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on the entering and modifying data in the SysCAD.93.db3 file, please see Species Table. In addition to the Standard species model, which is available to

Navigation: User Guide ➔ View ➔ Plant Model ➔ Species This tab page on the Plant Model Access Window has a number of parameters that the user may either

Latest SysCAD Version: 23 April 2024 - SysCAD 9.3 Build 139.35250 Related Links: Alumina 3 Bayer Species Model The Precipitator is modelled as a continuous

thermodynamic model solution back into SysCAD species. When all species predicted by a TCE equilibrium solution are directly mapped to SysCAD species, reverse mapping

solute species Cp is based on ALL aqueous species dissolved in the solution regardless of Cp method selected for the individual solute species. This method

some configuration data has since been changed. In such case, the current solution is not valid and project solve is required. Most Data Fields can be copied

of other species in solution, most importantly NaCl and MgCl2. The curve for KCl solubility as a single species is not valid when other species are present

the Temperature and Pressure AND the species composition, on the Define Species - DSp page. The Default species composition in a Feeder is 100% water

the OLI algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to OLI streams is done via Species Mapping. The OLI Reactor

of species that have been developed for use with sugar solutions, although any species may be added. The species and descriptions are in the table below

Temperature = {25, 30, 35} const Array AcidConc = {0, 9.8} const matrix GypsumSolubility = { {2.12, 2.11, 2.10}, {1.77, 1.82, 1.88} } ;Array Temperature = {25

set nFC = -2, nC = 2 : [math]\displaystyle{ \left(\cfrac{A_o - A^*}{F}\right)^2=\left(\cfrac{A_o - A^*}{C}\right)^2 \times \cfrac{C^2}{F^2} }[/math] SAL

calculations to generate a set of data. The data can be copied and pasted into external programs such as Excel to allow the data to be plotted and analysed.

have surge). Example 2: Dynamic Project Overall Mass Balance See How to perform a Species Mass Balance See also Example PGM - Species Check for how to check

PHREEQC algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to PHREEQC streams is done via Species Mapping. The PHREEQC

algorithms and data to determine the status of the aqueous solution in the defined stream/s. Mapping of the SysCAD to PHREEQC streams is done via Species Mapping

138 to Build 139. A table of the SysCAD 9.3 Build 139 changes at the time of first release are shown below. Please click on the table headings, or use the

the OLI algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to OLI streams is done via Species Mapping. The OLI Mixer

Vapour is flashed off and the remaining solution is then supersaturated with the required species. This species then precipitates out as the crystal product

'map' OLI species/ions to SysCAD species/ions used in the project. This allows the other OLI models in SysCAD to convert the SysCAD species flow data to OLI

PHREEQC algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to PHREEQC streams is done via Species Mapping. The PHREEQC

algorithms and data to determine the status of the aqueous solution in the defined stream/s. Mapping of the SysCAD to OLI streams is done via Species Mapping

ensure the organic species are defined with a lower density than the aqueous species. This requires the specification of appropriate data for organic-aqueous

configuration file. In Step 2 of 2, select the Species tab, select the required "Species Display Order". (See also Customising the Species Display Window) Use

Evaporator has solubility data for the species, then the amount of species that precipitates will be automatically calculated. The solution properties will be

AQSol algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to AQSol streams is done via Species Mapping. The AQSol

the OLI algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to OLI streams is done via Species Mapping. The OLI Reverse

32925 21 Apr 2023 Video: Modelling Non-Ideal Binary Solutions using SysCAD GFEM and Optimising Solution Parameters 29 Mar 2023 Conference attendance: We are

Vapour is flashed off and the remaining solution is then supersaturated with the required species. This species then precipitates out as the crystal product

the OLI algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to OLI streams is done via Species Mapping. The OLI Feeder

calculations to generate a set of data. The data can be copied and pasted into external programs such as Excel to allow the data to be plotted and analysed.

Evaporator has solubility data for the species, then the amount of species that precipitates will be automatically calculated. The solution properties will be

Standard species model, primarily a mass weighted mean method. These calculations are illustrated using the example below: Table 1 Stream Make Up Table 2 Species

Vapour is flashed off and the remaining solution is then supersaturated with the required species. This species then precipitates out as the crystal product

Evaporator has solubility data for the species, then the amount of species that precipitates will be automatically calculated. The solution properties will be

PHREEQC species/ions to SysCAD species/ions used in the project. This allows the other PHREEQC models in SysCAD to convert the SysCAD species flow data to PHREEQC

mapping step testing if both aqueous acid species and aqueous base species are present in the SysCAD solution. New display of total solids yield, useful

PHREEQC algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to PHREEQC streams is done via Species Mapping. The PHREEQC

\Theta_2)^{1.5}}\right]^{\frac{1}{12}} }[/math] where [math]\displaystyle{ \Theta_1 = \left[-2.457 \ln\left( \left(\frac{7}{\mathrm{Re}}\right)^{0.9} + 0

algorithms and data to determine the status of the aqueous solution in the defined stream/s. Mapping of the SysCAD to AQSol streams is done via Species Mapping

please make sure Plant Model - Species tab - Species Property Overrides - Vapours is set to IF97_2 for H2O(g).Rho and H2O(g).Cp. Please solve and retune

flashing/condensing of a species, user must specify the vapour pressure data for the species. The vapour pressure data for H2O is included in SysCAD. Users

AQSol algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to AQSol streams is done via Species Mapping. The AQSol

The SysCAD feed stream(s) using SysCAD species is converted into ChemApp "Input" using ChemApp Species. The species mapping is defined in the corresponding

calculations to generate a set of data. The data can be copied and pasted into external programs such as Excel to allow the data to be plotted and analysed.

other liquid, as selected in the Solvent section of the species database. (Please see Species Table - Density and Editing SysCAD Database) Since this method

the OLI algorithms and data to determine the status of the aqueous solution. Mapping of the SysCAD to OLI streams is done via Species Mapping. The OLI Pond

DotProduct = y.inner(y2) ;sum of each element y_i * y2_i, returns 45068 EndSub ;Logic d = a.GetLen() ;gets the array length a.SetAll(2.2/2) ;sets all elements

of differences between SysCAD 9.1 and SysCAD 9.2, please refer to SysCAD 9.2 Release Notes. Install SysCAD 9.2. This should be installed to a new location

➔ Energy Transfer Models ➔ Shell and Tube Heat Exchanger 2 The Shell and Tube Heat Exchanger 2 is used to transfer energy from one stream to another. It