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Learn how to optimize the performance of your mechanical and thermal components, in a practical way, working on real cases from day 1 and applying everything to projects in your portfolio.
Learn how to design smaller, more powerful, manufacturable and affordable HEAT SINKS
40+ Lattice Structures for Thermal Dissipation
Designed using Simcenter (Siemens) by Malcolm Johnson
Learn how to generate and simulate 40+ Lattice Structures for Thermal Dissipation and Cooling Optimization.
First, a bit of context:
Electronic devices are everywhere.
Including electronics, automotive, aerospace, data centers and HVAC.
And most electronic devices have HEAT SINKS to manage the heat generated by components such as:
– CPUs,
– GPUs,
– Power transistors, and
– Other semiconductor devices.
Professionals designing thermal management devices encounter several challenges, including:
1. Miniaturization:
Electronic devices and heat sinks are becoming smaller and more powerful.
2. Traditional Manufacturing:
Current manufacturing technology limits the manufacture of efficient and innovative heat dissipation structures.
3. Cost Constraints:
Validation through physical testing can be time-consuming and costly.
4. Lack of familiarity with Computational Tools:
Tools such as nTop, Rhino, General Lattice, CDS, ANSYS, COMSOL Multiphysics, or Abaqus.
That's the reason why companies are hiring professionals capable of designing:
– Compact and effective heat sinks that prevents overheating,
– Heat sinks that minimize energy consumption while effectively managing heat, and
– Robust heat sinks that minimize failures, and lower cost and weight.
Our hands-on training course to help you become this in-demand professional:
Learn how to generate optimal lattices for thermal dissipation and cooling optimization.
Lattice Structures:
Learn about 40+ different lattice structures (e.g., octet, body-centered cubic, face-centered cubic, Diamond, Kelvin Cell, Iso Truss, Re-entrant, Weaire-Phelan, Honeycomb, Gyroid, Voronoi…) and their thermal properties.
Conduction, Convection and Radiation:
Familiarize yourself with the heat transfer mechanisms (conduction, convection, and radiation), and thermal conductivity.
Material Properties:
Understand how different materials conduct heat and how their properties can affect thermal performance.
Surface area and Weight:
Study methods for optimizing lattice structures for specific applications, focusing on maximizing surface area for heat dissipation while minimizing weight.
Finite Element Analysis (FEA):
FEA will help you analyze thermal performance and simulate heat transfer in lattice structures.
Additive Manufacturing Technologies:
Understand how 3D printing can be used to create complex lattice structures that may be difficult to fabricate using traditional methods.
Become a specialist in Lattice Structures, Topology Optimization and Generative Design in 4 months:
About the training course:
– 120h of practical training in Topology Optimization, Lattices and Generative Design
– Online, but always accompanied
– 17 weeks part-time
– 30-60 minutes / day
– At your own pace (It is not necessary to be online at a specific time each day)
– Mentoring sessions every 2 weeks
– Free access to the software
– Training co-developed with Topology Optimization and Lattice specialists at nTop and Cognitive Design Systems
– Cost of our next edition: here.
– [Only 10 seats available]
– Registration Process (1 minute): Now