Abstract
A centrifugal separator includes a cylindrical bowl having a conical
lower end with an opening through which feed liquid is injected during
a feed mode of operation. During the feed mode, solids separate from
the feed liquid and accumulate along the inner surface of the bowl
as the bowl rotates at high speed. After accumulation of the solids,
the rotation of the bowl is stopped and residual liquid is drained
by gravity from the bowl. In a solids discharge mode of operation,
a piston of a piston assembly is urged downward along a vertical axis
in response to fluid such as compressed gas or hydraulic liquid. The
downward movement of the piston forces accumulated solids from the
bowl via the opening in the conical lower end thereof. The solids
pass from the bowl and into a passage leading to an outlet port, where
the solids exit the separator.
Claims
1. A solids discharge assembly for a centrifugal separator, comprising:
a piston movably disposed against an inner surface of a bowl for a
separator, the piston comprising an upper portion and a lower portion;
and a driving port operative for introducing fluid into the bowl above
the upper portion of the piston, wherein increased fluid pressure
in the bowl above the upper portion of the piston relative to that
below the lower portion of the piston causes the piston to move within
the bowl.
2. The solids discharge assembly for a centrifugal separator of
claim 1, wherein during a solids discharge mode of operation introduction
of fluid into the bowl above the upper portion of the piston causes
the piston to push solids accumulated along the inner surface of
the bowl.
3. The solids discharge assembly for a centrifugal separator of
claim 1, wherein a lower end of the bowl and the lower portion of
the piston have complementary shapes.
4. The solids discharge assembly for a centrifugal separator of
claim 3, wherein the lower portion of the piston and the lower end
of the bowl have substantially frustoconical shapes.
5. The solids discharge assembly for a centrifugal separator of
claim 1, further comprising a port operative for introducing fluid
into the bowl below the lower portion of the piston, wherein increased
fluid pressure in the bowl below the lower portion of the piston
relative to that above the upper portion of the piston causes the
piston to move within the bowl.
6. The solids discharge assembly for a centrifugal separator of
claim 5, wherein introduction of fluid into the bowl below the lower
portion of the piston causes the piston to move toward an upper
end of the bowl.
7. The solids discharge assembly for a centrifugal separator of
claim 1, further comprising a valve in an upper end region of the
separator, wherein the valve is operable to enable pressurization
of the bowl above the upper portion of the piston.
8. The solids discharge assembly for a centrifugal separator of
claim 7, wherein the valve is actuated in response to fluid pressure
applied against an annular member operably associated with the valve.
9. A centrifugal separator, comprising: a cylindrical bowl for
a separator having a lower end with an opening, the bowl being operative
during a feed mode of operation to rotate at a high speed to separate
solids from feed liquid, wherein solids accumulate along an inner
surface of the bowl; a solids discharge assembly comprising a piston
movably disposed against an inner surface of a bowl, the piston
comprising an upper portion and a lower portion, and a driving port
operative for introducing fluid into the bowl above the upper portion
of the piston, wherein increased fluid pressure in the bowl above
the upper portion of the piston relative to that below the lower
portion of the piston causes the piston to move within the bowl;
and a first valve member, wherein the first valve member defines
a drain passage, the drain passage operative to permit liquid to
drain from the opening in the bowl when the first valve member is
in a closed position.
10. The centrifugal separator of claim 9, wherein during a solids
discharge mode of operation introduction of fluid into the bowl
above the upper portion of the piston moves the piston axially downward
with respect to the bowl.
11. The centrifugal separator of claim 10, wherein during the solids
discharge mode of operation the piston forces solids accumulated
along the inner surface of the bowl through the opening in the bowl.
12. The centrifugal separator of claim 9, wherein the opening in
the bowl and the drain passage are configurable to enable liquid
to drain by gravity from the bowl into the drain passage.
13. The centrifugal separator of claim 9, wherein the first valve
member defines a feed passage, the feed passage cooperating with
the opening in the bowl during the feed mode of operation to permit
feed liquid to be injected into the bowl.
14. The centrifugal separator of claim 9, wherein the first valve
member is operatively coupleable to a valve actuator for rotating
the first valve member about a rotational axis.
15. The centrifugal separator of claim 9, wherein the lower end
of the bowl and the lower portion of the piston are complementarily
shaped.
16. The centrifugal separator of claim 15, wherein the lower portion
of the piston and the lower end of the bowl have substantially frustoconical
shapes.
17. The centrifugal separator of claim 9, further comprising a
port operative for introducing fluid into the bowl below the lower
portion of the piston, wherein increased fluid pressure in the bowl
below the lower portion of the piston relative to that above the
upper portion of the piston causes the piston to move within the
bowl.
18. The centrifugal separator of claim 17, wherein introduction
of fluid into the bowl below the lower portion of the piston causes
the piston to move toward an upper end of the bowl.
19. The centrifugal separator of claim 9, further comprising a
valve in an upper end region of the separator, wherein the valve
is operable to pressurize the bowl above the upper portion of the
piston.
20. The centrifugal separator of claim 19, wherein the valve is
actuated in response to fluid pressure applied against an annular
member operably associated with the valve.
21. A centrifugal separator, comprising: a cylindrical bowl for
a separator having a lower end with an opening, the bowl being operative
during a feed mode of operation to rotate at a high speed to separate
solids from feed liquid, wherein solids accumulate along an inner
surface of the bowl; a solids discharge assembly comprising a piston
movably disposed against an inner surface of a bowl, the piston
comprising an upper portion and a lower portion, and a driving port
operative for introducing fluid into the bowl above the upper portion
of the piston, wherein increased fluid pressure in the bowl above
the upper portion of the piston relative to that below the lower
portion of the piston causes the piston to move within the bowl;
a first valve member proximate to the opening of the bowl, the first
valve member operatively coupleable to a valve actuator for rotating
the first valve member about a rotational axis; a second valve member
cooperating with a lower surface of the first valve member when
the first valve member is in a closed position; and a valve piston
having an uppermost end at which the second valve member is proximately
disposed, the valve piston operative to move the second valve member
with respect to the bowl.
22. The centrifugal separator of claim 21, wherein during a solids
discharge mode of operation the valve piston moves the second valve
member upward along a vertical axis to cooperate with the opening
in the bowl.
23. The centrifugal separator of claim 21, wherein during the feed
mode of operation the first valve member is in the closed position
defining a feed passage cooperating with the opening in the bowl
to permit feed liquid to be injected into the bowl.
24. The centrifugal separator of claim 21, wherein the first valve
member defines a drain passage, the drain passage operative to permit
liquid to drain from the opening in the bowl by gravity when the
first valve member is in the closed position.
25. The centrifugal separator of claim 21, wherein a first passage
is partially disposed within the valve piston, the first passage
cooperating with the second valve member at the uppermost end of
the valve piston, whereby the opening in the bowl and the first
passage are configurable to enable solids from the bowl to pass
through the first passage during a solids discharge mode of operation.
26. The centrifugal separator of claim 25, wherein the first passage
cooperates with a second passage partially disposed within the valve
piston, whereby fluid introduced through a port for the second passage
enters the first passage to contact solids therein, when a valve
member of the first passage is open.
27. The centrifugal separator of claim 21, wherein an annular flange
is disposed about the valve piston, whereby the valve piston moves
in response to fluid pressure applied against the annular flange.
28. The centrifugal separator of claim 21, wherein during a solids
discharge mode of operation introduction of fluid into the bowl
above the upper portion of the piston moves the piston axially downward
with respect to the bowl.
29. The centrifugal separator of claim 28, wherein during the solids
discharge mode of operation the piston forces solids accumulated
along the inner surface of the bowl through the opening in the bowl.
30. The centrifugal separator of claim 21, wherein the lower end
of the bowl and the lower portion of the piston have complementary
shapes.
31. The centrifugal separator of claim 30, wherein the lower portion
of the piston and the lower end of the bowl have substantially frustoconical
shapes.
32. The centrifugal separator of claim 21, further comprising a
port operative for introducing fluid into the bowl below the lower
portion of the piston, wherein increased fluid pressure in the bowl
below the lower portion of the piston relative to that above the
upper portion of the piston causes the piston to move within the
bowl toward an upper end thereof.
33. The centrifugal separator of claim 21, further comprising a
valve in an upper end region of the separator, wherein the valve
is operable to enable pressurization of the bowl above the upper
portion of the piston.
34. The centrifugal separator of claim 33, wherein the valve is
actuated in response to fluid pressure applied against an annular
member operably associated with the valve.
35. The centrifugal separator of claim 21, wherein a first passage
is partially disposed within the valve piston, the first passage
cooperating with the second valve member at the uppermost end of
the valve piston and a second passage partially disposed within
the valve piston.
36. The centrifugal separator of claim 35, wherein when a valve
member of the first passage is closed, fluid introduced through
a port for the second passage enters the bowl below the lower portion
of the piston, whereby increased fluid pressure in the bowl below
the lower portion of the piston relative to that above the upper
portion of the piston causes the piston to move within the bowl
toward an upper end thereof.
37. A method for discharging solids from a centrifugal separator,
comprising: providing a solids discharge assembly, the solids discharge
assembly comprising a piston movably disposed against an inner surface
of a bowl for a separator, the piston comprising an upper portion
and a lower portion, and a driving port operative for introducing
fluid into the bowl above the upper portion of the piston, wherein
increased fluid pressure in the bowl above the upper portion of
the piston relative to that below the lower portion of the piston
causes the piston to move within the bowl; introducing fluid through
the driving port to increase fluid pressure in the bowl above the
upper portion of the piston relative to that below the lower portion
of the piston to cause the piston to move within the bowl; and discharging
from the bowl solids accumulated along the inner surface thereof.
38. The method of claim 37, further comprising injecting feed liquid
into the bowl to separate solids therefrom by high speed rotation
of the bowl, prior to introducing fluid through the driving port.
39. The method of claim 37, further comprising returning the piston
substantially to an uppermost position by introducing fluid into
the bowl below the lower portion of the piston to increase fluid
pressure in the bowl below the lower portion of the piston relative
to that above the upper portion of the piston so as to cause the
piston to move within the bowl, after discharging from the bowl
solids accumulated along the inner surface thereof.
40. A method for discharging solids from a centrifugal separator,
comprising: providing a centrifugal separator, the centrifugal separator
comprising a cylindrical bowl for a separator having a lower end
with an opening, the bowl being operative during a feed mode of
operation to rotate at a high speed to separate solids from feed
liquid, wherein solids accumulate along an inner surface of the
bowl, a solids discharge assembly comprising a piston movably disposed
against an inner surface of a bowl, the piston comprising an upper
portion and a lower portion, and a driving port operative for introducing
fluid into the bowl above the upper portion of the piston, wherein
increased fluid pressure in the bowl above the upper portion of
the piston relative to that below the lower portion of the piston
causes the piston to move within the bowl, a first valve member
proximate to the opening of the bowl, the first valve member operatively
coupleable to a valve actuator for rotating the first valve member
about a rotational axis, a second valve member cooperating with
a lower surface of the first valve member when the first valve member
is in a closed position, and a valve piston having an uppermost
end at which the second valve member is proximately disposed, the
valve piston operative to move the second valve member with respect
to the bowl; introducing fluid through the driving port to increase
fluid pressure in the bowl above the upper portion of the piston
relative to that below the lower portion of the piston to cause
the piston to move within the bowl; and discharging from the bowl
solids accumulated along the inner surface thereof.
41. The method of claim 40, further comprising injecting feed liquid
into the bowl to separate solids therefrom by high speed rotation
of the bowl, prior to introducing fluid through the driving port.
42. The method of claim 40, further comprising returning the piston
substantially to an uppermost position by introducing fluid into
the bowl below the lower portion of the piston to increase fluid
pressure in the bowl below the lower portion of the piston relative
to that above the upper portion of the piston so as to cause the
piston to move within the bowl, after discharging from the bowl
solids accumulated along the inner surface thereof.
Description
BACKGROUND OF THE INVENTION
[0001] Many different types of centrifugal separators are known
for separating heterogeneous mixtures into components based on specific
gravity. Typically, a heterogeneous mixture, which may also be referred
to as feed material or liquid, is injected into a rotating bowl
of a centrifugal separator. The rotating bowl spins at high speeds
and forces components of the mixture that have a high specific gravity
to separate therefrom by sedimentation. As a result, dense solids
compress as a cake tightly against an inner surface or wall of the
bowl and clarified liquid forms radially inward from the cake. The
bowl may spin at speeds sufficient to produce forces 20,000 times
greater than gravity so as to separate the solids from the centrate.
[0002] As solids accumulate along the wall of the bowl, the clarified
liquid exits from the bowl and leaves the separator as "centrate."
Once it is determined that a desired amount of solids has accumulated,
the separator is placed in a discharge mode in which the solids
are removed from the separator. Often, for example, an internal
scraper is engaged to scrape the solids from the walls of the bowl.
[0003] Conventional separators have many shortcomings when discharging
particular kinds of solids and liquids. For example, some separators
may not be capable of completely discharging solids that are sticky,
which can result in poor yields. A poor yield can be especially
problematic for high-value solids such as those encountered in pharmaceutical
processes. Traditional separators also subject a feed material to
very high shear forces when accelerating the material to the rotational
speed of the bowl, which can damage, for example, sensitive chemical
or biological substances such as intact cells.
[0004] Still, other separators do not provide a convenient means
by which to handle and recover sensitive solids. For example, an
operator is commonly used to assist with solids discharge and recovery.
Separators that require such operator intervention often suffer
from contamination problems. Furthermore, some separators employ
numerous mechanical components to facilitate solids recovery, which
can affect separator durability. Such components are usually external
to the separator or in the form of add-on equipment that poses both
size and compatibility issues. Conventional separators also tend
to be difficult to clean or sterilize without significantly increasing
maintenance costs.
[0005] It would be desirable to have a centrifugal separator that
can be effectively used with solids of the type described above,
namely, those that result in sticky accumulations or are sensitive
to shear forces generated during centrifugation. It would also be
useful to have a separator that can easily recover such solids without
the possibility of external contamination or additional mechanical
equipment. Such a separator should also be able to be conveniently
cleaned or sterilized-in-place.
SUMMARY OF THE INVENTION
[0006] In accordance with the present invention, a centrifugal
separator is disclosed that performs well with sticky solids and
exhibits low-shear acceleration of feed material. The separator
can be particularly useful for sensitive solids such as chemical
or biological substances. A separator of the invention can recover
sensitive solids, liquids, materials or combinations thereof without
operator intervention or additional mechanical equipment. The separator
can also be conveniently cleaned or sterilized-in-place.
[0007] The separator can include a cylindrical bowl having a conical
lower end with an opening through which feed material or liquid
is injected during a feed mode of operation. As the bowl spins or
rotates at a high speed, the injected feed liquid encounters a sloped
surface of the conical lower end of the bowl. Rotational acceleration
forces are imparted relatively gradually as the liquid continues
its movement radially outward. Solids then separate from the feed
liquid and accumulate along the inner surface of the bowl, for example,
as a cake.
[0008] Additionally, the separator can include a piston assembly
disposed within the bowl in tight-fitting relationship with an inner
surface thereof. The piston features an upper portion and a lower
conical portion that are contacted by pneumatic or hydraulic pressure
during different modes of separator operation. For example, in a
solids discharge mode, fluid such as compressed gas or hydraulic
liquid acts against the upper portion of the piston urging it axially
downward to force accumulated solids from the bowl via the opening
in the conical lower end thereof. Exemplary types of compressed
gas for moving the piston include nitrogen and argon. Similarly,
an exemplary hydraulic liquid for moving the piston in the bowl
can include distilled water. In one embodiment, the lower end of
the bowl and lower portion of the piston have complementary shapes
to promote relatively complete discharge of solids. For example,
the lower end of the bowl and lower portion of the piston can feature
substantially frustoconical shapes.
[0009] For a separator of the invention, the piston can be held
in an uppermost position during a feed mode of operation by hydraulic
pressure from the feed liquid as well as frictional forces between
one or more piston seals and the inner surface or wall of the bowl.
Such seals can be disposed about the piston and adjacent to the
inner surface of the bowl. The piston includes a centrate valve
that can be urged open during the feed mode to permit the feed liquid,
after solids have been separated therefrom, to flow out of the bowl
as clarified liquid and into a centrate case having a passage leading
to a centrate outlet port. As the piston is urged downward by fluid
acting against the upper portion thereof during solids discharge,
the centrate valve automatically closes to prevent accumulated solids
from passing into the centrate case.
[0010] With the piston held in its uppermost position, it is permitted
to rotate with the bowl as high speed rotational separation of the
solids from the feed liquid is performed. During the feed mode and
solids separation, clarified liquid exits the bowl and enters the
centrate case. The centrate case can also include an isolation valve
that may be urged open or closed by pneumatic or hydraulic pressure.
For example, the isolation valve is open in the feed mode to allow
clarified liquid to flow through the centrate outlet port and an
open centrate outlet port valve to exit the separator as centrate.
As the feed mode concludes, hydraulic pressure from the feed liquid
is reduced such that the piston is held substantially in its uppermost
position by frictional forces between one or more piston seals and
the inner wall of the bowl as well as any solids accumulated within
the bowl. When the feed mode of operation is complete, the bowl
stops rotating and remaining or residual liquid in the separator
flows by gravity through the opening in the conical lower end thereof.
[0011] The separator can also feature a divert assembly including
a solids divert valve movably located below a rotatable residual
divert valve when the residual divert valve is at the opening in
the conical lower end of the bowl. As residual liquid drains from
the bowl, the residual divert valve is in a closed position to permit
the liquid to flow from the bowl and into a residual liquid drain
passage. The liquid drain passage leads into a drain port, where
residual liquid exits the separator. The solids discharge mode of
operation can, for example, begin after the residual liquid has
substantially drained from the separator bowl.
[0012] In the solids discharge mode, a residual divert valve actuator
rotates the residual divert valve to an open position such that
the solids divert valve can be urged upward, by a solids divert
piston, into communication with the opening in the bowl. The centrate
outlet port valve is then closed and a solids outlet port valve
for the divert assembly is opened. The isolation valve is also urged
closed by fluid such as compressed gas or hydraulic liquid acting
against an annular member associated with the isolation valve, which
controls its actuation and movement. In addition, as described above,
the piston is urged downward along a vertical axis during solids
discharge by fluid acting against the upper portion thereof. The
piston subsequently pushes or "pumps" accumulated solids
from the bowl into a solids passage leading to a solids outlet port
that features the open solids outlet port valve.
[0013] In one embodiment, a solids discharge assembly for the separator
features the piston movably disposed against the inner surface of
the bowl. The piston can comprise an upper portion and a lower portion.
The solids discharge assembly can also feature a driving port operative
for introducing fluid into the bowl above the upper portion of the
piston. When fluid pressure in the bowl above the upper portion
of the piston is increased relative to that below the lower portion
of the piston, the piston moves within the bowl. For example, during
solids discharge, introduction of fluid into the bowl above the
upper portion of the piston can move the piston axially downward.
Preferably, the piston is urged axially downward with respect to
the bowl. As described above, during the solids discharge mode of
operation, introduction of fluid into the bowl above its upper portion
causes the piston to push solids accumulated along the inner surface
of the bowl.
[0014] The solids discharge assembly can also comprise a port operative
for introducing fluid into the bowl below the lower portion of the
piston. When fluid pressure in the bowl below the lower portion
of the piston is increased relative to that above the upper portion
of the piston, the piston moves within the bowl. For example, introduction
of fluid into the bowl below the lower portion of the piston can
cause the piston to move toward an upper end of the bowl. In another
embodiment, the separator can also comprise a valve in an upper
end region thereof, which is operable to enable pressurization of
the bowl above the upper portion of the piston. Such a valve can
be actuated in response to fluid pressure applied against an annular
member operably associated therewith.
[0015] In another embodiment, the separator of the invention can
comprise a cylindrical bowl having a lower end with an opening.
During the feed mode of operation, the bowl is operative to rotate
at a high speed to separate solids from feed liquid. As described
above, the solids accumulate along the inner surface of the bowl.
The separator can also feature a solids discharge assembly and first
valve member, which defines a drain passage. The drain passage is
operative to permit liquid to drain from the opening in the bowl
when the first valve member is in a closed position. Preferably,
the opening in the bowl and the drain passage are configurable to
enable liquid to drain by gravity from the bowl into the passage.
[0016] The first valve member can also define a feed passage that
cooperates with or is proximate to the opening in the bowl during
the feed mode of operation. The feed passage permits feed liquid
to be injected into the bowl. The first valve member can also be
operatively coupleable to a valve actuator for rotating the member
about a rotational axis. In one embodiment, the separator can also
comprise a second valve member that cooperates with a lower surface
of the first valve member when the first valve member is in a closed
position. Moreover, the separator can feature a valve piston having
an uppermost end at which the second valve member is proximately
disposed. The valve piston can be operative to move the second valve
member with respect to the bowl. For example, during solids discharge,
the valve piston can move the second valve member upward along a
vertical axis to cooperate with the opening in the bowl. Similarly,
during the feed mode of operation, the first valve member is in
the closed position and defines the feed passage, which, as describe
above, can cooperate with the opening in the bowl to permit feed
liquid to be injected therein.
[0017] In one embodiment, the separator of the invention can comprise
a first passage partially disposed within the valve piston. For
example, the first passage can cooperate with the second valve member
at the uppermost end of the valve piston. The opening in the separator
bowl and the first passage can also be configurable to enable solids
from the bowl to pass through the first passage during solids discharge.
The first passage can also cooperate with a second passage that
is partially disposed in the valve piston such that fluid introduced
through a port for the second passage may enter the first passage
so as to contact solids therein. Preferably, fluid introduced through
the port for the second passage enters the first passage to contact
solids therein when a valve member of the first passage is open.
The valve piston of the separator can also feature an annular flange
disposed thereabout such that the valve piston moves in response
to fluid pressure applied against the annular flange.
[0018] In one embodiment, the separator also comprises a first
passage partially disposed within the valve piston. The first passage
can cooperate with the second valve member, for example, at the
uppermost end of the valve piston, and a second passage partially
disposed within the valve piston. Preferably, when a valve member
of the first passage is closed, fluid introduced through a port
for the second passage enters the bowl below the lower portion of
the piston. Fluid introduced through the port increases fluid pressure
in the bowl below the lower portion of the piston relative to that
above the upper portion thereof so as to cause the piston to move
toward an upper end of the bowl.
[0019] The invention also provides a method for discharging solids
from a centrifugal separator. In one embodiment, the method comprises
providing the separator and/or solids discharge assembly described
above and introducing fluid through the driving port to increase
fluid pressure in the bowl above the upper portion of the piston
relative to that below the lower portion thereof so as to cause
the piston to move within the bowl. The method can also comprise
discharging solids accumulated along the inner surface of the bowl.
Additionally, the method features injecting feed liquid into the
bowl for solids separation by high speed rotation of the bowl. Preferably,
the feed liquid is injected into the bowl prior to introducing fluid
through the driving port. A method of the invention also includes
returning the piston substantially to an uppermost position. The
piston can be returned substantially to its uppermost position by
introducing fluid into the bowl below the lower portion of the piston
so as to increase fluid pressure in the bowl below the lower portion
of the piston relative to that above the upper portion thereof.
The piston is preferably returned substantially to its uppermost
position after discharging solids accumulated along the inner surface
of the bowl. The invention also contemplates carrying out the above
method in any particular order or manner.
DESCRIPTION OF THE DRAWINGS
[0020] Other features and advantages of the present invention will
be apparent from the following detailed description of the invention,
taken in conjunction with the accompanying drawings of which:
[0021] FIG. 1 is a section view of a centrifugal separator in accordance
with the invention;
[0022] FIG. 2 is a section view of a centrifugal separator in accordance
with the invention;
[0023] FIG. 3 is a section view of the separator in FIG. 2 featuring
a laser sensor assembly;
[0024] FIG. 4 is a section view of the separator in FIG. 1 illustrating
operation in a feed mode;
[0025] FIG. 5 is a detailed section view including the piston and
bowl of the separator in FIG. 1 illustrating operation in the feed
mode;
[0026] FIG. 6 is a section view of the separator in FIG. 1 illustrating
operation when residual liquid drains from the bowl;
[0027] FIG. 7 is a section view of the separator in FIG. 1 illustrating
operation in a solids discharge mode;
[0028] FIG. 8 is a section of the centrifuge in FIG. 1 illustrating
operation after the solids discharge mode when the piston is returned
substantially to its uppermost position;
[0029] FIG. 9 is a detailed section view of a lower end region
of the separator of FIG. 1 when a solids passage is cleaned;
[0030] FIG. 10 is a detailed section view of an upper portion of
the separator of FIG. 1 in the feed mode; and
[0031] FIG. 11 is a detailed section view of an upper portion of
the separator of FIG. 1 in a solids discharge mode.
DETAILED DESCRIPTION OF THE INVENTION
[0032] FIG. 1 shows a centrifugal separator in vertical section,
with a middle portion removed so as to illustrate a horizontal section
as well. The centrifugal separator includes a cylindrical separator
bowl 10 mounted in a central region 11 of a separator housing 13.
Preferably, the separator bowl can be of a length that is greater
than a diameter thereof. By having the length of the bowl longer
than its diameter, "end effects" in the bowl can be minimized
with respect to the bowl's internal volume. In general, end effects
can be caused by fluid eddies along any of the angled portions within
the interior of the bowl and, particularly, near the ends thereof.
In one embodiment, the separator bowl 10 can be a cylindrical type
bowl having a relatively small diameter D and a length L such that
the ratio of L/D is approximately 5/1 or greater. Such a ratio of
L/D tends to prevent axial waves from developing within the bowl
as such waves substantially dissipate as they travel the length
of the bowl. By employing an L/D ratio of approximately 5/1 or greater,
a separator of the invention can also avoid the need for baffles
within the bowl, which are used in conventional separators to minimize
axial waves.
[0033] The separator in FIG. 1 also includes a piston assembly
comprising a piston 12. As shown, the piston 12 can have a lower
conical portion that matches the shape of a conical lower end 17
of the bowl 10. The conical lower end 17 acts as a rotational accelerator
of the feed liquid during a feed mode of operation for the separator.
The separator can also feature, in an upper portion 19, a centrate
case 30 having an isolation valve 26 that is urged open or closed
by pneumatic or hydraulic pressure.
[0034] A variable speed drive motor 16 can also be connected by
a drive belt 5 to a drive pulley 18 of a mounted bearing and spindle
assembly 23 located at a collar-like extension 22 of the upper end
for the separator housing 13. A separator of the invention can also
be operated using other conventional motor and drive systems. Preferably,
the bearing and spindle assembly 23 can comprise a semi-spherical
portion 1 and a short cylindrical spindle portion 20, although other
suitable assembly configurations could be used in accordance with
the invention. In one embodiment, the semi-spherical portion comprises
an upper semi-hemispherical portion and a lower semi-hemispherical
portion. Optionally, the semi-spherical portion 1 can rest against
mating surfaces of one or more seats. For example, FIG. 1 shows
seats 24 and 25 in compressive contact with the upper and lower
semi-hemispherical portion, respectively, of the semi-spherical
portion 1. An exemplary semi-spherical portion that can be employed
in a separator of the invention has been described by U.S. application
Ser. No. 10/874,150, which is hereby incorporated by reference herein.
[0035] Exemplary seats 24 and 25 can comprise low friction components
such as polytetrafluoroethylene (PTFE) or TEFLON-based (E. I. du
Pont de Nemours and Company, 1007 Market Street, Wilmington, Del.
19898) materials such that they allow some extent of shifting of
the semi-spherical portion 1 about a central vertical axis 41 of
the separator. Seats 24 and 25 tend to prevent the semi-spherical
portion 1 from processing radially outward and axially upward or
downward. Moreover, seats 24 and 25 can limit the amount of vertical
and horizontal swiveling of the spindle portion 20 as it rotates
about the central vertical axis 41 of the separator at high speed
during operation. Swiveling of the spindle portion 20 may also be
dampened by an optional swing resistant ring 21 made, for example,
of rubber. By preventing such radial or axial processing and limiting
the amount of swiveling, vibration associated with the natural frequency
of the rotating bowl 10 can be reduced. Seats 24 and 25 can also,
for example, be arched seating elements that substantially prevent
translation such as rotational translation of the assembly 23 or
housing thereof. Generally, preventing such translation can operatively
stabilize the semi-spherical portion 1.
[0036] In one embodiment, seats 24 and 25 can be formed as continuous
ring members, discrete stabilizing members or any combination of
such members. Seats 24 and 25 can also be adjustable such that their
compressive contact with the semi-spherical portion 1 can be modified
depending, for example, on particular process requirements for the
separator. Such adjustability of seats 24 and 25 can be facilitated
by, for example, the use of one or more adjustment members associated
therewith. As described above, the invention also contemplates employing
an individual seat that may be in compressive contact with the upper
and/or lower semi-hemispherical portion of the semi-spherical portion
1.
[0037] Rotation of the mounted bearing and spindle assembly 23
can also be prevented by, for example, a positioning member such
as an anti-rotation pin 29. For example, FIG. 1 shows pin 29 positioned
so as to extend through an enlarged opening in the assembly 23.
In one embodiment, such a positioning member can cooperate with
a mounting region for the bearing and spindle assembly 23 to substantially
prevent translation, for example, rotational translation, of the
assembly 23 or housing thereof. As shown, the anti-rotation pin
29 can move within the opening in the assembly 23 so that it does
not interfere with the swiveling of the spindle portion 20. The
extent of rotation and swiveling experienced by the separator can
relate to the speed at which high speed separation occurs. The drive
motor 16 can also be controllably operated to rotate the separator
bowl 10 at desired speeds for separation of the feed liquid.
[0038] Also shown in FIG. 1 are the centrate case 30, a centrate
outlet port 32, a centrate outlet port valve 33 and a centrate valve
34, all of which are, during operation, involved in removing clarified
liquid from the bowl 10 and centrate from the separator. As described
in greater detail below, the centrate case 30 includes an isolation
valve 26 that is open as the feed liquid enters the bowl 10 in the
feed mode. The isolation valve 26 can comprise an annular member
9, preferably, disposed thereabout. During the feed mode, the centrate
outlet port valve 33 is also maintained open. In contrast, the isolation
26 and centrate outlet port valves 33 both close when solids are
pumped from the separator. The isolation valve is described in greater
detail below with reference to FIG. 10, which shows the upper portion
19 of the separator during the feed mode. The centrate outlet port
valve 33 can be closed manually or via a conventional automatic
valve control assembly. The separator further comprises a lower
end region 39 of the separator housing 13.
[0039] FIG. 1 also illustrates an embodiment of the separator having,
for example, a solids divert valve 90 movably located in the lower
end region 39 of the separator housing 13, below a lower surface
of a rotatable residual divert valve 92. Optionally, the lower surface
of the residual divert valve 92 can have a feature that partially
extends within the solids divert valve 90. The residual divert valve
92 located at an opening 76 in the conical lower end 17 of the bowl
10 is shown in a closed position, which is maintained during the
feed mode. When closed, the valve 92 defines a feed liquid passage
94 in communication with a feed liquid port 96, as well as a residual
drain passage 98 in communication with a residual liquid drain port
100. The residual divert valve 92 can also be disposed to communicate
within valve receiving member 120, which may be provided integrally
with the lower end 39 of the separator housing 13. The valve 92
can also be rotated from its closed position about axis 6 such that
the solids divert valve 90 can be urged upward into communication
with the opening 76 to the bowl.
[0040] The separator of the invention can also comprise, as shown
in FIG. 1, a solids passage 104, preferably, disposed axially within
a solids divert piston 102 and extending beyond the divert piston
102 at a lowermost end to incorporate a solids outlet port 106 and
a solids outlet port valve 107. The passage 104, piston 102, port
106 and valve 107 are each involved in removing accumulated solids
from the centrifugal separator during the solids discharge mode
of operation. While solids are pumped from the separator bowl 10,
the solids outlet port valve 107 can be open to, for example, allow
solids to pass from the solids passage 104 through the solids outlet
port 106 to exit the separator.
[0041] The solids outlet port valve 107 may be opened manually
or via a conventional automatic valve control assembly. The solids
discharge mode generally pumps and recovers sensitive solids, such
as, for example, intact cells, and can, for example, pass these
solids onto another process or a storage vessel without further
handling. Without the solids being handled by an operator, they
are less likely to be damaged or contaminated. A separator of the
invention such as, for example, the separator of FIG. 1 can also
feature any configuration or arrangement of passages, valves, pistons,
actuators, assemblies, ports, members and so forth, as described
above, that would be suitable for a particular application.
[0042] A cleaning passage 108 can also be disposed within the solids
divert piston 102, preferably, parallel to the solids passage 104
and, optionally, extending beyond the piston 102 at a lowermost
end to incorporate a cleaning port 111. At an uppermost end, the
cleaning passage 108 may be in communication with the solids passage
104. The cleaning port 111 and passage 108 together can aid in the
recovery of any solids remaining in the passage 104 following the
solids discharge mode, as well as in cleaning or sterilizing the
separator. The cleaning port 111 and passage 108 can also operate
to urge the piston 12 axially upward once the solids discharge mode
is complete.
[0043] In particular, after solids are pumped from the separator,
the solids outlet port valve 107 can be closed such that fluid,
for example, compressed gas or hydraulic liquid, introduced through
the cleaning port 111 and passage 108 contacts the lower conical
portion of the piston 12 and urges the piston upward until it is
returned substantially to an uppermost position for the next feed
mode of operation. Exemplary types of compressed gas for moving
the piston 12 include nitrogen and argon. Similarly, an exemplary
hydraulic liquid that can be used to move the piston 12 within the
bowl 10 can include distilled water.
[0044] In another embodiment, a separator of the invention can
feature, for example, a pinch or ball type valve assembly to facilitate
solids discharge. A conventional pinch type valve assembly may be
preferable for a separator encountering paste-like solids during
operation. An exemplary ball type valve assembly can comprise a
half-ball shaped discharge valve disposed in the lower end region
of the separator housing. The discharge valve of a ball type valve
assembly can also include passages for the feed liquid and residual
liquid being drained from the separator bowl. For example, the discharge
valve can rotate between a closed and an open position during, respectively,
the feed mode and solids discharge mode of operation.
[0045] During the feed mode, the separator housing can be closed
except for the feed and residual liquid passages of the ball type
valve assembly, which may communicate with, for example, the opening
in the conical lower end of bowl. A ball type valve assembly can
also include, for example, one or more ports for piston retraction
and cleaning or sterilizing the separator. An exemplary ball type
valve assembly that can be employed in a separator of the invention
has been described by U.S. Pat. No. 6,776,752, which is hereby incorporated
by reference herein.
[0046] FIG. 2 shows one embodiment of a separator of the invention
comprising ball type valve assembly 40 disposed in the lower end
region 39 of the separator housing 13. Preferably, the ball type
valve assembly 40 features, as shown, a discharge valve 42. For
example, the discharge valve 42 can be mounted below an inward-facing
flange 43. In one embodiment, the discharge valve 42 can incorporate
a feed liquid passage 44 in communication with a feed liquid port
45, as well as a residual liquid drain passage 46 in communication
with a residual liquid drain port 47. A valve seal 48 can also be
disposed on a lower surface of the flange 43.
[0047] During the feed mode, the separator of FIG. 2 features the
discharge valve 42 in a closed position in which its outer upper
surface rests against the valve seal 48. The valve seal 48 can be
inflated by fluid such as, for example, compressed gas or hydraulic
liquid introduced through a valve actuator 49. Preferably, the valve
seal 48 remains inflated throughout the feed mode. FIG. 2 shows
that solids-bearing feed liquid can be introduced through the feed
liquid port 45. The feed liquid can flow from the feed liquid port
45 into the feed liquid passage 44. Preferably, the feed liquid
passage 44 communicates with a main passage 50, which can be axially
disposed within a piston retract actuator 52. An upper end of the
main passage 50 incorporates a jet port 154 for, during the feed
mode, injecting feed liquid into the opening 76 in the conical lower
end 17 of the bowl 10.
[0048] The feed mode of operation for a separator of the invention
is described in greater detail below with reference to FIG. 4, which
shows an embodiment of the separator featuring the solids divert
valve movably located in the lower end region 39 of the separator
housing 13, below a lower surface of the rotatable residual divert
valve. With regard to FIG. 2, the feed mode can, for example, be
further characterized by having the piston retract actuator 52 in
contact with the conical lower end 17 of the separator bowl 10.
As shown, the piston retract actuator 52 can move axially upward
and downward in response to fluid such as, for example, compressed
gas or hydraulic liquid.
[0049] After solids have been separated from the feed liquid, the
piston remains in contact with the separator bowl 10 as residual
liquid in the bowl drains through the opening 76 onto a shaped surface
of the discharge valve 42, which also remains, as described above,
in a closed position. As shown in FIG. 2, residual liquid can then
be channeled by the shaped surface of the discharge valve 42 so
as to pass through the residual liquid drain passage 46. The residual
liquid passes through the drain passage 46 and eventually exits
the separator through the residual liquid drain port 47.
[0050] In one embodiment, fluid pressure introduced at a fluid
port 58 acts against a lower surface of an annular actuator flange
57 disposed about the piston retract actuator 52 to urge the retract
actuator 52 upward. The axial movement of the piston retract actuator
52 may also be controlled by fluid introduced through an actuator
control port 54. For example, the actuator control port 54 can be
provided in the lower end region 39 of the separator housing 13
such that fluid enters the port 54 and contacts an upper surface
of the annular actuator flange 57 disposed about the piston retract
actuator 52.
[0051] The actuator control 54 and fluid port 58 can also act in
concert to actuate and move the piston retract actuator 52 by concomitantly
contacting the upper and lower surfaces of the annular actuator
flange 57 fluid. For example, the piston retract actuator 52 can
be urged upward when pressure acting against the upper surface of
the annular actuator flange 57 is less than that acting against
the lower surface thereof. During the feed mode, the piston retract
actuator 52 can be urged axially upward and held in gas-tight communication
with the opening 76 of the bowl 10. The interface of the piston
retract actuator 52 and the bowl opening 76 can also be sealed by,
for example, PTFE or TEFLON-based (E. I. du Pont de Nemours and
Company, 1007 Market Street, Wilmington, Del. 19898) elastomeric
seals disposed therebetween.
[0052] Preferably, the piston retract actuator 52 is also in gas-tight
communication with the opening 76 of the bowl 10 while the piston
12 is being returned substantially to its uppermost position, which
generally follows the solids discharge mode. As described above,
such gas-tight communication can be achieved via fluid pressure
introduced through the fluid port 58, which acts against the lower
surface of the annular actuator flange 57 disposed about the piston
retract actuator 52. Although fluid may also enter the separator
at the actuator control port 54, the pressure exerted on the upper
surface of the flange 57 would be less than that acting against
its lower surface to maintain the gas-tight communication. It could
also be preferable for the actuator control port 54 not to introduce
fluid to the upper surface of the flange 57 such that the fluid
port 58 would entirely control the movement of the piston retract
actuator 52.
[0053] To return the piston 12 substantially to its uppermost position,
fluid contacts the lower conical portion of the piston 12 after
entering the separator bowl 10 via the feed liquid port 45 after
fluid pressure urges the piston retract actuator 52 upward along
the vertical axis 41 to communicate with the bowl opening 76. When
the piston is returned substantially to its uppermost position,
fluid introduced through the feed liquid port 45 can be discontinued.
The piston 12 is then held substantially in its uppermost position
by frictional forces between one or more piston seals adjacent the
inner wall of the bowl 10. As shown in FIG. 2, an annular piston
seal 59 is disposed about the piston 12 and interfaces with the
inner wall of the bowl 10. The seal 59 can comprise components such
as, for example, PTFE or TEFLON-based (E. I. du Pont de Nemours
and Company, 1007 Market Street, Wilmington, Del. 19898) elastomeric
materials.
[0054] Prior to returning the piston 12 substantially to its uppermost
position, the separator is typically operated in the solids discharge
mode in which solids are pumped from the bowl 10. In the separator
of the invention shown in FIG. 2, the solids discharge mode is characterized
by the discharge valve 42 rotated about a rotational axis 6 to an
open position such that solids can leave the separator as the piston
12 travels axially downward. The separator can also be readily cleaned
or sterilized-in-place, preferably, after the solids discharge mode,
with the discharge valve 42 rotated into an open position.
[0055] For example, in order to rotate the discharge valve 42 from
a closed position, during the feed mode, to an open position, during
the solids discharge mode, the valve seal 48 can be deflated. The
valve seal can be deflated by, for example, discontinuing the introduction
of fluid at the valve actuator 49. An upper offset portion of the
discharge valve 42, which can include the piston retract actuator
52, is then preferably rotated 90.degree. about the rotational axis
6, away from the opening defined by the inner edge of the flange
43. In one embodiment, prior to rotating the discharge valve 42
to an open position for the solids discharge mode, the piston retract
actuator 52 is removed from gas-tight communication with the opening
76 of the bowl 10. The actuator 52 can move axially downward away
from the bowl 10, for example, as described above.
[0056] With the piston retract actuator 52 removed from gas-tight
communication with the bowl opening 76 and the discharge valve 42
rotated to an open position, solids can be pumped from the separator
through the conical lower end 17 of the bowl 10. Preferably, solids
are pumped from the separator bowl as the piston 12 travels axially
downward. In general, the solids discharge mode begins in the upper
portion 19 of the separator such as described in greater detail
below with reference to the separator in FIG. 7. As shown in FIG.
2, the piston 12 can also feature a knife-edge 62, which may aid
in the separation of exceptionally paste-like solids that stick
near the conical lower end 17 or at the opening 76 of the separator
bowl 10.
[0057] FIG. 3 is a section view of the separator of FIG. 2 featuring
a laser sensor assembly 122. For example, the assembly 122 can be
mounted within or external to the separator housing 13 by any suitable
means. In general, optical elements such as, for example, focusing
and reflecting members can be used to facilitate any suitable mounting
options, configurations or arrangements for the assembly 122. As
shown, the laser sensor assembly can be disposed above or at the
upper portion 19 of the separator. Preferably, the assembly 122
is disposed above the collar-like extension 22 of the upper end
for the separator housing 13. The laser sensor assembly 122 can
be used to monitor the axial movement of the piston 12 within the
separator bowl 10. In one embodiment, the separator can, for example,
be any conventional type of laser light emitting device.
[0058] For example, the laser sensor assembly 122 of FIG. 3 can
monitor the axial movement of the piston 12 by emitting a pulsed
laser light 124. As will be appreciated by those of ordinary skill
within the art, the assembly 122, by emitting then detecting the
pulsed laser light 124, can provide a time-to-travel measurement
from which the location of the piston 12 within the bowl 10 can
be determined. In one embodiment, a reflective surface or member
associated with the piston 12, and, preferably, optically aligned
with the laser sensor assembly 122 such as via an optical path within
the hub 60 of the bowl 10, can reflect the laser light back to the
assembly 122. Moreover, such a time-to-travel measurement can also
provide an operator with input regarding the axial distance that
the piston 12 has traveled. The laser sensor assembly 122 in FIG.
3 can be used to monitor the piston 12 within the bowl as the piston
travels axially upward or downward as, for example, a function of
pressure employed to move the piston 12 within the bowl 10. The
invention also contemplates using other such conventional assemblies
or devices based on, for example, ultrasonic, infrared or radiation
energy emitting means to monitor the movement of the piston 12.
[0059] FIG. 4 illustrates a separator of the invention operating
during the feed mode in which the bowl 10 and the piston 12 are
rotating together at high speed. For example, the solids-bearing
feed liquid is injected into the bowl and flows in a path 64 up
the inner surface of the conical lower end 17 of the bowl. Preferably,
the piston 12 is held at its uppermost position by hydraulic pressure
from the clarified liquid 72 such that it is urged against the hub
60 of the bowl, maintaining the centrate valve 34 in the open position.
In one embodiment, the centrate valve 34 is urged open by pins 67
extending from the hub 60 and into the piston 12 to push the valve
34 downward along the vertical axis 41. The centrate valve 34 can
close during the solids discharge mode as, for example, springs
66 are urged upward, which is described in greater detail below.
[0060] The centrate valve 34 and piston 12 can, for example, also
include one or more seals. Preferably, one or more seals can be
employed with the centrate valve to prevent clarified liquid from
returning to the interior of the separator bowl 10 after exiting
therefrom. Such seals can also be used so as to prevent solids from
entering the centrate case 30 during the downward movement of the
piston 12 in the solids discharge mode. Moreover, such seals can
allow a portion of the separator bowl 10 above the piston 12 to
become and remain pressurized such that the piston can be efficiently
urged downward by fluid pressure during the solids discharge mode.
Seals associated with the centrate valve 34 and piston 12 may also
prevent clarified liquid from flowing between the interior surface
of the bowl 10 and piston 12. The invention also contemplates employing
one or more seals in association with any one of or all of the passages,
valves, pistons, actuators, assemblies, ports, members and the like
described herein.
[0061] Exemplary seals of the centrate valve 34 and piston 12 can
comprise components such as, for example, PTFE or TEFLON-based (E.
I. du Pont de Nemours and Company, 1007 Market Street, Wilmington,
Del. 19898) elastomeric materials. For example, such seals are described
in greater detail below with reference to the separator shown in
FIG. 10. As shown in FIG. 4, the piston 12 can also be held substantially
in its uppermost position by frictional forces between piston seals
56 adjacent the inner wall of the bowl 10. Preferably, these seals
56 are disposed about the piston 12 and interface with the inner
wall of the bowl 10. In one embodiment, the seals 56 can be separated
from each other by a linear portion on the piston 12. The seals
56 can, for example, prevent misalignment of the piston during its
axial movement and provide for uniform communication with the interior
surface of the bowl such that the bowl may be efficiently pressurized
either above or below the piston 12. In another embodiment, the
piston 12 can feature a plurality of seals disposed thereabout and
interfaced with the inner wall of the bowl 10. Moreover, in lieu
of the seals 56, a single seal 59 such as, for example, shown in
FIG. 2 can be disposed about the piston 12.
[0062] In one embodiment, the interior of the bowl 10 of a separator
of the invention can feature a scratch resistant type coating. For
example, such a coating can be disposed along a portion or the entire
interior surface of the bowl 10. Exemplary coatings for the interior
of a separator bowl can include hard chromium, boron-nitride, titanium
or combinations thereof. Preferably, a scratch resistant type coating
can prevent abrasions to the bowl. Such abrasions can lead to the
feed liquid shearing, which may hinder efficient solids separation
and recovery. A scratch resistant type coating within the bowl can
also provide for uniform communication between the interior surface
thereof and one or more seals disposed about the piston 12. Uniform
communication between the interior surface of the bowl and one or
more seals disposed about the piston 12 can aid in the efficient
pressurization of the bowl such as described above and in the efficient
recovery of accumulated solids.
[0063] Under the separation forces generated by high speed rotation
of the bowl 10, FIG. 4 shows the feed liquid separated into accumulated
solids 70 and clarified liquid 72. The clarified liquid 72 continues
upward along the path 64, through the centrate valve 34 and exits
the bowl at the centrate discharge aperture 74. In one embodiment,
the centrate discharge aperture 74 can be disposed at or substantially
at an upper end of the separator bowl 10. Preferably, the discharge
aperture 74 leads into the centrate case 30 that can feature the
isolation valve 26, which is, for example, open during the feed
mode of operation. The isolation valve 26 can be maintained open
by fluid such as compressed gas or hydraulic liquid acting against
an annular member 9 disposed about the valve 26.
[0064] For example, in the feed mode, fluid can be introduced to
a lower surface of the annular member 9 through a lower port 4.
The clarified liquid 72 can then pass from the centrate case 30
into the centrate outlet port 32, which features the centrate outlet
port valve 33. Preferably, the centrate outlet port valve 33 is
open during the feed mode to allow the clarified liquid 72 to exit
the separator as centrate 73.
[0065] A separator of the invention can also be employed in applications
in which there is a need to preserve the quality of the centrate
73 that exits therefrom. For example, a sensitive organic polymer
that exits the separator as centrate may be the only desired yield
from a given separation. Indeed, the invention also contemplates
an application in which both the centrate and solids are desired
yields. In an application in which it is important to preserve the
quality of centrate exiting the separator, the separator of the
invention can be used to reduce overall shearing of clarified liquid
and centrate resulting therefrom. Typically, such shearing can,
for example, degrade the quality of sensitive centrate.
[0066] In one embodiment, a separator of the invention can employ,
for example, a separation and/or solids recovery means in addition
to or in lieu of a rotating bowl. One example of a separation means
is a conventional pairing-disc assembly. A separator of the invention
can comprise a pairing-disc assembly to, for example, reduce the
overall shearing of clarified liquid and centrate resulting therefrom.
For example, a pairing-disc assembly can be used in an application
for a separator of the invention in which it is desired to preserve
the quality of the centrate. As will be appreciated by those of
ordinary skill within the art, a pairing-disc assembly can perform
generally continuous separation of solids from feed liquid with
minimal overall shearing of, for example, desired centrate.
[0067] A separator of the invention can also comprise one or more
features such as, for example, fastening and mounting means, by
which the bowl 10 can be decoupled from the separator housing 13.
Preferably, with the bowl 10 decoupled, the piston 12 and its associated
assemblies can be substituted with a separation and/or solids recovery
means such as the pairing-disc assembly described above. A separator
bowl suitable for use with the substituting separation and/or solids
recovery means could subsequently be coupled to the separator of
the invention via one or more features. The separator of the invention
is then able to be used for a specific application. The ability
to modify the configuration of a separator of the invention for
a given solids separation application permits use of such separation
and/or solids recovery means as an axial scraper or a piston-extrusion
assembly described by U.S. Pat. No. 6,776,752, which is hereby incorporated
by reference herein.
[0068] As shown in the separator of FIG. 4, in the feed mode of
operation, the solids divert valve 90 can be held upwardly against
a lower surface of the residual divert valve 92 in gas-tight agreement.
In one embodiment, the solids divert valve 90 can feature one or
more seals such as, for example, disposed thereon. For example,
such seals can be used to enable pressurization of the separator
housing 13 and bowl 10, preferably, above the upper portion of the
piston 12 to provide for movement of the piston 12. Such seals can
comprise components such as, for example, PTFE or TEFLON-based (E.
I. du Pont de Nemours and Company, 1007 Market Street, Wilmington,
Del. 19898) elastomeric materials. With such seals enabling pressurization
of the separator housing 13 and the bowl 10, preferably, above the
upper portion of the piston 12, the isolation valve 26 can remain
open during, for example, the solids discharge mode. A configuration
in which the isolation valve 26 of the separator in FIG. 4 remains
open during, for example, the solids discharge mode of operation
can be advantageous for a particular application.
[0069] Preferably, the separator shown in FIG. 4 features the solids
divert valve 90 with one or more seals. Such seals can provide for
efficient pressurization of the separator bowl 10, preferably, above
the upper portion of the piston 12 when, for example, the isolation
valve 26 is in a closed position such as during the solids discharge
mode. For example, by having the isolation valve 26 closed during
a solids discharge mode of operation, the volume pressurized to
move the piston within the bowl and the time required for pressurization
can be reduced. The separator of the invention as described above
with reference to FIG. 2 preferably features the isolation valve
26 in the closed position when it is desirous to pressurize the
separator bowl 10, for example, above the upper portion of the piston
12 in order to axially move the piston such as during the solids
discharge mode of operation. With the isolation valve closed, the
volume between the housing 13 and the bowl 10 need not be pressurized,
and the housing also need not be constructed so as to be capable
of maintaining such pressurization.
[0070] Seals comprising components such as, for example, PTFE or
TEFLON-based (E. I. du Pont de Nemours and Company, 1007 Market
Street, Wilmington, Del. 19898) elastomeric materials can also,
for example, be disposed on or associated with the residual divert
valve 92 to, preferably, seal the interface between the valve 92
and the solids divert valve 90. In one embodiment, the solids divert
valve 90 can be urged upward by the solids divert piston 102 on
which the valve 90 is disposed at an uppermost end in communication
with the solids passage 104 of the piston 102. As shown in FIG.
4, pneumatic or hydraulic pressure introduced at an actuator port
112 acts against a lower surface of an annular flange 110 disposed
about the solids divert piston to urge the piston 102 upward.
[0071] The solids divert piston 102 moves axially upward and downward
in response to pneumatic or hydraulic pressure. The axial movement
of the divert piston 102 may also be controlled by compressed gas
or hydraulic fluid introduced through a control port 113. The control
port 113 is provided in the lower end region 39 of the separator
such that compressed gas or hydraulic fluid enters the port 113
and contacts an upper surface of the annular flange 110 disposed
about the solids divert piston 102. The control 113 and actuator
port 112 can also act in concert to actuate and move the divert
piston by concomitantly contacting the upper and lower surfaces
of the annular flange 110 with compressed gas or hydraulic fluid.
[0072] Also shown in FIG. 4 is the residual divert valve 92 in
a closed position located at the opening 76 in the bottom of the
bowl 10. The valve 92 defines the feed liquid passage 94 in communication
with the feed liquid port 96 such that the feed liquid can be injected
into the bowl 10 along the path 64. The feed liquid is injected
into the bowl 10 across a gap such that the residual divert valve
92 need not contact the bowl 10 as it rotates, preventing mechanical
wear of the valve 92 and the bowl 10. Operatively coupled to the
valve 92 is a residual divert valve actuator 114. The actuator 114,
which can be a pneumatic or hydraulic cylinder, rotates the residual
divert valve 92 from its closed position about axis 6. While feed
liquid is fed through the feed liquid passage 94 and into the bottom
of the bowl 10, the solids outlet port 106 of the solids divert
piston 102 features the solids outlet port valve 107 in a closed
position.
[0073] In one embodiment, a separator of the invention can reduce
the extent of overall shearing of the clarified liquid 72 as it
passes upward along path 64, through the centrate valve 34 and exits
the bowl 10 at the centrate discharge aperture 74. For example,
the extent of overall shearing of the clarified liquid 72 can be
reduced by the movement of the clarified liquid 72 such as shown
in FIG. 5. FIG. 5 shows that a separator of the invention and, in
particular, the centrate valve 34 can, by design, cause an underflow
effect of the clarified liquid along underflow path 129.
[0074] The underflow path shown in FIG. 5 is submerged below the
external boundary 130 of the clarified liquid 72 by the configuration
and/or arrangement of, for example, the bowl 10 and centrate valve
34 during the feed mode. Preferably, by having the underflow path
130 submerged beneath the external boundary 130, air currents, surface
waves, any non-concentric effects of the bowl 10 and so forth generally
tend not to disturb the movement of the clarified liquid. For example,
by not disturbing the movement of the clarified liquid, the extent
of overall shearing thereof can be minimized using a separator of
the invention.
[0075] As shown in FIG. 5, the underflow path 129 also tends to
avoid contact with the solids 70 accumulated along the interior
surface of the bowl 10, thereby avoiding any shearing of the clarified
liquid that could result from such contact. Generally, in a conventional
separator, the flow of clarified liquid is along a surface boundary
such as, for example, the boundary at the accumulated solids or
at the surface interior to the separator bowl. In particular, coriolis
acceleration effects within a conventional separator tend to cause
clarified liquid to flow along the surface boundary at the interior
of the bowl, exposing the liquid to any potential shearing forces
in the bowl. The underflow path 129 of clarified liquid 72 in a
separator of the invention avoids any such surface boundaries so
as to limit the extent of overall shearing.
[0076] FIG. 6 illustrates the separator with the residual divert
valve 92 closed to permit the residual liquid 132 to drain out of
the bowl 10 and into the residual liquid drain passage 98. The drain
passage 98 leads into the residual liquid drain port 100, where
the residual liquid 132 eventually drains from the separator. In
one embodiment, the residual liquid 132 can also be, for example,
provided back to a feed tank associated with the separator. The
feed tank can then provide the separator with the residual liquid,
for example, in the feed liquid for further solids separation. The
liquid 132 is typically drained from the separator by gravity after
the feed mode is completed and the high speed rotational separation
has been performed. The feed liquid port 96 is also closed or under
sufficient back pressure to prevent liquid 132 from exiting the
separator through the feed liquid passage 94. Although the bowl
10 and the piston 12 are no longer rotating, accumulated solids
70 remain compressed tightly against the inner surface of the separator
bowl 10. The accumulated solids 70 can be recovered from the bowl
10 during the solids discharge mode of operation.
[0077] As the residual liquid 132 drains from the bowl 10, the
piston 12 is also held substantially in its uppermost position predominately
by frictional forces between the piston seal or seals 56 adjacent
the inner wall of the bowl 10. In FIG. 6, the separator is also
shown with the solids outlet port valve 107 closed and the centrate
outlet port valve 33 open. The isolation valve 26 of the centrate
case 30 is also maintained open as it was throughout the feed mode
of operation. Also shown is the solids divert piston 102 and the
annular flange 110 disposed about the piston 102. The lower surface
of the annular flange 110 is contacted by fluid such as, for example,
compressed gas or hydraulic liquid introduced through actuator port
112 such that the solids divert piston 102 holds the solids divert
valve 90 upward in gas-tight agreement with the residual divert
valve 92. The agreement between the solids divert valve 90 and the
residual divert valve 92 permits residual liquid 132 to drain out
of the bowl 10 and into the residual liquid drain passage 98, where
the liquid exits the separator.
[0078] After the residual liquid 132 has substantially drained
from the bowl 10, the separator is prepared for pumping of the accumulated
solids 70 in the solids discharge mode. The centrate outlet port
valve 33 and the isolation valve 26 are closed prior to solids pumping.
As described above, the centrate outlet port valve 33 may be closed
manually or via an automatic valve control assembly. The isolation
valve 26 is closed by discontinuing fluid introduced through the
lower port 4 of the separator. The fluid had acted on a lower surface
of the annular member 9 disposed about the isolation valve 26 to
maintain it open. For the solids discharge mode, as shown in FIG.
7, fluid such as, for example, compressed gas or hydraulic liquid
instead contacts an upper surface of the annular member 9 to actuate
and close the isolation valve 26. The fluid is introduced through
an upper port 61 during solids discharge and contacts the annular
member 9 to urge the isolation valve 26 against the flange 51 disposed
in the upper portion 19 of the separator.
[0079] FIG. 7 illustrates the separator operating in the solids
discharge mode of operation. FIG. 7 is split lengthwise to show
two separate positions of the piston 12. On the left, the piston
is partway through its downward travel, and on the right, the piston
is at the lowermost point of its stroke completing the discharge
operation, with its lower conical portion resting against the inner
surface of the conical lower end 17 of the bowl 10. As shown, the
piston is urged downward along the vertical axis 41 by, for example,
fluid such as compressed gas or hydraulic liquid acting against
the upper portion of the piston 12. Also shown is the centrate valve
34 in a closed position, under the upward urging force of the springs
66. The springs 66 are urged upward by interaction between the accumulated
solids 70 and the lower conical portion of the piston 12 during
its downward travel. With the piston 12 traveling downward, the
accumulated solids 70 are pressed out of the opening 76 at the bottom
of the bowl 10.
[0080] The lower conical portion of the piston 12 and the inner
surface of the conical lower end 17 of the bowl 10 are machined
for precise fit to efficiently remove as much of the accumulated
solids 70 as possible. The movement of the piston 12 along the vertical
axis 41 is primarily caused by fluid introduced through a driving
port 2 in the upper portion 19 of the separator. Fluid pressure
introduced at the driving port 2 eventually contacts the upper portion
of the piston 12, when the centrate case 30 and the section of the
bowl 10 above the upper portion of the piston 12 disposed therein
are completely sealed and pressurized. The centrate case 30 and
the section of the bowl 10 above the upper portion of the piston
12 can be sealed and pressurized when the isolation valve 26 is
closed.
[0081] Moreover, the isolation valve 26 closes as it is urged downward
against the flange 51 by compressed gas or hydraulic fluid introduced
through the upper port 61. The compressed gas or hydraulic fluid
eventually contacts the upper surface of the annular member 9, which
actuates the isolation valve 26. The centrate outlet port valve
33 for the centrate outlet port 32 is also closed manually or by
an automatic valve control assembly during solids discharge mode.
The isolation valve 26 is described in greater detail below with
reference to FIG. 11, which shows the upper portion 19 of the separator
during the solids discharge mode.
[0082] The solids discharge mode begins in the upper portion 19
of the separator when the piston 12 is urged axially downward. At
the separator lower end region 39, the pumping mode begins as the
residual divert valve 92 is rotated from its closed position by
the residual divert valve actuator 114. The valve actuator 114 rotates
the residual divert valve about axis 6 in response to, for example,
fluid pressure. After the solids divert piston 90 has been lowered
along the vertical axis 41 from contact with the residual divert
valve 92, the valve 92 is preferably rotated 90.degree. from its
closed position. The solids divert piston 90 is then urged upward
along the vertical axis 41 as fluid such as, for example, compressed
gas or hydraulic liquid is applied through the actuator port 112
to act on a lower surface of the annular flange 110. Movement of
the solids divert piston 102 may also be controlled by fluid pressure
introduced through the control port 113, which can act in concert
with the actuator port 112. The control port 113 allows fluid to
contact the upper surface of the annular flange 110. The solids
divert piston 102 is then urged upward when pressure acting against
the upper surface of the annular flange 110 is less than that acting
against its lower surface.
[0083] As shown, the solids divert piston 102 is urged axially
upward such that the solids divert valve 90 is held in gas-tight
communication with the opening 76 at the bottom of the separator
bowl 10. The interface of the solids divert valve 90 and the bowl
opening 76 can also be sealed by seals disposed therebetween comprising
components such as, for example, PTFE or TEFLON-based (E. I. du
Pont de Nemours and Company, 1007 Market Street, Wilmington, Del.
19898) elastomeric materials such that any solids pumped from the
bowl 10 will not become contaminated by contact with the surrounding
environment. A sealed interface also prevents accumulated solids
70 from being lost during recovery.
[0084] Accumulated solids 70 pushed through the opening 76 in the
bottom of the bowl 10 pass into the solids passage 104 disposed
partially within the solids divert piston 102 below the solids divert
valve 90. The solids passage 104 extends beyond the lowermost end
of the piston 102 leading into the solids outlet port 106. As described
above, the solids outlet port valve 107 for outlet port 106 is opened
prior to discharge such that the pumped solids can pass through
the outlet port and valve 106, 107 to exit the separator. The solids
outlet port and valve 106, 107 can also be configured so that the
pumped solids may be passed onto another process or a storage vessel
without further handling by an operator, which reduces the likelihood
of or opportunity for contamination.
[0085] Solids discharge is complete when the piston 12 reaches
the lowermost point of its downward stroke and rests against the
inner surface of the conical lower end 17 for the bowl 10. After
the accumulated solids 70 have been discharged from the bowl 10,
the piston 12 is returned substantially to its uppermost position
by fluid acting against the lower conical portion of the piston
12, as shown in FIG. 8. Fluid such as, for example, compressed gas
or hydraulic liquid introduced at the driving port 2 in the upper
portion 19 of the separator, which had acted on the upper portion
of the piston 12, is discontinued before the piston can be urged
upward along the vertical axis 41. Also shown in FIG. 8 is fluid
contacting the lower conical portion of the piston 12 after entering
the separator through the cleaning passage 108 from the cleaning
port 111. When the solids outlet port valve 107 is closed, the fluid
introduced at the cleaning port 111 eventually passes through the
bowl opening 76 to urge the piston 12 upward. The separator bowl
10 may also be cleaned or sterilized-in-place while the piston 12
is moved upward or after it has substantially reached its uppermost
position.
[0086] The solids outlet port valve 107 transitions from an open
to a closed position after the accumulated solids are substantially
pumped from the separator. The outlet port valve 107 remains in
a closed position while the piston 12 is urged upward and throughout
the next feed cycle of operation. FIG. 8 further shows that before
the lower conical portion of the piston 12 is contacted by, for
example, compressed gas or hydraulic liquid, the isolation valve
26 for the centrate case 30 and the centrate outlet port valve 33
are opened. Fluid is also no longer introduced through upper port
61 in the upper portion 19 of the separator. Instead, fluid such
as, for example, compressed gas or hydraulic liquid enters the separator
through the lower port 4 to eventually contact a lower surface of
the annular member 9 disposed about the isolation valve 26 so as
to open the valve 26. After the upward stroke of the piston 12 is
complete, the piston is held substantially at an uppermost position
by frictional forces between piston seals 56 adjacent the inner
wall of the bowl 10.
[0087] The solids divert piston 102 remains in gas-tight communication
with the opening 76 at the bottom of the bowl 10 while the piston
12 is urged upward. The gas-tight communication is achieved by fluid
pressure introduced through the actuator port 112, which acts against
the lower surface of the annular flange 110 disposed about the solids
divert piston 102. Although fluid such as, for example, compressed
gas or hydraulic liquid may also enter the separator at control
port 113, the pressure exerted on the upper surface of the annular
flange 110 would be less than that acting against its lower surface
to maintain the gas-tight communication. It could also be preferable
for the control port 113 to not introduce fluid to the upper surface
of the annular flange 110 such that the actuator port 112 would
entirely control the movement of the solid divert piston 102.
[0088] When the piston 12 substantially reaches its uppermost position,
the solids divert valve 90 is drawn downward along the vertical
axis 41 in response to movement by the solids divert piston 102
such that the residual divert valve 92 can be rotated to its closed
position about the rotational axis 6. The residual divert valve
92 is rotated closed by the residual divert valve actuator 114.
The solids divert piston 102 can be lowered by discontinuing or
reducing the fluid pressure previously applied at actuator port
112. Movement of the solids divert piston 102 may also be controlled
by fluid pressure introduced through the control port 113, which
can act in concert with the actuator port 112. The control port
113 allows fluid such as, for example, compressed gas or hydraulic
liquid to contact the upper surface of the annular flange 110. The
solids divert piston 102 is then urged downward when pressure acting
against the upper surface of the annular flange 110 is greater than
that acting against its lower surface.
[0089] FIG. 9 illustrates the lower end region 39 of the separator
in greater detail with the residual divert valve 92 returned to
its closed position. Although not shown, the piston has been returned
substantially to its uppermost position within the bowl. As described
above, the piston can be held in an uppermost position by frictional
forces between the piston seals adjacent the inner wall of the bowl.
In FIG. 9, the solids divert valve 90 is held upward against the
lower surface of the residual divert valve 92 by the solids divert
piston 102. As shown, fluid such as, for example, compressed gas
or hydraulic liquid introduced at the actuator port 112 acts against
a lower surface of the annular flange 110 disposed about the divert
piston 102 to urge it upward along a vertical axis 41. Although
the solids discharge mode has been completed, solids can remain
in the solids passage 104 of the piston 102. To remove the remaining
solids, fluid such as, for example, compressed gas or hydraulic
liquid is introduced through the cleaning port 111 of the cleaning
passage 108, while the solids outlet port valve 107 is open.
[0090] The cleaning passage 108 and port 111 extend beyond the
lowermost end of the solids divert piston 102, with the cleaning
passage partially disposed within the piston 102. The cleaning passage
108 is also in communication at its uppermost end with the solids
passage 104 of the piston 102. This communication permits fluid
introduced at the cleaning port 111 to pass through the cleaning
passage 108 and into the solids passage 104. The fluid pushes the
remaining solids in the passage 104 toward the solids outlet port
106, when the solids outlet port valve 107 is open. As described
above, when the solids outlet port valve 107 is closed, the cleaning
passage 108 and port 108 operate to urge the piston 12 axially upward
and return it substantially to an uppermost position for the next
feed cycle of operation.
[0091] As shown, the solids passage 104 is in communication with
the solids outlet port 106 such that any remaining solids in the
passage 104 can exit the separator by passing through the solids
outlet port valve 107. The solids outlet port 106 may pass the recovered
solids onto another process or a storage vessel without further
handling such as, for example, by an operator. The cleaning passage
108 and port 111 can also be used to clean or sterilize the solids
passage 104 and solids outlet port 106 and valve 107. Such clean-in-place
or sterilize-in-place processes are convenient for preparing the
centrifugal separator for the next cycle of operation. These processes
also increase the solids recovery yield and can reduce the likelihood
of or opportunity for contamination.
[0092] FIG. 10 illustrates the upper portion 19 of the separator
in greater detail during the feed mode of operation with the isolation
valve 26 in an open position. In the feed mode, as described above,
the piston 12 is held at its uppermost position by fluid pressure
from the feed liquid as well as frictional forces between piston
seals 56 adjacent the inner wall of the bowl 10. As shown, the isolation
valve 26 can be urged open or closed by movement upward or downward,
respectively, along the vertical axis 41. The isolation valve 26
is urged upward by, for example, compressed gas or hydraulic liquid
acting against the lower surface of the annular member 9 disposed
about the valve 26. The compressed gas or hydraulic liquid is provided
to the lower surface of the annular member 9 through the lower port
4.
[0093] FIG. 10 also shows optional seals 140 for the centrate valve
34 and seals 145 for the piston 12. Preferably, the seals 145 can
prevent clarified liquid from flowing between the piston 12 and
the interior surface of the separator bowl 10. As described above,
seals 140 can be used so as to prevent solids from entering the
centrate case 30 during the downward movement of the piston 12 in
the solids discharge mode. Seals 145 can allow the bowl 10 above
the piston 12 to become and remain pressurized such that the piston
can be efficiently urged downward by fluid pressure during the solids
discharge mode. The invention also contemplates additional seals
that can be used in any one of the embodiments of the invention.
[0094] Also shown in FIG. 10 is the isolation valve 26 separated
from flange 51 such that the piston 12 and bowl 10 can freely rotate
without significant mechanical wear. With the isolation valve in
an open position, the centrate 70 is allowed to enter the centrate
case 30 by passing through the centrate discharge opening 74. The
centrate 70 eventually exits the separator after it passes through
the centrate outlet port 32 and the centrate outlet port valve 33,
which is also maintained in an open position in the feed mode. The
centrate outlet port valve 33 may be opened manually or by an automated
valve control.
[0095] FIG. 11 illustrates the upper portion 19 of the separator
in greater detail during the solids discharge mode of operation.
As shown, the isolation valve 26 can be urged open or closed by
movement upward or downward, respectively, along the vertical axis
41. The isolation valve 26 is urged downward by fluid such as, for
example, compressed gas or hydraulic liquid acting against the upper
surface of the annular member 9 disposed about the valve 26. The
fluid is provided to the upper surface of the annular member 9 through
upper port 61. Prior to the solids discharge mode, fluid introduced
to the lower surface of the annular member 9, maintaining the isolation
valve 26 open, is preferably discontinued. The bowl 10 and piston
12 are also no longer rotating such that the isolation valve 26
can then rest against the flange 51.
[0096] With the isolation valve 26 in contact with the flange 51
and, as described above, the centrate outlet port valve 33 closed,
the centrate case 30 and the section of the bowl 10 above the upper
portion of the piston 12 disposed therein can be pressurized. Pressurization
of the centrate case 30 and the section of the bowl 10 above the
upper portion of the piston 12 occurs as fluid such as, for example,
compressed gas or hydraulic liquid is introduced to the separator
at the driving port 2. The fluid does not exit the centrate case
30 or the bowl 10 due to the gas-tight agreement between the valve
26 and flange 51. A seal made of components such as, for example,
PTFE or TEFLON-based (E. I. du Pont de Nemours and Company, 1007
Market Street, Wilmington, Del. 19898) elastomeric materials can
also be disposed on the valve 26 to seal its interface with the
flange 51. For example, in one embodiment, such as the seal associated
with the valve 26 can prevent clarified liquid from passing into
the separator housing 13.
[0097] As the centrate case 30 and the section of the bowl 10 above
the piston 12 pressurizes, the isolation valve 26 is maintained
closed against the flange 51. Pressurization of the centrate case
30 and the section of the bowl 10 above the upper portion of the
piston 12 eventually provides a greater pressure above the piston
12 than below its lower conical portion. The difference in pressure
causes the piston 12 to be urged downward along the vertical axis
41 as fluid contacts the upper portion of the piston. The downward
axial movement of the piston 12, as described above and shown in
FIG. 7, pushes any accumulated solids 72 along the inner wall of
the bowl 10 through an opening 76 in its conical lower end 17.
[0098] The following table is presented to more fully characterize
and describe the modes of operation for the various embodiments
of the invention described above. TABLE I provides, by way of example
only, the position or configuration of the isolation valve 26, centrate
valve 34, centrate outlet port valve 33, solids outlet port valve
107, solids divert valve 90 and residual divert valve 92 during
the feed and the solids discharge mode of operation for the separator
of FIG. 1. TABLE I also provides, by way of example only, the position
or configuration of each valve of the separator in FIG. 1 when centrate
drains from the bowl, the piston is returned substantially to an
uppermost position following solids discharge and when the separator
of FIG. 1 is cleaned or sterilized-in-place. The valves 26, 34,
33, 107, 90, 92 are each shown in the separator illustrated by FIG.
1. TABLE I is not intended in any way to otherwise limit the scope
of the disclosure or any particular embodiment of the invention.
TABLE-US-00001 TABLE I Centrate Solids Outlet Outlet Solids Residual
Mode Of Isolation Centrate Port Port Divert Divert Operation Valve
Valve Valve Valve Valve Valve Feed Open Open Open Closed -- Closed
Discharge Closed Closed Closed Open Upward Rotated Drain Open Open
Open Closed -- Closed Piston Open -- Open Closed Upward Rotated
Clean -- -- -- Open -- Closed
[0099] While the present invention has been described in conjunction
with a preferred embodiment, one of ordinary skill in the art, after
reading the foregoing specification, will be able to effect various
changes, substitutions of equivalents and other alterations to the
compositions, articles, methods and apparatuses set forth herein.
For example, fluid pressure may be replaced in other embodiments
by, without limitation, an electromechanical force. Similarly, the
lower portion and end of the piston and bowl, respectively, may
not be conical in shape, although it is preferable for solids recovery
that their shapes be complimentary.
[0100] Moreover, the invention also contemplates that the various
passages, valves, pistons, actuators, assemblies, ports, members
and the like described herein can be in any configuration or arrangement
that would be suitable for operation of a centrifugal separator.
The embodiments described above may also each include or incorporate
any of the variations of all other embodiments. For example, the
laser sensor assembly described herein can be used in conjunction
with any or all of the embodiments of the present invention. It
is therefore intended that the protection granted by Letter Patent
hereon be limited only by the definitions contained in the appended
claims and equivalents thereof.
|