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An experimental study on the heat transfer and wettability characteristics of micro-structured surfaces during water vapor condensation under different pressure conditions

Title	An experimental study on the heat transfer and wettability characteristics of micro-structured surfaces during water vapor condensation under different pressure conditions
Author	Budaklı, M., Salem, T. K., Arık, Mehmet, Dönmez, B., Menceloglu, Y.
Publication Date:	2021-01
Publication Place	- Elsevier
Subject	Condensation, Electronics cooling, Heat transfer, Hydrophobicity, Micro-structuring, Polymer coating, Thermal management, Wettability
Type	Periodical
Language	English
Digital	Yes
Manuscript	No
Library:	Özyeğin University
Library Asset ID	0735-1933
Record ID	2d3461f3-47cf-4c6d-b099-ee32eaa8d399
Library Location	Mechanical Engineering
Date	2021-01
Notes	TÜBİTAK ; European Union’s The Seventh Framework Programme
Sample Text	In this study, condensation characteristics of water vapor on micro-structured surfaces at different pressures and subcooling temperature has been investigated experimentally. This work represents a basic study in order to design a secondary evaporator section in a refrigeration cycle. A set of surfaces has been manufactured over copper substrates with one sample used as unstructured (smooth) reference surface and two micro-structured surfaces with longitudinal grooves having V-shape and square cross-sections. As the second step, the surfaces have been modified by using a polymer coating to achieve stronger hydrophobicity at the surface and hence to influence wettability such that increased heat transfer rates should be reached. The polymer coating has been created with a dip coating process by applying a mixture of perfluoroalkyl triethoxysilane. Concerning the wettability, a high-speed flow visualization study has been performed for the interpretation of heat transfer results. Experimental results showed that an increase in the droplet contact angle by applying the polymer coating over surfaces, while the largest droplet contact angle was obtained (130.9°±2.0°) for the surface with V-shaped micro-structuring compared to other surfaces. The comparison of heat transfer performance reveals an enhancement in heat transfer coefficient for the coated version of unstructured, square-grooved and V-grooved surface by 34.5%, 61.8%, and 73.4%, respectively.
DOI	10.1016/j.icheatmasstransfer.2020.105063
Cilt	120

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Özyeğin University

An experimental study on the heat transfer and wettability characteristics of micro-structured surfaces during water vapor condensation under different pressure conditions

Author Budaklı, M., Salem, T. K., Arık, Mehmet, Dönmez, B., Menceloglu, Y.

Publication Date 2021-01

Publication Place - Elsevier

Subject Condensation, Electronics cooling, Heat transfer, Hydrophobicity, Micro-structuring, Polymer coating, Thermal management, Wettability

Type Periodical

Language English

Digital Yes

Manuscript No

Library Özyeğin University

Library Asset ID 0735-1933

Record ID 2d3461f3-47cf-4c6d-b099-ee32eaa8d399

Library Location Mechanical Engineering

Date 2021-01

Notes TÜBİTAK ; European Union’s The Seventh Framework Programme

Sample Text In this study, condensation characteristics of water vapor on micro-structured surfaces at different pressures and subcooling temperature has been investigated experimentally. This work represents a basic study in order to design a secondary evaporator section in a refrigeration cycle. A set of surfaces has been manufactured over copper substrates with one sample used as unstructured (smooth) reference surface and two micro-structured surfaces with longitudinal grooves having V-shape and square cross-sections. As the second step, the surfaces have been modified by using a polymer coating to achieve stronger hydrophobicity at the surface and hence to influence wettability such that increased heat transfer rates should be reached. The polymer coating has been created with a dip coating process by applying a mixture of perfluoroalkyl triethoxysilane. Concerning the wettability, a high-speed flow visualization study has been performed for the interpretation of heat transfer results. Experimental results showed that an increase in the droplet contact angle by applying the polymer coating over surfaces, while the largest droplet contact angle was obtained (130.9°±2.0°) for the surface with V-shaped micro-structuring compared to other surfaces. The comparison of heat transfer performance reveals an enhancement in heat transfer coefficient for the coated version of unstructured, square-grooved and V-grooved surface by 34.5%, 61.8%, and 73.4%, respectively.

DOI 10.1016/j.icheatmasstransfer.2020.105063

Cilt 120