SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3038018614> ?p ?o ?g. }

Showing items 1 to 100 of ±110 with 100 items per page.

W3038018614 endingPage "110205" @default.
W3038018614 startingPage "110205" @default.
W3038018614 abstract "The knowledge of wave structure and velocity is of great importance to the prediction of annular two-phase flow phenomena. Given that most existing experimental studies focus on the low liquid flow rate, the goal of this study is to extend the understanding of wave characteristics to high liquid flow rate annular flow, i.e. wispy annular flow. Conductance film thickness probes have been used to measure the film structure of upward annular flow at a high temporal resolution. The inlet superficial gas velocity ranges from 10 m/s to 30 m/s and the range of inlet superficial liquid velocity is from 0.06 m/s to 2 m/s. Important parameters including average film thickness, wave height, base film thickness, wave frequency, wave velocity, and interfacial shear stress are measured and analyzed. Existing models for predicting these parameters are comprehensively reviewed and evaluated using the new data. The evaluation results indicate that although these models are developed for annular flow with low liquid flow rates, some of them can also be used in wispy annular flow with reasonable prediction accuracy, except for wave velocity models. The measured wave velocity in wispy annular flow is significantly higher than that in typical annular flow. A new correlation for wispy annular flow wave velocity is developed based on the new data." @default.
W3038018614 created "2020-07-02" @default.
W3038018614 creator A5037543721 @default.
W3038018614 creator A5059449750 @default.
W3038018614 creator A5085470186 @default.
W3038018614 date "2021-01-01" @default.
W3038018614 modified "2023-10-11" @default.
W3038018614 title "Wave structure and velocity in vertical upward annular two-phase flow" @default.
W3038018614 cites W1963743205 @default.
W3038018614 cites W1964702221 @default.
W3038018614 cites W1966662813 @default.
W3038018614 cites W1970022240 @default.
W3038018614 cites W1973734214 @default.
W3038018614 cites W1974774542 @default.
W3038018614 cites W1975901848 @default.
W3038018614 cites W1976237106 @default.
W3038018614 cites W1979827710 @default.
W3038018614 cites W1999001812 @default.
W3038018614 cites W2002725695 @default.
W3038018614 cites W2004391058 @default.
W3038018614 cites W2008445688 @default.
W3038018614 cites W2009257798 @default.
W3038018614 cites W2014489327 @default.
W3038018614 cites W2022584965 @default.
W3038018614 cites W2029612389 @default.
W3038018614 cites W2034199822 @default.
W3038018614 cites W2044152058 @default.
W3038018614 cites W2044762986 @default.
W3038018614 cites W2045132934 @default.
W3038018614 cites W2046137376 @default.
W3038018614 cites W2049309678 @default.
W3038018614 cites W2054842766 @default.
W3038018614 cites W2056800048 @default.
W3038018614 cites W2056990755 @default.
W3038018614 cites W2057047089 @default.
W3038018614 cites W2069957301 @default.
W3038018614 cites W2070677481 @default.
W3038018614 cites W2078067509 @default.
W3038018614 cites W2078206077 @default.
W3038018614 cites W2081856556 @default.
W3038018614 cites W2094438341 @default.
W3038018614 cites W2100850250 @default.
W3038018614 cites W2107370838 @default.
W3038018614 cites W2137535306 @default.
W3038018614 cites W2168323577 @default.
W3038018614 cites W2533905520 @default.
W3038018614 cites W2950536581 @default.
W3038018614 cites W2973742934 @default.
W3038018614 cites W2995124780 @default.
W3038018614 cites W391952020 @default.
W3038018614 cites W4211056035 @default.
W3038018614 cites W567899987 @default.
W3038018614 cites W641902968 @default.
W3038018614 cites W643036508 @default.
W3038018614 doi "https://doi.org/10.1016/j.expthermflusci.2020.110205" @default.
W3038018614 hasPublicationYear "2021" @default.
W3038018614 type Work @default.
W3038018614 sameAs 3038018614 @default.
W3038018614 citedByCount "25" @default.
W3038018614 countsByYear W30380186142021 @default.
W3038018614 countsByYear W30380186142022 @default.
W3038018614 countsByYear W30380186142023 @default.
W3038018614 crossrefType "journal-article" @default.
W3038018614 hasAuthorship W3038018614A5037543721 @default.
W3038018614 hasAuthorship W3038018614A5059449750 @default.
W3038018614 hasAuthorship W3038018614A5085470186 @default.
W3038018614 hasConcept C114793014 @default.
W3038018614 hasConcept C120665830 @default.
W3038018614 hasConcept C121332964 @default.
W3038018614 hasConcept C127313418 @default.
W3038018614 hasConcept C144308804 @default.
W3038018614 hasConcept C166693061 @default.
W3038018614 hasConcept C172120300 @default.
W3038018614 hasConcept C192562407 @default.
W3038018614 hasConcept C201289731 @default.
W3038018614 hasConcept C26682833 @default.
W3038018614 hasConcept C38349280 @default.
W3038018614 hasConcept C57879066 @default.
W3038018614 hasConceptScore W3038018614C114793014 @default.
W3038018614 hasConceptScore W3038018614C120665830 @default.
W3038018614 hasConceptScore W3038018614C121332964 @default.
W3038018614 hasConceptScore W3038018614C127313418 @default.
W3038018614 hasConceptScore W3038018614C144308804 @default.
W3038018614 hasConceptScore W3038018614C166693061 @default.
W3038018614 hasConceptScore W3038018614C172120300 @default.
W3038018614 hasConceptScore W3038018614C192562407 @default.
W3038018614 hasConceptScore W3038018614C201289731 @default.
W3038018614 hasConceptScore W3038018614C26682833 @default.
W3038018614 hasConceptScore W3038018614C38349280 @default.
W3038018614 hasConceptScore W3038018614C57879066 @default.
W3038018614 hasLocation W30380186141 @default.
W3038018614 hasOpenAccess W3038018614 @default.
W3038018614 hasPrimaryLocation W30380186141 @default.
W3038018614 hasRelatedWork W1996901009 @default.
W3038018614 hasRelatedWork W2001035143 @default.
W3038018614 hasRelatedWork W2057108160 @default.
W3038018614 hasRelatedWork W2065697493 @default.
W3038018614 hasRelatedWork W2379682260 @default.