Abstract:
A gasket material for sealing between two members, The gasket material includes a flexible, woven skeletal member. Enclosing the skeletal member is a flexible, compressible resilient body member having a tacky outer surface, the tacky outer surface for engagement between the two members. In a preferred embodiment the flexible skeletal member is closer to a top surface of the resilient body then it is to a bottom surface of the resilient body. The resilient body may be comprised of urethane. The flexible skeletal member may be comprised of a metallic or a non-metallic material.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     Gasket material, more specifically, a gasket material comprising a resilient, pliable body having a skeletal mesh member embedded therein. 
     2. Background Information 
     A gasket is a sealing member for use between two mating surfaces to help prevent the movement of fluid or gas between the mating surfaces. Gaskets are often used on vehicles such as aircraft to prevent moisture from corroding the sealed off areas and the mating surfaces. For example, on the outside skin of an aircraft antenna are often mounted to assist in communications between the aircraft and a remote location. Such antennas often consist of a tabular mounting plate having an inner and outer surface, the inner surface mating to the outer skin of the aircraft and having an electrical connector projecting from the inner surface. The electrical connector is intended to fit partially into the interior of the aircraft through a small opening in the aircraft skin designed for such purpose. The electrical connector element will connect to the appropriate electrical circuit in the aircraft. On the outer surface of the mounting plate, and often incorporated with the mounting plate, is the antenna transceiving member for transmitting and/or receiving radio frequencies. 
     Traditionally, the antenna is removably mounted to the aircraft through typical threaded fasteners. Holes in the tabular mounting plate of the antenna support the threaded fasteners which pass into the aircraft&#39;s skin, typically threading into blind nuts mounted against the inside surface of the aircraft&#39;s skin. 
     Gaskets typically are provided for covering a portion of the “footprint” of the antenna against the outer surface of the aircraft. When the fasteners are tightened down, they compress the gasket typically with some defamation, between the aircraft&#39;s skin and the inner surface or face of the antenna mounting plate. This is done in an effort to prevent moisture from penetrating the gasket barrier. 
     However, prior art gaskets have a number of shortcomings which applicants novel gasket material overcomes. These shortcomings include allowing moisture to penetrate the area between the antenna and the aircraft&#39;s skin. Often, for example, a site of corrosion is the junction between the antenna inner surface and the electrical connective elements of the antenna. Moisture has been found to “pool” in this area, accelerating corrosion. Further shortcomings of the prior art gaskets include their moisture content or moisture absorption ability, which moisture may encourage the formation of corrosion, when the gasket is under pressure between the mating surfaces and, especially, where such gasket includes a metallic element. Further shortcomings of the prior art gaskets include their “non-selective retentivity.” This means that after the gasket has been installed and in use for a period of time, that upon an attempt to separate the antenna from the aircraft&#39;s skin, some portions of the gasket will non-selectively stick to portions of the aircraft&#39;s skin and other portions of the gasket will stick to the antenna (see FIG.  1 A.). The result, often, is the destruction of the gasket. 
     Applicants have invented a gasket with a novel combination of properties and qualities that effectively prevent moisture from passing the sealed area while maintaining selective retentivity. This allows the effective separation between the mating surfaces upon removal of the antenna. 
     Flexibility, resiliency, compressibility and pliability are other favorable properties which help affect a good seal between the mating surfaces. 
     All of these beneficial properties should have a useful life that is reasonable in view of operating conditions and aircraft maintenance schedules. The gasket should be inert, that is non-reactive with the work pieces (typically aluminum) as well as non-reactive to water, including salt water. 
     Not surprisingly, it has proven to be a challenge to develop a gasket with these properties that will survive repeated heat and pressure cycling (as the aircraft climbs and descends), structural flexing, and vibration while protecting the aircraft components and having a useful life. 
     While some of the prior art gaskets have provided some of the favorable properties set forth above, none have provided all of these properties in an aircraft gasket with a useful life. Such typical useful life would be a minimum of greater than one year under proper torque specifications. 
     Applicants, however, provide for all of the above properties in an aircraft gasket and gasket tape and a novel method of manufacturing the aircraft gasket and gasket tape. Gasket tape is gasket material that is rolled into tape rather than precut to the pattern of the mating surfaces. Applicants further provide for a method of using the preformed gasket with a liquid setable gel too, in some cases, help insure a waterproof seal. 
     Applicants have also found a novel method of preparing a gasket material. 
     Applicants provide a gasket with the following beneficial properties, heretofore unavailable in a preformed gasket or a gasket tape: elasticity (with memory), low water absorption, low water content, leak free (especially of silicon oil), dessication resistant, compressibility and surface tackiness (including selective retentivity). 
     The elasticity and pliability helps make an effective seal between the two mating surface as compression against such elasticity helps seal over mating surface irregularities and structural flexing or vibration of the two surfaces. The maintenance of this elasticity property is important since the surfaces undergo thermal expansion and contraction during repeated altitude and temperature changes which causes relative movement (flexing) between the mating surfaces. 
     Low water absorption and low water content is also a beneficial quality as it is typically water or moisture that the gasket is meant to keep out. 
     Nor should a gasket material itself be the source of oil, as such oil can mar the finish of the aircraft surface. This oil leaching has been a problem with prior art gaskets including those silicon-based gaskets. 
     An additional beneficial property of an effective gasket includes a resistence to drying out. Drying out of a gasket brings the problem of shrinkage and break-up, which destroys the integrity of the gasket/mating surface. 
     Tackiness has been found beneficial since there is also vibration and flexing of the mating surfaces. Tackiness and resiliency provide a better seal should there be a slight separation between the mating surfaces. 
     SUMMARY OF THE INVENTION 
     Applicant&#39;s novel gasket consists of two parts. The first part comprises a skeletal member—typically an open-weave mesh member and, more typically, an open-woven mesh made of a metallic material or a non-metallic fabric such as fiberglass. 
     The second part of applicant&#39;s novel gasket is a flexible resilient body member typically formed around and through the skeletal member so that the skeletal member is substantially encapsulated within the resilient body member and gives some structure and form to the gasket. 
     The gasket and gasket tape are usually tabular in shape and the skeletal member and resilient body share a tabular shape and plane. However, when viewed in cross-section, Applicants skeletal member is not centered between the two opposed tabular surfaces of the gasket (or gasket tape), but instead is closer to one surface than the other. It is believed that this property provides selective retentivity to the material. 
     The resilient body is typically comprised of a semi-solid gelatin polyurethane, typically between 40 and 150 (10 −1  mm) cone penetration and having a surface tackiness of between about 2 to 7 inch pounds and which tackiness allows some adhesion to a metal mating surface, but will release easily and leave no residue upon release. The resilient body will not undergo dessication, does not leak oil, but retains memory and does not absorb more than about one percent by weight water. Other resilient, pliable bodies may be used, such as silicon or polyolefinic block copolymers or other materials with similar cone penetration and tackiness. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIGS. 1 and 1A illustrate prior art gaskets and their use. 
     FIG. 2 is a cross-sectional view of Applicants preformed gasket. 
     FIG. 3 is a side elevational view of Applicants preformed gasket in use. 
     FIGS. 4,  5  and  6  are elevational views of various “footprints” of Applicants preformed gaskets. 
     FIG. 7 is a cross-sectional elevational view of Applicants gasket tape. 
     FIG. 8 is a perspective view of a step in the manufacture of Applicants preformed gaskets. 
     FIG. 9 is a perspective view of another step in the process of manufacturing Applicants preformed gaskets. 
     FIG. 9A is a side elevational view of a table for use in the method of manufacturing Applicants gasket material and illustrating Applicants&#39; gasket material on the upper surface thereof. 
     FIG. 10 is a perspective view of a manufacturing step in preparing Applicants&#39; gasket material. 
     FIG. 11 is a perspective view of a step in the manufacturing of Applicants&#39; preformed gaskets. 
     FIG. 12 is a side elevational view of a step undertaken in preparation for manufacturing Applicants gasket material. 
     FIG. 13 is a side elevational view of a table for use in the manufacture of Applicants gasket tape illustrating the stretching and clamping of a woven, non-metallic fiberglass member against the upper surface of the table, the table upper surface having been covered with a release film. 
     FIG. 14 is a perspective view of the cutting of gasket tape stock into tape. 
     FIGS. 15,  15 A and  15 B illustrate a method of using Applicants preformed gasket with a liquid, curable mix with a preformed gasket to provide an effective gasket seal between an aircraft skin and an aircraft antenna. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIGS. 1 and 1A illustrate a prior art gasket. In FIG. 1 the prior art gasket is seen to contain a woven, typically mesh member within a gel body. However, the mesh member is located in a central area of the gasket body between the two other outer faces of the gasket, This is to be compared to Applicant&#39;s preformed gasket  10  as illustrated in FIG.  2 . Applicant&#39;s preformed gasket  10  has a metallic skeletal member  12  (or non-metallic skeletal member  12 A, see FIG. 14) wherein the skeletal member lays close to or adjacent one of the two outer surfaces of the gasket. One beneficial result of this placement is that Applicant&#39;s gasket has selective tackiness or retentivity, unlike prior art gaskets. Without such selective retentivity or tackiness, when prior art gaskets undergo tension during the release of the mating surfaces as illustrated in FIG. 1A (Prior Art) one face of the gasket often sticks to one mating surface and the other face of the gasket to a second mating surface. Such a result may be damaging to the gasket, preventing its reusability. 
     As seen in FIG. 2, Applicant&#39;s preformed gasket or gasket tape (FIG. 7) includes a skeletal member which may be metallic  12  or nonmetallic  12 A. A typically woven skeletal member is, more typically, a woven aluminum mesh of thickness typically between 0.11 to 0.25 mil. Non-metallic mesh  12 A (see FIGS. 13 and 14) may be woven fiberglass, for example, as when used in Applicant&#39;s gasket tape  16  typically between 7 and 20 mil. Sources of 1010 aluminum wire mesh are Estey wire and woven fiberglass is available from Teague Lumber as part number 337,600. 
     Substantially encapsulating skeletal member  12  or  12 A is a resilient body  14  typically a semisolid gel and more typically formed from a curable polyurethane mix. The resilient body includes a first surface  14 A and an opposed second surface  14 B, the two surfaces with parallel planes. A typical thickness of Applicant&#39;s preformed gasket  10  is 0.032 inches to 0.050 inches before compression. A typical thickness of Applicants gasket tape is between 0.032 and 0.060 inches before compression. The preformed gasket and tape share the same resilient body and both have a sticky or tacky surface typically in the range of 2 to 7 inch pounds. 
     FIG. 3 illustrates Applicant&#39;s gasket as it is used to mount between two mating surfaces, here aircraft skin As and aircraft antenna Aa, with preformed gasket  10  cut to dimensions dictated by the specifications of the antenna. It is placed between the aircraft skin and antenna and fasteners are tightened down typically to between about 15 and 35 inch pounds, to compress and slightly deform (squish out along the gasket edges) the gasket. 
     FIGS. 4,  5 , and  6  illustrate three “footprints” available for Applicants preformed gasket. 
     EXAMPLE 1 
     Applicant provides in example 1 a preformed gasket  10  with a footprint similar to FIG. 4 with an inner diameter about 5 inches and an outer diameter of 7 inches. The gasket has a resilient body of about 40 mil thickness comprised of polyurethane from a curable mix available from KBS Chemical of Fort Worth, Tex. as part numbers P-1011 (polyol) and U-1010 (urethane). Aluminum mesh of about 22 mil thickness is used. The preformed gasket was installed on a commercial jet airliner (Boeing 737) between the aircraft skin and the aircraft antenna to between 15 and 35 inch pounds pressure. The resulting compression allowed the wire mesh to ground the antenna to the skin, with the making surfaces about 20 mil distance apart. Upon removal, after 7 months of service, there was observed clean separation of the antenna from the gasket and the gasket maintained adhesion to the aircraft skin, expanding to about 40-90% of its original thickness and shape. The gasket did not dry out, and maintained its structural integrity and other chemical and physical properties, providing an effective seal. 
     EXAMPLE 2 
     A second gasket, similar in dimensions and structure to that set forth in Example 1, was joined between two mating surfaces under conditions similar to Example 1 and underwent 1,554 hours of salt fog testing per ASTM B 117. This gasket had a central cutout area in which a high tac, self leveling, green polyurethane sealant (Part No. U-1020 and P-1021 from KBS) was injected. The gasket was subject to a specified torque of 15 and 35 inch pounds. Upon release of the two mating surfaces the gasket was seen to maintain its integrity and to release clean from one mating surface of the two mating surfaces. It was seen to retain its resiliency and memory, as did the gasket in Example 1 above making an effective environmental seal. 
     FIG. 7 illustrates the use of Applicant&#39;s unique gasket material in tape form  16 , rolled up and available to be cut to length for placing between a pair of mating surfaces or as a self sealing tape. Applicant&#39;s tape  16  uses, typically, the same polyurethane body as preformed gasket  10  which has surface tackiness and has a mesh,  12 A, typically woven fiberglass, that is closer to one of the two tape other surfaces then to the other. This is believed to result in Applicants unique selective retentivity. 
     FIGS. 8,  9 ,  10  and  11  illustrate a method of producing Applicant&#39;s precut gasket  10 . 
     The first step is the flattening step. The purpose of this step is to flatten out a skeletal member  12 . The way in which this is done, if the skeletal member is metallic wire mesh, is to place the wire mesh  12  between two flat weighed members  20 A and  20 B and then placing the weighed members with the wire mesh between them in an oven  22 . The wire mesh is typically 18 inches by 24 inches and the weighed members are typically ¼″ stainless steel plates. The mesh and weighed member are typically laid flat in an oven  22  and heated 60 degrees F. for about 30 minutes. This anneals the metallic wire mesh and keeps it flat. The metal plates and the wire mesh are then removed from the oven and allowed to cool. Following cooling the weighed plates are removed and the wire mesh is ready for placement onto flat table  24 . 
     At this point it is germane to examine the nature of flat table  24  in more detail. With reference to FIG. 9A, table  24  has legs and a table top. The table top typically includes a flat transparent glass member  24 A with a flat upper surface. It also includes beneath the glass member  24 A longitudinal aligned flourescent lights  24 B. Before placement of wire mesh  12  onto the glass table top a release sheet, such as an FEP sheet (fluorinated ethylene propylene) film is applied to the table top. The FEP film is inert and will not stick to the polyurethane mix or the cured mix and will allow a clean removal of the cured polyurethane mix, which comprises the resilient body, from the table top. It is noted with reference to FIG. 12 the FEP film is typically applied to the flat glass table top  24 A from a roll, after Windex® an ammonia based cleaner  38  is applied to the surface of a table top and a squeegee  40  is used to squeeze out any air bubbles. This is done to insure a flat, bubble free surface for gasket formation. Thus, it is seen with reference to FIGS. 9A and 12 that table top  24 A has been prepared prior to the placement of the flattened wire mesh on top thereof, with an FEP or otherwise suitable release film which will lay flat to the table top, be inert to the cure mix and allow the gasket material to release therefrom. 
     The next step in the manufacture of the preformed gasket, may be called the “mixing and pouring” step and is best illustrated with reference to FIG.  9 . In FIG. 9 it is seen that a mix applicator  28  containing a curable mix of resilient body such as a mix of polyol and urethane available from KBS Chemical as set forth above, is applied to the mesh through the applicator. The prior art applicator stores the liquid mix typically as a resin (here urethane) and hardener (here polyol) in the body thereof, but injection through the nozzle thereof allows the two compositions to mix. Thus, in the process of pouring or applying the resilient body liquid mix, the two components are typically combined. This application and pouring step is typically done at room temperature. Moreover, it is noted that the resilient body liquid mix is self leveling. This step may also be done as two separate steps. First, one could separately mix the two components of the curable mix and, before it begins to set, apply it by pouring or any other suitable manner, onto the skeletal member. 
     With a minimum practice and experience the proper amount of liquid mix for the mesh may be determined. That is, sufficient liquid mix should be applied to the mesh for it to sufficiently cover the mesh such that the resilient body contains the wire mesh closer one surface than the other (see FIG.  2 ). For example, it been determined that using a 10½ inch by 17 inch 22 mil aluminum wire mesh such as set forth above, one applies about 160 milliliters of mix, typically, in the crisscross or zig zag pattern as illustrated in FIG.  9 . This will typically result in a gasket of about 40 mil thickness. 
     The next step in preparing Applicant&#39;s preformed gasket is to allow the liquid mix to cure. Typical time to curing is about 4 hours at room temperature. Upon curing a second FEP layer here  30 A (see FIG. 10) is applied to the top surface of the gasket stock  10 A as seen in FIG.  10 . This second layer of FEP material will help protect the gasket stock in handling and also will release easily from the surface therefrom. 
     Further in FIG. 11 it is seen that gasket stock  10 A may be cut with a die stamp machine  34  in ways known in the trade to form precut gaskets  10  to any number of suitable configurations (see for example FIGS. 4,  5  and  6 ). 
     FIG. 13 illustrates a manner for making Applicant&#39;s gasket tape  16 . This involves the step utilizing a table such as is illustrated in FIG.  9 A and stretching a non-metallic skeletal member  12 A from a roll or other stock of such material under tension atop the FEP layered table. Some tension and clamping is necessary to insure that the mesh  1   2 A is maintained flat against the FEP bottom layer  30 B. 
     The mixing and pouring step is similar to that illustrated in FIG. 9, with the same resilient body liquid mix as used in the preformed gasket  10 , coating all of the skeletal member to a thickness sufficient to place the skeletal member closer to one surface of the gasket tape than the other. 
     Following a period of curing the resulting gasket tape stock as illustrated in FIG. 14 may be cut longitudinally, covered with a top layer of FEP and rolled into a roll resulting in the gasket tape  16  illustrated in FIG.  7 . 
     This tape may be then used in lining aluminum structural members of the frame of aircraft such as those in cargo bays and also on aluminum mating surface beneath lavatories and galleys, where moisture may be a problem. This will help prevent access of moisture to the structural member. It is noted that use of Applicant&#39;s tape or gaskets will be self sealing around fasteners hole. This occurs when there is some defamation of the tape or gaskets at their edges under compression between the two joined mating surfaces. 
     In summary, it may be seen that Applicant&#39;s unique method of manufacturing either the tape or the prevent gasket includes the step of flattening the skeletal member against a flat surface, typically a table top and more typically table top against which a flat release film such as an FEP film has been placed thereon. It is seen that a curable liquid mix is combined and applied in liquid form, to cover the skeletal member to a depth sufficient to insure that the skeletal member is closer to the bottom surface of the resulting stock then to the upper surface. It is further seen that the resilient body liquid mix is typically self leveling and will cure at room temperature. The resulting stock may be then precut to a desire shape or cut to a preselected width and rolled up in a form of gasket tape. It is further seen that the gasket tape, as illustrated in FIG. 7 is provided with a first protected film  18 A and a second protective film  18 B, typically FEP and that after by cutting, the precut gaskets are typically covered top and bottom with the same protective FEP film. 
     FIG. 15 shows Applicants preformed gasket  10  ready for installation between two mating surfaces As and Aa. FIG. 15A illustrates the use of non-preformed pliable sealant mix  13 , typically a resin and a hardner, more typically a polyurethane curable mix. Mix  13  will set in place, and may fill any central cut-out areas  13 A in gasket  10 . This will often protect against the trapping of moisture in such area. Note that this curable mix should have the beneficial properties of the resilient body of Applicants preformed gasket  10 . Such curable mixes are available from KBS Chemical of Fort Worth as U-1020 and P-1021. 
     Although the invention has been described with reference to specific embodiments, this description is not meant to be construed in a limited sense. Various modifications of the disclosed embodiments, as well as alternative embodiments of the inventions will become apparent to persons skilled in the art upon the reference to the description of the invention. It is, therefore, contemplated that the appended claims will cover such modifications that fall within the scope of the invention.