SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2184236487> ?p ?o ?g. }

Showing items 1 to 100 of ±140 with 100 items per page.

W2184236487 endingPage "986" @default.
W2184236487 startingPage "980" @default.
W2184236487 abstract "The energy density of DBPFCs (direct borohydride–hydrogen peroxide fuel cells) is estimated for air-independent propulsion applications. The performance of DBPFCs containing heat-treated electrocatalysts supported on multiwalled carbon nanotubes is evaluated. The open circuit voltage and the maximum power density are 1.44 V and 243 mW/cm2, respectively, whereas the voltage efficiency is 17.9% at the maximum power density. Based on experimental results, the energy density is estimated to be 63.2 Wh/kg (87.1 Wh/L), which is much lower than those of other power sources. The degree of influence of various parameters on the energy density is ranked in the following order: fuel utilization efficiency > voltage efficiency > H2O2 (hydrogen peroxide) concentration > NaBH4 (sodium borohydride) concentration > maximum power density. Performance targets comprising of fuel utilization efficiency of 90%, voltage efficiency of 40%, H2O2 concentration of 50 wt%, NaBH4 concentration of 20 wt%, and maximum power density of 650 mW/cm2, have been determined. Under these conditions, the energy density and fuel volume are expected to be 378.5 Wh/kg (541.4 Wh/L) and 1.57 L, respectively, which would allow them to be used widely as power sources for air-independent propulsion." @default.
W2184236487 created "2016-06-24" @default.
W2184236487 creator A5000374920 @default.
W2184236487 creator A5074537006 @default.
W2184236487 creator A5077480578 @default.
W2184236487 date "2015-10-01" @default.
W2184236487 modified "2023-10-18" @default.
W2184236487 title "Estimating the energy density of direct borohydride–hydrogen peroxide fuel cell systems for air-independent propulsion applications" @default.
W2184236487 cites W1965181346 @default.
W2184236487 cites W1966315404 @default.
W2184236487 cites W1966969094 @default.
W2184236487 cites W1969846405 @default.
W2184236487 cites W1973607932 @default.
W2184236487 cites W1975839251 @default.
W2184236487 cites W1976270484 @default.
W2184236487 cites W1987060221 @default.
W2184236487 cites W1990796164 @default.
W2184236487 cites W1995215844 @default.
W2184236487 cites W1996263866 @default.
W2184236487 cites W2001755801 @default.
W2184236487 cites W2006949925 @default.
W2184236487 cites W2010225452 @default.
W2184236487 cites W2010249258 @default.
W2184236487 cites W2010799824 @default.
W2184236487 cites W2011758542 @default.
W2184236487 cites W2017582286 @default.
W2184236487 cites W2028676258 @default.
W2184236487 cites W2028823061 @default.
W2184236487 cites W2029727764 @default.
W2184236487 cites W2030680033 @default.
W2184236487 cites W2036208326 @default.
W2184236487 cites W2037222357 @default.
W2184236487 cites W2041721054 @default.
W2184236487 cites W2046553126 @default.
W2184236487 cites W2051073669 @default.
W2184236487 cites W2052916187 @default.
W2184236487 cites W2053336434 @default.
W2184236487 cites W2054833977 @default.
W2184236487 cites W2062446417 @default.
W2184236487 cites W2062747757 @default.
W2184236487 cites W2062774445 @default.
W2184236487 cites W2063801558 @default.
W2184236487 cites W2065535779 @default.
W2184236487 cites W2066802681 @default.
W2184236487 cites W2068014967 @default.
W2184236487 cites W2072734192 @default.
W2184236487 cites W2073364237 @default.
W2184236487 cites W2074880614 @default.
W2184236487 cites W2075180660 @default.
W2184236487 cites W2080604850 @default.
W2184236487 cites W2084378567 @default.
W2184236487 cites W2087926035 @default.
W2184236487 cites W2133236542 @default.
W2184236487 cites W2156895276 @default.
W2184236487 cites W2907896833 @default.
W2184236487 cites W2950436183 @default.
W2184236487 cites W817196397 @default.
W2184236487 doi "https://doi.org/10.1016/j.energy.2015.08.002" @default.
W2184236487 hasPublicationYear "2015" @default.
W2184236487 type Work @default.
W2184236487 sameAs 2184236487 @default.
W2184236487 citedByCount "16" @default.
W2184236487 countsByYear W21842364872016 @default.
W2184236487 countsByYear W21842364872017 @default.
W2184236487 countsByYear W21842364872018 @default.
W2184236487 countsByYear W21842364872020 @default.
W2184236487 countsByYear W21842364872021 @default.
W2184236487 countsByYear W21842364872022 @default.
W2184236487 countsByYear W21842364872023 @default.
W2184236487 crossrefType "journal-article" @default.
W2184236487 hasAuthorship W2184236487A5000374920 @default.
W2184236487 hasAuthorship W2184236487A5074537006 @default.
W2184236487 hasAuthorship W2184236487A5077480578 @default.
W2184236487 hasConcept C1034443 @default.
W2184236487 hasConcept C113196181 @default.
W2184236487 hasConcept C116915560 @default.
W2184236487 hasConcept C119599485 @default.
W2184236487 hasConcept C121332964 @default.
W2184236487 hasConcept C127413603 @default.
W2184236487 hasConcept C147789679 @default.
W2184236487 hasConcept C161790260 @default.
W2184236487 hasConcept C163258240 @default.
W2184236487 hasConcept C165801399 @default.
W2184236487 hasConcept C17525397 @default.
W2184236487 hasConcept C178790620 @default.
W2184236487 hasConcept C185592680 @default.
W2184236487 hasConcept C192562407 @default.
W2184236487 hasConcept C21881925 @default.
W2184236487 hasConcept C2780048404 @default.
W2184236487 hasConcept C2985463592 @default.
W2184236487 hasConcept C42360764 @default.
W2184236487 hasConcept C512968161 @default.
W2184236487 hasConcept C533411734 @default.
W2184236487 hasConcept C89395315 @default.
W2184236487 hasConcept C9682599 @default.
W2184236487 hasConcept C97355855 @default.
W2184236487 hasConceptScore W2184236487C1034443 @default.
W2184236487 hasConceptScore W2184236487C113196181 @default.