Note: Descriptions are shown in the official language in which they were submitted.
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1 This application is a divisional of application serial
number 340,931 filed November 2g, 1979.
SUMMARY OF THE INVENTION
This invention relates generally to apparatus for use
with material flowing through a body, and including a member that
is slidable transversely in the body across the flow stream for
selective or progressive interposition in the stream. Mo~e
particularly, it relates to structures forming a seal between
the body and the slide member.
An application of this invention relates to filter
changers of the type typically employed for the filtration of melt
streams of polymers and, in general, any flowable material passing
from an extruder. In the past, filter changers have been con-
structed with a slidable member carrying the filter material and
means for adjustably clamping the slidable member so that in
operating position it provides a seal that prevents the leakage
of polymer through the transverse passage. However, the slidable
member must not be clamped so tightly as to interfere with move-
ment of the slidable member.
An object of this invention is to provide an improvedmechanical seal for the slidable member, and thereby to eliminate
the necessity for adjustment of seal lockup, associated with the
use of prior art clamping means. It is desirable for such a seal
to be of compact construction and to apply a predetermined
effective force directly to the sealing surfaces. It should apply
the seal force uniformly to these surfaces with little or no
variation in the event of misalignments. It should also com-
pensate for thermal expansion, structural deflections and seal
wear. Further, it should allow for less precise and therefore
more economical tolerancing of components.
A second object of this invention is to provide filter
changers having a substantially uniform and constant active
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1 filter configuration throughout the filter changing operation,
which may comprise either a continuous or an intermittent move-
ment of the filter.
A third object of the invention, in the filter changer
application, is to permit the gradual removal of portions of the
filter from the polymer flow path, and the replacement thereof
with clean filter portions in a manner having minimal effect on
the pressure drop across the filter, and without the introduction
of air into the melt stream.
The problems arising from sudden changes in the
pressure drop are typified by the conventional slide-plate filter
screen changer. A typical changer of this type incorporates a
slide plate containing openings for two breaker plates, recessed
into the slide plate to hold a screen pack. In operation, one
breaker plate and screen pack are in the polymer flow, while the
other breaker plate and screen pack are being cleaned. T~hen the
screen pack in the polymer flow has become sufficiently blinded,
that is, filled with impurities filtered out of the polymer, the
slide plate is rammed across the polymer stream, usually by a
hydraulically powered cylinder, and the clean breaker plate is
put into position for filtering. The sudden change in pressure
drop results from the replacement of a substantially blinded or
plugged screen pack with a clean one. This pressure phenomenon
may be termed a "saw-tooth characteristic."
Cartridge screen changers co~prise a development from
conventional slide-plate changers. The slide plate is eliminated,
and independently removable cartridges are aligned for consecu-
tive advancement into the flow stream. In cartridge changers
adapted for the sudden replacement of each cartridge with the
next, the same problem as that characterizing the slide-plate
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1 changer exists, namely, the production of a sudden change in the
pressure drop across the screen. On the other hand, in cartridge
changers adapted to impart small incremental or continuous
movements to the cartridges for the purpose of minimizing such
sudden changes, the structures of the cartridges are such as to
present non-uniform filter configurations within the polymer
stream. Typically, such cartridges comprise solid frames having
central apertures in which the screens are received. As the
solid marginal portions of these frames advance through the
polymer flow stream, they may present substantial areas thereto
comprising barriers around which the polymer must flow. This
occurs whenever a cartridge is only partially situated with the
polymer flow stream. Further, since the screen pack comprises
the major flow restriction, the cartridge is effectively fully
on-line after it has entered only a short distance into the flow
stream. This also results in a "saw-tooth characteristic."
Another object of the invention is to provide a filter
changer in which the filter is so constructed as to mechanically
prevent the appreciable flow of polymer laterally from the flow
passage between the seals of the slide or filter member.
With the foregoing and other objects in view, as
hereinafter appearing, this invention includes a body having
upstream and downstream passages respectively communicating with
a slide member. A seal member has a surface urged into sealing
engagement with the slide member at an end of a passage. The
urging force may be advantageously applied by spring means
situated around and external to the polymer flow passage. In
particular, a Belleville spring around and external to the
passage is preferred because of its ability to exert high forces
while being contained within a compact space.
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1 In a filter changer application, the invention also
features a filter movable through a filter channel to advance a
portion of the filter progressively into sliding engagement with
and over upstream and downstream seals, and over openings in the
seals that respectively communicate through a portion of the
filter between the upstream and downstream polymer flow passages.
That portion of the filter that slidably engages with the seals
and enters into these openings comprises a region of uniform
porosity, thus presenting a substantially uniform and constant
active filter configuration within the polymer flow stream at all
times during the changing operation, and in all positions of the
filter within and relative to the polymer flow stream.
Another feature comprises a filter plate structure in
which the screen may be made either impermeable, or selectively
permeable to gas flow laterally between the seals, thus allowing
air to be expelled from the interstices of the filter before it
enters into the polymer flow stream. In the latter case, the air
is forced back toward the entrance port of the filter channel by
the polymer under pressure from the extruder.
BRIEF DESCRIPTION OF THE D~AWING
. . _ . ._ . . .
Fig. 1 is a plan view in section showing an extruder
equipped with a preferred form of filter changer according to
this invention.
Fig. 2 is a front elevation corresponding to Fig. 1.
Fig. 3 is a fragmentary detailed elevation of one
embodiment of the filter comprising a filter plate.
Fig. 4 is a fragmentary plan view in section showing
details of the filter plate.
DETAILED DESCRIPTION
Referring to the drawing, a conventional extruder for
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1 heated flowable plastic material is shown at 12. The extruder
has a cylindrical body 14 threaded for mounting an upstream body
16. In front elevation this body has the same rectangular
peripheral outline as a downstream body 18, as viewed in Fig. 2.
The bodies 16 and 18 are secured together by four screws 20. The
upstream body 16 defines an upstream passage 22 and the down-
stream body 18 defines a downstream passage 24.
A slide or filter channel is formed by rectangular
apertures 26 and 28 formed in and between the bodies 16 and 18,
the aperture 26 comprising an entrance port and the aperture 28
comprising an exit aligned therewith.
The downstream body 18 has a reducer bushing 30 within
the downstream passage and fitted on an annular shoulder in the
body. The bushing has a tapered surface 32 formed to facilitate
polymer flow, avoiding the formation of polymer retention regions
that might result in nonuniformities thereof.
Adjacent the filter channel, the body 18 has an annular
inner shoulder 34 in which is fitted a seal and bearing plate 36.
This is a round plate of uniform thickness somewhat exceeding the
depth of the shoulder 34. The plate has a flat, circular and
annular sealing surface 38 located within the filter channel, and
a circular opening defined by this surface that communicates
between the filter channel and the downstream passage 24. This
opening comprises a plurality of apertures 40 formed in the plate
36 by drilling holes therethrough in a uniform pattern, thus
providing lands 42.
The body 14 has an inner annular shoulder 44 receiving
an adaptor ring 46. An upstream seal ring 48 is slidable over a
cylindrical external surface on the ring 46, forming therewith a
seal effective against the penetration of polymer. A Belleville
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1 spring 50 is supported under compression between the adaptor ring
and the seal 48. This spring is of conventional construction,
and typically comprises a number of dished washerlike elements
forming a stack for compression loading. This form of spring i5
capable of providing the high pressures required for an effective
seal. The seal 48 has a flat circular sealing surface 52 located
within the filter channel and urged by the spring toward the
surface 38 of the downstream seal.
Slidable between the sealing surfaces 38 and 52 there
is located a rectangular slide member comprising a filter plate
54. Abutting an edge of this plate is a second filter plate 56
of identical construction. This construction is more par-
ticularly shown in Figs. 3 and 4.
Each filter plate comprises a laminated structure
having a pair of flat metal plates 58 and 60 and a woven metal
screen 62 between the plates. The plate 58 comprises a support
plate and the plate 60 comprises a bearing plate. Although this
embodiment is shown with one screen and two plates 58 and 60,
other embodirnents may be constructed with one plate which is the
bearing plate, or with more than two plates, and with more than
one screen. The screen or screens are calendered to reduce their
permeability so that there will be no appreciable polymer flow
internally thereof into the filter channel, and the screens may
be bonded to one another and/or to the plates to form a
permanent rigid structure,
~ s shown, the entire area of the bearing plate 60 has
formed therein a plurality of upstream perforations 64 forming a
uniform pattern. Similarly, the entire area of the plate 58 has
formed therein a plurality of perforations 66 forming a uniform
pattern in registration with the perforations 64. The width "w'
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1 of the filter plate is preferably not less than the outermost
diameter of the sealing surfaces 38 and 52, represented by a
broken outline 68 in Fig. 2. A broken outline 70 represents the
inner diameter of the sealing surfaces.
Thus the movement of the filter plate through the
filter channel causes portions thereof to move progressively into
sliding engagement with and over the sealing surfaces, and thence
into the openings defined thereby. These portions lie within a
region of the surface of the filter plate that has uniform poro-
sity as shown in Fig. 3, this region including all such portions
passing at any time within the outline 70. More specifically,
within the outline 70, both the pattern formed by the per-
forations 70 and the porosity of the screen or screens with
respect to poly~er flow between the passages remain uniform as
the filter plate moves through the filter channel. By reason of
the construction described, at any position of the filter plate
with respect to the polymer flow channels a substantially uniform
and constant active filter configuration is situated within the
polymer flow stream.
The maximum lateral dimension or diameter of each of
the perforations 64 and 66 is smaller than the width of the
sealing surface 38 or 52 over which it passes, the latter width
being equal to the radial distance between the outlines 68 and
70. Thus in every position of the filter plate, the sealing
surfaces 38 and 52 are effective to prevent polymer flow lateral-
ly of and external to the filter plate.
Moreover, the maKimum lateral dimension of each of the
perforations 64 and 66 is very much smaller than the cross
sectional area of the polymer flow openings defined by the seal-
ing surfaces 38 and 52. Therefore, even though small
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1 transitional changes occur in the effective areas of the aper-
tures 64 and 66 as they enter and leave the openings within the
sealing surfaces, the total of the effective aperture areas
within the openings remains substantially constant. This
prevents any sudden changes in the pressure differential across
the filter plate when it is advanced at a substantially uniform
rate. It will be noted that the construction described provides
a direct, compact and effective means of applying the necessary
seal force through an internally mounted spring. The use of this
spring arrangement provides a uniform application of sealing
force between the surface 52 and the surface of the bearing plate
60, which will result in even seal wear and leak-free operation.
This arrangement also allows the seal to compensate for thermal
expansion, structural deflection and seal wear. In addition,
because of the inherent compensating characteristics of the
spring mechanism, there is allowance for less precise, and
therefore more economical, tolerancing of the parts. Finally,
this arrangement eliminates all requirements for seal lockup
adjustments by the operator, since a predetermined seal force is
~ applied when the unit is assembled and operated within the
specified design limits.
As seen more particularly in Fig. 4, the screen 62
comprises woven strands, preferably of metal, between and through
which air but no appareciable amount of polymer may flow inter-
nally thereof and laterally between the plates 58 and 60. When
each of the perforations 64 and 66 enters the polymer flow chan-
nel, polymer fills the aperture, flowing between and around the
strands of the screen 62 in the direction of the flowing stream.
This flow occurs throughout each aperture and is accompanied by
the application of pressure to the screen portions immediately
11463~8
1 surrounding the aperture. The screen is constructed to permit
the flow of gas internally thereof laterally between the plates
in the regions adjacent the apertures, thus preventing the air
that was initially present in the interstices of the screen from
entering the polymer stream.
Alternatively, the screen may be constructed so that
gas cannot pass internally through it laterally between the
plates in any direction external to the outline 70 but may be
expelled to the space external to the filter changer by leakage
along the surfaces 38 and 52.
In place of the filter plate 54 constructed as shown,
other forms of filter may be used. These may comprise porous
bodies formed of sintered metals, flat metal sheets made porous
by electrochemical etching or other processes, or diffusion-
bonded mats. These forms may comprise either a laminated
construction or they may be monolithic, non-laminated shee~s.
In any case, for the reasons noted above, they are preferably
constructed so that the portions that progress into sliding
engagement with the sealing surfaces and into the openings in
~ the seals are within a region of uniform porosity.
In the practice of this invention, the entire struc-
ture of the filter changer adjacent the polymer flow stream is
maintained at a sufficiently high temperature to ensure the
fluidity of the polymer. In some applications this structure
may even be maintained at a higher temperature than the polymer
by any one of the common methods of heating, such as electrical
resistance heating or steam heating. Apparatus for this purpose
has been omitted from the drawing for the sake of clarity. It
will be obvious that for acceptable operation of the apparatus,
the exact temperature is not of critical importance with respect
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1 to either the formation of seals at the entry and exit ports of
the filter channel or the rate of advancement of the filter into
and out of the polymer flow stream.
The filter is preferably advanced by pushing or pulling
it either continuously at a slow rate, or by a series of con-
secutive incremental intermittent small movements each being a
small fraction of the diameter of the active p~rtion of the
filter within the polymer flow stream. Preferably the filter is
pushed through the filter channel by a suitable pneumatic or
hydraulic mechanism. For illustration, the drawing shows a
hydraulic mechanism having a cylinder 72. The cylinder has
connections 74 and 76, one of which is fitted with a metering
valve or other conventional flow control device 7g for limiting
the force or impluse applied to the filter plate. The filter is
mounted on four guide bars 80 fastened by screws 82 to the
upstream and downstream bodies 16 and 18. Flanges 84 on the
guide bars are fastened by screws 88 to a head plate ~6 on the
cylinder. The cylinder has a piston 90 with an end 9Z threaded
into a blind hole in a pusher block 94. A lock nut 96 ensures
a tight connection to the pusher block. The pusher block is
guided by the guide bars ~0 as it advances. A slot 98 in the
pusher receives one end of the filter 56, this filter being
guided laterally between the guide bars 80 and abutting the
preceding filter 54.
After the pushen block has advanced the filter 56 by a
distance exc~eding its length, hydraulic pressure may be applied
to the connection 74 to retract the pusher block and to permit
the insertion of a clean filter plate.
It will be appreciated that a number of means are
available in the art for controlling the rate of advancement of
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1 the filter, the sizes of incremental movements, their frequency
and the relationship of these parameters to the quantity of
contaminants accumulated in any given time interval on the active
portion of the filter plate. mhese contaminants accumulate
within the apertures 64 on the upstream side of the filter, from
which they are eventually removed when the plate is cleaned.
These apertures become progressively blinded or clogged, thereby
tending to increase the pressure drov across the filter. If
desired, conventional pressure detectors may be introduced in the
polymer flow passages and connected to associated controls for
the hydraulic cylinder 72. Such controls may operate to increase
the rate of advancement of the filter with any increase in the
rate of accumulation of contaminants.
It will be evident that the thicknesses of the plates
58 and 60 in the particular embodiment shown may be the same or
different, that of the plate 60 being chosen to provide apertures
64 of the requisite volumetric capacity for receiving the con-
taminants, and that of the plate 58 being chosen to provide
adequate stiffness to withstand the applied polymer pressure.
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