Casting a nanofiltration polymer membrane for water softening
Potable water is essential for survival of all forms of lives. However, only a small percentage of water is available for consumption without going through water treatment process. Water hardness is one of the parameters which must take into considerations when concerning water quality. Dissolved...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2009
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/17143 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Potable water is essential for survival of all forms of lives. However, only a small
percentage of water is available for consumption without going through water treatment
process. Water hardness is one of the parameters which must take into considerations
when concerning water quality. Dissolved Magnesium and Calcium ions in water are the
main contributors to hard water’s characteristics. Hard water can pose several problems
to users and is definitely undesirable. Thus, the author aims to investigate low cost and
improved methods for water softening through casting of nanofiltration membranes as
well as testing commercially available nanofiltration membrane. The ultimate outcome
is the high reduction of Calcium Carbonate content in hard water.
In this project, 13 experiments were carried out. The author used two types of
membranes, namely, Polyacrylonitrile (PAN) 10 ultrafiltration membrane and
Polytetrafluoroethylene (PTFE) coated fiber glass cloth (a nanofiltration membrane).
This was done so as to compare the performance of the commercially made
nanofiltration membrane with the self cast nanofiltration membranes. Out of the 13
experiments conducted, 12 of them were tested through the casting of the nanofiltration
layer on the commercially bought PAN 10 ultrafiltration membrane. The membrane has
an asymmetric porous structure which is used as the support for the thin active layer.
Consistency in the usage of same support membrane will ensure constant performance
of the backing material. The materials and their concentrations used for the thin layer
were varied. The fabrication technique applied for casting the thin film is interfacial
polymerization. The desired properties for the support membrane are high mechanical
strength and uniform porous structures. As for the thin film, high selectivity is desired.
On the contrary, the PTFE coated fiber glass cloth was tested in one experiment. PTFE
coated fiber glass cloth has a remarkably low coefficient of friction, heat and chemical
resistance.
The results have shown that better salt rejection rate was achieved when the i) transmembrane
pressure is higher, ii) concentrations of the aqueous and organic phase
solutions are increased and iii) thickness of the nanofiltration layer is increased. On the
other hand, higher salt rejection rate is accompanied by the decrease in flux rate. Besides
carrying out the experiment to test for the rejection rate and flux rate, surface
characterization of membranes was also performed. Scanning Electron Microscope
(SEM) and Atomic Force Microscope (AFM) were used to view the microscopic
structures of the membranes’ surfaces as well as their cross sections. These allowed the
author to have a better understanding of the membranes’ characteristics. |
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