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12 views4 pages

Document 2

Uploaded by

Rishi Chourasia
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
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Membrane Techniques

1. Nanofiltration (NF):
a. Nanofiltration membranes have pore sizes between reverse
osmosis (RO) and ultrafiltration, enabling selective removal of
multivalent ions, small organic molecules, and larger dissolved
salts. NF operates at moderate pressures, making it suitable for
water softening, removing pesticides, and concentrating valuable
nutrients. The process effectively separates molecules without
completely desalinating, which conserves more monovalent salts
and reduces energy costs.

2. Reverse Osmosis (RO):


a. RO is a high-pressure-driven process that forces water through a
semi-permeable membrane, blocking nearly all dissolved salts,
organics, and contaminants. Known for their efficiency in
desalination and water purification, RO membranes are highly
selective, capturing even small ions and particles. Although
energy-intensive due to the pressure required, it offers a reliable
solution for producing high-purity water or concentrating
solutions in industries like food and pharmaceuticals.
3. Electrodialysis (ED):
a. In electrodialysis, an electric current drive charged particles
through ion-selective membranes, with anions and cations
migrating toward electrodes of opposite charge. This technique is
useful for desalination of brackish water, separation of acids from
salts, and recovery of valuable ions, as it specifically targets
charged molecules. ED is often more energy-efficient than RO in
applications focusing on ionic separation, especially when high
purity of the solvent (like water) is not required.
Dialysis

Dialysis is a membrane process using natural diffusion through a semi-


permeable membrane, commonly for separating smaller molecules from
larger macromolecules. It enables the removal of unwanted ions or small
impurities while retaining desirable macromolecules, making it suitable for
medical uses (like hemodialysis) and industrial applications (like desalting
proteins). Dialysis occurs due to a concentration gradient, making it less
energy-demanding than pressure-driven processes, ideal for gentle
separation where preserving delicate molecules is essential.

Advances in Membranes

1. Biocompatible and Anti-fouling Membranes:


a. New biocompatible membranes, especially in medical and food
processing, are designed to minimize fouling (accumulation of
unwanted material on surfaces), which can impair performance.
Advances include coatings with hydrophilic (water-attracting)
materials, anti-bacterial surfaces, or functionalized membranes
that reduce biofouling and increase durability. These
modifications improve membrane lifespan and reduce the need
for frequent cleaning or replacement, enhancing overall process
efficiency and stability.
Modeling and Critical Analysis

1. Membrane Process Modeling:


a. Computational modeling of membrane processes allows
prediction of separation performance, fueling potential, and
energy requirements. These models simulate fluid flow, solute
transport, and membrane behavior under various operational
conditions, enabling optimization before large-scale
implementation. Modeling helps refine parameters such as
pressure, membrane type, and flow rate to achieve desired
separations cost-effectively.
2. Comparison with Traditional Methods:
a. Membrane processes often excel in cost and efficiency compared
to traditional separation techniques, like distillation and chemical
precipitation. Distillation is energy-intensive and less effective for
thermally sensitive compounds, while chemical methods require
extensive reagents. Membranes operate at lower energy levels,
use fewer chemicals, and can be continuous, reducing
operational costs. Initial investment may be higher, but
membrane systems offer long-term savings through low
maintenance, minimal chemical use, and adaptability across
different separations.

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