Buildings.Media.Specialized.Water.TemperatureDependentDensity
Package with model for liquid water with temperature-dependent density
Information
This medium package models liquid water.
The mass density is computed using a 3rd order polynomial, which yields the density as a function of temperature as shown in the figure below. Note, however, that computing density as a function of temperature can lead to considerably slower computing time compared to using Buildings.Media.Water in which the density is a constant. We therefore recommend to use Buildings.Media.Water for typical building energy simulations.
For the specific heat capacities at constant pressure and at constant volume, a constant value of 4184 J/(kg K), which corresponds to 20°C is used. The figure below shows the relative error of the specific heat capacity that is introduced by this simplification. Using a constant value for the specific heat capacity allows to compute temperature from enthalpy without having to solve an implicit equation, and therefore leads to faster simulation.
Thermal conductivity is calculated as a function of temperature as shown in the figure below. The correlation used to calculate the thermal conductivity is
λ(T) = λ(298.15 K) ⋅ (-1.48445+4.12292⋅(T/298.15)-1.63866⋅(T/298.15)2),
where λ(298.15 K) = 0.6065 W/(m ⋅ K) is the adopted standard value of the thermal conductivity of water at 298.15 K and 0.1 MPa.
Dynamic viscosity is calculated as the product of density and kinematic viscosity, both temperature dependent. However, the kinematic viscosity has its own temperature dependent correlation, implemented at Buildings.Media.Specialized.Water.TemperatureDependentDensity.kinematicViscosity. Results of the kinematic viscosity as a function of temperature are shown in the figure below.
The enthalpy is computed using the convention that h=0 if T=0 °C.
Limitations
Phase changes are not modeled.
Extends from Modelica.Media.Interfaces.PartialPureSubstance (Base class for pure substances of one chemical substance), Modelica.Icons.Package (Icon for standard packages).
Package Content
Name | Description |
---|---|
FluidConstants | |
ThermodynamicState | Thermodynamic state variables |
cp_const=4184 | Specific heat capacity at constant pressure |
BaseProperties | Base properties |
density | Return the density |
dynamicViscosity | Return the dynamic viscosity |
specificEnthalpy | Return the specific enthalpy |
enthalpyOfLiquid | Return the specific enthalpy of liquid |
specificInternalEnergy | Return the specific enthalpy |
specificEntropy | Return the specific entropy |
specificGibbsEnergy | Return the specific Gibbs energy |
specificHelmholtzEnergy | Return the specific Helmholtz energy |
isentropicEnthalpy | Return the isentropic enthalpy |
isobaricExpansionCoefficient | Return the isobaric expansion coefficient |
isothermalCompressibility | Return the isothermal compressibility factor |
density_derp_T | Return the partial derivative of density with respect to pressure at constant temperature |
density_derT_p | Return the partial derivative of density with respect to temperature at constant pressure |
density_derX | Return the partial derivative of density with respect to mass fractions at constant pressure and temperature |
specificHeatCapacityCp | Return the specific heat capacity at constant pressure |
specificHeatCapacityCv | Return the specific heat capacity at constant volume |
thermalConductivity | Return the thermal conductivity |
pressure | Return the pressure |
temperature | Return the temperature |
molarMass | Return the molar mass |
setState_dTX | Return thermodynamic state from d, T, and X or Xi |
setState_phX | Return the thermodynamic state as function of pressure p, specific enthalpy h and composition X or Xi |
setState_pTX | Return the thermodynamic state as function of p, T and composition X or Xi |
setState_psX | Return the thermodynamic state as function of p, s and composition X or Xi |
cv_const=cp_const | Specific heat capacity at constant volume |
a_const=1484 | Constant velocity of sound |
MM_const=0.018015268 | Molar mass |
der_specificHeatCapacityCp | Return the derivative of the specific heat capacity at constant pressure |
der_enthalpyOfLiquid | Temperature derivative of enthalpy of liquid per unit mass of liquid |
kinematicViscosity | Return the kinematic viscosity |
Inherited | |
setState_pT | Return thermodynamic state from p and T |
setState_ph | Return thermodynamic state from p and h |
setState_ps | Return thermodynamic state from p and s |
setState_dT | Return thermodynamic state from d and T |
density_ph | Return density from p and h |
temperature_ph | Return temperature from p and h |
pressure_dT | Return pressure from d and T |
specificEnthalpy_dT | Return specific enthalpy from d and T |
specificEnthalpy_ps | Return specific enthalpy from p and s |
temperature_ps | Return temperature from p and s |
density_ps | Return density from p and s |
specificEnthalpy_pT | Return specific enthalpy from p and T |
density_pT | Return density from p and T |
ThermoStates=Modelica.Media.Interfaces.Choices.IndependentVariables.T | Enumeration type for independent variables |
mediumName="WaterDetailed" | Name of the medium |
substanceNames={mediumName} | Names of the mixture substances. Set substanceNames={mediumName} if only one substance. |
extraPropertiesNames=fill("", 0) | Names of the additional (extra) transported properties. Set extraPropertiesNames=fill("",0) if unused |
singleState=true | = true, if u and d are not a function of pressure |
reducedX=true | = true if medium contains the equation sum(X) = 1.0; set reducedX=true if only one substance (see docu for details) |
fixedX=true | = true if medium contains the equation X = reference_X |
reference_p=300000 | Reference pressure of Medium: default 1 atmosphere |
reference_T=273.15 | Reference temperature of Medium: default 25 deg Celsius |
reference_X={1} | Default mass fractions of medium |
p_default=300000 | Default value for pressure of medium (for initialization) |
T_default=Modelica.Units.Conversions.from_degC(20) | Default value for temperature of medium (for initialization) |
h_default=specificEnthalpy_pTX(p_default, T_default, X_default) | Default value for specific enthalpy of medium (for initialization) |
X_default=reference_X | Default value for mass fractions of medium (for initialization) |
C_default=fill(0, nC) | Default value for trace substances of medium (for initialization) |
nS=size(substanceNames, 1) | Number of substances |
nX=nS | Number of mass fractions |
nXi=if fixedX then 0 else if reducedX then nS - 1 else nS | Number of structurally independent mass fractions (see docu for details) |
nC=size(extraPropertiesNames, 1) | Number of extra (outside of standard mass-balance) transported properties |
C_nominal=1.0e-6*ones(nC) | Default for the nominal values for the extra properties |
setSmoothState | Return thermodynamic state so that it smoothly approximates: if x > 0 then state_a else state_b |
prandtlNumber | Return the Prandtl number |
heatCapacity_cp | Alias for deprecated name |
heatCapacity_cv | Alias for deprecated name |
isentropicExponent | Return isentropic exponent |
velocityOfSound | Return velocity of sound |
beta | Alias for isobaricExpansionCoefficient for user convenience |
kappa | Alias of isothermalCompressibility for user convenience |
density_derp_h | Return density derivative w.r.t. pressure at const specific enthalpy |
density_derh_p | Return density derivative w.r.t. specific enthalpy at constant pressure |
specificEnthalpy_pTX | Return specific enthalpy from p, T, and X or Xi |
specificEntropy_pTX | Return specific enthalpy from p, T, and X or Xi |
density_pTX | Return density from p, T, and X or Xi |
temperature_phX | Return temperature from p, h, and X or Xi |
density_phX | Return density from p, h, and X or Xi |
temperature_psX | Return temperature from p,s, and X or Xi |
density_psX | Return density from p, s, and X or Xi |
specificEnthalpy_psX | Return specific enthalpy from p, s, and X or Xi |
MassFlowRate | Type for mass flow rate with medium specific attributes |
AbsolutePressure | Type for absolute pressure with medium specific attributes |
Density | Type for density with medium specific attributes |
DynamicViscosity | Type for dynamic viscosity with medium specific attributes |
EnthalpyFlowRate | Type for enthalpy flow rate with medium specific attributes |
MassFraction | Type for mass fraction with medium specific attributes |
MoleFraction | Type for mole fraction with medium specific attributes |
MolarMass | Type for molar mass with medium specific attributes |
MolarVolume | Type for molar volume with medium specific attributes |
IsentropicExponent | Type for isentropic exponent with medium specific attributes |
SpecificEnergy | Type for specific energy with medium specific attributes |
SpecificInternalEnergy | Type for specific internal energy with medium specific attributes |
SpecificEnthalpy | Type for specific enthalpy with medium specific attributes |
SpecificEntropy | Type for specific entropy with medium specific attributes |
SpecificHeatCapacity | Type for specific heat capacity with medium specific attributes |
SurfaceTension | Type for surface tension with medium specific attributes |
Temperature | Type for temperature with medium specific attributes |
ThermalConductivity | Type for thermal conductivity with medium specific attributes |
PrandtlNumber | Type for Prandtl number with medium specific attributes |
VelocityOfSound | Type for velocity of sound with medium specific attributes |
ExtraProperty | Type for unspecified, mass-specific property transported by flow |
CumulativeExtraProperty | Type for conserved integral of unspecified, mass specific property |
ExtraPropertyFlowRate | Type for flow rate of unspecified, mass-specific property |
IsobaricExpansionCoefficient | Type for isobaric expansion coefficient with medium specific attributes |
DipoleMoment | Type for dipole moment with medium specific attributes |
DerDensityByPressure | Type for partial derivative of density with respect to pressure with medium specific attributes |
DerDensityByEnthalpy | Type for partial derivative of density with respect to enthalpy with medium specific attributes |
DerEnthalpyByPressure | Type for partial derivative of enthalpy with respect to pressure with medium specific attributes |
DerDensityByTemperature | Type for partial derivative of density with respect to temperature with medium specific attributes |
DerTemperatureByPressure | Type for partial derivative of temperature with respect to pressure with medium specific attributes |
SaturationProperties | Saturation properties of two phase medium |
FluidLimits | Validity limits for fluid model |
FixedPhase | Phase of the fluid: 1 for 1-phase, 2 for two-phase, 0 for not known, e.g., interactive use |
Basic | The most basic version of a record used in several degrees of detail |
IdealGas | The ideal gas version of a record used in several degrees of detail |
TwoPhase | The two phase fluid version of a record used in several degrees of detail |
Types and constants
constant Modelica.Units.SI.SpecificHeatCapacity cp_const=4184 "Specific heat capacity at constant pressure";
final constant Modelica.Units.SI.SpecificHeatCapacity cv_const=cp_const "Specific heat capacity at constant volume";
constant Modelica.Units.SI.VelocityOfSound a_const=1484 "Constant velocity of sound";
constant Modelica.Units.SI.MolarMass MM_const=0.018015268 "Molar mass";
Buildings.Media.Specialized.Water.TemperatureDependentDensity.FluidConstants
Parameters
Type | Name | Default | Description |
---|---|---|---|
Custom Parameters | |||
String | iupacName | "oxidane" | Complete IUPAC name (or common name, if non-existent) |
String | casRegistryNumber | "7732-18-5" | Chemical abstracts sequencing number (if it exists) |
String | chemicalFormula | "H2O" | Chemical formula, (brutto, nomenclature according to Hill |
String | structureFormula | "H2O" | Chemical structure formula |
MolarMass | molarMass | MM_const | Molar mass [kg/mol] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.ThermodynamicState
Thermodynamic state variables
Information
Extends from (Minimal variable set that is available as input argument to every medium function).
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.BaseProperties
Base properties
Information
Base properties of the medium.
Parameters
Type | Name | Default | Description |
---|---|---|---|
Advanced | |||
Boolean | preferredMediumStates | true | = true if StateSelect.prefer shall be used for the independent property variables of the medium |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.density
Return the density
Information
This function computes the density as a function of temperature.
Implementation
The function is based on the IDA implementation in therpro.nmf
, which
implements
d := 1000.12 + 1.43711e-2*T_degC - 5.83576e-3*T_degC^2 + 1.5009e-5*T_degC^3;
This has been converted to Kelvin, which resulted in the above expression. In addition, below 5 °C and above 100 °C, the density is replaced by a linear function to avoid inflection points. This linear extension is such that the density is once continuously differentiable.
Extends from (Return density).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
Density | d | Density [kg/m3] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.dynamicViscosity
Return the dynamic viscosity
Information
This function computes the dynamic viscosity.
Extends from (Return dynamic viscosity).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
DynamicViscosity | eta | Dynamic viscosity [Pa.s] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificEnthalpy
Return the specific enthalpy
Information
This function computes the specific enthalpy.
Extends from (Return specific enthalpy).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
SpecificEnthalpy | h | Specific enthalpy [J/kg] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.enthalpyOfLiquid
Return the specific enthalpy of liquid
Information
This function computes the specific enthalpy of liquid water.
Extends from Modelica.Icons.Function (Icon for functions).
Inputs
Type | Name | Default | Description |
---|---|---|---|
Temperature | T | Temperature [K] |
Outputs
Type | Name | Description |
---|---|---|
SpecificEnthalpy | h | Specific enthalpy [J/kg] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificInternalEnergy
Return the specific enthalpy
Information
This function computes the specific internal energy.
Extends from (Return specific internal energy).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
SpecificEnergy | u | Specific internal energy [J/kg] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificEntropy
Return the specific entropy
Information
This function computes the specific entropy.
To obtain the state for a given pressure, entropy and mass fraction, use Buildings.Media.Air.setState_psX.
Extends from Modelica.Icons.Function (Icon for functions), (Return specific entropy).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
SpecificEntropy | s | Specific entropy [J/(kg.K)] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificGibbsEnergy
Return the specific Gibbs energy
Information
This function computes the specific Gibbs energy.
Extends from Modelica.Icons.Function (Icon for functions), (Return specific Gibbs energy).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
SpecificEnergy | g | Specific Gibbs energy [J/kg] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificHelmholtzEnergy
Return the specific Helmholtz energy
Information
This function computes the specific Helmholtz energy.
Extends from Modelica.Icons.Function (Icon for functions), (Return specific Helmholtz energy).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
SpecificEnergy | f | Specific Helmholtz energy [J/kg] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.isentropicEnthalpy
Return the isentropic enthalpy
Information
This function computes the specific enthalpy for
an isentropic state change from the temperature
that corresponds to the state refState
to reference_T
.
Extends from (Return isentropic enthalpy).
Inputs
Type | Name | Default | Description |
---|---|---|---|
AbsolutePressure | p_downstream | Downstream pressure [Pa] | |
ThermodynamicState | refState | Reference state for entropy |
Outputs
Type | Name | Description |
---|---|---|
SpecificEnthalpy | h_is | Isentropic enthalpy [J/kg] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.isobaricExpansionCoefficient
Return the isobaric expansion coefficient
Information
This function returns the isobaric expansion coefficient,
βp = - 1 ⁄ v (∂ v ⁄ ∂ T)p,
where v is the specific volume, T is the temperature and p is the pressure.
Extends from (Return overall the isobaric expansion coefficient beta).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
IsobaricExpansionCoefficient | beta | Isobaric expansion coefficient [1/K] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.isothermalCompressibility
Return the isothermal compressibility factor
Information
This function returns the isothermal compressibility coefficient, which is zero as this medium is incompressible. The isothermal compressibility is defined as
κT = - 1 ⁄ v (∂ v ⁄ ∂ p)T,
where v is the specific volume, T is the temperature and p is the pressure.
Extends from (Return overall the isothermal compressibility factor).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
IsothermalCompressibility | kappa | Isothermal compressibility [1/Pa] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.density_derp_T
Return the partial derivative of density with respect to pressure at constant temperature
Information
This function returns the partial derivative of density with respect to pressure at constant temperature, which is zero as the medium is incompressible.
Extends from (Return density derivative w.r.t. pressure at const temperature).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
DerDensityByPressure | ddpT | Density derivative w.r.t. pressure [s2/m2] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.density_derT_p
Return the partial derivative of density with respect to temperature at constant pressure
Information
This function computes the derivative of density with respect to temperature at constant pressure.
Extends from (Return density derivative w.r.t. temperature at constant pressure).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
DerDensityByTemperature | ddTp | Density derivative w.r.t. temperature [kg/(m3.K)] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.density_derX
Return the partial derivative of density with respect to mass fractions at constant pressure and temperature
Information
This function returns the partial derivative of density with respect to mass fraction, which is zero as the medium is a single substance.
Extends from (Return density derivative w.r.t. mass fraction).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
Density | dddX[nX] | Derivative of density w.r.t. mass fraction [kg/m3] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificHeatCapacityCp
Return the specific heat capacity at constant pressure
Information
This function returns the specific heat capacity at constant pressure.
Extends from (Return specific heat capacity at constant pressure).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
SpecificHeatCapacity | cp | Specific heat capacity at constant pressure [J/(kg.K)] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificHeatCapacityCv
Return the specific heat capacity at constant volume
Information
This function computes the specific heat capacity at constant volume.
Extends from (Return specific heat capacity at constant volume).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
SpecificHeatCapacity | cv | Specific heat capacity at constant volume [J/(kg.K)] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.thermalConductivity
Return the thermal conductivity
Information
This function returns the thermal conductivity. The expression is obtained from Ramires et al. (1995).
References
Ramires, Maria L. V. and Nieto de Castro, Carlos A. and Nagasaka, Yuchi and Nagashima, Akira and Assael, Marc J. and Wakeham, William A. Standard Reference Data for the Thermal Conductivity of Water. Journal of Physical and Chemical Reference Data, 24, p. 1377-1381, 1995. DOI:10.1063/1.555963.
Extends from (Return thermal conductivity).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
ThermalConductivity | lambda | Thermal conductivity [W/(m.K)] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.pressure
Return the pressure
Information
This function returns the pressure.
Extends from (Return pressure).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
AbsolutePressure | p | Pressure [Pa] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.temperature
Return the temperature
Information
This function returns the temperature.
Extends from (Return temperature).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
Temperature | T | Temperature [K] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.molarMass
Return the molar mass
Information
This function returns the molar mass, which is assumed to be constant.
Extends from (Return the molar mass of the medium).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Outputs
Type | Name | Description |
---|---|---|
MolarMass | MM | Mixture molar mass [kg/mol] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.setState_dTX
Return thermodynamic state from d, T, and X or Xi
Information
Extends from Modelica.Icons.Function (Icon for functions).
Inputs
Type | Name | Default | Description |
---|---|---|---|
Density | d | Density [kg/m3] | |
Temperature | T | Temperature [K] | |
MassFraction | X[:] | reference_X | Mass fractions [kg/kg] |
Outputs
Type | Name | Description |
---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.setState_phX
Return the thermodynamic state as function of pressure p, specific enthalpy h and composition X or Xi
Information
This function returns the thermodynamic state for a given pressure, specific enthalpy and composition.
Extends from (Return thermodynamic state as function of p, h and composition X or Xi).
Inputs
Type | Name | Default | Description |
---|---|---|---|
AbsolutePressure | p | Pressure [Pa] | |
SpecificEnthalpy | h | Specific enthalpy [J/kg] | |
MassFraction | X[:] | reference_X | Mass fractions [kg/kg] |
Outputs
Type | Name | Description |
---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.setState_pTX
Return the thermodynamic state as function of p, T and composition X or Xi
Information
This function returns the thermodynamic state for a given pressure, temperature and composition.
Extends from (Return thermodynamic state as function of p, T and composition X or Xi).
Inputs
Type | Name | Default | Description |
---|---|---|---|
AbsolutePressure | p | Pressure [Pa] | |
Temperature | T | Temperature [K] | |
MassFraction | X[:] | reference_X | Mass fractions [kg/kg] |
Outputs
Type | Name | Description |
---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.setState_psX
Return the thermodynamic state as function of p, s and composition X or Xi
Information
This function returns the thermodynamic state based on pressure, specific entropy and mass fraction.
The state is computed by symbolically solving Buildings.Media.Specialized.Water.TemperatureDependentDensity.specificEntropy for temperature.
Extends from (Return thermodynamic state as function of p, s and composition X or Xi).
Inputs
Type | Name | Default | Description |
---|---|---|---|
AbsolutePressure | p | Pressure [Pa] | |
SpecificEntropy | s | Specific entropy [J/(kg.K)] | |
MassFraction | X[:] | reference_X | Mass fractions [kg/kg] |
Outputs
Type | Name | Description |
---|---|---|
ThermodynamicState | state | Thermodynamic state record |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.der_specificHeatCapacityCp
Return the derivative of the specific heat capacity at constant pressure
Information
This function computes the derivative of the specific heat capacity at constant pressure with respect to the state.
Extends from Modelica.Icons.Function (Icon for functions).
Inputs
Type | Name | Default | Description |
---|---|---|---|
ThermodynamicState | state | Thermodynamic state | |
ThermodynamicState | der_state | Derivative of thermodynamic state |
Outputs
Type | Name | Description |
---|---|---|
Real | der_cp | Derivative of specific heat capacity [J/(kg.K.s)] |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.der_enthalpyOfLiquid
Temperature derivative of enthalpy of liquid per unit mass of liquid
Information
This function computes the temperature derivative of the enthalpy of liquid water per unit mass.
Extends from Modelica.Icons.Function (Icon for functions).
Inputs
Type | Name | Default | Description |
---|---|---|---|
Temperature | T | Temperature [K] | |
Real | der_T | Temperature derivative |
Outputs
Type | Name | Description |
---|---|---|
Real | der_h | Derivative of liquid enthalpy |
Modelica definition
Buildings.Media.Specialized.Water.TemperatureDependentDensity.kinematicViscosity
Return the kinematic viscosity
Information
This function computes the kinematic viscosity as a function of temperature.
Implementation
The function is based on the IDA implementation in therpro.nmf
.
The original equation is
kinVis :=1E-6*Modelica.Math.exp(0.577449 - 3.253945e-2*T_degC + 2.17369e-4* T_degC^2 - 7.22111e-7*T_degC^3);
This has been converted to Kelvin, which resulted in the above expression. In addition, at 5 °C the kinematic viscosity is linearly extrapolated to avoid a large gradient at very low temperatures. We selected the same point for the linearization as we used for the density, as the density and the kinematic viscosity are combined in Buildings.Media.Specialized.Water.TemperatureDependentDensity.dynamicViscosity.
Extends from Modelica.Icons.Function (Icon for functions).
Inputs
Type | Name | Default | Description |
---|---|---|---|
Temperature | T | Temperature [K] |
Outputs
Type | Name | Description |
---|---|---|
KinematicViscosity | kinVis | Kinematic viscosity [m2/s] |