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# see the URL below for information on how to write OpenStudio measures
# http://openstudio.nrel.gov/openstudio-measure-writing-guide
# see the URL below for information on using life cycle cost objects in OpenStudio
# http://openstudio.nrel.gov/openstudio-life-cycle-examples
# see the URL below for access to C++ documentation on model objects (click on "model" in the main window to view model objects)
# http://openstudio.nrel.gov/sites/openstudio.nrel.gov/files/nv_hash/cpp_documentation_it/model/html/namespaces.html
# load OpenStudio measure libraries from openstudio-extension gem
require 'openstudio-extension'
require 'openstudio/extension/core/os_lib_constructions'
# load OpenStudio measure libraries
require "#{File.dirname(__FILE__)}/resources/OsLib_AedgMeasures"
# start the measure
class ZEDGK12ExteriorWallConstruction < OpenStudio::Measure::ModelMeasure
include OsLib_AedgMeasures
include OsLib_Constructions
# define the name that a user will see, this method may be deprecated as
# the display name in PAT comes from the name field in measure.xml
def name
return 'ZEDG K12 ExteriorWallConstruction'
end
# define the arguments that the user will input
def arguments(model)
args = OpenStudio::Measure::OSArgumentVector.new
# make an argument for material and installation cost
material_cost_insulation_increase_ip = OpenStudio::Measure::OSArgument.makeDoubleArgument('material_cost_insulation_increase_ip', true)
material_cost_insulation_increase_ip.setDisplayName('Increase Cost per Area of Construction Where Insulation was Improved ($/ft^2).')
material_cost_insulation_increase_ip.setDefaultValue(0.0)
args << material_cost_insulation_increase_ip
return args
end
# define what happens when the measure is run
def run(model, runner, user_arguments)
super(model, runner, user_arguments)
# use the built-in error checking
if !runner.validateUserArguments(arguments(model), user_arguments)
return false
end
# assign the user inputs to variables
material_cost_insulation_increase_ip = runner.getDoubleArgumentValue('material_cost_insulation_increase_ip', user_arguments)
# no validation needed for cost inputs, negative values are fine, however negative would be odd choice since this measure only improves vs. decreases insulation and SRI performance
# global variables for costs
expected_life = 25
years_until_costs_start = 0
material_cost_insulation_increase_si = OpenStudio.convert(material_cost_insulation_increase_ip, '1/ft^2', '1/m^2').get
running_cost_insulation = 0
# prepare rule hash
rules = [] # climate zone, wall type, thermal transmittance (Btu/h·ft2·°F)
# zedg doesn't have wall type lookup like aedg, altert user of this
runner.registerInfo('Wall insulation values based on Steel Framed walls.')
rules << ['0', 'SteelFramed', 0.124] # # measure setup to use only for this target and wall type
rules << ['1', 'SteelFramed', 0.077] # higher conductance than 50% AEDG
rules << ['2', 'SteelFramed', 0.077] # higher conductance than 50% AEDG
rules << ['3', 'SteelFramed', 0.064] # nc
rules << ['4', 'SteelFramed', 0.061]
rules << ['5', 'SteelFramed', 0.052] # higher conductance than 50% AEDG
rules << ['6', 'SteelFramed', 0.047] # higher conductance than 50% AEDG
rules << ['7', 'SteelFramed', 0.047] # higher conductance than 50% AEDG
rules << ['8', 'SteelFramed', 0.035]
# make rule hash for cleaner code
rulesHash = {}
rules.each do |rule|
rulesHash["#{rule[0]} #{rule[1]}"] = { 'conductivity_ip' => rule[2] }
end
# get climate zone
climateZoneNumber = OsLib_AedgMeasures.getClimateZoneNumber(model, runner)
# climateZoneNumber = "4" # this is just in for quick testing of different climate zones
# return false with error if can't find climate zone number
if climateZoneNumber == false
return false
end
# get starting r-value
startingRvaluesExtWall = []
# flag for wall surface type for tips
massFlag = false
steelFramedFlag = false
woodFramedFlag = false
metalFlag = false
# affected area counter
insulation_affected_area = 0
# construction hashes (construction is key, value is array [thermal transmittance (Btu/h·ft2·°F),rule thermal transmittance (Btu/h·ft2·°F),classification string)
massConstructions = {}
steelFramedConstructions = {}
woodFramedConstructions = {}
metalConstructions = {}
# this contains constructions that do not have a recognized Standards Construction Type
otherConstructions = []
# loop through constructions
constructions = model.getConstructions
constructions.each do |construction|
# skip if not used
next if construction.getNetArea <= 0
# skip if not opaque
next if !construction.isOpaque
# get construction and standard
constructionStandard = construction.standardsInformation
# get intended surface and standards construction type
intendedSurfaceType = constructionStandard.intendedSurfaceType
# because it is assumed to be SteelFramed, hard code vs. inspecting construction
# constructionType = constructionStandard.standardsConstructionType
constructionType = 'SteelFramed'
# get conductivity
conductivity_si = construction.thermalConductance.get
r_value_ip = OpenStudio.convert(1 / conductivity_si, 'm^2*K/W', 'ft^2*h*R/Btu').get
# check rules based on intended use and type
if intendedSurfaceType.to_s == 'ExteriorWall' # this should not include attics as they will be "Attic Wall"
if constructionType.to_s == 'Mass'
# store starting values
startingRvaluesExtWall << r_value_ip
massFlag = true
# test construction against rules
ruleSet = rulesHash["#{climateZoneNumber} Mass"]
if 1 / r_value_ip > ruleSet['conductivity_ip']
massConstructions[construction] = { 'conductivity_ip' => 1 / r_value_ip, 'transmittance_ip_rule' => ruleSet['conductivity_ip'], 'classification' => 'massConstructions' }
end
elsif constructionType.to_s == 'SteelFramed'
# store starting values
startingRvaluesExtWall << r_value_ip
steelFramedFlag = true
# test construction against rules
ruleSet = rulesHash["#{climateZoneNumber} SteelFramed"]
if 1 / r_value_ip > ruleSet['conductivity_ip']
steelFramedConstructions[construction] = { 'conductivity_ip' => 1 / r_value_ip, 'transmittance_ip_rule' => ruleSet['conductivity_ip'], 'classification' => 'steelFramedConstructions' }
end
elsif constructionType.to_s == 'WoodFramed'
# store starting values
startingRvaluesExtWall << r_value_ip
woodFramedFlag = true
# test construction against rules
ruleSet = rulesHash["#{climateZoneNumber} WoodFramed"]
if 1 / r_value_ip > ruleSet['conductivity_ip']
woodFramedConstructions[construction] = { 'conductivity_ip' => 1 / r_value_ip, 'transmittance_ip_rule' => ruleSet['conductivity_ip'], 'classification' => 'woodFramedConstructions' }
end
elsif constructionType.to_s == 'Metal'
# store starting values
startingRvaluesExtWall << r_value_ip
metalFlag = true
# test construction against rules
ruleSet = rulesHash["#{climateZoneNumber} Metal"]
if 1 / r_value_ip > ruleSet['conductivity_ip']
metalConstructions[construction] = { 'conductivity_ip' => 1 / r_value_ip, 'transmittance_ip_rule' => ruleSet['conductivity_ip'], 'classification' => 'metalConstructions' }
end
else
# track other constructions
otherConstructions << construction
end
end
end
# create warning if construction used on exterior wall doesn't have a surface type of "ExteriorWall", or if constructions tagged to be used as exterior wall, are used on other surface types
otherConstructionsWarned = []
surfaces = model.getSurfaces
surfaces.each do |surface|
if !surface.construction.empty?
construction = surface.construction.get
if (surface.outsideBoundaryCondition == 'Outdoors') && (surface.surfaceType == 'Wall')
if otherConstructions.include?(construction) && (!otherConstructionsWarned.include? construction)
runner.registerWarning("#{construction.name} is used on one or more exterior wall surfaces but has an intended surface type or construction type not recognized by this measure. As we can not infer the proper performance target, this construction will not be altered.")
otherConstructionsWarned << construction
end
else
if massConstructions.include?(construction) || steelFramedConstructions.include?(construction) || woodFramedConstructions.include?(construction) || metalConstructions.include?(construction)
runner.registerWarning("#{surface.name} uses #{construction.name} as a construction that this measure expects to be used for exterior walls. This surface has a type of #{surface.surfaceType} and a a boundary condition of #{surface.outsideBoundaryCondition}. This may result in unexpected changes to your model.")
end
end
end
end
# alter constructions and add lcc
constructionsToChange = massConstructions.sort + steelFramedConstructions.sort + woodFramedConstructions.sort + metalConstructions.sort
constructionsToChange.each do |construction, hash|
# gather insulation inputs
# gather target decrease in conductivity
conductivity_ip_starting = hash['conductivity_ip']
conductivity_si_starting = OpenStudio.convert(conductivity_ip_starting, 'Btu/ft^2*h*R', 'W/m^2*K').get
r_value_ip_starting = 1 / conductivity_ip_starting # ft^2*h*R/Btu
r_value_si_starting = 1 / conductivity_si_starting # m^2*K/W
conductivity_ip_target = hash['transmittance_ip_rule'].to_f
conductivity_si_target = OpenStudio.convert(conductivity_ip_target, 'Btu/ft^2*h*R', 'W/m^2*K').get
r_value_ip_target = 1 / conductivity_ip_target # ft^2*h*R/Btu
r_value_si_target = 1 / conductivity_si_target # m^2*K/W
# infer insulation material to get input for target thickness
minThermalResistance = OpenStudio.convert(1, 'ft^2*h*R/Btu', 'm^2*K/W').get
inferredInsulationLayer = OsLib_Constructions.inferInsulationLayer(construction, minThermalResistance)
rvalue_si_deficiency = r_value_si_target - r_value_si_starting
# add lcc for insulation
lcc_mat_insulation = OpenStudio::Model::LifeCycleCost.createLifeCycleCost("LCC_Mat_Insulation - #{construction.name}", construction, material_cost_insulation_increase_si, 'CostPerArea', 'Construction', expected_life, years_until_costs_start)
lcc_mat_insulation_value = lcc_mat_insulation.get.totalCost
running_cost_insulation += lcc_mat_insulation_value
# adjust existing material or add new one
if (inferredInsulationLayer['insulationFound'] && (hash['classification'] == 'massConstructions')) || (inferredInsulationLayer['insulationFound'] && (hash['classification'] == 'metalConstructions')) # if insulation layer was found
# gather inputs for method
target_material_rvalue_si = inferredInsulationLayer['construction_thermal_resistance'] + rvalue_si_deficiency
# run method to change insulation layer thickness in cloned material (material,starting_r_value_si,target_r_value_si, model)
new_material = OsLib_Constructions.setMaterialThermalResistance(inferredInsulationLayer['construction_layer'], target_material_rvalue_si)
# connect new material to original construction
construction.eraseLayer(inferredInsulationLayer['layer_index'])
construction.insertLayer(inferredInsulationLayer['layer_index'], new_material)
# get conductivity
final_conductivity_si = construction.thermalConductance.get
final_r_value_ip = OpenStudio.convert(1 / final_conductivity_si, 'm^2*K/W', 'ft^2*h*R/Btu').get
# report on edited material
runner.registerInfo("The R-value of #{construction.name} has been increased from #{OpenStudio.toNeatString(r_value_ip_starting, 2, true)} to #{OpenStudio.toNeatString(final_r_value_ip, 2, true)}(ft^2*h*R/Btu) at a cost of $#{OpenStudio.toNeatString(lcc_mat_insulation_value, 2, true)}. Increased performance was accomplished by adjusting thermal resistance of #{new_material.name}.")
else
# inputs to pass to method
conductivity = 0.045 # W/m*K
thickness = rvalue_si_deficiency * conductivity # meters
addNewLayerToConstruction_Inputs = {
'roughness' => 'MediumRough',
'thickness' => thickness, # meters,
'conductivity' => conductivity, # W/m*K
'density' => 265.0,
'specificHeat' => 836.8,
'thermalAbsorptance' => 0.9,
'solarAbsorptance' => 0.7,
'visibleAbsorptance' => 0.7
}
# if wall is metal, than new layer should go at index 1 vs. 0
if hash['classification'] == 'metalConstructions'
addNewLayerToConstruction_Inputs['layerIndex'] = 1
end
# create new material if can't infer insulation material (construction,thickness, conductivity, density, specificHeat, roughness,thermalAbsorptance, solarAbsorptance,visibleAbsorptance,model)
newMaterialLayer = OsLib_Constructions.addNewLayerToConstruction(construction, addNewLayerToConstruction_Inputs)
# get conductivity
final_conductivity_si = construction.thermalConductance.get
final_r_value_ip = OpenStudio.convert(1 / final_conductivity_si, 'm^2*K/W', 'ft^2*h*R/Btu').get
# report on edited material
if hash['classification'] == 'metalConstructions'
runner.registerInfo("The R-value of #{construction.name} has been increased from #{OpenStudio.toNeatString(r_value_ip_starting, 2, true)} to #{OpenStudio.toNeatString(final_r_value_ip, 2, true)}(ft^2*h*R/Btu) at a cost of $#{OpenStudio.toNeatString(lcc_mat_insulation_value, 2, true)}. Increased performance was accomplished by adding a new material layer to the second layer of #{construction.name}.")
else
runner.registerInfo("The R-value of #{construction.name} has been increased from #{OpenStudio.toNeatString(r_value_ip_starting, 2, true)} to #{OpenStudio.toNeatString(final_r_value_ip, 2, true)}(ft^2*h*R/Btu) at a cost of $#{OpenStudio.toNeatString(lcc_mat_insulation_value, 2, true)}. Increased performance was accomplished by adding a new material layer to the outside of #{construction.name}.")
end
end
# add to area counter
insulation_affected_area += construction.getNetArea # OpenStudio handles matched surfaces so they are not counted twice.
end
# reporting initial condition of model
startingRvalue = startingRvaluesExtWall
runner.registerInitialCondition("Starting R-values for constructions intended for exterior wall surfaces range from #{OpenStudio.toNeatString(startingRvalue.min, 2, true)} to #{OpenStudio.toNeatString(startingRvalue.max, 2, true)}(ft^2*h*R/Btu).")
# reporting final condition of model
insulation_affected_area_ip = OpenStudio.convert(insulation_affected_area, 'm^2', 'ft^2').get
runner.registerFinalCondition("#{OpenStudio.toNeatString(insulation_affected_area_ip, 0, true)}(ft^2) of constructions intended for exterior wall surfaces had insulation enhanced at a cost of $#{OpenStudio.toNeatString(running_cost_insulation, 0, true)}.")
return true
end
end
# this allows the measure to be use by the application
ZEDGK12ExteriorWallConstruction.new.registerWithApplication