Fastening devices typically include two flexible elongated components having teeth (i.e zippers) which are forced to interlock and separate by moving a slide along the components. Although such fastening devices have long been used to close and open various articles, such as clothing and bags, such devices suffer from the allowance of liquids and gases within the fastener, and are therefore not useful for conditions in which a wind-proof, gas-tight and/or waterproof article is desirable.
In response to the short comings of the above described devices, fastening devices having mating surface with rails that interlock to form fluid tight closures have been developed. In some constructions (such as jackets), these fastening devices are generally inserted into a bottom stop to hold the interlocked rails in place and prevent them from sliding upon each other during use. Although, these devices are highly useful in applications which require protection from wind and water, the devices may experience pull-out during use. That is, the rails may disengage from the bottom stop or slide past each other when a force parallel to the axis of the rails is applied.
In order to prevent pull-out of the rails, the opening in the bottom stop has been previously made smaller to facilitate a snugger fit of the rail into the bottom stop. This, however, may make it difficult to insert the rail into the bottom stop in the first place.
Thus, there remains a need for a fastening device that is waterproof and that is constructed in a manner that decreases the likelihood of pull out while maintaining ease of use of the fastening device.
A waterproof fastening device having interlocking mating surfaces is described. The fastening device includes a first fastening member (10) having two opposing ends (20). The first fastening device also includes a first mating surface (30) having a plurality of rails (40) having channels (50) there between, wherein at least one of the plurality of rails comprises an opening (60).
The waterproof fastening device also includes a second fastening member. The second fastening member (70) has two opposing ends (20) and further has a second mating surface (80) having a plurality of rails (40) with channels (50) there between. The second mating surface (80) is adapted for operatively engaging the first mating surface (30) to facilitate the formation of a waterproof seal. Further, at least one of the channels (50) has a projection (110) which is adapted to engage the opening (60) in the plurality of rails when the first mating surface (30) and the second mating surfaces (80) are operatively engaged.
The waterproof fastening device also includes a slider (90) engageable and movable along the first and said second mating surfaces. In this regard, the slider is adapted for forming and maintaining a waterproof seal between said first and said second mating surfaces.
The waterproof fastening device may also include a stop block (100) fixedly connected to one end of the two opposing ends of the first fastening member or the second fastening member. The stop block is adapted to house one end of the first fastening member and the second fastening member when the first mating surface and the second mating surface are operatively engaged.
In an embodiment of the invention, the projection is positioned closer to the end having a stop block fixedly connected thereto than to said opposing end. Additionally, the projection desirably possesses the same shape as the opening or openings. Desirably, the opening is the shape of a circle, trapezoid, triangle, square, rhombus, rectangle, or the like. Alternatively, the opening is a series of repeating geometries and/or repeating alternating geometries.
Another aspect of the invention addresses a waterproof fastening device having a first fastening member (10) having two opposing ends (20). The first fastening device also includes a first mating surface (30) having a plurality of rails (40) having channels (50) there between, wherein at least one of the plurality of rails comprises multiple openings (60).
The waterproof fastening device also includes a second fastening member. The second fastening member (70) has two opposing ends (20) and further has a second mating surface (80) having a plurality of rails (40) with channels (50) there between. The second mating surface (80) is adapted for operatively engaging the first mating surface (30) to facilitate the formation of a waterproof seal. Further, at least one of the channels (50) has multiple projections (110) which is adapted to engage the multiple opening (60) in the plurality of rails when the first mating surface (30) and the second mating surfaces (80) are operatively engaged.
Yet another aspect of the invention addresses a waterproof fastening device having a first fastening member (10) having two opposing ends (20). The first fastening device also includes a first mating surface (30) having a plurality of rails (40) having channels (50) there between.
The waterproof fastening device also includes a second fastening member. The second fastening member (70) has two opposing ends (20) and further has a second mating surface (80) having a plurality of rails (40) with channels (50) there between. The second mating surface (80) is adapted for operatively engaging the first mating surface (30) to facilitate the formation of a waterproof seal.
The fastening device also includes at least one interlocking protuberance positioned in communication with the mating surface of the first fastening member and at least one interlocking protuberance 130 in communication with the mating surface of the second fastening member wherein the at least one interlocking protuberance positioned in communication with the mating surface of the first fastening member and the at least one interlocking protuberance in communication with the mating surface of the second fastening member are adapted to interlock with each other when said first mating surface and said second mating surface are operatively engaged.
Yet another aspect of the invention addresses a waterproof fastening device having a first fastening member having two opposing ends. The first fastening device also includes a first mating surface having a plurality of rails having channels there between.
The waterproof fastening device also includes a second fastening member. The second fastening member has two opposing ends and further has a second mating surface having a plurality of rails with channels there between. The second mating surface is adapted for operatively engaging the first mating surface to facilitate the formation of a waterproof seal.
Desirably, the first fastening member and second fastening member do not pull-out when between about 10 up to about 200 Newtons or about 10 up to about 90 Newtons of force is applied using the holding force test.
Yet another aspect of the invention addresses a waterproof fastening device having a first fastening member having two opposing ends. The first fastening member also includes a high coefficient of friction first mating surface having a plurality of rails having channels there between.
The waterproof fastening device also includes a second fastening member. The second fastening member has two opposing ends and further has a high coefficient of friction second mating surface having a plurality of rails with channels there between. The second mating surface is adapted for operatively engaging the first mating surface to facilitate the formation of a waterproof seal.
Yet another aspect of the invention addresses a waterproof fastening device having a first fastening member having two opposing ends and a first mating surface. The first mating surface has a plurality of rails having a plurality of depressions and peaks thereon.
The waterproof fastening device also includes a second fastening member. The second fastening member has two opposing ends and a second mating surface and further has a plurality of rails having a plurality of depressions and peaks thereon. The depressions and peaks of the first mating surface are adapted to interlock with the depressions and peaks of the second mating surface to prevent pull-out. Further, the second mating surface is adapted for operatively engaging the first mating surface to facilitate the formation of a waterproof seal.
Fastening devices for creating and maintaining a seal are described herein. The devices of the present invention utilize various constructions for preventing mating surfaces from sliding past each other or pulling out during use. These constructions include, for example, projection/opening combinations, interlocking protuberances, high coefficient of friction mating surfaces, and depression/peak combinations.
The invention will be described with reference to the following description and figures which illustrate certain embodiments. It will be apparent to those skilled in the art that these embodiments do not represent the full scope of the invention which is broadly applicable in the form of variations and equivalents as may be embraced by the claims appended hereto. Furthermore, features described or illustrated as part of one embodiment may be used with another embodiment to yield still a further embodiment. It is intended that the scope of the claims extend to all such variations and embodiments.
It should be noted that any given range presented herein is intended to include any and all lesser included ranges. For example, a range of from 45-90 would also include 50-90; 45-80; 46-89 and the like. Thus, for example, the range of 95% to 99.999% also includes, for example, the ranges of 96% to 99.1%, 96.3% to 99.7%, and 99.91 to 99.999%.
Referring initially to
In use, a seal is formed by sliding the slider 90 down the length of the fastening member which causes the slider 90 to interlock the mating surface 30 of the first fastening member 10 with the mating surface 80 of the second fastening member 70. In this regard, the slider is moved in a direction causing the first fastening member and the second fastening member to pass within the slider from the opening end 20 to the closing end 20. The slider confines the first mating surface into contact with the second mating surface thereby creating a seal. As such, the fastening device bears similarity to a zipper, whereby the user of the fastening device manipulates the slider 90 to facilitate the formation of the seal, and also manipulates the slider 90 to unseal the fastening device and gain access to the interior of the seal. Alternatively, the fastening members may interlock without the use of a slider. In this regard, the fastening members of the fastening device may by manually coupled. Regardless of how the seal if formed, the fastening devices currently described, unlike conventional zippers, do not utilize teeth and are generally waterproof. The property of waterproofness is described below.
Referring now to
It is appropriate to utilize materials of sufficient dimension and material type such that the fastening device may be incorporated into a variety of different objects incorporating fabrics or other laminate materials (which may be waterproof or non-waterproof), such as wet suits, waders, rain gear, marine apparel, and boots, to name but a few. Accordingly, the first fastening member desirably includes a sufficient width of runout material 120 such that it may be permanently attached to an object, such as, for example, a clothing article, to form one side of the seal on the object. Similarly, the second fastening member 70 also includes a sufficient width of runout material 120 such that it too may be permanently attached to an object to form a second side of the seal for the object.
The first fastening member 10 and second fastening member 70 are made of resilient material that is capable of interlocking to form a seal. The first fastening member and second fastening member can be made of the same or different resilient materials utilizing extrusion, casting or other methods known in the art. Such materials may include, but are not limited to rubber or plastic, such as poly-vinyl chloride (PVC) or linear low density polyethylene (LLDPE) or elastomers such as polyurethane or elastomeric polyamides or polyesters. Depending upon the material used, the first fastening member 10 and second fastening member 70 may be glued, heat welded or otherwise bonded to an adjacent material. In this regard, the fastening device may be formed as an integral part of an object during manufacture of the object itself. For example, the first and second fastening members may be attached to adjacent material surfaces as part of a product, such as, for example, a jacket front. Thus, the material surfaces would be the left and right front sides of the jacket, which substantially define a first plane. The interlocked first and second mating surfaces of the first and second members also substantially define a plane (which may be parallel), such as is illustrated in
Returning for
Referring to
Additionally, in use, it is contemplated the two fastening members will be able to pass through the slider without obstruction and can be seated and unseated with the slider. However, because of the combination of the opening and projection, once seated, the two mating surfaces will be prevented from sliding past each other along the parallel axis of the fastening device.
It is also further contemplated that multiple openings and multiple projections may be used along the length of the mating surfaces of the first fastening member and second fastening member (See
Regardless of the number of openings and projections, a variety of geometries may be used for the opening(s) and projections (s). Non-limiting examples include the shape of a circle, trapezoid, triangle, square, rhombus, rectangle, the like, or combinations thereof. Alternatively, the opening is a series of repeating geometries and/or repeating alternating geometries. It is also contemplated that the openings and projections may be in a notch/groove configuration and they may also relate to each other in planar or linear relation as well as non-planar and non-linear relations. It should also be noted that the projections and opening (as well as the additional configurations described below) may be oriented on the sides of the individual rails/and or channels as shown in
In one particular embodiment the projection/opening configuration may be created by providing two fastening members of similar shape, but not similar size. The fastening member having the oversized profile can be trimmed in the longitudinal direction along the majority of the rail length leaving only a small section having the oversized profile. When the first and second extrusions are mated, this small oversized region presses tightly into a groove on the opposing rail thereby reducing the longitudinal slippage between the two rails. Optionally, a cavity, such as an indentation or slot or transverse groove or notch or the like, can be created in the mating rail of the second extrusion in a location so that the oversized section of the first extrusion fits into this cavity in the second extrusion. The presence of the oversized region of the first extrusion in the cavity of the second extrusion can also reduce the longitudinal slippage between the two extrusions.
In an additional embodiment of the invention interlocking protuberances 130 are used as locking mechanisms in lieu of the projection opening configuration. In practice at least one interlocking protuberance is in communication with the mating surface of the first fastening member. At least one corresponding interlocking protuberance is in communication with the mating surface of the second fastening member. Upon sealing of the fastening members together, the interlocking protuberances lock together, similar to a snap on a school backpack, to form a locking mechanism. The interlocking protuberances may be found on the surface of the rail, the channels of the rail, or combination thereof. Additionally, in some embodiments openings may be cut through the rails and/or channels of the first and/or second fastening members and the interlocking protuberances may be inserted therein. Further, the interlocking protuberances may be found in continuous and/or discontinuous patterns along the mating surfaces.
Regardless of how the interlocking protuberances are in communication with the mating surfaces, the protuberances may be formed from a wide variety of materials. These materials, include, but are not limited to plastic, metals, and other high durometer materials. The interlocking protuberances may also take on a variety of shapes and sized. Non-limiting examples of these are shown in
A further embodiment of the invention utilizes high coefficient of friction mating surfaces for forming a locking mechanism. High coefficient of friction (COF) is a COF of greater than 0.7 utilizing standard COF testing as known in the art. These mating surfaces may be formed by many mechanisms including, but not limited to, sand blasting. Further, a high COF may be achieved by applying fine powder, abradents, silica, or the like to the mating surfaces in continuous or discontinuous patterns. In use, the high COF portions of the first fastening member mate with the high COF portions of the second fastening member to form a locking mechanism and help prevent pullout of the fastening device.
Turning to
Desirably, the fastening devices of the present invention resist pull-out when between about 10 up to about 50 Newtons of Force, more desirably between about 10 up to about 90 units of force, more desirably between about 10 and about 200 Newton of force, and even more desirably between about 10 and about 400 Newtons of force is applied. It is also contemplated that the fastening devices of the present invention may resist pull-out when more than 400 Newtons of force is applied. In contrast, fastening devices which do not utilize the locking mechanisms described above may typically experience pullout when less than 10 Newtons of force is applied to the fastening members. A description of the method utilized to determine holding force is below.
The above described fastening devices of the present invention have a wide variety of uses and advantages. In general, the device can be used for outdoor clothing and apparel, outdoor equipment and cases, marine apparel and equipment, and even for everyday apparel. The device is particularly useful for products that are required to be fully waterproof. Such products include, without limitation, hazardous material suits, fire suits, dry suits, dry bags, bivy sacks, waders, space suits, tents, shipping packages, household storage bags, map cases, chart cases, kayak skirts, backpack covers, computer cases, electronic device cases, watercraft containers, inflatable cases (for cameras, etc.), flotation bags, flotation devices, waterproof pockets, fishing vest pockets, smell-proof pockets (for bears, etc.), and wetsuits. The device of the present invention is also particularly useful for products requiring or benefiting from being wind proof. Such products include, without limitation, jackets, sleeping bags, rain gear, boots, kayak jackets, wind breakers, wind proof fleeces, and tents. In addition to the advantages of being waterproof and wind proof, the device of the present invention has a number of other advantages, including, without limitation, being: airtight, watertight, gas tight, wind proof, quiet, less likely to get caught or jammed, lightweight, nonmetal (i.e., light, cheap and not cold), fully recyclable, smooth to operate, inexpensive and easy to produce. This device also eliminates the need for zipper-covering flaps and can be used in essentially any zipper function, thereby allowing hundreds of new products to be made using the device. Specifically, such new products can include the following: zip-down waders, zip-down dry bags, zip-down bivy sacks, easy access kayak skirts, fully waterproof rope bags, fully waterproof pockets, watertight/airtight shipping packages, easy access dry suits, everyday camera bags for underwater photos or films, fully waterproof and fully functional backpacks or fanny packs, zip-down rain pants and zip-in-half rain tarps.
In order to test the waterproofness of the fastening devices described herein, the devices where subjected to the Suter test as known in the art, described below. Fastening devices (available from W.L. Gore and Associates, Elkton, Md.) were attached, by seam sealing as known in the art, to a waterproof laminate fabric (available from W.L. Gore and Associates, Elkton, Md.) appropriate for use in a waterproof jacket. The sample tested and described below included a portion of the fabric and the fastening device including the intersections (s) where the fabric was attached to the fastening device.
To determine whether a protective barrier fabric or the seams of a garment made from the protective barrier fabric are waterproof, the Suter test procedure is used, which is based generally on the description in ISO 811-1981. This procedure provides a low pressure challenge to the sample being tested by forcing water against one side of the test sample and observing the other side for indication that water has penetrated through the sample.
The sealed seam test sample is clamped and sealed between rubber gaskets in a fixture that holds the sample so that water can be applied to an area of the sample 3 inches in diameter (7.62 cm). The water is applied under air pressure of 3 psig (0.21 bar) to one side of the sample. In testing a fabric laminate, the water would be applied to the face or exterior side. In testing a sealed seam, water is applied to the face side of the sample and the opposite side, or seam backer layer, is observed for leaks.
The opposite side of the sample is observed visually for any sign of water appearing (either by wicking or the appearance of droplets) at the seam edge for 3 minutes. If no water is observed, the sample has passed the test and the sample is considered to have a water entry pressure greater than the 3 psig load at which the test was conducted. In the case of the fastening devices of the present invention, all samples passed the Suter test and are considered waterproof.
Samples in accordance with the present invention were tested to measure their resistance to pull-out as described previously herein. An illustration of the test is in
1 Seat the two fastening members by hand, making sure the locking mechanism is securely closed. In the case of fastening members with projection(s) and opening(s), the locking mechanisms are the rails and channels of the mating surfaces as well as the placement of the projection into the opening to securely seal the mating surface of the first fastening member to the second fastening member. In some examples, the projection was constructed from the rubber materials utilized for construction of the mating surfaces. In other examples, the projection was constructed from a set or sets of metal inserts attached to a mating surface. In yet other examples, peaks and depressions as described above were utilized in lieu of openings and/or projections.
2. Attach a vice grip to one end of one of the fastening members.
3. Attach a force gauge to the other fastening member on the end opposite to where the vice grip is attached.
4. Pull the vice grip and the force gauge apart from one another until the fastening members slide apart and disengage.
5. Record the maximum force required to cause the fastening members to slide apart and disengage.
A first and second fastening member similar in shape to
A first and second fastening member similar in shape to
A first and second fastening member similar in shape to
A first and second fastening member similar in shape to
A first and second fastening member similar in shape to
A first and second fastening member similar in shape to
A first and second fastening member similar in shape to
A thin metal ruler was placed inside the channel of the first fastening member. Then a heated soldering iron with a tip of diameter approximately 0.7 mm was inserted between the metal ruler and the adjacent rail thereby melting the side of the rail and forming a depression on the side of the rail adjacent to the channel. This process of forming a depression was repeated down the entire length of the first fastening member at intervals of approximately 1.58 mm, thus forming a row of depressions with corresponding raised areas (peaks) in between. Depressions were then created down the entire length of the second fastening member in an identical manner. The depressions and peaks were located on the sides of the rails in such a manner that when the first fastening member and second fastening member were seated together, the depressions and peaks on the first fastening member lined up and interacted with the depressions and peaks on the second fastening member.
In this manner a locking mechanism having two rows of interacting depressions and peaks was created. The resulting fastening device exhibited a holding force of 59.1N when subjected to the holding force test.
A first and second fastening member similar in shape to
A thin metal ruler was placed inside the channel of the first fastening member. Then a heated soldering iron with a tip of diameter approximately 0.7 mm was inserted between the metal ruler and the adjacent rail thereby melting the side of the rail and forming a depression on the side of the rail adjacent to the channel. This process of forming a depression was repeated down the entire length of the first fastening member at intervals of approximately 1.58 mm, thus forming a row of depressions with corresponding raised areas (peaks) in between. Depressions were then created down the entire length of the second fastening member in an identical manner. The depressions were located on the sides of the rails in such a manner that when the first fastening member and second fastening member were seated together, the depressions and peaks on the first fastening member lined up and interacted with the depressions and peaks on the second fastening member.
In this manner a locking mechanism having two rows of interacting depressions and peaks was created. The resulting fastening device exhibited a holding force of 101.3N when subjected to the holding force test.
It is contemplated that fastening devices constructed of mating surfaces having higher durometer materials and/or having wider mating surfaces (See
By way of non-limiting example, with regard to the fastening devices constructed with inserts, if instead of using cast polyurethane for the insert materials, steel, for example, was used, it is contemplated that holding forces as high as high as 400 N and beyond could be achieved. For example, an insert constructed of steel with an ultimate tensile strength of 58,000 psi and a tensile modulus of 30,000,000 psi, would have a holding force at least five times as great as an insert constructed with PT8902, which has a tensile strength of 10,010 psi and a tensile modulus of 371,000 psi.
The resulting data from the Holding Force Test are summarized below.
The present application is a continuation-in-part application of pending U.S. patent application Ser. No. 11/942,555 filed Nov. 19, 2007, and further claims the benefit of U.S. Provisional Application No. 60/866,427 filed Nov. 19, 2006.
Number | Date | Country | |
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60866427 | Nov 2006 | US |
Number | Date | Country | |
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Parent | 11942555 | Nov 2007 | US |
Child | 12639537 | US |