Recovery of silk sericin from the filature wastewater by using a novel foam fractionation column

A new type of foam fractionation column with spiral internal had been designed for enhancing the foam drainage and thus for the removal of minute hazardous materials. Chromium was separated from wastewater using the continuous foam separation method. According to the similar physical behavior of foam separation and chemical reaction processes, the equivalent chemical reaction constant was introduced, Establishment concentrate distributed mathematical model of the whole tower under the condition of continuous foam separation with SDS as active agent. The model has been tested by experiments. The result indicated that foam separation process could be regarded as a first order reaction, and diffusion coefficient was 4.86cm2/s.

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Uncoupling Foam Fractionation and Foam Adsorption for Enhanced Biosurfactant Synthesis and Recovery

Microorganisms ◽

10.3390/microorganisms8122029 ◽

2020 ◽

Vol 8 (12) ◽

pp. 2029

Author(s):

Christian C. Blesken ◽

Tessa Strümpfler ◽

Till Tiso ◽

Lars M. Blank

Keyword(s):

Scale Up ◽

Recovery Process ◽

Downstream Processing ◽

Biosurfactant Production ◽

Foam Fractionation ◽

Pseudomonas Putida Kt2440 ◽

Culture Volume ◽

Product Removal ◽

Fractionation Column ◽

Space Time Yield

The production of biosurfactants is often hampered by excessive foaming in the bioreactor, impacting system scale-up and downstream processing. Foam fractionation was proposed to tackle this challenge by combining in situ product removal with a pre-purification step. In previous studies, foam fractionation was coupled to bioreactor operation, hence it was operated at suboptimal parameters. Here, we use an external fractionation column to decouple biosurfactant production from foam fractionation, enabling continuous surfactant separation, which is especially suited for system scale-up. As a subsequent product recovery step, continuous foam adsorption was integrated into the process. The configuration is evaluated for rhamnolipid (RL) or 3-(3-hydroxyalkanoyloxy)alkanoic acid (HAA, i.e., RL precursor) production by recombinant non-pathogenic Pseudomonas putida KT2440. Surfactant concentrations of 7.5 gRL/L and 2.0 gHAA/L were obtained in the fractionated foam. 4.7 g RLs and 2.8 g HAAs could be separated in the 2-stage recovery process within 36 h from a 2 L culture volume. With a culture volume scale-up to 9 L, 16 g RLs were adsorbed, and the space-time yield (STY) increased by 31% to 0.21 gRL/L·h. We demonstrate a well-performing process design for biosurfactant production and recovery as a contribution to a vital bioeconomy.

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Theoretical analysis of the performance of a foam fractionation column

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2013.0625 ◽

2014 ◽

Vol 470 (2165) ◽

pp. 20130625 ◽

Cited By ~ 2

Author(s):

S. T. Tobin ◽

D. Weaire ◽

S. Hutzler

Keyword(s):

Theoretical Analysis ◽

Surfactant Solution ◽

Model System ◽

Foam Fractionation ◽

Fractionation Column ◽

Foam Drainage Equation ◽

Limiting Case ◽

Alternative Set ◽

Theory And Experiment ◽

Foam Drainage

A model system for theory and experiment which is relevant to foam fractionation consists of a column of foam moving through an inverted U-tube between two pools of surfactant solution. The foam drainage equation is used for a detailed theoretical analysis of this process. In a previous paper, we focused on the case where the lengths of the two legs are large. In this work, we examine the approach to the limiting case (i.e. the effects of finite leg lengths) and how it affects the performance of the fractionation column. We also briefly discuss some alternative set-ups that are of interest in industry and experiment, with numerical and analytical results to support them. Our analysis is shown to be generally applicable to a range of fractionation columns.

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