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Combining liquid inertia and evaporation momentum forces to achieve flow boiling inversion and performance enhancement in asymmetric Dual V-groove microchannels

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Author(s):
Moreira, D. C. ; Nascimento, V. S. ; Ribatski, G. ; Kandlikar, S. G.
Total Authors: 4
Document type: Journal article
Source: INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER; v. 194, p. 14-pg., 2022-09-15.
Abstract

Increasing critical heat flux (CHF) and heat transfer coefficient (HTC), and reducing pressure drop (delta p) are highly desirable during flow boiling. An asymmetric Dual-V groove microchannels geometry was de-veloped and combined with a tapered open manifold to achieve significant performance enhancements in all three aspects while reporting boiling inversion for the first time in flow boiling. Evaporation momen-tum force is utilized to direct bubbles along a central region of the doubly-finned structure, while inertia force is utilized to create a two-phase flow in the microchannel flow passages formed by the fins. The microchannel passages are contoured as adjoining pairs of asymmetric Dual-V grooves. Bubbles nucleate at the corners of the V-grooves and the evaporation momentum force modulates their traverse over the inclined surfaces of the microchannels. High-speed video images reveal that the growing bubbles flow rapidly over the microchannel walls and emerge into the microgap region a certain distance away from their respective nucleation sites. This leads to a self-feeding mechanism that causes boiling inversion in which wall superheat drops with increase in heat flux. Early departure from the nucleation site before fully growing improves the CHF and the bubble traverse normal to flow direction improves HTC. Further-more, the momentum of the growing bubbles in the tapered open microgap configuration reduces the pressure drop. Using water as working fluid, we have reached a heat dissipation of 508.1 W/cm(2) without reaching CHF at a wall superheat of 12.3 C with a pressure drop of only 3 kPa. The resulting HTC was 412.2 kW/(m(2) K). (C) 2022 Elsevier Ltd. All rights reserved. (AU)

FAPESP's process: 17/12576-5 - Design and experimental evaluation of microchannels-based thermal absorbers for solar collectors
Grantee:Debora Carneiro Moreira
Support Opportunities: Scholarships abroad - Research Internship - Post-doctor
FAPESP's process: 15/24834-3 - Development of high performance heat spreaders based on multi-microchannels with micro- and nanostructured surfaces aiming at applications in solar absorbers
Grantee:Debora Carneiro Moreira
Support Opportunities: Scholarships in Brazil - Post-Doctoral
FAPESP's process: 16/09509-1 - Phase change heat transfer processes of high performance applied to solar energy recovery
Grantee:Gherhardt Ribatski
Support Opportunities: Research Projects - Thematic Grants
FAPESP's process: 18/23538-0 - MULTICHANNELS FABRICATION FOR DEVELOPMENT OF HIGH PERFORMANCE PROCESSES INVOLVING HEAT TRANSFER WITH PHASE CHANGE APPLIED TO SOLAR ENERGY USE
Grantee:Valter Salles do Nascimento Junior
Support Opportunities: Scholarships in Brazil - Post-Doctoral