Online Maker Training through LinkedIn Learning: Difference between revisions

From sandbox
Jump to navigation Jump to search
No edit summary
No edit summary
 
(23 intermediate revisions by the same user not shown)
Line 1: Line 1:
Contents


Design for Additive Manufacturing: FDM


INSTRUCTOR
[[Category:Training]]
=Online Maker Training through LinkedIn Learning =


Kacie Hultgren
LinkedIn Learning (formerly Lynda.com) is a leading provider of online training video courses. The entire LinkedIn Learning library is available to the UMD community at no charge. While many of the LinkedIn Learning courses are focused on learning business applications such as Microsoft Excel or Google Sheets, there are a number of training modules on maker-related subjsts like 3d modeling in Autodesk Fusion 360, Designining for 3d Printing, and others.
 
To make use of LinkedIn Learning training material, you need to log in using your UMD directory ID and authenticate through the UMD sign on page. Since this material is somewhat hidden away, we've added this page to list LinkedIn Learning classes and videos that may be of interest. This page consists almost entirely of content taken from the LinkedIn Learning site and links directly to that site for viewing the lessons.
 
== Learning Related to Sandbox Prototyping Studio ==
 
 
===''Course:'' Design for Additive Manufacturing: FDM===
 
INSTRUCTOR: Kacie Hultgren
 
Length: 1h 47m
Level: 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====
<div style="column-count:2;-moz-column-count:2;-webkit-column-count:2">
 
* 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
 
</div>
 
<!---
====Course Outline====
 
 
Introduction
 
=====1. FDM Basics=====
 
*[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 What is FDM? (2m  32s)  ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/thermoplastics?autoplay=true Thermoplastics (4m  36s)  ]
 
=====2. CAD and CAM=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cad-vs-cam?autoplay=true  CAD vs. CAM (2m  27s)  ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cam-basics-in-cura?autoplay=true  CAM basics in Cura (7m  5s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/cam-basics-in-makerbot-print?autoplay=true  CAM basics in MakerBot Print (5m  52s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/using-third-party-gcode-viewer?autoplay=true  Using third-party GCode Viewer (1m  50s) ]
 
=====3. Bases and Supports=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-build-plate-surfaces?autoplay=true  Exploring build plate surfaces (2m  12s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-build-plate-adhesion?autoplay=true  Exploring build plate adhesion (2m  53s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/understanding-overhangs-and-support?autoplay=true  Understanding overhangs and support (2m  50s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-supportless-designs?autoplay=true  Creating supportless designs (1m  40s) ]
 
=====4. Features and Options=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/the-body-of-a-3d-print?autoplay=true  The body of a 3D print (3m  4s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/optimizing-line-width?autoplay=true  Optimizing line width (3m  33s)]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/understanding-layer-height-and-resolution?autoplay=true  Understanding layer height and resolution (2m  52s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-small-details?autoplay=true  Creating small details (1m  28s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/achieving-accuracy-and-fit?autoplay=true  Achieving accuracy and fit (2m  10s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/planning-for-strength-and-flexibility?autoplay=true  Planning for strength and flexibility (1m  20s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/exploring-color-options?autoplay=true  Exploring color options (1m  50s) ]
 
=====5. Optimizing with Cura=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/support-material-and-build-plate-adhesion?autoplay=true  Support material and build plate adhesion (4m) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/shells-infill-top-and-bottom-layers?autoplay=true  Shells, infill, top, and bottom layers (2m  49s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/small-details?autoplay=true  Small details (57s) ]
 
=====6. Optimizing with MakerBot=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/support-material-and-rafts?autoplay=true  Support material and rafts (1m  43s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/line-width-and-wall-thickness?autoplay=true  Line width and wall thickness (59s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/shells-infill-roofs-and-floors?autoplay=true  Shells, infill, roofs, and floors (2m  44s) ]
 
=====7. Assemblies=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/designing-assemblies?autoplay=true  Designing assemblies (3m  46s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/print-in-place-strategies?autoplay=true  Print in place strategies (1m  51s) ]
 
=====8. Design a Hinged Box=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/setting-up-your-project?autoplay=true  Setting up your project (1m  3s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/sketching-the-box?autoplay=true  Sketching the box (2m  59s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/navigation-basics?autoplay=true  Navigation basics (58s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/modeling-the-box?autoplay=true  Modeling the box (3m  41s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/sketching-the-hinge?autoplay=true  Sketching the hinge (3m  39s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/modeling-the-hinge?autoplay=true  Modeling the hinge (3m  16s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/separating-the-knuckles?autoplay=true  Separating the knuckles (7m  42s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/creating-components-and-assembling-a-joint?autoplay=true  Creating components and assembling a joint (2m  15s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/3d-printing-with-cura?autoplay=true  3D printing with Cura (2m  56s) ]
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/3d-printing-with-makerbot-print?autoplay=true  3D printing with MakerBot Print (3m  33s) ]
 
=====Conclusion=====
 
*[https://www.linkedin.com/learning/design-for-additive-manufacturing-fdm/next-steps?autoplay=true  Next steps (41s) ]
 
--->
 
====Course Outline====


<div style="column-count:3;-moz-column-count:3;-webkit-column-count:3">


Introduction
Introduction
Line 12: Line 155:
1. FDM Basics
1. FDM Basics


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


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


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


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


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


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


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


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


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


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


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


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


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


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


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


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


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


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


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


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


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


7. Assemblies
7. Assemblies


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


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


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


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


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


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


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


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


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


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


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


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


Conclusion
Conclusion


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


</div>


<!---
RELATED TO THIS COURSE
RELATED TO THIS COURSE


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


Exercise Files See all
Exercise Files See all
Line 144: Line 289:


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


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


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


Viewers of this course
Viewers of this course


raz soffer Filippo Scarpetta Jayapal Koli
raz soffer Filippo Scarpetta Jayapal Koli
*4,567 members* like this course
*[https://www.linkedin.com/learning/instructors/kacie-hultgren?u=41910388 4,567 members* like this course
*13,560* people watched this course
*13,560* people watched this course


Line 183: Line 328:
Multidisciplinary Designer  
Multidisciplinary Designer  


[https://www.linkedin.com/learning/instructors/kacie-hultgren?u=41910388]


Related courses
--->
 
===Course: Learning 3D Printing===
 
Length: 1h 16m
 
[https://www.linkedin.com/learning/learning-3d-printing Learning 3D Printing]
 
 
===''Course'': Rapid Prototyping for Product Design===
 
Length: 1h 38m
 
[https://www.linkedin.com/learning/rapid-prototyping-for-product-design Rapid Prototyping for Product Design]
 
 
 
===''Course'': Design Foundations: Physical Materials===
 
Length: 1h 31m
 
[https://www.linkedin.com/learning/design-foundations-physical-materials Design Foundations: Physical Materials]
 
 
===Course: Additive Manufacturing: Optimizing 3D Prints===
 
Length: 1h 27m
 
[https://www.linkedin.com/learning/additive-manufacturing-optimizing-3d-prints-2 Additive Manufacturing: Optimizing 3D Prints]
 
 
 
===''Course'': Additive Manufacturing: Short Run Production===
 
Length: 1h
 
[https://www.linkedin.com/learning/additive-manufacturing-short-run-production Additive Manufacturing: Short Run Production]
 
== Learning Related to Sandbox Digital Media Studio ==


Course: Learning 3D Printing
===''Course:'' Making Video 2: Teach Something===
[https://www.linkedin.com/learning/making-video-2-teach-something/welcome Making Video 2: Teach Something]


1h 16m
===''Course:'' Learning Video Production and Editing===
[https://www.linkedin.com/learning/learning-3d-printing?u=41910388]
[https://www.linkedin.com/learning/learning-video-production-and-editing-3/ Learning Video Production and Editing]
COURSE Course POPULAR
Learning 3D Printing
[https://www.linkedin.com/learning/learning-3d-printing?u=41910388]


* 18,352 viewers
===''Course:'' Creating and Deploying Microlearning ===


*
====Course details====


Save Learning 3D Printing
Length: 1h 1m


Course: Rapid Prototyping for Product Design
Level: Beginner


1h 38m
Released: 10/5/2018
[https://www.linkedin.com/learning/rapid-prototyping-for-product-design?u=41910388]


COURSE Course POPULAR
Feel like you can't capture the attention of your learners? Get to the next level of engagement with microlearning. Microlearning is more than just short educational videos. It's a system of training that places emphasis on providing the right content to the learner at the right time, in an easy-to-use format. In this course, Chris Mattia explores how to create and deploy microlearning that will provide employees and students with the training they need where they can use it the most—on their mobile devices. Learn how to develop engaging assets, including everything from infographics and podcasts to memes and GIFs, and track the effectiveness of your microlearning campaigns to see what content is getting the most attention.
Rapid Prototyping for Product Design
[https://www.linkedin.com/learning/rapid-prototyping-for-product-design?u=41910388]


* 17,686 viewers
Learning objectives


*
*   Is microlearning right for your organization?
*    Developing a microlearning strategy
*    Assessing what students have learned
*    Creating lessons with infographics and animated GIFs
*    Creating lessons with audio and video
*    Deploying lessons to mobile devices
*    Leveraging social media
*    Tracking engagement and effectiveness


Unsave Rapid Prototyping for Product Design
[https://www.linkedin.com/learning/creating-and-deploying-microlearning/is-microlearning-the-right-strategy-for-you Creating and Deploying Microlearning]


Course: Design Foundations: Physical Materials


1h 31m
== Learning Related to Autodesk Fusion 360 3d Modeling Software  ==
[https://www.linkedin.com/learning/design-foundations-physical-materials?u=41910388]


COURSE Course
Design Foundations: Physical Materials
[https://www.linkedin.com/learning/design-foundations-physical-materials?u=41910388]


* 4,529 viewers
===Course: Fusion 360: Basic Part Modeling===
By: Vladimir Mariano o Updated Dec 16, 2019


*
Learn how to measure and model real-world objects so you can create parts that are manufacture-ready.


Save Design Foundations: Physical Materials


Course: Additive Manufacturing: Optimizing 3D Prints
===Course: Fusion 360: Multi-Body Modeling===
47m


1h 27m
Course Fusion 360: Multi-Body Modeling o By: Jomarc Baquiran o Released Aug 2, 2018 Learn techniques for modeling complex components in Fusion 360, specifically modeling multiple bodies in a single design file. o 2,607 viewers *
[https://www.linkedin.com/learning/additive-manufacturing-optimizing-3d-prints-2?u=41910388]


COURSE Course
===Course: Fusion 360: Surfacing with the Patch Workspace===
Additive Manufacturing: Optimizing 3D Prints
1h 22m Preview COURSE Course Fusion 360: Surfacing with the Patch Workspace
[https://www.linkedin.com/learning/additive-manufacturing-optimizing-3d-prints-2?u=41910388]
o By: Jomarc Baquiran o Released Nov 17, 2017 Learn to use the surfacing tools in the Autodesk Fusion 360 Patch workspace to design complex organic shapes and water-tight solid bodies like the plastic bottles in this course.  


* 2,467 viewers
===Course: Fusion 360: Animating Assemblies===


*
1h 7m Preview COURSE Course Fusion 360: Animating Assemblies o By: Jomarc Baquiran o Released Jun 19, 2018 Learn how to create animations for your product assemblies in Fusion 360. o 1,953 viewers *  


Unsave Additive Manufacturing: Optimizing 3D Prints
===Course: Fusion 360: Product Rendering Techniques===


Course: Additive Manufacturing: Short Run Production
1h 52m Course Fusion 360: Product Rendering Techniques o By: Jomarc Baquiran o Released Apr 5, 2018 Learn how to create realistic and engaging product renderings in Autodesk Fusion 360. o 2,530 viewers *


1h
===Course: Fusion 360: 3D Printed Product Enclosure===
[https://www.linkedin.com/learning/additive-manufacturing-short-run-production?u=41910388]


COURSE Course
1h 58m Preview COURSE Course Fusion 360: 3D Printed Product Enclosure o By: Vladimir Mariano o Updated Dec 16, 2019 Learn how to design product enclosures to manufacture a 3D printing of the design using Autodesk Fusion 360. o 7,135 viewers *
Additive Manufacturing: Short Run Production
[https://www.linkedin.com/learning/additive-manufacturing-short-run-production?u=41910388]


* 3,300 viewers
===Course: Fusion 360: Designing for Plastics (2017)===


*
56m Preview COURSE Course Fusion 360: Designing for Plastics (2017) o By: Thom Tremblay o Released Nov 9, 2017 Learn about designing for additive manufacturing in plastic using Fusion 360. Discover how to create a form, complete and visualize your design, and set it up for 3D printing. o 4,500 viewers *  


Unsave Additive Manufacturing: Short Run Production
===Course: Fusion 360: Designing for Metal (2017)===


In this video
1h 23m Preview COURSE Course Fusion 360: Designing for Metal (2017) o By: Thom Tremblay o Released Nov 13, 2017 Use Fusion 360—the cloud-powered, accessible CAM tool—to create effective designs for subtractive manufacturing (such as CNC milling) in metal.

Latest revision as of 22:59, 2 June 2020

Online Maker Training through LinkedIn Learning

LinkedIn Learning (formerly Lynda.com) is a leading provider of online training video courses. The entire LinkedIn Learning library is available to the UMD community at no charge. While many of the LinkedIn Learning courses are focused on learning business applications such as Microsoft Excel or Google Sheets, there are a number of training modules on maker-related subjsts like 3d modeling in Autodesk Fusion 360, Designining for 3d Printing, and others.

To make use of LinkedIn Learning training material, you need to log in using your UMD directory ID and authenticate through the UMD sign on page. Since this material is somewhat hidden away, we've added this page to list LinkedIn Learning classes and videos that may be of interest. This page consists almost entirely of content taken from the LinkedIn Learning site and links directly to that site for viewing the lessons.

Learning Related to Sandbox Prototyping Studio

Course: Design for Additive Manufacturing: FDM

INSTRUCTOR: Kacie Hultgren

Length: 1h 47m Level: 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


Course Outline

Introduction

1. FDM Basics

2. CAD and CAM

3. Bases and Supports

4. Features and Options

5. Optimizing with Cura

6. Optimizing with MakerBot

7. Assemblies

8. Design a Hinged Box

Conclusion


Course: Learning 3D Printing

Length: 1h 16m

Learning 3D Printing


Course: Rapid Prototyping for Product Design

Length: 1h 38m

Rapid Prototyping for Product Design


Course: Design Foundations: Physical Materials

Length: 1h 31m

Design Foundations: Physical Materials


Course: Additive Manufacturing: Optimizing 3D Prints

Length: 1h 27m

Additive Manufacturing: Optimizing 3D Prints


Course: Additive Manufacturing: Short Run Production

Length: 1h

Additive Manufacturing: Short Run Production

Learning Related to Sandbox Digital Media Studio

Course: Making Video 2: Teach Something

Making Video 2: Teach Something

Course: Learning Video Production and Editing

Learning Video Production and Editing

Course: Creating and Deploying Microlearning

Course details

Length: 1h 1m

Level: Beginner

Released: 10/5/2018

Feel like you can't capture the attention of your learners? Get to the next level of engagement with microlearning. Microlearning is more than just short educational videos. It's a system of training that places emphasis on providing the right content to the learner at the right time, in an easy-to-use format. In this course, Chris Mattia explores how to create and deploy microlearning that will provide employees and students with the training they need where they can use it the most—on their mobile devices. Learn how to develop engaging assets, including everything from infographics and podcasts to memes and GIFs, and track the effectiveness of your microlearning campaigns to see what content is getting the most attention.

Learning objectives

  • Is microlearning right for your organization?
  • Developing a microlearning strategy
  • Assessing what students have learned
  • Creating lessons with infographics and animated GIFs
  • Creating lessons with audio and video
  • Deploying lessons to mobile devices
  • Leveraging social media
  • Tracking engagement and effectiveness

Creating and Deploying Microlearning


Learning Related to Autodesk Fusion 360 3d Modeling Software

Course: Fusion 360: Basic Part Modeling

By: Vladimir Mariano o Updated Dec 16, 2019

Learn how to measure and model real-world objects so you can create parts that are manufacture-ready.


Course: Fusion 360: Multi-Body Modeling

47m

Course Fusion 360: Multi-Body Modeling o By: Jomarc Baquiran o Released Aug 2, 2018 Learn techniques for modeling complex components in Fusion 360, specifically modeling multiple bodies in a single design file. o 2,607 viewers *

Course: Fusion 360: Surfacing with the Patch Workspace

1h 22m Preview COURSE Course Fusion 360: Surfacing with the Patch Workspace o By: Jomarc Baquiran o Released Nov 17, 2017 Learn to use the surfacing tools in the Autodesk Fusion 360 Patch workspace to design complex organic shapes and water-tight solid bodies like the plastic bottles in this course.

Course: Fusion 360: Animating Assemblies

1h 7m Preview COURSE Course Fusion 360: Animating Assemblies o By: Jomarc Baquiran o Released Jun 19, 2018 Learn how to create animations for your product assemblies in Fusion 360. o 1,953 viewers *

Course: Fusion 360: Product Rendering Techniques

1h 52m Course Fusion 360: Product Rendering Techniques o By: Jomarc Baquiran o Released Apr 5, 2018 Learn how to create realistic and engaging product renderings in Autodesk Fusion 360. o 2,530 viewers *

Course: Fusion 360: 3D Printed Product Enclosure

1h 58m Preview COURSE Course Fusion 360: 3D Printed Product Enclosure o By: Vladimir Mariano o Updated Dec 16, 2019 Learn how to design product enclosures to manufacture a 3D printing of the design using Autodesk Fusion 360. o 7,135 viewers *

Course: Fusion 360: Designing for Plastics (2017)

56m Preview COURSE Course Fusion 360: Designing for Plastics (2017) o By: Thom Tremblay o Released Nov 9, 2017 Learn about designing for additive manufacturing in plastic using Fusion 360. Discover how to create a form, complete and visualize your design, and set it up for 3D printing. o 4,500 viewers *

Course: Fusion 360: Designing for Metal (2017)

1h 23m Preview COURSE Course Fusion 360: Designing for Metal (2017) o By: Thom Tremblay o Released Nov 13, 2017 Use Fusion 360—the cloud-powered, accessible CAM tool—to create effective designs for subtractive manufacturing (such as CNC milling) in metal.