PREPARATION OF HETEROGENEOUS ION-EXCHANGE MEMBRANE BY PORE FILLING METHOD
Ion-exchange membrane (IEM) is an important part of several electro-membrane processes used for water treatment and energy storage. For these processes to run effectively, an ion-exchange membrane with good separation characteristics, such as high conductivity, high permselectivity, and good chem...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/84436 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Ion-exchange membrane (IEM) is an important part of several electro-membrane
processes used for water treatment and energy storage. For these processes to run
effectively, an ion-exchange membrane with good separation characteristics, such as high
conductivity, high permselectivity, and good chemical and mechanical stability, is
required. Based on their structure, ion exchange membranes are divided into two, namely
homogeneous and heterogeneous membranes. Homogeneous membranes have good
eletrochemical properties, but the fabrication process is difficult. Meanwhile,
heterogeneous membranes are easier to fabricate and have good mechanical strength.
However, heterogeneous membranes have insufficient electrochemical properties due to
non-uniform charge distribution. With the right preparation method, heterogeneous
membranes are expected to have superior characteristics.
Heterogeneous structure ion exchange membrane was fabricated from polypropylene by
streching technique and pore filling with sulfonated polysulfone. Experiments were
conducted by varying the stretching ratio and temperature to test its effect on the
membrane charasteristic. The result showed that the addition of sulfonated polysulfone
affected the membrane characteristic, characterized by a decrease in water contact angle
and an increase in water absorption. The results showed that the stretching ratio variation
in the range 25% to 150% and the stretching temperature variation in the range of 80 °C
to 120 °C will increase the water absoprtion, conductivity, and ion exchange capacity.
The highest water absorption value was 0.145 g H2O/g membrane. The highest
conductivity value was 0.680 mS/cm. The highest ion exchange capacity values was
1.98 meq/mL. |
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