Surface Design of Separators for Oil/Water Separation with High Separation Capacity and Mechanical Stability

A convection heat treatment that can replace existing chemical oxidation methods was developed for the preparation of hierarchically oxidized Cu meshes with various surface morphologies, representing a very simple and green route that does not involve toxic chemicals. Three types of Cu meshes [bumpy...

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Veröffentlicht in:	Langmuir 2017-08, Vol.33 (32), p.8012-8022
Hauptverfasser:	Lim, Yong Taek, Han, Nara, Jang, Wooree, Jung, Wooyoung, Oh, Min, Han, Seung Whan, Koo, Hye Young, Choi, Won San
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Sprache:	eng
Schlagworte:	contact angle copper heat treatment oils oxidation separators toxic substances viscosity
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creator	Lim, Yong Taek Han, Nara Jang, Wooree Jung, Wooyoung Oh, Min Han, Seung Whan Koo, Hye Young Choi, Won San
description	A convection heat treatment that can replace existing chemical oxidation methods was developed for the preparation of hierarchically oxidized Cu meshes with various surface morphologies, representing a very simple and green route that does not involve toxic chemicals. Three types of Cu meshes [bumpy-like (BL) and short and long needle-like (NL) structures] exhibited similar separation efficiencies of 95–99% over 20 separation cycles, as indicated by their similar water contact angles (WCAs; 147–150°). However, these Cu meshes exhibited different flux behaviors. Excessively rough and excessively smooth surfaces of the Cu mesh resulted in increased resistance to flow and to a decrease of the penetration of oil. A surface with intermediate smoothness, such as the BL-Cu mesh, was necessary for high flux over a broad range of oil viscosities. Furthermore, a less rough surface was more suitable for the separation of highly viscous oil. Computational fluid dynamics (CFD) simulations were carried out to support our experimental results. The BL-Cu meshes also showed outstanding mechanical stability because of their low resistance to the flow of fluids.
doi_str_mv	10.1021/acs.langmuir.7b01800
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Three types of Cu meshes [bumpy-like (BL) and short and long needle-like (NL) structures] exhibited similar separation efficiencies of 95–99% over 20 separation cycles, as indicated by their similar water contact angles (WCAs; 147–150°). However, these Cu meshes exhibited different flux behaviors. Excessively rough and excessively smooth surfaces of the Cu mesh resulted in increased resistance to flow and to a decrease of the penetration of oil. A surface with intermediate smoothness, such as the BL-Cu mesh, was necessary for high flux over a broad range of oil viscosities. Furthermore, a less rough surface was more suitable for the separation of highly viscous oil. Computational fluid dynamics (CFD) simulations were carried out to support our experimental results. 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subjects	contact angle copper heat treatment oils oxidation separators toxic substances viscosity
title	Surface Design of Separators for Oil/Water Separation with High Separation Capacity and Mechanical Stability
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