Emily Welsh

Ms. Welsh is an educational technologist in the MIT Mechanical Engineering Department. She assists MIT faculty in the development of online courses and develops digital education tools for use in MIT courses. Prior to joining MIT, she worked as a Sustaining Engineer for an original equipment manufacturer. She holds a B.S in Mechanical Engineering from Case Western Reserve University.

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Fundamentals of Manufacturing Processes (edX) EdX
MIT,MITx

Fundamentals of Manufacturing Processes (edX)

Management & Leadership Engineering

Explore the world of manufacturing with our Fundamentals of Manufacturing Processes course. Dive into the core concepts and practical applications that drive product creation from concept to completion. Whether you're a student, an aspiring engineer, or simply curious about how things are made, this course offers insights into key processes like machining, injection molding, casing, and 3D printing.

This course is archived
5-12 Weeks
Technology Manufacturing 3D Printing
Details
Advanced Fluid Mechanics 1: Fundamentals (edX) EdX
MIT,MITx

Advanced Fluid Mechanics 1: Fundamentals (edX)

Engineering Sci: Physics

Dive into the core concepts of fluid mechanics with our Advanced Fluid Mechanics 1: Fundamentals course. This edX offering provides a strong foundation in essential principles such as kinematics of deformation, hydrostatics, buoyancy, inviscid flow, Bernoulli's theorem and control volume analysis. Ideal for engineers and students seeking to understand the basics that underpin fluid dynamics.

Self Paced
Self-Paced
Physics Engineering Fluid Mechanics
Details
Advanced Fluid Mechanics 3: Potential Flows & Boundary Layers (edX) EdX
MIT,MITx

Advanced Fluid Mechanics 3: Potential Flows & Boundary Layers (edX)

Engineering Sci: Physics

Dive deep into the intricate world of fluid mechanics with our Advanced Fluid Mechanics 3: Potential Flows & Boundary Layers course. This course is designed for those who wish to understand high Reynolds number flows, boundary layers, circulation, lift, flow separation, transition to turbulence, and the impact of surface tension on engineering applications.

Self Paced
Self-Paced
Physics Fluid Mechanics Flows
Details
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