Products
& Services - Vibratory Shear
Enhanced Processing VSEP
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While
membrane-based separations of liquids from solids have enjoyed
increasing popularity over the last 20 years, the technology
has an inherent Achilles heel that affects all membrane devices:
fouling. This long-term loss in throughput capacity is due
primarily to the formation of a boundary layer that builds
up naturally on the membranes surface during the filtration
process. In addition to cutting down on the flux performance
of the membrane, this boundary or gel layer acts as a secondary
membrane reducing the native design selectivity of the membrane
in use. This inability to handle the buildup of solids has
also limited the use of membranes to low-solids feed streams.
 (Figure1)
To
help minimize this boundary layer buildup, membrane designers
have used a method known as tangential-flow or cross-flow
filtration that relies on high velocity fluid flow pumped
across the membranes surface as a means of reducing the boundary
layer effect. (See Figure 1)
In
cross-flow designs, it is not economic to create high shear
forces, thus limiting the use of cross-flow to low-viscosity
(watery) fluids. In addition, increased cross-flow velocities
result in a significant pressure drop from the inlet (high
pressure) to the outlet (lower pressure) end of the device,
which leads to premature fouling of the membrane that creeps
up the device until permeate rates drop to unacceptably low
levels.
 (Figure
2)
Instead
of producing high cross flow, an alternative method for producing
intense shear waves on the face of a membrane is developed.
The technique is called Vibratory Shear Enhanced Processing
(VSEP). In a VSEP System, the feed slurry remains nearly stationary,
moving in a leisurely, meandering flow between parallel membrane
leaf elements. Shear cleaning action is created by vigorously
vibrating the leaf elements in a direction tangent to the
faces of the membranes.
The
shear waves produced by the membrane's vibration cause solids
and foulants to be lifted off the membrane surface and remixed
with the bulk material flowing through the membrane stack.
This high shear processing exposes the membrane pores for
maximum throughput that is typically between 3 and 10 times
the throughput of conventional cross-flow systems. (See Figure
2, above)
The
oscillation produces a shear at the membrane surface of about
150,000 inverse seconds (equivalent to over 200 G's of force),
which is approximately 10 times the shear rate of the best
conventional cross-flow systems. More importantly, the shear
in a VSEP System is focused at the membrane surface where
it is cost effective and most useful in preventing fouling,
while the bulk fluid between the membrane disks moves very
little.
Because
VSEP does not depend on feed flow induced shearing forces,
the feed slurry can become extremely viscous and still be
successfully dewatered. The concentrate is essentially extruded
between the vibrating disc elements and exits the machine
once it reaches the desired concentration level. Thus, VSEP
Systems can be run in a single pass through the system, eliminating
the need for costly working tanks, ancillary equipment and
associated valving.
The
disc pack hold up volume of a system with 1,400 ft2 (130 sq.
meters) of membrane area, is less than 50 gallons (189 liters).
As a result, product recovery in batch processes can be extremely
high.
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