FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2500047089> ?p ?o ?g. }

• W2500047089 endingPage "233" @default.
• W2500047089 startingPage "201" @default.
• W2500047089 abstract "Abstract Investigation of heat transfer at supercritical pressures began as early as the 1930s with the study of free-convection heat transfer to fluids at the near-critical point. In the 1950s, the concept of using supercritical “steam” to increase the thermal efficiency of fossil-fired thermal power plants became an attractive option. The USA, the former USSR, Germany, and some other countries extensively studied supercritical heat transfer during the 1950s till the 1980s. The research was primarily focused around water-cooled circular-tube flow geometry. Currently, the use of supercritical “steam” in fossil-fired thermal power plants is the largest industrial application of fluids at supercritical pressures. Near the end of the 1950s and at the beginning of the 1960s, several studies were conducted to investigate the potential of using supercritical water as a coolant in nuclear reactors. However, these activities were abandoned for some time and regained momentum in 1990s. The primary objectives for using supercritical water as a coolant in nuclear reactors are (1) to increase the thermal efficiency of modern nuclear power plants, which is currently 30–36%, to approximately 45% or even higher; (2) to decrease the operational and capital costs by eliminating steam generators, steam separators, steam dryers, etc.; and (3) possible cogeneration of hydrogen through thermochemical cycles. In support of the development of supercritical water-cooled nuclear reactor concepts, it is necessary to perform a heat-transfer analysis. As the first step in this process, heat transfer to supercritical water in bare vertical tubes can be investigated as a conservative approach (in general, heat transfer in fuel bundles will be enhanced with various types of appendages, i.e. grids, end plates, spacers, bearing pads, fins, ribs, etc.). A comparison of selected supercritical-water heat-transfer correlations has shown that their results may differ from one another by more than 200%. Based on these comparisons, it became evident that there is a need for a reliable, accurate, and wide-range supercritical-water heat-transfer correlation to be used. For this reason, the new Mokry et al. correlation was used in the presented analyses. The objective of this review is to assess the work performed concerning thermophysical properties and the associated heat transfer and pressure drop at supercritical pressures, based on examples of water and carbon dioxide." @default.
• W2500047089 created "2016-08-23" @default.
• W2500047089 creator A5048622791 @default.
• W2500047089 date "2014-01-01" @default.
• W2500047089 modified "2023-10-14" @default.
• W2500047089 title "Application of Supercritical Pressure in Power Engineering" @default.
• W2500047089 cites W1555115840 @default.
• W2500047089 cites W1966511772 @default.
• W2500047089 cites W1972581853 @default.
• W2500047089 cites W1976823003 @default.
• W2500047089 cites W1988518769 @default.
• W2500047089 cites W2001795581 @default.
• W2500047089 cites W2007756528 @default.
• W2500047089 cites W2019004909 @default.
• W2500047089 cites W2031049028 @default.
• W2500047089 cites W2046671481 @default.
• W2500047089 cites W2050074602 @default.
• W2500047089 cites W2054597284 @default.
• W2500047089 cites W2074976029 @default.
• W2500047089 cites W2075169679 @default.
• W2500047089 cites W2097426384 @default.
• W2500047089 cites W2100956312 @default.
• W2500047089 cites W2130961501 @default.
• W2500047089 doi "https://doi.org/10.1016/b978-0-444-62696-7.00011-3" @default.
• W2500047089 hasPublicationYear "2014" @default.
• W2500047089 type Work @default.
• W2500047089 sameAs 2500047089 @default.
• W2500047089 citedByCount "7" @default.
• W2500047089 countsByYear W25000470892015 @default.
• W2500047089 countsByYear W25000470892016 @default.
• W2500047089 countsByYear W25000470892017 @default.
• W2500047089 countsByYear W25000470892020 @default.
• W2500047089 countsByYear W25000470892021 @default.
• W2500047089 countsByYear W25000470892023 @default.
• W2500047089 crossrefType "book-chapter" @default.
• W2500047089 hasAuthorship W2500047089A5048622791 @default.
• W2500047089 hasConcept C118419359 @default.
• W2500047089 hasConcept C121332964 @default.
• W2500047089 hasConcept C192562407 @default.
• W2500047089 hasConcept C97355855 @default.
• W2500047089 hasConceptScore W2500047089C118419359 @default.
• W2500047089 hasConceptScore W2500047089C121332964 @default.
• W2500047089 hasConceptScore W2500047089C192562407 @default.
• W2500047089 hasConceptScore W2500047089C97355855 @default.
• W2500047089 hasLocation W25000470891 @default.
• W2500047089 hasOpenAccess W2500047089 @default.
• W2500047089 hasPrimaryLocation W25000470891 @default.
• W2500047089 hasRelatedWork W2097734592 @default.
• W2500047089 hasRelatedWork W2316032560 @default.
• W2500047089 hasRelatedWork W2357086870 @default.
• W2500047089 hasRelatedWork W2370685986 @default.
• W2500047089 hasRelatedWork W2371292460 @default.
• W2500047089 hasRelatedWork W2382967792 @default.
• W2500047089 hasRelatedWork W2899084033 @default.
• W2500047089 hasRelatedWork W3196163622 @default.
• W2500047089 hasRelatedWork W4244441149 @default.
• W2500047089 hasRelatedWork W2130313128 @default.
• W2500047089 isParatext "false" @default.
• W2500047089 isRetracted "false" @default.
• W2500047089 magId "2500047089" @default.
• W2500047089 workType "book-chapter" @default.