FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2998112113> ?p ?o ?g. }

• W2998112113 abstract "A model of dynamics of the vapor bubbles that emerge on solid surfaces of porous structures and the steam generating wall (bottom layer) is presented in this work. The model was filmed and photographed by a high-speed camera SKS-1М. The discharge of high heat flows (up to 2·106 W/m2) was maintained by the joint action of capillary and mass forces with the help of intensifiers. An analytical model was developed based on the theory of thermoelasticity. The limit state of the porous coating with poor thermal conductivity and the metal bottom layer was determined. Heat flows were calculated from the spontaneous birth of the vapour nucleus (10–8) to the material destruction (102–103 s), thus the interval from the process of relaxation to the maximum process (destruction) was described. The size of the pullout particles determined in the model at the moment of porous coating destruction showed good congruence with the experimental data obtained at the optic stand. The destruction of coating under the compression forces occurs much earlier than the tension forces. It is probable that the destruction will happen under the impact of the compression and shear forces. The intervals of the heat flow when such destruction takes place are different for quartz and granite coating. Each thickness of the pullout particles under the impact of compression forces has its limit values of the heat flows, which are located within the mentioned intervals. As the specific heat flow in the heated layer increases and, therefore, the heating time decreases, the impact of the compression stresses increases as well. Despite the high resistance to compression, destruction from the compressive heat tension occurs in more favorable conditions immediately, and in diminutive volumes. Experimental testing units, test conditions, the outcome of the heat exchange crisis, the limit state of the surface and the calculation of critical heat flows are presented. The capillary porous system that works under the joint action of capillary and mass forces is studied. The system has advantages compared to pool boiling, thin-film evaporators and heat pipes." @default.
• W2998112113 created "2020-01-10" @default.
• W2998112113 creator A5017362809 @default.
• W2998112113 creator A5048799710 @default.
• W2998112113 date "2019-12-01" @default.
• W2998112113 modified "2023-09-27" @default.
• W2998112113 title "An Analysis of Heat Exchange Crisis in the Capillary Porous System for Cooling Parts of Heat and Power Units" @default.
• W2998112113 doi "https://doi.org/10.18698/0536-1044-2019-12-21-35" @default.
• W2998112113 hasPublicationYear "2019" @default.
• W2998112113 type Work @default.
• W2998112113 sameAs 2998112113 @default.
• W2998112113 citedByCount "0" @default.
• W2998112113 crossrefType "journal-article" @default.
• W2998112113 hasAuthorship W2998112113A5017362809 @default.
• W2998112113 hasAuthorship W2998112113A5048799710 @default.
• W2998112113 hasConcept C107706546 @default.
• W2998112113 hasConcept C121332964 @default.
• W2998112113 hasConcept C159188206 @default.
• W2998112113 hasConcept C159985019 @default.
• W2998112113 hasConcept C192562407 @default.
• W2998112113 hasConcept C196806460 @default.
• W2998112113 hasConcept C2781448156 @default.
• W2998112113 hasConcept C50517652 @default.
• W2998112113 hasConcept C57879066 @default.
• W2998112113 hasConcept C6648577 @default.
• W2998112113 hasConcept C97355855 @default.
• W2998112113 hasConceptScore W2998112113C107706546 @default.
• W2998112113 hasConceptScore W2998112113C121332964 @default.
• W2998112113 hasConceptScore W2998112113C159188206 @default.
• W2998112113 hasConceptScore W2998112113C159985019 @default.
• W2998112113 hasConceptScore W2998112113C192562407 @default.
• W2998112113 hasConceptScore W2998112113C196806460 @default.
• W2998112113 hasConceptScore W2998112113C2781448156 @default.
• W2998112113 hasConceptScore W2998112113C50517652 @default.
• W2998112113 hasConceptScore W2998112113C57879066 @default.
• W2998112113 hasConceptScore W2998112113C6648577 @default.
• W2998112113 hasConceptScore W2998112113C97355855 @default.
• W2998112113 hasLocation W29981121131 @default.
• W2998112113 hasOpenAccess W2998112113 @default.
• W2998112113 hasPrimaryLocation W29981121131 @default.
• W2998112113 hasRelatedWork W10041369 @default.
• W2998112113 hasRelatedWork W15152949 @default.
• W2998112113 hasRelatedWork W15266706 @default.
• W2998112113 hasRelatedWork W16858108 @default.
• W2998112113 hasRelatedWork W23596899 @default.
• W2998112113 hasRelatedWork W25724108 @default.
• W2998112113 hasRelatedWork W26317301 @default.
• W2998112113 hasRelatedWork W307306 @default.
• W2998112113 hasRelatedWork W7204530 @default.
• W2998112113 hasRelatedWork W8185754 @default.
• W2998112113 isParatext "false" @default.
• W2998112113 isRetracted "false" @default.
• W2998112113 magId "2998112113" @default.
• W2998112113 workType "article" @default.