Changes of resistance during polyelectrolyte-enhanced stirred batch ultrafiltration

Xin Sheng Zhu, Kwang Ho Choo

Research output: Contribution to journalArticlepeer-review

Abstract

The permeation flux or the resistance in the ultrafiltration process is mainly limited by osmotic pressure, and it may originate from various kinds of polymer interactions. However, the real origin of permeation resistance hasn't been clarified yet in the light of polymer solution nature. The removal of nitrate contamination by polyelectrolytes was carried out with stirred batch ultrafiltration. The polyelectrolyte concentrations both in permeate and retentate were analyzed with total organic carbon analyzer and permeate mass was acquired by electronic balance connected with computer. The total resistance was calculated and interpreted based on the osmotic pressures in three concentration regimes. In the dilute region, the resistance was proportional to polymer concentration; in the semidilute region, the resistance depended on polymer concentration in the parabolic relationship; in the highly concentrated solution regime, the osmotic pressure factor (OPF) would dominate the total resistance; and the deviation from OPF control could come from the electrostatic repulsion between the tightly compacted and charged polyelectrolyte particles at extremely concentrated solution regime. It was first found that dilute and semidilute concentration regions can be easily detected by plotting the log-log curves of the polymer concentration versus the ratio of the total resistance to polymer concentration. The new concept OPF was defined and did work well at highly concentrated regime.

Original languageEnglish
Pages (from-to)478-483
Number of pages6
JournalJournal of Donghua University (English Edition)
Volume24
Issue number4
StatePublished - 2007

Keywords

  • Overlap concentration
  • Permeation resistance
  • Polymer chain collapse
  • Semi-dilute solution
  • Ultrafiltration

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