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Autodesk advance steel 2019 tutorial pdf free download
Is this content inappropriate? Report this Document. Description: Autodesk Steel Training. Flag for inappropriate content. Download now. Original Title: Autodesk Advance Steel. Jump to Page. Search inside document. Autodesk Advance Steel detailing software helps accelerate design, steel detailing, steel fabrication, and steel construction—built on the familiar AutoCAD platform.
Autodesk Advance Steel features: Parametric connections Model steel faster with a library of ready-to-use connections. Steel shop drawings Use customizable templates to generate high-quality drawings. Revit interoperability Use a BIM process from design to fabrication. You might also like Weight Restriction Order in Malaysia.
Example Road Marking Measurement Sheet. Network Price List - Ausgrid. Good Construction Practices. My Cesmm2 Wm 5apr Road Signboard. The effect of the depth is more selected point can still apparent if your cut crosses the web of a section. Therefore, if you need a cut out but only know one reference point such as that the middle of one end of the rectangle must line up with the node at the end of a beam , use the By center option to create the cut out and then change the position in the Positioning tab.
Practice 10h Experiment with Contours 1. Try using each of the contour features. Try cutting the flange of the blue beam where the yellow beam cuts it. Try cutting the flange of the green beam where the blue beam cuts it.
Ensure that you only cut one flange. To return to the feature properties and edit them, you must select the green shape and select Advance Properties or Advance Joint Properties when editing an Element Contour — Rule or Parametric Cope — Joint. Presentation Type The green shape is often not displayed. To edit the feature you must display the shape first. Alternatively, there might be many green shapes in the display and you might want to hide them.
The cut out in the beam is always displayed, regardless of whether the green shape is displayed or not. Several options are available for changing the display of the features:. In the Display Type tab, select Standard to hide the features or Features to display the green shapes. If you want to hide all of the beam features in the model you can do the following:. This cuts the beams straight across at a bisecting angle and then optionally welds them together. The beams are cut at the bisecting angle and the Miter Properties dialog box opens.
If you want the beams to be welded together you must select Create Weld in the Cut tab. The cuts are made and you are returned to the Command Prompt.
Merge Beams It joins two or more beams into one. The beams must be in line, meet end to end, and be of the same section. If they meet end to end, the beams are converted into a single object. Practice 10i Modify Columns 1. Modify Columns C4 and D4 in the training structure.
Modify the tops of the top of the RHS columns on grid C4 and D4 ready for the joint, as shown in the drawings. Practice 11a Open the Drawing 1.
Continue working in Feature Practice File. Therefore, you need to set the UCS as required first. Rectangular Plate, Centre It enables you to create a rectangular plate using a single reference point for its position. A single plate is created on the XY plane at the selected location with the default dimensions.
The Plate Properties dialog box opens. Rectangular Plate, 2 Points It enables you to create a rectangular plate using two points to define its position and size. A single plate is created with its corners on the selected points. Rectangular Plate, 3 Points It enables you to create a rectangular plate at any angle to the XY plane using three points to define its position and size. A plate is created using the defined shape, the size is defined, and the Plate Properties dialog box opens.
A plate is created matching the shape of the polyline and the Plate Properties dialog box opens. Circular Plate If you want to create a circular or ring-shaped plate, you can do so with this command. Your plate is created with its center point at the current UCS origin.
The plate that is created is a square plate with plate features for creating the curved edges and hole as required. Set the length and width of the plate as needed. Use the icons for the three basic options or enter a value in the field if another position is required. A folded plate is considered a single object for drawing and manufacturing purposes. Although very powerful, the software is not a sheet metal package.
If a fold does not cover an entire edge, a bend relief is not modeled. Therefore, the fold is modeled as a tear. Corner reliefs are not modeled at any time either. Folded Plate without Position Adjustment Convert two neighboring plates into a folded plate. These plates should be positioned with the joined edges touching in the required location.
Any plate features that already exist in the individual pieces of plate are preserved and remain in the correct position relative to the piece of plate. Folded Plate with Position Adjustment It joins any two plates together into a folded plate. The second plate is moved and rotated so the selected edges are joined and the plates do not have to be touching at the start.
The second plate is moved so that the midpoints of the selected edges touch and is then be tilted to the specified angle. Any plate features that already exist in the individual pieces of plate are preserved and remain in the correct positions relative to the piece of plate.
When setting the sizes of individual plates remember to allow for the plate thickness in your required final dimensions. The individual plates on the left are aligned before the fold is applied. Create Conical Folded Plate It creates a folded plate between any two closed polyline shapes. This was originally used for hoppers or ducting type shapes in which rectangles are converted into round sections.
The command can merge any two shapes together. Complete the required options before continuing. A shaped folded plate is created, merging the two selected shapes.
Create Twisted Folded Plate It creates a twisted, folded plate between any two lines, arcs, or polylines. Complete the required settings before continuing. A folded plate with flat facets is created to go between the two selected edges. If the shape can be created using fewer facets than you set in the Properties dialog box it is done.
If the two elements. The polylines can include straight or arc segments, but you cannot use a curved polyline one that uses the Fit or Spline options. Fold Line Properties After it has been created, the folded plate is treated as a single object. After creation you cannot return to the Conical Folded Plate Properties dialog box. If you select a flat piece of plate and select Advance Properties the normal Plate Properties dialog box opens. If you select the curved portion of plate between two flats and select Advance Properties the Fold Line Properties dialog box opens.
If you change the angle the associated plate moves to suit. All of the features in the plate are preserved in the plate segment. Check Unfolding When creating folded plates it would be possible to model something that could not be developed into one sheet of material.
To ensure that you have not done so, you can use the Check Unfolding command. If you enter Yes a preview of the theoretical unfolded outline displays, enabling you to identify where the overlap would occur. If no message is displayed, the plate can be safely developed into a flat pattern. There are special commands for drawing the grating, but after creation it can be modified, etc.
Gratings are modeled as a flat plate shape, but are visually distinguished by the hatch pattern that is applied to one surface. The details of the hatch pattern are representative and do not match the exact specification of the grating.
Standard Grating It creates a model of a standard grating panel. A default grating panel is created and the Standard Grating Properties dialog box opens. In the Shape and Connector tab, select the required grating. A grating is modeled with the straight edges of the shape you have defined and the Variable Grating Properties dialog box opens. A rectangular piece of grating is modeled between the selected points and the Variable Grating Properties dialog box opens.
Set the grating specification as required in the Shape and Connector tab. Span Direction The span direction of the grating the direction of the largest sections is indicated by the direction of the hatch pattern and a symbol in the middle of the hatch. For a Standard Grating, the span direction is always parallel to the shortest edge of the panel. For a Variable Grating you can set a custom span direction. When created, a span direction that is parallel to the UCS X-axis is set.
You can modify this setting, if required. Practice 11b Remodel Ducting and Add Plates 1. Recreate the ducting in the Feature Practice file. This requires that the four plates be turned into a folded plate and then a conical folded plate be created based on the yellow polyline and circle provided. They are located at the bottom of the palette. These features work in the same way as the UCS versions, but the direction of the cut is always perpendicular to the surface of the plate.
As with beams, you might need to cut holes or shapes into plates. This is done using Plate Features. Contour features create cut outs of a closed shape anywhere on your plate. In each case, the contour shape is drawn in the current UCS. Therefore, you always need to ensure that the UCS is set correctly first usually on top of your plate. Rectangular Contour, Centre, UCS It enables you to cut a rectangular shape through a plate based on reference point for the position.
The Contour Processing Properties dialog box opens. Rectangular Contour, 2 Points, UCS It enables you to create a rectangular cut out in a plate using two points to define its position and size.
A rectangular cut out is created in the plate between the two selected points and the Contour Processing Properties dialog box opens. Circular Contour, Centre, UCS It enables you to place a circular cut out in a plate using one reference point for the position. A circular cut out is created at a default size and centered on the selected point.
Circular Contour, 2 Points, UCS Creates a circular cut out in a plate using a center point and radius to control its position and size. Please identify the object which is to be modified: Select the plate that you want to cut. A circular cut out is created at the specified position and size and the Contour Processing Properties dialog box opens. The arc is tangential to the last segment. A cut out of the specified shape is created and the Contour Processing Properties dialog box opens.
Alternatively, you can draw the required shape as a polyline before using this command. At the Please specify start point or select [Polyline s ] prompt, enter P for the Polyline option and select the polyline. Your predefined shape is cut out of the plate. Element Contour It makes a cut through a plate around a section.
The cut is created matching the shape of the selected section and the Contour Processing Properties dialog box opens. Set the size of the cut out. This distance measures from the green shape.
If the UCS is not parallel to the surface of the plate, or if using Element Contour and the section is not perpendicular to the surface of the plate, the shape is not square to the plate. The cut is still the defined shape and avoids a clash with the other members. However, for manufacture it is easier to have the edges of the cut perpendicular to the plate surface, so the Straight Cut option is intended to be used in this situation. Practice 12a Ducting 1. Cut the Duct around the blue beam in the Feature Practice drawing.
At the end of the ducting in Feature Practice file, cut a contour around the blue beam with a 5mm clearance. These features work in the same way as those above, but the direction of the cut is always perpendicular to the surface of the plate. The UCS position is not important. Corner Cut Cuts a corner from your plate by selecting near the corner that you want to cut.
The cut is placed at a default size and the Edge Processing Properties dialog box opens. Set the required size for the chamfer or type of the fillet. The distances are measured from the corner along the edge of the plate. Bevel Cut It Cuts a chamfer along one of the long edges of the plate.
A chamfer is placed along the edge and the Weld Preparation — Bevel Properties dialog box opens. Enter the required angle and leg length s for the chamfer or select the fillet type. Note that Weld preparations are not usually displayed on the model in shaded views. If you want to display them you must set the Display Type of the plate to Exact with Weld Preparations.
Split Plate by Two Points It cuts a plate into two pieces with a straight cut between two defined points. Merge Plates It combines multiple plates with common edges into a single plate. Note that each plate must share at least one edge with one of the other selected plates. The type of object that is currently placed depends on the setting of the switch. The icon next to the switch indicates which mode is active.
It is recommended that you ensure that the UCS XY plane is on the surface of the objects that you want to join before using these commands. When a bolt pattern is created, the holes to be used by the bolts are created automatically. Rectangle, 2 Points Places a rectangular pattern of bolts based on two points that define the position and spacing. A pattern of bolts is placed and the Bolts Properties dialog box opens.
Rectangle, Corner Point Places a rectangular pattern of bolts based on one corner to define the position and spacing. Rectangle, Centre Point Places a rectangular pattern of bolts based on a center point to define the position and spacing. Circular, Centre Point Places a circular pattern of bolts based on a center and radius. A circular pattern of bolts is placed and the Bolt Properties dialog box opens. This can be corrected using this command. For RHS sections this can mean that the bolt heads or nuts can be in inaccessible places.
Clear the option to have the bolt go through the section so that the Head or Nut are easily accessible on the outside of the section. If you want to place a o Number X and Number Y: Sets the number of bolts in single bolt in the that direction.
Rectangle, 2 Points instead. Select the corners of the area in o Intermediate Distance X and Y: The space between the which you want to bolts in each direction. One bolt is added to the middle of the o Changing one value recalculates the others. Total Length area. You would not normally want to change the For threaded holes, a Total sizes, but can use the other values to create the hole tolerance of zero must be set to ensure required bolt pattern in the specified area.
Set the Radius and drawings. However, a Number of Bolts. You have to recognize and ignore o Part: Select the part in which you want to change the hole.
The selected part is highlighted in red in the model. Set these other options to suit your needs. When using a Base Plate type joint, Anchors are placed automatically instead of bolts. If you have bolts or The range of Anchors includes hooked anchors of various shapes. Welds are identified in the model by pink crosses. They are only displayed in the 2D Wire Frame visual style. The selected point is used in the drawings to locate the weld note. Set to None if a lower weld is not required.
Add Connection Objects It adds additional objects to a connection. If the connection is a bolt group the grip is adjusted to include the new object s.
Remove Connection Objects Removes selected objects from a connection. If the connection is a bolt group the grip is adjusted accordingly. Practice 13a Add Bolts and Welds 1. Add Bolts and Welds to the top joints of columns C4 and D4.
However, while the situation might be uncommon in the industry, you might want to use that configuration many times. To do so you can create a Custom Connection to suit your needs. For example, a conservatory manufacturer wants to have concealed connections between members and designs a special joint for this purpose. Therefore, they create a Custom Connection. You can also use a Custom Connection when you have a common arrangement of several beams and joints that are often repeated, such as the bottom of a hip rafter.
Different people have different solutions for connecting the bottom of the hip rafter. One variation would be to create a cross beam at an angle, add a simple connection on either end of the cross beam, and then add a simple connection between the hip rafter and the cross beam.
The entire arrangement of cross beam and three joints could be created as a custom connection so that it is quick and easy to place in future. In this example the red members are part of the Custom Connection, which has a blue joint box rather than a gray one.
This can include other joints from the Connection Vault if your custom joint is a combination of common elements. When modeling your sample joint, do so in a separate file rather than in the actual project model. This file becomes a library file for custom connections. Ensure that you use good modeling practices, such as ensuring that system lines meet and assigning model roles to all of the parts.
Do not number the parts unless you want the part to have the same number when it is used, regardless of the model content. These are similar to micro-joints. Each one only creates one or two simple objects, but those objects have some simple intelligence, such as automatically putting a plate on both flanges of a beam.
In this example, you might model a plate manually on each flange, setting the size and position of the plates. However, when these plates are included in a Custom Connection, the position and size of these plates is fixed relative to the joint.
If the beam in one use was a different size to another use, the plates would be in the wrong place at least once. In this example, you would select the Plate Along Beam Flange brick. It places one or two plates on the flanges of a beam at the selected end. The plate size and position is controlled in the Properties dialog box and the gap between the plates is self-adjusting to the two flanges of the beam. When this is used in a Custom Connection and placed on beams of different sizes the two plates are always placed correctly on the flanges of each beam.
The range of Building Bricks available is going to be expanded in future releases of the software. Ensure that all of the features and joint boxes related to the objects in your joint are displayed. Each prompt starts with Select. A blue joint box should display around the sample joint.
You can model a number of custom connections in the same file as the library file, but this should not be an actual project model. It only displays the files in the path. The prompts were defined when you created the template.
The joint is placed. In the limits of the joint definition and the parts it contains, the joint works in any orientation and updates according to the members on it has been placed. If you select this option you can use most of the editing functions on any part in the joint. For example, you can move the cross beam up. You can also access the Joint Properties for any Building Bricks or full Joints that are included in the User Template and edit the properties as required, such as changing the bolt spacing.
If the Allow object modification option is not selected you cannot edit anything inside the joint. If you select the blue joint box or any part in the custom joint and select Custom Connection Properties, the User Template dialog box opens, enabling you to toggle Allow object modification on or off. After placing your first User Connection you can use the Joint Copy and Joint Group commands as required, to work efficiently when placing the joint in multiple locations.
The following example shows the same joint in four locations covering different beam sizes and with different stiffener dimensions in one position. This command can be used to create bracing in a specific area.
It has the option of creating many common configurations, such as crossed, single angle, or multiple pitch from any sections. Ensure that X is horizontal and Y is vertical. Select whether to split in one or the other direction or both into two lengths. This is used to make the bracing miss a beam at the using Offset from top or bottom of your area. In all cases ensure that the UCS is set with Z vertical. You can use the WCS for all stairs. Straight Stair It creates a straight flight of stairs with an optional landing at thetop and bottom.
This is defined using two points at either end ofthe flight of stairs the angled portion, not the landings. Enter 0 for left, 1 for middle, or 2 for right. Some of the stair treads have a fixed width so the width of the stair might be fixed until you change the tread type.
If you change the width or height, the bottom point that you have selected remains fixed and the stair adjusts about it. Size Front and Back: Select the section from which you want the stringer to be created. On installation, the target is Clear the option if you want to override the default Rise and Going values. Types 1 to 4 are made of grating or wood and can have a fixed shape and size, depending on the selected manufacturer. Types 5 to 21 are folded plates and you can define almost any dimension for them.
Types 22 to 24 are custom user-defined treads and are outside the scope of this training guide. The exact options vary depending on the tread type. These tabs work as they do for Step — General, but only apply to the top tread.
These tabs work the same as for Step — General, but only apply to the bottom When modeling a tread. Transform Elements. Create Lat Tread activates a tread at the landing the front or rear level and the Step — Top group of tabs. Saddle Stair It creates a flight of stairs with the stringers below the steps rather than at the side. It is based on four input points. A flight of stairs is created and the Saddle Stair Properties dialog box opens.
As with any macro, you can store your preferred settings in the Table so you do not have to input the settings each time. Spiral Stair This command models a complete spiral or helical stair based on a center point, height, direction, and radius. Enter F for first or bottom tread and L for top or last tread. The angle of the fixed tread does not change. The angle of the other treads and total flight are calculated based on the parameters in the Properties dialog box.
A spiral stair is created as specified and the Spiral Stair Properties dialog box opens. The spiral stair always includes a handrail on the outside edge. The inner radius is disabled if you have a center post, so you must toggle it off first to enable this setting.
If not selected an inside stringer is modeled from a twisted section. See Handrails for more information. Stair Joints There are two special joints in the connection vault for stair footings. These are used normally, but have different options to a normal base plate joint, which are appropriate to the bottom of stringers. Practice 15a Create Stairs 1. Create the stairs in the training structure. Model the stairs in the training structure according to the drawings and apply the appropriate joints at the top and bottom of the stringers.
The rail must be placed on existing sections in your model. The railing does not have to cover the full length of the selected sections. Railings can be created on slopes such as stair stringers or horizontal beams. They can be straight or curved and go around corners. They do not have to be exactly end to end, but must make a sensible and obvious path for the rail to follow.
If so, enter Yes and select a nosing point. Otherwise, enter No. The default railing is created along the specified path and the Railing Properties dialog box opens. If cleared, a fixed number of posts are created at the resulting spacing. If cleared, the entire length of the rail is used to calculate the spacing and quantity of posts, even if the space goes around a corner.
If this would cause a clash e. Enter a negative value to make the rail shorter. If using a tube for the top rail, the distance is measured to the center line of the tube. If using another section, the distance is measured to the top of the section.
You can also select to end at the last rail post. If there is only one middle rail, the balusters go to the top handrail. You can select whether to have a rail at all on the horizontal or sloping sections of the rail. Any railing created with the macro is constructed as a set of fabricated assemblies, one per each beam selected. The top rail is one length per assembly, regardless of how long that is. As with any macro, you can store your preferred settings in the Table to you do not have to input the settings each time.
If the table has an entry for the section size that is selected when placing the rail, it automatically selects that specification of railing. When selecting end points for the railing, special grips are placed at these points.
Alternatively, you can adjust the overall length of your railing by moving these grips. Select the type of joint that you want to use: Miter cut or Elbow, and complete the properties as needed. If you select Elbow, the inserted curved piece of beam matches the section of the first piece of rail. Practice 15b Add Railings 1. Add all of the railings to the training structure.
Add all of the railings to the training structure according to the drawings. Select the appropriate parameters that match the drawings where specified or shown. Try to ensure that all of the joints are smooth and avoid clashes in all of the locations. A ladder is created and the Cage Ladder Properties dialog box opens. Use the settings on this tab to do so. The Wall distance option moves the ladder away from the selected points. Select the type and properties on this tab. If selected the cage stops at the exit height and enables you to use separate settings for an exit cage.
You can also select a cage that has exits on the side of the ladder, rather than in front of the climber. As with any macro, you can store your preferred settings in the table so that you do not have to input the settings each time.
Practice 15c Add a Cage Ladder 1. Add a cage ladder to the training structure. Create the cage ladder in the training structure as shown in the drawings. Select your own properties where they are not defined in the drawings. Similar standard panels can also be used for decking.
These panels are often complex shapes and must be placed at fixed pitches. Define Cladding Area The first stage of the cladding process is to define the area to clad. This area can be any shape, but must be in a single plane. If you enter Yes, the panel length splits at the supporting beams. Always delete the selected object.
If you do not do so, a Cladding Area Object and a Polyline are created on top of each other making it difficult to select the correct item later. Define Cladding Opening If you want to have openings in your cladding you must define them as the second stage of the process.
Note that this shape must be in the same plane as the cladding area. A Cladding Opening Object is created that matches the polyline. Always delete the selected objects or you create an opening area object that is on top of the polyline. Create Claddings The third and final stage is to create the cladding in the defined areas. The cladding panels are created and the Cladding Properties dialog box opens.
The orientation and finish properties can also be set. The last panel width is reduced accordingly to fit the area. If set to Level according to slope the panel lengths vary to fit the shape of the area.
If set to Sloping Cuts the panels are cut at an angle this is always a straight cut to best fit the defined area. Therefore, it is not unusual for the cladding area to be drawn on top of existing beams. In these situations, various tools are available to help you when drawing and selecting such objects. With 3D snaps active, the Osnaps work as normal.
In 2D Osnap mode, when you hover the cursor over an Osnap point, an additional symbol displays in line with the point but on the current XY plane i.
When you select an Osnap in this mode the point is located on the XY plane. Cycle Select After drawing the polyline it might be hard to select it when it is on top of other objects. You can turn layers off to make this process easier. If you want to toggle it on, click Customization to expand the menu in the Status Bar and select Selection Cycling. Project Explorer — Model Views If you are still having trouble displaying the required objects clearly, you might want to limit what is on screen to just the relevant objects in the required area.
You can do so using Model Views. When active, a Model View hides everything but the selected area. When turned off everything is displayed. The Create Level dialog box opens. Select the arrow that is pointing in the direction that you want to use for your view and accept.
The view is added to the Model Views list in Project Explorer. Levels are activated immediately but other Model Views are not. Click the Light Bulb icon again to toggle it off and everything should be displayed. To ensure that no other settings are hiding objects and that the entire structure is displayed, click Show All Elements.
You can close Project Explorer by clicking the small X in the top right corner of the panel. Practice 15d Add Decking 1. Add some decking to the mezzanine level in the training structure.
Learn how to create different types of model elements, such as beams, plates, welds, processing or connections and how to modify their properties. Advance Steel creates intelligent connections joints that consists of basic elements and dependent elements controlled by construction rules. Skip to main content. Knowledge Network Support and learning Advance Steel.
Autodesk advance steel 2019 tutorial pdf free download
Autodesk advance steel 2019 tutorial pdf free download. Advance Steel 2020 - Essentials Metric - Training Guide
Once installed, you can start Advance Steel using one of the following procedures:. Desktop : double click on the product icon shortcut. For the English and French language installations, a content selection dialog appears at the first start-up of Advance Steel. Learn how you can launch your software after installing it on your computer.
Once installed, you can start Advance Steel using one of the following procedures: Desktop : double click on the product icon shortcut. Windows menu : All Programs Autodesk Advance Steel Advance Steel Select the country specific content for the English and French installations For the English and French language installations, a content selection dialog appears at the first start-up of Advance Steel.
Don't show this again on startup check box If checked, the Country Settings and Configurations dialog will no longer appear when starting Advance Steel. In the Management Tools application window, choose the Options tab. Parent topic: Get Started. If checked, the Country Settings and Configurations dialog will no longer appear when starting Advance Steel.
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