Extends from Modelica.Icons.VariantsPackage (Icon for package containing variants).
Name | Description |
---|---|
Fanger | Thermal comfort model according to Fanger |
Examples | Collection of models that illustrate model use and test models |
The thermal sensation of a human being is mainly related to the thermal balance of its body as a whole. This balance is influenced by two groups of factors, personal and physical. The activity level and clothing thermal insulation of the subject form the group of personal factors, while the environmental parameters: air temperature, mean radiant temperature, air velocity, and air humidity compose the group of physical factors. When the personal factors have been estimated and the physical factors have been measured the thermal sensation for the body as a whole (general thermal comfort) can be predicted by calculating the PMV index. The PPD index, obtained from the PMV index, provides information on thermal discomfort (thermal dissatisfaction) by predicting the percentage of people likely to feel too hot or too cold in the given thermal environment.
The Predicted Mean Vote (PMV) model combines four physical variables (air temperature, air velocity, mean radiant temperature, and relative humidity), and two personal variables (clothing insulation and activity level) into an index that can be used to predict the average thermal sensation of a large group of people.
To determine appropriate thermal conditions, practitioners refer to standards such as ASHRAE Standard 55 (ASHRAE, 1992) and ISO Standard 7730 (ISO, 1994). These standards define temperature ranges that should result in thermal satisfaction for at least 80% of occupants in a space.
Cold | Cool | Slightly cool | Neutral | Slightly warm | Warm | Hot |
-3 | -2 | -1 | 0 | +1 | +2 | +3 |
Summer:
clothing = 0.5 clo,
air flow = 50 fpm (0.25 m/sec),
Optimum Operative Temperature (top) = 24.4° C (76° F).
All equation numbers in the model refer to the ASHRAE Handbook Fundamentals, Chapter 8, Thermal Comfort, 1997.
The following table is obtained from ASHRAE page 8.8
Clothing ensemble | clo |
---|---|
ASHRAE Standard 55 Winter | 0.90 |
ASHRAE Standard 55 Summer | 0.50 |
Walking shorts, short-sleeve shirt | 0.36 |
Trousers, long-sleeve shirt | 0.61 |
Trousers, long-sleeve shirt, suit jacket | 0.96 |
Trousers, long-sleeve shirt, suit jacket, T-shirt | 1.14 |
Trousers, long-sleeve shirt, long-sleeve sweater, T-shirt | 1.01 |
Same as above + suit jacket, long underwear bottoms | 1.30 |
Sweat pants, sweat shirt | 0.74 |
Knee-length skirt, short-sleeve shirt, panty hose, sandals | 0.54 |
Knee-length skirt, long-sleeve shirt, full slip, panty hose | 0.67 |
Knee-length skirt, long-sleeve shirt, half slip, panty hose, long sleeve sweater | 1.10 |
Long-sleeve coveralls, T-shirt | 0.72 |
Insulated coveralls, long-sleeve, thermal underwear, long underwear bottoms | 1.37 |
The following table is obtained from ASHRAE page 8.6.
Activity | W/m2 body surface area |
---|---|
ASHRAE Standard 55 | 58.2 |
reclining | 45 |
seated and quiet | 60 |
sedentary activity (reading, writing) | 60 |
standing, relaxed | 70 |
office (filling while standing) | 80 |
office (walking) | 100 |
Sleeping | 40 |
Seated quiet | 60 |
Standing Relaxed | 70 |
Walking 3.2 - 6.4km/h | 115-220 |
Reading | 55 |
Writing | 60 |
Typing | 65 |
Lifting/packing | 120 |
Driving Car | 60-115 |
Driving Heavy vehicle | 185 |
Cooking | 95-115 |
Housecleaning | 115-200 |
Machine work | 105-235 |
Pick and shovel work | 235-280 |
Dancing-Social | 140-225 |
Calisthenics | 175-235 |
Basketball | 290-440 |
Wrestling | 410-505 |
Extends from Buildings.BaseClasses.BaseIcon (Base icon).
Type | Name | Default | Description |
---|---|---|---|
HeatFlux | W | 0 | Rate of mechanical work accomplished (must be non-positive, typically equal to 0) [W/m2] |
CoefficientOfHeatTransfer | hRad | 0.8*4.7 | Radiative heat transfer coefficient [W/(m2.K)] |
Conditional inputs | |||
Boolean | use_vAir_in | false | Get the air velocity from the input connector |
Boolean | use_M_in | false | Get the metabolic rate from the input connector |
Boolean | use_ICl_in | true | Get the clothing insulation from the input connector |
Boolean | use_pAir_in | false | Get the air pressure from the input connector |
Velocity | vAir | 0.05 | Fixed value for air velocity [m/s] |
HeatFlux | M | 60 | Fixed value for metabolic rate [W/m2] |
Real | ICl | Fixed value for clothing insulation in units of clo (summer=0.5; winter=0.9) | |
Pressure | pAir | 101325 | Fixed value for air pressure [Pa] |
Type | Name | Description |
---|---|---|
output RealOutput | PMV | PMV |
output RealOutput | PPD | PPD [0.05...1] |
input RealInput | TAir | Air temperature [K] |
input RealInput | TRad | Radiation temperature [K] |
input RealInput | phi | Relative humidity |
input RealInput | pAir_in | Air pressure [Pa] |
input RealInput | ICl_in | Clothing thermal resistance in clo |
input RealInput | vAir_in | Air velocity |
input RealInput | M_in | Metabolic heat generation in W/m2 (not in met) [W/m2] |
model Fanger "Thermal comfort model according to Fanger" extends Buildings.BaseClasses.BaseIcon;Modelica.Blocks.Interfaces.RealOutput PMV "PMV"; Modelica.Blocks.Interfaces.RealOutput PPD "PPD [0.05...1]"; parameter Modelica.SIunits.HeatFlux W(max=0)=0 "Rate of mechanical work accomplished (must be non-positive, typically equal to 0)"; parameter Modelica.SIunits.CoefficientOfHeatTransfer hRad( min=0, max=10)=0.8*4.7 "Radiative heat transfer coefficient"; parameter Boolean use_vAir_in=false "Get the air velocity from the input connector"; parameter Boolean use_M_in= false "Get the metabolic rate from the input connector"; parameter Boolean use_ICl_in= true "Get the clothing insulation from the input connector"; parameter Boolean use_pAir_in= false "Get the air pressure from the input connector"; parameter Modelica.SIunits.Velocity vAir= 0.05 "Fixed value for air velocity"; parameter Modelica.SIunits.HeatFlux M = 60 "Fixed value for metabolic rate"; parameter Real ICl "Fixed value for clothing insulation in units of clo (summer=0.5; winter=0.9)"; parameter Modelica.SIunits.Pressure pAir = 101325 "Fixed value for air pressure";Modelica.Blocks.Interfaces.RealInput TAir(final quantity="Temperature", final unit = "K", displayUnit = "degC") "Air temperature"; Modelica.Blocks.Interfaces.RealInput TRad(final quantity="Temperature", final unit = "K", displayUnit = "degC") "Radiation temperature"; Modelica.SIunits.Temperature TOpe "Operative temperature"; Modelica.SIunits.Temperature TClo "Surface temperature of clothing"; Modelica.SIunits.Temperature TSki( min=273.15+10, max=273.15+42) "Skin temperature";Modelica.Blocks.Interfaces.RealInput phi(min=0, max=1) "Relative humidity"; Modelica.Blocks.Interfaces.RealInput pAir_in( final quantity="Pressure", final unit="Pa", min=0) if use_pAir_in "Air pressure"; Modelica.Blocks.Interfaces.RealInput ICl_in if use_ICl_in "Clothing thermal resistance in clo"; Modelica.Blocks.Interfaces.RealInput vAir_in if use_vAir_in "Air velocity"; Modelica.Blocks.Interfaces.RealInput M_in( min=40, max=600, final quantity="HeatFlux", final unit="W/m2") if use_M_in "Metabolic heat generation in W/m2 (not in met)"; Modelica.SIunits.CoefficientOfHeatTransfer hCom( min=0, max=10) "Combined heat transfer coefficient"; Modelica.SIunits.CoefficientOfHeatTransfer hCon( min=0, max=10) "Convective heat transfer coefficient"; Modelica.SIunits.Pressure pSte( min=0, max=3000) "Partial pressure of water vapor in ambient air"; Modelica.SIunits.HeatFlux L "Thermal load of the body"; Real fCl(min=0) "Clothing area factor (61)"; Modelica.SIunits.ThermalInsulance RCl "Thermal resistance of clothing (10)"; protected Buildings.Utilities.Psychrometrics.X_pTphi steRat "Model to compute the steam mass fraction"; Real fCl1 "work variable for fCl"; Real fCl2 "work variable for fCl"; Real aux "Auxiliary variable used to eliminate common subexpressions"; Modelica.Blocks.Interfaces.RealInput vAir_in_internal "Needed to connect to conditional connector"; Modelica.Blocks.Interfaces.RealInput M_in_internal( min=40, max=600, final quantity="HeatFlux", final unit="W/m2") "Needed to connect to conditional connector"; Modelica.Blocks.Interfaces.RealInput ICl_in_internal "Needed to connect to conditional connector"; Modelica.Blocks.Interfaces.RealInput pAir_in_internal( final quantity="Pressure", final unit="Pa", min=0) "Needed to connect to conditional connector"; initial equation assert(W <= 0, "Parameter W must be equal to zero or negative."); equation // Conditional connectors connect(vAir_in, vAir_in_internal); if not use_vAir_in then vAir_in_internal = vAir; end if; connect(M_in, M_in_internal); if not use_M_in then M_in_internal = M; end if; connect(ICl_in, ICl_in_internal); if not use_ICl_in then ICl_in_internal = ICl; end if; connect(pAir_in, pAir_in_internal); if not use_pAir_in then pAir_in_internal = pAir; end if; TSki = 308.85 - 0.0275*(M_in_internal - W); // partial pressure of steam steRat.p_in = pAir_in_internal; connect(steRat.T, TAir); connect(steRat.phi, phi); pSte = Psychrometrics.Functions.pW_X(X_w=steRat.X[1], p=pAir_in_internal); // clothing insulation value RCl = 0.155 * ICl_in_internal; // clothing area factor fCl1 = 1.00 + 0.2*ICl_in_internal; fCl2 = 1.05 + 0.1*ICl_in_internal; // fcl eq (61) fCl = fCl1 + (fCl2 - fCl1)*Buildings.Utilities.Math.Functions.smoothHeaviside( x=(ICl_in_internal - 0.5), delta=0.01); // hCon, table 6, Mitchell hCon = 8.3*Buildings.Utilities.Math.Functions.smoothMax(x1=vAir_in_internal*vAir_in_internal, x2=0.0375213, deltaX=0.01)^0.3; hCom = hRad + hCon; // operative temperature (8) TOpe = (hRad*TRad + hCon*TAir)/hCom; // Clothing temperature (59) aux = - 3.05*(5.73 - 0.007*(M_in_internal - W) - pSte*1E-3) - 0.42*((M_in_internal - W) - 58.15) - 0.0173*M_in_internal*(5.87 - pSte*1E-3) - 0.0014*M_in_internal*(307.15 - TAir); TClo = Modelica.SIunits.Conversions.from_degC(35.7 - 0.0275 * (M_in_internal-W) - RCl * ( (M_in_internal-W) + aux)); // heat load on body, see (58) L = (M_in_internal - W) - 3.96*1e-8*fCl*(TClo^4 - TRad^4) - fCl*hCon*(TClo - TAir) + aux; // PMV (62) PMV = (0.303*Modelica.Math.exp(-0.036*M) + 0.028)*L; // PPD (64) PPD = 1 - 0.95*Modelica.Math.exp(-(0.03353*PMV^4 + 0.2179*PMV^2));end Fanger;