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Design and Analysis of a Nested Halbach Permanent Magnet Magnetic Refrigerator

A technology with the potential to create efficient and compact refrigeration devices is
an active magnetic regenerative refrigerator (AMRR). AMRRs exploit the
magnetocaloric effect displayed by magnetic materials whereby a reversible temperature
change is induced when the material is exposed to a change in applied magnetic field. By
using the magnetic materials in a regenerator as the heat storage medium and as the
means of work input, one creates an active magnetic regenerator (AMR). Although
several laboratory devices have been developed, no design has yet demonstrated the
performance, reliability, and cost needed to compete with traditional vapor compression
refrigerators. There are many reasons for this and questions remain as to the actual
potential of the technology.
The objective of the work described in this thesis is to quantify the actual and potential
performance of a permanent magnet AMR system. A specific device configuration
known as a dual-nested-Halbach system is studied in detail. A laboratory scale device is
created and characterized over a wide range of operating parameters. A numerical model
of the device is created and validated against experimental data. The resulting model is
used to create a cost-minimization tool to analyze the conditions needed to achieve
specified cost and efficiency targets.
Experimental results include cooling power, temperature span, pumping power and
work input. Although the magnetocaloric effect of gadolinium is small, temperature
spans up to 30 K are obtained. Analysis of power input shows that the inherent magnetic
work is a small fraction of the total work input confirming the assumption that potential

cycle efficiencies can be large. Optimization of the device generates a number of areas
for improvement and specific results depend upon targeted temperature spans and cooling
powers. A competitive cost of cooling from a dual-nested-Halbach configuration is
challenging and will depend on the ability to create regenerator matrices with near-ideal
adiabatic temperature change scaling as a function of temperature. / Graduate / 0548 / 0791 / 0607 / atura@uvic.ca

Identiferoai:union.ndltd.org:uvic.ca/oai:dspace.library.uvic.ca:1828/4783
Date19 August 2013
CreatorsTura, Armando
ContributorsRowe, Andrew Michael
Source SetsUniversity of Victoria
LanguageEnglish, English
Detected LanguageEnglish
TypeThesis
RightsAvailable to the World Wide Web

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