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  Mems filter moduleUSPTO Application #: 20070199877Title: Mems filter module Abstract: Various MEMS filter elements or modules are disclosed. One such MEMS filter module (34) includes a first film (70) and a second film (46) that are spaced and interconnected by a plurality of supports (78). A plurality of first flow ports (74) extend through the first film (70), and a plurality of second flow ports (50) extend through the second film (46). A plurality of annular filter walls (54) extend from the second film (46) toward the first film (70), and are separated therefrom by a filter trap gap (58). A filter trap chamber (62) is disposed on each side of each filter trap gap (58). Therefore, fluid will flow into one filter trap chamber (62), through a filter trap gap (58), and into another filter trap chamber (62), whether the flow is introduced into the filter module (34) through the first flow ports (74) or the second flow ports (50). (end of abstract) Agent: David W. Highet, Vp And ChiefIPCounsel Becton, Dickinson And Company - Franklin Lakes, NJ, US Inventors: M. STEVEN RODGERS, JEFFREY J. SNIEGOWSKI, PAUL J. MCWHORTER USPTO Applicaton #: 20070199877 - Class: 210321600 (USPTO) Related Patent Categories: Liquid Purification Or Separation, Casing Divided By Membrane Into Sections Having Inlet(s) And/or Outlet(s) The Patent Description & Claims data below is from USPTO Patent Application 20070199877. Brief Patent Description - Full Patent Description - Patent Application Claims
CROSS REFERENCE TO RELATED APPLICATIONS [0001] This patent application is a continuation of, and claims priority under 35 U.S.C. .sctn. 120 to, U.S. patent application Ser. No. 10/911,424, that is entitled "MEMS FILTER MODULE, and that was filed on Aug. 4, 2004, and further claims priority under 35 U.S.C. .sctn.119 to U.S. Provisional Patent Application Ser. No. 60/547,252, that is entitled "MEMS FILTER MODULE," and that was filed on Feb. 24, 2004. The entire disclosure of each of the above-noted patent applications is incorporated by reference in their entirety herein. FIELD OF THE INVENTION [0002] The present invention generally relates to field of filters and, more particularly, to a filter module that is microfabricated using multiple films disposed in spaced relation, where a flow is directed into the module before being directed through a filter trap that is defined by a substantially constant, fixed spacing between one of the films and a filter wall that extends from another of the films. BACKGROUND OF THE INVENTION [0003] Filters are used in a large number of applications. The filtering media used by a filter may be in the form of a porous material or combination of porous materials. Both the pore size and the distribution of pores may of course have an effect on the filtering capabilities of the filtering media. For instance, if the filtering media is produced in a manner where adjacent pores could overlap, a larger pore may be formed. Although this may be acceptable for certain applications, it may not be for others (e.g., filtering biological fluids). BRIEF SUMMARY OF THE INVENTION [0004] The present invention generally relates to a MEMS filter module that may be inserted into a flow of any appropriate type and in any appropriate manner (e.g., by disposing the MEMS filter module into a housing through which a flow is directed). Generally, the MEMS filter modules described herein are microfabricated. There are a number of microfabrication technologies that are commonly characterized as "micromachining," including without limitation LIGA (Lithographie, Galvonoformung, Abformung), SLIGA (sacrificial LIGA), bulk micromachining, surface micromachining, micro electrodischarge machining (EDM), laser micromachining, 3-D stereolithography, and other techniques. Hereafter, the term "MEMS filter module" or the like means any such filtering device that is fabricated using a technology that allows realization of a feature size of about 10 microns or less. [0005] One filter module in accordance with the present invention generally includes a first plate or film having a plurality of first flow ports that extend through its entire vertical extent or thickness, as well as a second plate or film that is spaced (e.g., vertically, such as when the filter module is in a first orientation) from this first film and that has a plurality of second flow ports that extend through its entire vertical extent or thickness. A plurality of filter walls are spaced on and extend from the second film in the direction of the first film. A gap between each filter wall and the first film defines a filter trap, such that there are then a plurality of filter traps. A first annular seal extends between the first and second films such that the first film, the second film, and the first annular seal collectively define an enclosed space. The region bounded by this first annular seal may be characterized as a filtering region. All of the filter walls, filter traps, first flow ports, and second flow ports are located in this filtering region. A plurality of posts or other supports extend between and interconnect the first and second films in the filtering region as well. [0006] A first aspect is directed to the above-noted type of MEMS filter module, where each of the filter walls have an annular extent in a plan view of the surface of the second film from which the plurality of filter walls extend. "Annular" in relation to the first aspect means that that each filter wall is defined by a closed perimeter, and does not limit the filter wall to a "circular" configuration in the noted plan view. A second aspect is directed to the above-noted type of MEMS filter module, where the number of supports in the filtering region is no less than the number of filter walls. Stated another way, there are at least as many supports in the filtering region as there are filter walls. A third aspect is directed to the above-noted type of MEMS filter module, where there are at least two first flow ports (the first film) and at least two second flow ports (the second film) associated with each filter trap. Therefore, any "plugging" of a particular first flow port or a second flow port should not totally disable its corresponding filter trap. [0007] Various refinements exist of the features noted in relation to the MEMS filter module associated with any of the first through the third aspects of the present invention. Further features may also be incorporated in the MEMS filter module associated with any of the first through the third aspects of the present invention as well. These refinements and additional features may exist individually or in any combination. Initially, the above-noted first, second, and third aspects may be used individually or in any combination. The MEMS filter module may be of any appropriate configuration, may be adapted for use in any appropriate filter housing or structure for receiving the same, may be used to filter any appropriate fluid, may be used to filter any appropriate flow, and may be used for any appropriate application. Although the MEMS filter module will typically be separately fabricated from the filter housing and separately mounted thereto in any appropriate manner, the present invention is not limited to such a configuration. [0008] Both the first film and the second film of the MEMS filter module associated with any of the first through the third aspects may have a maximum thickness of about 10 microns, and more typically within the range of about 1 micron to about 3 microns. Any appropriate material may be used for the first and second films. Although any appropriate microfabrication technique may be used in relation to this MEMS filter module, surface micromachining is a preferred approach, using materials such as polysilicon, silicon carbide, silicon nitride, polysilicon germanium, and tungsten for the first and second films, as well as for the filter wall. Typically the first and second films and the filter wall(s) will all be fabricated from the same material. The MEMS filter module also will typically be separated from any substrate that is used in the fabrication of the MEMS filter module prior to using the same in a filtering application (e.g., prior to disposing the same in the relevant filter housing or other structure for receiving the MEMS filter module). [0009] The first and second films used by the MEMS filter module of any of the first through the third aspects may define its upper and lower boundaries or opposing extremes for the MEMS filter module. The first and/or second films each could also be an "intermediate" film in the MEMS filter module. One embodiment has a lower film that is vertically spaced from the first film on the opposite side thereof in relation to the second film. That is, the first film is located at an intermediate elevation between the second film and the lower film. This lower film may include a plurality of flow ports extending therethrough as well. [0010] The filter walls used by the MEMS module of any of the first through the third aspects may be of an annular configuration or have a closed perimeter. Representative annular configurations for the filter walls include without limitation circular, square, and rectangular. In the case where the filter walls are annular, the corresponding filter trap will thereby also be annular. This may be of benefit for maintaining a desired flow rate through the MEMS filter module. Filter wall configurations other than annular may be used in relation to the above-noted second and third aspects as well. In one embodiment, each filter wall extends from the second film and terminates prior to reaching the surface of the first film that faces the surface of the second film from which the filter walls extend. In this case, each filter trap gap is defined by a distal end of a filter wall and the surface of the first film that faces the surface of the second film from which the filter walls extend. In another embodiment, an area encompassed by projecting each of the filter walls onto the first film does not encompass any of the first flow ports (e.g., each of the first flow ports are offset from each of the filter walls). [0011] The filter traps associated with the MEMS filter module of any of the first through the third aspects are each defined by a space between the first film and each of the various filter walls that extend from the second film. Preferably the filter traps are defined by the space between the distal end of each of the filter walls and the first film. That is, in this particular instance the filter walls do not extend all the way to the first film. In one embodiment, the height of this gap is about 0.3 microns. Any appropriate gap size may be utilized. [0012] The "density" of the supports that interconnect the first and second films throughout the filtering region may be selected to provide a desired degree of rigidity in relation to the anticipated flow rate(s) through the MEMS filter module of any of the first through the third aspects, may be selected to precisely maintain the magnitude of each filter trap throughout the filtering region for the anticipated flow rate(s) through the MEMS filter module of any of the first through the third aspects, or both. The second aspect again provides that there is at least one such support in the filtering region for each filter wall. In one embodiment, the maximum spacing between adjacent pairs of supports in the filtering region is no more than 100 microns, and may be on the order of 10 microns to about 20 microns. [0013] Multiple filter trap chambers may be associated with each filter trap of the MEMS filter module of any of the first through the third aspects. Each such filter trap chamber may be defined by the space between the first and second films. A first filter trap chamber may be the space "bounded" by each annular filter wall, and a second filter trap chamber may be the space between the various annular filter walls. The volume of each first filter trap chamber and the volume of the second filter trap chamber may be larger than the volume of any first flow port or any second flow port, although such need not be the case. In any case, the flow path through the MEMS filter module will either be into a first filter trap chamber, through the associated filter trap, and then into the second filter trap chamber, or the reverse. [0014] More than one annular seal may be provided between the first and second films in the case of the MEMS filter module of any of the first through the third aspects. For instance, a second annular seal may be spaced outwardly from the first annular seal, and may extend between and interconnect the first and second films as well. A third annular seal may be spaced outwardly from the second annular seal, and may extend between and interconnect the first and second films as well. Using multiple annular seals reduces the potential for undesirable leakage out of the filtering region. Stated another way, multiple annular seals increase the likelihood that all flow through the MEMS filter module will be directed through the various filter traps. In one embodiment, the width of a perimeter region having at least one annular seal is at least about 3 microns to about 4 microns, and may be on the order of about 20 microns to about 25 microns. [0015] A fourth aspect of the present invention is generally directed to a MEMS filter module having a first film having a plurality of first flow ports. A first chamber is fluidly connected with at least one of the first flow ports. A second film is spaced (e.g., vertically, when the MEMS filter module is disposed in a first orientation) from the first film and includes a plurality of second flow parts, and a second chamber is fluidly connected with at least one of the second flow parts. A first filter wall extends from the second film in the direction of the first film, and a first filter trap is defined in part by this first filter wall. The first and second chambers are fluidly connected by the filter trap gap. [0016] Various refinements exist of the features noted in relation to the MEMS filter module of the fourth aspect. Further features may also be incorporated into the MEMS filter module of the fourth aspect as well. These refinements and additional features may exist individually or in any combination. Initially the various features discussed above in relation to the first through the third aspects may be used by this fourth aspect, individually or in any combination. [0017] The first and second films may define the extremes of the MEMS filter in the case of the fourth aspect. One or both of the first and second films also may be disposed at an intermediate location or elevation within the MEMS filter module. In one embodiment, the filter trap gap is defined between the first filter wall and the first film. In another embodiment, at least one intermediate film section is disposed at an intermediate location or elevation between the first and second films and is interconnected with each by an appropriate support. Here the filter trap gap is defined between the first filter wall and the intermediate film section. In the case where a plurality of filter walls are utilized, there will be a corresponding number of intermediate film sections. An annular gap may exist around the perimeter of each such intermediate film section to fluidly communicate with the lower flow ports in the lower film. [0018] A fifth aspect of the present invention is directed to a method for fabricating a MEMS filter module. A first film is formed in overlying relation to a substrate. A first flow aperture is formed down through the entire vertical extent of the first film. A first sacrificial film is formed directly on the upper surface of the first film and will typically fill the first flow port aperture. A filter wall aperture is formed down through the entire vertical extent of the first sacrificial film, and thereby exposes a corresponding portion of the first film. Additional sacrificial material is thereafter deposited at least on the portion of the first film that is exposed by the filter wall aperture (i.e., on the "bottom" of the filter wall aperture, that is defined by the first film), and typically on the entire upper surface of the first sacrificial film. This subsequent deposition of sacrificial material may still be viewed as being part of the first sacrificial film. In any case, a second film is formed on the first sacrificial film and extends within the filter wall aperture to define a filter wall that extends toward, but not to (because of the sacrificial material that was previously deposited in the filter wall aperture), the first film. A second flow port aperture is formed down through the entire vertical extent of the second film. Once the first sacrificial layer is removed, the gap between the filter wall and the first film defines a filter trap. [0019] Various refinements exist of the features noted in relation to the fifth aspect of the present invention. Further features may also be incorporated in the fifth aspect of the present invention as well. These refinements and additional features may exist individually or in any combination. One benefit of this fifth aspect is the accuracy with which the sacrificial material may be deposited in the filter wall aperture, more specifically the thickness of this sacrificial material. As such, the size of the filter trap gap(s) may be precisely controlled. In one embodiment, the thickness of the sacrificial material deposited in the filter wall aperture varies by no more than about 2% from the target thickness. [0020] Although any fabrication technique may be used in relation to the fifth aspect, surface micromachining is preferred. Typically the first film will be separated from the substrate by an intermediate sacrificial layer. This would allow the MEMS filter module to be separated from the substrate after the MEMS filter module is released (e.g., by etching away sacrificial material). For instance, the MEMS filter module may remain supported above the substrate after any such release by one or more structural interconnections. Any such structural interconnections may be disabled (electrically/thermally and/or mechanically fractured), at which time the MEMS filter module may drop onto the underlying substrate (or any film(s) formed directly on the substrate). Preferably, one or more structures are formed on the substrate about the MEMS filter module to thereafter limit lateral movement of the MEMS filter module relative to the substrate until it is retrieved from the substrate. Another option would be to fabricate the MEMS filter module on a layer of a sacrificial material and not structurally interconnect the MEMS filter module with the underlying substrate. In this case, the removal of the sacrificial material will separate the MEMS filter module from the substrate. Continue reading... Full patent description for Mems filter module Brief Patent Description - Full Patent Description - Patent Application Claims Click on the above for other options relating to this Mems filter module patent application. ###  How KEYWORD MONITOR works... a FREE service from FreshPatents1. Sign up (takes 30 seconds). 2. Fill in the keywords to be monitored. 3. Each week you receive an email with patent applications related to your keywords. Start now! - Receive info on patent apps like Mems filter module or other areas of interest. ### Previous Patent Application: Fluid filtration system Next Patent Application: Pressure vessels for holding cylindrical filtration cartridges Industry Class: Liquid purification or separation ### FreshPatents.com Support Thank you for viewing the Mems filter module patent info. 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