Autodesk Inventor 2020 Advanced Part Modeling Mixed Units
Download Autodesk Inventor 2020 Advanced Part Modeling Mixed Units PDF/ePub or read online books in Mobi eBooks. Click Download or Read Online button to get Autodesk Inventor 2020 Advanced Part Modeling Mixed Units book now. This website allows unlimited access to, at the time of writing, more than 1.5 million titles, including hundreds of thousands of titles in various foreign languages.
Autodesk Inventor 2020: Advanced Part Modeling (Mixed Units)
Author: ASCENT - Center for Technical Knowledge
language: en
Publisher:
Release Date: 2019-07-11
Autodesk(R) Inventor(R) 2020: Advanced Part Modeling is the second in a series of guides on the Autodesk(R) Inventor(R) software that is published by ASCENT. The goal of this guide is to build on the skills acquired in the Autodesk Inventor: Introduction to Solid Modeling learning guide by taking users to a higher level of productivity when designing part models using the Autodesk Inventor software. In this guide, the user considers various approaches to part design. Specific advanced part modeling techniques covered include: multi-body design, advanced lofts, advanced sweeps, coils, generative shape design, surface modeling, and Freeform modeling. Material aimed at increasing efficiency includes: iFeatures for frequently used design elements, iParts for similar designs, and how to work with imported data. The guide also covers some miscellaneous drawing tools, such as: custom sketches symbols, working with title blocks and borders, and documenting iParts. Topics Covered Advanced model appearance options 2D and 3D sketching techniques Multi-body part modeling Advanced geometry creation tools (work features, area lofts, sweeps, and coils) Analysis tools Generative shape design using Shape Generator Creating and editing basic surfaces, importing surfaces, and surface repair tools iFeatures and iParts Importing data from other CAD systems and making edits Working with AutoCAD DWG files Freeform modeling Emboss and Decal features Advanced Drawing tools (iPart tables, surfaces in drawing views, and custom sketched symbols) Adding notes with the Engineer's Notebook Prerequisites Access to the 2020.0 version of the software (or later). The practices and files included with this guide are not compatible with prior versions. Future software updates that are released by Autodesk may include changes that will not be reflected in this guide. The material assumes a mastery of Autodesk Inventor basics, as taught in Autodesk(R) Inventor(R) Introduction to Solid Modeling. Users should know how to create and edit parts, use work features, create and annotate drawing views, etc. The use of Microsoft Excel is required for this guide.
Autodesk Inventor 2020: Advanced Assembly Modeling (Mixed Units)
Author: ASCENT - Center for Technical Knowledge
language: en
Publisher:
Release Date: 2019-07-11
The Autodesk(R) Inventor(R) 2020: Advanced Assembly Modeling guide builds on the skills acquired in the Autodesk Inventor 2020: Introduction to Solid Modeling and Autodesk Inventor 2020: Advanced Part Modeling guides to take you to a higher level of productivity when creating and working with assemblies. You begin by focusing on the Top-Down Design workflow. You learn how tools are used to achieve this workflow using Derive, Multi-Body Design, and Layouts. Other topics include model simplification tools, Positional and Level of Detail Representations, iMates and iAssemblies, Frame Generator, Design Accelerator, and file management and duplication techniques. A chapter has also been included about the Autodesk(R) Inventor(R) Studio to teach you how to render, produce, and animate realistic images. Topics Covered Applying motion to existing assembly constraints using Motion and Transitional Constraints. Introduction of the Top-Down Design technique for creating assemblies and its components. Tools for Top-Down Design, such as associative links, adaptive parts, multi-body and layout design, derived components, and skeleton models. Creating Positional Representations to review motion, evaluate the position of assembly components, or document an assembly in a drawing. Using Shrinkwrap and other model simplification tools to create a part model that represents an overall assembly. Creating Level of Detail Representations to reduce the clutter of large assemblies, reduce retrieval times, and substituting models. Using the Design Accelerator to easily insert standard and customizable components and features into your model. Creating rendered realistic images and animations of parts and assemblies using Autodesk Inventor Studio and the Video Producer. Prerequisites Access to the 2020.0 version of the software, to ensure compatibility with this guide. Future software updates that are released by Autodesk may include changes that are not reflected in this guide. The practices and files included with this guide are not compatible with prior versions (i.e., 2019). The class assumes mastery of Autodesk Inventor basics as taught in Autodesk(R) Inventor(R) Introduction to Solid Modeling. In addition, Autodesk(R) Inventor(R) Advanced Part Modeling knowledge is recommended. The use of Microsoft(R) Excel is required for this guide.
Algorithm-Driven Truss Topology Optimization for Additive Manufacturing
Author: Christian Reintjes
language: en
Publisher: Springer Nature
Release Date: 2022-02-01
Since Additive Manufacturing (AM) techniques allow the manufacture of complex-shaped structures the combination of lightweight construction, topology optimization, and AM is of significant interest. Besides the established continuum topology optimization methods, less attention is paid to algorithm-driven optimization based on linear optimization, which can also be used for topology optimization of truss-like structures. To overcome this shortcoming, we combined linear optimization, Computer-Aided Design (CAD), numerical shape optimization, and numerical simulation into an algorithm-driven product design process for additively manufactured truss-like structures. With our Ansys SpaceClaim add-in construcTOR, which is capable of obtaining ready-for-machine-interpretation CAD data of truss-like structures out of raw mathematical optimization data, the high performance of (heuristic-based) optimization algorithms implemented in linear programming software is now available to the CAD community.