Centrifuges
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Nov 28, 2017
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About This Presentation
Centrifugation
Slide Content
Centrifuges
In centrifuges, a centrifugal force, generated by high speed rotations, is used to
separate solids from liquids. Centrifugation can be used to recover solids from slurries,
to clarify liquids, or to clarify solids.
Centrifuges can be categorized as either sedimentation or filtration units. Sedimentation
centrifugation units rely on the density difference between the solid and liquid being
separated. As the slurry enters the spinning centrifuge, it forms an annulus next to the
bowl wall. Because of the centrifugal force, the denser material moves outwardly toward
the wall of the centrifuge bowl. At the same time, the liquid overflows from the bowl or is
picked up by a skimmer. Quite often, the solid must be removed from the centrifuge
manually or with a cutter knife. It can also be removed continuously with a screw
conveyor. On the other hand, filtration centrifuges filter the material with a rotating
basket fitted with a filter medium, where the centrifugal force of rotation expels the liquid
through the filter.
Shown below is an example of an industrial process that uses a disk centrifuge to
separate oil, water and sediment.
(Copyright Alfa Laval, Richmond, VA)
In centrifuges, a centrifugal force, generated by high speed rotations, is used to
separate solids from liquids. Centrifugation can be used to recover solids from slurries,
to clarify liquids, or to clarify solids.
Centrifuges can be categorized as either sedimentation or filtration units. Sedimentation
centrifugation units rely on the density difference between the solid and liquid being
separated. As the slurry enters the spinning centrifuge, it forms an annulus next to the
bowl wall. Because of the centrifugal force, the denser material moves outwardly toward
the wall of the centrifuge bowl. At the same time, the liquid overflows from the bowl or is
picked up by a skimmer. Quite often, the solid must be removed from the centrifuge
manually or with a cutter knife. It can also be removed continuously with a screw
conveyor. On the other hand, filtration centrifuges filter the material with a rotating
basket fitted with a filter medium, where the centrifugal force of rotation expels the liquid
through the filter.
Shown below is an example of an industrial process that uses a disk centrifuge to
separate oil, water and sediment.
(Copyright Alfa Laval, Richmond, VA)
Simple
Laboratory
General Information
The most basic laboratory centrifuge is a test-tube centrifuge. Test tubes are placed in a
holder, the lid is closed and the tubes are spun. The resulting centrifugal force causes
the denser components to move to the bottom of the tube, with the less dense
components above them.
Laboratory centrifuges are used primarily to separate small amounts of mixtures, such
as cell extracts. They are also heavily used in process development.
(Copyright Lab Essentials, Inc., Monroe, GA)
Advantages
Disadvantages
Laboratory
General Information
The most basic laboratory centrifuge is a test-tube centrifuge. Test tubes are placed in a
holder, the lid is closed and the tubes are spun. The resulting centrifugal force causes
the denser components to move to the bottom of the tube, with the less dense
components above them.
Laboratory centrifuges are used primarily to separate small amounts of mixtures, such
as cell extracts. They are also heavily used in process development.
(Copyright Lab Essentials, Inc., Monroe, GA)
Advantages
Disadvantages
Can be used to separate very small amounts of mixtures
Small size lends to ease in placement within workspace.
Small capacity.
Basic
Tubular-Bowl
Tubular-bowl centrifuges are sedimentation centrifuges. They can be used to separate
both solid/liquid and liquid/liquid mixtures.
General Information
In tubular-bowl centrifuges, feed enters from the bottom of the cylindrical bowl. A
distributor and baffle assembly accelerates the incoming liquid to rotor speed. Then, a
baffle separates the feed into its components (two liquid layers for liquid/liquid
separations, or solid and liquid layers for solid/liquid separations). The outer layer,
which consists of the heavier components, becomes concentrated against the wall,
while the inner layer, which consists of thelighter components, floats on top.
Each layer then travels up the side of the bowl as an annulus . Liquid layers are
discharged through overflow ports located on the top of the centrifuge. Solid buildups
remain in the bowl and are recovered manually.
Equipment Design
Tubular-bowl centrifuges generally consist of a bowl, a motor, and a drive assembly.
The bowl is suspended from an upper bearing and hangs freely. This allows the bowl to
find its natural axis of rotation if it becomes unbalanced.
The discharge ports at the top of the bowl are located at different radii and elevations
depending on the properties of the components to be separated. The picture below
shows the upper bearing suspending the bowl as well as a discharge port.
The inner bowl in tubular-bowl centrifuges can range in capacity from 1 to 15 gallons,
and can handle up to 1200 gal/hr of feed. Tubular-bowl centrifuges can be outfitted with
Small size lends to ease in placement within workspace.
Small capacity.
Basic
Tubular-Bowl
Tubular-bowl centrifuges are sedimentation centrifuges. They can be used to separate
both solid/liquid and liquid/liquid mixtures.
General Information
In tubular-bowl centrifuges, feed enters from the bottom of the cylindrical bowl. A
distributor and baffle assembly accelerates the incoming liquid to rotor speed. Then, a
baffle separates the feed into its components (two liquid layers for liquid/liquid
separations, or solid and liquid layers for solid/liquid separations). The outer layer,
which consists of the heavier components, becomes concentrated against the wall,
while the inner layer, which consists of thelighter components, floats on top.
Each layer then travels up the side of the bowl as an annulus . Liquid layers are
discharged through overflow ports located on the top of the centrifuge. Solid buildups
remain in the bowl and are recovered manually.
Equipment Design
Tubular-bowl centrifuges generally consist of a bowl, a motor, and a drive assembly.
The bowl is suspended from an upper bearing and hangs freely. This allows the bowl to
find its natural axis of rotation if it becomes unbalanced.
The discharge ports at the top of the bowl are located at different radii and elevations
depending on the properties of the components to be separated. The picture below
shows the upper bearing suspending the bowl as well as a discharge port.
The inner bowl in tubular-bowl centrifuges can range in capacity from 1 to 15 gallons,
and can handle up to 1200 gal/hr of feed. Tubular-bowl centrifuges can be outfitted with
a knife discharge system, which mechanically removes any built up solids within the
bowl. Shown below is the feed inlet into the bowl of a tubular centrifuge.
Usage Examples
Tubular-bowl centrifuges have a wide range of uses in industry. A typical application is
the purification of lubricating industrial oils containing 1% or less of sedimentable solids.
Tubular-bowl centrifuges also see much use in the food, biochemical,
and pharmaceutical industries. The picture below to the left is an example of a
laboratory scale tubular centrifuge that is powered by a single-phase motor. These
centrifuges can be powered with electric motors, steam turbines or compressed air. The
picture to the right is an example of tubular centrifuge used in industry.
Advantages
Disadvantages
Can be used for both liquid/liquid and solid/liquid separations
Foaming of liquids may occur
Continuous
Continuous decanter centrifuges contain a helical screw to remove solids from the bowl.
(Copyright Alfa Laval, Richmond, VA)
General Information
Continuous decanter centrifuges have a solid wall bowl with either a vertical or
horizontal axis of rotation. Feed enters the bowl through a concentric tube. The liquid
phase (arrows) migrates to the larger radius end of the bowl where it is discharged
bowl. Shown below is the feed inlet into the bowl of a tubular centrifuge.
Usage Examples
Tubular-bowl centrifuges have a wide range of uses in industry. A typical application is
the purification of lubricating industrial oils containing 1% or less of sedimentable solids.
Tubular-bowl centrifuges also see much use in the food, biochemical,
and pharmaceutical industries. The picture below to the left is an example of a
laboratory scale tubular centrifuge that is powered by a single-phase motor. These
centrifuges can be powered with electric motors, steam turbines or compressed air. The
picture to the right is an example of tubular centrifuge used in industry.
Advantages
Disadvantages
Can be used for both liquid/liquid and solid/liquid separations
Foaming of liquids may occur
Continuous
Continuous decanter centrifuges contain a helical screw to remove solids from the bowl.
(Copyright Alfa Laval, Richmond, VA)
General Information
Continuous decanter centrifuges have a solid wall bowl with either a vertical or
horizontal axis of rotation. Feed enters the bowl through a concentric tube. The liquid
phase (arrows) migrates to the larger radius end of the bowl where it is discharged
continuously, while the solids (red spheres) are continuously transported to the other
end of the bowl by a helical screw conveyor.
Equipment Design
Continuous decanter centrifuge bowls can be conical, cylindrical, or a combination of
the two. The solids discharge ports at one end are usually smaller in radius than the
liquids discharge ports at the other end. The helical screw conveyor runs the length of
the bowl. Flocculating agents may be added to the centrifuge to collect softer solids. A
flocculating agent is a substance that causes soft solids to congeal into small masses.
(Copyright Alfa Laval, Richmond, VA)
Usage Examples
Continuous decanter centrifuges are most typically used for processes in which
continuous production is required, such as purifying used lubricating oils. Corn used to
make ethanol is shown below, to the left. Ethanol producers use centrifuges in the
production of ethanol from corn. The picture to the right is an example of an industrial
pusher centrifuge used to separate coarse solids from crystalline slurries continuously
with minimum preventive maintenence.
end of the bowl by a helical screw conveyor.
Equipment Design
Continuous decanter centrifuge bowls can be conical, cylindrical, or a combination of
the two. The solids discharge ports at one end are usually smaller in radius than the
liquids discharge ports at the other end. The helical screw conveyor runs the length of
the bowl. Flocculating agents may be added to the centrifuge to collect softer solids. A
flocculating agent is a substance that causes soft solids to congeal into small masses.
(Copyright Alfa Laval, Richmond, VA)
Usage Examples
Continuous decanter centrifuges are most typically used for processes in which
continuous production is required, such as purifying used lubricating oils. Corn used to
make ethanol is shown below, to the left. Ethanol producers use centrifuges in the
production of ethanol from corn. The picture to the right is an example of an industrial
pusher centrifuge used to separate coarse solids from crystalline slurries continuously
with minimum preventive maintenence.
(Copyright Alfa Laval, Richmond, VA)
(Copyright B&P Process Equipment, Saginaw, MI)
Advantages
(Copyright B&P Process Equipment, Saginaw, MI)
Advantages
Disadvantages
Can be used continuously, eliminating cleaning time.
Mechanically complex.
Screen-Bowl
General Information
As seen in the animation below, screen-bowl continuous decanter centrifuges consist of
a solid bowl to which a cylindrical screen has been added. The bowl and the screen
rotate, creating a centrifugal force. Feed is introduced into the large portion of the bowl,
where the centrifugal force presses it to the edge (top and bottom) of the bowl. A helical
screw conveyor transports the solid component (yellow) to the small end of the bowl. As
the bowl diameter decreases, the solid component is raised above the water line (blue).
As the solid component passes over the screen, any remaining liquid exits through the
screen. The bulk of the liquid component flows back over baffles, and out the large end.
Equipment Design
The screen portion of screen-bowl continuous decanters provides additional time for the
solids to drain under centrifugal force. This additional step improves separation.
Self-Opening
General Information
As their name implies, self-opening centrifuges are able to open during operation to
discharge solids. Feed enters the bowl from the bottom, is exposed to centrifugal force,
and separates into its components. When the desired amount of solids has
accumulated, a sleeve inside the bowl opens and the solids are discharged radially
outward. The schematics below show the sleeve in open and closed positions.
Can be used continuously, eliminating cleaning time.
Mechanically complex.
Screen-Bowl
General Information
As seen in the animation below, screen-bowl continuous decanter centrifuges consist of
a solid bowl to which a cylindrical screen has been added. The bowl and the screen
rotate, creating a centrifugal force. Feed is introduced into the large portion of the bowl,
where the centrifugal force presses it to the edge (top and bottom) of the bowl. A helical
screw conveyor transports the solid component (yellow) to the small end of the bowl. As
the bowl diameter decreases, the solid component is raised above the water line (blue).
As the solid component passes over the screen, any remaining liquid exits through the
screen. The bulk of the liquid component flows back over baffles, and out the large end.
Equipment Design
The screen portion of screen-bowl continuous decanters provides additional time for the
solids to drain under centrifugal force. This additional step improves separation.
Self-Opening
General Information
As their name implies, self-opening centrifuges are able to open during operation to
discharge solids. Feed enters the bowl from the bottom, is exposed to centrifugal force,
and separates into its components. When the desired amount of solids has
accumulated, a sleeve inside the bowl opens and the solids are discharged radially
outward. The schematics below show the sleeve in open and closed positions.
(Copyright Alfa Laval, Richmond, VA)
Equipment Design
The sleeve in self-opening centrifuges is kept closed by static pressure induced by
hydraulic fluid. When the pressure decreases, the sleeve is allowed to open, exposing
an anular, ring-like, area through which solids are discharged. An elastomeric seal
around the top of the bowl ensures that there is no leakage while the sleeve is closed.
Self-opening centrifuges can typically handle up to 220 gal/min of feed. The diagram
below is of a typical self-opening centrifuge. The feed enters from the bottom (1) and
the solids are separated through the disk stack (3) and collect in the periphery. The
hydraulic system forces the bowl bottom (6) to drop down, opening the ports on the side
(8), allowing the solids to discharge.
Equipment Design
The sleeve in self-opening centrifuges is kept closed by static pressure induced by
hydraulic fluid. When the pressure decreases, the sleeve is allowed to open, exposing
an anular, ring-like, area through which solids are discharged. An elastomeric seal
around the top of the bowl ensures that there is no leakage while the sleeve is closed.
Self-opening centrifuges can typically handle up to 220 gal/min of feed. The diagram
below is of a typical self-opening centrifuge. The feed enters from the bottom (1) and
the solids are separated through the disk stack (3) and collect in the periphery. The
hydraulic system forces the bowl bottom (6) to drop down, opening the ports on the side
(8), allowing the solids to discharge.
(Copyright Alfa Laval, Richmond, VA)
Multi-Chamber
General Information
The bowl of multi-chamber centrifuges consists of a series of short tubular sections of
increasing diameter linked together to form a continuous tubular passage. Feed is
introduced into the smallest diameter tube first and progresses through outer tube
diameters as they increase in size. Typically, up to six chambers are connected.
Since the centrifugal force increases as the diameter increases, the heavier particles
will be deposited in the smallest diameter tube.
Multi-Chamber
General Information
The bowl of multi-chamber centrifuges consists of a series of short tubular sections of
increasing diameter linked together to form a continuous tubular passage. Feed is
introduced into the smallest diameter tube first and progresses through outer tube
diameters as they increase in size. Typically, up to six chambers are connected.
Since the centrifugal force increases as the diameter increases, the heavier particles
will be deposited in the smallest diameter tube.
Usage Examples
Multi-chamber centrifuges see much use in the food industry. They are used to clarify
fruit juices, wort , and beer.
Multi-chamber centrifuges see much use in the food industry. They are used to clarify
fruit juices, wort , and beer.
(Copyright Alfa Laval, Richmond, VA)
Advanced
Disk
Disk centrifuges are the most commonly used centrifuges in industry. The disk
centrifuge below is commonly used in the brewing industry.
(Copyright Alfa Laval, Richmond, VA)
General Information
Feed is introduced into a disk centrifuge from the center of the bowl near its bottom. The
feed then rises through a stack of disks. Each disk has numerous holes, which form flow
channels when the disks are stacked.
Advanced
Disk
Disk centrifuges are the most commonly used centrifuges in industry. The disk
centrifuge below is commonly used in the brewing industry.
(Copyright Alfa Laval, Richmond, VA)
General Information
Feed is introduced into a disk centrifuge from the center of the bowl near its bottom. The
feed then rises through a stack of disks. Each disk has numerous holes, which form flow
channels when the disks are stacked.
The liquid portion of the feed flows through these channels, while the solids collect on
the disks' surface. Centrifugal force causes the solids to move outward from the center
of the disk toward the wall of the bowl, where they collect.
Equipment Design
A typical disk centrifuge stack contains 100 or more disks. The disks reduce the
distance that a solid particle must travel before it is separated from the feed. Disk
centrifuges range in diameter from 102-762 mm, and are capable of creating forces up
to 14,000 times that of gravity. The two diagrams below show how disk centrifuges
work. In the first diagram, the feed enters through the bottom and accelerates up
through center of the bowl. As the bowl spins the solids separate through the disks and
collect on the outside of the bowl. The liquid continues out through the top and the
solids can be collected from the periphery. In the second diagram the feed enters
through the top and separates through the disks. The solids form pockets recessed on
the sides of the bowl. The solids then flow through axial discharge valves to be
collected.
(Copyright Alfa Laval, Richmond, VA)
the disks' surface. Centrifugal force causes the solids to move outward from the center
of the disk toward the wall of the bowl, where they collect.
Equipment Design
A typical disk centrifuge stack contains 100 or more disks. The disks reduce the
distance that a solid particle must travel before it is separated from the feed. Disk
centrifuges range in diameter from 102-762 mm, and are capable of creating forces up
to 14,000 times that of gravity. The two diagrams below show how disk centrifuges
work. In the first diagram, the feed enters through the bottom and accelerates up
through center of the bowl. As the bowl spins the solids separate through the disks and
collect on the outside of the bowl. The liquid continues out through the top and the
solids can be collected from the periphery. In the second diagram the feed enters
through the top and separates through the disks. The solids form pockets recessed on
the sides of the bowl. The solids then flow through axial discharge valves to be
collected.
(Copyright Alfa Laval, Richmond, VA)
(Copyright Alfa Laval, Richmond, VA)
Usage Examples
Disk centrifuges are typically used in separations in which the percentage of solids in
the liquid feed is small, such as cream separation and the concentration of butterfat
milk. Shown below are examples of disk stack centrifuges. The centrifuge on the right is
used to clarify liquids from shear sensitive particles. The centrifuge on the left is used to
refine oil and fat.
Usage Examples
Disk centrifuges are typically used in separations in which the percentage of solids in
the liquid feed is small, such as cream separation and the concentration of butterfat
milk. Shown below are examples of disk stack centrifuges. The centrifuge on the right is
used to clarify liquids from shear sensitive particles. The centrifuge on the left is used to
refine oil and fat.
(Copyright Alfa Laval, Richmond, VA)
Advantages
Disadvantages
Can be used for both liquid/liquid and solid/liquid separations
Advantages
Disadvantages
Can be used for both liquid/liquid and solid/liquid separations
Down time for cleaning lowers efficiency
Can only be used for feeds with small solid content
Nozzle-Discharge
General Information/Equipment Design
The animation below shows a nozzle-discharge centrifuge. In nozzle-discharge
centrifuges, the solids are continuously discharged through nozzles located around the
periphery of the bowl and are collected in a surrounding basket (not shown).
(Animation based on a schematic copyright Alfa Laval, Richmond, VA)
Nozzle diameters range from 0.6 mm to 3 mm, and are typically twice the diameter of
the largest particle to be separated. Nozzles are arranged around the bowl so that they
are directed tangentially backward to the direction of rotation. This serves two purposes:
recovery of kinetic energy and reduction of motor power requirements.
Shown below is an example of a nozzle-discharge centrifuge that is designed to handle
high solid loads.
(Copyright Alfa Laval, Richmond, VA)
Advantages
Disadvantages
Continuous operation results in faster separations.
Can only be used for feeds with small solid content
Nozzle-Discharge
General Information/Equipment Design
The animation below shows a nozzle-discharge centrifuge. In nozzle-discharge
centrifuges, the solids are continuously discharged through nozzles located around the
periphery of the bowl and are collected in a surrounding basket (not shown).
(Animation based on a schematic copyright Alfa Laval, Richmond, VA)
Nozzle diameters range from 0.6 mm to 3 mm, and are typically twice the diameter of
the largest particle to be separated. Nozzles are arranged around the bowl so that they
are directed tangentially backward to the direction of rotation. This serves two purposes:
recovery of kinetic energy and reduction of motor power requirements.
Shown below is an example of a nozzle-discharge centrifuge that is designed to handle
high solid loads.
(Copyright Alfa Laval, Richmond, VA)
Advantages
Disadvantages
Continuous operation results in faster separations.
Solids may build up, causing a decrease in clarification efficiency.
Prescreening may be necessary to weed out particles too large to fit through the
nozzles.
Prescreening may be necessary to weed out particles too large to fit through the
nozzles.
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