An Investigation on the Performance of Nanostructure 
Poly-Ether-Sulfone Hollow Fiber Membrane in Concentration and Purification of Whey

bakeri, gholamreza; lotfi, shabnam

doi:10.22034/jest.2019.7828.1650

Manuscript ID : 1650-JEST (R3) Visit : 119 Page: 1 - 13

10.22034/jest.2019.7828.1650

Article Type: Original Research

An Investigation on the Performance of Nanostructure Poly-Ether-Sulfone Hollow Fiber Membrane in Concentration and Purification of Whey

Subject Areas : Environment Pullotion (water and wastewater)

gholamreza bakeri ¹ , shabnam lotfi ²

1 - Associate Professor, Thermo-Kinetics and Catalyst Group, Faculty of Chemical Engineering, Babol Noshirvani University of Technology, Babol, Iran
2 - M.Sc., Chemical Engineering, Thermo-Kinetics and Catalyst Group, Faculty of Chemical Engineering, Babol Noshirvani University of Technology, Babol, Iran

Received: 2014-11-14 Accepted : 2018-05-16 Published : 2020-06-21

Keywords: whey, nanostructured Poly-Ether-Sulfone Membrane, ultrafiltration process, Protein, hollow fiber membrane,

Abstract :

Background and Objective: Whey is a by-product of dairy industries along cheese production. As a raw material, whey has several applications in food industries and its valuable protein and lactose contents. Membrane technology, more specifically ultrafiltration (UF), is being used in dairy industry to produce whey protein concentrate (WPC) because this technology allows selective separation of whey proteins compared to the rest of its components. In this regard, the objective of this research was to investigate the effects of different operating parameter on whey protein concentration and purification process using ultrafiltration membranes. Method: Three different nanostructure Poly-Eether-Sulfone (PES) hollow fiber membranes were tested and the effects of operating parameters, temperature (43 oC), three different pressures (1 bar, 2 bar, 3 bar) and feed flow rate on the permeate flow rate, protein rejection and lactose permeation were studied. Findings: Results showed that pressure increase enhances the permeation flow rate which is more sensible at lower pressures. Moreover, high pressures have not been considered suitable considering higher fouling and lower flux recovery. Increasing feed flow rate resulted in higher turbulence on the surface of the membrane and reduces the membrane fouling and enhances the permeation flow rate even though these parameters (pressure and feed flow rate) did not have any significant effect on the protein rejection and lactose permeation. At the best operating conditions, maximum protein rejection was %91.01. Discussion and Conclusion: considering the findings, it can be concluded that UF process using PES hollow fiber membrane is capable of performing desired separation and purification of whey.

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