Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties

Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties

In this study, flat sheet asymmetric polyphenylsulfone (PPSU) ultrafiltration membranes with enhanced antifouling properties were prepared with a non-solvent induced phase separation (NIPS) method through compound additives containing a polymeric pore-forming agent, a small molecular non-solvent and...

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Main Authors: Jie Liu, Zhencheng Zhong, Rui Ma, Weichen Zhang, Jiding Li
Format: Article
Language:English
Published: MDPI AG 2016-06-01
Series:Membranes
Subjects:
polyphenylsulfone
porous asymmetric membrane
compound additives
filtration resistance
properties and characterization
Online Access:http://www.mdpi.com/2077-0375/6/2/35
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spelling doaj-5fb607433533421fb0a9f574c989734f2020-11-24T23:59:44ZengMDPI AGMembranes2077-03752016-06-01623510.3390/membranes6020035membranes6020035Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant PropertiesJie Liu0Zhencheng Zhong1Rui Ma2Weichen Zhang3Jiding Li4National Institute of Clean and Low Carbon Energy, Beijing 102209, ChinaNational Institute of Clean and Low Carbon Energy, Beijing 102209, ChinaNational Institute of Clean and Low Carbon Energy, Beijing 102209, ChinaNational Institute of Clean and Low Carbon Energy, Beijing 102209, ChinaThe State Key Laboratory of Chemical Engineering, Department of Chemical Engineering, Tsinghua University, Beijing 100084, ChinaIn this study, flat sheet asymmetric polyphenylsulfone (PPSU) ultrafiltration membranes with enhanced antifouling properties were prepared with a non-solvent induced phase separation (NIPS) method through compound additives containing a polymeric pore-forming agent, a small molecular non-solvent and a surfactant. The formation processes of the porous asymmetric membranes with different kinds of additives were studied in detail, and the microstructure controllable preparation of membrane was achieved by establishing a bridge between the membrane preparation parameters and separation performances. All prepared membranes were characterized by using a scanning electron microscope (SEM), contact angle analysis, porosity, maximum pore size, water and BSA solution permeability studies. The performance efficiency of the membrane was evaluated by using BSA as a model foulant in terms of permeability, solute rejection (R), Rm (membrane inherent resistance), Rc (cake layer resistance), and Rp (pore plugging resistance). The results showed that when the compound additives were used, the inter-connected pores were observed, maximum pore size, contact angle and membrane filtration resistance decreased, while the porosity increased. When PVP compound additives were added, the water flux increased from 80.4 to 148.1 L/(m2·h), the BSA rejection increased from 53.2% to 81.5%. A similar trend was observed for membranes with added PEG compound additives; the water flux and BSA rejection simultaneously increased. The filtration resistance decreased as a result of compound additives. The uniformity of membrane and the number of effective pores could be enhanced by adding compound additives through the cooperation of different additives.http://www.mdpi.com/2077-0375/6/2/35polyphenylsulfoneporous asymmetric membranecompound additivesfiltration resistanceproperties and characterization
collection DOAJ
language English
format Article
sources DOAJ
author Jie Liu
Zhencheng Zhong
Rui Ma
Weichen Zhang
Jiding Li
spellingShingle Jie Liu
Zhencheng Zhong
Rui Ma
Weichen Zhang
Jiding Li
Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties
Membranes
polyphenylsulfone
porous asymmetric membrane
compound additives
filtration resistance
properties and characterization
author_facet Jie Liu
Zhencheng Zhong
Rui Ma
Weichen Zhang
Jiding Li
author_sort Jie Liu
title Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties
title_short Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties
title_full Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties
title_fullStr Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties
title_full_unstemmed Development of High-Antifouling PPSU Ultrafiltration Membrane by Using Compound Additives: Preparation, Morphologies, and Filtration Resistant Properties
title_sort development of high-antifouling ppsu ultrafiltration membrane by using compound additives: preparation, morphologies, and filtration resistant properties
publisher MDPI AG
series Membranes
issn 2077-0375
publishDate 2016-06-01
description In this study, flat sheet asymmetric polyphenylsulfone (PPSU) ultrafiltration membranes with enhanced antifouling properties were prepared with a non-solvent induced phase separation (NIPS) method through compound additives containing a polymeric pore-forming agent, a small molecular non-solvent and a surfactant. The formation processes of the porous asymmetric membranes with different kinds of additives were studied in detail, and the microstructure controllable preparation of membrane was achieved by establishing a bridge between the membrane preparation parameters and separation performances. All prepared membranes were characterized by using a scanning electron microscope (SEM), contact angle analysis, porosity, maximum pore size, water and BSA solution permeability studies. The performance efficiency of the membrane was evaluated by using BSA as a model foulant in terms of permeability, solute rejection (R), Rm (membrane inherent resistance), Rc (cake layer resistance), and Rp (pore plugging resistance). The results showed that when the compound additives were used, the inter-connected pores were observed, maximum pore size, contact angle and membrane filtration resistance decreased, while the porosity increased. When PVP compound additives were added, the water flux increased from 80.4 to 148.1 L/(m2·h), the BSA rejection increased from 53.2% to 81.5%. A similar trend was observed for membranes with added PEG compound additives; the water flux and BSA rejection simultaneously increased. The filtration resistance decreased as a result of compound additives. The uniformity of membrane and the number of effective pores could be enhanced by adding compound additives through the cooperation of different additives.
topic polyphenylsulfone
porous asymmetric membrane
compound additives
filtration resistance
properties and characterization
url http://www.mdpi.com/2077-0375/6/2/35
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AT zhenchengzhong developmentofhighantifoulingppsuultrafiltrationmembranebyusingcompoundadditivespreparationmorphologiesandfiltrationresistantproperties
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AT weichenzhang developmentofhighantifoulingppsuultrafiltrationmembranebyusingcompoundadditivespreparationmorphologiesandfiltrationresistantproperties
AT jidingli developmentofhighantifoulingppsuultrafiltrationmembranebyusingcompoundadditivespreparationmorphologiesandfiltrationresistantproperties
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