Correlation 18
- Last UpdatedOct 03, 2024
- 4 minute read
The following table lists the identification numbers of this correlation with respect to some well-known sources of thermodynamic data.
|
Source |
Correlation Number |
|---|---|
|
SimSci |
18 |
|
PPDS |
- |
|
DIPPR 801 |
1021 |
|
NIST TDE |
- |
|
DECHEMA IK-CAPE PPDX |
DIP5: DIPPR function for KVAP and VISV |
1 This correlation is the integrated form of the DIPPR 102 equation when DIPPR uses the equation for solid enthalpy and density. This correlation is not the full integrated version of the DIPPR 102, but DIPPR currently uses only the first two coefficients for solid enthalpy and density. Therefore, the first three coefficients of this correlation account for the integration of the first two coefficients of the DIPPR 102 equation.
The equation has the following form:
You must use at least 3 coefficients with this correlation.
You can use up to 5 coefficients with this correlation.
The input temperature must be in absolute units (K or R).
If you want to use the IK-CAPE DIP5 equation, set the C1 coefficient to zero.
Modification for specific heat in AVEVA Process Simulation
In the Component Data section of the Fluid Editor, AVEVA Process Simulation shows temperature-dependent correlations for specific heat instead of enthalpy. When
you enter correlation coefficients for specific heat in the Fluid Editor, you enter
values for the derivative (specific heat) form of the correlation (
).
However, AVEVA Thermodynamic Data Manager (TDM) shows temperature-dependant correlations for enthalpy, not specific heat. Therefore,
when you specify the temperature-dependent properties in TDM, you see and enter the
correlation coefficient values for the integrated (enthalpy) form of the equation
(
). When you specify the correlation coefficient values in TDM, you should take care
to follow the correct coefficient mapping between the AVEVA Process Simulation coefficients () and the TDM coefficients (). See Example of coefficient mapping between AVEVA Thermodynamic Data Manager and AVEVA
Process Simulation for more information.
Internally, AVEVA Process Simulation still uses the integrated (enthalpy) form of the equation to perform calculations.
The 
coefficient in TDM is the constant of integration, and this term cancels out when
performing calculations. Therefore, you can set the coefficient in TDM to any value without affecting the calculation results. When we
specify the coefficient mapping for the correlation, we set the coefficient to zero, but you can use any value in TDM and still get matching calculation
results in both AVEVA Process Simulation and TDM.
The following equation shows the derivative form of this correlation:
The following equations show the coefficient mapping between the integrated and derivative forms of the correlation:
You must use at least 2 coefficients with this correlation.
You can use up to 4 coefficients with this correlation.
Usage
We recommend that you use this correlation to calculate only the following properties:
-
Solid Enthalpy
-
Solid Specific Heat Capacity
-
Solid Density
References
-
Thermodynamics-Package for CAPE-Applications. DECHEMA e.V. [Online] March 28, 2002, pp 7-10. http://dechema.de/dechema_media/IK_CAPE_Equations-p-888.pdf (accessed May 1, 2018).