_res["TIME [s]"] = np.arange(0, 30*60, 5)
    dict_res["HRR [kW]"] = fire(dict_res["TIME [s]"], growth, cap_hrr_to_time=cap_time) / 1000
    df = pd.DataFrame(dict_res)
    df = df[["TIME [s]", "HRR [kW]"]]
    df.to_csv("fire "+growth+str(cap_time)+".csv", index=False)
Exemplo n.º 5
0
def protected_steel2():
    """
    This test is for protected steel in eurocode under parametric fire curve.
    """
    import copy
    import matplotlib.pyplot as plt
    from sfeprapy.func.temperature_fires import parametric_eurocode1 as fire
    from sfeprapy.func.temperature_steel_section import protected_steel_eurocode as steel
    from sfeprapy.dat.steel_carbon import Thermal

    steel_prop = Thermal()
    c = steel_prop.c()
    rho = steel_prop.rho()

    kwargs_fire = {
        "A_t": 360,
        "A_f": 100,
        "A_v": 72,
        "h_eq": 1,
        "q_fd": 600e6,
        "lambda_": 1,
        "rho": 1,
        "c": 2250000,
        "t_lim": 20 * 60,
        "time_end": 2 * 60 * 60,
        "time_step": 1,
        "time_start": 0,
        "temperature_initial": 293.15
    }
    time_fire, temp_fire = fire(**kwargs_fire)

    kwargs_steel = {
        "time": time_fire,
        "temperature_ambient": temp_fire,
        "rho_steel_T": rho,
        "c_steel_T": c,
        "area_steel_section": 0.017,
        "k_protection": 0.2,
        "rho_protection": 800,
        "c_protection": 1700,
        "thickness_protection": 0.01,
        "perimeter_protected": 2.14
    }
    time_steel, temp_steel, c = steel(**kwargs_steel)

    plt.plot(time_fire, temp_fire)
    plt.plot(time_steel, temp_steel)
    plt.show()
Exemplo n.º 6
0
def travelling_fire():
    from sfeprapy.func.temperature_fires import travelling_fire as fire
    import matplotlib.pyplot as plt
    import numpy as np
    time, temperature, data = fire(
        T_0=293.15,
        q_fd=900e6,
        RHRf=0.15e6,
        l=150,
        w=17.4,
        s=0.012,
        h_s=3.5,
        l_s=105,
        time_step=60,
        time_ubound=22080
    )
    fig, ax = plt.subplots()
    ax.plot(time/60, temperature-273.15)
    ax.set_xlabel('Time [min]')
    ax.set_ylabel('Temperature [C]')
    ax.set_xticks(np.arange(0, 361, 30))
    ax.set_yticks(np.arange(0, 1201, 100))
    plt.show()
Exemplo n.º 7
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def parametric_fire():
    import copy
    import numpy as np
    import matplotlib.pyplot as plt
    from sfeprapy.func.temperature_fires import parametric_eurocode1 as fire

    kwargs = {"A_t": 360,
              "A_f": 100,
              "A_v": 72,
              "h_eq": 1,
              "q_fd": 600e6,
              "lambda_": 1,
              "rho": 1,
              "c": 2250000,
              "t_lim": 20*60,
              "time_end": 2*60*60,
              "time_step": 1,
              "time_start": 0,
              "temperature_initial": 293.15}

    fig, ax = plt.subplots()

    for i in [72, 50.4, 36.000000001, 32.4, 21.6, 14.4, 7.2]:
        if i == 36:
            print("stop")
        kwargs["A_v"] = i
        x, y = fire(**copy.copy(kwargs))
        ax.plot(x/60, y-273.15, label="O={:03.2f}".format(kwargs["A_v"]*kwargs["h_eq"]**0.5/kwargs["A_t"]))

    ax.set_xlabel('Time [min]')
    ax.set_ylabel('Temperature [C]')
    ax.set_xticks(np.arange(0, 121, 10))
    ax.set_yticks(np.arange(0, 1201, 100))
    ax.grid(True)
    plt.legend(loc=1)
    plt.show()
    return 0
Exemplo n.º 8
0
def test_eurocode_parametric_fire():
    """
    NAME: _test_eurocode_parametric_fire
    AUTHOR: yan fu
    VERSION: 0.0.1
    DATE: 1 Oct 2018
    DESCRIPTION:
    This function verifies sfeprapy.func.temperature_fires.parametric_eurocode1 based on figure 7 in the referenced
    document below.
    Holicky, M., Meterna, A., Sedlacek, G. and Schleich, J.B., 2005. Implementation of eurocodes, handbook 5, design of
    buildings for the fire situation. Leonardo da Vinci Pilot Project: Luxemboug.

    :return:
    """

    import copy, pandas, os
    import numpy as np
    from sfeprapy.func.temperature_fires import parametric_eurocode1 as fire

    kwargs = {
        "A_t": 360,
        "A_f": 100,
        # "A_v": 72,
        "h_eq": 1,
        "q_fd": 600e6,
        "lambda_": 1,
        "rho": 1,
        "c": 2250000,
        "t_lim": 20 * 60,
        "time_end": 2 * 60 * 60,
        "time_step": 1,
        "time_start": 0,
        "temperature_initial": 293.15
    }

    # define opening area
    A_v_list = [72, 50.4, 36.000000001, 32.4, 21.6, 14.4, 7.2]

    # Calculate fire curves
    x1_list = []  # calculated time array
    y1_list = []  # calculated temperature array
    for i in A_v_list:
        x, y = fire(A_v=i, **copy.copy(kwargs))
        x += 10 * 60
        x1_list.append(x / 60)
        y1_list.append(y - 273.15)

    # Validation data
    # Load data

    verification_data = pandas.read_csv(
        os.path.join(os.path.dirname(os.path.realpath(__file__)),
                     'ec_parametric_fire_verification_data.csv'))

    # Calculate least square against the referenced data
    for i in range(len(A_v_list)):
        x1 = x1_list[i]
        y1 = y1_list[i]
        x2 = verification_data['time_{}'.format(int(i + 1))]
        y2 = verification_data['temperature_{}'.format(int(i + 1))]

        assert least_square(x1, y1, x2, y2) < 100

    return 0