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Détail de l'auteur
Auteur Samuele Piazzini
Documents disponibles écrits par cet auteur
Affiner la recherchePrediction of condensation in steam ejector for a refrigeration system / Giuseppe Grazzini in International journal of refrigeration, Vol. 34 N° 7 (Novembre 2011)
[article]
in International journal of refrigeration > Vol. 34 N° 7 (Novembre 2011) . - pp. 1641-1648
Titre : Prediction of condensation in steam ejector for a refrigeration system Titre original : Prévision de la condensation dans l'éjecteur à vapeur d'un système frigorifique Type de document : texte imprimé Auteurs : Giuseppe Grazzini, Auteur ; Adriano Milazzo, Auteur ; Samuele Piazzini, Auteur Année de publication : 2011 Article en page(s) : pp. 1641-1648 Note générale : Génie Mécanique Langues : Anglais (eng) Mots-clés : Ejector Condensation Subcooling Water Index. décimale : 621.5 Energie pneumatique. Machinerie et outils. Réfrigération Résumé : An experimental refrigeration system based on a two-stage steam ejector was set-up in the Thermodynamics and Heat Transfer Laboratory of our Department. The system optimization and realization have been described elsewhere ( [Grazzini and Mariani, 1998] and [Grazzini and Rocchetti, 2008] ). In both stages, primary flows are highly supersonic and reach low pressure and temperature levels. As usual in the literature, an ideal gas model was used during the design process. This paper is intended to check the validity of this assumption. In order to understand the actual working condition of our system, several models have been compared. The presence of high flow speed suggests the existence of metastable conditions. To set the border for the metastable region, the spinodal curve has been drawn. Isentropic expansion of vapour through the nozzle, modelled as ideal gas, seems well within the metastable zone. However, the Classic Nucleation Theory shows that the Wilson line is crossed at the nozzle throat. Condensation produces a marked difference in the conditions at the nozzle exit. Results coming from the present analysis will be used in further optimization of the experimental ejector design. DEWEY : 621.5 ISSN : 0140-7007 En ligne : http://www.sciencedirect.com/science/article/pii/S0140700710002264 [article] Prediction of condensation in steam ejector for a refrigeration system = Prévision de la condensation dans l'éjecteur à vapeur d'un système frigorifique [texte imprimé] / Giuseppe Grazzini, Auteur ; Adriano Milazzo, Auteur ; Samuele Piazzini, Auteur . - 2011 . - pp. 1641-1648.
Génie Mécanique
Langues : Anglais (eng)
in International journal of refrigeration > Vol. 34 N° 7 (Novembre 2011) . - pp. 1641-1648
Mots-clés : Ejector Condensation Subcooling Water Index. décimale : 621.5 Energie pneumatique. Machinerie et outils. Réfrigération Résumé : An experimental refrigeration system based on a two-stage steam ejector was set-up in the Thermodynamics and Heat Transfer Laboratory of our Department. The system optimization and realization have been described elsewhere ( [Grazzini and Mariani, 1998] and [Grazzini and Rocchetti, 2008] ). In both stages, primary flows are highly supersonic and reach low pressure and temperature levels. As usual in the literature, an ideal gas model was used during the design process. This paper is intended to check the validity of this assumption. In order to understand the actual working condition of our system, several models have been compared. The presence of high flow speed suggests the existence of metastable conditions. To set the border for the metastable region, the spinodal curve has been drawn. Isentropic expansion of vapour through the nozzle, modelled as ideal gas, seems well within the metastable zone. However, the Classic Nucleation Theory shows that the Wilson line is crossed at the nozzle throat. Condensation produces a marked difference in the conditions at the nozzle exit. Results coming from the present analysis will be used in further optimization of the experimental ejector design. DEWEY : 621.5 ISSN : 0140-7007 En ligne : http://www.sciencedirect.com/science/article/pii/S0140700710002264