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Latent heat storage

III) Latent heat storage, with fully mixed storage fluid. [Pg.39]

Bjurstrom, H., and B. Carlsson, 1985. An exergy analysis of sensible and latent heat storage, Heat Recovery Syst., 5, 233-250. [Pg.45]

Keywords Latent heat storage exergy analysis, thermoeconomics, economic analysis... [Pg.133]

Component 2 Latent heat storage system Removed exergy by the LHS system during charging is... [Pg.143]

Aceves-Saborio, S., Nakamura, H., and Reistad, G.M., 1994, Optimum efficiencies and phase change temperatures in latent heat storage systems, ASME J. Energy Res. Technol. 116 ... [Pg.148]

Bascetincelik, A., Ozturk, H.H., Paksoy, H.O., and Demirel, Y., 1999, Energetic and exer-getic efficiency of latent heat storage system for greenhouse heating, Renewable Energy 16 691-694. [Pg.149]

Cabeza, L.F., Roca, J., Noguee, M., Melding H., and Hiebler, S., 2005, Long term immersion corrosion tests on metal-PCM pairs used for latent heat storage in the 24 to 29 8 °C temperature range, Materials and Corrosion 56 33—38. [Pg.149]

Hidaka H., and Yamazaki M., 2004, New PCMs prepared from erythrito 1-polyalcohols mixtures for latent heat storage between 80 and 100 °C, J. Chem. Eng. Jap. 37 1155—1162. [Pg.150]

Ramayya, A.V., and Ramesh, K.N., 1998, Exergy analysis of latent heat storage system with sensible heating and subcooling of PCM, Int. J. Energy Res. 22 411—426. [Pg.150]

Shiina, Y., and Inagaki, T., 2005, Study on the efficiency of effective thermal conductivities on melting characteristics of latent heat storage capsules, Int. J. Heat Mass Transfer 48 373-383. [Pg.150]

Tun bilek, K., Sari, A., Tarhan, S., Ergunes, G., and Kaygusuz, K., 2005, Laurie and palmitic acids eutectic mixture as latent heat storage material for low temperature heating applications, Energy 30 677—692. [Pg.150]

Potential fields of application for PCM can be found directly from the basic difference between sensible and latent heat storage as explained in Figure 102. [Pg.259]

As Figure 102 shows, heat can be supplied or extracted from a latent heat storage material without significant temperature change. PCM can therefore be applied to stabilize the temperature in an application, for example the indoor temperature in a building or the temperature of the interior of transport boxes. [Pg.259]

It was concluded that the storage block is the most promising application. A prototype with approx. 4.1 kWh latent heat storage capacity was then built and is currently operated at Grammar. The storage (Figure 177) is charged via a 20 m2 collector with an air flow of 180-300 m3/h. [Pg.331]

The limitation of the storage capacity is, as mentioned before, caused by the limitation of entropy change AS within the storage (see Figure 4). For sensible and latent heat storage (so-called direct thermal energy storage) this is defined by the specific heat... [Pg.395]

The method of latent heat storage based on liquid-solid phase transition is available to make smaller the volume of heat storage tank, because of its higher thermal density than that of sensible heat storage. Therefore, a substance which has a large amount of latent heat of fusion is more profitable as a heat storage material. [Pg.395]

CaCl2 6H2O, characteristics for latent heat storage, 396 Caldum sulfate... [Pg.409]

Fig. 1.12. Maximum temperature (a) and ethylbenzene conversion (b) during one production cycle for a fixed bed of uniform heat capacity (dotted line), fora structured fixed-bed with inert end sections of higher heat capacity (dashed line), and for latent heat storage inside the catalytic section (solid line) [9]. Fig. 1.12. Maximum temperature (a) and ethylbenzene conversion (b) during one production cycle for a fixed bed of uniform heat capacity (dotted line), fora structured fixed-bed with inert end sections of higher heat capacity (dashed line), and for latent heat storage inside the catalytic section (solid line) [9].
A charging fluid heats the phase changing material, which may initially be at a subcooled temperature Tsc, and may eventually reach a temperature 7 sh after sensible heating. Therefore, the latent heat storage system undergoes a temperature difference of 7 sh 7 sc, as shown in Figure 5.19. Heat available for storage would be... [Pg.307]

Figure 5.18. Units of the latent heat storage system. Figure 5.18. Units of the latent heat storage system.
Figure 5.19. Approximate temperature profiles fora latent heat storage unit. Figure 5.19. Approximate temperature profiles fora latent heat storage unit.

See other pages where Latent heat storage is mentioned: [Pg.481]    [Pg.133]    [Pg.134]    [Pg.134]    [Pg.142]    [Pg.147]    [Pg.259]    [Pg.302]    [Pg.335]    [Pg.396]    [Pg.19]    [Pg.20]    [Pg.20]    [Pg.21]    [Pg.43]    [Pg.37]    [Pg.38]    [Pg.39]    [Pg.307]    [Pg.307]    [Pg.307]    [Pg.309]    [Pg.311]   
See also in sourсe #XX -- [ Pg.39 , Pg.133 , Pg.134 , Pg.141 , Pg.142 , Pg.147 , Pg.259 , Pg.302 , Pg.331 , Pg.335 , Pg.395 , Pg.396 ]

See also in sourсe #XX -- [ Pg.16 ]




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