When it comes to their material properties, high-efficiency compact heat exchangers require a suitable combination of creep, high-temperature strength, oxidation resistance, and thermal shock. Current heat exchanger designs incur costly pressure drops while only marginally increasing heat transfer. The ability to manufacture complex geometries is needed to reduce this wasteful pressure drop. However, conventional material and manufacturing methods cannot achieve this combination of material properties and complex geometries.

About

Researchers at Sandia National Laboratories have identified thermal and structural properties of advanced refractory high-entropy alloys (RHEAs) as candidates for high-temperature heat exchangers enabled by combined additive and substractive manufacturing. This technology achieves near net shape geometries that are currently impractical for conventional manufacturing, allowing the end-user to better control function through structure and material design. This is relevant in systems where improvements are limited by current state-of-the-art alloys' performance, such as conventional Ni-based superalloys.

Key Benefits

Reduces pressure drop in heat exchangers by 100-500% Extends high temperature allowable stress Achieves near net shape manufacturing

Applications

Fusion and fission applications Refrigeration Petroleum refining Power plants Renewable energy systems

Register for free for full unlimited access to all innovation profiles on LEO

  • Discover articles from some of the world’s brightest minds, or share your thoughts and add one yourself
  • Connect with like-minded individuals and forge valuable relationships and collaboration partners
  • Innovate together, promote your expertise, or showcase your innovations