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W4280494237 startingPage "118622" @default.
W4280494237 abstract "Integrating metal hydride (MH) for hydrogen storage with phase change materials (PCMs) received increasing attention today to ensure effective thermal management in MH-storage reactors and reduce the operating cost of the process. This study revealed the first coupling approach (at large scale) of hydrogen storage in LaNi5 alloys with heat recovery by using a PCM loaded with nanoparticles (i.e. the MH-nano-PCM system) in a cylindrical MH-tank reactor (diameter: 1 m) equipped with four tubes of nano-PCM. Mass and heat transfer phenomena were computationally analyzed in the diverse regions of the reactor. The temporal temperature profiles (average and contours), the MH-hydrogenation efficiency, the velocity contours and PCM-liquid fraction were established in the presence (at 5% v/v) and absence of four types of nano-oxides (Al2O3, MgO, SnO2 and SiO2). Significant results were obtained. The nano-PCM system efficiently recuperates the heat lost from the exothermal absorption reaction; however, a slight reduction in the latent energy storage unit's performance is obtained compared to pure paraffin, probably due to the thermo-transfer resistant created by the nano-particles agglomeration during the melting cycle. The PCM-tube position plays a crucial role in the PCM melting rate, where the tube located above the H2-charging pipe melts more quickly than the other tubes." @default.
W4280494237 created "2022-05-22" @default.
W4280494237 creator A5011607168 @default.
W4280494237 creator A5025145863 @default.
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W4280494237 date "2022-08-01" @default.
W4280494237 modified "2023-10-15" @default.
W4280494237 title "Heat and mass transfer characteristics of charging in a metal hydride-phase change material reactor with nano oxide additives: The large scale-approach" @default.
W4280494237 cites W1662131158 @default.
W4280494237 cites W1858780293 @default.
W4280494237 cites W1910461738 @default.
W4280494237 cites W1968671164 @default.
W4280494237 cites W1969452858 @default.
W4280494237 cites W1972308906 @default.
W4280494237 cites W1997506344 @default.
W4280494237 cites W2002296495 @default.
W4280494237 cites W2012136380 @default.
W4280494237 cites W2014149686 @default.
W4280494237 cites W2021930098 @default.
W4280494237 cites W2029786920 @default.
W4280494237 cites W2032540229 @default.
W4280494237 cites W2035258007 @default.
W4280494237 cites W2046650465 @default.
W4280494237 cites W2046674818 @default.
W4280494237 cites W2050779718 @default.
W4280494237 cites W2058651654 @default.
W4280494237 cites W2064982060 @default.
W4280494237 cites W2066814782 @default.
W4280494237 cites W2076224867 @default.
W4280494237 cites W2082121289 @default.
W4280494237 cites W2082799466 @default.
W4280494237 cites W2088101573 @default.
W4280494237 cites W2088254324 @default.
W4280494237 cites W2094680648 @default.
W4280494237 cites W2121837178 @default.
W4280494237 cites W2156582295 @default.
W4280494237 cites W2189101993 @default.
W4280494237 cites W2196347028 @default.
W4280494237 cites W2207190483 @default.
W4280494237 cites W2341631474 @default.
W4280494237 cites W2394712747 @default.
W4280494237 cites W2490336040 @default.
W4280494237 cites W2589812516 @default.
W4280494237 cites W2614927102 @default.
W4280494237 cites W2733088462 @default.
W4280494237 cites W2742578126 @default.
W4280494237 cites W2794043420 @default.
W4280494237 cites W2795431645 @default.
W4280494237 cites W2796444718 @default.
W4280494237 cites W2796830317 @default.
W4280494237 cites W2810214257 @default.
W4280494237 cites W2884887364 @default.
W4280494237 cites W2886258901 @default.
W4280494237 cites W2912966611 @default.
W4280494237 cites W2913763325 @default.
W4280494237 cites W2915701402 @default.
W4280494237 cites W2945414860 @default.
W4280494237 cites W2971442178 @default.
W4280494237 cites W2973292738 @default.
W4280494237 cites W2979627963 @default.
W4280494237 cites W2981159167 @default.
W4280494237 cites W2988212305 @default.
W4280494237 cites W3003075903 @default.
W4280494237 cites W3020394035 @default.
W4280494237 cites W3022077551 @default.
W4280494237 cites W3024130543 @default.
W4280494237 cites W3035154428 @default.
W4280494237 cites W3045836352 @default.
W4280494237 cites W3082946405 @default.
W4280494237 cites W3087483547 @default.
W4280494237 cites W3090475428 @default.
W4280494237 cites W3108278657 @default.
W4280494237 cites W3118375922 @default.
W4280494237 cites W3135592555 @default.
W4280494237 cites W3171711765 @default.
W4280494237 cites W3192858413 @default.
W4280494237 cites W3196717362 @default.
W4280494237 cites W3198313709 @default.
W4280494237 cites W3212254908 @default.
W4280494237 cites W3213301446 @default.
W4280494237 cites W616261794 @default.
W4280494237 cites W987223101 @default.
W4280494237 doi "https://doi.org/10.1016/j.applthermaleng.2022.118622" @default.
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