Access Steel Tub Girder Training Example
Please follow below instructions in order to access ‘Steel Tub Girder Training Example’
1 | → Log in to your account and locate the 'Project' option in the top right corner. |  |
Please note that the initial setup process for the user experience take approximately 5-8 seconds to complete. Subsequent interactions will not require as much time. | ||
→ Click on 'Project' and then select 'NEW' from the top left corner of the screen. |  | |
2 | → Under the 'Example Project' section, click on 'New Project' specifically located within the 'Steel Tub-Girder Training Example'. |   |
3 | → Provide a name for your project and proceed to open the example project. |   |
Please note that the initial download process for the library components take approximately 2 minutes and 20 seconds to complete. Subsequent interactions will not require as much time. | ||
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View Design Reports of Steel Tub Girder Training Example
Please follow the instructions provided below to initiate steel tub-girder code check reports.
This quick guide provides a concise overview of the design reports presented on the right side of the screen. | Steel Tub-Girder Code Check | |
Internal Cross-Frame Code Check | ||
Field Splice Code Check | ||
Pier Cap Code Check | ||
Pier Column Code Check | ||
Pier Footing Code Check | ||
Pile Capacity Code Check | ||
1 | Please ensure that the 'FEM' button located in the top-middle of the screen is active. If the button is inactive, the 'Analysis' button will not appear. |  |
Please be aware that the appearance of the analysis button for this project typically takes around 15-20 seconds. | ||
Once the 'Analysis' button appears in the top left corner, it indicates that the FE model has been compiled and is ready for analysis. |   | |
→ Click on it to initiate the finite element analysis (FEA) of the steel tub-girder bridge. |  | |
Please note that the analysis for this project typically takes around 3.5 minutes to complete. | ||
2 | → Once the analysis is completed, click the "Close" button to exit the analysis interface. |  |
3 | → Proceed by clicking the "Design" button to calculate the parametric design parameters and collect the analysis results required for the design reports. During the design process, you can track the design progress from the top-middle of the screen. ⚠️ You should keep the design tab visible until the task completes, as hiding or minimizing the page pauses the process of collecting analysis results. |   |
Please be aware that the design verification for this project generally takes approximately 9 minutes to complete. | ||
4 | → After the design run is completed, click on the "OK" button to start viewing the created design reports. |  |
5 | → Clicking on the "Report" and "Detailed Report" buttons successively will display a range of design reports that can be accessed. |  |
→ By clicking on the "Detailed Report" option, you will be able to access a diverse range of design outputs that provide: |  | |
The common steps before investigating individual design reports have been completed.
Now hover over and click on your favorite design process from the selection below to further explore the process of viewing a design report for it:
Steel Tub-Girder Code Check Report
Please follow the instructions provided below to create steel tub-girder code check reports.
| 1 | In the summary report, the code checks for the employed girder, code check station, limit state are presented along with the corresponding design check parameters (D/C ratio, Pass/Fail State). |  |
| 2 | Clicking on the "Detailed Report" icon, as illustrated in the previous step, will open a detailed code check report. |  |
| 3 | ||
Internal Cross-Frame Code Check Report
Please follow the instructions provided below to create cross frame code check reports.
| 1 | In the summary report form, the resultant code check values for each chord of the cross frame are presented. Additionally, the summary report format includes gusset plate bolted connection checks. |  |
| 2 | Clicking on the "Detailed Report" icon (marked in red), as illustrated in the previous step, will open a detailed code check report that includes axial force member checks. |  |
| 3 | Clicking on the "Detailed Report" icon (marked in blue) will open a separate report specifically for bolted gusset plate checks. |  |
| 4 | ||
Field Splice Code Check Report
Please follow the instructions provided below to create field splice code check reports.
| 1 | In the summary report, the code check parameters for the corresponding splices are presented for splice plates and bolts, considering the D/C ratio. These parameters specifically address the strength and service limit states. |  |
| 2 | Clicking on the "Detailed Report" icon, as illustrated in the previous step, will open a detailed code check report. |  |
| 3 | ||
Pier Cap Code Check Report
Please follow the instructions provided below to create pier cap code check reports.
| 1 | In the summary report, pier cap code checks are conducted using a design templates, namely for AASHTO (marked in red). The report presents the results of these code checks for the pier cap design. |  |
| 2 | Clicking on the "Detailed Report" icon (marked in red), as illustrated in the previous step, will open a detailed code check report that includes pier cap code checks for flexure, shear, torsion, fatigue and reinforcement limits. |  |
| 3 | ||
Pier Column Code Check Report
Please follow the instructions provided below to create pier column code check reports.
| 1 | In the summary report, the pier column code check presents the results of code checks as either D/C ratios or in Pass/Fail form, accordingly. |  |
| 2 | Clicking on the "Detailed Report" icon, as illustrated in the previous step, will open a detailed code check report that includes pier column code checks for axial force-moment interaction, axial compression, shear, torsion, and reinforcement limits. |  |
| 3 | ||
Pier Footing Code Check Report
Please follow the instructions provided below to create pier footing code check reports.
| 1 | The summary report for pier footing code check includes D/C values and Pass/Fail status for flexure, one-way shear, two-way shear, and reinforcement limits. |  |
| 2 | Clicking on the "Detailed Report" icon, as illustrated in the previous step, will open a detailed code check report that includes pier footing code checks. |  |
| 3 | ||
Pile Capacity Code Check Report
Please follow the instructions provided below to create pile capacity code check reports.
| 1 | The summary report for pile capacity code check reports the maximum D/C value against the specified pile capacity. |  |
| 2 | Clicking on the "Detailed Report" icon, as illustrated in the previous step, will open a detailed code check report that includes the most critical results, as well as all the results from different limit states. |  |
| 3 | ||
Quick Tips - Exploring Design Variables in Depth
To quickly search for a specific design parameter, simply press CTRL + F and type the relevant keyword. 
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To grasp the computation of design parameters, their annotation, and delve into the underlying formulation used, refer to the relevant piece of information provided below: i) To access the design parameter annotation, hover over the parameter of interest. ii) To explore the design parameter computation, click on the parameter. iii) Additionally, the design report may already include explicit reporting of the computation and the parameters used in a regular format throughout the document.
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