SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2758461040> ?p ?o ?g. }

Showing items 1 to 100 of ±170 with 100 items per page.

W2758461040 endingPage "838" @default.
W2758461040 startingPage "818" @default.
W2758461040 abstract "The current study discusses a new design regarding embedded simple distiller to a solar collector cylindrical shape. Investigating the performance improvement is based on solving transit thermal energy balance equations which can predict temperatures in different locations of the still. Introducing the pre–heater system was also modeled using a third ordinary differential equation for water as a working fluid. In order to validate the obtained findings, Dunkle's model was employed and outputs compared to previous works. Results demonstrated that the collector contributes appreciably in augmenting the basin water temperature higher than a simple still case and both couples of distillate amounts and instantaneous efficiencies were respectively (∼2.77 kg/m2, ∼4 kg/m2) which an augmentation rate of yield of ∼ 44.40% and (∼40%, ∼80%) for the passive and active targets. The total cost of the collector materials was estimated to be about 63 US Dollars which represents a cheap price. Moreover, a critical issue was examined around heat losses of the proposed solar heater. At this stage, used empirical correlations available in literature enabling UL prediction (overall heat loss coefficient) of the former and flat–plate collector method has been performed. It was reached that the TSC can perform against a FPC with lower heat loss. Other parameters such as painted receiver, absorbtivity–emissivity effects and environmental circumstances have all influenced the TSC performance were also analyzed." @default.
W2758461040 created "2017-10-06" @default.
W2758461040 creator A5055070233 @default.
W2758461040 creator A5069480018 @default.
W2758461040 date "2017-12-01" @default.
W2758461040 modified "2023-10-18" @default.
W2758461040 title "Tubular solar-energy collector integration: Performance enhancement of classical distillation unit" @default.
W2758461040 cites W1615636353 @default.
W2758461040 cites W1968031518 @default.
W2758461040 cites W1974562423 @default.
W2758461040 cites W1976789733 @default.
W2758461040 cites W1978338836 @default.
W2758461040 cites W1985124309 @default.
W2758461040 cites W1987307560 @default.
W2758461040 cites W1988718031 @default.
W2758461040 cites W1990916906 @default.
W2758461040 cites W1991753806 @default.
W2758461040 cites W1993596447 @default.
W2758461040 cites W1995640457 @default.
W2758461040 cites W2002840513 @default.
W2758461040 cites W2007210283 @default.
W2758461040 cites W2009026870 @default.
W2758461040 cites W2009321337 @default.
W2758461040 cites W2012202891 @default.
W2758461040 cites W2014039556 @default.
W2758461040 cites W2021346774 @default.
W2758461040 cites W2021834744 @default.
W2758461040 cites W2032259208 @default.
W2758461040 cites W2033916676 @default.
W2758461040 cites W2052084248 @default.
W2758461040 cites W2053591921 @default.
W2758461040 cites W2057109419 @default.
W2758461040 cites W2060925711 @default.
W2758461040 cites W2063315947 @default.
W2758461040 cites W2065740957 @default.
W2758461040 cites W2069398847 @default.
W2758461040 cites W2073843466 @default.
W2758461040 cites W2076215993 @default.
W2758461040 cites W2077744428 @default.
W2758461040 cites W2080292030 @default.
W2758461040 cites W2082719576 @default.
W2758461040 cites W2088247716 @default.
W2758461040 cites W2089474584 @default.
W2758461040 cites W2102406694 @default.
W2758461040 cites W2111320669 @default.
W2758461040 cites W2133384963 @default.
W2758461040 cites W2205471807 @default.
W2758461040 cites W2211636657 @default.
W2758461040 cites W2224731722 @default.
W2758461040 cites W2262404033 @default.
W2758461040 cites W2277134273 @default.
W2758461040 cites W2279669307 @default.
W2758461040 cites W2284965738 @default.
W2758461040 cites W2286938817 @default.
W2758461040 cites W2337979667 @default.
W2758461040 cites W2353534392 @default.
W2758461040 cites W2403452253 @default.
W2758461040 cites W2417787117 @default.
W2758461040 cites W2490608617 @default.
W2758461040 cites W2516800791 @default.
W2758461040 cites W2518840709 @default.
W2758461040 cites W2520029423 @default.
W2758461040 cites W2520831967 @default.
W2758461040 cites W2534797555 @default.
W2758461040 cites W2550110283 @default.
W2758461040 cites W2554896931 @default.
W2758461040 cites W2563002513 @default.
W2758461040 cites W2563515187 @default.
W2758461040 cites W2568240202 @default.
W2758461040 cites W2569445516 @default.
W2758461040 cites W2570311788 @default.
W2758461040 cites W2584179645 @default.
W2758461040 cites W2586304318 @default.
W2758461040 cites W2587038611 @default.
W2758461040 cites W2588071283 @default.
W2758461040 cites W2591789044 @default.
W2758461040 cites W2598615128 @default.
W2758461040 cites W2601154749 @default.
W2758461040 cites W2604253068 @default.
W2758461040 cites W2604701545 @default.
W2758461040 cites W2605346136 @default.
W2758461040 cites W2605381871 @default.
W2758461040 cites W2609455396 @default.
W2758461040 cites W2618083951 @default.
W2758461040 cites W2619190789 @default.
W2758461040 cites W2620184718 @default.
W2758461040 cites W2622787130 @default.
W2758461040 cites W2623293347 @default.
W2758461040 cites W2625093079 @default.
W2758461040 cites W2714790369 @default.
W2758461040 cites W2723981098 @default.
W2758461040 cites W2727258149 @default.
W2758461040 cites W345075156 @default.
W2758461040 cites W1972052929 @default.
W2758461040 doi "https://doi.org/10.1016/j.energy.2017.09.110" @default.
W2758461040 hasPublicationYear "2017" @default.
W2758461040 type Work @default.
W2758461040 sameAs 2758461040 @default.