SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3080783268> ?p ?o ?g. }

Showing items 1 to 100 of ±156 with 100 items per page.

W3080783268 endingPage "101778" @default.
W3080783268 startingPage "101778" @default.
W3080783268 abstract "Abstract Hybrid kind of thermal management systems (TMSs) is emerging as a powerful, reliable, and efficient cooling device for controlling the temperature of Li-ion cells in the battery pack of an electric vehicle. Adding metal foams to a pure PCM (which results in a composite material) is a suitable way for the enhancement of the passive part's performance. In this paper, a novel hybrid TMS that uses cooling water channels (as the active part of TMS) and a composite of paraffin PCM and Al foam surrounding each lithium 18650 cylindrical cell (as the passive part of TMS) is introduced, and the role of foam anisotropy (according to the three main axial, radial, and tangential directions in the cylindrical coordinate system) on its performance is investigated, for the first time. The results of this study show that the hybrid operating mode of TMS consists of two periods: PCM recovery and cell cooling. In the first period, most of the water's cooling capability is paid for the solidification of PCM through a progressive process from top to bottom; and hence, less cell cooling effect is achievable. The results demonstrate that only increasing the tangential conductivity has a notable positive effect on the average cell temperature and the liquid fraction. Additionally, only increasing the axial thermal conductivity has a positive effect on the controlling of the maximum temperature difference through the cell." @default.
W3080783268 created "2020-09-01" @default.
W3080783268 creator A5009592972 @default.
W3080783268 creator A5034674260 @default.
W3080783268 creator A5057036615 @default.
W3080783268 date "2020-12-01" @default.
W3080783268 modified "2023-09-26" @default.
W3080783268 title "Role of foam anisotropy used in the phase-change composite material for the hybrid thermal management system of lithium-ion battery" @default.
W3080783268 cites W1433382471 @default.
W3080783268 cites W1965634670 @default.
W3080783268 cites W1968385512 @default.
W3080783268 cites W1977520694 @default.
W3080783268 cites W1984899867 @default.
W3080783268 cites W1985839707 @default.
W3080783268 cites W1996649544 @default.
W3080783268 cites W2023248330 @default.
W3080783268 cites W2026074071 @default.
W3080783268 cites W2055023990 @default.
W3080783268 cites W2065535779 @default.
W3080783268 cites W2088181754 @default.
W3080783268 cites W2197515183 @default.
W3080783268 cites W2217071023 @default.
W3080783268 cites W2295269567 @default.
W3080783268 cites W2418122581 @default.
W3080783268 cites W2463802614 @default.
W3080783268 cites W2480376784 @default.
W3080783268 cites W2484947688 @default.
W3080783268 cites W2513511139 @default.
W3080783268 cites W2516484088 @default.
W3080783268 cites W2552104536 @default.
W3080783268 cites W2611079843 @default.
W3080783268 cites W2613389393 @default.
W3080783268 cites W2728448076 @default.
W3080783268 cites W2737697189 @default.
W3080783268 cites W2757640801 @default.
W3080783268 cites W2765316395 @default.
W3080783268 cites W2770588592 @default.
W3080783268 cites W2774749758 @default.
W3080783268 cites W2781783527 @default.
W3080783268 cites W2790820685 @default.
W3080783268 cites W2809374274 @default.
W3080783268 cites W2809975514 @default.
W3080783268 cites W2888395579 @default.
W3080783268 cites W2888706702 @default.
W3080783268 cites W2891455674 @default.
W3080783268 cites W2899457642 @default.
W3080783268 cites W2901701492 @default.
W3080783268 cites W2907599189 @default.
W3080783268 cites W2930261547 @default.
W3080783268 cites W2946488662 @default.
W3080783268 cites W2947455708 @default.
W3080783268 cites W2966607880 @default.
W3080783268 cites W2969213688 @default.
W3080783268 cites W2978357748 @default.
W3080783268 cites W2983402152 @default.
W3080783268 cites W2985368154 @default.
W3080783268 cites W2986109549 @default.
W3080783268 cites W2989349780 @default.
W3080783268 cites W2989353516 @default.
W3080783268 cites W2990095460 @default.
W3080783268 cites W2990212845 @default.
W3080783268 cites W2991040400 @default.
W3080783268 cites W2991518591 @default.
W3080783268 cites W2993629702 @default.
W3080783268 cites W2997116942 @default.
W3080783268 cites W2997927316 @default.
W3080783268 cites W2998560094 @default.
W3080783268 cites W3000956022 @default.
W3080783268 cites W3004698989 @default.
W3080783268 cites W3005857912 @default.
W3080783268 cites W3011693377 @default.
W3080783268 cites W3012164571 @default.
W3080783268 cites W3033364666 @default.
W3080783268 cites W3034050493 @default.
W3080783268 doi "https://doi.org/10.1016/j.est.2020.101778" @default.
W3080783268 hasPublicationYear "2020" @default.
W3080783268 type Work @default.
W3080783268 sameAs 3080783268 @default.
W3080783268 citedByCount "37" @default.
W3080783268 countsByYear W30807832682021 @default.
W3080783268 countsByYear W30807832682022 @default.
W3080783268 countsByYear W30807832682023 @default.
W3080783268 crossrefType "journal-article" @default.
W3080783268 hasAuthorship W3080783268A5009592972 @default.
W3080783268 hasAuthorship W3080783268A5034674260 @default.
W3080783268 hasAuthorship W3080783268A5057036615 @default.
W3080783268 hasConcept C104779481 @default.
W3080783268 hasConcept C114834414 @default.
W3080783268 hasConcept C121332964 @default.
W3080783268 hasConcept C127413603 @default.
W3080783268 hasConcept C133256868 @default.
W3080783268 hasConcept C134018914 @default.
W3080783268 hasConcept C145148216 @default.
W3080783268 hasConcept C159985019 @default.
W3080783268 hasConcept C163258240 @default.
W3080783268 hasConcept C178790620 @default.
W3080783268 hasConcept C185592680 @default.
W3080783268 hasConcept C192562407 @default.