class NECB2011 def model_add_hvac(model:) OpenStudio.logFree(OpenStudio::Info, 'openstudio.model.Model', 'Started Adding HVAC') system_fuel_defaults = get_canadian_system_defaults_by_weatherfile_name(model) necb_autozone_and_autosystem(model: model, runner: nil, use_ideal_air_loads: false, system_fuel_defaults: system_fuel_defaults) OpenStudio.logFree(OpenStudio::Info, 'openstudio.model.Model', 'Finished adding HVAC') return true end # NECB does not change damper positions # # return [Bool] returns true if successful, false if not def air_loop_hvac_apply_multizone_vav_outdoor_air_sizing(air_loop_hvac) # Do not change anything. return true end # Determine whether or not this system # is required to have an economizer. # # @return [Bool] returns true if an economizer is required, false if not def air_loop_hvac_economizer_required?(air_loop_hvac) economizer_required = false # need a better way to determine if an economizer is needed. return economizer_required if ((air_loop_hvac.name.to_s.include? 'Outpatient F1' ) || (air_loop_hvac.sizingSystem.typeofLoadtoSizeOn.to_s == "VentilationRequirement")) # A big number of btu per hr as the minimum requirement infinity_btu_per_hr = 999_999_999_999 minimum_capacity_btu_per_hr = infinity_btu_per_hr # Determine if the airloop serves any computer rooms # / data centers, which changes the economizer. is_dc = false if air_loop_hvac_data_center_area_served(air_loop_hvac) > 0 is_dc = true end # Determine the minimum capacity that requires an economizer minimum_capacity_btu_per_hr = 68_243 # NECB requires economizer for cooling cap > 20 kW # puts air_loop_hvac.name.to_s # Design Supply Air Flow Rate: This method below reads the value from the sql file. dsafr_m3_per_s = air_loop_hvac.model.getAutosizedValue(air_loop_hvac, 'Design Supply Air Flow Rate', 'm3/s') min_dsafr_l_per_s = 1500 unless dsafr_m3_per_s.empty? dsafr_l_per_s = dsafr_m3_per_s.get * 1000 if dsafr_l_per_s > min_dsafr_l_per_s economizer_required = true puts "economizer_required = true for #{air_loop_hvac.name} because dsafr_l_per_s(#{dsafr_l_per_s}) > 1500" if is_dc OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "#{air_loop_hvac.name} requires an economizer because the 'Design Supply Air Flow Rate' of #{dsafr_l_per_s} L/s exceeds the minimum air flow rate of #{min_dsafr_l_per_s} L/s for data centers.") else OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "#{air_loop_hvac.name} requires an economizer because the 'Design Supply Air Flow Rate' of #{dsafr_l_per_s} L/s exceeds the minimum air flow rate of #{min_dsafr_l_per_s} L/s.") end end end # Check whether the system requires an economizer by comparing # the system capacity to the minimum capacity. total_cooling_capacity_w = air_loop_hvac_total_cooling_capacity(air_loop_hvac) total_cooling_capacity_btu_per_hr = OpenStudio.convert(total_cooling_capacity_w, 'W', 'Btu/hr').get if total_cooling_capacity_btu_per_hr >= minimum_capacity_btu_per_hr if is_dc OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "#{air_loop_hvac.name} requires an economizer because the total cooling capacity of #{total_cooling_capacity_btu_per_hr.round} Btu/hr exceeds the minimum capacity of #{minimum_capacity_btu_per_hr.round} Btu/hr for data centers.") else OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "#{air_loop_hvac.name} requires an economizer because the total cooling capacity of #{total_cooling_capacity_btu_per_hr.round} Btu/hr exceeds the minimum capacity of #{minimum_capacity_btu_per_hr.round} Btu/hr.") end puts "economizer_required = true for #{air_loop_hvac.name} because total_cooling_capacity_btu_per_hr(#{total_cooling_capacity_btu_per_hr}) >= #{minimum_capacity_btu_per_hr}" economizer_required = true else if is_dc OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "#{air_loop_hvac.name} does not require an economizer because the total cooling capacity of #{total_cooling_capacity_btu_per_hr.round} Btu/hr is less than the minimum capacity of #{minimum_capacity_btu_per_hr.round} Btu/hr for data centers.") else OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "#{air_loop_hvac.name} does not require an economizer because the total cooling capacity of #{total_cooling_capacity_btu_per_hr.round} Btu/hr is less than the minimum capacity of #{minimum_capacity_btu_per_hr.round} Btu/hr.") end end return economizer_required end # NECB always requires an integrated economizer # (NoLockout); as per 5.2.2.8(3) # this means that compressor allowed to turn on when economizer is open # # @note this method assumes you previously checked that an economizer is required at all # via #economizer_required? # @param (see #economizer_required?) # @return [Bool] returns true if successful, false if not def air_loop_hvac_apply_economizer_integration(air_loop_hvac, climate_zone) # Get the OA system and OA controller oa_sys = air_loop_hvac.airLoopHVACOutdoorAirSystem # No OA system return false if !oa_sys.is_initialized oa_sys = oa_sys.get oa_control = oa_sys.getControllerOutdoorAir # Apply integrated economizer oa_control.setLockoutType('NoLockout') return true end # Check if ERV is required on this airloop. # # @param (see #economizer_required?) # @return [Bool] Returns true if required, false if not. # @todo Add exception logic for systems serving parking garage, warehouse, or multifamily def air_loop_hvac_energy_recovery_ventilator_required?(air_loop_hvac, climate_zone) # ERV Not Applicable for AHUs that serve # parking garage, warehouse, or multifamily # if space_types_served_names.include?('PNNL_Asset_Rating_Apartment_Space_Type') || # space_types_served_names.include?('PNNL_Asset_Rating_LowRiseApartment_Space_Type') || # space_types_served_names.include?('PNNL_Asset_Rating_ParkingGarage_Space_Type') || # space_types_served_names.include?('PNNL_Asset_Rating_Warehouse_Space_Type') # OpenStudio::logFree(OpenStudio::Info, "openstudio.standards.AirLoopHVAC", "For #{self.name}, ERV not applicable because it because it serves parking garage, warehouse, or multifamily.") # return false # end erv_required = nil # ERV not applicable for medical AHUs (AHU1 in Outpatient), per AIA 2001 - 7.31.D2. if air_loop_hvac.name.to_s.include? 'Outpatient F1' erv_required = false return erv_required end # ERV not applicable for medical AHUs, per AIA 2001 - 7.31.D2. if air_loop_hvac.name.to_s.include? 'VAV_ER' erv_required = false return erv_required elsif air_loop_hvac.name.to_s.include? 'VAV_OR' erv_required = false return erv_required end # ERV Not Applicable for AHUs that have DCV # or that have no OA intake. controller_oa = nil controller_mv = nil oa_system = nil if air_loop_hvac.airLoopHVACOutdoorAirSystem.is_initialized oa_system = air_loop_hvac.airLoopHVACOutdoorAirSystem.get controller_oa = oa_system.getControllerOutdoorAir controller_mv = controller_oa.controllerMechanicalVentilation if controller_mv.demandControlledVentilation == true OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV not applicable because DCV enabled.") return false end else OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV not applicable because it has no OA intake.") return false end # Get the AHU design supply air flow rate dsn_flow_m3_per_s = nil if air_loop_hvac.designSupplyAirFlowRate.is_initialized dsn_flow_m3_per_s = air_loop_hvac.designSupplyAirFlowRate.get elsif air_loop_hvac.autosizedDesignSupplyAirFlowRate.is_initialized dsn_flow_m3_per_s = air_loop_hvac.autosizedDesignSupplyAirFlowRate.get else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name} design supply air flow rate is not available, cannot apply efficiency standard.") return false end dsn_flow_cfm = OpenStudio.convert(dsn_flow_m3_per_s, 'm^3/s', 'cfm').get # Get the minimum OA flow rate min_oa_flow_m3_per_s = nil if controller_oa.minimumOutdoorAirFlowRate.is_initialized min_oa_flow_m3_per_s = controller_oa.minimumOutdoorAirFlowRate.get elsif controller_oa.autosizedMinimumOutdoorAirFlowRate.is_initialized min_oa_flow_m3_per_s = controller_oa.autosizedMinimumOutdoorAirFlowRate.get else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.AirLoopHVAC', "For #{controller_oa.name}: minimum OA flow rate is not available, cannot apply efficiency standard.") return false end min_oa_flow_cfm = OpenStudio.convert(min_oa_flow_m3_per_s, 'm^3/s', 'cfm').get # Calculate the percent OA at design airflow pct_oa = min_oa_flow_m3_per_s / dsn_flow_m3_per_s # The NECB2011 requirement is that systems with an exhaust heat content > 150 kW require an HRV # The calculation for this is done below, to modify erv_required # erv_cfm set to nil here as placeholder, will lead to erv_required = false erv_cfm = nil # Determine if an ERV is required # erv_required = nil if erv_cfm.nil? OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV not required based on #{(pct_oa * 100).round}% OA flow, design supply air flow of #{dsn_flow_cfm.round}cfm, and climate zone #{climate_zone}.") erv_required = false elsif dsn_flow_cfm < erv_cfm OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV not required based on #{(pct_oa * 100).round}% OA flow, design supply air flow of #{dsn_flow_cfm.round}cfm, and climate zone #{climate_zone}. Does not exceed minimum flow requirement of #{erv_cfm}cfm.") erv_required = false else OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV required based on #{(pct_oa * 100).round}% OA flow, design supply air flow of #{dsn_flow_cfm.round}cfm, and climate zone #{climate_zone}. Exceeds minimum flow requirement of #{erv_cfm}cfm.") erv_required = true end # This code modifies erv_required for NECB2011 # Calculation of exhaust heat content and check whether it is > 150 kW # get all zones in the model zones = air_loop_hvac.thermalZones # initialize counters sum_zone_oa = 0.0 sum_zone_oa_times_heat_design_t = 0.0 # zone loop zones.each do |zone| # get design heat temperature for each zone; this is equivalent to design exhaust temperature heat_design_t = 21.0 zone_thermostat = zone.thermostat.get if zone_thermostat.to_ThermostatSetpointDualSetpoint.is_initialized dual_thermostat = zone_thermostat.to_ThermostatSetpointDualSetpoint.get if dual_thermostat.heatingSetpointTemperatureSchedule.is_initialized htg_temp_sch = dual_thermostat.heatingSetpointTemperatureSchedule.get htg_temp_sch_ruleset = htg_temp_sch.to_ScheduleRuleset.get winter_dd_sch = htg_temp_sch_ruleset.winterDesignDaySchedule heat_design_t = winter_dd_sch.values.max end end # initialize counter zone_oa = 0.0 # outdoor defined at space level; get OA flow for all spaces within zone spaces = zone.spaces # space loop spaces.each do |space| unless space.designSpecificationOutdoorAir.empty? # if empty, don't do anything outdoor_air = space.designSpecificationOutdoorAir.get # in bTAP, outdoor air specified as outdoor air per oa_flow_per_floor_area = outdoor_air.outdoorAirFlowperFloorArea oa_flow = oa_flow_per_floor_area * space.floorArea * zone.multiplier # oa flow for the space zone_oa += oa_flow # add up oa flow for all spaces to get zone air flow end # space loop end sum_zone_oa += zone_oa # sum of all zone oa flows to get system oa flow sum_zone_oa_times_heat_design_t += (zone_oa * heat_design_t) # calculated to get oa flow weighted average of design exhaust temperature # zone loop end # Calculate average exhaust temperature (oa flow weighted average) avg_exhaust_temp = sum_zone_oa_times_heat_design_t / sum_zone_oa # for debugging/testing # puts "average exhaust temp = #{avg_exhaust_temp}" # puts "sum_zone_oa = #{sum_zone_oa}" # Get January winter design temperature # get model weather file name weather_file = BTAP::Environment::WeatherFile.new(air_loop_hvac.model.weatherFile.get.path.get) # get winter(heating) design temp stored in array # Note that the NECB2011 specifies using the 2.5% january design temperature # The outdoor temperature used here is the 0.4% heating design temperature of the coldest month, available in stat file outdoor_temp = weather_file.heating_design_info[1] # for debugging/testing # puts "outdoor design temp = #{outdoor_temp}" # Calculate exhaust heat content exhaust_heat_content = 0.00123 * sum_zone_oa * 1000.0 * (avg_exhaust_temp - outdoor_temp) # for debugging/testing # puts "exhaust heat content = #{exhaust_heat_content}" # Modify erv_required based on exhaust heat content if exhaust_heat_content > 150.0 erv_required = true OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV required based on exhaust heat content.") else erv_required = false OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV not required based on exhaust heat content.") end return erv_required end # Add an ERV to this airloop. # Will be a rotary-type HX # # @param (see #economizer_required?) # @return [Bool] Returns true if required, false if not. # @todo Add exception logic for systems serving parking garage, warehouse, or multifamily def air_loop_hvac_apply_energy_recovery_ventilator(air_loop_hvac, climate = nil) # Get the oa system oa_system = nil if air_loop_hvac.airLoopHVACOutdoorAirSystem.is_initialized oa_system = air_loop_hvac.airLoopHVACOutdoorAirSystem.get else OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}, ERV cannot be added because the system has no OA intake.") return false end # Create an ERV erv = OpenStudio::Model::HeatExchangerAirToAirSensibleAndLatent.new(air_loop_hvac.model) erv.setName("#{air_loop_hvac.name} ERV") erv.setSensibleEffectivenessat100HeatingAirFlow(0.5) erv.setLatentEffectivenessat100HeatingAirFlow(0.5) erv.setSensibleEffectivenessat75HeatingAirFlow(0.5) erv.setLatentEffectivenessat75HeatingAirFlow(0.5) erv.setSensibleEffectivenessat100CoolingAirFlow(0.5) erv.setLatentEffectivenessat100CoolingAirFlow(0.5) erv.setSensibleEffectivenessat75CoolingAirFlow(0.5) erv.setLatentEffectivenessat75CoolingAirFlow(0.5) erv.setSupplyAirOutletTemperatureControl(true) erv.setHeatExchangerType('Rotary') erv.setFrostControlType('ExhaustOnly') erv.setEconomizerLockout(true) erv.setThresholdTemperature(-23.3) # -10F erv.setInitialDefrostTimeFraction(0.167) erv.setRateofDefrostTimeFractionIncrease(1.44) # Add the ERV to the OA system erv.addToNode(oa_system.outboardOANode.get) # Add a setpoint manager OA pretreat # to control the ERV spm_oa_pretreat = OpenStudio::Model::SetpointManagerOutdoorAirPretreat.new(air_loop_hvac.model) spm_oa_pretreat.setMinimumSetpointTemperature(-99.0) spm_oa_pretreat.setMaximumSetpointTemperature(99.0) spm_oa_pretreat.setMinimumSetpointHumidityRatio(0.00001) spm_oa_pretreat.setMaximumSetpointHumidityRatio(1.0) # Reference setpoint node and # Mixed air stream node are outlet # node of the OA system mixed_air_node = oa_system.mixedAirModelObject.get.to_Node.get spm_oa_pretreat.setReferenceSetpointNode(mixed_air_node) spm_oa_pretreat.setMixedAirStreamNode(mixed_air_node) # Outdoor air node is # the outboard OA node of teh OA system spm_oa_pretreat.setOutdoorAirStreamNode(oa_system.outboardOANode.get) # Return air node is the inlet # node of the OA system return_air_node = oa_system.returnAirModelObject.get.to_Node.get spm_oa_pretreat.setReturnAirStreamNode(return_air_node) # Attach to the outlet of the ERV erv_outlet = erv.primaryAirOutletModelObject.get.to_Node.get spm_oa_pretreat.addToNode(erv_outlet) # Apply the prototype Heat Exchanger power assumptions. heat_exchanger_air_to_air_sensible_and_latent_apply_prototype_nominal_electric_power(erv) # Determine if the system is a DOAS based on # whether there is 100% OA in heating and cooling sizing. is_doas = false sizing_system = air_loop_hvac.sizingSystem if sizing_system.allOutdoorAirinCooling && sizing_system.allOutdoorAirinHeating is_doas = true end # Set the bypass control type # If DOAS system, BypassWhenWithinEconomizerLimits # to disable ERV during economizing. # Otherwise, BypassWhenOAFlowGreaterThanMinimum # to disable ERV during economizing and when OA # is also greater than minimum. bypass_ctrl_type = if is_doas 'BypassWhenWithinEconomizerLimits' else 'BypassWhenOAFlowGreaterThanMinimum' end oa_system.getControllerOutdoorAir.setHeatRecoveryBypassControlType(bypass_ctrl_type) return true end # Sets the minimum effectiveness of the heat exchanger per # the standard. def heat_exchanger_air_to_air_sensible_and_latent_apply_effectiveness(heat_exchanger_air_to_air_sensible_and_latent, erv_name = nil) # Assumed to be sensible and latent at all flow # This will now get data of the erv from the json file instead of hardcoding it. Defaults to NECB2011 erv we have been using. erv_name = 'NECB_Default' if erv_name.nil? erv_info = @standards_data['tables']['erv']['table'].detect { |item| item['erv_name'] == erv_name } raise("Could not find #{erv_name} in #{self.class.name} class' erv.json file or it's parents. The available ervs are #{@standards_data['tables']['erv']['table'].map { |item| item['erv_name'] }}") if erv_info.nil? heat_exchanger_air_to_air_sensible_and_latent.setHeatExchangerType(erv_info['HeatExchangerType']) heat_exchanger_air_to_air_sensible_and_latent.setSensibleEffectivenessat100HeatingAirFlow(erv_info['SensibleEffectivenessat100HeatingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setLatentEffectivenessat100HeatingAirFlow(erv_info['LatentEffectivenessat100HeatingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setSensibleEffectivenessat75HeatingAirFlow(erv_info['SensibleEffectivenessat75HeatingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setLatentEffectivenessat75HeatingAirFlow(erv_info['LatentEffectivenessat75HeatingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setSensibleEffectivenessat100CoolingAirFlow(erv_info['SensibleEffectivenessat100CoolingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setLatentEffectivenessat100CoolingAirFlow(erv_info['LatentEffectivenessat100CoolingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setSensibleEffectivenessat75CoolingAirFlow(erv_info['SensibleEffectivenessat75CoolingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setLatentEffectivenessat75CoolingAirFlow(erv_info['LatentEffectivenessat75CoolingAirFlow']) heat_exchanger_air_to_air_sensible_and_latent.setSupplyAirOutletTemperatureControl(erv_info['SupplyAirOutletTemperatureControl']) heat_exchanger_air_to_air_sensible_and_latent.setFrostControlType(erv_info['FrostControlType']) heat_exchanger_air_to_air_sensible_and_latent.setEconomizerLockout(erv_info['EconomizerLockout']) heat_exchanger_air_to_air_sensible_and_latent.setThresholdTemperature(erv_info['ThresholdTemperature']) heat_exchanger_air_to_air_sensible_and_latent.setInitialDefrostTimeFraction(erv_info['InitialDefrostTimeFraction']) update_sys_name(heat_exchanger_air_to_air_sensible_and_latent.airLoopHVAC.get, sys_hr: 'erv') return true end # Determine if demand control ventilation (DCV) is # required for this air loop. # # @param (see #economizer_required?) # @return [Bool] Returns true if required, false if not. # @todo Add exception logic for # systems that serve multifamily, parking garage, warehouse def air_loop_hvac_demand_control_ventilation_required?(air_loop_hvac, climate_zone) OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{template} #{climate_zone}: #{air_loop_hvac.name}: DCV is not required for any system.") dcv_required = false return dcv_required end # Set the VAV damper control to single maximum or # dual maximum control depending on the standard. # # @return [Bool] Returns true if successful, false if not # @todo see if this impacts the sizing run. def air_loop_hvac_apply_vav_damper_action(air_loop_hvac) damper_action = 'Single Maximum' # Interpret this as an EnergyPlus input damper_action_eplus = nil if damper_action == 'Single Maximum' damper_action_eplus = 'Normal' elsif damper_action == 'Dual Maximum' # EnergyPlus 8.7 changed the meaning of 'Reverse'. # For versions of OpenStudio using E+ 8.6 or lower damper_action_eplus = if air_loop_hvac.model.version < OpenStudio::VersionString.new('2.0.5') 'Reverse' # For versions of OpenStudio using E+ 8.7 or higher else 'ReverseWithLimits' end end # Set the control for any VAV reheat terminals # on this airloop. control_type_set = false air_loop_hvac.demandComponents.each do |equip| if equip.to_AirTerminalSingleDuctVAVReheat.is_initialized term = equip.to_AirTerminalSingleDuctVAVReheat.get # Dual maximum only applies to terminals with HW reheat coils if damper_action == 'Dual Maximum' if term.reheatCoil.to_CoilHeatingWater.is_initialized term.setDamperHeatingAction(damper_action_eplus) control_type_set = true end else term.setDamperHeatingAction(damper_action_eplus) control_type_set = true term.setMaximumFlowFractionDuringReheat(0.5) end end end if control_type_set OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}: VAV damper action was set to #{damper_action} control.") end return true end # NECB has no single zone air loop control requirements # # @return [Bool] returns true if successful, false if not def air_loop_hvac_apply_single_zone_controls(air_loop_hvac, climate_zone) OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.AirLoopHVAC', "For #{air_loop_hvac.name}: No special economizer controls were modeled.") return true end # NECB doesn't require static pressure reset. # # return [Bool] returns true if static pressure reset is required, false if not def air_loop_hvac_static_pressure_reset_required?(air_loop_hvac, has_ddc) # static pressure reset not required sp_reset_required = false return sp_reset_required end # Determine the air flow and number of story limits # for whether motorized OA damper is required. # @return [Array] [minimum_oa_flow_cfm, maximum_stories]. # If both nil, never required def air_loop_hvac_motorized_oa_damper_limits(air_loop_hvac, climate_zone) minimum_oa_flow_cfm = 0 maximum_stories = 0 return [minimum_oa_flow_cfm, maximum_stories] end # Applies the standard efficiency ratings and typical performance curves to this object. # # @param boiler_hot_water [OpenStudio::Model::BoilerHotWater] the object to modify # @return [Bool] true if successful, false if not def boiler_hot_water_apply_efficiency_and_curves(boiler_hot_water) successfully_set_all_properties = false # Define the criteria to find the boiler properties # in the hvac standards data set. search_criteria = boiler_hot_water_find_search_criteria(boiler_hot_water) fuel_type = search_criteria['fuel_type'] fluid_type = search_criteria['fluid_type'] # Get the capacity capacity_w = boiler_hot_water_find_capacity(boiler_hot_water) # Check if secondary and/or modulating boiler required if capacity_w / 1000.0 >= 352.0 if boiler_hot_water.name.to_s.include?('Primary Boiler') boiler_capacity = capacity_w boiler_hot_water.setBoilerFlowMode('LeavingSetpointModulated') boiler_hot_water.setMinimumPartLoadRatio(0.25) elsif boiler_hot_water.name.to_s.include?('Secondary Boiler') boiler_capacity = 0.001 end elsif ((capacity_w / 1000.0) >= 176.0) && ((capacity_w / 1000.0) < 352.0) boiler_capacity = capacity_w / 2 elsif (capacity_w / 1000.0) <= 176.0 if boiler_hot_water.name.to_s.include?('Primary Boiler') boiler_capacity = capacity_w elsif boiler_hot_water.name.to_s.include?('Secondary Boiler') boiler_capacity = 0.001 end end boiler_hot_water.setNominalCapacity(boiler_capacity) # Convert capacity to Btu/hr capacity_btu_per_hr = OpenStudio.convert(boiler_capacity, 'W', 'Btu/hr').get capacity_kbtu_per_hr = OpenStudio.convert(boiler_capacity, 'W', 'kBtu/hr').get # Get the boiler properties boiler_table = @standards_data['boilers'] blr_props = model_find_object(boiler_table, search_criteria, capacity_btu_per_hr) unless blr_props OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.BoilerHotWater', "For #{boiler_hot_water.name}, cannot find boiler properties, cannot apply efficiency standard.") successfully_set_all_properties = false return successfully_set_all_properties end # Make the EFFFPLR curve eff_fplr = model_add_curve(boiler_hot_water.model, blr_props['efffplr']) if eff_fplr boiler_hot_water.setNormalizedBoilerEfficiencyCurve(eff_fplr) else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.BoilerHotWater', "For #{boiler_hot_water.name}, cannot find eff_fplr curve, will not be set.") successfully_set_all_properties = false end # Get the minimum efficiency standards thermal_eff = nil # If specified as AFUE unless blr_props['minimum_annual_fuel_utilization_efficiency'].nil? min_afue = blr_props['minimum_annual_fuel_utilization_efficiency'] thermal_eff = afue_to_thermal_eff(min_afue) new_comp_name = "#{boiler_hot_water.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{min_afue} AFUE" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.BoilerHotWater', "For #{template}: #{boiler_hot_water.name}: #{fuel_type} #{fluid_type} Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; AFUE = #{min_afue}") end # If specified as thermal efficiency unless blr_props['minimum_thermal_efficiency'].nil? thermal_eff = blr_props['minimum_thermal_efficiency'] new_comp_name = "#{boiler_hot_water.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{thermal_eff} Thermal Eff" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.BoilerHotWater', "For #{template}: #{boiler_hot_water.name}: #{fuel_type} #{fluid_type} Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; Thermal Efficiency = #{thermal_eff}") end # If specified as combustion efficiency unless blr_props['minimum_combustion_efficiency'].nil? min_comb_eff = blr_props['minimum_combustion_efficiency'] thermal_eff = combustion_eff_to_thermal_eff(min_comb_eff) new_comp_name = "#{boiler_hot_water.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{min_comb_eff} Combustion Eff" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.BoilerHotWater', "For #{template}: #{boiler_hot_water.name}: #{fuel_type} #{fluid_type} Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; Combustion Efficiency = #{min_comb_eff}") end # Set the name boiler_hot_water.setName(new_comp_name) # Set the efficiency values unless thermal_eff.nil? boiler_hot_water.setNominalThermalEfficiency(thermal_eff) end return successfully_set_all_properties end # Applies the standard efficiency ratings and typical performance curves to this object. # # @return [Bool] true if successful, false if not def chiller_electric_eir_apply_efficiency_and_curves(chiller_electric_eir, clg_tower_objs) chillers = standards_data['chillers'] # Define the criteria to find the chiller properties # in the hvac standards data set. search_criteria = chiller_electric_eir_find_search_criteria(chiller_electric_eir) cooling_type = search_criteria['cooling_type'] condenser_type = search_criteria['condenser_type'] compressor_type = search_criteria['compressor_type'] # Get the chiller capacity capacity_w = chiller_electric_eir_find_capacity(chiller_electric_eir) # All chillers must be modulating down to 25% of their capacity chiller_electric_eir.setChillerFlowMode('LeavingSetpointModulated') chiller_electric_eir.setMinimumPartLoadRatio(0.25) chiller_electric_eir.setMinimumUnloadingRatio(0.25) if (capacity_w / 1000.0) < 2100.0 if chiller_electric_eir.name.to_s.include? 'Primary Chiller' chiller_capacity = capacity_w elsif chiller_electric_eir.name.to_s.include? 'Secondary Chiller' chiller_capacity = 0.001 end else chiller_capacity = capacity_w / 2.0 end chiller_electric_eir.setReferenceCapacity(chiller_capacity) # Convert capacity to tons capacity_tons = OpenStudio.convert(chiller_capacity, 'W', 'ton').get # Get the chiller properties chlr_table = @standards_data['chillers'] chlr_props = model_find_object(chlr_table, search_criteria, capacity_tons, Date.today) unless chlr_props OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.ChillerElectricEIR', "For #{chiller_electric_eir.name}, cannot find chiller properties, cannot apply standard efficiencies or curves.") successfully_set_all_properties = false return successfully_set_all_properties end # Make the CAPFT curve cool_cap_ft = model_add_curve(chiller_electric_eir.model, chlr_props['capft']) if cool_cap_ft chiller_electric_eir.setCoolingCapacityFunctionOfTemperature(cool_cap_ft) else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.ChillerElectricEIR', "For #{chiller_electric_eir.name}, cannot find cool_cap_ft curve, will not be set.") successfully_set_all_properties = false end # Make the EIRFT curve cool_eir_ft = model_add_curve(chiller_electric_eir.model, chlr_props['eirft']) if cool_eir_ft chiller_electric_eir.setElectricInputToCoolingOutputRatioFunctionOfTemperature(cool_eir_ft) else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.ChillerElectricEIR', "For #{chiller_electric_eir.name}, cannot find cool_eir_ft curve, will not be set.") successfully_set_all_properties = false end # Make the EIRFPLR curve # which may be either a CurveBicubic or a CurveQuadratic based on chiller type cool_plf_fplr = model_add_curve(chiller_electric_eir.model, chlr_props['eirfplr']) if cool_plf_fplr chiller_electric_eir.setElectricInputToCoolingOutputRatioFunctionOfPLR(cool_plf_fplr) else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.ChillerElectricEIR', "For #{chiller_electric_eir.name}, cannot find cool_plf_fplr curve, will not be set.") successfully_set_all_properties = false end # Set the efficiency value kw_per_ton = nil cop = nil if chlr_props['minimum_full_load_efficiency'] kw_per_ton = chlr_props['minimum_full_load_efficiency'] cop = kw_per_ton_to_cop(kw_per_ton) chiller_electric_eir.setReferenceCOP(cop) else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.ChillerElectricEIR', "For #{chiller_electric_eir.name}, cannot find minimum full load efficiency, will not be set.") successfully_set_all_properties = false end # Set cooling tower properties now that the new COP of the chiller is set if chiller_electric_eir.name.to_s.include? 'Primary Chiller' # Single speed tower model assumes 25% extra for compressor power tower_cap = capacity_w * (1.0 + 1.0 / chiller_electric_eir.referenceCOP) if (tower_cap / 1000.0) < 1750 clg_tower_objs[0].setNumberofCells(1) else clg_tower_objs[0].setNumberofCells((tower_cap / (1000 * 1750) + 0.5).round) end clg_tower_objs[0].setFanPoweratDesignAirFlowRate(0.015 * tower_cap) end # Append the name with size and kw/ton chiller_electric_eir.setName("#{chiller_electric_eir.name} #{capacity_tons.round}tons #{kw_per_ton.round(1)}kW/ton") OpenStudio.logFree(OpenStudio::Info, 'openstudio.model.ChillerElectricEIR', "For #{template}: #{chiller_electric_eir.name}: #{cooling_type} #{condenser_type} #{compressor_type} Capacity = #{capacity_tons.round}tons; COP = #{cop.round(1)} (#{kw_per_ton.round(1)}kW/ton)") return successfully_set_all_properties end # find search criteria # # @return [Hash] used for standards_lookup_table(model) def coil_heating_gas_find_search_criteria # Define the criteria to find the furnace properties # in the hvac standards data set. search_criteria = {} search_criteria['fluid_type'] = 'Air' search_criteria['fuel_type'] = 'Gas' return search_criteria end # find furnace capacity # # @return [Hash] used for standards_lookup_table(model) def coil_heating_gas_find_capacity(coil_heating_gas) # Get the coil capacity capacity_w = nil if coil_heating_gas.nominalCapacity.is_initialized capacity_w = coil_heating_gas.nominalCapacity.get elsif coil_heating_gas.autosizedNominalCapacity.is_initialized capacity_w = coil_heating_gas.autosizedNominalCapacity.get else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilHeatingGas', "For #{coil_heating_gas.name} capacity is not available, cannot apply efficiency standard.") successfully_set_all_properties = false return successfully_set_all_properties end return capacity_w end # Finds lookup object in standards and return minimum thermal efficiency # # @return [Double] minimum thermal efficiency def coil_heating_gas_standard_minimum_thermal_efficiency(coil_heating_gas, rename = false) # Get the coil properties search_criteria = coil_heating_gas_find_search_criteria capacity_w = coil_heating_gas_find_capacity(coil_heating_gas) capacity_btu_per_hr = OpenStudio.convert(capacity_w, 'W', 'Btu/hr').get capacity_kbtu_per_hr = OpenStudio.convert(capacity_w, 'W', 'kBtu/hr').get # Get the minimum efficiency standards thermal_eff = nil # Get the coil properties coil_table = @standards_data['furnaces'] coil_props = model_find_object(coil_table, search_criteria, [capacity_btu_per_hr, 0.001].max) unless coil_props OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilHeatingGas', "For #{coil_heating_gas.name}, cannot find coil props, cannot apply efficiency standard.") successfully_set_all_properties = false return successfully_set_all_properties end # New name initial value new_comp_name = coil_heating_gas.name # If specified as AFUE unless coil_props['minimum_annual_fuel_utilization_efficiency'].nil? min_afue = coil_props['minimum_annual_fuel_utilization_efficiency'] thermal_eff = afue_to_thermal_eff(min_afue) new_comp_name = "#{coil_heating_gas.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{min_afue} AFUE" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.CoilHeatingGas', "For #{template}: #{coil_heating_gas.name}: Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; AFUE = #{min_afue}") end # If specified as thermal efficiency unless coil_props['minimum_thermal_efficiency'].nil? thermal_eff = coil_props['minimum_thermal_efficiency'] new_comp_name = "#{coil_heating_gas.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{thermal_eff} Thermal Eff" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.CoilHeatingGas', "For #{template}: #{coil_heating_gas.name}: Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; Thermal Efficiency = #{thermal_eff}") end # If specified as combustion efficiency unless coil_props['minimum_combustion_efficiency'].nil? min_comb_eff = coil_props['minimum_combustion_efficiency'] thermal_eff = combustion_eff_to_thermal_eff(min_comb_eff) new_comp_name = "#{coil_heating_gas.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{min_comb_eff} Combustion Eff" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.CoilHeatingGas', "For #{template}: #{coil_heating_gas.name}: Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; Combustion Efficiency = #{min_comb_eff}") end unless thermal_eff OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilHeatingGas', "For #{CoilHeatingGas.name}, cannot find coil efficiency, cannot apply efficiency standard.") successfully_set_all_properties = false return successfully_set_all_properties end # Rename if rename coil_heating_gas.setName(new_comp_name) end return thermal_eff end # Applies the standard efficiency ratings and typical performance curves to this object. # # @return [Bool] true if successful, false if not def coil_heating_gas_apply_efficiency_and_curves(coil_heating_gas) successfully_set_all_properties = true # Define the search criteria search_criteria = coil_heating_gas_find_search_criteria # Get the coil capacity capacity_w = coil_heating_gas_find_capacity(coil_heating_gas) capacity_btu_per_hr = OpenStudio.convert(capacity_w, 'W', 'Btu/hr').get # lookup properties coil_table = @standards_data['furnaces'] coil_props = model_find_object(coil_table, search_criteria, [capacity_btu_per_hr, 0.001].max, Date.today) # Check to make sure properties were found if coil_props.nil? OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilHeatingGas', "For #{coil_heating_gas.name}, cannot find efficiency info using #{search_criteria}, cannot apply efficiency standard.") successfully_set_all_properties = false end # Make the plf vs plr curve plffplr_curve = model_add_curve(coil_heating_gas.model, coil_props['efffplr']) if plffplr_curve coil_heating_gas.setPartLoadFractionCorrelationCurve(plffplr_curve) else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilHeatingGas', "For #{coil_heating_gas.name}, cannot find plffplr curve, will not be set.") successfully_set_all_properties = false end # Thermal efficiency thermal_eff = coil_heating_gas_standard_minimum_thermal_efficiency(coil_heating_gas) # Set the efficiency values coil_heating_gas.setGasBurnerEfficiency(thermal_eff.to_f) return successfully_set_all_properties end # Applies the standard efficiency ratings and typical performance curves to this object. # # @return [Bool] true if successful, false if not def coil_cooling_dx_multi_speed_apply_efficiency_and_curves(coil_cooling_dx_multi_speed, sql_db_vars_map) successfully_set_all_properties = true model = coil_cooling_dx_multi_speed.model multi_speed_heat_pump = coil_cooling_dx_multi_speed.containingHVACComponent.get.to_AirLoopHVACUnitaryHeatPumpAirToAirMultiSpeed.get airloop = multi_speed_heat_pump.airLoopHVAC.get # Define the criteria to find the properties in the hvac standards data set search_criteria = coil_dx_find_search_criteria(coil_cooling_dx_multi_speed) capacity_w = coil_cooling_dx_multi_speed_find_capacity(coil_cooling_dx_multi_speed) # Find design outside air flow rate and flow fraction controller_oa = nil if airloop.airLoopHVACOutdoorAirSystem.is_initialized oa_system = airloop.airLoopHVACOutdoorAirSystem.get controller_oa = oa_system.getControllerOutdoorAir end min_oa_flow_rate = 0.0 oaf = 0.0 if controller_oa min_oa_flow_rate = nil if controller_oa.minimumOutdoorAirFlowRate.is_initialized min_oa_flow_rate = controller_oa.minimumOutdoorAirFlowRate.get elsif controller_oa.autosizedMinimumOutdoorAirFlowRate.is_initialized min_oa_flow_rate = controller_oa.autosizedMinimumOutdoorAirFlowRate.get end if min_oa_flow_rate then oaf = min_oa_flow_rate.to_f / airloop.autosizedDesignSupplyAirFlowRate.to_f end end # Find required capacity of each stage and total number of stages based on NECB rules # This implementation is limited to 4 stages only. The capacity of stages 1-3 is set to # 66 kW as stipulated by NECB. The capacity of the 4th stage is then allowed to exceed 66 kW # up to the design capacity. stage_cap = [] num_stages = (capacity_w / (66.0 * 1000.0) + 0.5).round max_cap = 66.0 * 1000.0 * num_stages final_num_stages = num_stages case num_stages when 1 stage_cap[0] = capacity_w / 2.0 stage_cap[1] = 2.0 * stage_cap[0] final_num_stages = 2 else stage_cap[0] = 66.0 * 1000.0 stage_cap[1] = 2.0 * stage_cap[0] case num_stages when 2 when 3 stage_cap[2] = 3.0 * stage_cap[0] else final_num_stages = 4 stage_cap[2] = 3.0 * stage_cap[0] stage_cap[3] = max_cap end end # Set final number of cooling stages and create missing stages if needed for istage in 2..final_num_stages - 1 new_clg_stage = OpenStudio::Model::CoilCoolingDXMultiSpeedStageData.new(model) coil_cooling_dx_multi_speed.addStage(new_clg_stage) end multi_speed_heat_pump.setNumberofSpeedsforCooling(final_num_stages) # Set final capacities for each of the stages. The flow rate for each of the stages # is maintained above the outside air flow rate coil_cooling_dx_multi_speed.stages[0].setGrossRatedTotalCoolingCapacity(stage_cap[0]) coil_cooling_dx_multi_speed.stages[1].setGrossRatedTotalCoolingCapacity(stage_cap[1]) case coil_cooling_dx_multi_speed.stages.size when 2 if oaf > 0.5 then multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) end when 3 coil_cooling_dx_multi_speed.stages[2].setGrossRatedTotalCoolingCapacity(stage_cap[2]) if (oaf > 0.333) && (oaf <= 0.666) multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) elsif oaf > 0.666 multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed2SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) end when 4 coil_cooling_dx_multi_speed.stages[2].setGrossRatedTotalCoolingCapacity(stage_cap[2]) coil_cooling_dx_multi_speed.stages[3].setGrossRatedTotalCoolingCapacity(stage_cap[3]) if (oaf > 0.25) && (oaf <= 0.5) multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) elsif (oaf > 0.5) && (oaf <= 0.75) multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed2SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) elsif oaf > 0.75 multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed2SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed3SupplyAirFlowRateDuringCoolingOperation(min_oa_flow_rate) end end capacity_btu_per_hr = OpenStudio.convert(stage_cap.last, 'W', 'Btu/hr').get capacity_kbtu_per_hr = OpenStudio.convert(stage_cap.last, 'W', 'kBtu/hr').get # Lookup efficiencies depending on whether it is a unitary AC or a heat pump ac_props = nil ac_props = if coil_dx_heat_pump?(coil_cooling_dx_multi_speed) model_find_object(standards_data['heat_pumps'], search_criteria, capacity_btu_per_hr, Date.today) else model_find_object(standards_data['unitary_acs'], search_criteria, capacity_btu_per_hr, Date.today) end # Check to make sure properties were found if ac_props.nil? OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilCoolingDXMultiSpeed', "For #{coil_cooling_dx_multi_speed.name}, cannot find efficiency info, cannot apply efficiency standard.") successfully_set_all_properties = false return sql_db_vars_map end # get clg stages clg_stages = coil_cooling_dx_multi_speed.stages # Make the COOL-CAP-FT curve cool_cap_ft = model_add_curve(model, ac_props['cool_cap_ft']) if cool_cap_ft clg_stages.sort.each do |stage| stage.setTotalCoolingCapacityFunctionofTemperatureCurve(cool_cap_ft) end else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilCoolingDXMultiSpeed', "For #{coil_cooling_dx_multi_speed.name}, cannot find cool_cap_ft curve, will not be set.") successfully_set_all_properties = false return sql_db_vars_map end # Make the COOL-CAP-FFLOW curve cool_cap_fflow = model_add_curve(model, ac_props['cool_cap_fflow']) if cool_cap_fflow clg_stages.sort.each do |stage| stage.setTotalCoolingCapacityFunctionofFlowFractionCurve(cool_cap_fflow) end else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilCoolingDXMultiSpeed', "For #{coil_cooling_dx_multi_speed.name}, cannot find cool_cap_fflow curve, will not be set.") successfully_set_all_properties = false return sql_db_vars_map end # Make the COOL-EIR-FT curve cool_eir_ft = model_add_curve(model, ac_props['cool_eir_ft']) if cool_eir_ft clg_stages.sort.each do |stage| stage.setEnergyInputRatioFunctionofTemperatureCurve(cool_eir_ft) end else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilCoolingDXMultiSpeed', "For #{coil_cooling_dx_multi_speed.name}, cannot find cool_eir_ft curve, will not be set.") successfully_set_all_properties = false return sql_db_vars_map end # Make the COOL-EIR-FFLOW curve cool_eir_fflow = model_add_curve(model, ac_props['cool_eir_fflow']) if cool_eir_fflow clg_stages.sort.each do |stage| stage.setEnergyInputRatioFunctionofFlowFractionCurve(cool_eir_fflow) end else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilCoolingDXMultiSpeed', "For #{coil_cooling_dx_multi_speed.name}, cannot find cool_eir_fflow curve, will not be set.") successfully_set_all_properties = false return sql_db_vars_map end # Make the COOL-PLF-FPLR curve cool_plf_fplr = model_add_curve(model, ac_props['cool_plf_fplr']) if cool_plf_fplr clg_stages.sort.each do |stage| stage.setPartLoadFractionCorrelationCurve(cool_plf_fplr) end else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilCoolingDXMultiSpeed', "For #{coil_cooling_dx_multi_speed.name}, cannot find cool_plf_fplr curve, will not be set.") successfully_set_all_properties = false return sql_db_vars_map end # Set the COP values cop, new_comp_name = coil_cooling_dx_multi_speed_standard_minimum_cop(coil_cooling_dx_multi_speed) unless cop.nil? clg_stages.sort.each do |curr_istage| curr_istage.setGrossRatedCoolingCOP(cop) end end sql_db_vars_map[new_comp_name] = coil_cooling_dx_multi_speed.name.to_s coil_cooling_dx_multi_speed.setName(new_comp_name) # It was found that the heat pump OS object doesn't respond to the call to turn on from the # system availability manager night cycle. This EMS script is then implemented to check the status # of the system availability manager night cycle and force the heat pump to turn on when needed. The # heat pump is still turned on when its availability schedule calls for it. create_ems_to_turn_on_AirLoopHVACUnitaryHeatPumpAirToAirMultiSpeed_for_night_cycle(multi_speed_heat_pump) return sql_db_vars_map end # Create EMS to turn on "AirLoopHVACUnitaryHeatPumpAirToAirMultiSpeed" in response to a call # from the night cycle availability manager of the air loop. It was found that this object # doesn't respond properly to this call from the night cycle def create_ems_to_turn_on_AirLoopHVACUnitaryHeatPumpAirToAirMultiSpeed_for_night_cycle(multi_speed_heat_pump) model = multi_speed_heat_pump.model avail_manager_name = nil if multi_speed_heat_pump.airLoopHVAC.is_initialized if !multi_speed_heat_pump.airLoopHVAC.get.availabilityManagers.empty? avail_manager_name = multi_speed_heat_pump.airLoopHVAC.get.availabilityManagers[0].name.to_s end end return unless avail_manager_name avail_manager_out_var_name = 'Availability Manager Night Cycle Control Status' avail_manager_out_var = OpenStudio::Model::OutputVariable.new(avail_manager_out_var_name, model) avail_manager_out_var.setKeyValue(avail_manager_name) avail_manager_out_var.setReportingFrequency('Timestep') night_cycle_sensor = OpenStudio::Model::EnergyManagementSystemSensor.new(model, avail_manager_out_var) heat_pump_avail_sch = nil if multi_speed_heat_pump.availabilitySchedule.is_initialized heat_pump_avail_sch = multi_speed_heat_pump.availabilitySchedule.get elsif multi_speed_heat_pump.airLoopHVAC.get.availabilitySchedule.is_initialized heat_pump_avail_sch = multi_speed_heat_pump.airLoopHVAC.get.availabilitySchedule.get else heat_pump_avail_sch = OpenStudio::Model::ScheduleConstant.new(model) heat_pump_avail_sch.setValue(1.0) end heat_pump_avail_sch_var = OpenStudio::Model::OutputVariable.new('Schedule Value', model) heat_pump_avail_sch_var.setKeyValue(heat_pump_avail_sch.name.to_s) heat_pump_avail_sch_sensor = OpenStudio::Model::EnergyManagementSystemSensor.new(model, heat_pump_avail_sch_var) updated_heat_pump_avail_sch = OpenStudio::Model::ScheduleConstant.new(model) multi_speed_heat_pump.setAvailabilitySchedule(updated_heat_pump_avail_sch) heat_pump_avail_sch_actuator = OpenStudio::Model::EnergyManagementSystemActuator.new(updated_heat_pump_avail_sch, 'Schedule:Constant', 'Schedule Value') heat_pump_avail_sch_prog = OpenStudio::Model::EnergyManagementSystemProgram.new(model) heat_pump_avail_sch_prog.setName("#{multi_speed_heat_pump.name.to_s.gsub(/[ +-.]/, '_')} Availability Schedule Program by Line") heat_pump_avail_sch_prog_body = <<-EMS IF #{heat_pump_avail_sch_sensor.handle} > 0.0 SET #{heat_pump_avail_sch_actuator.handle} = #{heat_pump_avail_sch_sensor.handle} ELSEIF #{night_cycle_sensor.handle} == 2.0 SET #{heat_pump_avail_sch_actuator.handle} = 1.0 ELSE SET #{heat_pump_avail_sch_actuator.handle} = 0.0 ENDIF EMS heat_pump_avail_sch_prog.setBody(heat_pump_avail_sch_prog_body) pcm = OpenStudio::Model::EnergyManagementSystemProgramCallingManager.new(model) pcm.setName("#{heat_pump_avail_sch_prog.name.to_s.gsub(/[ +-.]/, '_')} Calling Manager") pcm.setCallingPoint('InsideHVACSystemIterationLoop') pcm.addProgram(heat_pump_avail_sch_prog) end # Applies the standard efficiency ratings and typical performance curves to this object. # # @return [Bool] true if successful, false if not def coil_heating_gas_multi_stage_apply_efficiency_and_curves(coil_heating_gas_multi_stage) successfully_set_all_properties = true model = coil_heating_gas_multi_stage.model # get multi speed heat pump and air loop multi_speed_heat_pump = nil multi_speed_heat_pumps = model.getAirLoopHVACUnitaryHeatPumpAirToAirMultiSpeeds multi_speed_heat_pumps.sort.each do |iheat_pump| htg_coil = iheat_pump.heatingCoil if htg_coil.name.to_s.strip == coil_heating_gas_multi_stage.name.to_s.strip multi_speed_heat_pump = iheat_pump break end end airloop = multi_speed_heat_pump.airLoopHVAC.get # Define the criteria to find the properties in the hvac standards data set. search_criteria = coil_heating_gas_multi_stage_find_search_criteria(coil_heating_gas_multi_stage) fuel_type = search_criteria['fuel_type'] capacity_w = coil_heating_gas_multi_stage_find_capacity(coil_heating_gas_multi_stage) # Find system design outside air flow rate and fraction controller_oa = nil if airloop.airLoopHVACOutdoorAirSystem.is_initialized oa_system = airloop.airLoopHVACOutdoorAirSystem.get controller_oa = oa_system.getControllerOutdoorAir end min_oa_flow_rate = 0.0 oaf = 0.0 if controller_oa min_oa_flow_rate = nil if controller_oa.minimumOutdoorAirFlowRate.is_initialized min_oa_flow_rate = controller_oa.minimumOutdoorAirFlowRate.get elsif controller_oa.autosizedMinimumOutdoorAirFlowRate.is_initialized min_oa_flow_rate = controller_oa.autosizedMinimumOutdoorAirFlowRate.get end if min_oa_flow_rate then oaf = min_oa_flow_rate.to_f / airloop.autosizedDesignSupplyAirFlowRate.to_f end end # Find capacities of each of the stages and the total number of stages required based on NECB rules. # This implementation is limited to 4 stages. The capacity of stages 1-3 is set to 66 kW as stipulated # by NECB. The capacity of the 4th stage can exceed 66 kW up to the design capacity. htg_stages = coil_heating_gas_multi_stage.stages num_stages = (capacity_w / (66.0 * 1000.0) + 0.5).round max_cap = 66.0 * 1000.0 * num_stages stage_cap = [] final_num_stages = num_stages if capacity_w == 0.001 final_num_stages = 1 stage_cap[0] = capacity_w else case num_stages when 1 stage_cap[0] = capacity_w / 2.0 stage_cap[1] = 2.0 * stage_cap[0] final_num_stages = 2 else stage_cap[0] = 66.0 * 1000.0 stage_cap[1] = 2.0 * stage_cap[0] case num_stages when 2 when 3 stage_cap[2] = 3.0 * stage_cap[0] else final_num_stages = 4 stage_cap[2] = 3.0 * stage_cap[0] stage_cap[3] = max_cap end end end # Set final number of stages and create missing stages if needed for istage in 1..final_num_stages - 1 new_htg_stage = OpenStudio::Model::CoilHeatingGasMultiStageStageData.new(model) coil_heating_gas_multi_stage.addStage(new_htg_stage) end multi_speed_heat_pump.setNumberofSpeedsforHeating(final_num_stages) # Set final capacities for each of the stages. The air flow rate for each of the stages # is maintained above the outside air flow rate coil_heating_gas_multi_stage.stages[0].setNominalCapacity(stage_cap[0]) case coil_heating_gas_multi_stage.stages.size when 2 coil_heating_gas_multi_stage.stages[1].setNominalCapacity(stage_cap[1]) if oaf > 0.5 then multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) end when 3 coil_heating_gas_multi_stage.stages[1].setNominalCapacity(stage_cap[1]) coil_heating_gas_multi_stage.stages[2].setNominalCapacity(stage_cap[2]) if (oaf > 0.333) && (oaf <= 0.666) multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) elsif oaf > 0.666 multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed2SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) end when 4 coil_heating_gas_multi_stage.stages[1].setNominalCapacity(stage_cap[1]) coil_heating_gas_multi_stage.stages[2].setNominalCapacity(stage_cap[2]) coil_heating_gas_multi_stage.stages[3].setNominalCapacity(stage_cap[3]) if (oaf > 0.25) && (oaf <= 0.5) multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) elsif (oaf > 0.5) && (oaf <= 0.75) multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed2SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) elsif oaf > 0.75 multi_speed_heat_pump.setSpeed1SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed2SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) multi_speed_heat_pump.setSpeed3SupplyAirFlowRateDuringHeatingOperation(min_oa_flow_rate) end end # Convert capacity to Btu/hr capacity_btu_per_hr = OpenStudio.convert(stage_cap.last, 'W', 'Btu/hr').get capacity_kbtu_per_hr = OpenStudio.convert(stage_cap.last, 'W', 'kBtu/hr').get # Lookup efficiencies heater_props = nil heater_props = model_find_object(standards_data['furnaces'], search_criteria, capacity_btu_per_hr, Date.today) # Check to make sure properties were found if heater_props.nil? OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilHeatingGasMultiSpeed', "For #{coil_heating_gas_multi_stage.name}, cannot find efficiency info, cannot apply efficiency standard.") successfully_set_all_properties = false return successfully_set_all_properties end # Make the EFFPLR curve efffplr = model_add_curve(coil_heating_gas_multi_stage.model, heater_props['efffplr']) if efffplr coil_heating_gas_multi_stage.setPartLoadFractionCorrelationCurve(efffplr) else OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.CoilHeatingGasMultiStage', "For #{coil_heating_gas_multi_stage.name}, cannot find efffplr curve, will not be set.") successfully_set_all_properties = false return successfully_set_all_properties end # Get the minimum efficiency standards thermal_eff = nil # If specified as AFUE unless heater_props['minimum_annual_fuel_utilization_efficiency'].nil? min_afue = heater_props['minimum_annual_fuel_utilization_efficiency'] thermal_eff = afue_to_thermal_eff(min_afue) new_comp_name = "#{coil_heating_gas_multi_stage.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{min_afue} AFUE" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.CoilHeatingGasMultiStage', "For #{template}: #{coil_heating_gas_multi_stage.name}: #{fuel_type} Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; AFUE = #{min_afue}") end # If specified as thermal efficiency unless heater_props['minimum_thermal_efficiency'].nil? thermal_eff = heater_props['minimum_thermal_efficiency'] new_comp_name = "#{coil_heating_gas_multi_stage.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{thermal_eff} Thermal Eff" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.CoilHeatingGasMultiStage', "For #{template}: #{coil_heating_gas_multi_stage.name}: #{fuel_type} Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; Thermal Efficiency = #{thermal_eff}") end # If specified as combustion efficiency unless heater_props['minimum_combustion_efficiency'].nil? min_comb_eff = heater_props['minimum_combustion_efficiency'] thermal_eff = combustion_eff_to_thermal_eff(min_comb_eff) new_comp_name = "#{coil_heating_gas_multi_stage.name} #{capacity_kbtu_per_hr.round}kBtu/hr #{min_comb_eff} Combustion Eff" OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.BoilerHotWater', "For #{template}: #{coil_heating_gas_multi_stage.name}: #{fuel_type} Capacity = #{capacity_kbtu_per_hr.round}kBtu/hr; Combustion Efficiency = #{min_comb_eff}") end coil_heating_gas_multi_stage.setName(new_comp_name) # Set the name coil_heating_gas_multi_stage.setName(new_comp_name) # Get heating stages htg_stages = coil_heating_gas_multi_stage.stages # Set the efficiency values unless thermal_eff.nil? htg_stages.sort.each do |stage| stage.setGasBurnerEfficiency(thermal_eff) end end return successfully_set_all_properties end # Determines the baseline fan impeller efficiency # based on the specified fan type. # # @return [Double] impeller efficiency (0.0 to 1.0) # @todo Add fan type to data model and modify this method def fan_baseline_impeller_efficiency(fan) # Assume that the fan efficiency is 65% for normal fans # TODO add fan type to fan data model # and infer impeller efficiency from that? # or do we always assume a certain type of # fan impeller for the baseline system? # TODO check COMNET and T24 ACM and PNNL 90.1 doc fan_impeller_eff = 0.65 return fan_impeller_eff end # Determines the minimum fan motor efficiency and nominal size # for a given motor bhp. This should be the total brake horsepower with # any desired safety factor already included. This method picks # the next nominal motor catgory larger than the required brake # horsepower, and the efficiency is based on that size. For example, # if the bhp = 6.3, the nominal size will be 7.5HP and the efficiency # for 90.1-2010 will be 91.7% from Table 10.8B. This method assumes # 4-pole, 1800rpm totally-enclosed fan-cooled motors. # # @param motor_bhp [Double] motor brake horsepower (hp) # @return [Array] minimum motor efficiency (0.0 to 1.0), nominal horsepower def fan_standard_minimum_motor_efficiency_and_size(fan, motor_bhp) fan_motor_eff = 0.85 nominal_hp = motor_bhp # Don't attempt to look up motor efficiency # for zero-hp fans, which may occur when there is no # airflow required for a particular system, typically # heated-only spaces with high internal gains # and no OA requirements such as elevator shafts. return [fan_motor_eff, 0] if motor_bhp == 0.0 # Lookup the minimum motor efficiency motors_table = @standards_data['motors'] # Assuming all fan motors are 4-pole ODP motor_use = 'FAN' motor_type = '' if (fan.class.name == 'OpenStudio::Model::FanConstantVolume') || (fan.class.name == 'OpenStudio::Model::FanOnOff') motor_type = 'CONSTANT' elsif fan.class.name == 'OpenStudio::Model::FanVariableVolume' # Is this a return or supply fan if fan.name.to_s.include?('Supply') motor_type += 'VARIABLE-SUPPLY' elsif fan.name.to_s.include?('Return') motor_type += 'VARIABLE-RETURN' end # 0.909 corrects for 10% over sizing implemented upstream # 0.7457 is to convert from bhp to kW fan_power_kw = 0.909 * 0.7457 * motor_bhp power_vs_flow_curve_name = if fan_power_kw >= 25.0 'VarVolFan-FCInletVanes-NECB2011-FPLR' elsif fan_power_kw >= 7.5 && fan_power_kw < 25 'VarVolFan-AFBIInletVanes-NECB2011-FPLR' else 'VarVolFan-AFBIFanCurve-NECB2011-FPLR' end power_vs_flow_curve = model_add_curve(fan.model, power_vs_flow_curve_name) fan.setFanPowerMinimumFlowRateInputMethod('Fraction') fan.setFanPowerCoefficient5(0.0) fan.setFanPowerMinimumFlowFraction(power_vs_flow_curve.minimumValueofx) fan.setFanPowerCoefficient1(power_vs_flow_curve.coefficient1Constant) fan.setFanPowerCoefficient2(power_vs_flow_curve.coefficient2x) fan.setFanPowerCoefficient3(power_vs_flow_curve.coefficient3xPOW2) fan.setFanPowerCoefficient4(power_vs_flow_curve.coefficient4xPOW3) elsif fan.class.name == 'OpenStudio::Model::FanZoneExhaust' motor_type = 'CONSTANT-RETURN' else raise('') end search_criteria = { 'motor_use' => motor_use, 'motor_type' => motor_type, 'number_of_poles' => 4.0, 'type' => 'Enclosed' } # Exception for small fans, including # zone exhaust, fan coil, and fan powered terminals. # In this case, use the 0.5 HP for the lookup. if fan_small_fan?(fan) nominal_hp = 0.5 else motor_properties = model_find_object(motors_table, search_criteria, motor_bhp) if motor_properties.nil? OpenStudio.logFree(OpenStudio::Error, 'openstudio.standards.Fan', "For #{fan.name}, could not find motor properties using search criteria: #{search_criteria}, motor_bhp = #{motor_bhp} hp.") return [fan_motor_eff, nominal_hp] end nominal_hp = motor_properties['maximum_capacity'].to_f.round(1) # If the biggest fan motor size is hit, use the highest category efficiency if nominal_hp == 9999.0 OpenStudio.logFree(OpenStudio::Warn, 'openstudio.standards.Fan', "For #{fan.name}, there is no greater nominal HP. Use the efficiency of the largest motor category.") nominal_hp = motor_bhp end # Round to nearest whole HP for niceness if nominal_hp >= 2 nominal_hp = nominal_hp.round end end # Get the efficiency based on the nominal horsepower # Add 0.01 hp to avoid search errors. motor_properties = model_find_object(motors_table, search_criteria, nominal_hp + 0.01) if motor_properties.nil? OpenStudio.logFree(OpenStudio::Error, 'openstudio.standards.Fan', "For #{fan.name}, could not find nominal motor properties using search criteria: #{search_criteria}, motor_hp = #{nominal_hp} hp.") return [fan_motor_eff, nominal_hp] end fan_motor_eff = motor_properties['nominal_full_load_efficiency'] return [fan_motor_eff, nominal_hp] end # Determines the minimum pump motor efficiency and nominal size # for a given motor bhp. This should be the total brake horsepower with # any desired safety factor already included. This method picks # the next nominal motor catgory larger than the required brake # horsepower, and the efficiency is based on that size. For example, # if the bhp = 6.3, the nominal size will be 7.5HP and the efficiency # for 90.1-2010 will be 91.7% from Table 10.8B. This method assumes # 4-pole, 1800rpm totally-enclosed fan-cooled motors. # # @param motor_bhp [Double] motor brake horsepower (hp) # @return [Array] minimum motor efficiency (0.0 to 1.0), nominal horsepower def pump_standard_minimum_motor_efficiency_and_size(pump, motor_bhp) motor_eff = 0.85 nominal_hp = motor_bhp # Don't attempt to look up motor efficiency # for zero-hp pumps (required for circulation-pump-free # service water heating systems). return [1.0, 0] if motor_bhp == 0.0 # Lookup the minimum motor efficiency motors = @standards_data['motors'] # Assuming all pump motors are 4-pole ODP search_criteria = { 'motor_use' => 'PUMP', 'number_of_poles' => 4.0, 'type' => 'Enclosed' } motor_properties = model_find_object(motors, search_criteria, motor_bhp) if motor_properties.nil? OpenStudio.logFree(OpenStudio::Error, 'openstudio.standards.Pump', "For #{pump.name}, could not find motor properties using search criteria: #{search_criteria}, motor_bhp = #{motor_bhp} hp.") return [motor_eff, nominal_hp] end motor_eff = motor_properties['nominal_full_load_efficiency'] nominal_hp = motor_properties['maximum_capacity'].to_f.round(1) # Round to nearest whole HP for niceness if nominal_hp >= 2 nominal_hp = nominal_hp.round end # Get the efficiency based on the nominal horsepower # Add 0.01 hp to avoid search errors. motor_properties = model_find_object(motors, search_criteria, nominal_hp + 0.01) if motor_properties.nil? OpenStudio.logFree(OpenStudio::Error, 'openstudio.standards.Fan', "For #{pump.name}, could not find nominal motor properties using search criteria: #{search_criteria}, motor_hp = #{nominal_hp} hp.") return [motor_eff, nominal_hp] end motor_eff = motor_properties['nominal_full_load_efficiency'] return [motor_eff, nominal_hp] end # Determines whether there is a requirement to have a # VSD or some other method to reduce fan power # at low part load ratios. def fan_variable_volume_part_load_fan_power_limitation?(fan_variable_volume) part_load_control_required = false return part_load_control_required end # Determine if demand control ventilation (DCV) is # required for this zone based on area and occupant density. # Does not account for System requirements like ERV, economizer, etc. # Those are accounted for in the AirLoopHVAC method of the same name. # # @return [Bool] Returns true if required, false if not. # @todo Add exception logic for 90.1-2013 # for cells, sickrooms, labs, barbers, salons, and bowling alleys def thermal_zone_demand_control_ventilation_required?(thermal_zone, climate_zone) return false end def model_apply_sizing_parameters(model) model.getSizingParameters.setHeatingSizingFactor(get_standards_constant('sizing_factor_max_heating')) model.getSizingParameters.setCoolingSizingFactor(get_standards_constant('sizing_factor_max_cooling')) OpenStudio.logFree(OpenStudio::Info, 'openstudio.prototype.Model', "Set sizing factors to #{get_standards_constant('sizing_factor_max_heating')} for heating and #{get_standards_constant('sizing_factor_max_heating')} for cooling.") end def fan_constant_volume_apply_prototype_fan_pressure_rise(fan_constant_volume) fan_constant_volume.setPressureRise(get_standards_constant('fan_constant_volume_pressure_rise_value')) return true end # Determine and set type of part load control type for heating and chilled # water variable speed pumps # # @param pump [OpenStudio::Model::PumpVariableSpeed] OpenStudio pump object # @return [Boolean] Returns true if applicable, false otherwise def pump_variable_speed_control_type(pump) return false end # Sets the fan pressure rise based on the Prototype buildings inputs # which are governed by the flow rate coming through the fan # and whether the fan lives inside a unit heater, PTAC, etc. def fan_variable_volume_apply_prototype_fan_pressure_rise(fan_variable_volume) # 1000 Pa for supply fan and 458.33 Pa for return fan (accounts for efficiency differences between two fans) if fan_variable_volume.name.to_s.include?('Supply') sfan_deltaP = get_standards_constant('supply_fan_variable_volume_pressure_rise_value') fan_variable_volume.setPressureRise(sfan_deltaP) elsif fan_variable_volume.name.to_s.include?('Return') rfan_deltaP = get_standards_constant('return_fan_variable_volume_pressure_rise_value') fan_variable_volume.setPressureRise(rfan_deltaP) end return true end def apply_economizers(climate_zone, model) # NECB2011 prescribes ability to provide 100% OA (5.2.2.7-5.2.2.9) econ_max_100_pct_oa_sch = OpenStudio::Model::ScheduleRuleset.new(model) econ_max_100_pct_oa_sch.setName('Economizer Max OA Fraction 100 pct') econ_max_100_pct_oa_sch.defaultDaySchedule.setName('Economizer Max OA Fraction 100 pct Default') econ_max_100_pct_oa_sch.defaultDaySchedule.addValue(OpenStudio::Time.new(0, 24, 0, 0), 1.0) # Check each airloop model.getAirLoopHVACs.sort.each do |air_loop| if air_loop_hvac_economizer_required?(air_loop) == true # If an economizer is required, determine the economizer type # in the prototype buildings, which depends on climate zone. economizer_type = nil # NECB 5.2.2.8 states that economizer can be controlled based on difference betweeen # return air temperature and outside air temperature OR return air enthalpy # and outside air enthalphy; latter chosen to be consistent with MNECB and CAN-QUEST implementation economizer_type = 'DifferentialEnthalpy' # Set the economizer type # Get the OA system and OA controller oa_sys = air_loop.airLoopHVACOutdoorAirSystem if oa_sys.is_initialized oa_sys = oa_sys.get else OpenStudio.logFree(OpenStudio::Error, 'openstudio.prototype.Model', "#{air_loop.name} is required to have an economizer, but it has no OA system.") next end oa_control = oa_sys.getControllerOutdoorAir oa_control.setEconomizerControlType(economizer_type) end end end def set_zones_thermostat_schedule_based_on_space_type_schedules(model, runner = nil) puts 'in set_zones_thermostat_schedule_based_on_space_type_schedules' BTAP.runner_register('DEBUG', 'Start-set_zones_thermostat_schedule_based_on_space_type_schedules', runner) model.getThermalZones.sort.each do |zone| BTAP.runner_register('DEBUG', "Zone = #{zone.name} Spaces =#{zone.spaces.size} ", runner) array = [] zone.spaces.sort.each do |space| schedule_type = determine_necb_schedule_type(space).to_s BTAP.runner_register('DEBUG', "space name/type:#{space.name}/#{schedule_type}", runner) # if wildcard space type, need to get dominant schedule type if '*'.to_s == schedule_type dominant_sched_type = determine_dominant_necb_schedule_type(model) schedule_type = dominant_sched_type end array << schedule_type end array.uniq! if array.size > 1 BTAP.runner_register('Error', "#{zone.name} has spaces with different schedule types. Please ensure that all the spaces are of the same schedule type A to I.", runner) return false end htg_search_string = "NECB-#{array[0]}-Thermostat Setpoint-Heating" clg_search_string = "NECB-#{array[0]}-Thermostat Setpoint-Cooling" if model.getScheduleRulesetByName(htg_search_string).empty? == false htg_sched = model.getScheduleRulesetByName(htg_search_string).get else BTAP.runner_register('ERROR', "heating_thermostat_setpoint_schedule NECB-#{array[0]} does not exist", runner) return false end if model.getScheduleRulesetByName(clg_search_string).empty? == false clg_sched = model.getScheduleRulesetByName(clg_search_string).get else BTAP.runner_register('ERROR', "cooling_thermostat_setpoint_schedule NECB-#{array[0]} does not exist", runner) return false end name = "NECB-#{array[0]}-Thermostat Dual Setpoint Schedule" # If dual setpoint already exists, use that one, else create one ds = if model.getThermostatSetpointDualSetpointByName(name).empty? == false model.getThermostatSetpointDualSetpointByName(name).get else BTAP::Resources::Schedules.create_annual_thermostat_setpoint_dual_setpoint(model, name, htg_sched, clg_sched) end thermostat_clone = ds.clone.to_ThermostatSetpointDualSetpoint.get zone.setThermostatSetpointDualSetpoint(thermostat_clone) BTAP.runner_register('Info', "ThermalZone #{zone.name} set to DualSetpoint Schedule NECB-#{array[0]}", runner) end BTAP.runner_register('DEBUG', 'END-set_zones_thermostat_schedule_based_on_space_type_schedules', runner) return true end # Helper method to find out which climate zone set contains a specific climate zone. # Returns climate zone set name as String if success, nil if not found. def model_find_climate_zone_set(model, clim) return 'NECB-CNEB ClimatZone 4-8' end def setup_hw_loop_with_components(model, hw_loop, boiler_fueltype, pump_flow_sch) hw_loop.setName('Hot Water Loop') sizing_plant = hw_loop.sizingPlant sizing_plant.setLoopType('Heating') sizing_plant.setDesignLoopExitTemperature(82.0) # TODO: units sizing_plant.setLoopDesignTemperatureDifference(16.0) # pump (set to variable speed for now till fix to run away plant temperature is found) # pump = OpenStudio::Model::PumpConstantSpeed.new(model) pump = OpenStudio::Model::PumpVariableSpeed.new(model) # TODO: the keyword "setPumpFlowRateSchedule" does not seem to work. A message # was sent to NREL to let them know about this. Once there is a fix for this, # use the proper pump schedule depending on whether we have two-pipe or four-pipe # fan coils. # pump.resetPumpFlowRateSchedule() # pump.setPumpFlowRateSchedule(pump_flow_sch) # boiler boiler1 = OpenStudio::Model::BoilerHotWater.new(model) boiler2 = OpenStudio::Model::BoilerHotWater.new(model) boiler1.setFuelType(boiler_fueltype) boiler2.setFuelType(boiler_fueltype) boiler1.setName('Primary Boiler') boiler2.setName('Secondary Boiler') # boiler_bypass_pipe boiler_bypass_pipe = OpenStudio::Model::PipeAdiabatic.new(model) # supply_outlet_pipe supply_outlet_pipe = OpenStudio::Model::PipeAdiabatic.new(model) # Add the components to the hot water loop hw_supply_inlet_node = hw_loop.supplyInletNode hw_supply_outlet_node = hw_loop.supplyOutletNode pump.addToNode(hw_supply_inlet_node) hw_loop.addSupplyBranchForComponent(boiler1) hw_loop.addSupplyBranchForComponent(boiler2) hw_loop.addSupplyBranchForComponent(boiler_bypass_pipe) supply_outlet_pipe.addToNode(hw_supply_outlet_node) # Add a setpoint manager to control the # hot water based on outdoor temperature hw_oareset_stpt_manager = OpenStudio::Model::SetpointManagerOutdoorAirReset.new(model) hw_oareset_stpt_manager.setControlVariable('Temperature') hw_oareset_stpt_manager.setSetpointatOutdoorLowTemperature(82.0) hw_oareset_stpt_manager.setOutdoorLowTemperature(-16.0) hw_oareset_stpt_manager.setSetpointatOutdoorHighTemperature(60.0) hw_oareset_stpt_manager.setOutdoorHighTemperature(0.0) hw_oareset_stpt_manager.addToNode(hw_supply_outlet_node) end # of setup_hw_loop_with_components def setup_chw_loop_with_components(model, chw_loop, chiller_type) chw_loop.setName('Chilled Water Loop') sizing_plant = chw_loop.sizingPlant sizing_plant.setLoopType('Cooling') sizing_plant.setDesignLoopExitTemperature(7.0) sizing_plant.setLoopDesignTemperatureDifference(6.0) # Note: pump of 'chilled water loop' has been changed to the variable one as the constant one caused fatal errors for LargeOffice-Yellowknife-NaturalGas for some ECMs and inputs. # Fatal error was: 'CheckForRunawayPlantTemps: Simulation terminated because of run away plant temperatures, too cold' OR '..., too hot' for the PlantLoop of 'Chilled Water Loop'. # Note that the variable speed pump has been already used for 'Hot Water Loop'. chw_pump = OpenStudio::Model::PumpVariableSpeed.new(model) chiller1 = OpenStudio::Model::ChillerElectricEIR.new(model) chiller2 = OpenStudio::Model::ChillerElectricEIR.new(model) chiller1.setCondenserType('WaterCooled') chiller2.setCondenserType('WaterCooled') chiller1_name = "Primary Chiller WaterCooled #{chiller_type}" chiller1.setName(chiller1_name) chiller2_name = "Secondary Chiller WaterCooled #{chiller_type}" chiller2.setName(chiller2_name) chiller_bypass_pipe = OpenStudio::Model::PipeAdiabatic.new(model) chw_supply_outlet_pipe = OpenStudio::Model::PipeAdiabatic.new(model) # Add the components to the chilled water loop chw_supply_inlet_node = chw_loop.supplyInletNode chw_supply_outlet_node = chw_loop.supplyOutletNode chw_pump.addToNode(chw_supply_inlet_node) chw_loop.addSupplyBranchForComponent(chiller1) chw_loop.addSupplyBranchForComponent(chiller2) chw_loop.addSupplyBranchForComponent(chiller_bypass_pipe) chw_supply_outlet_pipe.addToNode(chw_supply_outlet_node) # Add a setpoint manager to control the # chilled water to a constant temperature chw_t_c = 7.0 chw_t_sch = BTAP::Resources::Schedules.create_annual_constant_ruleset_schedule(model, 'CHW Temp', 'Temperature', chw_t_c) chw_t_stpt_manager = OpenStudio::Model::SetpointManagerScheduled.new(model, chw_t_sch) chw_t_stpt_manager.addToNode(chw_supply_outlet_node) return chiller1, chiller2 end # of setup_chw_loop_with_components def setup_cw_loop_with_components(model, cw_loop, chiller1, chiller2) cw_loop.setName('Condenser Water Loop') cw_sizing_plant = cw_loop.sizingPlant cw_sizing_plant.setLoopType('Condenser') cw_sizing_plant.setDesignLoopExitTemperature(29.0) cw_sizing_plant.setLoopDesignTemperatureDifference(6.0) cw_pump = OpenStudio::Model::PumpConstantSpeed.new(model) clg_tower = OpenStudio::Model::CoolingTowerSingleSpeed.new(model) # TO DO: Need to define and set cooling tower curves clg_tower_bypass_pipe = OpenStudio::Model::PipeAdiabatic.new(model) cw_supply_outlet_pipe = OpenStudio::Model::PipeAdiabatic.new(model) # Add the components to the condenser water loop cw_supply_inlet_node = cw_loop.supplyInletNode cw_supply_outlet_node = cw_loop.supplyOutletNode cw_pump.addToNode(cw_supply_inlet_node) clg_tower.setDesignInletAirWetBulbTemperature(24.0) clg_tower.setDesignInletAirDryBulbTemperature(35.0) clg_tower.setDesignApproachTemperature(5.0) clg_tower.setDesignRangeTemperature(6.0) cw_loop.addSupplyBranchForComponent(clg_tower) cw_loop.addSupplyBranchForComponent(clg_tower_bypass_pipe) cw_supply_outlet_pipe.addToNode(cw_supply_outlet_node) cw_loop.addDemandBranchForComponent(chiller1) cw_loop.addDemandBranchForComponent(chiller2) # Add a setpoint manager to control the # condenser water to constant temperature cw_t_c = 29.0 cw_t_sch = BTAP::Resources::Schedules.create_annual_constant_ruleset_schedule(model, 'CW Temp', 'Temperature', cw_t_c) cw_t_stpt_manager = OpenStudio::Model::SetpointManagerScheduled.new(model, cw_t_sch) cw_t_stpt_manager.addToNode(cw_supply_outlet_node) return clg_tower end # This method cycles through the spaces in a thermal zone and then sorts them by story. The method then cycles # through the spaces on a story and then calculates the centroid of the spaces in the thermal zone on that floor. The # method returns an array of hashes, one for each story. Each hash has the following structure: # { # story_name: Name of a given story. # spaces: Array containing all of the spaces in the thermal zone on the story in story_name. # centroid: Array containing the x, y, and z coordinates of the centroid of the ceilings of the spaces # listed in 'spaces:' above. # ceiling_area: Total area of the ceilings of the spaces in 'spaces:' above. # } # Only spaces which are conditioned (heated or cooled) and are not plenums are included. def thermal_zone_get_centroid_per_floor(thermal_zone) stories = [] thermal_zone.spaces.sort.each do |space| spaceType_name = space.spaceType.get.nameString sp_type = spaceType_name[15..-1] # Including regular expressions in the following match for cases where extra characters, which do not belong, are # added to either the space type in the model or the space type reference file. sp_type_info = @standards_data['space_types'].detect do |data| (Regexp.new(data['space_type'].to_s.upcase).match(sp_type.upcase) || Regexp.new(sp_type.upcase).match(data['space_type'].to_s.upcase) || (data['space_type'].to_s.upcase == sp_type.upcase)) && (data['building_type'].to_s == 'Space Function') end if sp_type_info.nil? OpenStudio.logFree(OpenStudio::Info, 'openstudio.standards.thermal_zone_get_centroid_per_floor', "The space type called #{sp_type} could not be found. Please check that the schedules.json file is available and that the space types are spelled correctly") next end # Determine if space is heated or cooled via spacetype heating or cooling setpoints also checking if the space is # a plenum by checking if there is a hvac system associtated with it if sp_type_info['heating_setpoint_schedule'].nil? heated = FALSE else heated = TRUE end if sp_type_info['cooling_setpoint_schedule'].nil? cooled = FALSE else cooled = TRUE end if (sp_type_info['necb_hvac_system_selection_type'] == '- undefined -') || /undefined/.match(sp_type_info['necb_hvac_system_selection_type']) not_plenum = FALSE else not_plenum = TRUE end # If the spaces are heated or cooled and are not a plenum then continue if (heated || cooled) && not_plenum # Get the story name and sit it to none if there is no story name story_name = space.buildingStory.get.nameString story_name = 'none' if story_name.nil? # If this is the first story in the arry then add a new one. if stories.empty? stories << { story_name: story_name, spaces: [space], centroid: [0, 0, 0], ceiling_area: 0 } next else # If this is not the first story in the array check if the story already is in the array. i = nil stories.each_with_index do |storycheck, index| if storycheck[:story_name] == story_name i = index end end # If the story is not in the array then add it. if i.nil? stories << { story_name: story_name, spaces: [space], centroid: [0, 0, 0], ceiling_area: 0 } else # If the story is already in the arry then add the space to the array of spaces for that story stories[i][:spaces] << space end end end end # Go through each story in the array above stories.each do |story| tz_centre = [0, 0, 0, 0] # Go through each space in a given story story[:spaces].each do |space| # Determine the top surface of the space and calculate it's centroid. # Get the coordinates of the origin for the space (the coordinates of points in the space are relative to this). xOrigin = space.xOrigin yOrigin = space.yOrigin zOrigin = space.zOrigin # Go through each surface in the space and find ceilings by determining which is called 'RoofCeiing'. Find the # overall centroid of all the ceilings in the spaces. Find centroid by multiplying the centroid of the surfaces # multiplied by the area of the surface and add them all up. Then divide this by the overall area. This is the # area weighted average of the centroid coordinates. ceiling_centroid = [0, 0, 0, 0] space.surfaces.each do |sp_surface| if sp_surface.surfaceType.to_s.upcase == 'ROOFCEILING' ceiling_centroid[0] = ceiling_centroid[0] + sp_surface.centroid.x.to_f * sp_surface.grossArea.to_f ceiling_centroid[1] = ceiling_centroid[1] + sp_surface.centroid.y.to_f * sp_surface.grossArea.to_f ceiling_centroid[2] = ceiling_centroid[2] + sp_surface.centroid.z.to_f * sp_surface.grossArea.to_f ceiling_centroid[3] = ceiling_centroid[3] + sp_surface.grossArea end end ceiling_centroid[0] = ceiling_centroid[0] / ceiling_centroid[3] ceiling_centroid[1] = ceiling_centroid[1] / ceiling_centroid[3] ceiling_centroid[2] = ceiling_centroid[2] / ceiling_centroid[3] # This part is used to determine the overall x, y centre of the thermal zone. This is determined by summing the # x and y components times the ceiling area and diving by the total ceiling area. I also added z since the # ceilings may not be all have the same height. tz_centre[0] += (ceiling_centroid[0] + xOrigin) * ceiling_centroid[3] tz_centre[1] += (ceiling_centroid[1] + yOrigin) * ceiling_centroid[3] tz_centre[2] += (ceiling_centroid[2] + zOrigin) * ceiling_centroid[3] tz_centre[3] += (ceiling_centroid[3]) end tz_centre[0] /= tz_centre[3] tz_centre[1] /= tz_centre[3] tz_centre[2] /= tz_centre[3] # Update the :centroid and :ceiling_area hashes for the story to reflect the x, y, and z coordinates of the # overall centroid of spaces on that floor. story[:centroid] = tz_centre[0..2] story[:ceiling_area] = tz_centre[3] end return stories end # Create a new DX cooling coil with NECB curve characteristics def add_onespeed_DX_coil(model, always_on) # clg_cap_f_of_temp = OpenStudio::Model::CurveBiquadratic.new(model) # clg_cap_f_of_temp = model_add_curve("DXCOOL-NECB2011-REF-CAPFT") clg_cap_f_of_temp = OpenStudio::Model::CurveBiquadratic.new(model) clg_cap_f_of_temp.setCoefficient1Constant(0.867905) clg_cap_f_of_temp.setCoefficient2x(0.0142459) clg_cap_f_of_temp.setCoefficient3xPOW2(0.000554364) clg_cap_f_of_temp.setCoefficient4y(-0.00755748) clg_cap_f_of_temp.setCoefficient5yPOW2(3.3048e-05) clg_cap_f_of_temp.setCoefficient6xTIMESY(-0.000191808) clg_cap_f_of_temp.setMinimumValueofx(13.0) clg_cap_f_of_temp.setMaximumValueofx(24.0) clg_cap_f_of_temp.setMinimumValueofy(24.0) clg_cap_f_of_temp.setMaximumValueofy(46.0) # clg_cap_f_of_flow = OpenStudio::Model::CurveQuadratic.new(model) clg_cap_f_of_flow = OpenStudio::Model::CurveQuadratic.new(model) clg_cap_f_of_flow.setCoefficient1Constant(1.0) clg_cap_f_of_flow.setCoefficient2x(0.0) clg_cap_f_of_flow.setCoefficient3xPOW2(0.0) clg_cap_f_of_flow.setMinimumValueofx(0.0) clg_cap_f_of_flow.setMaximumValueofx(1.0) # clg_energy_input_ratio_f_of_temp = = model_add_curve(""DXCOOL-NECB2011-REF-COOLEIRFT") # clg_energy_input_ratio_f_of_temp = OpenStudio::Model::CurveBiquadratic.new(model) clg_energy_input_ratio_f_of_temp = OpenStudio::Model::CurveBiquadratic.new(model) clg_energy_input_ratio_f_of_temp.setCoefficient1Constant(0.116936) clg_energy_input_ratio_f_of_temp.setCoefficient2x(0.0284933) clg_energy_input_ratio_f_of_temp.setCoefficient3xPOW2(-0.000411156) clg_energy_input_ratio_f_of_temp.setCoefficient4y(0.0214108) clg_energy_input_ratio_f_of_temp.setCoefficient5yPOW2(0.000161028) clg_energy_input_ratio_f_of_temp.setCoefficient6xTIMESY(-0.000679104) clg_energy_input_ratio_f_of_temp.setMinimumValueofx(13.0) clg_energy_input_ratio_f_of_temp.setMaximumValueofx(24.0) clg_energy_input_ratio_f_of_temp.setMinimumValueofy(24.0) clg_energy_input_ratio_f_of_temp.setMaximumValueofy(46.0) # clg_energy_input_ratio_f_of_flow = OpenStudio::Model::CurveQuadratic.new(model) # clg_energy_input_ratio_f_of_flow = = model_add_curve("DXCOOL-NECB2011-REF-CAPFFLOW") clg_energy_input_ratio_f_of_flow = OpenStudio::Model::CurveQuadratic.new(model) clg_energy_input_ratio_f_of_flow.setCoefficient1Constant(1.0) clg_energy_input_ratio_f_of_flow.setCoefficient2x(0.0) clg_energy_input_ratio_f_of_flow.setCoefficient3xPOW2(0.0) clg_energy_input_ratio_f_of_flow.setMinimumValueofx(0.0) clg_energy_input_ratio_f_of_flow.setMaximumValueofx(1.0) # NECB curve modified to take into account how PLF is used in E+, and PLF ranges (> 0.7) # clg_part_load_ratio = model_add_curve("DXCOOL-NECB2011-REF-COOLPLFFPLR") clg_part_load_ratio = OpenStudio::Model::CurveCubic.new(model) clg_part_load_ratio.setCoefficient1Constant(0.0277) clg_part_load_ratio.setCoefficient2x(4.9151) clg_part_load_ratio.setCoefficient3xPOW2(-8.184) clg_part_load_ratio.setCoefficient4xPOW3(4.2702) clg_part_load_ratio.setMinimumValueofx(0.7) clg_part_load_ratio.setMaximumValueofx(1.0) return OpenStudio::Model::CoilCoolingDXSingleSpeed.new(model, always_on, clg_cap_f_of_temp, clg_cap_f_of_flow, clg_energy_input_ratio_f_of_temp, clg_energy_input_ratio_f_of_flow, clg_part_load_ratio) end # Zonal systems def add_zone_baseboards(baseboard_type:, hw_loop:, model:, zone:) always_on = model.alwaysOnDiscreteSchedule if baseboard_type == 'Electric' zone_elec_baseboard = OpenStudio::Model::ZoneHVACBaseboardConvectiveElectric.new(model) zone_elec_baseboard.addToThermalZone(zone) end return unless baseboard_type == 'Hot Water' baseboard_coil = OpenStudio::Model::CoilHeatingWaterBaseboard.new(model) # Connect baseboard coil to hot water loop hw_loop.addDemandBranchForComponent(baseboard_coil) zone_baseboard = OpenStudio::Model::ZoneHVACBaseboardConvectiveWater.new(model, always_on, baseboard_coil) # add zone_baseboard to zone zone_baseboard.addToThermalZone(zone) end def add_ptac_dx_cooling(model, zone, zero_outdoor_air) # Create a PTAC for each zone: # PTAC DX Cooling with electric heating coil; electric heating coil is always off # TO DO: need to apply this system to space types: # (1) data processing area: control room, data centre # when cooling capacity <= 20kW and # (2) residential/accommodation: murb, hotel/motel guest room # when building/space heated only (this as per NECB; apply to # all for initial work? CAN-QUEST limitation) # TO DO: PTAC characteristics: sizing, fan schedules, temperature setpoints, interaction with MAU always_on = model.alwaysOnDiscreteSchedule always_off = BTAP::Resources::Schedules::StandardSchedules::ON_OFF.always_off(model) htg_coil = OpenStudio::Model::CoilHeatingElectric.new(model, always_off) # Set up PTAC DX coil with NECB performance curve characteristics; clg_coil = add_onespeed_DX_coil(model, always_on) # Set up PTAC constant volume supply fan fan = OpenStudio::Model::FanConstantVolume.new(model, always_on) fan.setPressureRise(640) ptac = OpenStudio::Model::ZoneHVACPackagedTerminalAirConditioner.new(model, always_on, fan, htg_coil, clg_coil) ptac.setName("#{zone.name} PTAC") if zero_outdoor_air ptac.setOutdoorAirFlowRateWhenNoCoolingorHeatingisNeeded 1.0e-5 ptac.setOutdoorAirFlowRateDuringCoolingOperation(1.0e-5) ptac.setOutdoorAirFlowRateDuringHeatingOperation(1.0e-5) end ptac.addToThermalZone(zone) end def common_air_loop(model:, system_data:) mau_air_loop = OpenStudio::Model::AirLoopHVAC.new(model) mau_air_loop.setName(system_data[:name]) air_loop_sizing = mau_air_loop.sizingSystem air_loop_sizing.autosizeDesignOutdoorAirFlowRate air_loop_sizing.setPreheatDesignTemperature(system_data[:PreheatDesignTemperature]) unless system_data[:PreheatDesignTemperature].nil? air_loop_sizing.setPreheatDesignHumidityRatio(system_data[:PreheatDesignHumidityRatio]) unless system_data[:PreheatDesignHumidityRatio].nil? air_loop_sizing.setPrecoolDesignTemperature(system_data[:PrecoolDesignTemperature]) unless system_data[:PrecoolDesignTemperature].nil? air_loop_sizing.setPrecoolDesignHumidityRatio(system_data[:PrecoolDesignHumidityRatio]) unless system_data[:PrecoolDesignHumidityRatio].nil? air_loop_sizing.setSizingOption(system_data[:SizingOption]) unless system_data[:SizingOption].nil? air_loop_sizing.setCoolingDesignAirFlowMethod(system_data[:CoolingDesignAirFlowMethod]) unless system_data[:CoolingDesignAirFlowMethod].nil? air_loop_sizing.setCoolingDesignAirFlowRate(system_data[:CoolingDesignAirFlowRate]) unless system_data[:CoolingDesignAirFlowRate].nil? air_loop_sizing.setHeatingDesignAirFlowMethod(system_data[:HeatingDesignAirFlowMethod]) unless system_data[:HeatingDesignAirFlowMethod].nil? air_loop_sizing.setHeatingDesignAirFlowRate(system_data[:HeatingDesignAirFlowRate]) unless system_data[:HeatingDesignAirFlowRate].nil? air_loop_sizing.setSystemOutdoorAirMethod(system_data[:SystemOutdoorAirMethod]) unless system_data[:SystemOutdoorAirMethod].nil? air_loop_sizing.setCentralCoolingDesignSupplyAirHumidityRatio(system_data[:CentralCoolingDesignSupplyAirHumidityRatio]) unless system_data[:CentralCoolingDesignSupplyAirHumidityRatio].nil? air_loop_sizing.setCentralHeatingDesignSupplyAirHumidityRatio(system_data[:CentralHeatingDesignSupplyAirHumidityRatio]) unless system_data[:CentralHeatingDesignSupplyAirHumidityRatio].nil? air_loop_sizing.setTypeofLoadtoSizeOn(system_data[:TypeofLoadtoSizeOn]) unless system_data[:TypeofLoadtoSizeOn].nil? air_loop_sizing.setCentralCoolingDesignSupplyAirTemperature(system_data[:CentralCoolingDesignSupplyAirTemperature]) unless system_data[:CentralCoolingDesignSupplyAirTemperature].nil? air_loop_sizing.setCentralHeatingDesignSupplyAirTemperature(system_data[:CentralHeatingDesignSupplyAirTemperature]) unless system_data[:CentralHeatingDesignSupplyAirTemperature].nil? air_loop_sizing.setAllOutdoorAirinCooling(system_data[:AllOutdoorAirinCooling]) unless system_data[:AllOutdoorAirinCooling].nil? air_loop_sizing.setAllOutdoorAirinHeating(system_data[:AllOutdoorAirinHeating]) unless system_data[:AllOutdoorAirinHeating].nil? air_loop_sizing.setMinimumSystemAirFlowRatio(system_data[:MinimumSystemAirFlowRatio]) unless system_data[:MinimumSystemAirFlowRatio].nil? return mau_air_loop end def create_heating_cooling_on_off_availability_schedule(model) # TODO: Create a feature to derive start and end heating and cooling seasons from weather file. avail_data = [{ start_month: 1, start_day: 1, end_month: 6, end_day: 30, htg_value: 1, clg_value: 0 }, { start_month: 7, start_day: 1, end_month: 10, end_day: 31, htg_value: 0, clg_value: 1 }, { start_month: 11, start_day: 1, end_month: 12, end_day: 31, htg_value: 1, clg_value: 0 }] # Heating coil availability schedule for tpfc htg_availability_sch = OpenStudio::Model::ScheduleRuleset.new(model) htg_availability_sch.setName('tpfc_htg_availability') # Cooling coil availability schedule for tpfc clg_availability_sch = OpenStudio::Model::ScheduleRuleset.new(model) clg_availability_sch.setName('tpfc_clg_availability') avail_data.each do |data| htg_availability_sch_rule = OpenStudio::Model::ScheduleRule.new(htg_availability_sch) htg_availability_sch_rule.setName('tpfc_htg_availability_sch_rule') htg_availability_sch_rule.setStartDate(model.getYearDescription.makeDate(data[:start_month], data[:start_day])) htg_availability_sch_rule.setEndDate(model.getYearDescription.makeDate(data[:end_month], data[:end_day])) htg_availability_sch_rule.setApplySunday(true) htg_availability_sch_rule.setApplyMonday(true) htg_availability_sch_rule.setApplyTuesday(true) htg_availability_sch_rule.setApplyWednesday(true) htg_availability_sch_rule.setApplyThursday(true) htg_availability_sch_rule.setApplyFriday(true) htg_availability_sch_rule.setApplySaturday(true) day_schedule = htg_availability_sch_rule.daySchedule day_schedule.setName('tpfc_htg_availability_sch_rule_day') day_schedule.addValue(OpenStudio::Time.new(0, 24, 0, 0), data[:htg_value]) clg_availability_sch_rule = OpenStudio::Model::ScheduleRule.new(clg_availability_sch) clg_availability_sch_rule.setName('tpfc_clg_availability_sch_rule') clg_availability_sch_rule.setStartDate(model.getYearDescription.makeDate(data[:start_month], data[:start_day])) clg_availability_sch_rule.setEndDate(model.getYearDescription.makeDate(data[:end_month], data[:end_day])) clg_availability_sch_rule.setApplySunday(true) clg_availability_sch_rule.setApplyMonday(true) clg_availability_sch_rule.setApplyTuesday(true) clg_availability_sch_rule.setApplyWednesday(true) clg_availability_sch_rule.setApplyThursday(true) clg_availability_sch_rule.setApplyFriday(true) clg_availability_sch_rule.setApplySaturday(true) day_schedule = clg_availability_sch_rule.daySchedule day_schedule.setName('tpfc_clg_availability_sch_rule_day') day_schedule.addValue(OpenStudio::Time.new(0, 24, 0, 0), data[:clg_value]) end return clg_availability_sch, htg_availability_sch end # Method to set the base system name based on the following syntax: # |sys_abbr|sys_oa|sc>?|sh>?|ssf>?|zh>?|zc>?|srf>?| # "sys_abbr" designates the NECB system type ("sys_1, sys_2, ... sys_6") # "sys_oa": "mixed" or "doas" # "sys_name_pars" is a hash for the remaining system name parts for heat recovery, # heating, cooling, supply fan, zone heating, zone cooling, and return fan def assign_base_sys_name(airloop, sys_abbr:, sys_oa:, sys_name_pars:) sys_name = "#{sys_abbr}|#{sys_oa}|" sys_name_pars.each do |key, value| case key.downcase when 'sys_hr' case value.downcase when 'none' sys_name += 'shr>none' end when 'sys_htg' case value.downcase when 'none' sys_name += 'sh>none' when 'electric' sys_name += 'sh>c-e' when 'hot water' sys_name += 'sh>c-hw' when 'gas' sys_name += 'sh>c-g' when 'dx' sys_name += 'sh>ashp' when 'ccashp' sys_name += 'sh>ccashp' when 'ashp' sys_name += 'sh>ashp' end when 'sys_clg' case value.downcase when 'none' sys_name += 'sc>none' when 'chilled water' sys_name += 'sc>c-chw' when 'dx' if sys_name_pars['sys_htg'] == 'dx' sys_name += 'sc>ashp' else sys_name += 'sc>dx' end when 'ccashp' sys_name += 'sc>ccashp' when 'ashp' sys_name += 'sc>ashp' end when 'sys_sf' case value.downcase when 'none' sys_name += 'ssf>none' when 'cv' sys_name += 'ssf>cv' when 'vv' sys_name += 'ssf>vv' end when 'zone_htg' case value.downcase when 'none' sys_name += 'zh>none' when 'electric' sys_name += 'zh>b-e' when 'hot water' sys_name += 'zh>b-hw' when 'tpfc' sys_name += 'zh>fpfc' when 'fpfc' sys_name += 'zh>tpfc' when 'pthp' sys_name += 'zh>pthp' end when 'zone_clg' case value.downcase when 'none' sys_name += 'zc>none' when 'tpfc' sys_name += 'zc>tpfc' when 'fpfc' sys_name += 'zc>fpfc' when 'ptac' sys_name += 'zc>ptac' when 'pthp' sys_name += 'zc>pthp' end when 'sys_rf' case value.downcase when 'none' sys_name += 'srf>none' when 'cv' sys_name += 'srf>cv' when 'vv' sys_name += 'srf>vv' end end sys_name += '|' end airloop.setName(sys_name) end # Method to update the base system name based on the inputs provided. # Only the parts of the name with string inputs are updated def update_sys_name(airloop, sys_abbr: nil, sys_oa: nil, sys_hr: nil, sys_htg: nil, sys_clg: nil, sys_sf: nil, zone_htg: nil, zone_clg: nil, sys_rf: nil) name_parts = airloop.name.to_s.split('|').reject(&:empty?) if sys_abbr.is_a? String then name_parts[0] = sys_abbr end if sys_oa.is_a? String then name_parts[1] = sys_oa end for i in 0..name_parts.size - 1 if (name_parts[i].include? 'shr>') && (sys_hr.is_a? String) name_parts[i] = "shr>#{sys_hr}" elsif (name_parts[i].include? 'sh>') && (sys_htg.is_a? String) name_parts[i] = "sh>#{sys_htg}" elsif (name_parts[i].include? 'sc>') && (sys_clg.is_a? String) name_parts[i] = "sc>#{sys_clg}" elsif (name_parts[i].include? 'ssf') && (sys_sf.is_a? String) name_parts[i] = "ssf>#{sys_sf}" elsif (name_parts[i].include? 'zh>') && (zone_htg.is_a? String) name_parts[i] = "zh>#{zone_htg}" elsif (name_parts[i].include? 'zc>') && (zone_clg.is_a? String) name_parts[i] = "zc>#{zone_clg}" elsif (name_parts[i].include? 'srf>') && (sys_rf.is_a? String) name_parts[i] = "srf>#{sys_rf}" end end sys_name = '' name_parts.each { |part| sys_name += "#{part}|" } # Check if the last part of the system name is an integer. If it is, then remove the last part from the system name. check_int = begin Integer(name_parts.last.strip) rescue StandardError nil end sys_name = sys_name.chop unless check_int.nil? airloop.setName(sys_name) end end