Low-Force Elastocaloric Refrigeration via Bending

TL;DR

This paper introduces a low-force, low-fatigue elastocaloric cooling mechanism using bending, demonstrating a rotary prototype with improved performance, scalability, and durability compared to traditional uniaxial methods.

Contribution

It defines the physics of axisymmetric flexural bending for elastocaloric cooling and demonstrates a rotary-driven prototype with enhanced efficiency and lifespan.

Findings

Temperature reduction up to 11.3°C achieved

Material coefficients of performance between 2.31 and 21.71

Actuation force reduced by 6.09 to 7.75 times compared to uniaxial tension

Abstract

Elastocaloric cooling has been identified as a promising alternative to high global warming potential vapor compression cooling. Two key bottlenecks to adoption are the need for bulky/expensive actuators to provide sufficient uniaxial stress and inadequate elastocaloric material fatigue life. This paper defines the physics that govern performance of axisymmetric flexural bending for use as an emerging low-force and low-fatigue elastocaloric heating and cooling mechanism and further demonstrates a continuous rotary-driven cooling prototype using polycrcrystalline Ni50.7Ti48.9. Elastocaloric material performance is determined using infrared thermography during uniaxial-tension and four-point bending thermomechanical testing. A systematic study reveals the effects of strain rate (from 0.001 to 0.025 s-1), maximum strain (from 2 to 8%), and strain mode on the temperature evolution, mechanical response, and coefficient of performance. Four-point bending experiments demonstrate a temperature reduction up to 11.3{\deg}C, material coefficients of performance between 2.31 and 21.71, and a 6.09- to 7.75-fold reduction in required actuation force compared to uniaxial tension. The absence of L\"uders bands and reduced mechanical dissipation during flexure represent reduced microstructure degradation and improved fatigue life. The rotary-based elastocaloric cooling prototype is shown to provide similar thermomechanical performance with the added benefit of discrete hot and cold zones, continuous cooling, inexpensive rotary actuation, and scalability, which represents a significant advancement for compact, long lifetime, and inexpensive elastocaloric cooling.