SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2017601290> ?p ?o ?g. }

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

W2017601290 endingPage "734" @default.
W2017601290 startingPage "718" @default.
W2017601290 abstract "This paper is a part of a recent series of studies by the authors to develop universal predictive tools for pressure drop and heat transfer coefficient for mini/micro-channel flows that are capable of tackling fluids with drastically different thermophysical properties and very broad ranges of all geometrical and flow parameters of practical interest. In this study, a new technique is proposed to predict the frictional pressure gradient for saturated flow boiling. To both develop and validate the new technique, a consolidated database consisting of 2378 data points is amassed from 16 sources. The database consists of 9 working fluids, hydraulic diameters from 0.349 to 5.35 mm, mass velocities from 33 to 2738 kg/m2s, liquid-only Reynolds numbers from 156 to 28,010, qualities from 0 to 1, reduced pressures from 0.005 to 0.78, and both single-channel and multi-channel data. Careful examination of many prior models and correlations shows clear differences in frictional pressure gradient predictions between non-boiling (adiabatic and condensing) versus boiling mini/micro-channel flows that are caused by differences in flow structure, especially droplet entrainment effects. A separated flow technique previously developed by the authors for non-boiling mini/micro-channel flows is modified to account for these differences. The new technique shows very good predictions of the entire consolidated database, evidenced by an overall MAE of 17.2% and even predictive accuracy for different working fluids, and over broad ranges of hydraulic diameter, mass velocity, quality and pressure, and for both single and multiple mini/micro-channels." @default.
W2017601290 created "2016-06-24" @default.
W2017601290 creator A5030653020 @default.
W2017601290 creator A5080009425 @default.
W2017601290 date "2013-03-01" @default.
W2017601290 modified "2023-10-06" @default.
W2017601290 title "Universal approach to predicting two-phase frictional pressure drop for mini/micro-channel saturated flow boiling" @default.
W2017601290 cites W1963743205 @default.
W2017601290 cites W1967019043 @default.
W2017601290 cites W1967084038 @default.
W2017601290 cites W1967137646 @default.
W2017601290 cites W1967536964 @default.
W2017601290 cites W1973445566 @default.
W2017601290 cites W1973512043 @default.
W2017601290 cites W1973516065 @default.
W2017601290 cites W1975045869 @default.
W2017601290 cites W1975116394 @default.
W2017601290 cites W1978294611 @default.
W2017601290 cites W1979182722 @default.
W2017601290 cites W1980322901 @default.
W2017601290 cites W1983430285 @default.
W2017601290 cites W1985187828 @default.
W2017601290 cites W1985498571 @default.
W2017601290 cites W1990353002 @default.
W2017601290 cites W1993961095 @default.
W2017601290 cites W1997408423 @default.
W2017601290 cites W2001391163 @default.
W2017601290 cites W2005096126 @default.
W2017601290 cites W2007489027 @default.
W2017601290 cites W2011351939 @default.
W2017601290 cites W2015100536 @default.
W2017601290 cites W2015169564 @default.
W2017601290 cites W2015601913 @default.
W2017601290 cites W2018865338 @default.
W2017601290 cites W2020309076 @default.
W2017601290 cites W2021616963 @default.
W2017601290 cites W2023877760 @default.
W2017601290 cites W2023895358 @default.
W2017601290 cites W2024231571 @default.
W2017601290 cites W2026391198 @default.
W2017601290 cites W2027652022 @default.
W2017601290 cites W2030793799 @default.
W2017601290 cites W2031182931 @default.
W2017601290 cites W2033480915 @default.
W2017601290 cites W2034067355 @default.
W2017601290 cites W2034331428 @default.
W2017601290 cites W2037251669 @default.
W2017601290 cites W2038068215 @default.
W2017601290 cites W2039278331 @default.
W2017601290 cites W2040671971 @default.
W2017601290 cites W2041606062 @default.
W2017601290 cites W2041878330 @default.
W2017601290 cites W2043267633 @default.
W2017601290 cites W2059824169 @default.
W2017601290 cites W2059861994 @default.
W2017601290 cites W2064180392 @default.
W2017601290 cites W2064916413 @default.
W2017601290 cites W2069809377 @default.
W2017601290 cites W2072763737 @default.
W2017601290 cites W2075592407 @default.
W2017601290 cites W2081035561 @default.
W2017601290 cites W2083927591 @default.
W2017601290 cites W2084855976 @default.
W2017601290 cites W2086328034 @default.
W2017601290 cites W2086333565 @default.
W2017601290 cites W2087703288 @default.
W2017601290 cites W2088875386 @default.
W2017601290 cites W2091403836 @default.
W2017601290 cites W2092884317 @default.
W2017601290 cites W2093677593 @default.
W2017601290 cites W2104529521 @default.
W2017601290 cites W2126289622 @default.
W2017601290 cites W2142798234 @default.
W2017601290 cites W2143937923 @default.
W2017601290 cites W2169092245 @default.
W2017601290 cites W2171813442 @default.
W2017601290 cites W2736774462 @default.
W2017601290 cites W2799092247 @default.
W2017601290 cites W4247872955 @default.
W2017601290 doi "https://doi.org/10.1016/j.ijheatmasstransfer.2012.11.045" @default.
W2017601290 hasPublicationYear "2013" @default.
W2017601290 type Work @default.
W2017601290 sameAs 2017601290 @default.
W2017601290 citedByCount "148" @default.
W2017601290 countsByYear W20176012902013 @default.
W2017601290 countsByYear W20176012902014 @default.
W2017601290 countsByYear W20176012902015 @default.
W2017601290 countsByYear W20176012902016 @default.
W2017601290 countsByYear W20176012902017 @default.
W2017601290 countsByYear W20176012902018 @default.
W2017601290 countsByYear W20176012902019 @default.
W2017601290 countsByYear W20176012902020 @default.
W2017601290 countsByYear W20176012902021 @default.
W2017601290 countsByYear W20176012902022 @default.
W2017601290 countsByYear W20176012902023 @default.
W2017601290 crossrefType "journal-article" @default.
W2017601290 hasAuthorship W2017601290A5030653020 @default.
W2017601290 hasAuthorship W2017601290A5080009425 @default.