Etude d'un cycle frigorifique monoétagé à mélange de gaz pour le refroidissement avec charges thermiques réparties.

Study of the single-stage mixed-gases refrigeration cycle for cooling temperature-distributed heat loads.

Auteurs : GONG M., WU J., LUO E., et al.

Type d'article : Article

Résumé

The single-stage mixture refrigeration cycle is the simplest of numerous existing mixture refrigeration cycles. In this article, the use of a single-stage closed throttling refrigeration cycle with multicomponent zeotropic mixtures for cooling temperature-distributed heat loads was investigated. The heat capacity balance of the heat exchanger with temperature-distributed heat loads was calculated with an equation of state. Because of the important contribution of specific heat capacity from latent heat, the results showed that with optimal mixtures, the single-stage cycle can provide excellent performance for cooling temperature-distributed heat loads associated with gas liquefaction. The optimization result was also compared with other published results. A small-scale prototype based on the single-stage cycle was also developed and tested; it is driven by an oil-lubricated air-conditioning compressor with a nominal input power of 1.1 kW. Electrical resistances were used to simulate the temperature-distributed heat loads along the heat exchanger. The temperature-distributed heat loads were just used to simulate the gas liquefaction heat loads. Preliminary experimental results of 0.77 litre liquid methane per 1.2 kW/h and 1.3 litre liquid CF4 per 1.2 kW/h were achieved. The significance of using a single-stage mixture refrigeration cycle is that the configuration of the refrigeration system becomes much simpler than the traditional liquefaction system, while maintaining a high efficiency.

Détails

  • Titre original : Study of the single-stage mixed-gases refrigeration cycle for cooling temperature-distributed heat loads.
  • Identifiant de la fiche : 2004-1549
  • Langues : Anglais
  • Source : International Journal of thermal Sciences - vol. 43 - n. 1
  • Date d'édition : 01/2004

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