Difference between revisions of "DWSIM/C2/Binary-Phase-Envelope/English-timed"

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(Created page with "{|border=1 ||'''Time''' ||'''Narration''' |- ||00:01 || Welcome to this spoken tutorial on '''Binary Phase Envelope '''in '''DWSIM'''. |- ||00:07 || In this tutorial, we...")
 
 
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|-  
 
|-  
 
||00:01
 
||00:01
|| Welcome to this spoken tutorial on '''Binary Phase Envelope '''in '''DWSIM'''.  
+
|| Welcome to this '''spoken tutorial''' on '''Binary Phase Envelope '''in '''DWSIM'''.  
  
 
|-  
 
|-  
 
||00:07
 
||00:07
|| In this tutorial, we will learn to generate:  '''Txy''' plot at given '''pressure'''  
+
|| In this tutorial, we will learn to generate:  '''Txy''' plot at given '''pressure''',
  
 
|-  
 
|-  
 
|| 00:14
 
|| 00:14
||  '''xy''' plot for the obtained '''Txy''' data  
+
||  '''xy''' plot for the obtained '''Txy''' data,
  
 
|-  
 
|-  
 
|| 00:18
 
|| 00:18
||  '''Pxy''' plot at given '''temperature'''  
+
||  '''Pxy''' plot at given '''temperature'''.
  
 
|-  
 
|-  
 
|| 00:22
 
|| 00:22
|| To record this tutorial, I am using  '''DWSIM 5.2 (Classic UI)''' and  '''Windows 10'''  
+
|| To record this tutorial, I am using  '''DWSIM 5.2 (Classic UI)''' and  '''Windows 10'''.
  
 
|-  
 
|-  
 
|| 00:32
 
|| 00:32
|| The process demonstrated in this tutorial is identical in other OS also, such as-  
+
|| The process demonstrated in this tutorial is identical in other '''OS''' also, such as-  
  
 
'''Linux''',  
 
'''Linux''',  
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|-  
 
|-  
 
||00:44
 
||00:44
|| To practice this tutorial, you should know to : add components to a '''flowsheet'''  
+
|| To practice this tutorial, you should know to : add components to a '''flowsheet''',
  
 
|-  
 
|-  
 
|| 00:51
 
|| 00:51
||  Select '''thermodynamic '''packages
+
||  Select '''thermodynamic '''packages,
  
 
|-  
 
|-  
 
|| 00:54
 
|| 00:54
||  Add '''material '''streams and specify their properties.  
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||  add '''material '''streams and specify their properties.  
 
   
 
   
 
|-  
 
|-  
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|-  
 
|-  
 
||01:10
 
||01:10
|| In this tutorial, using '''DWSIM''', we will generate:  '''Txy''' plot at a constant pressure of '''1.013 bar'''  
+
|| In this tutorial, using '''DWSIM''', we will generate:  '''Txy''' plot at a constant pressure of '''1.013 bar''',
  
 
|-  
 
|-  
 
|| 01:21
 
|| 01:21
|| '''xy''' plot for the obtained '''Txy''' data  
+
|| '''xy''' plot for the obtained '''Txy''' data,
  
 
|-  
 
|-  
 
|| 01:25
 
|| 01:25
||  '''Pxy''' plot at a constant temperature of '''75 degree centrigade'''  
+
||  '''Pxy''' plot at a constant temperature of '''75 degree centigrade'''.
  
 
|-  
 
|-  
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|-  
 
|-  
 
||02:35
 
||02:35
|| From '''Default Flash Algorithm '''select '''Nested Loops(VLE)'''  
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|| From '''Default Flash Algorithm '''select '''Nested Loops(VLE)'''.
  
 
|-  
 
|-  
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|-  
 
|-  
 
||02:54
 
||02:54
|| At the bottom, click on '''Finish '''button.  
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|| At the bottom, click on the '''Finish '''button.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
||04:01
 
||04:01
|| Change '''Temperature '''to '''30 degree Centrigade '''and press '''Enter.'''  
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|| Change '''Temperature '''to '''30 degree Centigrade '''and press '''Enter.'''  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 04:20
 
|| 04:20
|| Now let us specify the '''feed stream compositions'''.  
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|| Now, let us specify the '''feed stream compositions'''.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
||04:59
 
||04:59
|| Now we will see how '''property package''' calculates '''phase equilibrium''' data of compounds.  
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|| Now ,we will see how '''property package''' calculates '''phase equilibrium''' data of compounds.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 05:13
 
|| 05:13
|| In the '''Add Utility '''window under '''Object Type''', select '''Material Streams.'''  
+
|| In the '''Add Utility '''window, under '''Object Type''', select '''Material Streams.'''  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 06:56
 
|| 06:56
|| So lets not worry about the '''pressure''' value.  
+
|| So, let's not worry about the '''pressure''' value.  
  
 
|-  
 
|-  
 
|| 07:00
 
|| 07:00
|| Make sure that the '''property package''' is selected as '''Soave-Redlich-Kwong '''  
+
|| Make sure that the '''property package''' is selected as '''Soave-Redlich-Kwong.'''  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 07:34
 
|| 07:34
|| Hover the mouse to the lower line at '''Ethanol mole fraction'''  of '''0.5.'''  
+
|| Hover the '''mouse''' to the lower line at '''Ethanol mole fraction'''  of '''0.5.'''  
  
 
|-  
 
|-  
 
|| 07:40
 
|| 07:40
|| We can see the '''bubble point temperature '''to be '''86.2853 deg C.'''  
+
|| We can see the '''bubble point temperature '''to be '''86.2853 degree  Centigrade.'''  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 08:03
 
|| 08:03
|| We can see the '''dew point temperature '''to be '''89.5881 degree Centrigade'''  
+
|| We can see the '''dew point temperature '''to be '''89.5881 degree Centigrade'''  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 08:16
 
|| 08:16
|| The area enclosed between these two lines is the '''VLE region.'''  
+
|| The area enclosed between these two lines is the '''VLE''' region.
  
 
|-  
 
|-  
 
|| 08:21
 
|| 08:21
|| Here both vapor and liquid phases exist in '''equilibrium'''.  
+
|| Here, both vapor and liquid phases exist in equilibrium.  
  
 
|-  
 
|-  
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|| 08:49
 
|| 08:49
|| Close this window.  
+
|| Close this '''window'''.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
||11:44
 
||11:44
|| Enter '''Temperature''' as '''75 degree Centrigade.'''  
+
|| Enter '''Temperature''' as '''75 degree Centigrade.'''  
  
 
|-  
 
|-  
 
|| 11:49
 
|| 11:49
|| Here we are going to plot a '''Pxy '''diagram.  
+
|| Here, we are going to plot a '''Pxy '''diagram.  
  
 
|-  
 
|-  
 
|| 11:53
 
|| 11:53
|| So let us not worry about the '''temperature''' value.  
+
|| So, let us not worry about the '''temperature''' value.  
  
 
|-  
 
|-  
 
|| 11:57
 
|| 11:57
|| Make sure that the property package is selected as '''Soave-Redlich-Kwong '''  
+
|| Make sure that the property package is selected as '''Soave-Redlich-Kwong. '''  
  
 
|-  
 
|-  
 
|| 12:03
 
|| 12:03
|| Now click on '''Calculate '''button at the bottom.  
+
|| Now, click on '''Calculate '''button at the bottom.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 12:17
 
|| 12:17
|| '''Y -axis''' indicates the Pressure range for which the '''VLE''' is generated.  
+
|| '''Y -axis''' indicates the pressure range for which the '''VLE''' is generated.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 13:06
 
|| 13:06
|| The area enclosed between these two lines is the '''VLE region'''.  
+
|| The area enclosed between these two lines is the '''VLE''' region.  
  
 
|-  
 
|-  
 
|| 13:11
 
|| 13:11
|| Here both vapor and liquid phases exist in '''equilibrium'''.  
+
|| Here, both vapor and liquid phases exist in equilibrium.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
||13:29
 
||13:29
|| In this tutorial, we have learnt to generate:  '''Txy''' plot at given '''pressure'''  
+
|| In this tutorial, we have learnt to generate:  '''Txy''' plot at given '''pressure''',
  
 
|-  
 
|-  
 
|| 13:34
 
|| 13:34
||  '''xy''' plot for the obtained '''Txy''' data  
+
||  '''xy''' plot for the obtained '''Txy''' data,
  
 
|-  
 
|-  
 
|| 13:38
 
|| 13:38
||  '''Pxy''' plot at given '''temperature'''  
+
||  '''Pxy''' plot at given '''temperature'''.
  
 
|-  
 
|-  
 
|| 13:41
 
|| 13:41
|| As an assignment, Generate '''P(xy)''' plot for the '''Pxy''' data obtained.  
+
|| As an assignment, generate '''P(xy)''' plot for the '''Pxy''' data obtained.  
  
 
|-  
 
|-  
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|-  
 
|-  
 
|| 13:56
 
|| 13:56
|| It summarizes the Spoken Tutorial project.  
+
|| It summarizes the '''Spoken Tutorial''' project.  
  
 
|-  
 
|-  
 
||14:00
 
||14:00
|| The Spoken Tutorial Project Team, Conducts workshops and gives certificates  
+
|| The Spoken Tutorial Project Team  conducts workshops and gives certificates.
  
 
For more details, please write to us.
 
For more details, please write to us.
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|-  
 
|-  
 
|| 14:13
 
|| 14:13
|| The '''FOSSEE '''team coordinates conversion of existing flow sheets into '''DWSIM'''.  
+
|| The '''FOSSEE '''team coordinates conversion of existing '''flow sheets''' into '''DWSIM'''.  
  
 
We give honorarium and certificates.  
 
We give honorarium and certificates.  
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|-  
 
|-  
 
|| 14:43
 
|| 14:43
|| We give honorarium and certificates. For more details, please visit this site  
+
|| We give honorarium and certificates. For more details, please visit this site.
  
 
|-  
 
|-  

Latest revision as of 18:25, 25 September 2018

Time Narration
00:01 Welcome to this spoken tutorial on Binary Phase Envelope in DWSIM.
00:07 In this tutorial, we will learn to generate: Txy plot at given pressure,
00:14 xy plot for the obtained Txy data,
00:18 Pxy plot at given temperature.
00:22 To record this tutorial, I am using DWSIM 5.2 (Classic UI) and Windows 10.
00:32 The process demonstrated in this tutorial is identical in other OS also, such as-

Linux,

Mac OS X or

FOSSEE OS on ARM.

00:44 To practice this tutorial, you should know to : add components to a flowsheet,
00:51 Select thermodynamic packages,
00:54 add material streams and specify their properties.
00:59 The pre-requisite tutorials are mentioned on our website.
01:04 You can access these tutorials and all the associated files from this site.
01:10 In this tutorial, using DWSIM, we will generate: Txy plot at a constant pressure of 1.013 bar,
01:21 xy plot for the obtained Txy data,
01:25 Pxy plot at a constant temperature of 75 degree centigrade.
01:31 Here we give compounds, inlet stream conditions and property package.
01:38 I have already opened DWSIM on my machine.
01:43 Go to File menu and select New Steady-state Simulation.
01:50 Simulation Configuration Wizard window appears.
01:54 At the bottom, click on the Next button.
01:58 Now, in the Compounds Search tab, type Ethanol.
02:04 Select Ethanol from ChemSep database.
02:08 Similarly, add 1-propanol.
02:12 At the bottom, click on the Next button.
02:16 The Property Packages opens.
02:19 From Available Property Packages list, double-click on Soave-Redlich-Kwong (SRK).
02:26 Then click on the Next button.
02:30 We are moved to a new window named Flash Algorithm.
02:35 From Default Flash Algorithm select Nested Loops(VLE).
02:41 At the bottom, click on the Next button.
02:45 Next option is System of Units.
02:49 Under System of Units, select C5.
02:54 At the bottom, click on the Finish button.
02:58 Let us maximize the simulation window for better visibility.
03:03 Let’s insert a material stream for which we have to generate the Txy, xy and Pxy plots.
03:12 On the right hand side of the main simulation window, go to Flowsheet Objects.
03:19 In the Filter List tab, type Material Stream.
03:24 From the displayed list, drag and drop a Material Stream to the Flowsheet.
03:30 Click on the Material Stream “MSTR-000” to view its properties.
03:37 Let’s change the name of this stream to Feed.
03:41 Now we will specify the Feed stream properties.
03:46 Go to Input Data.
03:48 Select Flash Spec as Temperature and Pressure (TP), if not already selected.
03:55 By default, Temperature and Pressure are already selected as Flash Spec.
04:01 Change Temperature to 30 degree Centigrade and press Enter.
04:07 Change Pressure to 3.5 bar and press Enter.
04:13 Change Molar Flow to 120 kmol/h and press Enter.
04:20 Now, let us specify the feed stream compositions.
04:25 Under Composition, choose the Basis as Mole Fractions, if not already selected.
04:33 By default, Mole Fractions will be selected as Basis.
04:38 For Ethanol, enter the Amount as 0.5 and press Enter.
04:46 Similarly, for 1-propanol, enter it as 0.5 and press Enter.
04:54 On the right side, click on this green tick to Accept Changes.
04:59 Now ,we will see how property package calculates phase equilibrium data of compounds.
05:06 To do this, go to Utilities.
05:10 Click on Add Utility.
05:13 In the Add Utility window, under Object Type, select Material Streams.
05:20 Under Utility Type, select Binary Phase Envelope.
05:25 Under Flowsheet Object, select Feed.
05:29 At the bottom, click on the Add Utility button.
05:34 Binary Phase Envelope window opens.
05:37 Let us adjust the phase envelope window for better visibility.
05:43 Enter Name as Txy-plot.
05:49 Go to Diagram Settings.
05:52 Select Ethanol as Compound 1, if not already selected.
05:57 By default, Ethanol is selected as Compound 1.
06:02 Make sure that the other compound is selected as Compound 2.
06:07 In this case, it is 1-propanol which is Compound 2.
06:12 Select Envelope type as Txy, if not already selected.
06:19 By default, Txy is selected as Envelope type.
06:24 Select Txy Diagram Options as VLE, if not already selected.
06:31 By default, VLE is selected as Txy Diagram Options.
06:36 Select X-Axis Basis as Mole Fraction, if not already selected.
06:43 By default, Mole Fraction is selected as X-Axis Basis
06:48 Enter Pressure as 1.013 bar.
06:53 Here we are going to plot a Txy diagram.
06:56 So, let's not worry about the pressure value.
07:00 Make sure that the property package is selected as Soave-Redlich-Kwong.
07:07 Now click on Calculate button at the bottom.
07:12 The diagram generated is a Txy diagram or Constant Pressure Phase Diagram.
07:19 X-axis indicates the mole fraction of Ethanol.
07:23 Y -axis indicates the temperature range for which the VLE is generated.
07:29 The lower line of the envelope represents Bubble Point Curve.
07:34 Hover the mouse to the lower line at Ethanol mole fraction of 0.5.
07:40 We can see the bubble point temperature to be 86.2853 degree Centigrade.
07:47 For any mixture composition below this line, is subcooled liquid.
07:52 The upper line of the envelope represents Dew Point Curve.
07:57 Hover the mouse to the upper line at Ethanol mole fraction of 0.5.
08:03 We can see the dew point temperature to be 89.5881 degree Centigrade
08:10 For any mixture composition above this line, the mixture is superheated vapour.
08:16 The area enclosed between these two lines is the VLE region.
08:21 Here, both vapor and liquid phases exist in equilibrium.
08:26 We can see the bubble points and dew points at every composition.
08:32 For this, go to Results section and click on Table.
08:37 Here we can see the corresponding mole fractions and temperatures values.
08:43 Let us now generate the xy plot for data obtained in the above Txy diagram.
08:49 Close this window.
08:53 Go to Utilities and click on Add Utility.
08:58 In the Add Utility window, under Object Type, select Material Streams.
09:06 Under Utility Type, select Binary Phase Envelope.
09:11 Under Flowsheet Object, select Feed.
09:15 At the bottom, click on the Add Utility button.
09:19 Once again, Binary Phase Envelope window opens.
09:23 Let us adjust the window for better visibility.
09:27 Enter Name as xy-plot.
09:32 Go to Diagram Settings.
09:35 Let the Compound settings be the default settings.
09:39 Select Envelope type as (T)xy.
09:44 Select X-Axis Basis as Mole Fraction, if not already selected.
09:51 By default, Mole Fraction is selected as X-Axis Basis.
09:56 Enter Pressure as 1.013 bar.
10:01 Now click on the Calculate button at the bottom.
10:05 The diagram is generated is called xy diagram.
10:09 X-axis indicates the mole fraction of Ethanol in liquid phase.
10:15 Y -axis indicates the mole fraction of Ethanol in vapour phase.
10:20 The upper curve is called Equilibrium Curve.
10:24 Hover the mouse to the upper line at Ethanol mole fraction of 0.6.
10:30 We can see the vapour phase mole fraction of Ethanol to be 0.7539.
10:37 Let us generate the Pxy plot now.
10:41 Close this window.
10:45 Go to Utilities and click on Add Utility.
10:50 In the Add Utility window, under Object Type, select Material Streams.
10:57 Under Utility Type, select Binary Phase Envelope.
11:02 Under Flowsheet Object, select Feed.
11:06 At the bottom, click on the Add Utility button.
11:10 Once again, Binary Phase Envelope window opens.
11:14 Let us adjust the window for better visibility.
11:18 Enter Name as Pxy-plot.
11:23 Go to Diagram Settings.
11:25 Let the Compound settings be the default settings.
11:29 Select Envelope type as Pxy.
11:33 Select X-Axis Basis as Mole Fraction, if not already selected.
11:39 By default, Mole Fraction is selected as X-Axis Basis.
11:44 Enter Temperature as 75 degree Centigrade.
11:49 Here, we are going to plot a Pxy diagram.
11:53 So, let us not worry about the temperature value.
11:57 Make sure that the property package is selected as Soave-Redlich-Kwong.
12:03 Now, click on Calculate button at the bottom.
12:07 The diagram generated is a Pxy diagram or Constant Temperature Phase Diagram.
12:13 X-axis indicates the mole fraction of Ethanol.
12:17 Y -axis indicates the pressure range for which the VLE is generated.
12:23 The lower line of the envelope represents Dew Points.
12:28 Hover the mouse to the lower line at Ethanol mole fraction of 0.4.
12:34 We can see the dew point pressure to be 0.523 bar.
12:39 For any mixture composition below this line, is completely vapour.
12:45 The upper line of the envelope represents Bubble Points.
12:49 Hover the mouse to the upper line at Ethanol mole fraction of 0.8.
12:55 We can see the bubble point pressure to be 0.782 bar.
13:01 For any mixture composition above this line, is completely liquid.
13:06 The area enclosed between these two lines is the VLE region.
13:11 Here, both vapor and liquid phases exist in equilibrium.
13:16 Now, go to Results section. Click on Table.
13:21 Here we can see the corresponding mole fractions and pressure values.
13:27 Let's summarize.
13:29 In this tutorial, we have learnt to generate: Txy plot at given pressure,
13:34 xy plot for the obtained Txy data,
13:38 Pxy plot at given temperature.
13:41 As an assignment, generate P(xy) plot for the Pxy data obtained.
13:47 Generate P(xy) plot using NRTL model.
13:51 Compare the results.
13:53 Watch the video available at following link.
13:56 It summarizes the Spoken Tutorial project.
14:00 The Spoken Tutorial Project Team conducts workshops and gives certificates.

For more details, please write to us.

14:09 Please post your times queries in this forum.
14:13 The FOSSEE team coordinates conversion of existing flow sheets into DWSIM.

We give honorarium and certificates.

14:22 For more details, please visit this site.
14:26 The FOSSEE team coordinates coding of solved examples of popular books.
14:31 We give honorarium and certificates. For more details, please visit this site.
14:37 The FOSSEE team helps migrate commercial simulator labs to DWSIM.
14:43 We give honorarium and certificates. For more details, please visit this site.
14:49 Spoken Tutorial and FOSSEE projects are funded by NMEICT, MHRD, Government of India.
14:57 This tutorial is contributed by Kaushik Datta and Priyam Nayak.

Thanks for joining.

Contributors and Content Editors

PoojaMoolya, Sandhya.np14