Using Design Accelerators in Autodesk® Inventor pptx

• Beam Column • Plate • Brakes o Shoe Brakes o Disc Brakes o Cone Brakes o Band Brakes And finally, the Design Accelerator includes an Engineer’s Handbook that contains formulae associat

Using Design Accelerators in Autodesk®

Inventor™

Ravi Akella – Autodesk, Inc

Ales Ricar – Autodesk, Inc

MA 201 - 3P Getting things in gear are easy with the Design Accelerators in Autodesk Inventor Find out how functional design capabilities allow you to design gear, belt, and chain drive systems using engineering knowledge to drive the geometry

About the Speaker:

Ravi joined Autodesk in January 2006, and is a Product Manager for Inventor at the Manufacturing Solutions Division (MSD) Formerly, Ravi was a Solutions Engineer with MSD sales team and a member of the Simulation Experts Group Ravi has experience presenting the capabilities of Autodesk Inventor to the CAD industry press, at Autodesk University 2006 and at Autodesk’s annual training event for reseller engineers Prior to joining Autodesk, Ravi worked at LMS International, makers of engineering analysis software built to work with CATIA V5 While at LMS, he gained considerable experience in kinematics and dynamics, FEA, and solid mechanics Ravi earned a Master of Science degree in Structural Mechanics from The University of Iowa in Iowa City in 2002

ravi.akella@autodesk.com

What is a Design Accelerator?

Well the first place to look was the dictionary and this is what I found…

Design

• a plan or drawing produced to show the look and function or workings of something before it is built or made

• the art or action of producing such a plan or drawing

• underlying purpose or planning: the appearance of design in the universe

• a decorative pattern

Accelerator

• a foot pedal which controls the speed of a vehicle’s engine

• an apparatus for accelerating charged particles to high velocities

• a substance that speeds up a chemical process

Even though these definitions cannot be used directly in the context of Autodesk Inventor, they guided me while in my attempts to come up with a definition that is in the context of this session

Design Accelerators are some of the most time saving and productivity enhancing features in Autodesk Inventor They empower the designer to focus on solving the design problem and save him/her time and energy by generating the geometry required for the solution Design Accelerators also allow the designer

to validate the design without needing to leave the software and needing to do lengthy hand calculations Plain and simple, Design Accelerators take the process of creating validated solutions for design

problems to warp speed leaving traditional geometry creation practices in the dust

History… Czech it out

Design Accelerators were integrated into the Autodesk Inventor product following the acquisition of MechSoft, Inc in 2004 MechSoft, Inc., based in Decin in the Czech Republic, had over 12 years as a CAD knowledge and productivity developer prior to the acquisition

Autodesk has greatly benefitted from the Decin team’s main focus, which is Mechanical Design &

Knowledge Management

Capabilities… the list is endless… almost

Design Accelerators in Autodesk Inventor facilitate the creation and validation of many commonly created components

The following is the list of components that can be generated using Design Accelerators…

• Bolted Connections

• Shafts

• Parallel spline connections

• Involute spline connections

• Key connections

• Disc Cams

• Linear Cams

• Spur Gears

• Bevel Gears

• Worm Gears

• Ball Bearings

• Roller Bearings

• Plain Bearings

• Compression Spring

• Extension Spring

• Torsion Spring

• Belleville Spring

• V-Belts

• Synchronous Belts

• Roller Chains

• Clevis Pin

• Joint Pin

• Secure Pin

• Cross Pin

• Radial Pin

As you can see the list is very extensive and all of these

component generators have in built calculators to validate them

in the context of the assembly’s design issues

Wait there’s more…

There is another set of tools in the Inventor Design

Accelerators; these are a set of mechanical calculators for the

following facets of a design…

• Welds

o Plug and Groove Welds

o Butt Welds

o Spot Welds

o Fillet Welds (Connection Plane Loads)

o Fillet Welds (Spatial Loads)

• Solder Joints

o Butt Solder Joints

o Bevel Solder Joints

o Lap Solder Joints

o Step Solder Joints

o Step Tube Solder Joints

• Hub Joints

o Slotted Hub Joints

o Separated Hub Joints

o Cone Joints

• Fits

o Tolerance

o Limits and Fits

o Press Fits

• Power Screw

• Beam Column

• Plate

• Brakes

o Shoe Brakes

o Disc Brakes

o Cone Brakes

o Band Brakes

And finally, the Design Accelerator

includes an Engineer’s Handbook that

contains formulae associated for the

following…

• Joints

• Shaft Generator

• Bearings

• Spring Generators

• Transmission Mechanisms

Generators and Calculators

• Beam and Column Calculator

• Tolerance Calculator

• Plate Calculator

As is evident from the extensive list

above, Design Accelerators have matured

over the releases to include a whole host of tools

In this session, we will focus on a particular design, an overhead hoist assembly This is a good example

of the type of design tasks that can be performed with the Design Accelerator in the material handling industry, which has traditionally represented a large and successful segment of the user base for

Autodesk Inventor

Gearing up…

The first part of the session focuses on the Spur Gear Generator portion of the Design Accelerators

In this case the Design Guide type is set to Module and the geometry for the gears is created by the generator based upon the Helix Angle, number of teeth and the selections for the Cylindrical Faces and the Start Plane

To emphasize the design validation abilities of Design Accelerators we then move to running some calculations on the gears based on loads…

The strength calculations can be done according to various different methods in this case we will use the ISO method

After setting the Power and Speed values for one of the gears and picking the desired material properties for the gears, we can proceed to set the Required Life and the Factors for Additional Load, Contact and Bending

The results will confirm is the design meets the strength requirements, if not, the geometry is modified and the modified results are just one more click away

Finally, all there is left to do is to save the newly created gear parts and the gear set assembly in the desired folders with the desired names The gears are created, correctly constrained and validated The best way to further

explore the formulae used

to determine the Factors

and do these strength

calculations is to look at the

Engineer’s Handbook built

into the Design

Accelerators and go under

Transmission Mechanisms

Generators and Calculators

-> Spur Gears Generator ->

Strength Calculations ->

Strength calculation with

CSN 01 4686, ISO 6336

and DIN 3990

Keyed in…

The focus in the second section of the session shifts to the creation and validation of keys using Design Accelerators

Selecting the reference cylinder and planes creates the key geometry The number of keys and their angular placement is also set and then it’s time to pick the type of key from the Content Center, which ties directly into the Design Accelerators

Once the keys are in place 3D grips make it possible to change the size of the keys and rotate the

placement about the shaft axis

Yup… you guessed it right, the calculations to validate the key connections come next

The Power and Torque values used here are the same as those used in the Spur Gear calculations After setting the materials for the keys, shaft and hub and setting the Loading Conditions, it’s time to run the calculations

The Type of Strength Calculation is set to Design Key Length if the intent is to have the key length

computed based on passing the strength requirements This is a clear case where the validation of the design is driving the geometry for the solution instead of being a back-end checking process

The formulae used in these calculations can

be explored in more detail right in Inventor

using the Engineer’s Handbook in Design

Accelerators by going to Joints -> Movable

Joints -> Key Generator

Shaft!

The Shaft Component Generator in Design Accelerators has seen considerable changes in Inventor

2008 The new user interface makes the workflow for creating and validating shaft designs a lot more intuitive

The various sections are added and the diameters and the lengths are determined based on the gear and bearing geometry

The loads used to perform the shaft calculations come from the Results of the Spur Gears Component Generator calculations These results are output as an html file that can be opened in a browser window and referred to during the shaft calculations

The shaft calculations are based on formulae that can be found

in the Engineer’s Handbook under Shaft Generator -> Shaft

calculations formulas

Splining…

The alternative to creating key connections is to create a spline connection between a shaft and the gears In this case, the Parallel Spline Connection Generator in the Design Accelerators is used to create the spline geometry, the cuts in the hub to accommodate the splines and validate the spline connection for strength

After picking the selections for the shaft and hub references and modifying the length of the splines using the 3D grips, the calculations can be done to check the splines for strength

The Power value is the same as the one used before for Gear and Key connection calculations The speed in rpm is added in, the safety factor is set and the material properties are set The calculation type can be changed to Length or Diameter Design to create geometry that satisfies strength requirements

As seen in the other component generator sections

the formulae used to do the strength calculations are

in the Engineer’s Handbook at Joints -> Movable

Joints -> Parallel Splines Generator

To solve or not to solve…

The components created using the Design Accelerator can be set to solve manually or automatically This means changes needed to accommodate any modifications made by the user can be set to being

automatically computed or manually This choice may have a performance implication and must be chosen wisely to achieve maximum productivity

In the case of the Parallel Spline Component, any changes made to the shaft diameters will cause

changes in the spline geometry which can be manually or automatically solved

The component can be set to automatically solve by right-clicking on it in the browser or the model

display and selecting the Component -> Automatic Solve or Manual Solve option

As we part…

We have looked at Design Accelerators to create geometry, validate the components for strength

requirements and explore the underlying formulae sourced from the Engineer’s Handbook in order to create a gear box for an overhead hoist assembly

There are many such applications where different components and calculators in Design Accelerators can be leveraged to create complete and validated designs much faster than traditional modeling and validation methods