CAD and Digital Manufacturing Specialization

Start Date: 10/11/2020

Course Type: Specialization Course

Course Link:

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About Course

The future of making is here, bringing with it radical changes in the way things are designed, made, and used. And it’s disrupting every industry. With the right knowledge and tools, this disruption is your opportunity—whether you're an entrepreneur, designer, or engineer. Today’s dominant technology trends—cloud computing, mobile technology, social connection, and collaboration—are driving businesses and consumers alike to explore profoundly different ways to design, make, and use things. This kind of industry transformation has happened before, but the pace of change is now much faster. In today’s competitive landscape, anyone can be an innovator—and it’s all about who innovates first. Through this specialization, you will learn the foundations of product innovation and digital manufacturing while developing your technical skills within Autodesk® Fusion 360™. Plus, by completing this Specialization, you’ll unlock an Autodesk Credential as further recognition of your success! The Autodesk Credential comes with a digital badge and certificate, which you can add to your resume and share on social media platforms like LinkedIn, Facebook, and Twitter. Sharing your Autodesk Credential can signal to hiring managers that you’ve got the right skills for the job and you’re up on the latest industry trends like digital manufacturing.

Course Syllabus

Intro to Digital Manufacturing with Autodesk Fusion 360
Autodesk Fusion 360 Integrated CAD/CAM/CAE
3D Model Creation with Autodesk Fusion 360
Engineering Design Process with Autodesk Fusion 360

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Course Introduction

Start your Career in Digital Manufacturing. Practice your CAD/CAM/CAE skills and learn about industry trends, while creating your own drone. CAD and Digital Manufacturing Specialization In this course taught by Professor Evangelista Locatelli and Capstone Project student Gianluigi Martini, we introduce you to CAD and its applications in design and manufacturing industries. You will learn about the most popular CAD CAD software and the tools that you need to get started with very little explanation. We will show you how to apply CAD in a real-world context to solve technical problems related to machining, tooling, and quality control. We will also show you how to apply CAD to solve problems related to the design and manufacturing process. You will even practice exporting CAD files for final use in another CAD program. We’ll also show you how to use free software to practice the skills taught in this course. This is the second course in the Digital Manufacturing & Design Technology specialization that looks at the many facets of manufacturing’s “Fourth Revolution,” aka Industry 4.0. The specialization has been designed to provide you with the knowledge and the confidence to make (correct) decisions in the manufacturing process. The first course discussed CAD as a tool for CAD-designers. This second course focuses on manufacturing’s use of free software to practice the skills taught in this course. What you’ll learn: - How to use free software to practice the skills taught in this course - How to obtain free software to practice the skills taught in this course - How to find free software to practice the skills taught

Course Tag

Computer-Aided Design (CAD) Autodesk Manufacturing Processes Sustainable Design

Related Wiki Topic

Article Example
Digital manufacturing There are many different tooling processes that digital manufacturing utilizes. However, every digital manufacturing process involves the use of computerized numerical controlled machines (CNC). This technology is crucial in digital manufacturing as it not only enables mass production and flexibility, but it also provides a link between a CAD model and production. The two primary categories of CNC tooling are additive and subtractive. Major strides in additive manufacturing have come about recently and are at the forefront of digital manufacturing. These processes allow machines to address every element of a part no matter the complexity of its shape.
Digital manufacturing Digital manufacturing is an integrated approach to manufacturing that is centered around a computer system. The transition to digital manufacturing has become more popular with the rise in the quantity and quality of computer systems in manufacturing plants. As more automated tools have become used in manufacturing plants it has become necessary to model, simulate, and analyze all of the machines, tooling, and input materials in order to optimize the manufacturing process. Overall, digital manufacturing can be seen sharing the same goals as computer-integrated manufacturing (CIM), flexible manufacturing, lean manufacturing, and design for manufacturability (DFM). The main difference is that digital manufacturing was evolved for use in the computerized world.
Digital manufacturing Digital manufacturing systems often incorporate optimization capabilities to reduce time, cost, and improve the efficiency of most processes. These systems improve optimization of floor schedules, production planning, and decision making. The system analyzes feedback from production, such as deviations or problems in the manufacturing system, and generates solutions for handling them.
Cloud-based design and manufacturing manufacturing, enhancing digital manufacturing and design innovation in distributed and collaborative environments, and adapting to rapidly changing
CAD/CAM in the footwear industry 3D CAD/CAM is the core technology for shoe sole mould in the footwear industry and develops towards specialization.
Threading (manufacturing) Often subtractive, additive, deformative, or transformative methods are combined in whatever ways are advantageous. Such multidisciplinary manufacturing falls under classifications including rapid prototyping, desktop manufacturing, direct manufacturing, direct digital manufacturing, digital fabrication, instant manufacturing, or on-demand manufacturing.
CAD data exchange In a true PLM environment, CAD to CAM data exchange must provide for more than the transfer of geometry. Product Manufacturing Information, whether generated by the designer for use by manufacturing, or generated by the manufacturing organization for use by design, must be a part of the data exchange system. STEP-NC was designed to carry GD&T and other PMI through CAD and CAM into a CNC.
Digital modeling and fabrication Digital modeling and fabrication is a process that joins design with production through the use of 3D modeling software or computer-aided design (CAD) and additive and subtractive manufacturing processes. 3D printing falls under additive, while machining falls under subtractive. These tools allow designers to produce material digitally, which is something greater than an image on screen, and actually tests the accuracy of the software and computer lines.
Product and manufacturing information Product and manufacturing information, also abbreviated PMI, conveys non-geometric attributes in 3D computer-aided design (CAD) and Collaborative Product Development systems necessary for manufacturing product components and assemblies. PMI may include geometric dimensions and tolerances, 3D annotation (text) and dimensions, surface finish, and material specifications. PMI is used in conjunction with the 3D model within model-based definition to allow for the elimination of 2D drawings for data set utilization.
CAD/CAM in the footwear industry Benefits of CAD/CAM in the mould manufacturing are:
Digital manufacturing Manufacturing engineers use 3D modeling software to design the tools and machinery necessary for their intended applications. The software allows them to design the factory floor layout and the production flow. This technique lets engineers analyze the current manufacturing processes and allows them to search for ways to increase efficiency in production before production even begins.
CAD/CAM in the footwear industry CAD/CAM in the footwear industry is the use of computers and graphics software for designing and grading of shoe upper patterns and, for manufacturing of cutting dies, shoe lasts and sole moulds. CAD/CAM software is a PC-based system, which is made up of program modules. Today, there are 2D and 3D versions of CAD/CAM systems in the shoe industry.
CAD data exchange Many companies use different CAD systems internally and exchange CAD data with suppliers, customers and subcontractors. Transfer of data is necessary so that, for example, one organization can be developing a CAD model, while another performs analysis work on the same model; at the same time a third organization is responsible for manufacturing the product. The CAD systems currently available in the market differ not only in their application aims, user interfaces and performance levels, but also in data structures and data formats therefore accuracy in the data exchange process is of paramount importance and robust exchange mechanisms are needed.
Comparison of CAD, CAM and CAE file viewers This is an overview of notable viewers for files, that are produced by Computer aided design (CAD), Computer-aided manufacturing (CAM) and Computer-aided engineering (CAE) applications.
CAD Overlay The first version of CAD Overlay was demonstrated at A/E/C trade show in Chicago in May 1988. Subsequent versions include CAD Overlay ESP, CAD Overlay GSX, and CAD Overlay LFX.
CAD Overlay CAD Overlay is a commercial software application for raster-to-vector translation in 2D computer-aided design (CAD) and drafting — available between 1988 and 1996 as a third-party application for AutoCAD and other CAD systems.
Open manufacturing Open manufacturing may also include digital modeling and fabrication and computer numeric control (CNC) of the machines used for production through open source software and open source hardware.
CAD standards CAD Standards are a set of guidelines for the way Computer-aided drafting (CAD), or (CADD) Computer Aided Design and Drawing, drawings should appear, to improve productivity and interchange of CAD documents between different offices and CAD programs, especially in architecture and engineering.
Digital prototyping Digital Prototyping also enables product teams to share detailed assembly instructions digitally with manufacturing teams. While paper assembly drawings can be confusing, 3D visualizations of digital prototypes are unambiguous. This early and clear collaboration between manufacturing and engineering teams helps minimize manufacturing problems on the shop floor.
CAD data exchange The exchange process targets primarily the geometric information of the CAD data but it can also target other aspects such as metadata, knowledge, manufacturing information, tolerances and assembly structure.