论文信息 - Shape identification for water–ice interface within the cylindrical capsule in cold storage system by inverse heat transfer method

Shape identification for water–ice interface within the cylindrical capsule in cold storage system by inverse heat transfer method

In this study, the inverse heat transfer method is applied to shape identification for the ice layer within the cylindrical capsule in cold storage system. The approach is constructed by combining the curvilinear grid generation scheme, the direct problem solver, the conjugate gradient optimization method, and the redistribution method. According to the practical condition of freezing ice, shape identification for the water–ice interface based on the data of the outer surface temperature is attempted. Results show that the profile of the water–ice interface is possible to be identified by using the inverse heat transfer approach and the accuracy of the ice shape identification is dependent on the uncertainty of the outer surface temperature data, the Biot number, the thickness of the ice layer, and the geometric configuration as well.

Chin-Hsiang Cheng | Chin‐Hsiang Cheng | Mei-Hsia Chang | Mei-Hsia Chang

[1] Eun-Pil Kim,et al. Experimental study on freezing of water with supercooled region in a horizontal cylinder , 2001 .

[2] R. R. Gilpin,et al. The effects of dendritic ice formation in water pipes , 1977 .

[3] Matsuzawa Kazuyuki,et al. Fundamental research on the supercooling phenomenon on heat transfer surfaces—investigation of an effect of characteristics of surface and cooling rate on a freezing temperature of supercooled water , 1990 .

[4] Sih-Li Chen,et al. An experimental investigation of nucleation probability of supercooled water inside cylindrical capsules , 1998 .

[5] Chin-Hsiang Cheng, Chun-Yin Wu. AN APPROACH COMBINING BODY-FITTED GRID GENERATION AND CONJUGATE GRADIENT METHODS FOR SHAPE DESIGN IN HEAT CONDUCTION PROBLEMS , 2000 .

[6] Sih-Li Chen,et al. An experimental investigation of cold storage in an encapsulated thermal storage tank , 2000 .

[7] Chin-Hsiang Cheng,et al. SHAPE DESIGN FOR HEAT CONDUCTION PROBLEMS USING CURVILINEAR GRID GENERATION, CONJUGATE GRADIENT, AND REDISTRIBUTION METHODS , 2001 .

[8] M. Akyurt,et al. Freezing phenomena in ice–water systems , 2002 .

[9] I. Eames,et al. Freezing and melting of water in spherical enclosures of the type used in thermal (ice) storage systems , 2002 .

[10] Joe F. Thompson,et al. Automatic numerical generation of body-fitted curvilinear coordinate system for field containing any number of arbitrary two-dimensional bodies , 1974 .