Performance assessment of a rotary active magnetic regenerator prototype using gadolinium

We present the experimental results for a rotary magnetocaloric prototype that uses the concept of active
magnetic regeneration, presenting an alternative to conventional vapor compression cooling systems. Thirteen
packed-bed regenerators subjected to a rotating two-pole permanent magnet with a maximum magnetic field of
1.44 T are implemented. It is the first performance assessment of the prototype with gadolinium spheres as the
magnetocaloric refrigerant and water mixed with commercial ethylene glycol as the heat transfer fluid. The
importance of various operating parameters, such as fluid flow rate, cycle frequency, cold and hot reservoir
temperatures, and blow fraction on the system performance is reported. The cycle frequency and utilization
factor ranged from 0.5 to 1.7 Hz and 0.25 to 0.50, respectively. Operating near room temperature and employing
3.83 kg of gadolinium, the device produced cooling powers exceeding 800 W at a coefficient of performance of 4
or higher over a temperature span of above 10 K at 1.4 Hz. It was also shown that variations in the flow resistance
between the beds could significantly limit the system performance, and a method to correct those is presented.
The performance metrics presented here compare well with those of currently existing magnetocaloric devices.
Such a prototype could achieve efficiencies as high as conventional vapor compression systems without the use of
refrigerants that have high global warming potential.