This invention relates to fastener products having arrays of discrete male fastener elements that engage arrays of male fastener elements to form a fastening, to articles incorporating such elements, and to methods of making such elements.
Area fastener products (i.e., those that engage over an overlapped area) include adhesives and hook-and-loop fasteners. Another type of area fastener product has an array of discrete male projections that interlock with male projections of a related product. This latter type of fastener is sometimes referred to as ‘self-engaging,’ particularly when the fastener elements of each product are of a similar size and shape. Many self-engaging fastener products employ mushroom-type fastener elements, having heads that overhang in multiple directions. Such mushroom fastener elements are arranged with sufficient density that edges of mating mushrooms snap past each other during engagement.
Self-engaging fastener (SEF) products are generally considered to exhibit high shear and tension resistance, and require higher force for engagement, than typical hook-and-loop fasteners. During disengagement of SEF products by peel it is common to experience a peel force ripple and associated noise, as individual fastener elements snap out of engagement. However, such products can also be desirable in many low-load applications, such as those in which loop fibers are not desired.
Improvements in area fastener products employing male-male fastener element engagement are desired.
Various aspects of the invention feature an area fastener product with a strip-form base of resin having a broad surface from which an array of discrete fastener elements extends. The base and fastener elements together form a unitary and seamless mass of resin, preferably a molded mass. The fastener elements each have a molded stem extending from the broad surface of the base to a curved head that extends toward a front side of the fastener element. The head forms a crook and ends in a distal tip, the crook defined in part by an underside head surface that overhangs a lower portion of the stem.
According to one aspect of the invention, the curved head protrudes beyond the stem on the back side of the fastener element (opposite its front side) to form an overhang defined by an overhang surface of the head directed toward the base.
In some preferred embodiments, the stem tapers in width, such as measured between the front and back sides of the fastener element.
In some embodiments the head has an upper surface that extends from the tip to the overhang surface without inflection. In some cases, the upper surface forms a smooth, inflection-free curve from tip to overhang surface. For example, the upper surface may follow a radius from tip to overhang surface, and the center of curvature the upper surface of the curved head can be approximately centered over a lower portion of the stem, for example, between front and rear stem fillets, such that a highest elevation of the curved head is also approximately centered over the lower stem portion.
In some arrangements the distal tip is directed toward the base, and can be molded to be so directed, such as in a mold cavity of such shape.
Preferably, a rearmost extent of the curved head extends rearward of the foremost extent of the back side of the stem by an overhang distance, measured parallel to the broad surface of the base, of at least about 10 percent of an overall width of the curved head, measured parallel to the base. The overhang distance is preferably less than about 30 percent of the overall width of the curved head.
The stem preferably has a width, measured parallel to the base fore-aft at an elevation of the foremost extent of the back side of the stem, that is greater than about 50 percent of the overall width of the curved head, measured parallel to the base.
In some embodiments, the fastener elements are arranged in the array to provide a distension overlap of at least 30 percent (preferably, at least 50 percent, and more preferably, at least 75 percent) when mated with an identical fastener product. By ‘distension overlap’ we mean the ratio of distension length to pitch spacing, as discussed below with respect to
In some examples, each fastener element has planar lateral sides interconnecting its front and rear sides. The lateral sides in some cases are parallel and extend from the broad surface of the base to an uppermost extent of the curved head of the fastener element. The front and rear sides of some fastener elements intersect their lateral sides at right angles.
In some cases, the array of fastener elements includes parallel rows and parallel columns of fastener elements forming an orthogonal array, with the curved heads of the fastener elements directed along their respective columns. For some applications, the heads of the fastener elements in adjacent columns are directed in opposite directions. In some arrangements, the curved heads of the adjacent fastener elements of the row only partially overlap when viewed along the row, such that the tips of two adjacent fastener elements of the row are visible from the end of the row.
The fastener elements may be arranged in various configurations. In one example configuration, discussed below with respect to
In some other applications the heads of substantially all of the fastener elements are directed in a common direction. In some cases, the stems of adjacent fastener elements of a row are aligned in a direction perpendicular to their columns.
Some embodiments also include one or more shear stops extending from the broad surface of the base between rows of fastener elements and positioned to engage heads of molded fastener elements of a mated, identical fastener product, to resist movement relative to the mated product along the row. Each shear stop preferably extends to a height above the broad surface that is less than half of a height of the fastener elements above the broad surface. Preferably, the shear stops are so short as to hot preclude engagement of adjacent fastener elements. Some examples have multiple shear stops dispersed within the array at a shear stop density of one per 25 to 100 fastener elements.
In some embodiments, adjacent fastener elements of each column are spaced apart according to a pitch spacing less than twice an overall width of the head, measured along the column.
The fastener element heads of adjacent columns in some examples are spaced apart by a gap width less than their thickness measured perpendicular to their columns.
In some examples, the overhang surface on the back side of the fastener element defines an inflection point between an upper Surface of the curved head and a curved back surface of the stem. In some cases the curved back surface of the stem and the upper surface of the curved head each define a similar radius of curvature.
In some configurations, the front and back sides of the fastener element join the base at curved fillets.
In some examples, the stem and curved head together form a single continuous projection from base to tip, defining a constantly narrowing flow thickness. In some cases the curved head defines a flow thickness, measured at a rearmost extent of the crook, that is less than half of an overall lateral thickness of the head.
Various examples can be configured with additional features and functions. For example, in some cases the curved head has an electrically conductive upper surface, such as for providing a conductive fastening when mated.
The fastener elements are preferably shaped and arranged such that the product will releasably engage in either of two opposite orientations with a like product.
For many applications, the fastener elements extend to a height of less than about 0.050 inch (1.25 mm) from the broad surface of the base, and the array preferably has a fastener element density of more than 2,000 fastener elements per square inch (300 per square centimeter) for some applications, although the fastener elements maybe scaled up and arranged in a density up to 200 per square inch (30 per square centimeter), for example, for other applications.
Another aspect of the invention features two of the fastener products as described above, releasably engaged to one another. Each fastener element of a first of the two products is disposed between respective adjacent fastener elements of a respective column of the second of the two. The heads of each of the fastener elements of each of the two products is disposed adjacent the broad surface of the base of the other of the two products, such that interference between the fastener elements of the two products resists separation of the products.
In many applications, the heads of the fastener elements of both of the products extend in a common direction.
In some embodiments, the tip of each fastener element of one product is directed toward the overhang surface of the back side of a respective, adjacent fastener element of the other product. In some cases, the tips and overhang surfaces of the adjacent fastener elements define a contact angle and static friction coefficient such that the crooks distend upon separation.
In some other embodiments, wherein the tip of each fastener element of one product is directed toward the front side of a respective, adjacent fastener element of the other product, such that the tips of the fastener elements interengage upon release to temporarily distend the crooks.
The bases of the two products are, in some examples, carried by flexible substrates, such that the releasably engaged products can be peeled apart by flexing the bases.
According to another aspect of the invention, the fastener elements are arranged in the array to provide a distension overlap of at least 30 percent (preferably, at least 50 percent, and more preferably, at least 75 percent) when mated with an identical fastener product. In some examples of this aspect of the invention, the curved head protrudes beyond the stem on a back side of the fastener element to form an overhang defined by an overhang surface of the head directed toward the base, and/or the crook formed by the curved head is defined in part by an underside head surface that overhangs a lower portion of the stem.
Another aspect of the invention features two area fastener products in which the arrays of fastener elements are releasably engageable with one another upon a normal engagement pressure to form a fastening in which each fastener element of a first of the two being disposed between respective adjacent fastener elements of the second of the two, the heads of each of the fastener elements of each of the two products being disposed partially beneath the heads of the other of the two products, such that interference between the fastener elements of the two products resists separation of the products. The fastening resists normal separation with a separation resistance, the normal engagement pressure being less than 80 percent (preferably, less than 75 percent or even around 60 percent) of the separation resistance.
By ‘normal engagement pressure’ we mean the minimum pressure required to fully engage the two arrays as they are brought together in a normal direction with their bases retained in a rigid, planar and parallel orientation. By ‘separation resistance’ we mean the minimum pressure required to subsequently separate the engaged arrays.
Another aspect of the invention features a method of forming fastener products of the type described herein, by pressing flowable resin into an array of blind cavities extending from a mold surface, cooling the resin to solidify molded fastener elements in the cavities and a layer of resin on the mold surface, and then stripping the resin layer from the mold surface along with the molded fastener elements from their cavities.
In some cases, the cavities are arranged to form fastener free lanes between columns or rows or sets of columns or rows of fastener elements.
Fastener products of the type described herein can be configured to provide a pleasingly smooth peel performance and a tactile confirmation of engagement and/or develop a substantially higher disengagement pressure than the pressure required for engagement. The fastener element arrays can enable some self-alignment of the arrays as they are brought into engagement, not only with respect to lateral displacement but also with respect to angulation, particularly with the fastener elements arranged in fully aligned rows and columns. The products can be readily made inexpensively in continuous fashion in molded form, for example. In many cases the fastener element arrays can be engaged in either of two opposite orientations.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like reference symbols in the various drawings indicate like elements.
Referring first to
In this configuration, fastener elements 16 are arranged in parallel rows and orthogonal columns, the columns extending in the machine direction MD, and the rows extending perpendicular to the columns, in the cross-machine direction CD. All fastener elements 16 face in a common machine direction, rather than in opposite directions. Adjacent rows are separated by fastener element-free lanes, such that one could look across the entire product in the cross-machine direction and see open space between adjacent fastener elements of the near column, as illustrated in the side view shown in
Referring next to
The stem and curved head together form a single continuous projection from base surface 14 to tip 30, defining a constantly narrowing flow thickness so as to enable extraction from a similarly shaped mold cavity without cavity opening. The curved head defines a flow thickness tF, measured at the rearmost extent 46 of the crook, of 0.0036 inch (0.09 mm). This flow thickness is less than half of the overall lateral thickness of the head (i.e., the dimension perpendicular to the view as shown in
Still referring to
Referring back to
In the mating engagement illustrated in
If a less smooth peel is desired, the tip-back engagement configuration can be modified (e.g., by altering the static coefficient of friction and/or engagement angle between the tips and fastener element backs), such that the fastener element crooks of the flexed product are compressed, rather than distended, to separate from the other product. In such a configuration, the tips of the moving fastener elements slide along the back surfaces of the other fastener elements, rather than remaining relatively stationary as illustrated. Such an arrangement is similar to many other self-engaging fastener products, in which each row of elements separates over a relatively narrow range of motion. In some such products, such as some rigid-head mushroom-shaped products, the interfering edges of the mating fastener elements ‘snap’ against each other both during engagement and disengagement. By way of contrast, the fastener elements shown in
One advantageous feature of the fastener element arrays described above is that they also enable engagement with the fastener elements of the two products facing in opposite directions, such that the tips of cooperating fastener elements face each other. Of course, separation from such an engagement involves slightly different mechanics, as will be discussed below.
As will be understood from
The fastener element arrangement of
As illustrated in either of
Furthermore, because of the relatively high fastener element density and the stiffness of the individual fastener elements, the fastening surface of the product is very resistant to damage while remaining relatively smooth to the touch. Some earlier self-engaging fastener arrays required the stems flex to give enough room for the heads to slide past each other during disengagement, and more vulnerable to damage. Because the overhang is in the machine direction only, the fastener products of
The shapes and spacing of the fastener elements of product 10a are such that when two such products are brought into releasable engagement with their fastener elements in face-to-face orientation, as shown in
The fastener elements 16a of each row in
As in the first-described fastener element shape, the stem and curved head together form a single continuous projection from base surface 14 to tip 30a, defining a constantly narrowing flow thickness so as to enable extraction from a similarly shaped mold cavity without cavity opening. The curved head defines a flow thickness tF, measured at the rearmost extent 46a of the crook, of 0.0044 inch (0.11 mm). This flow thickness is only slightly greater than half of the overall lateral thickness of the head (i.e., the dimension perpendicular to the view as shown in
Still referring to
Referring back to
Referring to
The types of self-engaging fastener elements and fastener element arrays discussed above can be molded from various types of thermoplastic resins, such as polypropylenes, nylons and polyethylenes, to name a few. The fastener elements can also be molded from electrically conductive resins to make an electrically conductive closure. These products can also be molded from an elastomeric material, such as SARLINK or SANTOPRENE, to provide a closure that is virtually “silent” when engaging and disengaging. Elastomeric materials may also provide closures with very long cycle life.
It is also anticipated that the size of the features could be scaled up or down to adjust the relative strength of the closure, or for various applications. The closure strength can also be controlled by the stiffness of the resin used, and/or by eliminating fastener elements from the array. For example, a fastener product could have an array as shown in any of the above figures but in which a number of discrete elements, whether adjoining each other or spaced apart within the array, are removed.
As an example,
Such spaced rows of fastener elements 16b can further provide a notched or interrupted peel force, where that is desired, whereas maintaining a generally uniform fastener element density along the fastener strip generally maintains a constant peel performance while lowering overall peel strength.
The fastener elements and arrays described above are generally best suited for applications in which the mating arrays will generally be overlapped in parallel, or near-parallel alignment. As an example,
Much of the above discussion has focused on peel as a mode of separating the fastener products with flexible bases, at least one of which is bonded or laminated to a flexible substrate, such that the base of at least one product flexes during disengagement. Another application of the above-described fastener products involves bonding or laminating both mating products to rigid substrates, such that the bases of the products remain relatively planar during both engagement and disengagement. In such cases engagement and disengagement are both typically accomplished by a force provided normal or perpendicular to the plane of engagement. In such applications these products can develop very high disengagement load resistance. The amount of disengagement resistance can be so high, in fact, that relatively small areas of engaged fasteners may be substantially unreleasable without tools but the products can be readily separated by sliding a thin sheet of metal between them. What is more, examples of the above-described products in rigid applications can be engaged with lower normal force than that required subsequently for disengagement, in some cases requiring for full engagement only about 60 percent of the disengagement resistance capacity. According to one test performed on the product as described above with respect to
The above-described fastener products may all be made in a continuous forming process involving a rotating mold roll with discrete, fastener element shaped cavities, as described in the Fischer patent mentioned above. For moldability, the illustrated fastener elements all have stems and heads that taper in width from base to tip. More specifically, each fastener element has a flow thickness or flow area, perpendicular to the flow of a flowable resin being forced into the cavity from base to tip, that continuously decreases from base to tip, such that the resin as molded may be extracted from the cavity without opening the cavity. The illustrated fastener products in which the fastener elements of a given row all face in one direction may also be manufactured according to profile extrusion methods known in the art of fastener product manufacture, such as by extruding a fastener element shaped rails on a continuous base and then severing the rails to form individual fastener elements. The severed fastener elements will differ from those of the fully molded type in that their opposing side surfaces will be of severed form, rather than having a resin ‘skin’ effect resulting from molding against a cooled surface. The severed elements can be spaced apart along their rows by stretching the base following severing, or by removing segments of each rail between elements, or by shrinking the extruded material after severing. Fastener elements formed by extrusion need not taper in width from base to tip.
While a number of examples have been described for illustration purposes, the foregoing description is not intended to limit the scope of the invention, which is defined by the scope of the appended claims. There are and will be other examples and modifications within the scope of the following claims.
This application claims priority to U.S. Provisional Application Ser. No. 60947919, filed on Jul. 3, 2007, which is incorporated by reference in its entirety.
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