APPLICATION MEMBRANE DISTILLATION FOR ZERO LIQUID DISCHARGE (ZLD) DESALINATION
It is estimated that 33% of the world's population is currently experiencing a clean water crisis. Ironically, the facts prove that of 70% of the water on the earth's surface, only 0.03% can be used as clean water. Adjustment of salt content through seawater desalination is feasible to...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/68152 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | It is estimated that 33% of the world's population is currently experiencing a clean water
crisis. Ironically, the facts prove that of 70% of the water on the earth's surface, only
0.03% can be used as clean water. Adjustment of salt content through seawater
desalination is feasible to be developed to overcome the scarcity of clean water. MD is a
thermally controlled separation process, in which only vapor molecules can pass through
a porous hydrophobic membrane. The MD works with the difference in feed vapor
pressure. The operating temperature of the MD can be reduced to 30 oC. This technology
has the potential to carry out zero liquid discharge (ZLD) desalination without producing
by-products.
Two main weaknesses occur in the MD process, namely the emergence of fouling and
wetting. Fouling is the phenomenon of the formation of unwanted material (foulant) on
the surface of the membrane pores. Fouling will make the membrane pores lose their
hydrophobic properties and become wetted by the liquid. This makes the permeate
contaminated by passing impurities and the product quality decreases. This phenomenon
is called wetting. Fouling can be suppressed by reducing foulants that are abundant in
seawater. This can be done by pretreatment using nanofiltration (NF). Fouling in MD
can be suppressed by adjusting the operating temperature and permeate flow rate.
Increasing the operating temperature MD will increase the flux of the membrane as the
temperature polarization decreases. Increasing the permeate flow rate can increase the
heat and mass transfer coefficients so that the driving force of vapor permeation along
the membrane increases. Prevention of fouling and wetting in the membrane pores can
also be done by modifying the membrane structure. The use of hydrophilic materials such
as Nafion is projected to ensure a high flux.
Research on the NF process shows that the higher the operating pressure in the NF
process, the higher the membrane flux produced. The average flux for operating
pressures of 4, 6, and 8 bar is 3.6, respectively; 3.8; and 3.9 LMH. There does not appear
to be any particular trend that shows a correlation between the operating pressure in the
NF process and the rejection of the Ca, Mg, and Na ions obtained. The best rejection
profile was obtained by the process at a pressure of 5 bar with the rejection values of Ca,
Mg, and Na being 65%, 65%, and 8%, respectively.
Research on the MD process shows that the higher the MD operating temperature, the
higher the flux value produced. The highest average flux value was obtained at a
temperature variation of 70 oC and a permeate circulation rate of 0.88 m/s which reached
9.94 kg/m2hour. No clear correlation was found between the operating temperature and
the conductivity of the resulting permeate. It appears that the permeate circulation rate
strongly correlates with the resulting membrane flux. The higher the permeate circulation
rate, the higher and/or stable the resulting membrane flux will be. The correlation
between the permeate circulation rate and the resulting permeate conductivity is more
difficult to determine. Overall, the effect of operating temperature and permeate
circulation rate on the resulting permeate conductivity tends to be inconsistent.
Research related to composite membrane fabrication showed that the variation of the
12% composite membrane gave a better anti-fouling profile than the pristine membrane
and the 15% composite membrane where the flux could remain stable in the range of 5.5
to 7 kg/m2hour for 48 hours. On the other hand, the 15% composite membrane variation
gave a better anti-wetting profile than the 12% composite membrane where the
conductivity could be maintained stable for 30 hours of operation. However, the antiwetting
profile of the pristine membrane was the best of all variations, where the permeate
conductivity could be kept below 300 ?s/cm. Overall, there are obstacles to validating
the existing data considering that the SEM image shows that the coating layers are not
evenly distributed. The interaction between the coating layer with flux and the
conductivity of the permeate cannot be stated clearly because there is a factor in the
uneven distribution of the coating.
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