Osdag/C3/Specifying-design-preferences-in-Osdag/English
Title of the script: Specifying design preferences in Osdag
Author: Anandajith TS
Keywords: Osdag, member design, connection design, steel design optimisation, Tension member, Design Preference, bolt design, detailing, gusset plate, video tutorial
Visual Cue | Narration |
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Title Slide |
Welcome to the Spoken Tutorial on Specifying design preferences in Osdag. |
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Learning Objectives |
In this tutorial, we will learn to,
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System Requirements |
To record this tutorial, I am using
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Pre-requisites |
To follow this tutorial you should have,
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Code Files |
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Only narration | The user interface of Osdag for Ubuntu Linux, and for Windows is the same.
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Point to the home page of the Tension Member Design - Bolted to End Gusset module | Switch to the home page of the Tension Member Design- Bolted to End Gusset module. |
Point toward the Input Dock fields | I have loaded the Preference hyphen sample hyphen design dot OSI file. |
Only narration | Please pause the tutorial and perform the same steps on your computer. |
Click on the Design button | Click on the Design button below to perform the design. |
Only narration | Osdag carries out the design. |
Point toward the INFO message in the log message window | The design is complete and safe. |
Point toward the CAD window and the Output Dock | The CAD window becomes active, and the Output Dock is populated with results. |
Only narration | Let us specify some design preferences and check for updated results. |
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Sample Design Example |
Perform a design check by adopting the given design preferences:
Bolt:
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Sample Design Example |
Detailing:
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Switch back to Tension Member Design - Bolted to End Gusset module homepage | Performing design with above preferences may change the design results completely. |
Only narration | Design Preference is an advanced feature.
It should be used after due consideration. |
Click on the Spacing Details button. | Click the Spacing Details button under End Connection in the Output Dock. |
Point toward the Spacing Details window | The Spacing Details window opens. |
Point toward Bolt Rows (nos) | Notice that the number of Bolt Rows is 2 on each gusset plate. |
Point toward Bolt Columns (nos) | And the number of Bolt Columns is 16. |
Only narration | This means that there are 32 bolts on each gusset plate or 16 bolts per Angle. |
Only narration | Let us see if the bolt configuration changes after designing with special preferences. |
Click on the close button | Click on the close button at the top right corner to exit the window. |
Point toward Capacity (kN) under Bolt Details output | Also, notice the bolt capacity for the given design.
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Only narration | Let us see if the bolt capacity changes after designing with special preferences. |
Only narration | Let us now define the preferences for our design. |
Click on the Edit menu in the menu bar | Click on the Edit menu in the menu bar and |
Select Design Preferences | Select Design Preferences from the list. |
Point toward the Design Preference window | The Design Preference window will open. |
Only narration | The Design Preference window is categorised into various sections. |
Click on Angle Section | Typically, these sections include;
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Click on Connector |
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Click on Bolt |
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Click on Detailing |
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Click on Design |
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Only narration | Let's explore the sections and define the corresponding preferences individually. |
Click on the Angle Section tab | Click on the Angle Section tab to view the selected member details. |
Point toward Designation, Section Profile and Conn_Location | Here, section details like designation and the profile are shown. |
Point toward Mechanical Properties | Below section details, we see Mechanical Properties. |
Point to the properties. | These properties get populated based on inputs in the Input Dock and the codal provisions |
Point toward Dimensions | Dimensions of the selected section are listed under the Dimensions section. |
Point to the dimensions. | These dimensions are fetched from the Indian Standard, IS 808 database of Osdag. |
Point toward the section image | A detailed and representative cross-section drawing of the selected section is shown. |
point to the 2D drawing. | This 2D drawing is typical and has standard notations marked over it for better visualisation. |
Point toward Section Properties | The sectional properties corresponding to the selected section are listed under Section Properties. |
Point toward Section Properties fields | These properties are also fetched from the Osdag database at run-time. |
Only narration | For a user-defined section not present in the database, properties are calculated by Osdag internally. |
Only narration | The properties of this user-defined section are inserted into the database for reuse. |
Only narration | Users can add single or multiple custom sections to the Osdag database and use it in design. |
Point toward Add button | The Add button at the bottom allows to Add a single custom section to the database. |
Point toward the Download xlsx file, and Import xlsx file buttons | For adding multiple sections at once using an excel sheet, use the Download and Import xlsx buttons. |
Point toward the Download xlsx file, and Import xlsx file buttons | We will explore this feature in another tutorial. |
Point toward the Clear button | The Clear button will clear the user-defined inputs in the Design Preference window. |
Click on the Connector tab | Let us move to the Connector tab. |
Point toward the Inputs fields | Here, we see the Material properties of the connector material. |
Point toward the Material drop-down menu | E 250 (Fe 410 W)A is selected by default. |
Point toward the Ultimate Strength and Yield Strength field | The corresponding values of the ultimate and yield strengths are shown below. |
Point to the material grade. | We need to change the material grade to E300. |
Click on the Material drop-down menu and select E300 (Fe 440) from the list | Click on the Material drop-down menu and select E300 (Fe 440) from the list. |
Point toward the Ultimate Strength and Yield Strength field | Notice the values of the ultimate and yield strength are now updated automatically. |
Click on the Bolt tab | Let us now move to the Bolt tab. |
Point toward Type and Hole Type | The default bolt type is Pre-tensioned, and the Hole Type is Standard. |
Point to the Hole type. | The desired Hole Type is Over-sized. |
Click on the Hole Type drop-down menu and select Over-sized from the list | Click on the Hole Type drop-down menu and select Over-sized from the list. |
Point to the slip factor value. | Now, let us change the Slip factor to 0.48. |
Click on the Slip factor drop-down menu, scroll and select 0.48 from the list | Click on the Slip factor drop-down menu
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Point toward the Description text box | A description of the slip factor values is shown in the Description text box. |
Highlight IS 800 Table 20 | The description is referred from the Indian Standard, IS 800, Table 20. |
Highlight xi) Sand blasted surface 0.48 in the Description text box | We see, for a slip factor of 0.48, the surface treatment is of Sand blasted type. |
Point to the bolt preferences. | We have defined preferences for the Bolt. |
Click on the Detailing tab | Let us now move to the Detailing tab. |
Click on the Edge Preparation Method drop-down menu and select machine-flame cut from the list | Click on the Edge Preparation Method drop-down menu and select machine-flame cut from the list. |
Point toward the Gap textbox | The Gap preference is not applicable here.
We will leave it as default. |
Only narration | In our design, the members are exposed to corrosive influences.
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Point toward the Are the Members Exposed to Corrosive Influences drop-down menu. | Click on the Corrosive Influences drop-down menu and select Yes. |
Point toward the Description text box | The Description text box shows a description with reference to the corresponding IS 800 clauses |
Point to the Description text box . | Users may refer to this description for a better understanding of these design clauses. |
Click on the Design tab | Let us now move to the Design tab. |
Point toward the Design Method drop-down menu | We see the default Design Method is Limit State Design. |
Only narration | Osdag performs design using the Limit State Method. |
Click on the Design Method drop-down menu | Other methods of design are not available with this version. |
Only narration | We have defined all the preferences.
We are now ready to perform the design. |
Point toward the Defaults button | The Defaults button below sets the preferences to the default value.
Do not press this button after defining the preferences. |
Point toward the Save button | The Save button saves the defined preferences. |
Click on the Save button | Click on the Save button to save and exit the Design Preferences window. |
Cursor in the CAD window. | We are ready to perform the design with saved preferences. |
Click on the Design button | Click on the Design button again. |
Only narration | Osdag carries out the design. |
Only narration | The design process might take some time to complete. |
Point toward the INFO message in the log message window | The design is completed successfully. |
Only narration | Now, let us check if the design results have changed from that recorded previously |
Click on the Spacing Details button. | Click on the Spacing Details button in the Output Dock under End Connection. |
Point toward Bolt Rows (nos). | The number of Bolt Rows is 2 on each gusset plate. |
Point toward Bolt Rows (nos). | This has not changed. |
Point toward Bolt Columns (nos). | The number of Bolt Columns is now 12. |
Point toward Bolt Columns (nos). | This has been reduced from 16 to 12. |
Only narration | This means that now there are 24 bolts on each gusset plate or 12 bolts per Angle. |
Only narration | There is a change in the total number of bolts after designing with special preferences. |
Click on the close button. | Click on the close button at the top right corner to exit the window. |
Point toward Capacity (kN) under Bolt Details output | Also, notice the bolt capacity has changed to 26.98 kilo Newton. |
Only narration | Users can refer to other design outputs and compare the results similarly. |
Only narration | This brings us to the end of this tutorial.
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Summary
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In this tutorial, we have:
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Assignment |
As an assignment, do the following
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About Spoken Tutorial Project |
The video at the following link summarizes the Spoken Tutorial Project.
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The Spoken Tutorial Project team conducts workshops and gives certificates.
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Answers for THIS Spoken Tutorial |
Please post your timed queries in this forum. |
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FOSSEE Forum |
For any general or technical questions on Osdag, visit the FOSSEE forum and post your question |
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Sample Design Examples |
https://osdag.fossee.in/resources/sample-design
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Acknowledgement |
The Spoken Tutorial project was established by the Ministry of Education, Government of India |
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Thank you |
This is Anandajith TS, FOSSEE IIT Bombay signing off
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