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As the products you build grow more powerful, they generate more heat. Yet, the available space that a thermal management system can occupy usually remains the same.
This creates a need for next-generation heat exchangers that are more efficient and compact than their predecessors.
This guide explores how additive manufacturing, when combined with advanced engineering design software like nTop, can help you create more efficient and compact heat exchangers.
How to achieve dramatically better thermal management with additive manufacturing.
What is the basic anatomy of an AM heat exchanger.
What are the benefits of AM heat exchangers, with use cases and examples.
How can you use AM to optimize other thermal management system elements.
A fundamentally different and unbreakable modeling technology that delivers unprecedented speed, scalability, and reliability.
How does it relate to thermal management?
Even the most complex lattice structures or shells are generated in seconds. Modeling operations are extremely robust, ensuring that your models will not break even when you make radical changes.
A new design method that enables you to control geometry at every point in space directly from simulation results, test data, and engineering formulas.
How does it relate to thermal management?
You can control key design parameters from CFD fields and thermal data. Advanced implementations enable you to build generative design workflows based on iterative geometry generation and simulation.
A block-based approach to design automation that allows you to speed up design iterations and package engineering processes.
How does it relate to thermal management?
During design exploration, blocks enable you to quickly test new ideas. In later stages, reusable workflows allow you to automatically generate geometry and run computational Design of Experiments to refine your designs.