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Thermodynamics & Heat Transfer in 3D Printing Masterclass

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Master the Thermal Science Behind Additive Manufacturing Conduction, Convection, Radiation, Cooling, Warping & Cases.
1
1/5
(61) Ratings
1 students
Created by NextGen 3D
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What you'll learn

  • Apply the First and Second Laws of Thermodynamics to additive manufacturing processes
  • Analyze energy balance equations for FDM, MEX, and industrial 3D printing systems
  • Understand temperature ranges, material states, and processing windows for PLA, ABS, PETG, and PEEK
  • Master conduction, convection, and radiation heat transfer in 3D printing context
  • Calculate heat flux, thermal conductivity, and temperature gradients using Fourier’s Law
  • Interpret nozzle temperature profiles and optimize melt-zone behavior
  • Analyze polymer crystallization kinetics and cooling rate effects on microstructure
  • Design controlled cooling strategies for improved mechanical properties
  • Predict thermal stresses and warping using engineering principles
  • Evaluate real-world case studies from aerospace, medical, automotive, and construction industries
  • Improve printer energy efficiency through insulation, enclosure design, and power management
  • Diagnose thermal defects and develop engineering-grade solutions
This course includes:
2.5 total hours on-demand video
0 articles
0 downloadable resources
20 lessons
Full lifetime access
Access on mobile and TV
Certificate of completion
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Course content

Requirements

  • Diagnose thermal defects and develop engineering-grade solutions
  • Familiarity with 3D printing concepts or hands-on printing experience is helpful but not mandatory
  • No prior thermodynamics coursework required concepts are built from the ground up
  • A computer or mobile device to access course content
  • Curiosity about engineering, materials science, and additive manufacturing

Description

This course contains the use of artificial intelligence.
Welcome to the Thermodynamics & Heat Transfer in 3D Printing Masterclass — a complete, theory-driven engineering course built for anyone who wants to truly understand the thermal science that controls every single 3D print. Whether you are an engineer, designer, researcher, student, or advanced hobbyist, this course will transform the way you think about additive manufacturing by giving you a deep, structured understanding of the heat and energy phenomena that decide whether a print succeeds or fails.

You will begin with the fundamentals of thermodynamics applied to additive manufacturing — the First and Second Laws of Thermodynamics, entropy considerations, energy balance equations, and how electrical energy converts into the thermal energy that melts your filament or fuses your powder. You will study phase transitions, glass transition temperatures (Tg), melting points (Tm), heat of fusion, and the precise temperature ranges that define each material state from feed zone to melt pool.

Next, you will master the three core heat transfer mechanisms — conduction, convection, and radiation — and learn exactly how each one operates inside FDM, SLS, SLA, and metal AM systems. You will learn how to analyze combined heat transfer scenarios, calculate heat flux, and predict thermal behavior across the build chamber.

The course then takes a deep technical dive into extrusion thermodynamics, including FDM thermal analysis, nozzle temperature profiles, viscosity-temperature relationships, and heat transfer in advanced metal extrusion (MEX) processes. You will understand exactly what happens inside the hotend, the heat break, and the melt zone.

From there, you will explore cooling rates and crystallization — polymer crystallization kinetics, the effect of cooling rate on microstructure, mechanical strength, and surface quality, and how to design controlled cooling strategies for optimal part performance.

You will then move into one of the most critical areas of 3D printing engineering — thermal stresses and warping theory. You will learn the fundamentals of thermal stress, the mechanisms behind warping and delamination, predictive techniques, and proven mitigation strategies used across industry.

Finally, the course closes with real-world case studies and applications from across the globe — aerospace component manufacturing in the UK, medical implant production in the USA, automotive part optimization in Germany, and construction component printing in Australia. These case studies translate everything you learn into applied, industry-grade insight.

By the end of this masterclass, you will think like a thermal engineer, troubleshoot prints with scientific precision, and design parts and processes that are optimized for thermal performance from day one.

This course is brought to you by NextGen3D Academy, with carefully crafted content, real engineering examples, and a step-by-step learning structure built to make you industry-ready.

Enroll today and master the thermal science behind world-class 3D printing.

Who this course is for:

  • Mechanical, manufacturing, and materials engineering students
  • 3D printing hobbyists who want to upgrade to professional-level understanding
  • Additive manufacturing professionals seeking thermal engineering expertise
  • Engineering educators looking for structured AM teaching material
  • Anyone troubleshooting warping, layer adhesion, or dimensional accuracy issues
  • Researchers and graduate students in polymer processing and AM technologies
  • R&D engineers in aerospace, medical, automotive, and construction sectors
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