Autodesk inventor 2015 frame generator free

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Print Book. How To Make Frames. Sheet Metal Tools. Home Decor. Decoration Home. Sheet Metal tools – YouTube. Mechanical Movement. Avion Rc. Metal Bending Tools. Robotics Projects. Star Wars Droids. Cool Woodworking Projects. Table Frame. Steel Table. Auto Design. Car Design. Solidworks Tutorial. Autocad Drawing. Audi R8. Graphic Card. How To Make Frames. Sheet Metal Tools. Home Decor. Decoration Home. Page Layout. Sheet Metal tools – YouTube.

Metal Bending Tools. Robotics Projects. Star Wars Droids. Cool Woodworking Projects. Popular Mechanics. Table Frame. Steel Table. Solidworks Tutorial. Auto Design. Audi R8. Industrial Design Sketch. Creative Outlet. Restaurant Design. The book also includes a project at the beginning to help those new to Inventor quickly understand key interface conventions and capabilities.

In addition, there is more information on Inventor LT, new practice drawings at the end of each chapter to reinforce lessons learned, and thorough coverage of all of Inventor\’s new features. The author\’s extensive experience across industries and his expertise enables him to teach the software in the context of real-world workflows and work environments.

Mastering Inventor explores all aspects of part design, including sketching, basic and advanced modeling techniques, working with sheet metal, and part editing. Here are just a few of the key topics covered:.

The book\’s detailed discussions are reinforced with step-by-step tutorials, and readers can compare their work to the downloadable before-and-after tutorial files. In addition, you\’ll find an hour of instructional videos with tips and techniques to help you master the software. Mastering Inventor is the ultimate resource for those who want to quickly become proficient with Autodesk\’s 3D manufacturing software and prepare for the Inventor certification exams.

Master Mechanical Design the Autodesk Inventor Way If you\’re a professional or student in any manufacturing or design field, this expert guide gives you everything you need to make the most of the industry-leading 3D mechanical design software.

Complemented with straightforward explanations, real-world examples, and practical tutorials, this comprehensive guide to Autodesk Inventor and Inventor LT gives you the know-how to become proficient quickly with Autodesk\’s 3D manufacturing software. Coverage includes: Getting started with Autodesk Inventor Creating 2D and 3D sketches and features Conquering all aspects of part design and part editing Working with sketching, sheet metal, and basic and advanced modeling techniques Getting the most out of Inventor for building large assemblies Mastering the basic concepts of parametric 3D design Using productivity-boosting tools and data exchange Making sense of the Frame Generator and the Inventor Studio Using tube-and-pipe and cable-and-harness routing tools Preparing for the Inventor certification exam Master Autodesk Inventor and Inventor LT Understand Key Interface Conventions and Capabilities Benefit from Drawings that Reinforce Lessons Learned Grasp the Topic in the Context of Real-World Workflows Prepare for the Inventor Certification Exams.

Curtis Waguespack, an Inventor Expert Elite and Autodesk Certified Instructor, has taught Inventor in the classroom and consulted with and supported manufacturing and design firms in industries ranging from aerospace to consumer products and industrial machinery. He uses Inventor daily in a real-world environment to design and document various product types, and maintains the popular \”From the Trenches\” Inventor blog inventortrenches.

He has served as lead author on multiple editions of Mastering Autodesk Inventor. He has taught Inventor in the classroom and has consulted with and supported manufacturing and design firms in industries ranging from aerospace, to consumer products, to industrial machinery. Curtis uses Inventor daily in a real world design environment and has used Inventor to design a wide range of manufactured products. Customer Reviews, including Product Star Ratings help customers to learn more about the product and decide whether it is the right product for them.

Instead, our system considers things like how recent a review is and if the reviewer bought the item on Amazon. It also analyzed reviews to verify trustworthiness. A comprehensive guide to Autodesk Inventor and Inventor LT This detailed reference and tutorial provides straightforward explanations, real-world examples, and practical tutorials that focus squarely on teaching Autodesk Inventor tips, tricks, and techniques. Here are just a few of the key topics covered: Assemblies and subassemblies Real-world workflows and offering extensive detail on working with large assemblies Weldment design Functional design using Design Accelerators and Design Calculators Everything from presentation files to simple animations to documentation for exploded views Frame Generator Inventor Studio visualization tools Inventor Professional\’s dynamic simulation and stress analysis features Routed systems features piping, tubing, cabling, and harnesses The book\’s detailed discussions are reinforced with step-by-step tutorials, and readers can compare their work to the downloadable before-and-after tutorial files.

This is true when you create frame members as well, and since it is so easy to create members, it may not be obvious that you need to save them after the initial creation. Pay attention to the Save reminders and limit the amount of data you risk losing between saves.

Keep in mind that you needn\’t have used iLogic to use the iLogic Design Copy tool for copying frames. You can find the iLogic Design Copy tool by closing all of your Inventor files and then going to the Tools tab and looking on the iLogic panel.

Use the Assemblies list panel in the iLogic Design Copy dialog box to select the frame assembly you want to copy. All files referenced by the frame assembly will be selected in the other lists. You can then specify a target folder to copy to and specify a naming prefix or suffix as needed. Once you start the copy process, the frame files will be copied, and the internal references will be updated. Note that there are a couple of limitations to be aware of.

First, you cannot create more than one frame subassembly in the same assembly. Another limitation is that you can\’t use copies of the frame generated with the assembly Copy tool in other assemblies and maintain Frame Generator functionality.

Frame Generator initially creates frame members the same length as the selected geometry. When you add end treatments, the length is adjusted to make the member longer or shorter. To accomplish this, the structural profiles are created with a From-To extrusion between two work planes, as shown in Figure When the part is first created, the start plane is coincident with the XY plane, and the end plane is set to the initial length. When an end treatment is added, the start or end plane is moved to shorten or lengthen the member.

The parameter relationships that control the length are complex. Three parameters drive the length, two parameters are driven by those parameters to determine the length, a reference parameter reports the overall length, and a parameter is used in the BOM, as indicated in Figure The process for inserting frame members can be broken down into three basic steps.

You select the frame member profile this comes from Content Center , select the placement geometry for placing the frame members, and then adjust the orientation of the frame members.

The left side of the Insert dialog box, shown in Figure These fields are progressive from top to bottom, with one updating when changes are made to the one above it. However, the update behavior varies depending on the field selected. If you select a new standard, the first family is automatically selected. If you select a new family, the size is not automatically selected. After you have selected the placement geometry, you can change the position and orientation of the member.

A thumbnail of the profile is displayed in a grid of radio buttons that control the position of the member, as shown in Figure These positions are based on the rectangular bounds of the profile.

As a result, the corner positions of a pipe that\’s 1 inch in diameter are the same as they are in a 1-inch-byinch square tube. You can fine-tune the placement position by entering values in the horizontal and vertical offset fields.

You can also rotate the member. For example, food processing equipment frequently has horizontal members rotated 45 degrees so spilled food doesn\’t build up on top of square tubing. The Mirror Frame Member button is shown in the lower-right corner of Figure This button is used for profiles that don\’t have rotational symmetry, such as C-channel and angle iron. The orientation changes affect all the members of a select set. Depending on the geometry, it might be more efficient to use a batch select tool and change the orientation of a few members afterward, or you might want to select only those members that have a similar orientation.

Since structural shapes are extruded, Frame Generator needs a method for determining the extrude direction. When an edge is selected, Frame Generator uses the closest endpoint as the start of the extrusion. Depending on where you select an edge, the same radio button can cause the member to be in a different position. The thumbnail is the view of the profile looking at the XY plane. It takes some practice to get a good feel for the relationship between how an edge is selected and the behavior of the radio buttons.

Once you understand this relationship, you will be able to predict the behavior and use it to increase your productivity.

Although you can use 3D sketches to base a frame on, you don\’t need to do this. You can create 3D solids or surfaces to create a frame base. Once you have a 3D shape, you can then add 2D sketches to the various faces and use those sketches as selection edges as well.

So, you don\’t need to be well versed in the 3D sketch tools to create 3D frames. When you\’re using a custom profile with an alternate insertion point defined, the Custom Point control is enabled. This adds another insertion point to the nine standard ones. The custom point is not displayed in the thumbnail image, so you should confirm that the preview is in the expected position relative to the selected edge. When selecting placement geometry, you can select edges of 3D models and visible sketch lines, or you can select two endpoints.

For instance, if you had a cube-shaped base solid, you would use the edges to place vertical and horizontal frame members. To place diagonal cross bracing, you would use the corner endpoints. When you use the default Insert Members On Edges option, you can select edges and lines for placement references. Using edges for placement allows you to insert multiple members at once.

When you use the Insert Members Between Points option, you select two vertices or endpoints. This method allows you to place only one member at a time.

The most common placement method is by selecting lines and edges. This allows the most flexibility in geometry selection and the use of batch select tools.

There are two philosophies for placing frame members. Some people like to place frame members individually, making sure each one is in the correct position and orientation. Others like to place as many members as possible and then edit them as necessary. The method you choose will depend on the type of models you work with, how much effort you put into setting up the skeleton models, and, most importantly, the way you like to work.

Frame Generator has several tools for selecting geometry. Multi Select is the default selection mode. The standard methods for creating a Multi Select selection allow you to select individual edges, use selection windows, and use the Shift and Ctrl keys to add and remove objects to or from the selection. In addition to Multi Select, two other select modes are available in the context menu shown in Figure Chain Select automatically selects all lines and edges that are tangentially connected to the selection.

Chain Select will not follow past a point that has multiple lines or edges, even if one of them is tangential. For instance, if you have a rectangular sketch profile with rounded corners, you can use Chain Select and select just one of the lines or arcs, and all of the others will be added automatically. By contrast, if you have the same profile in a 3D shape, Chain Select will not automatically select the edges because each edge of the 3D shape has multiple edge intersections.

Sketch Select selects all the lines in a sketch. You can select the sketch in the browser or click a line in the graphics window. For instance, if you have a ladder-shaped sketch, you can use Sketch Select and automatically select the rungs and rails all at once. The Merge option is enabled when there are connected lines or edges. Merge combines the selections into one member. Although Merge is useful when you want to have one continuous member, you cannot add end treatments to merged members.

To create an elementary frame, you\’ll use a prepared file that has been set up for you. If you have not already downloaded the Chapter 15 files from www. The prepared file you\’ll be using is an assembly file consisting of just two parts and the frame subassembly.

One of the parts contains an unconsumed sketch that you will use to place frame members. The frame members will be automatically placed in the predefined frame subassembly.

When creating your own frame designs from scratch, you\’ll be asked to supply the name and locations for the frame subassembly and skeleton files. In this design, you\’ll add frame members to be embedded in a monument base to support a sign plate:. Use the radio buttons in the Orientation area of the Insert dialog box to orient the frame member so it matches up with the square cutout in the base. Select the other four vertical sketch lines as well.

Note that the two end members are not centered in the cutouts. Click the OK button to generate the frame members; then click the OK button in the Frame Member Naming dialog box to accept the defaults. Click the Insert Frame button again and click the bottom half of one of the outside vertical sketch lines. Use the radio buttons in the Orientation area to orient the frame member so it matches up with the square cutout.

Select the bottom half of the other outside vertical sketch line and notice that the frame member preview does not match the cutout. Using the Orientation radio buttons, you\’ll notice that none of the solutions allows both members to match the cutouts. Select the sketch line again, this time toward the top, and you\’ll see that this flips the orientation to provide the correct solution.

Uncheck the Prompt For File Name check box found along the bottom of the dialog box. This suppresses the filenaming dialog prompt and automatically accepts the default naming for the frame members. In this simple example you explored the basics of placing frame members, noting the use of the Ctrl key on the keyboard to remove selections. Unfortunately, I don\’t have it. You would be surprised that we actually agree more than we disagree.

Inventor team has been trying very hard to change the negative perception for the past few years. I hope you are seeing the change in the product itself recenltly. Certainly there is still a lot of work remaining. The team is fully aware of it. The team has a lot of enthusiasts like me trying our best to help customers and do the right things. Jingyi is a product manager now. He is trying to understand this particular request and thinking about how to enhance it.

Please feel free to contact him directly. Back to the Copy issue, I\’ve attached a couple of documents on the various methods to copy assemblies. Inventor Forum. Share your knowledge, ask questions, and explore popular Inventor topics. Turn on suggestions. Auto-suggest helps you quickly narrow down your search results by suggesting possible matches as you type. Showing results for. Search instead for. Did you mean:. This page has been translated for your convenience with an automatic translation service.

This is not an official translation and may contain errors and inaccurate translations. Autodesk does not warrant, either expressly or implied, the accuracy, reliability or completeness of the information translated by the machine translation service and will not be liable for damages or losses caused by the trust placed in the translation service. Back to Inventor Category.

Back to Topic Listing Previous Next. Message 1 of Message 2 of Inventor Professional. Message 3 of Message 4 of My exact workflow is listed out below but there are a few things to note first: 1.

My frame generator models always follow a similar setup with the skeleton geometry, etc. My workflow is this: 1. I open the top most assembly of my required design in design assistant. I use the \”find files\” option at the bottom of the window to locate the drawing files.

Good luck. Preview file.

 
 

 

[Solved: frame generator – Autodesk Community

 

The Miter end treatment makes angle cuts on two members. You can miter multiple members by applying the end treatment to each pair of members. You can add a gap between the members by entering a value in the gap input box.

The default gap is split between the two members. If you want the gap to be taken from just one member, you can use the Miter Cut At One Side button, and the gap will be taken from the first member you selected. The default selections cut along an angle, resulting in full-face contact between the members, as shown in Figure Bi-sect Miter splits the angle between the members.

The vertical member needs to be mitered to fit. The vertical member still needs a miter to trim the other side, so the miter is repeated with the same settings, this time choosing the member on the right and the vertical member, as shown in Figure The resulting miter, shown in Figure Practice creating miter gaps and two- and three-member miters to understand the process.

This end treatment is the only one that can trim multiple members at once. When trimming or extending to a face, you select the members you want to trim and then select the cutting face. A separate end treatment feature is created for each frame member.

If you edit or delete the end treatment for a particular member, it does not affect the other members. You would select the vertical member for the member to trim and the top face of the horizontal member as the face to trim to. This end treatment can also be used to create miters.

Applying miter end treatments to already mitered frame members results in a costly complex joint cut for all three members. Remember, you can select multiple frame members to trim to the same face.

Experiment with this file as you like—there is no set solution to the final frame outcome. Be aware that when using the Trim tools in Frame Generator, the short end is always the one to be discarded. This end treatment trims or extends both members so they are flush. The first selection is made flush to the second selection, and the second selection butts up to the first.

These tools are often used together to achieve a specific result. The Notch tool cuts one frame member to match the other. It uses the profile to create a cutting surface. By default you can\’t create an offset, so the cut is an exact match. This is simply a cut operation, so the frame member is not shortened or extended before the cut.

If you have authored a notch profile into a custom frame member library file, you can select the Apply Notch Profile check box; however, if the member does not contain a notch profile definition, the check box is grayed out. If you were to notch the shorter I-beam shown in Figure If the members don\’t intersect, the notch will have no effect.

Because of this, it\’s often best to create a notch as a secondary end treatment. For example, if you had two intersecting frame members as shown in Figure Use the flanged beams to create notches in the T-shaped members.

Notch shapes are driven by manufacturing requirements. Typically, the shape is simplified to reduce cost, and there may be a gap between the members to allow for tolerances. You can also define notch profiles in custom frame member definitions. By default, frame members are initially assigned the length of the reference edge or the distance between selected points.

However, you will often need to change the length. Much of the time you will simply use another frame member and one of the Extend or Trim tools. So if you applied a mm extension value, the frame member would grow mm on both ends for a total of mm. If you enter a negative value, the frame member will be shortened. You should spend time planning your frame design to minimize the number of end treatments required because each end treatment is an opportunity for the model to fail if a change is made.

For example, if you create a skeleton to the inside dimensions of a frame, you can offset members during placement so the members butt against one another without adding end treatments. When you use the Insert Frame tool, Inventor creates a new part file for each new frame member you insert. This allows you to create separate part files that allow separate end treatments.

For instance, you might initially insert two identical frame members but then choose to miter both ends of one but only one end of the other. Having two separate part files allows this. However, there are often times when you might want to reuse the same frame member over and over.

In these cases you would prefer not to have separate part files and could use the Reuse tool to ensure that the same part file is being reused as needed. To see the Reuse tool in action, follow these steps:.

Click the longer sketch line to use as the Placement selection, but be sure to select it at the end of the line furthest from the existing short member near the sketched arc.

Choose the member you just created and then click the Reverse Member Direction button; then click the OK button to see the change. Notice the direction of the holes again. Click the Miter tool and select the ends of the two original frame members when they come to an intersection and then click Apply. Still in the Miter tool, click the remaining end of the short member and the corresponding end of the new long frame member even though it is already mitered and then click the OK button.

Choose the remaining straight sketch line for the Placement selection and then click the OK button to create the new frame member. Click the Change Reuse button, select the new short frame member, set Orientation Angle to degrees, and then click the OK button. Click the Miter tool and select the unmitered end of the original longer member and the corresponding end of the shorter member; then click the OK button to create the miter. The Reuse and Change Reuse tools offer powerful options for working with repetitive frame members in your frame designs.

Keep these tools in mind when working with frame design, and you can likely simplify your frame bill of materials and save yourself some work along the way. When you\’ve finished exploring the Reuse and Change Reuse tools, you can close this file without saving changes and continue to the next section.

Maintaining existing assemblies can be time-consuming. Frame Generator provides several tools that help streamline the process of modifying end treatments and determining how frames were originally designed.

The Remove End Treatments tool removes all end treatments from a selected frame member. You can also select multiple members for the batch removal of end treatments.

This is handy if you need to change the end treatments on a few members or if you have to rebuild a frame. You can find the Remove End Treatments tool in the Frame drop-down list indicated by the small black arrow on the Frame panel of the Design tab. See Figure The Frame Member Information tool is used to query frame members. It displays the family and size information, mass properties, and material.

This is a useful tool because it quickly gives you information about a member. For example, it can help you quickly determine the difference in the wall thickness of two similarly sized hollow tubes. Since the tool filters for only frame members, you can use it at any level of the assembly. You can find the Frame Member Information tool in the Frame drop-down list indicated by the small black arrow found on the Frame panel of the Design tab.

The Refresh tool is a Content Center tool. It checks Content Center for the latest revision of the members in the frame. If a newer version is available, it will prompt you to replace it. End treatments are retained during refresh, but other features, such as holes, are not carried over to the new member. You can find the Refresh tool in the Frame drop-down list indicated by the small black arrow on the Frame panel of the Design tab.

Frame Generator uses an algorithm to create default filenames. You can rename the files as you create them, when prompted by the Frame Member Naming dialog. But often this slows the design process and requires you to enter information you may not currently know.

Another approach is to let Inventor apply the filenames automatically. To do so, you can uncheck the filenaming prompt check box in the Insert Frame dialog box, and Inventor will create the filenames and save the files to the location specified when the frame subassembly and skeleton files were initially created.

It is a good idea to set the frame subassembly and skeleton filenames and locations to use a well-planned naming scheme, whether you specify the frame member names or let Inventor do so. If you decide to accept the default filenames, it is a good idea to use the BOM Editor to set the part number iProperty for each file to match your standard. In this way, you have a unique identifier for each part member. You can set two identical frame members to have the same part number so they are rolled up together in the BOM.

Using part numbers you can think of them as mark numbers , rather than the filenames, to manage the frame members provides a more flexible and real-world workflow for the typical frame design. Once part numbers have been defined, you can also set the assembly browser to use the part number rather than the filenames.

This allows you to quickly index individual frame parts more easily. Do this by selecting the Assembly tab, clicking the drop-down list on the Productivity panel, and choosing the Rename Browser Nodes tool. Although Frame Generator can create frames and therefore a lot of part files quickly, once the frame is modeled, you should slow down and take the time to manage part numbers. This allows your design to be managed properly in the detailing and revision stages. These calculators are design accelerator tools that can do a simple stress analysis.

The Beam And Column Calculator, for instance, can analyze a single beam or column, but it assumes a uniform cross section, so it does not take into account holes or end treatments.

If you have Inventor Professional or Inventor Simulation, you can use the Frame Analysis tools that are part of those packages. You can find the Beam And Column Calculator tool in the Frame drop-down list indicated by the small black arrow found on the Frame panel of the Design tab. As with other design accelerator dialog boxes, the message pane at the bottom and the calculation results pane on the right side can be opened and closed by clicking the small symbols.

You can drag the splitter bar double gray lines to resize the panes, or you can double-click the splitter bar to open or close the panes. Take a moment to open this file from the Chapter 15 directory to become familiar with it. You will use this file to complete the exercise steps presented later. In this assembly, the Beam And Column Calculator might be used to calculate the loading on the power roller supports.

When one of the gold tubes is selected, the calculator automatically loads the section properties from Content Center, as shown in Figure Although Content Center has most of the section properties, be aware that some data is missing. You can use several methods for determining the properties.

Inventor has a tool to calculate the properties of a closed sketch profile. If you want to use this tool for the section properties of a frame member, you can open the frame member, place a sketch on one end, and project the face. Once you have the profile, select the Inspect tab, and click the Region Properties tool on the Measure panel.

Select the profile you want to analyze and click Calculate. The basic region properties for any closed loop are calculated.

You can then calculate the rest of the properties based on those results. The region properties are calculated with respect to the sketch origin. Depending on the profile, you may have to edit the sketch coordinate system to locate the sketch origin at the center of the profile.

Another option for calculating section properties is to use the Section button in the Beam And Column Calculator. When you click the button, a list of geometric shapes appears. When you select a shape, a dialog box like Figure The calculated properties assume sharp corners and constant thickness, so the results won\’t be accurate for profiles with tapered flanges but may be good enough for many applications.

The Flip Section button is used to change the orientation of the x- and y-axes. The z-axis is always in the direction of the extrusion. Gravity is always in the negative y-axis direction, so it is important to make sure the calculation coordinates match the assembly coordinates. If the beam is at an angle, you have a couple of options for handling gravity. You can place a copy of the beam horizontally in the assembly.

If you want to ignore the effect of gravity, there is an option on the Beam Calculation tab to turn the gravity load off. Both Beam and Column calculations are available. The Beam calculations focus on deflection based on loads and supports. The Column calculation checks for buckling. You can select Beam, Column, or both calculation types. The Calculation tabs are turned on and off based on the selections.

The default material properties do not correspond to a material style and are not linked to the style library in any way. Instead, these materials provide you with a starting point and an example of the required properties. You can enter properties for a particular material, or you can select one of the generic materials listed.

When you check the box, a dialog box appears with materials such as gray cast iron, steel, and aluminum. These properties can be used for initial calculations, but for more accurate results, you should enter the properties for the particular alloy you are using.

Follow these steps to enter the member data into the dialog box:. Recall that this button can be found in the drop-down list indicated by the small black arrow on the Frame panel of the Design tab. If necessary, click the padlock icon for the Section Length row in the table, thereby unlocking it for editing.

Change the value to 12 inch. In the Rectangle dialog box, enter the tubing dimensions. Enter 1. Then click the OK button. Click the check box next to the Material field to launch the Material Types dialog box.

Select Steel and click the OK button. Leave this dialog open because you will use it in the next set of steps, where you\’ll work with loads and supports. The coordinate system alignment is correct for this example.

So in this case, gravity could be ignored, but having the correct orientation simplifies adding the loads and interpreting the results. The dialog box should look like Figure Note that all the section properties except Shear Displacement Ratio are calculated. This property is optional for the calculations. Comparing the calculated values with the original ones, Section Area and Moments Of Inertia are close but higher.

The Beam Calculation tab, shown in Figure The Engineer\’s Handbook hidden away in the Power Transmission panel drop-down list; it\’s called Handbook contains the equations used in the calculations. You might want to review those equations before using the calculator. All of the controls can be accessed by using the buttons at the top or by right-clicking and choosing them from the context menu in the browser pane area. The drop-down menu switches the browser between Loads view and Supports view.

The controls, shown in Table Adds a torque load—a twisting force around the z-axis. Two equal and opposite torque loads are required. The Options dialog box, shown in Figure By default, the loads and supports dynamically update to maintain the same size as the view scale changes.

You can turn off the automatic update and set a static scale value. The Options dialog box is the same whether it is launched from the Loads control or Supports control. Each load or support can be edited in the browser by double-clicking or by clicking the browse … button.

A Properties dialog box displays controls for specifying the location, size, and direction of the force. The Calculation Properties group, as shown in Figure The Use Density check box adds gravity as a load. This is selected by default. The Use Shear Displacement Ratio check box is used when calculating the twist angle caused by torsional loads.

The value is determined by the profile shape. It is also called the form factor of shear. This check box is selected by default. The default setting for Number Of Beam Divisions is Increasing the number of divisions can result in improved accuracy for longer beams. You should experiment with different values to see whether the number of divisions causes a significant change in the results.

Mode Of Reduced Stress has two options for modeling the stress distribution. The Huber-Mises-Hencky HMH method is based on the maximum-energy-distortion criterion, and the Tresca-Guest method is based on the maximum-shearing-stress criterion. The HMH method is the default selection. The Results pane on the right side of the Beam Calculation tab updates when you click the Calculate button. Warnings will appear in the lower pane if the calculation indicates that stresses are too high.

For the conveyor example, the support will be welded to the frame at one end and unsupported at the other. The power roller weighs pounds, and the torque is 40 pound-feet. The torque causes the power roller to twist between the supports. The edge of the flat is 1. This means the reaction force at that point is pounds. Both the weight and the reaction force are split between the two sides.

Follow these steps to explore the results and calculation workflow:. Enter 10 inches for the distance and 75 pounds-force for the force. This is the maximum distance for the power roller. Click the OK button to close the Radial Force dialog box. Enter Click the Calculate button and compare the reduced stress to the yield strength of the specified material. Note that the forces are displayed in the graphics window. If you hover over a force arrow on the model, a tool tip displays the information.

You can drag the force to a different position, or you can double-click the force to display the properties dialog box. On the Beam Graphs tab, the Graph Selection pane allows you to select the results you want to display.

The selected graph displays in the bottom of the Graph area. At the top of the Graph area is a schematic of the beam, supports, and loads. You can drag the supports and loads to different positions to update them. If you double-click a support or load, the properties dialog box displays so you can directly edit the data. The Calculate button is not available on the Beam Graphs tab, so you need to switch back to the Beam Calculation tab to update the results.

The Beam Graphs tab is primarily intended for reviewing results. Twenty-two graphs are available on the tab. This example is a pretty simple analysis. You should experiment with other loads torques and bending moments and support types and then view the results on the graphs. The Column Calculation tab checks for column buckling.

In the Loads area, you enter the axial load and the safety factor and select a coefficient for the end loading conditions. When you click the … button, a dialog box appears with four end conditions. If you have different end conditions, you should enter the proper coefficient from a reference book. You shouldn\’t need to enter any data in the Column area. The length, section area, and least moment of inertia are carried over from the Model tab.

The reduced length value is calculated by multiplying the length by the end coefficient. For example, imagine that during transport, the frame shifts and the power roller supports slam into the trailer wall.

The power roller was removed during shipping, so the supports take all the force from the impact, estimated at 4, pounds evenly distributed across the four supports.

Set the axial load to 1,pound force, and click Calculate to determine whether the supports will buckle. When you click the Results button in the upper-right corner of the dialog box, an HTML page appears with all the data, calculation results, and graphs.

You can save or print this file for your records. The File Naming button, found next to the Results button in the upper-right corner of the dialog box, allows you to specify the calculation\’s filename. When you click the OK button to exit the Beam And Column Calculator dialog box, a subassembly file is created in the assembly file.

This subassembly file is just a container for the calculations, allowing you to access them again at any point. A browser node is created for the calculations. To edit the results, simply right-click the browser node and choose Edit Using Design Accelerator.

Frame Generator\’s frame member library is integrated with Content Center. The authoring and publishing process is similar to that used to create any custom Content Center files. Since Frame Generator requires specific modeling techniques, the authoring process will make some changes to the model and the parameters to ensure that all of the required parameters are included.

The authoring process for a frame member is similar to component authoring. The Structural Shape Authoring tool, located on the Part-Modeling panel bar, is used to prepare the part for publishing. The tool identifies the geometry used for placement, sets the parameters, and modifies the part so Frame Generator can use it.

This example uses a rubber bumper iPart file like might be attached to frames to guard against impact. In the iPart table there are parameters to control the dimensions and three sizes defined. If this were a true frame member profile, the engineering properties moments of inertia and so on might need to be calculated, and therefore that information would be set up as well.

Since this isn\’t a load-bearing part, those properties aren\’t required. To explore the authoring process, follow these steps:. From the Manage tab, locate the drop-down list on the Author panel and then click the Structural Shape button. When the authoring tool starts, everything is blank. Once a category is selected, the dialog box will update with the appropriate controls. Because this is an unusual part, select the Other category, as shown in Figure Frame Generator looks in the Structural Shapes category only, so you have to select one of the standard categories or create a new one in the Content Center Editor.

You can\’t add a category through the authoring tool, so you have to add the category to Content Center before authoring. Next when you completed the frame you can start the clumbersomme work off making individual drawings off every element off that frame. It is maby nice to have mudbox in the suit.

A good working frame generator would make more peaple happy. Go to Solution. Solved by JDMather. It would be nice to have a built in generator for things like caps and reinforcement gussets, but I suspect most users have a limited number of sizes they need and even if not limited it would be pretty easy to create iParts for the purpose.

The price in comparison with other programs that do not communicate with Inventor are much more expensive. Summe 2. I asked them many times for a solution but until now I dint received any reply. When I get acquainted with the program I let you know and I will inform the Belgian representatives.

This program looks very impressive, and quite a lot of work went into it I would love to hear how well it will work for you, Solidworks has a very good frame generator, I believe it is called Solidworks Weldments. Has easy placement of gussets, caps, easy to change sizes, cut list, and it generates a part file, instead of an assembly file. The skeleton sketch in Solidworks is much easier to build also. Inventor has terrible 3d sketching tools, or a lack therof.

Solidworks has Inventor beat in a lot of areas. I use both. The biggest thing Solidworks does is make their software intuitive. Its not as advanced as some other software gear more toward surfacing work, but Inventor and Solidworks go head to head in machine design and Solidworks is out ahead by a good margin right now. I cannot figure out what you see as difference between Inventor and SolidWorks 3D sketching.

They both work logically and fine for me! I am a certified Solidworks Professional. I learned Inventor in school, and have been using it professionally off and on for 6 years. The main tools that both packages have for 3d sketching are there, yes, however Solidworks does make it far easier to use.

How much Solidworks training or experience do you have? My technique for 3D sketching is quite different in both SolidWorks and Inventor than the technique that I see most people use. Attach a completed Inventor 3D sketch here or even a SolidWorks example and I will demonstrate how I might create the sketch.

At work right now, but will try to come up with something later. Maybe I am unfamiliar with the 3d sketch tools in INventor, but in Solidworks I really like the constraints.

All I can see is to make the line coincident to a plane, or perpendicular to another line. Maybe I need to go to the settings and turn something on to have more 3d sketching tools, but they seem basic in Inventor.

I was able to create some nice gun stock designs for Remington Arms in Solidworks, and tried Inventor for similar projects and couldn\’t get anywhere with it. I wasn\’t even aware Autodesk had a certification program like Solidworks. There is a reduced cost \”Open Doors\” certification day coming up on Oct 2. I think that we all have to come to the conclusion that at the least the frame generator in Inventor has some issues.

Is not bad at all. For the it is all a matter of copy and paste. If you start a project the first day they are already breeding in your neck and wanted to see the results. If possible with a bom and the construction drawings spick and span ready for the workshop.

SO you can forget iPart libraries. I work 7days a week and about 10 hours a day. And last but not least for my friend Raygyver I know 3d sketch in Inventor is a pain in the proverbial! All his videos are very nice. Take a look at it and maybe it will release you of your agony. I finally installed ASI-Profile. It works like a charm!!!

IT is adaptive it is intuitive it is parametric it makes correct bill off materials even if you change lengths of profiles during the design. AND if you put two connection plates on a profile the profile length automatically adapt itself and it does it also in the bill off material.

I will continuing working and experimenting with it and I will post you some updates in due course. For those who need bolted structural design in Inventor this is the way to go. It pays itself in one job. Even though that I was the moron they pulled me trough and the job was finish in a minimum of time.

Send me a mail on francis. Take care. Inventor Forum. Share your knowledge, ask questions, and explore popular Inventor topics. Turn on suggestions. Auto-suggest helps you quickly narrow down your search results by suggesting possible matches as you type. Showing results for.

 
 

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