Etude de performance d'un système de fabrication de glace à adsorption de type caloduc, polyvalent et de grande efficacité doté de nouveaux procédés de récupération de chaleur et de masse.

Performance study of a highly efficient multifunctional heat pipe type adsorption ice making system with novel mass and heat recovery processes.

Auteurs : LI T. X., WANG R. Z., WANG L. W., et al.

Type d'article : Article

Résumé

The purpose of this paper is to present the performance analysis of a multifunction heat pipe type adsorption ice maker with activated carbon-CaCl2 as compound adsorbent and ammonia as refrigerant. For this test unit, the heating, cooling and heat recovery processes between two adsorbent beds are performed by multifunction heat pipes. A novel mass and heat recovery adsorption refrigeration cycle is developed. When mass recovery process is implemented before heat recovery process, the performance of the cycle with novel mass and heat recovery processes is much better than that for the cycle with the conventional mass and heat recovery processes. The experimental results show that the former cycle can increase the COP and specific cooling power (SCP) by more than 17% compared with the latter cycle. In comparison with the basic adsorption cycle, the mass and heat recovery cycle can enlarge the cycled refrigerant mass and reduce the power consumption of boiler; the COP and SCP were improved by more than 11% when the mass recovery time was 20 s, while at the optimal mass recovery time of 40 s, the COP improvements for conventional and novel mass and heat recovery cycles are 43.8 and 68.7%, respectively. It was concluded that the novel mass and heat recovery processes are more beneficial to improve the performance of adsorption refrigeration system in comparison with the conventional mass and heat recovery processes. [Reprinted with permission from Elsevier. Copyright, 2007].

Détails

  • Titre original : Performance study of a highly efficient multifunctional heat pipe type adsorption ice making system with novel mass and heat recovery processes.
  • Identifiant de la fiche : 2008-0762
  • Langues : Anglais
  • Source : International Journal of thermal Sciences - vol. 46 - n. 12
  • Date d'édition : 12/2007

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