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8/3/2019 1.2.1 Getting Started_3
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Getting Started 1
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Getting Started
2000 AEA Technology plc - All Rights Reserved.Chem 1_3.pdf
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WorkshopThe Getting Started module introduces you to some of the basic
concepts necessary for creating simulations in HYSYS. Some of the
things you will learn from this module are:
Methods for moving through different environments
Selecting property packages and components
Adding streams
Attaching utilities
You will use HYSYS to define three streams. You will learn how to
determine the properties of these streams by using the Property Table
utility.
Learning ObjectivesOnce you have completed this section, you will be able to:
Define a Fluid Package (Property Package and Components)
Add Streams Understand Flash Calculations
Attach Stream Utilities
Customize the Workbook
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Building the SimulationThe Simulation Basis Manager
HYSYS uses the concept of the Fluid Package to contain all necessary
information for performing flash and physical property calculations.
This approach allows you to define all information (property package,
components, interaction parameters, reactions, tabular data,
hypothetical components, etc.) inside a single entity. There are three
key advantages to this approach:
All associated information is defined in a single location,allowing for easy creation and modification of the information
Fluid Packages can be stored as a completely separate entityfor use in any simulation
Multiple Fluid Packages can be used in the same simulation;however, they are all defined inside the common BasisManager.
The Simulation Basis Manager is a property view that allows you to
create and manipulate every Fluid Package in the simulation.
Whenever you begin a New Case, HYSYS places you at this location.
The opening tab of the Simulation Basis Manager, Fluid Pkgs, contains
the list of current Fluid Package definitions. You can use multiple Fluid
Packages within one simulation by assigning them to differentflowsheets and linking the flowsheets together.
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Inside the Current Fluid Packages group, there are a number of
buttons:
View - this is only active when a Fluid Package exists in thecase. It allows you to view the property view for the selectedFluid Package.
Add allows you to create and install a Fluid Package into thesimulation.
Delete removes the selected Fluid Package from thesimulation.
Copy makes a copy of the selected Fluid Package.
Everything is identical in the copied version, except the name.This is useful for modifying fluid packages.
Import allows you to import a predefined Fluid Package fromdisk. Fluid Packages have the file extension.fpk.
Export allows you to export the selected Fluid Package to adisk. The exported Fluid Package can be retrieved into anothercase, by using the Import function.
You can use the hot key to re-enter the Simulation Basis
Manager from any point in the simulation or choose the EnterBasis
Environmentbutton from the button bar.
Basis Environment button
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Defining the Simulation Basis1. Start a new case by selecting theNew Casebutton.
2. Create a Fluid Package by selecting theAddbutton from theSimulation Basis Manager.
3. Click theActivity Modelradio button and choose NRTL as theProperty Package.
4. Change the Name from the default Basis-1 to Stripper. Do this byclicking in the "Name" cell, and typing the new name. Hit the
key when you are finished.5. Switch to the Components tab. From this tab, you add
components to your case.
New Case button
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You can select components for your simulation using several different
methods:
Note: You can add a range of components by highlighting the entire
range and pressing theAdd Purebutton.
To Use Do This
Match Cell 1. Select one of the three nameformats, SimName, Full Name/Synonym, or Formulabyselecting the correspondingradio button.
2. Click on the Match cell and
enter the name of the
component. As you start to
type, the list will change to
match what you have entered.
3. Once the desired component ishighlighted either:
Press the key
Press the Add Purebutton
Double click on the component toadd it to your simulation.
Component List 1. Using the scroll bar for themain component list, scrollthrough the list until you findthe desired component.
2. To add the component either:
Press the key
Press the Add Purebutton
Double click on the component toadd it to your simulation
Family Filter 1. Ensure the Match cell is empty,and press the FamilyFilterbutton.
2. Select the desired family from
the Family Filter to display only
that type of component.
3. Use either of the two previous
methods to then select the
desired component.
4. To add the component either:
Press the key
Press the Add Purebutton
Double click on the component toadd it to your simulation
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5. Select the library components Chloroform, Toluene, Ethanol,H2O, Oxygen and Nitrogen.
6. Go to the Binary Coeffs tab. Press the Unknowns Onlybutton toestimate missing coefficients. View the Aij, Bij and ij matrices byselecting the corresponding radio button. The Aij matrix is shownbelow:
To view the Bijorijcoefficients, click theappropriate radio button intheCoefficient Matrix to Viewgroup.
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Exporting Fluid PackagesHYSYS allows you to export Fluid Packages for use in other simulations.
This functionality allows you to create a single common Fluid Package
which you may use in multiple cases.
1. On the Fluid Pkgs tab highlight the Stripper Fluid Package.
2. Press the Exportbutton.
3. Enter a unique name (Stripper) for the Fluid Package and pressthe OKbutton.
Now that the Fluid Package is now fully defined, you are ready to move
on and start building the simulation. Press the Enter Simulation
Environmentbutton or the Interactive Simulation Environment
button in the Button Bar.
HYSYS will automatically addthe file extension .fpk when itsaves your Fluid Package. Thefile is automatically saved tothe\HYSYS\pakssubdirectory.
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Selecting a Unit SetIn HYSYS, it is possible to change the unit set used to display the
different variables.
1. From the Tools menu, choose Preferences.
2. Switch to theVariables tab, and go to the Units page.
3. If it is not already selected, select the desired unit set. Both Fieldand SI units will be given in this course; you are free to use
whichever is more comfortable for you.4. Close the window to return to the simulation.
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Changing Units for a SpecificationTo change the units for a specification, simply type the numerical value
of the specification and press the space bar or click on the unit drop
down box. Choose the units for the value you are providing. HYSYS will
convert the units back to the default units.
You can scroll through theunit list by starting to type theunits, by using the arrow keysor by using the scroll bar.
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Adding StreamsIn HYSYS, there are two types of streams, Material and Energy. Material
streams have a composition and parameters such as temperature,
pressure and flowrates. They are used to represent Process Streams.
Energy streams have only one parameter, a Heat Flow. They are used to
represent the Duty supplied to or by a Unit Operation.
There are a variety of ways to add streams in HYSYS.
In this exercise, you will add three streams to represent the feeds to anair stripper. Each stream will be added using a different method of
installation.
To Use This Do This
Menu Bar SelectAdd Stream from the
Flowsheet menu.
Or
Press the Hot Key.
The Stream property view will open.
Workbook Open the Workbook and go to the
Material Streams tab. Type a stream
name into the **New** cell.
Object Palette Select Object Palette from the
Flowsheet menu or press to
open the Object Palette. Double
click on the stream icon.
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Adding a Stream from the Menu BarThis procedure describes how to add a stream using the hot key.
1. Press the hot key. The Stream Property view is displayed:
You can change the stream name by simply typing in a new name in the
Stream Name box.
2. Change the stream name to Eth rich.
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Entering Stream Compositions
There are two different methods to enter stream compositions from the
Worksheet tab.
3. Double click on the Mass Flowcell. The Input Composition forStream view displays.
4. We want to define the composition of this stream by specifyingthe mass flows for each component. By default, HYSYS has
chosen the basis for defining the composition as mass fraction.Press the Basisbutton and select the Mass Flowsradio button inthe Composition Basis group. You are now able to enter the datain the desired format.
When Using the Do This
Conditions page Double click on the Molar Flow cell
to enter mole fractions.
Or
Double click on the Mass Flow cell to
enter mass fractions.
Or
Double click on the LiqVolFlow cellto enter volume fractions.
The Input Composition for Stream
dialog is shown.
Composition page Press the Editbutton.
The Input Composition for Stream
dialog is shown.
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5. Enter the following compositions:
6. Press the OKbutton when all the mass flows have been entered.
7. Close the Stream Property view.
For This Component Enter This Mass Flow, kg/h (lb/hr)
Chloroform 2.5 (5.0)
Toluene 0
Ethanol 300 (600)
H2O 100 000 (200, 000)
Oxygen 0
Nitrogen 0
Note: If there are values, either enter 0 or presstheNormalizebutton.
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Adding a Stream from the WorkbookTo open or display the Workbook, press the Workbookbutton on the
Button Bar.
1. Enter the stream name, Tol rich in the **New** cell.
2. Enter the following component mass flow rates. You will have tochange the basis again.
3. Close the Stream Property view.
Workbook button
For This Component Enter This Mass Flow, kg/h (lb/hr)
Chloroform 1.5 (3.0)
Toluene 140 (280)
Ethanol 0
H2O 100 000 (200, 000)
Oxygen 0
Nitrogen 0
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Adding a Stream from the Object Palette
1. If the Object Palette is not open on the Desktop, press the hot key to open it.
2. Double Click on the Material Stream button. The StreamProperty view displays.
3. Change the name of the stream to Strip Air.
4. Double click on the Molar Flowcell and enter the followingstream compositions:
Saving your case
You can use one of several different methods to save a case in HYSYS:
From the File menu select Save to save your case with thesame name.
Form the File menu select Save As to save your case in adifferent location or with a different name.
Press the Save button on the button bar to save your case withthe same name.
Material Stream button (Blue)
For This Component Enter This Mole Fraction
Chloroform 0
Toluene 0
Ethanol 0
H2O 0
Oxygen 0.21
Nitrogen 0.79
Save your case often to avoidlosing information.
Save button
Save your case!
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Flash CalculationsHYSYS can perform five types of flash calculations on streams: P-T,
Vf-P, Vf-T, P-Molar Enthalpy and T-Molar Enthalpy. Once the
composition of the stream and two of either temperature, pressure,
vapour fraction or molar enthalpy are known, HYSYS performs a flash
calculation on the stream, calculating the other two parameters.
With the flash capabilities of HYSYS, it is possible to perform dew andbubble point calculations. By specifying a vapour fraction of1 and
either the pressure or temperature of the stream, HYSYS will calculate
the dew temperature or pressure. To calculate the bubble temperature
or pressure, a vapour fraction of0 and either pressure or temperature
must be entered.
1. Perform a T-P flash calculation on the streamTol Rich. Set the pressure to 101.3 kPa (14.7 psia) andthe temperature to 90C (200F). What is the vapourfraction? __________
2. Perform a dew point calculation on the streamTol Rich. Set the pressure to 101.3 kPa (14.7 psia).
What is the dew point temperature? __________3. Perform a bubble point calculation on the stream
Tol Rich. Set the pressure to 101.3 kPa (14.7 psia).What is the bubble point temperature? __________
Only 2 of these 4 streamparameters, Vapour Fraction,Temperature, PressureorMolar Enthalpycan besupplied.
If you try to supply temperature, pressure and vapourfraction, a consistency error can occur.
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Attaching UtilitiesThe utilities available in HYSYS are a set of useful tools that interact
with your process, providing additional information or analysis of
streams or operations. Once installed, the utility becomes part of the
Flowsheet, automatically calculating when conditions change in the
stream or operation to which it is attached.
As with the majority of objects in HYSYS, there are a number of ways to
attach utilities to streams.
To Use the Do this
Menu Bar Select Utilities from the Tools menu.or
Press the hot key.
TheAvailable Utilities window
displays.
Stream Property View Open the stream property view.
Switch to theAttachments tab and
choose the Utilities page. Press the
Createbutton.
TheAvailable Utilities window
displays.
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Adding a Utility from the Stream PropertyView
The Property Table utility allows you to examine property trends over a
range of conditions in both tabular and graphical formats. The utility
calculates dependent variables for up to two user specified
independent variable ranges or values.
A Property Table utility will be added to the stream Tol rich from the
stream propertyview.
1. Use the hot key combination to open theAvailableUtilities window.
2. Select Property Table from the menu on the right and press theAdd Utilitybutton. The Property Table view displays.
3. Press the Select Stream button and select the stream Tol rich.
4. Press the OKbutton to return to the Ind. Prop tab.
5. By default, Temperature is selected asVariable 1, and Pressure isselected asVariable 2.
6. Change the Lower Bound of the Temperature to 85 oC (185 oF)and change the Upper Bound to 100 oC (212 oF). Set the numberon increments to 5.
7. For the Pressure variable, use the drop down menu to change itsmode to State, and enter the following values: 90 kPa(13 psia),100 kPa(14.5 psia), 101.3 kPa(14.7 psia), 110 kPa(16.0 psia), and120 kPa(17.4 psia).
8. Switch to the Dep. Prop page.
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It is possible to choose multiple dependent properties for any of the
single phases (liquid, aqueous or vapour) or for the bulk phase.
9. Select the Bulkradio button and highlight a cell in the Propertymatrix.
10. Choose Mass Densityfrom the drop down list.
11. Select the Liquidradio button, and select theViscosityproperty.
12. Select theAqueousradio button, and select theAq. Mass Fractionproperty.
13. Select the Vapourradio button, and select theVapour MassFraction property.
14. Press the Calculate cell to generate the Property Table.
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You can examine the Property Table results in either graphical or
tabular formats on the Performance tab.
Finishing the Simulation
The final step in this section is to add the stream information necessary
for the case to be used in future modules.
Add the following temperatures and pressures to the streams:
Add a flowrate of18 000 kg/h(39, 700 lb/hr) to the stream Strip Air.
Examining the ResultsThe Stream Property View
Within HYSYS, it is possible to view the properties of the individual
phases for any stream.
1. Open the property view for the stream Tol Rich.
2. On theWorksheet tab, Conditions page, add a Temperaturevalue of90C (195F) and supply a pressure of101.3 kPa (14.7psia).
3. Move the mouse cursor to the left or right side of the view until
the cursor changes to resizing arrows.4. Press and hold the left mouse button and drag the edge of the
view until all the phases can be seen.
Pressure, kPa (psia) Temp., C (F)
Eth rich 101 kPa (14.7 psia) 15C (60F)
Tol rich 101 kPa (14.7 psia) 15C (60F)
Strip Air 101 kPa (14.7 psia) 25C (77F)
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The pages Properties and Composition also show data for the
individual phases.
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Customizing the WorkbookHYSYS allows you to customize the Workbook at several different levels.
You can add additional pages, change the variables which are displayed
on the current pages, or change the format of the values which are
displayed.
In this exercise a new Workbook tab containing stream properties,Vap
Frac on a Mass Basis, Molecular Weight, Mass Density and Mass
Enthalpy, will be added.
1. Open the Workbook by pressing the Workbookbutton on the
button bar.
2. From theWorkbookmenu, select Setup. The Setup windowdisplays.
3. Under theWorkbook Tabs group, press theAdd button, and inthe view which appears, select +Stream and press OK.
4. A new Workbook tab, Streams 2, will be listed in theWorkbookTabs group. Ensure that this new tab is highlighted.
5. Highlight the Name cell in the Tab Contents group, and changethe name to Other Prop.
6. In theVariables group, press the Deletebutton until all thedefault variables are removed.
7. Click theAddbutton to view the list of variables grouped underthe Select Variable(s) For Main page.
8. From theVariables list, selectVap Frac on a Mass Basis and clickOK.
Workbook button
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9. Repeat 7 and 8 for Molecular Weight, Mass DensityandMass Enthalpy.
10. Close this view to return to the Workbook.
The Workbook now contains the tab Other Prop which shows the
vapour fraction on a mass basis, the molecular weight, the mass density
and the mass enthalpy for all the components for the three streams.
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Printing Stream and WorkbookDatasheets
In HYSYS you have the ability to print datasheets for Streams,
Operations and Workbooks.
Printing the Workbook Datasheet
1. Open the Workbook.
2. Right click (Object Inspect) the Workbook title bar. The PrintDatasheet or Open Page pop-up menu appears.
3. Select Print Datasheet and the Select Datablock(s) to Print forWorkbookwindow is displayed.
4. You can choose to print or preview any of the available datasheets(press the + collapse button to view all available datasheets).Clicking on the box will activate or deactivate the datasheet forprinting or previewing.
To print all streams:
Customize the Workbook to
contain all the stream info
you want.
Print the Workbook
Datasheet.
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Printing an Individual Stream DatasheetTo print the datasheet for an individual Stream, Object Inspect the
stream property view title bar and follow the same procedure as with
the Workbook.
Save your case!
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Exercise 1
A. Use the Workbook to find the following values:
1. The dew point temperature of stream Eth Rich at 101 kPa(14.7 psia). __________
2. The bubble point pressure of stream Tol rich at 15C (60 F).__________
3. The dew point pressure of stream Strip Air at 25C (77 F).__________
4. The bubble point temperature of stream Strip Air at 101 kPa(14.7 psia). __________
B. Perform the following flash calculations:
1. The vapour fraction of stream Eth rich at 15C (60 F) and 101 kPa(14.7 psia). __________
2. The temperature of stream Tol rich at 101 kPa (14.7 psia) and 0.5vapour fraction. __________
3. What is the molar fraction of toluene in vapour phase for streamTol rich under the same condition? __________
4. The mass density of stream Strip Air at 25 C (77 F) and 101 kPa(14.7 psia). __________
5. The mass fraction of toluene in the aqueous phase of the stream"Tol rich" at 15 C (60 F) and 101.3 kPa (14.7 psia). __________
Exercise 2
The stream Eth Rich is stored in a 200 m3 (7000 ft3) vessel. Assuming the
storage vessel has a 45 minute hold-up and the vessel is at atmospheric
conditions (1 atm, 25C, 77 F):
What is the composition of the vapor space? _________
How full is the storage vessel? __________
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