OpenBrIM TRAINING MANUAL FOR STEEL I GIRDER BRIDGE PROJECTS
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| 1 | Click New from the left side bar | |
| 2 | Click Steel Girder Bridge Workflow template |  |
| 3 | Click Steel I Girder Bridge Workflow to create a new project |  |
| 4 | Enter the project name and the category | |
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| 1 | Click New from the left side bar | |
| 2 | Click Steel Girder Bridge Workflow template |  |
| 3 | Click Steel I Girder Bridge Workflow to create a new project |  |
| 4 | Enter the project name and the category |
ℹ️ About
The information presented in this publication has been prepared following recognized principles of design and construction. While it is believed to be accurate, this information should not be used or relied upon for any specific application without competent professional examination and verification of its accuracy, suitability, and applicability by a licensed engineer or architect. The publication of this information is not a representation or warranty on the part of the Red Equation Corporation, its officers, agents, employees, or committee members, or of any other person named herein that this information is suitable for any general or particular use, or of freedom from infringement of any patent or patents. All representations or warranties, express or implied, other than as stated above, are specifically disclaimed. Anyone making use of the information presented in this publication assumes all liability arising from such use. Caution must be exercised when relying upon standards and guidelines developed by other bodies and incorporated by reference herein since such material may be modified or amended from time to time after the printing of this edition. The Red Equation Corporation bears no responsibility for such material other than to refer to it and incorporate it by reference at the time of the initial publication of this edition.
Workshop Example Bridge
This section provides the basic instructions on how to model, analyze and design the Steel I Girder Bridge using OpenBrIM.App. The Excel file provides the complete set of bridge inputs ready to copy and paste into the OpenBrIM.App DATA spreadsheet.
Overview of Bridge Model
The bridge model adapted from Federal Highway Administration Design Example 3: Three-Span Continuous Horizontally Curved Composite Steel I-Girder Bridge, Publication No. FHWA-HIF-16-002 - Vol. 23.
Design Parameters
Structural Steel: AASHTO M270, Grade 50 (ASTM A709, Grade 50) steel with Fy = 50 ksi, Fu = 65 ksi
Concrete: fc′ = 4.0 ksi, = 150 pcf
Slab Reinforcing Steel: AASHTO M31, Grade 60 (ASTM A615, Grade 60) with Fy = 60 ksi
The bridge has spans of 160.0 feet – 210.0 feet – 160.0 feet measured along the centerline of the bridge. Span lengths are arranged to give similar positive dead load moments in the end and center spans. The radius of the bridge is 700 feet at the centerline of the bridge. The out-to-out deck width is 40.5 feet, and there are three 12-foot traffic lanes. All supports are radial with respect to the bridge centerline. There are four I-girders in the cross-section. The total deck thickness is 9.5 inches, with an assumed 0.5- inch integral wearing surface. Therefore, the concrete deck’s structural thickness is 9.0 inches. The deck haunch thickness is taken as 4.0 inches and is measured from the top of the web to the bottom of the deck. That is, the top flange thickness is included in the haunch. The roadway is superelevated 5 percent. The girders in this example are composite throughout the entire span, including regions of negative flexure since shear connectors are provided along the whole length of each girder. The bridge cross-section in this design example consists of four I-girders that are spaced at 11 feet in the center with 3.75-foot deck overhangs.
Design Loads
Permanent steel stay-in-place deck forms are used between the girders; the forms are assumed to weigh 15.0 psf since it is assumed concrete will be in the flutes of the deck forms. An allowance for a future wearing surface of 30.0 psf is incorporated in this design example. The bridge is designed for HL93 live load per Article 3.6.1.2. Live load for fatigue is taken as defined in Article 3.6.1.4. The bridge is designed for 75-year fatigue life, and single-lane average daily truck traffic (ADTTSL) in one direction is assumed to be 1,000 trucks per day. The bridge site is assumed to be in Seismic Zone 1, so seismic effects are not considered in this design example. Steel erection is not explicitly examined in this example, but the sequential placement of the concrete deck is considered. The concrete is the first cast from the left abutment to the dead load inflection point in Span 1, the concrete between dead load inflection points in Span 2, and the concrete beyond the dead load inflection point to the abutment in Span 3. Finally, the concrete between the points of dead load contra flexure over the two piers is cast.
Modeling on OpenBrIM.App
Creating a Steel I Girder Bridge Workflow Template
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| 2 | Click New from the left side bar | |
| 3 | Click Steel Girder Bridge Workflow template | |
| 4 | Click Steel I Girder Bridge Workflow to create a new project | |
| 5 | Enter the project name and the category | |
Bridge Layout
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| 2 | Go to Roadway Alignment |  | ||||||
| 3 | Enter Start Station as 0 | |||||||
| 4 | Click the three-dots icon |  | ||||||
| 5 | Click + icon nes to the Horizontal and add a circular segment |  | ||||||
| 6 | Enter Length as 530 ft, Radius as 700 ft, and Direction as Towards Right | |||||||
| 7 | You can edit the Vertical data such as grades and elevations of alignment in the Vertical tab. In this example, vertical data of alignment is set to 0 |  | ||||||
| 8 | Click + icon next to the Transverse to define the alignment cross-section at a specific station |  | ||||||
| 9 | Enter the cross-section Station as 0 ft |
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| 10 | Enter the Left Edge to PGL distance as 20 ft. This distance is the length from the left edge to the centerline of the alignment | |||||||
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| 13 | Go to Bridge Alignment Set Alignment | |||||||
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| 15 | Go to Support Line on tree view next to the data spreadsheet |  | ||||||
| 16 | Select Bridge and enter the support stations | |||||||
| 17 | ©️ You can copy this data, and paste it to Support Lines.
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| 19 | Go to Insertion Point on tree view next to the data spreadsheet. |  | ||||||
| 20 | Select a support line as Location. | |||||||
| 21 | Enter Transverse Offset to relocate the insertion point on the support line. | |||||||
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| 23 | Follow the below steps to create girder line layouts. | |||||||
| 24 | Go to Girder Layout on the tree view next to data spreadsheet |  | ||||||
| 25 | Click three-dots icon |  | ||||||
| 26 | Set Type as curved |  | ||||||
Properties
This section contains material, section, and rebar definitions. Once these properties are imported throughout the modeling, they will automatically appear under the Properties.
This section also serves as the input interface of the properties. Follow the below steps to define the properties that this interface will utilize in the example.
Materials
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| 2 | Go to Properties/Materials. |  |
| 3 | In 1st row, click-three-dots icon | |
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| 5 | From Database drop-down, select Steel Material Database (US) |  |
| 6 | Select Category as Structural Steel. | |
| 7 | Select Asset as A709_50. | |
| 8 | Click Import. | |
| 9 | Check the imported material placed in 1st row including the mechanical properties |  |
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| 11 | From Database drop-down, select Concrete Material Database (US). |  |
| 12 | Select Category as Cube. | |
| 13 | Select Asset as FcCube_4ksi | |
| 14 | Click Import. | |
| 15 | Check the change in Materials data spreadsheet |  |
| 16 | Check the Steel column and Concrete column for the material type-specific properties. |  |
| 17 |  | |
Stress-Strain Model
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