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1. FDM Basics
1. FDM Basics


* [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/design-for-manufacturing?autoplay=true&u=41910388 Design for manufacturing (2m  11s)]
* [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/design-for-manufacturing?autoplay=true Design for manufacturing (2m  11s)]


* [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/what-is-fdm?autoplay=true&u=41910388 What is FDM? (2m  32s)]
* [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/what-is-fdm?autoplay=true What is FDM? (2m  32s)]


* [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/thermoplastics?autoplay=true&u=41910388 Thermoplastics (4m  36s)]
* [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/thermoplastics?autoplay=true Thermoplastics (4m  36s)]


2. CAD and CAM
2. CAD and CAM


* CAD vs. CAM (2m  27s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cad-vs-cam?autoplay=true&u=41910388]
* CAD vs. CAM (2m  27s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cad-vs-cam?autoplay=true]


* CAM basics in Cura (7m  5s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cam-basics-in-cura?autoplay=true&u=41910388]
* CAM basics in Cura (7m  5s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cam-basics-in-cura?autoplay=true]


* CAM basics in MakerBot Print (5m  52s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cam-basics-in-makerbot-print?autoplay=true&u=41910388]
* CAM basics in MakerBot Print (5m  52s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cam-basics-in-makerbot-print?autoplay=true]


* Using third-party GCode Viewer (1m  50s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/using-third-party-gcode-viewer?autoplay=true&u=41910388]
* Using third-party GCode Viewer (1m  50s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/using-third-party-gcode-viewer?autoplay=true]


3. Bases and Supports
3. Bases and Supports


* Exploring build plate surfaces (2m  12s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-build-plate-surfaces?autoplay=true&u=41910388]
* Exploring build plate surfaces (2m  12s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-build-plate-surfaces?autoplay=true]


* Exploring build plate adhesion (2m  53s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-build-plate-adhesion?autoplay=true&u=41910388]
* Exploring build plate adhesion (2m  53s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-build-plate-adhesion?autoplay=true]


* Understanding overhangs and support (2m  50s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/understanding-overhangs-and-support?autoplay=true&u=41910388]
* Understanding overhangs and support (2m  50s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/understanding-overhangs-and-support?autoplay=true]


* Creating supportless designs (1m  40s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-supportless-designs?autoplay=true&u=41910388]
* Creating supportless designs (1m  40s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-supportless-designs?autoplay=true]


4. Features and Options
4. Features and Options


* The body of a 3D print (3m  4s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/the-body-of-a-3d-print?autoplay=true&u=41910388]
* The body of a 3D print (3m  4s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/the-body-of-a-3d-print?autoplay=true]


* Optimizing line width (3m  33s)[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/optimizing-line-width?autoplay=true&u=41910388]
* Optimizing line width (3m  33s)[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/optimizing-line-width?autoplay=true]


* Understanding layer height and resolution (2m  52s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/understanding-layer-height-and-resolution?autoplay=true&u=41910388]
* Understanding layer height and resolution (2m  52s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/understanding-layer-height-and-resolution?autoplay=true]


* Creating small details (1m  28s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-small-details?autoplay=true&u=41910388]
* Creating small details (1m  28s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-small-details?autoplay=true]


* Achieving accuracy and fit (2m  10s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/achieving-accuracy-and-fit?autoplay=true&u=41910388]
* Achieving accuracy and fit (2m  10s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/achieving-accuracy-and-fit?autoplay=true]


* Planning for strength and flexibility (1m  20s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/planning-for-strength-and-flexibility?autoplay=true&u=41910388]
* Planning for strength and flexibility (1m  20s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/planning-for-strength-and-flexibility?autoplay=true]


* Exploring color options (1m  50s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-color-options?autoplay=true&u=41910388]
* Exploring color options (1m  50s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-color-options?autoplay=true]


5. Optimizing with Cura
5. Optimizing with Cura


* Support material and build plate adhesion (4m) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/support-material-and-build-plate-adhesion?autoplay=true&u=41910388]
* Support material and build plate adhesion (4m) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/support-material-and-build-plate-adhesion?autoplay=true]


* Shells, infill, top, and bottom layers (2m  49s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/shells-infill-top-and-bottom-layers?autoplay=true&u=41910388]
* Shells, infill, top, and bottom layers (2m  49s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/shells-infill-top-and-bottom-layers?autoplay=true]


* Small details (57s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/small-details?autoplay=true&u=41910388]
* Small details (57s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/small-details?autoplay=true]


6. Optimizing with MakerBot
6. Optimizing with MakerBot


* Support material and rafts (1m  43s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/support-material-and-rafts?autoplay=true&u=41910388]
* Support material and rafts (1m  43s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/support-material-and-rafts?autoplay=true]


* Line width and wall thickness (59s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/line-width-and-wall-thickness?autoplay=true&u=41910388]
* Line width and wall thickness (59s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/line-width-and-wall-thickness?autoplay=true]


* Shells, infill, roofs, and floors (2m  44s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/shells-infill-roofs-and-floors?autoplay=true&u=41910388]
* Shells, infill, roofs, and floors (2m  44s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/shells-infill-roofs-and-floors?autoplay=true]


7. Assemblies
7. Assemblies


* Designing assemblies (3m  46s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/designing-assemblies?autoplay=true&u=41910388]
* Designing assemblies (3m  46s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/designing-assemblies?autoplay=true]


* Print in place strategies (1m  51s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/print-in-place-strategies?autoplay=true&u=41910388]
* Print in place strategies (1m  51s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/print-in-place-strategies?autoplay=true]


8. Design a Hinged Box
8. Design a Hinged Box


* Setting up your project (1m  3s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/setting-up-your-project?autoplay=true&u=41910388]
* Setting up your project (1m  3s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/setting-up-your-project?autoplay=true]


* Sketching the box (2m  59s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/sketching-the-box?autoplay=true&u=41910388]
* Sketching the box (2m  59s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/sketching-the-box?autoplay=true]


* Navigation basics (58s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/navigation-basics?autoplay=true&u=41910388]
* Navigation basics (58s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/navigation-basics?autoplay=true]


* Modeling the box (3m  41s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/modeling-the-box?autoplay=true&u=41910388]
* Modeling the box (3m  41s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/modeling-the-box?autoplay=true]


* Sketching the hinge (3m  39s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/sketching-the-hinge?autoplay=true&u=41910388]
* Sketching the hinge (3m  39s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/sketching-the-hinge?autoplay=true]


* Modeling the hinge (3m  16s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/modeling-the-hinge?autoplay=true&u=41910388]
* Modeling the hinge (3m  16s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/modeling-the-hinge?autoplay=true]


* Separating the knuckles (7m  42s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/separating-the-knuckles?autoplay=true&u=41910388]
* Separating the knuckles (7m  42s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/separating-the-knuckles?autoplay=true]


* Creating components and assembling a joint (2m  15s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-components-and-assembling-a-joint?autoplay=true&u=41910388]
* Creating components and assembling a joint (2m  15s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-components-and-assembling-a-joint?autoplay=true]


* 3D printing with Cura (2m  56s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/3d-printing-with-cura?autoplay=true&u=41910388]
* 3D printing with Cura (2m  56s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/3d-printing-with-cura?autoplay=true]


* 3D printing with MakerBot Print (3m  33s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/3d-printing-with-makerbot-print?autoplay=true&u=41910388]
* 3D printing with MakerBot Print (3m  33s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/3d-printing-with-makerbot-print?autoplay=true]


Conclusion
Conclusion


* Next steps (41s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/next-steps?autoplay=true&u=41910388]
* Next steps (41s) [https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/next-steps?autoplay=true]




Line 144: Line 144:


* Product Design
* Product Design
[https://www.linkedin.com/learning/search?keywords=Product%20Design&u=41910388]
[https://www.linkedin.com/learning/search?keywords=Product%20Design]


* Rapid Prototyping
* Rapid Prototyping
[https://www.linkedin.com/learning/search?keywords=Rapid%20Prototyping&u=41910388]
[https://www.linkedin.com/learning/search?keywords=Rapid%20Prototyping]


* FDM [https://www.linkedin.com/learning/search?keywords=FDM&u=41910388]
* FDM [https://www.linkedin.com/learning/search?keywords=FDM]
* Modeling
* Modeling
[https://www.linkedin.com/learning/search?keywords=Modeling&u=41910388]
[https://www.linkedin.com/learning/search?keywords=Modeling]
* 3D Modeling
* 3D Modeling
[https://www.linkedin.com/learning/search?keywords=3D%20Modeling&u=41910388]
[https://www.linkedin.com/learning/search?keywords=3D%20Modeling]


Viewers of this course
Viewers of this course

Revision as of 22:58, 29 May 2020

Contents

Design for Additive Manufacturing: FDM

INSTRUCTOR

Kacie Hultgren


Introduction

1. FDM Basics

2. CAD and CAM

  • CAD vs. CAM (2m 27s) [1]
  • CAM basics in Cura (7m 5s) [2]
  • CAM basics in MakerBot Print (5m 52s) [3]
  • Using third-party GCode Viewer (1m 50s) [4]

3. Bases and Supports

  • Exploring build plate surfaces (2m 12s) [5]
  • Exploring build plate adhesion (2m 53s) [6]
  • Understanding overhangs and support (2m 50s) [7]
  • Creating supportless designs (1m 40s) [8]

4. Features and Options

  • The body of a 3D print (3m 4s) [9]
  • Optimizing line width (3m 33s)[10]
  • Understanding layer height and resolution (2m 52s) [11]
  • Creating small details (1m 28s) [12]
  • Achieving accuracy and fit (2m 10s) [13]
  • Planning for strength and flexibility (1m 20s) [14]
  • Exploring color options (1m 50s) [15]

5. Optimizing with Cura

  • Support material and build plate adhesion (4m) [16]
  • Shells, infill, top, and bottom layers (2m 49s) [17]
  • Small details (57s) [18]

6. Optimizing with MakerBot

  • Support material and rafts (1m 43s) [19]
  • Line width and wall thickness (59s) [20]
  • Shells, infill, roofs, and floors (2m 44s) [21]

7. Assemblies

  • Designing assemblies (3m 46s) [22]
  • Print in place strategies (1m 51s) [23]

8. Design a Hinged Box

  • Setting up your project (1m 3s) [24]
  • Sketching the box (2m 59s) [25]
  • Navigation basics (58s) [26]
  • Modeling the box (3m 41s) [27]
  • Sketching the hinge (3m 39s) [28]
  • Modeling the hinge (3m 16s) [29]
  • Separating the knuckles (7m 42s) [30]
  • Creating components and assembling a joint (2m 15s) [31]
  • 3D printing with Cura (2m 56s) [32]
  • 3D printing with MakerBot Print (3m 33s) [33]

Conclusion

  • Next steps (41s) [34]


RELATED TO THIS COURSE

Exercise Files See all

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Course details

1h 47m Beginner + Intermediate Released: 1/18/2018

Fused deposition modeling (FDM), also known as fused filament fabrication (FFF), is a common type of 3D printing. Whether you are using FDM for prototyping or producing end-use parts, a design for manufacturing process will ensure your parts are easy to manufacture on FDM printers. Join Kacie Hultgren for a comprehensive overview of FDM design principles. Optimize your parts by understanding key concepts like orientation, tolerance, and support material. Learn how to use programs such as Cura and MakerBot Print to visualize your design before 3D printing, and achieve accuracy, fit, and strength. In chapter eight, Kacie uses Fusion 360 to take you step by step through a sample project—a hinged box—that puts these design strategies into action.

Learning objectives

  • What is FDM?
  • Thermoplastics and FDM
  • CAD and CAM
  • Creating supportless designs
  • Optimizing for orientation
  • Achieving accuracy and fit
  • Visualizing your design with Cura and MakerBot Print
  • Designing assemblies
  • Working with Fusion 360
  • 3D printing your design

Skills covered in this course

  • Product Design

[35]

  • Rapid Prototyping

[36]

[38]

  • 3D Modeling

[39]

Viewers of this course

raz soffer Filippo Scarpetta Jayapal Koli

  • 4,567 members* like this course
  • 13,560* people watched this course

What they do

  • Research Fellow
  • Student
  • Engineer
  • University Professor

Where they work

  • Walmart Walmart
  • Siemens Siemens
  • US Navy US Navy
  • Nokia Nokia
  • Ford Motor Company Ford Motor Company

Instructor

Kacie Hultgren

Kacie Hultgren Multidisciplinary Designer

[40]

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In this video

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