예제 #1
0
    def get_sim_config(self, sim_config_path):
        """
        Reads the simulation configuration. If not successful, program exits.

        :param sim_config_path: path of json file containing the simulation configuration
        """

        errors_found = False

        # read from JSON file
        try:
            with open(sim_config_path) as json_file:
                self.json_data = json.load(json_file)
        except:  # pragma: no cover
            PrintClass.fatal_error(
                message=
                "Error reading simulation configuration---check file path")

        try:
            try:
                self.aggregation_type = self.json_data[
                    'Simulation Configuration']['Aggregation Type']
            except:  # pragma: no cover
                PrintClass.my_print("....'Aggregation Type' key not found",
                                    "warn")
                errors_found = True

        except:  # pragma: no cover
            PrintClass.fatal_error(
                message="Error reading simulation configuration")

        if errors_found:  # pragma: no cover
            PrintClass.fatal_error(message="Error loading data")
예제 #2
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    def generate_output_reports(self):  # pragma: no cover
        """
        Generates output results
        """

        try:
            PrintClass.my_print("Writing output results")
            cwd = os.getcwd()
            path_to_output_dir = os.path.join(cwd, self.output_path)

            if not os.path.exists(path_to_output_dir):
                os.makedirs(path_to_output_dir)

            # open files
            out_file = open(os.path.join(path_to_output_dir, "GHX.csv"), 'w')

            # write headers
            out_file.write("Hour, BH Temp [C], MFT [C]\n")

            for i in range(len(self.temp_bh)):
                out_file.write("%d, %0.4f, %0.4f\n" %
                               (i + 1, self.temp_bh[i], self.temp_mft[i]))

            # close file
            out_file.close()

            PrintClass.my_print("....Success")

        except:  # pragma: no cover
            PrintClass.fatal_error(message="Error writing output results")
예제 #3
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파일: pipe.py 프로젝트: mitchute/Open-GHX
    def __init__(self, json_data_pipe, json_data_fluid, initial_temp,
                 print_output):

        BasePropertiesClass.__init__(self, json_data_pipe, print_output)

        self.fluid = FluidsClass(json_data_fluid, initial_temp, print_output)

        try:
            self.outer_diameter = json_data_pipe['Outside Diameter']
        except:  # pragma: no cover
            PrintClass.my_print("....'Outside Diameter' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing PipeClass")

        try:
            self.thickness = json_data_pipe['Wall Thickness']
        except:  # pragma: no cover
            PrintClass.my_print("....'Wall Thickness' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing PipeClass")

        self.outer_radius = self.outer_diameter / 2
        self.inner_radius = self.outer_radius - self.thickness
        self.inner_diameter = self.outer_diameter - 2 * self.thickness

        self.resist_pipe_convection = None
        self.resist_pipe_conduction = None
        self.resist_pipe = None

        self.calc_pipe_resistance()
예제 #4
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    def calc_g_func(self):
        """
        Calculate g-functions for given ground heat exchangers.
        """

        try:
            PrintClass.my_print("Calculating g-functions")
            self.g_func_present = True
            PrintClass.my_print("....Success")
        except:  # pragma: no cover
            PrintClass.fatal_error(message="Error calculating g-functions")
예제 #5
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    def __init__(self, json_data, print_output):

        BasePropertiesClass.__init__(self, json_data, print_output)

        try:
            self.undisturbed_temp = json_data['Temperature']
        except:  # pragma: no cover
            PrintClass.my_print("....'Temperature' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing SoilClass")

        self.heat_capacity = self.specific_heat * self.density
        self.thermal_diffusivity = self.conductivity / \
            (self.density * self.specific_heat)
예제 #6
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파일: fluids.py 프로젝트: mitchute/Open-GHX
    def __init__(self, json_data, initial_temp, print_output):

        try:
            self.fluid_type = json_data['Type']
        except:  # pragma: no cover
            PrintClass.my_print("....'Name' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing FluidsClass")

        try:
            self.concentration = json_data['Concentration']
        except:  # pragma: no cover
            PrintClass.my_print("....'Concentration' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing FluidsClass")

        try:
            self.flow_rate = json_data['Flow Rate']
            self.flow_rate_prev = 0.0
        except:  # pragma: no cover
            PrintClass.my_print("....'Flow Rate' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing FluidsClass")

        self.temperature = initial_temp
        self.temperature_prev = None
        self.pressure = 101325
        self.mass_flow_rate = self.calc_mass_flow_rate()
        self.dens_val = self.dens()
        self.cp_val = self.cp()
        self.visc_val = self.visc()
        self.cond_val = self.cond()
        self.pr_val = self.pr()
        self.heat_capacity_val = self.heat_capacity()
예제 #7
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    def __init__(self, json_data, loads_path, output_path, print_output=True):
        """
        Class constructor
        """

        # init base class
        BaseGHXClass.__init__(self, json_data, loads_path,
                              output_path, print_output)

        errors_found = False

        try:
            self.history_depth = json_data['Simulation Configuration']['History Depth']
        except:  # pragma: no cover
            PrintClass.my_print(
                "....'History Depth' key not found", 'warn')
            errors_found = True

        try:
            self.history_expansion_rate = json_data['Simulation Configuration']['History Expansion Rate']
        except:  # pragma: no cover
            PrintClass.my_print("....'History Expansion Rate' key not found", 'warn')
            errors_found = True

        # set load aggregation intervals
        self.set_load_aggregation()

        # pre-calculate all g-functions for load blocks
        self.load_g_functions()

        if not errors_found:
            # success
            PrintClass.my_print("Simulation successfully initialized")
        else:  # pragma: no cover
            PrintClass.fatal_error(message="Error initializing GHXArrayShiftingAggBlocks")
예제 #8
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    def simulate(self):
        """
        Main simulation routine. Simulates the GHXArray object.

        More docs to come...
        """

        PrintClass.my_print("Initializing simulation")

        if self.aggregation_type == "Fixed" or self.aggregation_type == "None":
            GHXArrayFixedAggBlocks(self.json_data, self.loads_path,
                                   self.output_path,
                                   self.print_output).simulate()
        elif self.aggregation_type == "Shifting":
            GHXArrayShiftingAggBlocks(self.json_data, self.loads_path,
                                      self.output_path,
                                      self.print_output).simulate()
        else:
            PrintClass.my_print(
                "\tAggregation Type \"%s\" not found" % self.aggregation_type,
                "warn")
            PrintClass.fatal_error(message="Error starting program")
예제 #9
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    def __init__(self, json_data, loads_path, output_path, print_output=True):
        """
        Constructor for the class.
        """

        PrintClass(print_output, output_path)

        # init base class
        BaseGHXClass.__init__(self, json_data, loads_path, output_path,
                              print_output)

        errors_found = False

        try:
            self.min_hourly_history = json_data['Simulation Configuration'][
                'Min Hourly History']
        except:  # pragma: no cover
            PrintClass.my_print("....'Min Hourly History' key not found",
                                'warn')
            errors_found = True

        try:
            self.agg_load_intervals = json_data['Simulation Configuration'][
                'Intervals']
        except:  # pragma: no cover
            PrintClass.my_print("....'Intervals' key not found", 'warn')
            errors_found = True

        if not errors_found:
            # success
            PrintClass.my_print("Simulation successfully initialized")
        else:  # pragma: no cover
            PrintClass.fatal_error(
                message="Error initializing GHXArrayFixedAggBlocks")

        # class data

        # set load aggregation intervals
        self.set_load_aggregation()

        # set first aggregated load, which is zero. Need this for later
        self.agg_load_objects.append(AggregatedLoadFixed([0], 0, 1, True))

        self.g_func_hourly = deque()
        self.hourly_loads = deque()
예제 #10
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    def __init__(self, json_data, print_output):

        try:
            self.conductivity = json_data['Conductivity']
        except:  # pragma: no cover
            PrintClass.my_print("....'Conductivity' key not found", 'warn')
            PrintClass.fatal_error(
                message="Error initializing BasePropertiesClass")

        try:
            self.specific_heat = json_data['Specific Heat']
        except:  # pragma: no cover
            PrintClass.my_print("....'Specific Heat' key not found", 'warn')
            PrintClass.fatal_error(
                message="Error initializing BasePropertiesClass")

        try:
            self.density = json_data['Density']
        except:  # pragma: no cover
            PrintClass.my_print("....'Density' key not found", 'warn')
            PrintClass.fatal_error(
                message="Error initializing BasePropertiesClass")
예제 #11
0
    def simulate(self):
        """
        More docs to come...
        """

        PrintClass.my_print("Beginning simulation")

        # calculate g-functions if not present
        if not self.g_func_present:
            PrintClass.my_print("G-functions not present", 'warn')
            self.calc_g_func()

        # pre-load hourly g-functions
        for hour in range(self.agg_load_intervals[0] +
                          self.min_hourly_history):
            ln_t_ts = np.log((hour + 1) * 3600 / self.ts)
            self.g_func_hourly.append(self.g_func(ln_t_ts))

        # set aggregate load container max length
        len_hourly_loads = self.min_hourly_history + self.agg_load_intervals[0]
        self.hourly_loads = deque([0] * len_hourly_loads,
                                  maxlen=len_hourly_loads)

        agg_hour = 0
        sim_hour = 0

        for year in range(self.sim_years):
            for month in range(ConstantClass.months_in_year):

                PrintClass.my_print("....Year/Month: %d/%d" %
                                    (year + 1, month + 1))

                for hour in range(ConstantClass.hours_in_month):

                    agg_hour += 1
                    sim_hour += 1

                    # get raw hourly load and append to hourly list
                    curr_index = month * ConstantClass.hours_in_month + hour
                    self.hourly_loads.append(self.sim_loads[curr_index])
                    curr_flow_rate = self.total_flow_rate[curr_index]

                    # update borehole flow rate
                    self.borehole.pipe.fluid.update_fluid_state(
                        new_flow_rate=curr_flow_rate)

                    # calculate borehole resistance
                    self.borehole.calc_bh_resistance()

                    # calculate borehole temp
                    # hourly effects
                    temp_bh_hourly = []
                    temp_mft_hourly = []
                    start_hourly = len(self.hourly_loads) - 1
                    end_hourly = start_hourly - agg_hour
                    g_func_index = -1
                    for i in range(start_hourly, end_hourly, -1):
                        g_func_index += 1
                        q_curr = self.hourly_loads[i]
                        q_prev = self.hourly_loads[i - 1]
                        g = self.g_func_hourly[g_func_index]
                        # calculate average bh temp
                        delta_q = (q_curr - q_prev) / \
                                  (2 * np.pi * self.borehole.soil.conductivity *
                                   self.total_bh_length)
                        temp_bh_hourly.append(delta_q * g)

                        # calculate mean fluid temp
                        g_rb = g + self.borehole.resist_bh

                        if g_rb < 0:
                            g = -self.borehole.resist_bh * 2 * np.pi * self.borehole.soil.conductivity
                            g_rb = g + self.borehole.resist_bh

                        temp_mft_hourly.append(delta_q * g_rb)

                    # aggregated load effects
                    temp_bh_agg = []
                    temp_mft_agg = []
                    if self.agg_loads_flag:
                        for i in range(len(self.agg_load_objects)):
                            if i == 0:
                                continue
                            curr_obj = self.agg_load_objects[i]
                            prev_obj = self.agg_load_objects[i - 1]

                            t_agg = sim_hour - curr_obj.time()
                            ln_t_ts = np.log(t_agg * 3600 / self.ts)
                            g = self.g_func(ln_t_ts)
                            # calculate the average borehole temp
                            delta_q = (curr_obj.q - prev_obj.q) / (
                                2 * np.pi * self.borehole.soil.conductivity *
                                self.total_bh_length)
                            temp_bh_agg.append(delta_q * g)

                            # calculate the mean fluid temp
                            g_rb = g + self.borehole.resist_bh

                            if g_rb < 0:
                                g = -self.borehole.resist_bh * 2 * np.pi * self.borehole.soil.conductivity
                                g_rb = g + self.borehole.resist_bh

                            temp_mft_agg.append(delta_q * g_rb)

                        # aggregate load
                        if agg_hour == self.agg_load_intervals[
                                0] + self.min_hourly_history - 1:
                            # this has one extra value for comparative purposes
                            # need to get rid of it here
                            self.hourly_loads.popleft()

                            # create new aggregated load object
                            self.aggregate_load()

                            # reset aggregation hour to '0'
                            agg_hour -= self.agg_load_intervals[0]

                    # final bh temp
                    self.temp_bh.append(self.borehole.soil.undisturbed_temp +
                                        sum(temp_bh_hourly) + sum(temp_bh_agg))

                    # final mean fluid temp
                    self.temp_mft.append(self.borehole.soil.undisturbed_temp +
                                         sum(temp_mft_hourly) +
                                         sum(temp_mft_agg))

                    # update borehole temperature
                    self.borehole.pipe.fluid.update_fluid_state(
                        new_temp=self.temp_mft[-1])

        self.generate_output_reports()

        PrintClass.my_print("Simulation complete", "success")
        PrintClass.my_print("Simulation time: %0.3f sec" %
                            (timeit.default_timer() - self.timer_start))

        PrintClass.write_log_file()
예제 #12
0
    def __init__(self, json_data, loads_path, output_path, print_output=True):
        """
        Class constructor
        """
        self.timer_start = timeit.default_timer()
        errors_found = False
        self.output_path = output_path

        if not os.path.exists(self.output_path):
            os.makedirs(self.output_path)

        with open(os.path.join(self.output_path, 'in.json'), 'w') as outfile:
            json.dump(json_data, outfile, indent=4, sort_keys=True)

        # load data into data structs
        PrintClass.my_print("....Loading GHX data")

        try:
            self.name = json_data['Name']
        except:  # pragma: no cover
            PrintClass.my_print("....'Name' key not found", 'warn')
            errors_found = True

        try:
            self.sim_years = json_data['Simulation Configuration'][
                'Simulation Years']
        except:  # pragma: no cover
            PrintClass.my_print("....'Simulation Years' key not found", 'warn')
            errors_found = True

        try:
            self.aggregation_type = json_data['Simulation Configuration'][
                'Aggregation Type']
        except:  # pragma: no cover
            PrintClass.my_print("....'Aggregation Type' key not found", 'warn')
            errors_found = True

        try:
            self.g_func_lntts = []
            self.g_func_val = []
            for pair in json_data['G-func Pairs']:
                self.g_func_lntts.append(pair[0])
                self.g_func_val.append(pair[1])
            self.g_func_present = True
        except:  # pragma: no cover
            PrintClass.my_print("....'G-func Pairs' key not found", 'warn')
            self.g_func_present = False

        self.total_bh_length = 0

        self.ghx_list = []
        ghx_dict_list = []

        for json_data_bh in json_data['GHXs']:
            ghx_dict_list.append(json_data_bh)
            this_bh = BoreholeClass(json_data_bh, print_output)
            self.total_bh_length += this_bh.depth
            self.ghx_list.append(this_bh)

        self.borehole = BoreholeClass(self.merge_dicts(ghx_dict_list),
                                      print_output)

        try:
            PrintClass.my_print("....Importing flow rates and loads")
            load_pairs = np.genfromtxt(loads_path,
                                       delimiter=',',
                                       skip_header=1)
            self.sim_hours = []
            self.sim_loads = []
            self.total_flow_rate = []
            for pair in load_pairs:
                self.sim_hours.append(pair[0])
                self.sim_loads.append(pair[1])
                self.total_flow_rate.append(pair[2])
        except:  # pragma: no cover
            PrintClass.fatal_error(message="Error importing loads")

        if errors_found:  # pragma: no cover
            PrintClass.fatal_error(message="Error initializing BaseGHXClass")

        self.ts = self.calc_ts()
        self.temp_bh = deque()
        self.temp_mft = deque()
        self.agg_load_objects = []
        self.agg_loads_flag = True
예제 #13
0
    def __init__(self, json_data, print_output):

        try:
            self.name = json_data['Name']
        except:  # pragma: no cover
            PrintClass.my_print("....'Name' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing BoreholeClass")

        try:
            self.location = json_data['Location']
        except:  # pragma: no cover
            PrintClass.my_print("....'Location' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing BoreholeClass")

        try:
            self.depth = json_data['Depth']
        except:  # pragma: no cover
            PrintClass.my_print("....'Depth' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing BoreholeClass")

        try:
            self.radius = json_data['Radius']
            self.diameter = self.radius * 2
        except:  # pragma: no cover
            PrintClass.my_print("....'Radius' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing BoreholeClass")

        try:
            self.shank_space = json_data['Shank Spacing']
        except:  # pragma: no cover
            PrintClass.my_print("....'Shank Spacing' key not found", 'warn')
            PrintClass.fatal_error(message="Error initializing BoreholeClass")

        self.soil = SoilClass(json_data['Soil'], print_output)
        self.grout = BasePropertiesClass(json_data['Grout'], print_output)
        self.pipe = PipeClass(json_data['Pipe'], json_data['Fluid'],
                              json_data['Soil']['Temperature'], print_output)

        # validate shank spacing
        if self.shank_space > (2 * self.radius - self.pipe.outer_diameter) \
                or self.shank_space < self.pipe.outer_diameter:  # pragma: no cover
            PrintClass.my_print("Invalid shank spacing", 'warn')
            PrintClass.my_print(
                "Check shank spacing, pipe diameter, and borehole radius",
                'warn')
            PrintClass.fatal_error(message="Error initializing BoreholeClass")

        self.resist_bh_ave = None
        self.resist_bh_total_internal = None
        self.resist_bh_grout = None
        self.resist_bh = None

        self.theta_1 = self.shank_space / (2 * self.radius)
        self.theta_2 = self.radius / self.pipe.outer_radius
        self.theta_3 = 1 / (2 * self.theta_1 * self.theta_2)
        self.sigma = (self.grout.conductivity - self.soil.conductivity) / \
                     (self.grout.conductivity + self.soil.conductivity)
        self.beta = None

        self.calc_bh_resistance()
예제 #14
0
    def simulate(self):
        """
        More docs to come...
        """

        PrintClass.my_print("Beginning simulation")

        sim_hour = 0
        sim_hour_old = 0

        for year in range(self.sim_years):
            for month in range(ConstantClass.months_in_year):

                PrintClass.my_print("....Year/Month: %d/%d" %
                                    (year + 1, month + 1))

                temp_bh_hourly = []
                temp_mft_hourly = []

                for hour in range(ConstantClass.hours_in_month):
                    sim_hour += 1

                    # get raw hourly load and append to hourly list
                    load_index = month * ConstantClass.hours_in_month + hour
                    curr_load = self.sim_loads[load_index]

                    # aggregate energy in load blocks
                    energy = curr_load * (sim_hour - sim_hour_old) * ConstantClass.sec_in_hour
                    self.shift_loads(energy)

                    # get current data
                    curr_index = month * ConstantClass.hours_in_month + hour
                    curr_flow_rate = self.total_flow_rate[curr_index]

                    # update borehole flow rate
                    self.borehole.pipe.fluid.update_fluid_state(
                        new_flow_rate=curr_flow_rate)

                    # calculate borehole resistance
                    self.borehole.calc_bh_resistance()

                    for i, curr_obj in enumerate(self.agg_load_objects):

                        if curr_obj.num_loads == 0:
                            break

                        if i == 0:
                            q_curr = curr_obj.q
                            q_prev = 0
                        else:
                            prev_obj = self.agg_load_objects[i - 1]
                            q_curr = curr_obj.q
                            q_prev = prev_obj.q

                        # calculate average bh temp
                        delta_q = (q_curr - q_prev) / \
                                  (2 * np.pi * self.borehole.soil.conductivity *
                                   self.total_bh_length)

                        g = curr_obj.g_func
                        temp_bh_hourly.append(delta_q * g)

                        # calculate mean fluid temp
                        g_rb = g + self.borehole.resist_bh

                        if g_rb < 0:
                            g = -self.borehole.resist_bh * 2 * np.pi * self.borehole.soil.conductivity
                            g_rb = g + self.borehole.resist_bh

                        temp_mft_hourly.append(delta_q * g_rb)

                    # final bh temp
                    self.temp_bh.append(self.borehole.soil.undisturbed_temp + sum(temp_bh_hourly))

                    # final mean fluid temp
                    self.temp_mft.append(self.borehole.soil.undisturbed_temp + sum(temp_mft_hourly))

                    # update borehole temperature
                    self.borehole.pipe.fluid.update_fluid_state(new_temp=self.temp_mft[-1])

                    sim_hour_old = sim_hour

        self.generate_output_reports()

        PrintClass.my_print("Simulation complete", "success")
        PrintClass.my_print("Simulation time: %0.3f sec" %
                            (timeit.default_timer() - self.timer_start))

        PrintClass.write_log_file()