def setUp(self): self.aep = aep_csm_assembly() self.aep.machine_rating = 5000.0 # Float(units = 'kW', iotype='in', desc= 'rated machine power in kW') self.aep.rotor_diameter = 126.0 # Float(units = 'm', iotype='in', desc= 'rotor diameter of the machine') self.aep.max_tip_speed = 80.0 # Float(units = 'm/s', iotype='in', desc= 'maximum allowable tip speed for the rotor') self.aep.drivetrain_design = 'geared' # Enum('geared', ('geared', 'single_stage', 'multi_drive', 'pm_direct_drive'), iotype='in') self.aep.altitude = 0.0 # Float(0.0, units = 'm', iotype='in', desc= 'altitude of wind plant') self.aep.turbine_number = 100 # Int(100, iotype='in', desc = 'total number of wind turbines at the plant') self.aep.hub_height = 90.0 # Float(units = 'm', iotype='in', desc='hub height of wind turbine above ground / sea level')s self.aep.max_power_coefficient = 0.488 #Float(0.488, iotype='in', desc= 'maximum power coefficient of rotor for operation in region 2') self.aep.opt_tsr = 7.525 #Float(7.525, iotype='in', desc= 'optimum tip speed ratio for operation in region 2') self.aep.cut_in_wind_speed = 3.0 #Float(3.0, units = 'm/s', iotype='in', desc= 'cut in wind speed for the wind turbine') self.aep.cut_out_wind_speed = 25.0 #Float(25.0, units = 'm/s', iotype='in', desc= 'cut out wind speed for the wind turbine') self.aep.hub_height = 90.0 #Float(90.0, units = 'm', iotype='in', desc= 'hub height of wind turbine above ground / sea level') self.aep.altitude = 0.0 #Float(0.0, units = 'm', iotype='in', desc= 'altitude of wind plant') #self.aep.air_density = Float(0.0, units = 'kg / (m * m * m)', iotype='in', desc= 'air density at wind plant site') # default air density value is 0.0 - forces aero csm to calculate air density in model self.aep.drivetrain_design = 'geared' #Enum('geared', ('geared', 'single_stage', 'multi_drive', 'pm_direct_drive'), iotype='in') self.aep.shear_exponent = 0.1 #Float(0.1, iotype='in', desc= 'shear exponent for wind plant') #TODO - could use wind model here self.aep.wind_speed_50m = 8.02 #Float(8.35, units = 'm/s', iotype='in', desc='mean annual wind speed at 50 m height') self.aep.weibull_k= 2.15 #Float(2.1, iotype='in', desc = 'weibull shape factor for annual wind speed distribution') self.aep.soiling_losses = 0.0 #Float(0.0, iotype='in', desc = 'energy losses due to blade soiling for the wind plant - average across turbines') self.aep.array_losses = 0.10 #Float(0.06, iotype='in', desc = 'energy losses due to turbine interactions - across entire plant') self.aep.availability = 0.941 #Float(0.94287630736, iotype='in', desc = 'average annual availbility of wind turbines at plant') self.aep.turbine_number = 100 #Int(100, iotype='in', desc = 'total number of wind turbines at the plant') self.aep.thrust_coefficient = 0.50 #Float(0.50, iotype='in', desc='thrust coefficient at rated power')
def setUp(self): self.aep = aep_csm_assembly() self.aep.machine_rating = 5000.0 # Float(units = 'kW', iotype='in', desc= 'rated machine power in kW') self.aep.rotor_diameter = 126.0 # Float(units = 'm', iotype='in', desc= 'rotor diameter of the machine') self.aep.max_tip_speed = 80.0 # Float(units = 'm/s', iotype='in', desc= 'maximum allowable tip speed for the rotor') self.aep.drivetrain_design = 'geared' # Enum('geared', ('geared', 'single_stage', 'multi_drive', 'pm_direct_drive'), iotype='in') self.aep.altitude = 0.0 # Float(0.0, units = 'm', iotype='in', desc= 'altitude of wind plant') self.aep.turbine_number = 100 # Int(100, iotype='in', desc = 'total number of wind turbines at the plant') self.aep.hub_height = 90.0 # Float(units = 'm', iotype='in', desc='hub height of wind turbine above ground / sea level')s self.aep.max_power_coefficient = 0.488 #Float(0.488, iotype='in', desc= 'maximum power coefficient of rotor for operation in region 2') self.aep.opt_tsr = 7.525 #Float(7.525, iotype='in', desc= 'optimum tip speed ratio for operation in region 2') self.aep.cut_in_wind_speed = 3.0 #Float(3.0, units = 'm/s', iotype='in', desc= 'cut in wind speed for the wind turbine') self.aep.cut_out_wind_speed = 25.0 #Float(25.0, units = 'm/s', iotype='in', desc= 'cut out wind speed for the wind turbine') self.aep.hub_height = 90.0 #Float(90.0, units = 'm', iotype='in', desc= 'hub height of wind turbine above ground / sea level') self.aep.altitude = 0.0 #Float(0.0, units = 'm', iotype='in', desc= 'altitude of wind plant') #self.aep.air_density = Float(0.0, units = 'kg / (m * m * m)', iotype='in', desc= 'air density at wind plant site') # default air density value is 0.0 - forces aero csm to calculate air density in model self.aep.drivetrain_design = 'geared' #Enum('geared', ('geared', 'single_stage', 'multi_drive', 'pm_direct_drive'), iotype='in') self.aep.shear_exponent = 0.1 #Float(0.1, iotype='in', desc= 'shear exponent for wind plant') #TODO - could use wind model here self.aep.wind_speed_50m = 8.02 #Float(8.35, units = 'm/s', iotype='in', desc='mean annual wind speed at 50 m height') self.aep.weibull_k = 2.15 #Float(2.1, iotype='in', desc = 'weibull shape factor for annual wind speed distribution') self.aep.soiling_losses = 0.0 #Float(0.0, iotype='in', desc = 'energy losses due to blade soiling for the wind plant - average across turbines') self.aep.array_losses = 0.10 #Float(0.06, iotype='in', desc = 'energy losses due to turbine interactions - across entire plant') self.aep.availability = 0.941 #Float(0.94287630736, iotype='in', desc = 'average annual availbility of wind turbines at plant') self.aep.turbine_number = 100 #Int(100, iotype='in', desc = 'total number of wind turbines at the plant') self.aep.thrust_coefficient = 0.50 #Float(0.50, iotype='in', desc='thrust coefficient at rated power')
def configure(self): configure_extended_financial_analysis(self) self.replace('tcc_a', tcc_csm_assembly()) self.replace('bos_a', bos_csm_assembly()) self.replace('opex_a', opex_csm_assembly()) self.replace('aep_a', aep_csm_assembly()) self.replace('fin_a', fin_csm_assembly()) # connect i/o to component and assembly inputs # turbine configuration # rotor self.connect('rotor_diameter', ['aep_a.rotor_diameter', 'tcc_a.rotor_diameter', 'bos_a.rotor_diameter']) self.connect('max_tip_speed', ['aep_a.max_tip_speed']) self.connect('opt_tsr','aep_a.opt_tsr') self.connect('cut_in_wind_speed','aep_a.cut_in_wind_speed') self.connect('cut_out_wind_speed','aep_a.cut_out_wind_speed') self.connect('altitude','aep_a.altitude') self.connect('shear_exponent','aep_a.shear_exponent') self.connect('wind_speed_50m','aep_a.wind_speed_50m') self.connect('weibull_k','aep_a.weibull_k') self.connect('soiling_losses','aep_a.soiling_losses') self.connect('array_losses','aep_a.array_losses') self.connect('availability','aep_a.availability') self.connect('thrust_coefficient','aep_a.thrust_coefficient') self.connect('blade_number','tcc_a.blade_number') self.connect('advanced_blade','tcc_a.advanced_blade') # drivetrain self.connect('machine_rating', ['aep_a.machine_rating', 'tcc_a.machine_rating', 'bos_a.machine_rating', 'opex_a.machine_rating']) self.connect('drivetrain_design', ['aep_a.drivetrain_design', 'tcc_a.drivetrain_design']) self.connect('crane','tcc_a.crane') self.connect('advanced_bedplate','tcc_a.advanced_bedplate') # tower self.connect('hub_height', ['aep_a.hub_height', 'tcc_a.hub_height', 'bos_a.hub_height']) self.connect('advanced_tower','tcc_a.advanced_tower') # plant configuration # climate self.connect('sea_depth', ['bos_a.sea_depth', 'opex_a.sea_depth', 'fin_a.sea_depth']) self.connect('offshore','tcc_a.offshore') # plant operation self.connect('turbine_number', ['aep_a.turbine_number', 'bos_a.turbine_number', 'opex_a.turbine_number']) # financial self.connect('year', ['tcc_a.year', 'bos_a.year', 'opex_a.year']) self.connect('month', ['tcc_a.month', 'bos_a.month', 'opex_a.month']) self.connect('fixed_charge_rate','fin_a.fixed_charge_rate') self.connect('construction_finance_rate','fin_a.construction_finance_rate') self.connect('tax_rate','fin_a.tax_rate') self.connect('discount_rate','fin_a.discount_rate') self.connect('construction_time','fin_a.construction_time') self.connect('project_lifetime','fin_a.project_lifetime') # connections self.connect('aep_a.rotor_thrust','tcc_a.rotor_thrust') self.connect('aep_a.rotor_torque','tcc_a.rotor_torque') self.connect('aep_a.net_aep', ['opex_a.net_aep']) self.connect('tcc_a.turbine_cost','bos_a.turbine_cost') # create passthroughs for key output variables of interest # aep_a self.connect('aep_a.rated_rotor_speed','rated_rotor_speed') self.connect('aep_a.rated_wind_speed','rated_wind_speed') self.connect('aep_a.rotor_thrust','rotor_thrust') self.connect('aep_a.rotor_torque','rotor_torque') self.connect('aep_a.power_curve','power_curve') self.connect('aep_a.max_efficiency','max_efficiency') self.connect('aep_a.gross_aep','gross_aep') # tcc_a self.connect('tcc_a.turbine_mass','turbine_mass') # fin_a self.connect('fin_a.lcoe','lcoe')
# 5 ---------- # A simple test of nrel_csm_aep model from plant_energyse.nrel_csm_aep.nrel_csm_aep import aep_csm_assembly aep = aep_csm_assembly() # 5 ---------- # 6 ---------- # Set input parameters aep.machine_rating = 5000.0 # Float(units = 'kW', iotype='in', desc= 'rated machine power in kW') aep.rotor_diameter = 126.0 # Float(units = 'm', iotype='in', desc= 'rotor diameter of the machine') aep.max_tip_speed = 80.0 # Float(units = 'm/s', iotype='in', desc= 'maximum allowable tip speed for the rotor') aep.drivetrain_design = 'geared' # Enum('geared', ('geared', 'single_stage', 'multi_drive', 'pm_direct_drive'), iotype='in') aep.altitude = 0.0 # Float(0.0, units = 'm', iotype='in', desc= 'altitude of wind plant') aep.turbine_number = 100 # Int(100, iotype='in', desc = 'total number of wind turbines at the plant') aep.hub_height = 90.0 # Float(units = 'm', iotype='in', desc='hub height of wind turbine above ground / sea level')s aep.max_power_coefficient = 0.488 #Float(0.488, iotype='in', desc= 'maximum power coefficient of rotor for operation in region 2') aep.opt_tsr = 7.525 #Float(7.525, iotype='in', desc= 'optimum tip speed ratio for operation in region 2') aep.cut_in_wind_speed = 3.0 #Float(3.0, units = 'm/s', iotype='in', desc= 'cut in wind speed for the wind turbine') aep.cut_out_wind_speed = 25.0 #Float(25.0, units = 'm/s', iotype='in', desc= 'cut out wind speed for the wind turbine') aep.hub_height = 90.0 #Float(90.0, units = 'm', iotype='in', desc= 'hub height of wind turbine above ground / sea level') #aep.air_density = Float(0.0, units = 'kg / (m * m * m)', iotype='in', desc= 'air density at wind plant site') # default air density value is 0.0 - forces aero csm to calculate air density in model aep.shear_exponent = 0.1 #Float(0.1, iotype='in', desc= 'shear exponent for wind plant') #TODO - could use wind model here aep.wind_speed_50m = 8.02 #Float(8.35, units = 'm/s', iotype='in', desc='mean annual wind speed at 50 m height') aep.weibull_k= 2.15 #Float(2.1, iotype='in', desc = 'weibull shape factor for annual wind speed distribution') aep.soiling_losses = 0.0 #Float(0.0, iotype='in', desc = 'energy losses due to blade soiling for the wind plant - average across turbines') aep.array_losses = 0.10 #Float(0.06, iotype='in', desc = 'energy losses due to turbine interactions - across entire plant') aep.availability = 0.941 #Float(0.94287630736, iotype='in', desc = 'average annual availbility of wind turbines at plant') aep.thrust_coefficient = 0.50 #Float(0.50, iotype='in', desc='thrust coefficient at rated power')
# 5 ---------- # A simple test of nrel_csm_aep model from plant_energyse.nrel_csm_aep.nrel_csm_aep import aep_csm_assembly aep = aep_csm_assembly() # 5 ---------- # 6 ---------- # Set input parameters aep.machine_rating = 5000.0 # Float(units = 'kW', iotype='in', desc= 'rated machine power in kW') aep.rotor_diameter = 126.0 # Float(units = 'm', iotype='in', desc= 'rotor diameter of the machine') aep.max_tip_speed = 80.0 # Float(units = 'm/s', iotype='in', desc= 'maximum allowable tip speed for the rotor') aep.drivetrain_design = 'geared' # Enum('geared', ('geared', 'single_stage', 'multi_drive', 'pm_direct_drive'), iotype='in') aep.altitude = 0.0 # Float(0.0, units = 'm', iotype='in', desc= 'altitude of wind plant') aep.turbine_number = 100 # Int(100, iotype='in', desc = 'total number of wind turbines at the plant') aep.hub_height = 90.0 # Float(units = 'm', iotype='in', desc='hub height of wind turbine above ground / sea level')s aep.max_power_coefficient = 0.488 #Float(0.488, iotype='in', desc= 'maximum power coefficient of rotor for operation in region 2') aep.opt_tsr = 7.525 #Float(7.525, iotype='in', desc= 'optimum tip speed ratio for operation in region 2') aep.cut_in_wind_speed = 3.0 #Float(3.0, units = 'm/s', iotype='in', desc= 'cut in wind speed for the wind turbine') aep.cut_out_wind_speed = 25.0 #Float(25.0, units = 'm/s', iotype='in', desc= 'cut out wind speed for the wind turbine') aep.hub_height = 90.0 #Float(90.0, units = 'm', iotype='in', desc= 'hub height of wind turbine above ground / sea level') #aep.air_density = Float(0.0, units = 'kg / (m * m * m)', iotype='in', desc= 'air density at wind plant site') # default air density value is 0.0 - forces aero csm to calculate air density in model aep.shear_exponent = 0.1 #Float(0.1, iotype='in', desc= 'shear exponent for wind plant') #TODO - could use wind model here aep.wind_speed_50m = 8.02 #Float(8.35, units = 'm/s', iotype='in', desc='mean annual wind speed at 50 m height') aep.weibull_k = 2.15 #Float(2.1, iotype='in', desc = 'weibull shape factor for annual wind speed distribution') aep.soiling_losses = 0.0 #Float(0.0, iotype='in', desc = 'energy losses due to blade soiling for the wind plant - average across turbines') aep.array_losses = 0.10 #Float(0.06, iotype='in', desc = 'energy losses due to turbine interactions - across entire plant') aep.availability = 0.941 #Float(0.94287630736, iotype='in', desc = 'average annual availbility of wind turbines at plant') aep.thrust_coefficient = 0.50 #Float(0.50, iotype='in', desc='thrust coefficient at rated power')
def configure(self): configure_extended_financial_analysis(self) self.replace('tcc_a', tcc_csm_assembly()) self.replace('bos_a', bos_csm_assembly()) self.replace('opex_a', opex_csm_assembly()) self.replace('aep_a', aep_csm_assembly()) self.replace('fin_a', fin_csm_assembly()) # connect i/o to component and assembly inputs # turbine configuration # rotor self.connect('rotor_diameter', ['aep_a.rotor_diameter', 'tcc_a.rotor_diameter', 'bos_a.rotor_diameter']) self.connect('max_tip_speed', ['aep_a.max_tip_speed']) self.connect('max_power_coefficient', 'aep_a.max_power_coefficient') self.connect('opt_tsr','aep_a.opt_tsr') self.connect('cut_in_wind_speed','aep_a.cut_in_wind_speed') self.connect('cut_out_wind_speed','aep_a.cut_out_wind_speed') self.connect('altitude','aep_a.altitude') self.connect('shear_exponent','aep_a.shear_exponent') self.connect('wind_speed_50m','aep_a.wind_speed_50m') self.connect('weibull_k','aep_a.weibull_k') self.connect('soiling_losses','aep_a.soiling_losses') self.connect('array_losses','aep_a.array_losses') self.connect('availability','aep_a.availability') self.connect('thrust_coefficient','aep_a.thrust_coefficient') self.connect('max_efficiency', 'aep_a.max_efficiency') self.connect('blade_number','tcc_a.blade_number') self.connect('advanced_blade','tcc_a.advanced_blade') # drivetrain self.connect('machine_rating', ['aep_a.machine_rating', 'tcc_a.machine_rating', 'bos_a.machine_rating', 'opex_a.machine_rating']) self.connect('drivetrain_design', ['aep_a.drivetrain_design', 'tcc_a.drivetrain_design']) self.connect('crane','tcc_a.crane') self.connect('advanced_bedplate','tcc_a.advanced_bedplate') # tower self.connect('hub_height', ['aep_a.hub_height', 'tcc_a.hub_height', 'bos_a.hub_height']) self.connect('advanced_tower','tcc_a.advanced_tower') # plant configuration # climate self.connect('sea_depth', ['bos_a.sea_depth', 'opex_a.sea_depth', 'fin_a.sea_depth']) self.connect('offshore','tcc_a.offshore') # plant operation self.connect('turbine_number', ['aep_a.turbine_number', 'bos_a.turbine_number', 'opex_a.turbine_number']) # financial self.connect('year', ['tcc_a.year', 'bos_a.year', 'opex_a.year']) self.connect('month', ['tcc_a.month', 'bos_a.month', 'opex_a.month']) self.connect('fixed_charge_rate','fin_a.fixed_charge_rate') self.connect('construction_finance_rate','fin_a.construction_finance_rate') self.connect('tax_rate','fin_a.tax_rate') self.connect('discount_rate','fin_a.discount_rate') self.connect('construction_time','fin_a.construction_time') self.connect('project_lifetime','fin_a.project_lifetime') # connections self.connect('aep_a.rotor_thrust','tcc_a.rotor_thrust') self.connect('aep_a.rotor_torque','tcc_a.rotor_torque') self.connect('aep_a.net_aep', ['opex_a.net_aep']) self.connect('tcc_a.turbine_cost','bos_a.turbine_cost') # create passthroughs for key output variables of interest # aep_a self.connect('aep_a.rated_rotor_speed','rated_rotor_speed') self.connect('aep_a.rated_wind_speed','rated_wind_speed') self.connect('aep_a.rotor_thrust','rotor_thrust') self.connect('aep_a.rotor_torque','rotor_torque') self.connect('aep_a.power_curve','power_curve') #self.connect('aep_a.max_efficiency','max_efficiency') self.connect('aep_a.gross_aep','gross_aep') self.connect('aep_a.capacity_factor','capacity_factor') # tcc_a self.connect('tcc_a.turbine_mass','turbine_mass') # fin_a self.connect('fin_a.lcoe','lcoe')
def configure(self): configure_extended_financial_analysis(self) self.replace("tcc_a", tcc_csm_assembly()) self.replace("bos_a", bos_csm_assembly()) self.replace("opex_a", opex_csm_assembly()) self.replace("aep_a", aep_csm_assembly()) self.replace("fin_a", fin_csm_assembly()) # connect i/o to component and assembly inputs # turbine configuration # rotor self.connect("rotor_diameter", ["aep_a.rotor_diameter", "tcc_a.rotor_diameter", "bos_a.rotor_diameter"]) self.connect("max_tip_speed", ["aep_a.max_tip_speed"]) self.connect("max_power_coefficient", "aep_a.max_power_coefficient") self.connect("opt_tsr", "aep_a.opt_tsr") self.connect("cut_in_wind_speed", "aep_a.cut_in_wind_speed") self.connect("cut_out_wind_speed", "aep_a.cut_out_wind_speed") self.connect("altitude", "aep_a.altitude") self.connect("shear_exponent", "aep_a.shear_exponent") self.connect("wind_speed_50m", "aep_a.wind_speed_50m") self.connect("weibull_k", "aep_a.weibull_k") self.connect("soiling_losses", "aep_a.soiling_losses") self.connect("array_losses", "aep_a.array_losses") self.connect("availability", "aep_a.availability") self.connect("thrust_coefficient", "aep_a.thrust_coefficient") self.connect("max_efficiency", "aep_a.max_efficiency") self.connect("blade_number", "tcc_a.blade_number") self.connect("advanced_blade", "tcc_a.advanced_blade") # drivetrain self.connect( "machine_rating", ["aep_a.machine_rating", "tcc_a.machine_rating", "bos_a.machine_rating", "opex_a.machine_rating"], ) self.connect("drivetrain_design", ["aep_a.drivetrain_design", "tcc_a.drivetrain_design"]) self.connect("crane", "tcc_a.crane") self.connect("advanced_bedplate", "tcc_a.advanced_bedplate") # tower self.connect("hub_height", ["aep_a.hub_height", "tcc_a.hub_height", "bos_a.hub_height"]) self.connect("advanced_tower", "tcc_a.advanced_tower") # plant configuration # climate self.connect("sea_depth", ["bos_a.sea_depth", "opex_a.sea_depth", "fin_a.sea_depth"]) self.connect("offshore", "tcc_a.offshore") # plant operation self.connect("turbine_number", ["aep_a.turbine_number", "bos_a.turbine_number", "opex_a.turbine_number"]) # financial self.connect("year", ["tcc_a.year", "bos_a.year", "opex_a.year"]) self.connect("month", ["tcc_a.month", "bos_a.month", "opex_a.month"]) self.connect("fixed_charge_rate", "fin_a.fixed_charge_rate") self.connect("construction_finance_rate", "fin_a.construction_finance_rate") self.connect("tax_rate", "fin_a.tax_rate") self.connect("discount_rate", "fin_a.discount_rate") self.connect("construction_time", "fin_a.construction_time") self.connect("project_lifetime", "fin_a.project_lifetime") # connections self.connect("aep_a.rotor_thrust", "tcc_a.rotor_thrust") self.connect("aep_a.rotor_torque", "tcc_a.rotor_torque") self.connect("aep_a.net_aep", ["opex_a.net_aep"]) self.connect("tcc_a.turbine_cost", "bos_a.turbine_cost") # create passthroughs for key output variables of interest # aep_a self.connect("aep_a.rated_rotor_speed", "rated_rotor_speed") self.connect("aep_a.rated_wind_speed", "rated_wind_speed") self.connect("aep_a.rotor_thrust", "rotor_thrust") self.connect("aep_a.rotor_torque", "rotor_torque") self.connect("aep_a.power_curve", "power_curve") # self.connect('aep_a.max_efficiency','max_efficiency') self.connect("aep_a.gross_aep", "gross_aep") self.connect("aep_a.capacity_factor", "capacity_factor") # tcc_a self.connect("tcc_a.turbine_mass", "turbine_mass") # fin_a self.connect("fin_a.lcoe", "lcoe")
def configure(self): """ tcc_a inputs: advanced_blade = Bool offshore = Bool assemblyCostMultiplier = Float overheadCostMultiplier = Float profitMultiplier = Float transportMultiplier = Float aep inputs: array_losses = Float other_losses = Float fin inputs: fixed_charge_rate = Float construction_finance_rate = Float tax_rate = Float discount_rate = Float construction_time = Float bos inputs: bos_multiplier = Float inputs: sea_depth year month project lifetime if csm opex additional inputs: availability = Float() if openwind opex additional inputs: power_curve rpm ct if with_landbos additional inputs: voltage distInter terrain layout soil """ # configure base assembly configure_extended_financial_analysis(self) # putting replace statements here for now; TODO - openmdao bug # replace BOS with either CSM or landbos if self.with_landbos: self.replace('bos_a', NREL_Land_BOSSE()) else: self.replace('bos_a', bos_csm_assembly()) #self.replace('tcc_a', Turbine_CostsSE_2015()) if self.with_ecn_opex: self.replace('opex_a', opex_ecn_assembly(ecn_file)) else: self.replace('opex_a', opex_csm_assembly()) self.replace('aep_a', aep_csm_assembly()) # TODO include AEP assembly from CSM and use to bridge rotor torque self.replace('fin_a', fin_csm_assembly()) # replace TCC with turbine_costs configure_lcoe_with_turb_costs(self) # replace BOS with either CSM or landbos if self.with_landbos: configure_lcoe_with_landbos(self) else: configure_lcoe_with_csm_bos(self) # replace AEP with weibull AEP (TODO: option for basic aep) configure_lcoe_with_csm_aep(self) self.connect('aep_a.rotor_torque','tcc_a.rotor_torque') # replace OPEX with CSM or ECN opex and add AEP if self.with_ecn_opex: configure_lcoe_with_ecn_opex(self,ecn_file) self.connect('opex_a.availability','aep_a.availability') # connecting here due to aep / opex reversal depending on model else: configure_lcoe_with_csm_opex(self) self.add('availability',Float(0.94, iotype='in', desc='average annual availbility of wind turbines at plant')) self.connect('availability','aep_a.availability') # connecting here due to aep / opex reversal depending on model # replace Finance with CSM Finance configure_lcoe_with_csm_fin(self)