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The influence of the magnetic field on the performance of an active magnetic regenerator (AMR) in Revue internationale du froid, vol 34, issue 1 (janvier 2011)
[article]
Titre : The influence of the magnetic field on the performance of an active magnetic regenerator (AMR) Titre original : Influence du champ magnétique actif sur la performance d'un régénérateur magnétique actif Type de document : texte imprimé Année de publication : 2012 Article en page(s) : pp. 192-203 Langues : Anglais (eng) Français (fre) Catégories : 621.5 : Technique pneumatique, du vide, des basses températures Mots-clés : Réfrigérateur magnétique; Champ magnétique; Simulation; Modélisation; Performance; Variation Index. décimale : 621.56 Technique des basses températures : réfrigération, pompe à chaleur Résumé : The influence of the time variation of the magnetic field, termed the magnetic field profile, on the performance of a magnetocaloric refrigeration device using the active magnetic regeneration (AMR) cycle is studied for a number of process parameters for both a parallel plate and packed bed regenerator using a numerical model. The cooling curve of the AMR is shown to be almost linear far from the Curie temperature of the magnetocaloric material. It is shown that a magnetic field profile that is 10% of the cycle time out of sync with the flow profile leads to a drop in both the maximum temperature span and the maximum cooling capacity of 20–40% for both parallel plate and packed bed regenerators. The maximum cooling capacity is shown to depend very weakly on the ramp rate of the magnetic field. Reducing the temporal width of the high field portion of the magnetic field profile by 10% leads to a drop in maximum temperature span and maximum cooling capacity of 5–20%. An increase of the magnetic field from 1 T to 1.5 T increases the maximum cooling capacity by 30–50% but the maximum temperature span by only 20–30%. Finally, it was seen that the influence of changing the magnetic field was more or less the same for the different regenerator geometries and operating parameters studied here. This means that the design of the magnet can be done independently of the regenerator geometry.
in Revue internationale du froid > vol 34, issue 1 (janvier 2011) . - pp. 192-203[article] The influence of the magnetic field on the performance of an active magnetic regenerator (AMR) = Influence du champ magnétique actif sur la performance d'un régénérateur magnétique actif [texte imprimé] . - 2012 . - pp. 192-203.
Langues : Anglais (eng) Français (fre)
in Revue internationale du froid > vol 34, issue 1 (janvier 2011) . - pp. 192-203
Catégories : 621.5 : Technique pneumatique, du vide, des basses températures Mots-clés : Réfrigérateur magnétique; Champ magnétique; Simulation; Modélisation; Performance; Variation Index. décimale : 621.56 Technique des basses températures : réfrigération, pompe à chaleur Résumé : The influence of the time variation of the magnetic field, termed the magnetic field profile, on the performance of a magnetocaloric refrigeration device using the active magnetic regeneration (AMR) cycle is studied for a number of process parameters for both a parallel plate and packed bed regenerator using a numerical model. The cooling curve of the AMR is shown to be almost linear far from the Curie temperature of the magnetocaloric material. It is shown that a magnetic field profile that is 10% of the cycle time out of sync with the flow profile leads to a drop in both the maximum temperature span and the maximum cooling capacity of 20–40% for both parallel plate and packed bed regenerators. The maximum cooling capacity is shown to depend very weakly on the ramp rate of the magnetic field. Reducing the temporal width of the high field portion of the magnetic field profile by 10% leads to a drop in maximum temperature span and maximum cooling capacity of 5–20%. An increase of the magnetic field from 1 T to 1.5 T increases the maximum cooling capacity by 30–50% but the maximum temperature span by only 20–30%. Finally, it was seen that the influence of changing the magnetic field was more or less the same for the different regenerator geometries and operating parameters studied here. This means that the design of the magnet can be done independently of the regenerator geometry.