Course Content
Module 1: Introduction to 3D Printing
This section gives an overview of what 3D Printing is and is origins.
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What is 3D Printing?
00:05
3D Printing’s origin…History and Evolution of Additive Manufacturing
Types of 3D Printing Technologies (FDM, SLA, SLS, etc.)
Part 1 Quiz
00:10:00
Module 2: 3D Printers & Materials
This section gives an overview of the various 3D Printer components, 3D Printer types and materials.
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Components of a 3D Printer
Filament Types and Resin Basics
Choosing the Right Printer and Materials!
Module 2 Quiz: Materials and Printer Components
00:05:00
Module 3: 3D Printing File Types
This lesson provides a comprehensive understanding of the myriads of file extensions in the 3D Printing.
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FDM (Fused Deposition Modeling)
SLA (Stereolithography)
SLS (Selective Laser Sintering)
FAM (Fluid Additive Manufacturing)
00:00
Other Technologies.
Module 3: 3D Printing File Types
00:05:00
Module 4: Introduction to 3D Modeling
Start designing your own printable objects with easy-to-use modeling tools. This module introduces you to beginner-friendly 3D modeling software and teaches you how to create objects that are optimized for the printing process.
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Basic Design Concepts
Beginner-Friendly Software (Tinkercad, Fusion 360, FreeCAD)
Getting Started with FreeCAD!
Designing for Printability
Module 5: Slicing and G-Code
Before printing, models need to be sliced into printable layers. Learn how slicing software works, how to adjust print settings like layer height and infill, and how the slicer generates the G-code that your printer uses to build the object.
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Introduction to Slicer Software (Cura, OrcaSlicer and more)!
03:52
Layer Height, Supports, Infill, and Print Settings
Generating and Reading G-code
Module 6: The Print Process
Now it’s time to bring your models to life. Learn how to set up your printer, load materials, calibrate settings, and start your first print. This module also covers how to identify and fix common printing issues like warping or layer shifting.
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Printer Setup and Calibration
Starting Your First Print
Troubleshooting Common Issues
Module 7: Post-Processing
After printing, your model might need some finishing work. Discover how to remove supports, sand rough edges, paint your models, and combine printed parts into assemblies. These techniques can take your prints from good to great.
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Removing Supports
Sanding and Surface Finishing
Painting and Assembly
Module 8: Introduction to 3D Scanning
Learn how physical objects can be digitized using 3D scanning technology. This module introduces different scanning methods, software for cleaning and editing scan data, and how scanning is used in design, repair, and reverse engineering.
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Types of 3D Scanners
Mesh Cleanup
Retopology Applications in Reverse Engineering
Module 9: Real-World Applications
Explore how 3D printing is transforming industries like healthcare, automotive, education, and aerospace. See case studies and examples of how professionals use 3D printing to solve real problems and prototype new ideas.
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3D Printing in Industry, Medicine, and Education
3D Printing in Construction & Housing
3D Printing in Fashion and Art
3D Printing in Defense and Military Applications
Module 10: The Business of 3D Printing
In this module, students explore how 3D printing extends beyond the workshop and into the world of business, sustainability, and emerging markets. From eco-conscious manufacturing to digital entrepreneurship, learners discover how additive manufacturing is reshaping supply chains, product development, and global commerce. The module begins by examining sustainability trends, showing how 3D printing reduces waste, supports local production, and enables environmentally friendly materials. Students then move into the future of additive technologies, including bioprinting, AI-driven design, and off-planet construction. The module also highlights how 3D printing enables new business models—from custom product startups and digital part libraries to contract printing services and hybrid manufacturing workflows. Students gain insight into market opportunities, value propositions, and the strategic use of 3D printing to create value across industries. Whether learners aim to start a business, join an innovative company, or simply understand the economics behind additive manufacturing, this module equips them with the tools and trends that define the future of 3D printing as a business.
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Sustainability and Future Trends
Building a Portfolio or Business in 3D Printing
Complete a Print-to-Finish Project
Submit for Feedback and Certification
Receive Your Certificate and Bonus Gift
Private: 3D Printing Fundamentals.

✅ Summary

In this lesson, you’ll explore the major types of 3D printing technologies, how they work, and where they are commonly used. Each technology has unique strengths and ideal use cases—from prototyping to industrial production. Understanding these methods will help you choose the right one for your needs.

🎯 Learning Objectives

By the end of this lesson, you will be able to:

  • Identify and describe the core 3D printing technologies: FDM, SLA, SLS, and more

  • Compare the differences between filament, resin, and powder-based printing

  • Match each printing technology with its ideal materials and use cases

  • Understand how printing methods impact resolution, strength, and cost

📘 Lesson Content

🔧 1. Fused Deposition Modeling (FDM)

How It Works:
FDM printers extrude melted thermoplastic filament through a heated nozzle, depositing material layer by layer to build the object.

Materials Used:
PLA, ABS, PETG, TPU, Nylon

Pros:

  • Affordable and widely accessible

  • Simple to operate and maintain

  • Good for prototyping and hobbyist use

Cons:

  • Limited detail compared to resin or powder-based printers

  • May require support structures

  • Visible layer lines

Best For:

  • Education, functional prototyping, household items, basic mechanical parts

🧪 2. Stereolithography (SLA)

How It Works:
SLA uses an ultraviolet (UV) laser to cure photosensitive resin in a vat, layer by layer.

Materials Used:
Liquid photopolymer resins (standard, tough, flexible, castable)

Pros:

  • High-resolution prints with smooth surfaces

  • Excellent for detailed models and fine features

  • Great for dental, jewelry, and product design

Cons:

  • Resin can be messy and requires post-curing

  • Limited material strength compared to FDM/SLS

  • Higher printer and resin costs

Best For:

  • Miniatures, dental models, prototypes, molds, and jewelry

⚙️ 3. Selective Laser Sintering (SLS)

How It Works:
SLS uses a high-powered laser to fuse powdered material (usually nylon) into solid cross-sections, layer by layer.

Materials Used:
Nylon (PA12), TPU, composites, metal powders (in advanced setups)

Pros:

  • Strong, functional parts with complex geometry

  • No need for supports (powder acts as a support medium)

  • High production-level detail and strength

Cons:

  • Expensive machines and materials

  • Requires advanced ventilation and post-processing

  • More technical setup

Best For:

  • Industrial prototyping, functional end-use parts, aerospace and automotive components

💡 4. Digital Light Processing (DLP)

How It Works:
DLP is similar to SLA but uses a digital projector screen to cure each layer in one flash instead of tracing it with a laser.

Materials Used:
Photopolymer resins

Pros:

  • Faster than SLA due to whole-layer exposure

  • Very high detail and accuracy

  • Less mechanical movement = lower failure rates

Cons:

  • Same resin handling and post-processing challenges as SLA

  • More expensive than FDM

Best For:

  • Dental, jewelry, miniatures, ultra-fine detail printing

⚙️ 5. Multi Jet Fusion (MJF)

How It Works:
Developed by HP, MJF uses a fine powder bed and applies fusing and detailing agents with a thermal inkjet head, then fuses it with infrared heat.

Materials Used:
Nylon powder (PA11, PA12), TPU, glass-filled nylons

Pros:

  • Fast production of highly functional parts

  • Superior strength, surface finish, and isotropy

  • Ideal for batch production

Cons:

  • High initial investment

  • Limited to industrial applications

Best For:

  • Short-run manufacturing, end-use parts, enclosures, mechanical assemblies

🔩 6. Direct Metal Laser Sintering (DMLS) / SLM

How It Works:
Metal powder is sintered or melted using a laser to produce fully metallic parts, layer by layer.

Materials Used:
Titanium, aluminum, stainless steel, cobalt-chrome

Pros:

  • High-performance metal parts with excellent accuracy

  • Ideal for aerospace, medical, and automotive

  • No tooling required—complex geometries are possible

Cons:

  • Extremely expensive

  • Requires specialized safety equipment

  • Long post-processing times

Best For:

  • Aerospace components, surgical tools, metal prototypes

🧠 Comparison Table

Technology Material Type Detail Level Speed Support Needed Common Uses
FDM Filament Moderate Medium Yes Prototypes, hobby parts
SLA Resin High Medium Yes Dental, jewelry, models
SLS Powder High Fast No Functional parts
DLP Resin Very High Fast Yes Miniatures, casting
MJF Powder High Very Fast No Batch production
DMLS/SLM Metal Powder High Slow No Aerospace, tooling

📂 Resources & Further Reading

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