Researchers design extreme heat exchanger using metal 3D printing

University of Illinois researchers design extreme heat exchanger using metal 3D printing
Computer Tomography (CT) X-ray image of the tube-in-tube heat exchanger. Color indicates whether hot fluid (red) in the outer tube or cold fluid (blue) in the inner tube. Credit: Hyunkyu Moon, Davis McGregor, Nenad Miljkovic and William P. King, University of Illinois Urbana-Champaign

Demonstrating next-generation energy technology, researchers at the University of Illinois Urbana-Champaign are using topology optimization and metal 3D printing to design ultra-compact, high-power heat exchangers.

Used in most major industries—including energy, water, manufacturing, transportation, construction, electronic, chemical, petrochemical, agriculture and aerospace—heat exchangers transfer thermal energy from one medium to another.

For decades, heat exchanger designs have remained relatively unchanged. Recent advancements in 3D printing allow the production of three-dimensional exchanger designs previously thought impossible. These new and innovative designs operate significantly more effectively and efficiently but require specific tools and design methods to manufacture the high-performance devices.

Recognizing the need to unlock new, high-performing heat exchangers, Grainger College of Engineering researchers have developed software tools that enable new 3D heat exchanger designs.

"We developed shape optimization software to design a high-performance heat exchanger," said William King, professor of Mechanical Science and Engineering at The Grainger College of Engineering and co-study leader. "The software allows us to identity 3D designs that are significantly different and better than conventional designs."

The team started by studying a type of exchanger known as a tube-in-tube heat exchanger—where one tube is nested inside another tube. Tube-in-tube heat exchangers are commonly used in drinking water and building energy systems. Using a combination of the shape optimization software and additive manufacturing, the researchers designed fins (only made possible using metal 3D printing) internal to the tubes.

"We designed, fabricated and tested an optimized tube-in-tube heat exchanger," said Nenad Miljkovic, associate professor of Mechanical Science and Engineering and co-study leader. "Our optimized heat exchanger has about 20 times higher volumetric power density than a current state-of-the-art commercial tube-in-tube device."

With billions of heat exchangers in use worldwide today and even more attention placed on our need to reduce fossil fuel consumption, compact and efficient are increasing in demand, particularly in industries where heat exchanger size and mass significantly impacts performance, range and costs.

The article "Ultra-power-dense exchanger development through genetic algorithm design and additive manufacturing," written by Hyunkyu Moon, Davis McGregor, Nenad Miljkovic and William P. King, is published in the journal Joule.


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More information: Hyunkyu Moon et al, Ultra-power-dense heat exchanger development through genetic algorithm design and additive manufacturing, Joule (2021). DOI: 10.1016/j.joule.2021.08.004
Journal information: Joule

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