1. Aisc Shapes Database V14
2. Aisc Shapes Database Excel
3. Aisc Shapes Database Historic
4. Aisc Shapes Database V15.0h
5. Aisc Shapes Database V15
6. Aisc Shapes Database Xls
7. Aisc Shapes Database

Shape Databases

For each material, there are several databases of common structural shapes such as Hot Rolled Steel Wide Flanges, Cold Formed Shapes, Wood, Concrete Tees, etc. You may also choose from shapes created in RISASection. You may type in the names directly, select shapes from these databases or add your own shapes.

Aisc structural shapes database: online viewer With virtually nothing to do at home during weekends, learning to write programs in javascript has now become a hobby. Does anyone know if there is a free downloadable database for all of AISC steel shapes? I’ve done some light searching on the web, and there seems to be a handful of random “free” links but I’m unsure on reliability of them. Was hoping AISC would provide this, to ensure credibility.

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Database Shape Types

There are different types of shapes for each material type including General shapes. Names for each shape type follow a syntax so that they may be typed directly into the Shape field on the Section Sets spreadsheet or on the Primary tab of the Members spreadsheet. Alternately you may click the button to look up a shape and select it.

Hot Rolled Shapes

AISC, Canadian, Trade Arbed and custom Hot Rolled shapes are accessed by clicking the Shape Database button from theAdvanced tab of the Ribbon and then clicking the Hot Rolled tab from within the Shape Database Editor dialog.

Aisc Shapes Database V14

The hot rolled shapes and databases are more fully described in the Hot Rolled Steel Design section. See Hot Rolled Steel Databases for more information.

Virtual Joists and Virtual Joist Girders

Aisc Shapes Database Excel

The Steel Joist Institute (SJI) has put together Virtual Joist and Virtual Joist Girder tables which convert common joist and joist girder sizes into equivalent wide flange beams. These shapes are available by selecting Virtual Joist Girder or Virtual Joist from the Database menu. For additional advice on this topic, please see the RISA Tips & Tricks webpage at risa.com/post/support. Type in Search keywords: Virtual Joist Girders

Cold Formed Shapes

Manufacturer and custom cold formed shapes are accessed by clicking the Shape Database button from theAdvanced tab of the Ribbon and then clicking the Cold Formed tab from within the Shape Database Editor dialog.

The cold formed shapes and database are more fully described in the Cold Formed Design section. See Cold Formed Steel Databases for more information

Concrete Shapes

Aisc Shapes Database Historic

Concrete shapes do not have a predefined database like hot rolled and cold formed steel. Instead, they are defined using a parametric shape code that may be assigned any depth or width. There are two types of shapes currently supported: Rectangular and Round. See Concrete Database for more information.

Wood Shapes

The available wood shapes are based on the dimension lumber and post and timber shapes given in the NDS or CSA O86, depending on what code you have chosen as your Wood design code. You may also design for multiple plies of these shapes. Note that the NDS dimension lumber shapes are all nominal sizes. CSA O86 shapes are actual sizes.

Allowable stress values for each shape are based on the species and grade information given in the selected design code. See Wood Database for more information.

Aluminum Shapes

US, Canadian and custom Aluminum shapes are accessed by clicking the Shape Database button from theAdvanced tab of the Ribbon and then clicking the Aluminum tab from within the Shape Database Editor dialog.

The aluminum shapes and databases are more fully described in the Aluminum - Databases section.

General Shapes

Arbitrary Shapes

Arbitrary Shapes are a special, catch-all shape. This arbitrary shape type is provided so that any shape can be added to the shape database.

AISC code checks are not calculated for arbitrary shapes since their place in the specification is unknown. Everything else will be calculated for them (forces, deflections, stresses). The max thickness (Max thick) value for the cross section is used to determine the pure torsional shear stress for the shape. 'J' is the torsional constant. The 'd' values (the distances to the extreme fibers) allow the program to calculate stresses at the extreme fibers.

Note:

• These shapes will generally be rendered using a greenish cruciform shape. The center of the cruciform will reflect the centroid of the section with the tips of the cruciform representing the distances from the neutral axis to the extreme fiber.
• Refer to Member Shear Deformations and Member Shear Stresses for more information on the shear area factors (As-zz Def, As-yy Def, .As-zz Stress, & As-yy Stress) shown in the figure below.

To Add an Arbitrary Shape to the Database

• To enter an arbitrary shape in the database, click the Shape Databasebutton from theAdvanced tab of the Ribbon and then clicking the General tab from within the Shape Database Editor dialog. Set the shape type to Arbitrary, click Add and then enter the shape name and properties.

RISASection Files

You may create simple or complex sections in RISASection and then import those sections for use in your model. Sections that exist in RISASection (files located in the 'RISASection' file specified in File - Application Settings - File Locations) will be available for use in the model. Each section must have a unique name for it to be available.

The shapes that are designated as General Material, Arbitrary Shape Type in RISASection will show up in the General tab under the 'RISASection' Database.

The shapes that are designated as Hot Rolled Steel Material in RISASection will show up in the Hot Rolled tab under the appropriate Shape Type (Channel, Wide Flange, etc.) when 'RISASection' is selected as the Database.

Note: Currently, RISASection can only import General and Hot Rolled Steel shapes. More material choices will be available in a future version.

For additional advice on this topic, please see the RISA Tips & Tricks webpage at risa.com/post/support. Type in Search keywords: RISASection Integration.

Troubleshooting RISASection / RISA- Interaction

There are a few common issues that arise when attempting to access RISASection files from within RISA-.

• When RISA-3D launches, it will only import RISASection files that exist in the directory specified in File - Application Settings - File Locations.
• RISA-3D only reads in database files when it is first launched. Therefore, if a RISASection file is created or modified, then RISA-3D must be closed and re-started before it will recognize the new or modified section.

There are some common mistakes that are made from within the RISASection program that may cause an issue when trying to read that shape from within RISA-3D.

• The name of the RISASection 'File' is actually different from the name of the section itself. Both names will appear in the RISA-3D database, but it is important to give your sections unique names in order to properly tell them apart. Note: each RISASection file can contain many different sections. Hence the need to name each individual section.
• Unless specifically identified as a Hot Rolled Material type and shape (from within RISASection), the shapes will be imported as Arbitrary shapes with a General Material type
• RISASection can save files with a new *.nmsx file type (for RISASection 2.0 or higher), or an old *.nms (for RISASection version 1.1 or older). If saved as the old file type, the sections will only come in as Arbitrary members with a General material type.

• If the file is saved with a *.nmsx extension it will not be read into older versions of the RISA programs (prior to RISA-3D version 9.1.1.

Structural Desktop (SDT) Shapes

The SDT database is provided by the Structural Desktop software in a file called SDT.FIL. Structural Desktop automates drawing production of RISA models. The SDT database is provided for shapes that are not directly supported in RISA models (such as bar joists) but are available in Structural Desktop. For more information on Structural Desktop see www.structuraldesktop.com.

On-Line Shapes

On-Line shapes are shapes whose dimensions are defined directly in the syntax of the shape name. On-line shapes are not stored in the shape database because there is enough information from the label syntax to calculate all the shape properties. A pipe, for example, can be fully defined by specifying the thickness and diameter.

These shapes are treated just like database shapes for stress calculations. Currently, Pipes, Solid Rectangular and Solid Circular shapes are defined on-line as discussed below in Pipe Database Shapes, Solid Rectangular Shapes, and Solid Circular Shapes.

Pipe Database Shapes

Pipe shapes, which are hollow circular shapes, are entered as on-line shapes. The syntax for these shapes is 'PIdiaXthick', where 'dia' is the pipe outside diameter and 'thick' is the pipe thickness (in inches or centimeters). For example (assuming US Standard units), PI10X.5 would be a 10' diameter pipe with a wall thickness of 1/2'.

Solid Rectangular Shapes

These shapes can be defined as on-line shapes. The syntax is 'REhtXbase', where 'ht' is the rectangle height and 'base' is the rectangle base (in inches or cm). For example, RE10X4 would be a 10' deep, 4' width rectangular shape (assuming US Standard units). These shapes can also be defined in the Shape Editor. When defined in the Shape Editor the depth of the solid rectangular section must always be greater than or equal to the width.

Solid Circular Shapes

Aisc Shapes Database V15.0h

These shapes are defined as on-line shapes. The syntax is 'BARdia', where 'dia' is the circle diameter. For example (assuming metric units), BAR2 would be a circular bar with a diameter of 2 cm.

Aisc Shapes Database V15

Database Files

Aisc Shapes Database Xls

The shape databases are stored in the database files (*.FIL). These files may only be edited through the program. The path to these files is set in the File Locations tab of Application Settings, which is found in the File menu.

Note

Aisc Shapes Database

• Alterations to the shape databases are not permanent unless you agree to save them. Changes that are not saved only remain valid for the current session and will not be present the next time you start RISA.
• New shapes are always added to the bottom of the database in blue text.
• To delete a shape specify the database and shape type you wish to delete and then click the Delete button.
• To edit a shape click the Edit button and edit the shape properties. Only shapes that are not part of the default database are able to be edited. If the shape you would like to edit is a default database shape, the program will ask if you would like to make a copy of the shape. Geometric values can be edited here, and will allow you to recalculate the section properties if edits have been made.

2D3DSteel Features:

• Compatible with Windows 10 and AutoCAD 2000 through 2021 and beyond.

• 2D3DSteel Main tool bar has six fly out tool bar buttons on it providing access to all of 2D3DSteels' commands on one tool bar to save screen space if needed.

• 2D3DSteel Settings tool bar controls 2D3DSteel layers, linetypes, centerline modes, node point modes, and dimension text lock colors. This toolbar has two commands for saving and restoring your object snap settings. It also includes commands for fast centerline and node point mode changes.

• 2D3DSteel Shape tool bar commands draw the shape selected in the ShapeBook dialog as 3DSolids, 2D Cross sections, and 2D Web and Flange Views. New cope commands draw a cope pline that can be used as the end of a 2D member or to cope a 3DSolid.

• 2D3DSteel Lines tool bar is a powerful set of tools for line work in your drawings. Line commands for the 2D3DSteel object lines, hidden lines, centerlines, and dimension lines. Line commands can also be used to quickly change to a 2D3DSteel layer/linetype setting. All of the commands in 2D3DSteel except for these line commands save and restore your current layer and linetype settings. Commands on this toolbar include drawing offset rows of centerlines, centered rows of centerlines, centerlines at equal spacing, centerlines at maximum spacing, and an intelligent handrail picket tool.

• 2D3DSteel Holes tool bar has four types of 2D holes, round holes, edge holes, slotted holes, and elliptical holes. Each of these four types can be drawn filled, open, or hidden. 3D Hole command is used to add holes in 3DSolids and the Polyline cut command can change any shape created with a closed polyline into a cut out in a 3DSolid with a specified depth. Two bolt group commands draw a single row of holes and a double row of holes.

• 2D3DSteel Dimension toolbar includes a transparent command for fast 10 key XX.YYZZ feet, inches, and sixteenths input at any AutoCAD distance prompt, a transparent command for metric input in millimeters at any AutoCAD distance prompt. Special dimensioning commands for horizontal or vertical dimensions with automatic .Y & .X point filters to quickly line up dimension rows, rotated dimension commands that remember your rotation angle, and commands to lock and unlock associative dimension text with text color id for easy member shortening and un-shortening.

• 2D3DSteel Plate tool bar has five commands for drawing 2D plates are used in addition to the commands on the 2D3DSteel Shape tool bar.

• 2D3DSteel Drawing Settings are stored in your drawing and are used automatically from drawing to drawing. The default value is 0 for all dimensional input entries that are encountered for the first time. 2D3DSteel saves all of your dimensional input entries. The saved value is offered as the default value for that command input entry until it is changed. All of the default values are automatically saved and then restored in your next AutoCAD session. What this means is, once you enter a hole diameter or slot length etc. that will be the value used when you hit return for the prompts for those dimensions the next time you use that command. If you change a value, that will be the next default value for that prompt.

Using AutoCAD with 2D3DSteel, you will have the tools to accurately draw or model 2D and 3D structural steel framing and connections. You can use 2D3DSteel to draw your sections and details or to draw structural 3D models using 3D solids created by 2D3DSteel and ShapeBook.

Please Note: The procedure for adding 2D3DSteel to your AutoCAD Startup Suite is documented in the ShapeBook software and help is available on the About tab.