Membrane module design and dynamic shear-induced techniques to enhance liquid separation by hollow fiber modules: a review

Yang, Xing; Wang, Rong; Fane, Anthony G.; Tang, Chuyang Y.; Wenten, I Gede

doi:10.1080/19443994.2012.751146

Cited by 110 publications

(42 citation statements)

References 98 publications

(133 reference statements)

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“…In industry, hollow fiber-based membrane modules are preferable due to their larger membrane area per unit volume and reduced vulnerability to TP [1]. Although it has been often stated that poorly-designed hollow fiber modules will result in reduced productivity, increased energy consumption and shortened membrane lifespan [21], there are limited studies on improving fluid dynamics and designing hollow fiber modules for MD applications in the open literature [3,[22][23][24][25]. It is well-recognized that by incorporating proper flow alteration aids or modifying fiber geometries to create secondary flows or eddies (such as novel fiber configurations or turbulence promoters, e.g.…”

Section: Introductionmentioning

confidence: 99%

Novel designs for improving the performance of hollow fiber membrane distillation modules

Yang

Wang

Fane

2011

Journal of Membrane Science

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120

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Five types of novel hollow fiber module configurations with structured-straight fibers, curly fibers, central-tubing for feeding, spacer-wrapped and spacer-knitted fibers, have been designed and constructed for the Direct Contact Membrane Distillation (DCMD) process. Their module performances were evaluated based on permeation flux experiments, fluid dynamics studies, and tracer-response tests for flow distribution as well as process heat transfer analysis.The novel designs showed flux enhancement from 53% to 92% compared to the conventional module, and the spacer-knitted module had the best performance. The fluxes of all the modified configurations, except the structured-straight module, were independent of the feed flow velocity, and the modules with undulating membrane surfaces (curly and spacer-knitted fibers) were able to achieve more than 300% flux improvement in the laminar flow regime. The improved performance was attributed to the improved fiber geometries or arrangements that can provide effective boundary layer surface renewal and more uniform flow distribution, confirmed by the sodium chloride tracer response

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Section: Introductionmentioning

confidence: 99%

Novel designs for improving the performance of hollow fiber membrane distillation modules

Yang

Wang

Fane

2011

Journal of Membrane Science

Self Cite

120

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“…Fouling and scaling depends on several factors, i.e. membrane morphology, feed water composition, and operation conditions [4][5][6][7][8]. Pre-treatment can be done in RO application to control membrane fouling and scaling by removing impurities from the feed water [3,9,10].…”

Section: Introductionmentioning

confidence: 99%

Case Study of a Small Scale Reverse Osmosis System for Treatment of Mixed Brackish Water and STP Effluent

Widiasa

Jayanti

2017

J. Eng. Technol. Sci.

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Abstract.A case study on utilizing reverse osmosis (RO) technology to fulfill fresh water needs at a mall and a hotel has been done on Bali Island, Indonesia. A mix of brackish water and sewage treatment plant (STP) effluent was used as feed water in the RO system. The system used 36 membrane elements (CSM RE 8040 BLN) arranged into two stages: 8 pressure vessels (PVs) in the first stage and 4 PVs in the second stage, each loaded with 3 membranes. The objectives of this research were to assess the cleaning effectivity in the plant, to evaluate the cleaning of 1 membrane element using a CIP system, and to assess the use of the membrane for filtration in the pre-treatment system. SEM and FTIR analysis indicated that the foulants on the membrane surface were dominated by organic foulants and inorganic deposits. To clean the discarded membrane the proposed method used NaOH solution (pH 12 and pH 13) and citric acid (pH 2 and pH 3). All membranes displayed a dramatic decline in rejection of about 80%. Based on the rejection tests of SO 4 2-, Cl -, turbidity reduction approached 100%. It can be concluded that an RO membrane that has undergone selectivity decline can be re-used as a filtration membrane in the pre-treatment system.

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“…In microalgae harvesting, UF is the most promising techniques for concentrating microalgae [19][20][21][22][23][24][25][26]. The advantages of UF in [13,[27][28][29][30][31][32][33]. By using the appropriate strategies, membrane technology could be operated effectively.…”

Section: Introductionmentioning

confidence: 99%

From lab to full-scale ultrafiltration in microalgae harvesting

Wenten

Steven

Dwiputra

et al. 2017

J. Phys.: Conf. Ser.

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Marine microalgae Nannochloropsis oculata biomass harvesting using ultrafiltration in cross-flow mode L A Devianto, D N Aprilia, D W Indriani et al.Study of cultivation and growth rate kinetic for mixed cultures of local microalgae as third generation (G-3) bioethanol feedstock in thin layer photobioreactor Wahyu Prihastuti Yuarrina, Yano Surya Pradana, Arief Budiman et al. Abstract. Ponding system is generally used for microalgae cultivation. However, selection of appropriate technology for the harvesting process is challenging due to the low cell density of cultivated microalgae from the ponding system and the large volume of water to be handled. One of the promising technologies for microalgae harvesting is ultrafiltration (UF). In this study, the performance of UF during harvesting of microalgae in a lab-and a full-scale test is investigated. The performances of both scales are compared and analyzed to provide an understanding of several aspects which affect the yield produced from lab and actual conditions. Furthermore, a unique self-standing non-modular UF is introduced in the full-scale test. The non-modular UF exhibits several advantages, such as simple piping and connection, single pump for filtration and backwashing, and smaller footprint. With those advantages, the non-modular UF could be a promising technology for microalgae harvesting in industrial-scale.

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Membrane module design and dynamic shear-induced techniques to enhance liquid separation by hollow fiber modules: a review

Cited by 110 publications

References 98 publications

Novel designs for improving the performance of hollow fiber membrane distillation modules

Novel designs for improving the performance of hollow fiber membrane distillation modules

Case Study of a Small Scale Reverse Osmosis System for Treatment of Mixed Brackish Water and STP Effluent

From lab to full-scale ultrafiltration in microalgae harvesting

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