Patent ID: 12214536

Repeat use of reference characters in the present specification and drawings is intended to represent the same or analogous features or elements of the present subject matter.

DETAILED DESCRIPTION

Reference now will be made to the embodiments of the present subject matter, one or more examples of which are set forth below. Each example is provided by way of an explanation of the present subject matter, not as a limitation. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present subject matter without departing from the scope or spirit of the present subject matter. For instance, features illustrated or described as one embodiment can be used on another embodiment to yield still a further embodiment. Thus, it is intended that the present subject matter cover such modifications and variations as come within the scope of the appended claims and their equivalents. It is to be understood by one of ordinary skill in the art that the present discussion is a description of exemplary embodiments only, and is not intended as limiting the broader aspects of the present subject matter, which broader aspects are embodied in exemplary constructions.

Although the terms first, second, right, left, front, back, etc. may be used herein to describe various features, elements, components, regions, layers and/or sections, these features, elements, components, regions, layers and/or sections should not be limited by these terms. These terms are only used to distinguish one feature, element, component, region, layer or section from another feature, element, component, region, layer or section. Thus, a first feature, element, component, region, layer or section discussed below could be termed a second feature, element, component, region, layer or section without departing from the teachings of the disclosure herein.

Similarly, when a layer or coating is being described in the present disclosure as “on” or “over” another layer or substrate, it is to be understood that the layers can either be directly contacting each other or have another layer or feature between the layers, unless expressly stated to the contrary. Thus, these terms are simply describing the relative position of the layers to each other and do not necessarily mean “on top of” since the relative position above or below depends upon the orientation of the device to the viewer.

Embodiments of the subject matter of the disclosure are described herein with reference to schematic illustrations of embodiments that may be idealized. As such, variations from the shapes and/or positions of features, elements or components within the illustrations as a result of, for example but not limited to, user preferences, manufacturing techniques and/or tolerances are expected. Shapes, sizes and/or positions of features, elements or components illustrated in the figures may also be magnified, minimized, exaggerated, shifted or simplified to facilitate explanation of the subject matter disclosed herein. Thus, the features, elements or components illustrated in the figures are schematic in nature and their shapes and/or positions are not intended to illustrate the precise configuration of the subject matter and are not intended to limit the scope of the subject matter disclosed herein.

It is to be understood that the ranges and limits mentioned herein include all ranges located within the prescribed limits (i.e., subranges). For instance, a range from about 100 to about 200 also includes ranges from 110 to 150, 170 to 190, 153 to 162, and 145.3 to 149.6. Further, a limit of up to about 7 also includes a limit of up to about 5, up to 3, and up to about 4.5, as well as ranges within the limit, such as from about 1 to about 5, and from about 3.2 to about 6.5.

The term “normal processing operations” as used herein in conjunction with filtration apparatuses generally means the state of operation at which a screen changer device of a filtration apparatus is processing a fluid, such as a molten polymer, such that a flow bore body around flow bores of the screen changer device as described herein are heated to an operating temperature associated with the fluid being processed. During such normal processing operations, top and bottom spacer plates and/or screws may be heated in some situations to between an ambient temperature within the environment in which the screen changer device is operating and the operating temperature associated with the fluid being processed. In some situations, top and bottom spacer plates and/or screws may not be heated during such normal processing operations.

The term “screen changing operations” as used herein in conjunction with filtration apparatus generally means the state of operation at which a screen changer device of a filtration apparatus as described herein is preparing for and moving a slide plate of the screen changer device from a first position where a first screen is aligned with flow bores within a flow bore body of the screen changer device to a second position where a second screen is aligned with the flow bores within the flow bore body of the screen changer device, or vice versa. During such screen changing operations, top and bottom spacer plates and/or screws may be heated to temperatures above the operating temperature associated with the fluid being processed during normal processing operations.

The term “chambers” is used herein can mean a cavity with walls and can include, but is not limited to through bores, or channels, that extend through a plate or body, bores that do not extend all the way through a body or plate having an end wall, or a cavity having two or more walls.

Referring toFIGS.1-6, a filtration apparatus, generally designated FA, is illustrated according to one exemplary embodiment. In general, filtration apparatus FA can be employed in one or more types of polymer processing systems in which filtration of a stream of heated polymer melt or extrudate is desired. As one typical yet non-limiting example of a polymer processing application generally known to persons skilled in the art, pelletized or granulated polymer feedstock is loaded into a hopper (not shown) from which the feedstock is delivered to an extruder (not shown). The extruder typically includes a motor-powered auger or screw and a means for heating and melting the feedstock to form a flowable polymer melt. The polymer melt exits the extruder and flows toward filtration apparatus FA. A suitable polymer pressurizing and transport means such as a motor-powered gear pump (not shown) can be provided to assist in driving and pressurizing the polymer melt. Depending on the application, such a gear pump if used can be installed either upstream or downstream from filtration apparatus FA. While the heated, pressurized polymer melt flows through filtration apparatus FA, filtration apparatus FA prevents hardened or agglomerated polymeric material, or other undesirable constituents, from passing to the downstream side. From filtration apparatus FA, the filtered polymer melt is flowed to any suitable downstream device or site, one example being a die (not shown) from which polymeric sheets, tubes, or other profiles can be extruded. The flow of polymeric material occurs in an in-line flow direction.

As shown inFIGS.1-6, fluid filtration apparatus FA is provided that can generally comprise a housing generally designated H, a screen changer device, generally designated SCD and a controller, or control panel, CP. As show inFIGS.1and2, the housing H generally can include one or more enclosing structures such as one or more guard structures H1and H2, and a base B to which the screen changer device SCD can be secured. The controller CP can comprise one or more computers, programmable logic controllers, mini-computers, data processing devices, or the like, in a manner known in the art. The controller CP can be in communication with a comprehensive control system for the entire polymer processing line. The guard structures H1and H2can have safety switches S that are in communication with the control panel that can stop operation of the filtration apparatus FA when the safety switches are activated. Alternatively, in some embodiments, the components of the filtration apparatus FA can be in direct communication with and can be controlled by and/or through the control system for the entire polymer processing line.

Referring toFIGS.1-6, the screen changer device SCD can comprise a slide plate assembly10and a flow bore body30comprising of multiple parts. The slide plate assembly10can comprise a hydraulic cylinder12with an extension arm14that is secured to a slide plate20at one end. The slide plate assembly10can also comprise a cylinder mounting plate, or mounting plate,16to which the hydraulic cylinder12can be secured and tie rods18A,18B that position and hold the mounting plate16relative to the flow bore body30. The slide plate20can also comprise an elongate body22that can comprise a first section22A and a second section22B, a first screen housing bore24A can extend through the first section22A of the elongate body22and a second screen housing bore24B can extend through the second section22B of the elongate body22to hold screens.

In particular, each of the first and second screen housing bores24A,24B can hold a breaker plate26A and a filter element, or screen,26BB that is used to filter polymeric material that flows through the filtration apparatus FA when the first screen housing bore24A or second screen housing bore24B are aligned with a flow bore in the body30. The breaker plate26A acts as a support for the screen26B. The breaker plate26A has larger or wider diameter apertures therethrough than the porous material of the screen26B. The screen26B as used herein is generic and can include but is not limited to screen packs having a mesh configuration. Examples of different mesh configurations can include, but are not limited to, 20/80/20, 20/40/100/40/20, 50/80/150/80/50, or the like. The screens26B can be removed for cleaning and/or replacement as is required to maintain proper filtration of the polymeric material being processed. Thereby, the screens26B can be exchanged. Similarly, as needed, the breaker plates26A can also be removed from the first or second screen housing bores24A,24B to be cleaned if the breaker plates26A become dirty, clogged, or damaged. Thus, the breaker plates26A can be cleaned and placed back in the first and second screen housing bores24A,24B or can be replaced with new breaker plates26A. Thus, the breaker plates26A are also exchangeable as needed.

The hydraulic cylinder12can extend or retract the slide plate20to properly align the first screen housing bore24A or the second screen housing bore24B depending on which one is to be aligned with the flow bore within the flow bore body30. The extension arm14of the hydraulic cylinder12, the mounting plate16and the tie rods18A and18B all help control the amount of extension and retraction of the slide plate20to ensure proper alignment.

The flow bore body30of the screen changer device SCD can comprise a front face plate32A and a back face plate32B. The front face plate32A and the back face plate32B include respective flow bores FBFand FBBthat align with each other and the flow bores of upstream portions and downstream portions of the polymer processing line. The flow bore body30of the screen changer device SCD can also comprise a top spacer plate34A and a bottom spacer plate34B that are positioned between a top portion of the two face plates32A,32B and a bottom portion of the two face plates32A,32B to form a slide plate chamber45in which the slide plate20resides and can slide during screen changing operations to align one of the respective first and second screen housing bores24A,24B with screens26therein with the respective flow bores FBFand FBBof the front face plate32A and the back face plate32B. The front face plate32A and the back face plate32B and the top spacer plate34A and the bottom spacer plate34B can be held tightly together with sets of top screws36A and bottom screws36B.

The front face plate32A and the back face plate32B and top spacer plate34A and a bottom spacer plate34B are machined and/or milled to such tolerances that during normal processing operations of the filtration apparatus FA when one of the first and second screen housing bores24A,24B is aligned with the respective flow bores FBFand FBBof the front face plate32A and the back face plate32B and polymer is flowing therethrough, the slide plate20is so tightly held within the chamber that is not movable and provides no perceivable seams between the flow bore body30and the slide plate20into which molten polymer being processed can flow. With such tight tolerances, the slide plate20is provided space within the chamber for movement of the slide plate20for screen changing during screen changing operations by heating the top spacer plate34A and the bottom spacer plate34B to a high temperature which causes the top spacer plate34A and a bottom spacer plate34B to expand to temporarily widen the slide plate chamber45to allow the hydraulic cylinder12to move the slide plate20within the chamber formed by the front and back face plates32A,32B and the top and bottom spacer plates34A,34B.

The top spacer plate34A can have a heating element chamber, or channel,40A and the bottom spacer plate34B can have a heating element chamber, or channel,40B that can each house a heating element52(seeFIG.3) that can heat the top and bottom spacer plates34A,34B to a temperature that will cause the top and bottom spacer plates34A,34B to expand to temporarily widen the slide plate chamber45during screen changing operations. In some embodiments as shown, the heating element chambers40A,40B can extend along a length of the top and bottom spacer plates34A,34B transverse to the flow bore direction. The top spacer plate34A can also have a cooling element chamber, or channel,42A and the bottom spacer plate34B can have a cooling element chamber, or channel,42B that can each house a cooling element or permit circulation of a cooling fluid to regulate the temperature of the top and bottom spacer plates34A,34B and/or to cool the top and bottom spacer plates34A,34B when a heating element52has been used to create space within the slide plate chamber45of the flow bore body30to allow the slide plate20to be moved to a different position and the top and bottom spacer plates34A,34B are being cooled down to an operating temperature that permits the tightening of the chamber of the flow bore body30on the sides of the slide plate20. In an alternative embodiment, the heating element chambers, or channels,40A,40B can be configured to be connect to a heating fluid circulation system, such as for example, heat transfer fluid systems produced and sold by MOKON located in Buffalo, N.Y., to heat the top and bottom spacer plates34A,34B. Examples of heat transfer oil systems sold by MOKON can include HFT 500 Series, HTF 600 Series, the HTF HF-2 Series, and the HTF ST Series. Other manufacturers make similar heat transfer fluid systems that can be used in conjunction with the filtration apparatuses described herein. In such embodiments, the fluid pumped through the heating element chambers40A,40B can be used to heat and cool the top and bottom spacer plates34A,34B as needed to reach desired temperatures and to regulate the temperatures of the top and bottom spacer plates34A,34B so that a second cooling element chamber or channel may not be needed.

The top spacer plate34A can additionally have a temperature gauge chamber46A and the bottom spacer plate34B can have a temperature gauge chamber46B that can each house a temperature gauge, such as a thermometer, that can be in communication with the control panel CP to provide feedback on the temperature of the top and bottom spacer plates34A,34B. The controller CP can be in operable communication with the heating element52and/or the heat control fluid circulation system. In this manner, the controller CP can monitor and control the heating of the top and bottom spacer plates34A,34B.

Further, in some embodiments, the top and bottom spacer plates34A,34B can have screw bores35that can extend through the width of the top and bottom spacer plates34A,34B which can be transverse to the heating element chambers40A,40B. The screws36A,36B can be heated as well to facilitate the expansion of the top and bottom spacer plates34A,34B and the temporary widening of the slide plate chamber45. In particular, the screws36A,36B can be heated during screen changing operations to expand the screws36A,36B and temporarily relieve torque, or loosen the tightness of the screws36A,36B to help facilitate the expansion of the top and bottom spacer plates34A,34B and outward movement of the upper and lower portions of the front and back face plates32A,32B that are being pushed outward by the expanded top and bottom spacer plates34A,34B to temporarily widen the slide plate chamber45. For example, as shown inFIGS.5and6, the screws36A,36B can have a chamber therein, or a channel therethrough, for receiving a heating element that can heat the respective screws36A,36B to a desired temperature.

In some embodiments, the tolerances of the front and back face plates32A,32B and the top and bottom spacer plates34A,34B can be within about 0.0001 inches and about 0.0009 inches, for example, about 0.0005 inches so that the chamber size, particularly on the sides of the front and back face plates32A,32B create a seal with the slide plate20when the top and bottom spacer plates34A,34B are contracted. With such tolerances, the slide plate20is held tightly with little to no leakage of polymer between the front and back face plates32A,32B and the slide plate20during normal processing operations. Thereby, no additional seal is needed between the front and back face plates32A,32B and the slide plate20. When it is time to shift the slide plate20to change screens26during screen changing operations, the top and bottom spacer plates34A,34B can be heated up to a temperature that will cause them to expand enough to loosen the contact between the sides of the front and back face plates32A,32B and the slide plate20so that the hydraulic cylinder12can move the slide plate20to the different position by either extending or retracting the extension arm14. For example, the top and bottom spacer plates34A,34B can be heated to temperatures between about 500° F. to about 800° F., for instance, about 700° F. This heating can be done quickly and for just long enough for the slide plate20to be moved. So, the heat transfer to the front and back face plates32A,32B can be minimized and the front and back face plates32A,32B will not reach temperatures that will cause the polymer, such as rigid or semi-rigid PVC, to degrade or burn.

As shown inFIGS.3,5,7,7A,8and9, the front and back face plates32A,32B can be heated around the flow bores FBBand FBFtherein to regulate the temperature around the flow bores FBBand FBFin the front and back face plates32A,32B to facilitate the processing of fluid through the screen changer device SCD. The front and back face plates32A,32B can have heating fluid chambers50A,50B,50C,50D as shown inFIG.5that allow for the circulation of a heating fluid therethrough to heat and regulate the temperature of the front and back face plates32A,32B around the flow bores FBBand FBF. The temperature within the front and back face plates FBBand FBFcan be monitored and regulated around the flow bores therein. In particular, the front and back face plates32A,32B can include temperature monitoring chambers47A and47B that can hold thermometers or other temperature gauges that can be in communication with the controller CP to monitor the heating of the front and back face plates32A,32B. This monitoring can make sure that the front and back face plates32A,32B stay within operating temperature range, especially around the flow bores FBFand FBBto maintain the integrity and desire flow rate/viscosity of the polymer being processed. Each of the front and back face plates32A,32B and the top and bottom spacer plates34A,34B include screw bores37for receiving the set of top screws36A and the set of bottom screws36B. Some of these screw bores can be threaded and some can be configured to receive a head of a screw depending on the intended orientation of the screws. Further, in some embodiments, the front and back face plates32A,32B can include compartments31,33formed therein and covers38,39to house wiring and other components used to heat and/or cool the front and back face plates32A,32B and the top and bottom spacer plates34A,34B. The front and back face plates32A,32B can also comprise chambers or channels for heating/cooling elements or for heating fluid circulation systems.

The front and back face plates32A,32B, the slide plate, and the top and bottom spacer plates34A,34B can comprise a metal. For example, the front and back face plates32A,32B, the slide plate, and the top and bottom spacer plates34A,34B can comprise steel. The seal created between the steel on steel contact between the front and back face plates32A,32B and the slide plate20can prevent leakage enough to allow polymers, such as rigid PVC and semi-rigid PVC to be run through the filtration apparatus FA without causing the slide plate to freeze or seize overtime due to polymer leakage. At the same time, the top and bottom spacer plates34A,34B can be quickly heated during a screen change procedure to a temperature that allows the expansion of the top and bottom spacer plates34A,34B to push outward on the front and back face plates32A,32B to temporarily widen the slide plate chamber45and create enough space between the front and back face plates32A,32B and slide plate20to permit the slide plate20to be moved to a different position before cooling the top and bottom spacer plates34A,34B allowing them to contract to create the tight steel on steel contact seal between the front and back face plates32A,32B and the slide plate20at the new position of the slide plate20. The cooling can occur using one or more cooling elements or fluid cooling system as described above and/or by turning off the heating elements. In some embodiments, the space created by the heating of the top and bottom spacer plates34A,34B to allow the movement of the slide plate20can be between a few ten thousandth of inch to a few thousandth of an inch. In some embodiments, for example, the space can be about 0.0005 inches on each side of the slide plate20.

FIG.10shows single-sided acting forces F shown only for deflection clarity to demonstrate how much stress the screws36A,36B place on the front and back face plates32A, and32B and the spacer plated34A and34B. The deflections DFas shown inFIG.10are exaggerated to help communicate that problem of deflection within the front and back face plates32A, and32B. The screws36A,36B when fully tightened creates forces F on the portions of the faceplates32A and32B and the spacer plated34A and34B where the screws36A,36B entered and the heads for the screws36A,36B abut against the side of the faceplates32A and32B. Thus, a lower side portion of the front face plate32A and the corresponding side of the bottom spacer plate34B are placed under great forces and stress as shown in sections DS1and DS2inFIG.10where deflection can range from about 0.00015 to about 0.00030 as compared to the opposing lower portion of the back face plate32B and the corresponding side of the bottom spacer plate34B as shown in sections DS3inFIG.10where deflection can still be about 0. Similarly, an upper side portion of the back face plate32B and the corresponding side of the top spacer plate34A are placed under great forces and stress as shown in sections DS1and DS2inFIG.10as compared to the opposing upper portion of the front face plate32A and the corresponding side of the top spacer plate34A as shown in sections DS3inFIG.10where deflection can still be about 0. These stresses, if not compensated for, can cause a slight bowing of the front and back face plates32A,32B around the chamber and create scoring of the slide plate20when the slide plate20is moved between the sides of the front and back face plates32A,32B.

To help maintain the tightness between the metal on metal contact between the slide plate20and the front and back face plates32A,32B without creating bowing on the interior side of the front and back face plates32A,32B and the slide plate20at the flow bores FBFand FBBwhen the screws36A,36B are fully tightened and potential scoring of the slide plate20when the slide plate is moved, relief channels48can be formed on the interior sides of the front and back face plates32A,32B as shown inFIGS.5A,7,7A,8, and9to provide deflection at critical points between the front and back face plates32A,32B and the slide plate20. Thereby, the metal on metal contact between the front and back face plates32A,32B and the slide plate20can maintain a seal. In some embodiments, the screws36A,36B can be heated to help facilitate the outward movement of the front and back face plates32A,32B.

Thus, as disclosed herein, filtration apparatuses and screen changer devices for filtering polymeric material as well as spacer plates and face plates for the screen changer devices and related methods are provided. For example, a fluid filtration apparatus for processing fluid can be provided that comprises a screen changer device that can include a slide plate assembly and a flow bore body. The slide plate assembly can comprise a hydraulic cylinder with an extension arm that extendable and retractable and a slide plate secured to an end of the extension arm. The slide plate can have a first screen housing bore and a second screen housing bore for housing exchangeable screens for filtering of a fluid being processed. The flow bore body can comprise front and back face plates and top and bottom spacer plates. The front face plate can have a front flow bore and the back face plate can have a back flow bore that align with each other and can align with flow bores of upstream process equipment and downstream process equipment of the polymer processing line. The top spacer plate can be positioned between a top portion of the front and back face plates and the bottom spacer plate can be positioned between a bottom portion of the front and back face plates to form a slide plate chamber in which the slide plate slidably resides to align one of the respective first and second screen housing bores with screens therein with the respective flow bores of the front face plate and the back face plate. The top spacer plate and the bottom spacer plate can each comprise a heating element chamber for receiving a heating element. The heating elements when heated causes the top spacer plate and the bottom spacer plate to expand to create enough space within the slide plate chamber to permit the slide plate to be movable within the slide plate chamber and when the top spacer plate and the bottom spacer plate are cooled, the slide plate is tightly held in place within the slide plate chamber. Thus, the heating elements when heated causes the top spacer plate and the bottom spacer plate to expand to temporarily widen the slide plate chamber. The fluid filtration apparatus can also comprise a controller that can be in operable communication with the screen changer device that extends and retracts the extension arm of the hydraulic cylinder and a housing that encloses at least a portion of the screen changer device.

In some embodiments, the slide plate assembly of the screen changer device can further comprise a mounting plate to which the hydraulic cylinder can be secured and tie rods secured to the mounting plate and the top and bottom spacer plates so as to position the slide plate relative to the slide plate of the flow bore body. The mounting plate and the tie rods can aid in the control of the amount of extension and retraction of the slide plate to ensure proper alignment of the respective first and second screen housing bore in the slide plate with the front and back flow bores in the respective front and back face plates. As stated above, in some embodiments, the slide plate of the slide plate assembly of the screen changer device can comprise an elongate body that can include a first section and a second section with the first screen housing bore extending through the first section of the elongate body and the second screen housing bore extending through the second section of the elongate body. When the extension arm of the hydraulic cylinder is extended, the first screen housing bore of the slide plate with a screen housed therein is aligned with the front and back flow bores in the respective front and back face plates of the flow bore body and the second screen housing bore resides outside the flow bore body to permit the removal of a screen from the second screen housing bore for cleaning or exchange. When the extension arm of the hydraulic cylinder is retracted, the second screen housing bore of the slide plate with a screen housed therein is aligned with the front and back flow bores in the respective front and back face plates of the flow bore body and the first screen housing bore resides outside the flow bore body to permit the removal of a screen from the first screen housing bore for cleaning or exchange.

In some embodiments, the front face plate and the back face plate and the top spacer plate and the bottom spacer plate can be secured tightly together with sets of top screws and bottom screws. The top screws and the bottom screws have screw heating element chambers therein for receiving heating elements. Heating elements stored within the screw heating element chambers can be heated to facilitate the expansion of the top spacer plate and the bottom spacer plate to create enough space within the slide plate chamber to permit the slide plate to be movable within the slide plate chamber. In particular, the heating elements stored within the screw heating element chambers can be heated to heat the screws to relieve torque on the screws to facilitate the expansion of the top spacer plate and the bottom spacer plate to create space within the slide plate chamber to permit the slide plate to be movable within the slide plate chamber.

The front face plate and the back face plate and top spacer plate and a bottom spacer plate are at least one of machined or milled to such tolerances that, during normal operations of the filtration apparatus, when one of the first and second screen housing bores is aligned with the respective front and back flow bores of the front face plate and the back face plate and polymer is flowing therethrough, the slide plate is tightly held within the chamber so as to be not movable and provides no perceivable seams between the flow bore body and the slide plate into which molten polymer being processed can flow and no additional seal is needed between the front and back face plates and the slide plate. In such embodiments, the heating elements in the top and bottom spacer plates can be heated to heat the top and bottom spacer plates to expand the top and bottom spacer plates to create enough space within the slide plate chamber for the hydraulic cylinder to move the slide plate within the chamber without damaging the front and back face plates or the slide plate.

In some embodiments, the heating element chambers within the top and bottom spacer plates extend along a length of the top and bottom spacer plates transverse to the flow bore direction within the screen changer device.

In some embodiments, each of the top and bottom spacer plate further comprise a cooling element chamber. In some such embodiments, the cooling element chambers in the top and bottom spacer plates can house a cooling element to regulate the temperature of the top and bottom spacer plates. In some embodiments, the cooling element chambers in the top and bottom spacer plates can permit circulation of a cooling fluid to regulate the temperature of the top and bottom spacer plates. The cooling element chambers in the top and bottom spacer plates can be used to cool the top and bottom spacer plates down to an operating temperature that permits the tightening of the slide plate chamber of the flow bore body against the slide plate.

In some embodiments, the heating element chambers can be configured to be a part of a heating fluid circulation system to heat and cool the top and bottom spacer plates as needed to regulate the temperatures of the top and bottom spacer plates. In some embodiments, each of the top and bottom spacer plates can further comprise temperature gauge chambers for housing temperature gauges. During operation, the top and bottom spacer plates can be heated to temperatures between about 500° F. to about 800° F. The front and back face plates can comprise temperature monitoring chambers for holding temperature gauges. The front and back face plates can also comprise relief channels on interior sides of the front and back face plates to prevent or minimize separation between the front and back face plate and the slide plate due to the heating the top and bottom spacer plates.

In one related method, the fluid filtration apparatus can comprise a method of changing a screen within a screen changer device within a fluid processing apparatus. Such a method of changing a screen within a screen changer device within a fluid processing apparatus can comprise heating a top spacer plate that is positioned between a top portion of a front and back face plates of a screen changer device and a bottom spacer plate that is positioned between a bottom portion of the front and back face plates causing the top and bottom spacer plates to expand to create space within a slide plate chamber of the screen changer device that is formed by the top and bottom spacer plates and the front and back face plates. A slide plate can be slid within the slide plate chamber from a first position where a first screen housing bore within the slide plate in which a first filter screen resides is aligned with flow bores in the front and back face plates to a second position where a second screen housing bore within the slide plate in which a second filter screen resides is aligned with the flow bores in the front and back face plates. The method can also comprise cooling the top and bottom spacer plates such that the top and bottom spacer plates contract to decrease space within the slide plate chamber to tightly hold the slide plate between the front and back face plates preventing movement of the slide plate within the slide plate chamber. When the slide plate assembly is moved to the second position with the second screen housing bore within the slide plate aligned with the flow bores in the front and back face plates, the first screen housing bore of the slide plate resides outside the front and back face plate to permit access to the first filter screen within the first screen housing bore, Thereby, the first filter screen can be removed from the first screen housing bore of the slide plate and a clean filter screen can be placed in the first screen housing bore of the slide plate.

Similarly, in this method, the top and bottom spacer plates can be heated as above so that the slide plate can be slid within the slide plate chamber from the second position where the second screen housing bore within the slide plate in which the second filter screen resides is aligned with flow bores in the front and back face plates to the first position where the first screen housing bore within the slide plate in which the first filter screen resides is aligned with the flow bores in the front and back face plates. The top and bottom spacer plates can then be cooled such that the top and bottom spacer plates contract to decrease space within the slide plate chamber to tightly hold the slide plate between the front and back face plates preventing movement of the slide plate within the slide plate chamber. When the slide plate assembly is moved to the first position with the first screen housing bore within the slide plate aligned with the flow bores in the front and back face plates, the second screen housing bore of the slide plate can reside outside the front and back face plate to permit access to the second filter screen within the second screen housing bore. Thereby, the second filter screen can be removed from the second screen housing bore of the slide plate and a clean filter screen can be placed in the second screen housing bore of the slide plate.

Further, in the method, as described above, the heating elements can be heated that are stored within screw heating element chambers within sets of top screws and bottom screws that secure the front face plate and the back face plate and the top spacer plate and the bottom spacer plate together to facilitate the expansion of the top spacer plate and the bottom spacer plate to create enough space within the slide plate chamber to permit the slide plate to be movable within the slide plate chamber. In particular, the screws can be heated to relieve torque on the screws to facilitate the expansion of the top spacer plate and the bottom spacer plate to create enough space within the slide plate chamber to permit the slide plate to be movable within the slide plate chamber.

The heating the top and bottom spacer plates can be accomplished by heating a heating element within the top spacer plate and a heating element within the bottom spacer plate. In particular, the heating elements can reside in heating element chambers in the top and bottom spacer plates. In some embodiments, the heating circulation system can engage the heating element chambers to allow heating fluids to be run through the heating element chambers to heat and regulate the temperature of the top and bottom spacer plates. The temperature of the top and bottom spacer plates can be monitored, for example, by temperature gauges. Cooling element within the top spacer plate and a cooling element within the bottom spacer plate can be used to cool the top and bottom spacer plates. For example, the top and bottom spacer plates can each have a cooling element chamber therein for housing the respective cooling element. Further, the temperature of the top and bottom spacer plates can be regulated through the heating and cooling of the top and bottom spacer plates based on information provided by the monitoring of the temperature within the top and bottom spacer plates.

Similarly, the front and back face plates can be heated around the flow bores therein to regulate the temperature around the flow bores in the front and back face plates to facilitate the processing of fluid through the screen changer device. The temperature within the front and back face plates can be monitored and regulated around the flow bores therein.

These and other modifications and variations to the present subject matter may be practiced by those of ordinary skill in the art, without departing from the spirit and scope of the present subject matter, which is more particularly set forth herein above. In addition, it should be understood the aspects of the various embodiments may be interchanged both in whole or in part. Furthermore, those of ordinary skill in the art will appreciate that the foregoing description is by way of example only, and is not intended to limit the present subject matter outside the scope of the appended claims and their equivalents.