edX: Fundamentals of Manufacturing Processes

Have you wondered how something was manufactured? Do you want to learn what it takes to turn your design into a finished product? This course introduces a wide range of manufacturing processes including machining, injection molding, and 3D printing; and explains the fundamental principles and practices of manufacturing at scale.

For each process, 2.008x explains the underlying physical principles, provides several practical examples and demonstrations, and summarizes design for manufacturing principles. Lectures are also included on cost estimation, quality and variation, robotics, and sustainability. Together, this knowledge will enable you to plan a manufacturing process for a multi-part product, make quantitative estimates of cost and throughput, and recognize important constraints and tradeoffs.

Whether you may be an engineer, entrepreneur, or from another field—by completing 2.008x you will gain the understanding needed to assess a wide variety of manufacturing techniques, identify potential improvements, and confidently pursue the scale-up of innovative products.


Week 1: Introduction and Process Planning
An introduction to the scope and significance of manufacturing worldwide, followed by an overview of the structure of 2.008x and highlights of key topics.  Then, a framework is presented for planning manufacturing processes, and for evaluating process performance based on four key attributes.
Week 2: Machining
This module describes machining, the most common process of material removal.  Chapters address the mechanics of material deformation, estimates of material removal rate and cutting forces, practical aspects of turning and milling operations, and methods of machining advanced materials and complex parts.
Week 3: Injection Molding
Injection molding is the most widely used plastics manufacturing process.  Chapters of this module describe the process physics, rate-limiting steps, process parameters, thermoplastic materials, mold tooling design, and guidelines for defect prevention.  Examples include molding of toy bricks, cups, and plastic furniture.
Week 4: Thermoforming and Sheet Metal Forming
These modules address sheet forming of plastics and metals.  Chapters describe the materials and process considerations, rate- and geometry-limiting aspects including springback and tearing, and explain various uses including manufacturing of plastic packaging and aluminum beverage cans.  A supplement to the thermoforming module introduces other polymer forming processes including those for plastic bottles, bags, and large containers.
Week 5: Casting
This module introduces casting, whereby a metal part is made by solidification within a mold.  Modules describe sand casting, die casting, and investment casting processes; rate-limiting steps and factors governing part microstructure, quality, and cost are also analyzed.
Week 6: Additive Manufacturing
We first introduce the spectrum of additive manufacturing (AM) technologies, its key applications, and reasons for its rapid growth and significance.  Next, we focus in-depth on the three most prevalent AM processes: extrusion of polymers and composites (i.e., FFF/FDM), photopolymerization (i.e., stereolithography or SLA), and selective laser melting (SLM) of metals.
Week 7: Quality and Variation
This module explains basic statistical methods for analyzing, monitoring, and controlling process variation, including the use of control charts.  The critical differences between variation, tolerances, and quality are explained; and principles of precision metrology are introduced.
Week 8: Manufacturing Cost
Understanding the cost of manufacturing a part or product, and its relationship to the process details and production volume, is essential to effective scale-up.  This module presents a methodology for estimating manufacturing cost, and examples discuss the cost of making toy bricks, window glass, and smartphones.
Week 9: Sustainability and Robotics
First, we discuss the implications of the energy consumption of manufacturing, and of the product life cycle life cycle.  Second, the robotics module introduces several types of robots used in manufacturing, compares their performance, and illustrates how robotics can improve production efficiency and quality.
Week 10: The Future of Manufacturing and Conclusion
To conclude, this module provides a brief summary of 2.008x, highlights important emerging manufacturing technologies, and presents the perspectives of instructors and guests on the exciting future of manufacturing.
1 Student
Cost Free Online Course
Pace Self Paced
Subject Engineering
Provider edX
Language English
Hours 4-6 hours a week
Calendar 10 weeks long

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What are MOOCs?
MOOCs stand for Massive Open Online Courses. These are free online courses from universities around the world (eg. Stanford Harvard MIT) offered to anyone with an internet connection.
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1 review for edX's Fundamentals of Manufacturing Processes

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a year ago
Maxime Zabiégo completed this course, spending 2 hours a week on it and found the course difficulty to be easy.
Very interesting course: a nice introduction to manufacturing, with some (fairly light) theoretical aspects, and a large variety of applications from the industry. If you ever wondered how such products as the iPhone or Lego bricks are manufactured, this is the place to go! After a brief introduction of the attributes Read More
Very interesting course: a nice introduction to manufacturing, with some (fairly light) theoretical aspects, and a large variety of applications from the industry. If you ever wondered how such products as the iPhone or Lego bricks are manufactured, this is the place to go!

After a brief introduction of the attributes that characterise process performance (rate, cost, quality and flexibility), the course successively covers several basic processes (one each week: machining, injection molding, thermoforming...), before concluding with a brief overview of robotics and sustainability, and a discussion of various perspectives.

I found it somewhat frustrating that some processes (forging, extrusion, rolling...) were not discussed, and that assembly issues (welding, mechanical fitting...) were mostly ignored. I do understand, however, that a single course cannot cover this vast topic exhaustively: 10 weeks is already quite long, I guess.

The videos are very clear and well structured. I particularly appreciated the demos (both MIT videos and industry examples taken from YouTube), which efficiently illustrate the concepts discussed in a general context.

I was a bit disappointed by the problem sets, though: they are generally straightforward and thus don't particularly motivate learners to explore complementary material, beyond the lectures.
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