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Design for Additive Manufacturing with Metals

Learn key foundational knowledge to design for Additive Manufacturing (AM) with metals.

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From December 13 - January 3, Non-Members save 20% and Members save 25% on any Self Study course (this offer excludes Learning Paths). 

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This Self Study course is designed to be taken at your convenience and on your own schedule. You have 365 days from the time of purchase to finish the course.

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ASME’s Design for Additive Manufacturing with Metals for Engineers (DfAM) course is one of the first commercially available Additive Manufacturing e-learning solutions dedicated specifically to designing metal parts for production/manufacturing. The course provides the key foundational knowledge to properly evaluate Additive Manufacturing (AM) as a potentially viable technology solution coupled with the in-depth technical knowledge necessary to efficiently shepherd AM parts from design, through post-processing and eventually into the market through three use cases: replication, adaptation, and optimization.

Importantly, this course was developed in a collaboration between ASME and industry-renowned Additive Manufacturing expert Dr. Timothy W. Simpson. Tim Simpson is a Professor of Engineering Design and Manufacturing Engineering at Penn State University in the Mechanical and Nuclear Engineering department, as well as Co-Director of Pennsylvania State University’s Center for Innovative Materials Processing through Direct Digital Deposition (CIMP 3D) Laboratory, which is a leader in additive manufacturing applied research and technology education.

Topics covered in this course include:

  • Design for additive manufacturing
  • Replicate Adapt Optimize™ methodology with AM parts
  • Processing & Post-processing
  • Business Considerations
  • Preparing for Build
  • Advanced Manufacturing Flight Check™

By participating in this course, you will be able to:

  • Leverage Replicate Adapt Optimize™ Methodology
  • Adopt the Iterative Loop to determine the most effective AM workflow for your situation and goals based on the case (replicate, adapt, or optimize)
  • Incorporate the Triple Ps of AM design: Product, Process, and Business Case Plan
  • Execute a final Advanced Manufacturing Flight Check™ validation of a design before final build utilizing a simulated checklist

Additional possibilities

  • Customize the design for additive manufacturing workflow to best design a part
  • Make a business case for the use of additive manufacturing for a specific application
  • Set expectations regarding additive manufacturing possibilities
  • Estimate the cost to fabricate and finish a part
  • Recognize the impact of design engineers in this field on everything from individual part performance to general innovation, to overall profitability.

Who Should Attend

Engineering teams at design and manufacturing firms, as well as individuals.

This course was designed for early to mid-career engineers, including design engineers, materials engineers, manufacturing engineers, and others with an interest in design for additive manufacturing with metals.


A certificate of completion with 1 CEU (10 PDHs) will be issued to registrants who successfully complete the course.


Course participants are expected to:

  • Be familiar with and have access to CAD and know how to use it
  • Have some awareness of analysis tools (i.e., FEA, CFD, GD&T methods)
  • Be familiar with traditional manufacturing processes (i.e., machining/milling, casting, forging)
  • Have basic knowledge of engineering and intellectual property ethics, such as ASME’s Code of Ethics of Engineers
  • Ideally, have some experience with 3D printing - plastics/polymers (however, this is not required)
  • Ideally, have access to a 3D metal printer (however, this is not required)
  • Ideally, have access to a 3D metal printer (however, this is not required)
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Included in these bundles
Design for Additive Manufacturing with Metals Professional Package
Includes:
Design for Additive Manufacturing with Metals, AM Manufacturability: Laser Powder Bed Fusion, Design for Additive Manufacturing with Metals Case Studies Package
Price if purchased separately: $425
You save: $130
List Price: $295
Outline

Module 1 – New Possibilities with Additive Manufacturing

  • Course Introduction
  • Benefits of AM
  • The Challenges of Additive Manufacturing
  • Use Cases and Applications of Additive Manufacturing

Module 2 – Design for Additive Manufacturing and the Design Engineer

  • Additive Manufacturing and the Design Engineer
  • Design for Additive Manufacturing (DfAM) Use Cases

Module 3 – Replicate with Additive Manufacturing

  • Why Replicate with Additive Manufacturing
  • When to Replicate?

Module 4 – Preparing a Part for Additive Manufacturing

  • Using CAD Software to Create 3D Models
  • The Build Plan
  • The Process Plan

Module 5 – Post Process Planning

  • Post Process Planning
  • A Case Study Analysis of Additive Manufacturing Post-Processing
  • Safety Considerations

Module 6 – Business Considerations

  • Business Considerations
  • Improving Consistency
  • Reducing Risk & Monitoring Results

Module 7 – Adapt for Additive Manufacturing

  • Deciding When to Adapt for Additive Manufacturing
  • Adapt for Additive Manufacturing: Techniques, Constraints, and Common Risks
  • Building a Better Business Case for Additive Manufacturing
  • Case Study: Oil and Gas Latticed Part

Module 8 – Optimize for Additive Manufacturing

  • Introduction: Optimizing Designs for Additive Manufacturing
  • Optimize for Additive Manufacturing: Software Takes the Lead
  • Weighing the Pros and Cons of an Optimized Design
  • Optimizing Case Studies: Oil/Gas Component and Race Car Uprigh

Module 9 – Preparing for Build

  • Preflight Checklist
  • Course Recap

Final Exam

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Course Developer

Timothy W. Simpson, Ph.D.

Professor of Engineering Design and Manufacturing

Timothy W. Simpson, Ph.D., is the Paul Morrow Professor of Engineering Design and Manufacturing Engineering at Pennsylvania State University.

More Information

Format

Self Study

100% online independent learning at your own pace. Learners can enroll and start at any time. Courses are accessible for 365 days.
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