Difference between revisions of "DWSIM/C2/Shell-and-Tube-Heat-Exchanger/English-timed"
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|| 00:01 | || 00:01 | ||
| − | || Welcome to this tutorial on | + | || Welcome to this tutorial on simulating a '''Shell & Tube Heat Exchanger '''in '''DWSIM.''' |
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| Line 14: | Line 14: | ||
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|| 00:11 | || 00:11 | ||
| − | || | + | || simulate a '''Shell & Tube Heat Exchanger''', |
|- | |- | ||
|| 00:14 | || 00:14 | ||
| − | || | + | || calculate the '''Outlet stream temperature'''s, |
|- | |- | ||
|| 00:17 | || 00:17 | ||
| − | || | + | || calculate '''Overall Heat Transfer Coefficient''', |
|- | |- | ||
|| 00:20 | || 00:20 | ||
| − | || | + | || calculate '''Heat Exchange Area''', |
|- | |- | ||
|| 00:23 | || 00:23 | ||
| − | || | + | || calculate '''Thermal Efficiency '''and''' LMTD'''. |
|- | |- | ||
|| 00:27 | || 00:27 | ||
| − | || To record this tutorial, I am using '''DWSIM 4.3 '''and '''Windows 7''' | + | || To record this tutorial, I am using '''DWSIM 4.3 '''and '''Windows 7'''. |
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|| 00:48 | || 00:48 | ||
| − | || To practice this tutorial, you should know how to add | + | || To practice this tutorial, you should know how to add '''component'''s to a '''flowsheet''', |
|- | |- | ||
|| 00:55 | || 00:55 | ||
| − | || | + | || select '''thermodynamic package'''s and add '''material stream''' and specify their properties. |
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| Line 56: | Line 56: | ||
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|| 01:08 | || 01:08 | ||
| − | ||You can access these tutorials and all the associated files from this site. | + | ||You can access these tutorials and all the associated files from this '''site'''. |
|- | |- | ||
|| 01:14 | || 01:14 | ||
| − | || Here, we will develop a '''flowsheet '''to determine: '''Outlet stream temperatures''' | + | || Here, we will develop a '''flowsheet '''to determine: '''Outlet stream temperatures''', |
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|| 01:24 | || 01:24 | ||
| − | ||Here we give '''Compounds '''and''' Inlet stream conditions.''' | + | ||Here, we give '''Compounds '''and''' Inlet stream conditions.''' |
|- | |- | ||
|| 01:29 | || 01:29 | ||
| − | || Here we give '''Heat Exchanger''' properties and '''Property package'''. | + | || Here, we give '''Heat Exchanger''' properties and '''Property package'''. |
|- | |- | ||
|| 01:34 | || 01:34 | ||
| − | || Here we give '''Shell & Tube Heat Exchanger''' | + | || Here, we give '''Shell & Tube Heat Exchanger''' properties. |
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| Line 108: | Line 108: | ||
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|| 02:11 | || 02:11 | ||
| − | || At the bottom, click on '''Next''' | + | || At the bottom, click on '''Next'''. |
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| Line 128: | Line 128: | ||
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|| 02:33 | || 02:33 | ||
| − | || From '''Default Flash Algorithm '''select '''Nested Loops(VLE)''' | + | || From '''Default Flash Algorithm, '''select '''Nested Loops(VLE)'''. |
|- | |- | ||
|| 02:39 | || 02:39 | ||
| − | || Click on '''Next '''button | + | || Click on '''Next '''button. |
|- | |- | ||
| Line 148: | Line 148: | ||
|- | |- | ||
|| 02:55 | || 02:55 | ||
| − | || Let us maximize the simulation window for better visibility. | + | || Let us maximize the '''simulation window''' for better visibility. |
|- | |- | ||
|| 03:00 | || 03:00 | ||
| − | || Now let’s insert two material | + | || Now, let’s insert two '''material stream'''s that enter the '''Heat Exchanger'''. |
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| Line 180: | Line 180: | ||
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|| 03:40 | || 03:40 | ||
| − | || Go to '''Input Data. | + | || Go to '''Input Data'''. |
|- | |- | ||
|| 03:43 | || 03:43 | ||
| − | || | + | || Select '''Flash Spec '''as '''Temperature and Pressure (TP), '''if not already selected. |
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| Line 232: | Line 232: | ||
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|| 05:01 | || 05:01 | ||
| − | || Click on '''Material Stream '''“'''MSTR-001” '''to view its properties. | + | || Click on '''Material Stream''' “'''MSTR-001” '''to view its properties. |
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| Line 264: | Line 264: | ||
|- | |- | ||
|| 05:55 | || 05:55 | ||
| − | || Now let us specify the '''Methanol In stream compositions'''. | + | || Now, let us specify the '''Methanol In stream compositions'''. |
|- | |- | ||
|| 06:01 | || 06:01 | ||
| − | || Under '''Composition''', choose the '''Basis '''as '''Mole Fractions, '''if not already selected | + | || Under '''Composition''', choose the '''Basis '''as '''Mole Fractions, '''if not already selected. |
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| Line 276: | Line 276: | ||
|- | |- | ||
|| 06:14 | || 06:14 | ||
| − | || Now for '''Methanol''', enter the '''Amount '''as '''1 '''and press '''Enter.''' | + | || Now, for '''Methanol''', enter the '''Amount '''as '''1 '''and press '''Enter.''' |
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|| 06:35 | || 06:35 | ||
| − | || Now let’s insert two more material | + | || Now, let’s insert two more '''material stream'''s that exit the '''Heat Exchanger'''. |
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|| 07:11 | || 07:11 | ||
| − | || Now let us insert a '''Heat Exchanger '''into the '''flowsheet'''. | + | || Now, let us insert a '''Heat Exchanger '''into the '''flowsheet'''. |
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|| 07:44 | || 07:44 | ||
| − | || Under '''Connections, '''click on the drop-down against '''Inlet Stream 1 | + | || Under '''Connections, '''click on the drop-down against '''Inlet Stream 1''' and select '''Methanol In.''' |
|- | |- | ||
|| 07:54 | || 07:54 | ||
| − | || Next, click on the drop-down against '''Outlet Stream 1 | + | || Next, click on the drop-down against '''Outlet Stream 1''' and select '''Methanol Out.''' |
|- | |- | ||
|| 08:03 | || 08:03 | ||
| − | || Then click on the drop-down against '''Inlet Stream 2 | + | || Then click on the drop-down against '''Inlet Stream 2 ''' and select '''Water In.''' |
|- | |- | ||
|| 08:11 | || 08:11 | ||
| − | || Then click on the drop-down against '''Outlet Stream 2 | + | || Then click on the drop-down against '''Outlet Stream 2 '''and select '''Water Out.''' |
| − | + | ||
| − | + | ||
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|| 08:40 | || 08:40 | ||
| − | || Next, click on the drop-down against '''Flow Direction''' | + | || Next, click on the drop-down against '''Flow Direction'''. |
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|| 08:48 | || 08:48 | ||
| − | || Then click on the field against '''Cold Fluid Pressure Drop '''and enter '''0.002 bar.''' | + | || Then click on the '''field''' against '''Cold Fluid Pressure Drop '''and enter '''0.002 bar.''' |
| − | + | ||
Then press '''Enter.''' | Then press '''Enter.''' | ||
| Line 420: | Line 417: | ||
|- | |- | ||
|| 09:28 | || 09:28 | ||
| − | || Here, we can see the | + | || Here, we can see the default values for '''Shell and Tube side configurations'''. |
|- | |- | ||
|| 09:34 | || 09:34 | ||
| − | || First we will edit the '''Shell Side Configuration.''' | + | || First we will '''edit''' the '''Shell Side Configuration.''' |
|- | |- | ||
||09:39 | ||09:39 | ||
| − | || Click on the field against '''Shell in Series''' and enter it as '''1''' | + | || Click on the field against '''Shell in Series''' and enter it as '''1'''. |
|- | |- | ||
|| 09:46 | || 09:46 | ||
| − | || Click on the field against '''Shell Passes''' and enter it as '''2''' | + | || Click on the field against '''Shell Passes''' and enter it as '''2'''. |
|- | |- | ||
|| 09:53 | || 09:53 | ||
| − | || Click on the field against '''Internal Diameter''' and enter it as '''1000''' | + | || Click on the field against '''Internal Diameter''' and enter it as '''1000'''. |
|- | |- | ||
|| 10:00 | || 10:00 | ||
| − | || Click on the field against '''Fouling Factor''' and enter it as '''0.00035''' | + | || Click on the field against '''Fouling Factor''' and enter it as '''0.00035'''. |
|- | |- | ||
|| 10:10 | || 10:10 | ||
| − | || Click on the field against '''Baffle Spacing''' and enter it as '''250''' | + | || Click on the field against '''Baffle Spacing''' and enter it as '''250'''. |
|- | |- | ||
|| 10:17 | || 10:17 | ||
| − | || Click on the field against '''Baffle Cut(% diameter)''' and enter it as '''25''' | + | || Click on the field against '''Baffle Cut(% diameter)''' and enter it as '''25'''. |
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||10:33 | ||10:33 | ||
| − | || Click on the field against '''Internal Diameter''' and enter it as '''15''' | + | || Click on the field against '''Internal Diameter''' and enter it as '''15'''. |
|- | |- | ||
||10:40 | ||10:40 | ||
| − | || Click on the field against '''External Diameter''' and enter it as '''20''' | + | || Click on the field against '''External Diameter''' and enter it as '''20'''. |
|- | |- | ||
|| 10:47 | || 10:47 | ||
| − | || Click on the field against '''Length''' and enter it as '''5''' | + | || Click on the field against '''Length''' and enter it as '''5'''. |
|- | |- | ||
|| 10:54 | || 10:54 | ||
| − | || Click on the field against '''Fouling Factor''' and enter it as '''0.00035''' | + | || Click on the field against '''Fouling Factor''' and enter it as '''0.00035'''. |
|- | |- | ||
||11:03 | ||11:03 | ||
| − | || Click on the field against '''Roughness''' and enter it as '''0.05''' | + | || Click on the field against '''Roughness''' and enter it as '''0.05'''. |
|- | |- | ||
|| 11:11 | || 11:11 | ||
| − | || Click on the field against '''Thermal Conductivity''' and enter it as '''60''' | + | || Click on the field against '''Thermal Conductivity''' and enter it as '''60'''. |
|- | |- | ||
|| 11:18 | || 11:18 | ||
| − | || Click on the field against '''Passes per Shell''' and enter it as '''4''' | + | || Click on the field against '''Passes per Shell''' and enter it as '''4'''. |
|- | |- | ||
|| 11:25 | || 11:25 | ||
| − | || Click on the field against '''Tubes per Shell''' and enter it as '''1024''' | + | || Click on the field against '''Tubes per Shell''' and enter it as '''1024'''. |
|- | |- | ||
||11:33 | ||11:33 | ||
| − | || Click on the field against '''Tube Spacing''' and enter it as '''25''' | + | || Click on the field against '''Tube Spacing''' and enter it as '''25'''. |
|- | |- | ||
|| 11:40 | || 11:40 | ||
| − | || Click on the drop down against '''Tube Layout''' and select '''Square''' | + | || Click on the drop down against '''Tube Layout''' and select '''Square'''. |
|- | |- | ||
|| 11:47 | || 11:47 | ||
| − | || Select the option '''Cold''' against '''Fluid in Tubes''' | + | || Select the option '''Cold''' against '''Fluid in Tubes'''. |
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|| 12:06 | || 12:06 | ||
| − | || Now we will run the '''simulation.''' | + | || Now we will '''run''' the '''simulation.''' |
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|| 12:28 | || 12:28 | ||
| − | || Check '''Cold Fluid Outlet Temperature'''. It is '''66.15 degree Centigrade''' | + | || Check '''Cold Fluid Outlet Temperature'''. It is '''66.15 degree Centigrade'''. |
|- | |- | ||
|| 12:37 | || 12:37 | ||
| − | ||Check '''Hot Fluid Outlet Temperature'''. It is '''40.95 degree Centigrade''' | + | ||Check '''Hot Fluid Outlet Temperature'''. It is '''40.95 degree Centigrade'''. |
|- | |- | ||
|| 12:45 | || 12:45 | ||
| − | ||Check '''Overall Heat Transfer Coefficient'''. It is '''191.83 Watt per meter square kelvin''' | + | ||Check '''Overall Heat Transfer Coefficient'''. It is '''191.83 Watt per meter square kelvin'''. |
|- | |- | ||
|| 12:54 | || 12:54 | ||
| − | ||Check '''Heat Exchange Area'''. It is '''319.12 meter square''' | + | ||Check '''Heat Exchange Area'''. It is '''319.12 meter square'''. |
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|| 13:08 | || 13:08 | ||
| − | || Under '''Results''' section, check '''Thermal efficiency;''' it is '''79.05 %''' | + | || Under '''Results''' section, check '''Thermal efficiency;''' it is '''79.05 %'''. |
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|| 13:49 | || 13:49 | ||
| − | || Enter '''Name '''as '''Heat Exchanger – Stream Wise Results''' | + | || Enter '''Name '''as '''Heat Exchanger – Stream Wise Results'''. |
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| Line 584: | Line 581: | ||
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|| 14:03 | || 14:03 | ||
| − | || So we will not change it. | + | || So, we will not change it. |
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|- | |- | ||
|| 14:24 | || 14:24 | ||
| − | ||Now select the properties as: '''Temperature''' | + | ||Now select the properties as: '''Temperature''', |
|- | |- | ||
|| 14:29 | || 14:29 | ||
| − | ||'''Pressure''' | + | ||'''Pressure''', |
|- | |- | ||
|| 14:31 | || 14:31 | ||
| − | ||'''Mass Flow''', '''Molar Flow''' | + | ||'''Mass Flow''', '''Molar Flow''', |
|- | |- | ||
|| 14:36 | || 14:36 | ||
| − | ||'''Molar Fraction(Mixture) / Methanol''' | + | ||'''Molar Fraction(Mixture) / Methanol''', |
|- | |- | ||
|| 14:41 | || 14:41 | ||
| − | ||'''Molar Fraction(Mixture) / Water''' | + | ||'''Molar Fraction(Mixture) / Water'''. |
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|| 14:54 | || 14:54 | ||
| − | ||Here we can see the corresponding results for '''Inlet '''and '''Outlet streams.''' | + | ||Here, we can see the corresponding results for '''Inlet '''and '''Outlet streams.''' |
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|| 15:31 | || 15:31 | ||
| − | || Under '''Properties to display''', select '''Object '''as '''HE-004''' | + | || Under '''Properties to display''', select '''Object '''as '''HE-004'''. |
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|| 15:45 | || 15:45 | ||
| − | ||Now select the properties as: '''Global Heat Transfer Coefficient (U)''' | + | ||Now, select the properties as: '''Global Heat Transfer Coefficient (U)''', |
|- | |- | ||
|| 15:52 | || 15:52 | ||
| − | ||'''Heat Exchange Area (A)''' | + | ||'''Heat Exchange Area (A)''', |
| − | '''Heat Load''' | + | '''Heat Load''', |
|- | |- | ||
|| 15:57 | || 15:57 | ||
| − | ||'''Cold fluid outlet temperature''' | + | ||'''Cold fluid outlet temperature''', |
|- | |- | ||
|| 15:59 | || 15:59 | ||
| − | ||'''Hot fluid outlet temperature''' | + | ||'''Hot fluid outlet temperature''', |
|- | |- | ||
|| 16:04 | || 16:04 | ||
| − | ||'''Logarithmic mean temperature difference LMTD''' and '''Thermal Efficiency''' | + | ||'''Logarithmic mean temperature difference LMTD''' and '''Thermal Efficiency'''. |
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||16:29 | ||16:29 | ||
| − | || In this tutorial, we have learnt to | + | || In this tutorial, we have learnt to: simulate a''' Shell & Tube Heat Exchanger''', |
|- | |- | ||
|| 16:35 | || 16:35 | ||
| − | || | + | ||calculate the''' Outlet stream temperatures''', |
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|| 16:38 | || 16:38 | ||
| − | || | + | || calculate '''Overall Heat Transfer Coefficient''', |
|- | |- | ||
|| 16:41 | || 16:41 | ||
| − | || | + | || calculate '''Heat Exchange Area''', |
|- | |- | ||
|| 16:44 | || 16:44 | ||
| − | || Calculate''' Thermal Efficiency '''and''' LMTD''' | + | || Calculate''' Thermal Efficiency '''and''' LMTD'''. |
|- | |- | ||
|| 16:48 | || 16:48 | ||
| − | || As an assignment, | + | || As an assignment, repeat this simulation with different '''Compounds, feed conditions '''and '''Thermodynamics'''. |
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|| 17:01 | || 17:01 | ||
| − | ||It summarizes the Spoken Tutorial project. | + | ||It summarizes the '''Spoken Tutorial''' project. |
|- | |- | ||
|| 17:05 | || 17:05 | ||
| − | || The Spoken Tutorial Project Team | + | || The Spoken Tutorial Project Team conducts workshops and gives certificates. For more details, please write to us. |
| − | + | ||
| − | + | ||
|- | |- | ||
Latest revision as of 12:30, 21 June 2018
| Time | Narration |
| 00:01 | Welcome to this tutorial on simulating a Shell & Tube Heat Exchanger in DWSIM. |
| 00:07 | In this tutorial, we will learn to: |
| 00:11 | simulate a Shell & Tube Heat Exchanger, |
| 00:14 | calculate the Outlet stream temperatures, |
| 00:17 | calculate Overall Heat Transfer Coefficient, |
| 00:20 | calculate Heat Exchange Area, |
| 00:23 | calculate Thermal Efficiency and LMTD. |
| 00:27 | To record this tutorial, I am using DWSIM 4.3 and Windows 7. |
| 00:36 | The process demonstrated in this tutorial is identical in other OS also, such as-
Linux, Mac OS X or FOSSEE OS on ARM. |
| 00:48 | To practice this tutorial, you should know how to add components to a flowsheet, |
| 00:55 | select thermodynamic packages and add material stream and specify their properties. |
| 01:03 | The prerequisite tutorials are mentioned on our website. |
| 01:08 | You can access these tutorials and all the associated files from this site. |
| 01:14 | Here, we will develop a flowsheet to determine: Outlet stream temperatures, |
| 01:19 | Overall Heat Transfer coefficient and Heat Exchange area. |
| 01:24 | Here, we give Compounds and Inlet stream conditions. |
| 01:29 | Here, we give Heat Exchanger properties and Property package. |
| 01:34 | Here, we give Shell & Tube Heat Exchanger properties. |
| 01:39 | I have already opened DWSIM on my machine. |
| 01:44 | Go to File menu and select New Steady-state Simulation. |
| 01:50 | Simulation Configuration Wizard window appears. |
| 01:54 | At the bottom, click on Next. |
| 01:57 | Now, in the Compounds Search tab, type Methanol. |
| 02:03 | Select Methanol from ChemSep database. |
| 02:07 | Similarly, add Water. |
| 02:11 | At the bottom, click on Next. |
| 02:14 | Now comes Property Packages. |
| 02:18 | From the Available Property Packages, double-click on Raoult’s Law. |
| 02:24 | Then click on Next button. |
| 02:28 | We are moved to a new window named Flash Algorithm. |
| 02:33 | From Default Flash Algorithm, select Nested Loops(VLE). |
| 02:39 | Click on Next button. |
| 02:42 | Next option is System of Units. |
| 02:46 | Under System of Units, select C5. |
| 02:51 | At the bottom, click on Finish button. |
| 02:55 | Let us maximize the simulation window for better visibility. |
| 03:00 | Now, let’s insert two material streams that enter the Heat Exchanger. |
| 03:06 | On the right hand side of the main simulation window, go to Flowsheet Objects. |
| 03:12 | In the Filter List tab, type Material Stream. |
| 03:17 | From the displayed list, drag and drop a Material Stream to the Flowsheet. |
| 03:23 | Click on MSTR-000 to view its properties. |
| 03:29 | Let’s change the name of this stream to Water In. |
| 03:34 | Now we will specify the Water In stream properties. |
| 03:40 | Go to Input Data. |
| 03:43 | Select Flash Spec as Temperature and Pressure (TP), if not already selected. |
| 03:50 | By default, Temperature and Pressure are already selected as Flash Spec. |
| 03:56 | Change Temperature to 10 degree Centigrade and press Enter. |
| 04:02 | Change Pressure to 1 bar and press Enter. |
| 04:08 | Change Mass Flow to 15000 kg/h and press Enter. |
| 04:16 | Now let us specify the feed stream compositions. |
| 04:21 | Under Composition, choose the Basis as Mole Fractions, if not already selected. |
| 04:29 | By default, Mole Fractions is selected as Basis. |
| 04:34 | Now for Methanol, enter the Amount as 0 and press Enter. |
| 04:42 | Similarly, for Water, enter it as 1 and press Enter. |
| 04:50 | On the right, click on this green tick to Accept Changes. |
| 04:55 | Now drag and drop another Material Stream to the flowsheet. |
| 05:01 | Click on Material Stream “MSTR-001” to view its properties. |
| 05:08 | Let’s change the name of this stream to Methanol In. |
| 05:13 | Now we will specify the Methanol In stream properties. |
| 05:19 | Go to Input Data. Select Flash Spec as Temperature and Pressure (TP). |
| 05:26 | By default, Temperature and Pressure are again already selected as Flash Spec. |
| 05:33 | Change Temperature to 80 degC and press Enter. |
| 05:40 | Change Pressure to 5 bar and press Enter. |
| 05:46 | Change Mass Flow to 25000 kg/h and press Enter. |
| 05:55 | Now, let us specify the Methanol In stream compositions. |
| 06:01 | Under Composition, choose the Basis as Mole Fractions, if not already selected. |
| 06:09 | By default, Mole Fractions is selected as Basis. |
| 06:14 | Now, for Methanol, enter the Amount as 1 and press Enter. |
| 06:22 | Similarly, for Water, enter it as 0 and press Enter. |
| 06:30 | On the right, click on this green tick to Accept Changes. |
| 06:35 | Now, let’s insert two more material streams that exit the Heat Exchanger. |
| 06:41 | To do that, let us drag one Material Stream. |
| 06:45 | Let us now arrange it. |
| 06:48 | Leave that stream as unspecified. |
| 06:52 | We will change the name of this stream to Water Out. |
| 06:57 | Next, we will insert another Material Stream. |
| 07:01 | Let us once again arrange it. |
| 07:04 | Leave that stream as unspecified. And name this stream as Methanol Out. |
| 07:11 | Now, let us insert a Heat Exchanger into the flowsheet. |
| 07:17 | Go to Flowsheet Objects. |
| 07:20 | In the Filter list tab, type Heat Exchanger. |
| 07:25 | Click on the Heat Exchanger displayed. |
| 07:28 | Drag and drop it to the flowsheet. |
| 07:31 | Let us now arrange it as required for better visibility. |
| 07:36 | Let's click on it. |
| 07:38 | On the left, we can see a tab called Property Editor Window. |
| 07:44 | Under Connections, click on the drop-down against Inlet Stream 1 and select Methanol In. |
| 07:54 | Next, click on the drop-down against Outlet Stream 1 and select Methanol Out. |
| 08:03 | Then click on the drop-down against Inlet Stream 2 and select Water In. |
| 08:11 | Then click on the drop-down against Outlet Stream 2 and select Water Out. |
| 08:21 | Now go to the next section- Calculation Parameters. |
| 08:27 | Here, the first option is Calculation Type. |
| 08:32 | Click on the drop-down against Calculation Type. |
| 08:35 | Select Shell and Tubes Exchanger Ratings. |
| 08:40 | Next, click on the drop-down against Flow Direction. |
| 08:45 | Select Counter Current. |
| 08:48 | Then click on the field against Cold Fluid Pressure Drop and enter 0.002 bar.
Then press Enter. |
| 09:01 | Click on the field against Hot Fluid Pressure Drop and enter it as 0.025 bar. |
| 09:10 | Then press Enter. |
| 09:13 | Now we will enter the properties of Shell & Tube Exchanger. |
| 09:18 | Click on Edit Shell and Tube Heat Exchanger Properties. |
| 09:24 | Shell and Tube Exchanger Properties window opens. |
| 09:28 | Here, we can see the default values for Shell and Tube side configurations. |
| 09:34 | First we will edit the Shell Side Configuration. |
| 09:39 | Click on the field against Shell in Series and enter it as 1. |
| 09:46 | Click on the field against Shell Passes and enter it as 2. |
| 09:53 | Click on the field against Internal Diameter and enter it as 1000. |
| 10:00 | Click on the field against Fouling Factor and enter it as 0.00035. |
| 10:10 | Click on the field against Baffle Spacing and enter it as 250. |
| 10:17 | Click on the field against Baffle Cut(% diameter) and enter it as 25. |
| 10:24 | This completes the Shell Side Configuration. |
| 10:28 | Now we will edit the Tube Side Configuration. |
| 10:33 | Click on the field against Internal Diameter and enter it as 15. |
| 10:40 | Click on the field against External Diameter and enter it as 20. |
| 10:47 | Click on the field against Length and enter it as 5. |
| 10:54 | Click on the field against Fouling Factor and enter it as 0.00035. |
| 11:03 | Click on the field against Roughness and enter it as 0.05. |
| 11:11 | Click on the field against Thermal Conductivity and enter it as 60. |
| 11:18 | Click on the field against Passes per Shell and enter it as 4. |
| 11:25 | Click on the field against Tubes per Shell and enter it as 1024. |
| 11:33 | Click on the field against Tube Spacing and enter it as 25. |
| 11:40 | Click on the drop down against Tube Layout and select Square. |
| 11:47 | Select the option Cold against Fluid in Tubes. |
| 11:53 | Now all the Shell & Tube Exchanger Properties are specified. |
| 11:58 | Close the Shell and Tube Exchanger Properties window by clicking red cross mark on the top right of the window. |
| 12:06 | Now we will run the simulation. |
| 12:09 | So, from the toolbar, click on Solve Flowsheet button. |
| 12:15 | When the calculations are completed, click on Heat Exchanger in the Flowsheet. |
| 12:21 | From the Property Editor Window of Heat Exchanger, locate Calculation Parameters section. |
| 12:28 | Check Cold Fluid Outlet Temperature. It is 66.15 degree Centigrade. |
| 12:37 | Check Hot Fluid Outlet Temperature. It is 40.95 degree Centigrade. |
| 12:45 | Check Overall Heat Transfer Coefficient. It is 191.83 Watt per meter square kelvin. |
| 12:54 | Check Heat Exchange Area. It is 319.12 meter square. |
| 13:01 | From the Property Editor Window of Heat Exchanger, locate Results section. |
| 13:08 | Under Results section, check Thermal efficiency; it is 79.05 %. |
| 13:17 | Check Log Mean Temperature Difference; it is 21.25 degree Centigrade. |
| 13:25 | Now we will check the stream-wise temperature results and Material balance. |
| 13:32 | Go to Insert menu and select Master Property Table. |
| 13:39 | Double-click on the Master Property Table to edit it. |
| 13:44 | Configure Master Property Table window opens. |
| 13:49 | Enter Name as Heat Exchanger – Stream Wise Results. |
| 13:55 | Enter Object Type as Material Stream. |
| 13:59 | By default, Material Stream is already selected. |
| 14:03 | So, we will not change it. |
| 14:06 | Under Properties to display, select Object as: Water In, Methanol In, Water Out and Methanol Out. |
| 14:18 | Under Property, scroll down to see all the parameters. |
| 14:24 | Now select the properties as: Temperature, |
| 14:29 | Pressure, |
| 14:31 | Mass Flow, Molar Flow, |
| 14:36 | Molar Fraction(Mixture) / Methanol, |
| 14:41 | Molar Fraction(Mixture) / Water. |
| 14:45 | Close this window. |
| 14:48 | Move the Master Property Table for better visibility. |
| 14:54 | Here, we can see the corresponding results for Inlet and Outlet streams. |
| 15:00 | Now we will check the properties of Heat Exchanger. |
| 15:05 | Go to Insert menu and select Master Property Table. |
| 15:11 | Double-click on the Master Property Table. |
| 15:15 | Configure Master Property Table window opens. |
| 15:20 | Enter Name as Heat Exchanger – Results. |
| 15:25 | Enter Object Type as Heat Exchanger. |
| 15:31 | Under Properties to display, select Object as HE-004. |
| 15:39 | Under Property, scroll down to see all the parameters. |
| 15:45 | Now, select the properties as: Global Heat Transfer Coefficient (U), |
| 15:52 | Heat Exchange Area (A),
Heat Load, |
| 15:57 | Cold fluid outlet temperature, |
| 15:59 | Hot fluid outlet temperature, |
| 16:04 | Logarithmic mean temperature difference LMTD and Thermal Efficiency. |
| 16:12 | Close this window. |
| 16:15 | Move the Master Property Table for better visibility. |
| 16:22 | Here we can see the corresponding results for Heat Exchanger. |
| 16:27 | Let's summarize. |
| 16:29 | In this tutorial, we have learnt to: simulate a Shell & Tube Heat Exchanger, |
| 16:35 | calculate the Outlet stream temperatures, |
| 16:38 | calculate Overall Heat Transfer Coefficient, |
| 16:41 | calculate Heat Exchange Area, |
| 16:44 | Calculate Thermal Efficiency and LMTD. |
| 16:48 | As an assignment, repeat this simulation with different Compounds, feed conditions and Thermodynamics. |
| 16:57 | Watch the video available at following link. |
| 17:01 | It summarizes the Spoken Tutorial project. |
| 17:05 | The Spoken Tutorial Project Team conducts workshops and gives certificates. For more details, please write to us. |
| 17:14 | Please post your times queries in this forum. |
| 17:18 | The FOSSEE team coordinates conversion of existing flow sheets into DWSIM. |
| 17:25 | We give honorarium and certificates. For more details, please visit this site. |
| 17:32 | The FOSSEE team coordinates coding of solved examples of popular books. |
| 17:38 | We give honorarium and certificates . For more details, please visit this site. |
| 17:44 | The FOSSEE team helps migrate commercial simulator labs to DWSIM. |
| 17:50 | We give honorarium and certificates. For more details, please visit this site |
| 17:57 | Spoken Tutorial and FOSSEE projects are funded by NMEICT, MHRD, Government of India. |
| 18:05 | This tutorial is contributed by Kaushik Datta and Priyam Nayak. Thanks for joining. |
