The present invention relates to footwear, and more particularly, is related to an anti-slip device.
Use of wearable traction cleats is currently limited by users' ability to quickly, easily, and safely don and doff the cleats when transitioning from outdoors to indoors environments and vice versa. Specifically, traditional traction cleats, made of metal or hard plastics, are designed to be worn outdoors to provide stability and traction in icy and slick conditions, whereby making an unsafe situation when the user walks back indoors on to smooth floors and non pervious surfaces creating a slip-and-fall risk.
Unfortunately, doffing and donning traction cleats, for many users, is cumbersome, time consuming and difficult due to many physical barriers including but not limited to strength and motor skills, balance issues, vision loss and physical range of motion.
Many existing removable cleats involve the user having to remove an entire piece of molded footwear from their shoe in order to disengage the cleats which are embedded in, or attached to, the footwear device. This may be dangerous and create a user fall risk. For example, to transition from walking outside on an icy surface to walking inside a building, the user would typically either sit down, or bend over and balance on one leg, while trying to pull off the footwear from their shoe. Many types of one piece footwear devices are tight fitting in order to provide stability on the shoe, making it even more challenging to remove cleats from the shoe. It may not only be difficult and dangerous to remove cleats, it may also be dangerous to ambulate on slick, nonporous floors with the cleats engaged.
In implementations where cleats are attached to a band of elastic webbing, manipulation of the cleats may be challenging due to the tension of the elastic webbing around the shoe. In addition, the cleats may be too aggressive to be used on most sidewalks, creating a painful, dangerous, and off-balance gait pattern when ambulating. Therefore, there is a need in the industry to address the aforementioned deficiencies.
Embodiments of the present invention provide a footwear cleats device. Briefly described, the present invention is directed to a slip-and-fall prevention footwear accessory having a first strap configured to wrap around a footwear upper portion and sole at a ball portion of the footwear. A second strap has an attachment end rotatably connected to a first end of the first strap and a cleat region with a plurality of cleats. A first fastener rotatably connects the first strap and the second strap. A second fastener adjusts the length of a loop portion of the first strap around the footwear. The accessory facilitates temporary relocation of the second strap from a first position arranging the cleat region adjacent to the sole of the footwear to a second position arranging the cleat region over the footwear upper portion away from the sole portion. Other systems, methods and features of the present invention will be or become apparent to one having ordinary skill in the art upon examining the following drawings and detailed description. It is intended that all such additional systems, methods, and features be included in this description, be within the scope of the present invention and protected by the accompanying claims.
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principals of the invention.
The following definitions are useful for interpreting terms applied to features of the embodiments disclosed herein, and are meant only to define elements within the disclosure.
As used within this disclosure, “substantially,” means “very nearly,” or “within typical manufacturing tolerances.” In some instances, for example, when referring to shapes, “substantially” indicates the overall shape, for example, a substantially rectangular slot or shaft may have a longer length than width, but have rounded ends or edges. A substantially flat/planar surface may include a slight curve or contour.
As used within this disclosure, “footwear” refers to a shoe or boot worn by a person. The “ball portion” of the footwear refers to a cross section of the footwear corresponding to midfoot and/or forefoot of the wearer.
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.
Exemplary embodiments of the device of the present invention are drawn to a footwear cleats device attachable to footwear, for example, a shoe or a boot. The device is generally attached to the footwear being wrapped around a forward portion of the footwear corresponding roughly to a ball of the foot of the wearer, with a bottom portion passing under the sole of the footwear, and a top portion wrapped around the top of the footwear, for example, over a laces portion. A relocatable cleat region may be attached to the device in a first (usage) position, where one or more cleats of the cleat region are under the sole of the footwear and protruding outward from the sole, and a second (storage) position, where the cleats are fastened over the top portion of the footwear (“footwear upper”).
From the shoe strap swivel end 111, the shoe strap 110 passes through an aperture of a swivel piece loop 151 portion of the swivel piece 150, forming a shoe strap shoe loop 115 that wraps around a front portion of a shoe. The shoe strap 110 continues on to the terminus at the shoe strap fastener end 112 forming a shoe strap fit loop 117. The shoe strap fit loop 117 is formed by a portion of the shoe strap 110 that partially overlaps the shoe strap shoe loop 115. The shoe strap fit loop 117 is used to adjust the tension of the shoe strap 110 around the shoe, for example, by inserting the shoe loop pin 136 through a selected one of a plurality of shoe loop pin holes (not shown) in the shoe strap 110 according to a desired size of the shoe strap shoe loop 115.
The cleat strap 170 rotatably attaches to the swivel piece pin 152 at a cleat strap swivel end 172. At the other end, the cleat strap 170 removably attaches to a cleat strap pin 132 located on the fastener 130 on a fastener top side 131 at a cleat strap fastener end 171. For example, the swivel piece pin 152 may be inserted through an aperture at the cleat strap swivel end 172 of the cleat strap 170 such that the cleat strap swivel end 172 is secured to the swivel piece pin, yet the cleat strap 170 may rotate freely around the swivel piece pin 152. The cleat strap 170 attaches to the fastener 130 in two configurations: A first configuration where the cleat region 180 is adjacent to the sole of the shoe and cleats project outward from the sole; the second configuration where the cleat strap 170 is rotated around the swivel piece pin 152 and spans across the top of the shoe, so the cleat region 180 extends across a top of a shoe, rather than across the sole.
A plurality of cleats 182 are affixed to the cleat region 180. While
The cleats 182 may be positioned laterally from left to right in three rows substantially parallel to the length of the cleat region 180. Under the first embodiment, the top row has 4 cleats 182, the middle row has three cleats 182 and the bottom row has four cleats 182. The cleats are arranged to allow near to equal distribution across the cleat region 180 surface forming a grid like pattern. Different embodiments may have different arrangements of cleats 182 in the cleat region 180.
As shown by
Cleats 182 may be made out of other materials and have various lengths, weights, and durability, for example, including titanium or stainless steel. While the cleat strap 170 generally remains rotatably affixed to the swivel piece pin during operation, the cleat strap 170 may be removable from the swivel piece 150 at the swivel piece pin 152 to allow an interchange of the entire cleat strap 170 with cleats 182 having different lengths, configurations, and cleat materials for different types of terrain or weather conditions. The entire cleat region 180 may be replaced by swapping out the cleat strap 170. Alternatively, or in addition, the cleats 182 themselves may be individually interchanged, for example, by cleats 182 may pop-in/pop out of the cleat region 180.
The cleat strap 170 and cleat region 180 may be cast molded to allow the cleats 182 and the cleat region 180 to be integrally formed and the cleat base 181 encased in the material with only the cleat pin tip 186 protruding outward from the surface of the cleat region 180.
The footwear cleats device 100 is intended to remain fixed on the shoe inside the shoe strap shoe loop 115, whether the cleat strap 170 is positioned across the top of the shoe as in
The footwear cleats device 100 may be implemented in both child and adult sizes to accommodate various sizes for the cleat region 180. For example, the cleat region 180 may have a thickness in the range of 0.1 inch to 0.3 inches, a width in the range of 0.5 inches to 2.0 inches, and a length in the range of 3.0 inches to 7.0 inches, as appropriate to fit the specific shoe of the wearer, which may range from child sizes to adult sizes.
In alternative embodiments, the fastener 130 may be implemented differently using other types of fasteners.
Once the footwear cleats device 100 is adjusted to the user's shoe, the fastener 130 may be easily accessible towards the top or side of the shoe/foot. This is important as it may allow use of long handled adaptive equipment, for example, a reacher or a dressing stick to release the cleat strap fastener end 171 from the cleat strap pin 132. This may make the footwear cleats device 100 accessible to users who have difficulty bending over, for example, users with decreased range of motion, balance, shortness of breath, etc.
The cleat strap 170 is configured to swivel around the swivel piece pin 152 and flip down and lay across the sole of the foot with the cleats 182 projecting outwards towards the ground as shown in the under-shoe (use) position in
A cleat strap 970 includes a cleat region 980 that is configured to hold a plurality of cleats 182 at an intermediate portion of the cleat strap 970. A cleat strap first end 971 removably and/or rotatably attaches to the buckle 1000, and a cleat strap second end 972 removably and/or rotatably attaches to a cleat strap fastener 1102.
The cleat strap 970 has a two perforated regions on opposite sides of the cleat region 980, each perforated region having plurality of cleat strap holes 974. The number of cleat strap holes 974 on either side of the cleat region 980 is variable, depending upon the size of the cleat region 980 and/or the footwear intended for use with the device 900. Each cleat strap hole 974 has a substantially circular cross section shape, having a radius sized to fit around the fastener shaft upper 1110 (
For example, the cleat strap 970 may be, but is not limited to on the order of 6-10 inches in total length including the cleat region 980. The cleat region 980 may be on the order of 1.6-2.6 inches long. The cleat strap 970 may be on the order of 1 inch wide, while the cleat region 980 may be on the order of 1.75 inches wide. The cleat strap 970 is 1/16 in thick. The cleat region 980 may be approximately 0.25 inches thick, and may generally be thicker than the rest of the cleat strap 970, as the cleats 982 surround the cleat strap at the cleat region 980 with an approximate thickness of ¼ inch.
While
For convenience, a first substantially planar surface of the buckle plate 1020 configured to face toward the footwear is referred to as the interior surface, and a second substantially planar surface of the buckle plate 1020 opposite the buckle plate interior surface is referred to as the buckle plate exterior surface.
A buckle horn 1010 is attached to the exterior of the buckle plate 1020. The buckle horn is disposed near the tip of the tapered end of the buckle plate 1020, and protrudes outwardly from the buckle plate 1020 exterior surface and extends in a direction substantially normal to the buckle plate exterior surface. The buckle horn 1010 includes a horn tip flange 1016 capping an end portion of the buckle horn shaft. The horn tip flange 1016 may have a profile shaped to retain the shoe strap 910 (
The surface area of the horn mid flange 1014 may be significantly larger than the profile area of the horn tip flange 1016. The horn mid flange 1014 is arranged to secure the non-loop end 911 (
The buckle horn 1010 may be integrally formed with the buckle plate 1020, or may be formed separately from the buckle plate 1020 and attached to the buckle plate 1020, for example using an adhesive, among other attachment means.
Under the second embodiment, exemplary dimensions for the buckle horn 1010 may be, but are not limited to the following. The buckle plate 1020 may have a length of 1¾ inch by width of 1¼ inch at the slotted end with a thickness on the order of ¼ inch. The buckle horn 1010 may have a ½ inch length and a diameter of ¼ inch at the upper portion 1018a and a diameter of ½ inch wide at 1018b, both on the order of ¼ inch thick. The horn tip flange 1016 is ⅜ inch long, ¼ inch wide at center and tapered at both ends, and about ⅛ inch thick. The horn mid flange 1014, may be ¾ inch in circumference and between 1/16-⅛ inches thick. The buckle 1000 may be formed by various conventional means, for example, molding, 3D printing, among others. The fasteners 1100 and/or buckle 1000 may be formed of a rigid or semi-rigid material such as plastic or metal. If metal is used, it is preferably a rust resistant metal or otherwise treated to resist rust and/or corrosion. Alternatively, the portions of the buckle 1000, for example the buckle plate 1010, may be formed of a semi-rigid material (such as a stiff rubber) with sufficient flexibility that the buckle plate 1010 may conform (for example, under tension from the shoe strap 910 and/or the cleat strap 970) to the contours of the footwear upper 901.
The shoe strap fastener 1101 and a cleat strap fastener 1102 attach to the shoe strap 910. The shoe strap fastener 1101 is used to removably fasten the shoe strap loop end 912 to an interior portion of the shoe strap 910. The cleat strap fastener 1102 is used to removably fasten the cleat strap 970 to the shoe strap 910. Under the second embodiment, the shoe strap fastener 1101 and the cleat strap fastener 1102 may be substantially identical, for example, as shown by the fastener 1100 of
A fastener shaft lower portion 1118 is attached to a base flange 1112. The fastener 1100 includes a top flange 1116 at an end portion of a fastener shaft upper portion 1110. The top flange 1116 may have a profile shaped to retain the shoe strap 910 or cleat strap 970 that have been slipped over the top flange 1116 to engage the fastener upper shaft 1010. For example, the top flange 1116 may have a substantially oblong or elliptical profile, among other possible shapes A fastener mid flange 1114 having, for example, a substantially circular profile shape, is disposed between the fastener shaft upper 1110 and the fastener shaft lower 1118 between the base flange 1112 and the top flange 1116. For the cleat strap fastener 1102, the fastener mid flange 1114 may help prevent the straps 910, 970 from sticking to each other. For the shoe strap fastener 1101, the fastener mid flange 1114 may help prevent looped portions of the shoe strap 910 from sticking to each other.
The profile area of the fastener mid flange 1114 may be significantly larger than the profile area of the fastener top flange 1116. The fastener mid flange 1114 is arranged to secure the shoe strap 970 between the fastener base flange 1112 and the fastener mid flange 1114. For example, a shoe strap slot 915 may be slipped over the fastener mid flange 1114. The fastener top flange 1116 is preferably sized to allow the cleat strap holes 974 or the shoe strap holes 914 to be removably slipped over the fastener top flange 1116. The fastener shaft upper 1110 may have a circular cross section shape to allow the cleat strap 970 to rotate around the fastener shaft upper 1110, while still being secured by the fastener top flange 1116. In contrast, the fastener shaft lower 1118 may have a substantially rectangular cross section shape to prevent the shoe strap 910 from rotating around the fastener shaft lower 1118.
The shoe strap 910 and cleat strap 970 are each preferably formed of a material that allows the shoe strap to flex in directions normal to its length, but to not stretch substantially along its length, for example, by less than 5%, and preferably less than 2%. The shoe strap 910, the cleat strap 970, and the cleat region 980 may be formed of the same material previously described for their counterparts 110, 170, 180 of the first embodiment, described previously, for example, hypalon material.
The shoe strap non-loop end 911 is configured to attach to the buckle horn 1010. The shoe strap loop end 912 is configured to be adjustably looped through the buckle slots 1030, and secured by a shoe strap fastener 1101.
Either end of the cleat strap 970 may rotatably attach to the buckle horn 1010. The opposite end of the cleat strap 970 removably attaches to the cleat strap fastener 1102 located on an opposite side of the shoe upper 901. For example, the buckle horn 1010 may be inserted through a cleat strap hole 974 such that the cleat strap 970 is secured to the buckle horn 1010, yet the cleat strap 970 may rotate freely around the buckle horn 1010. The cleat strap 970 attaches to the cleat strap fastener 1102 and the buckle horn 1010 in two configurations: A first configuration shown in
The footwear cleats device 900 may be implemented in both child and adult sizes to accommodate various sizes for the cleat region 980. In alternative embodiments, the buckle 1000 and/or the strap fasteners 1101, 1102 may be implemented using other types of fasteners according to the desired application, for example, magnetic fasteners hook-and-loop fasteners, snaps, a bullet fastener, a hinged clasp, and a slide lock fastener, among others. In general, fasteners that are unlikely to be clogged with dirt, snow, ice, or mud may be preferred.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.
This application is a continuation of U.S. patent application Ser. No. 17/933,241, filed Sep. 19, 2022, entitled “Footwear Cleats Device”, which claims the benefit of U.S. Provisional patent Application Ser. No. 63/246,361, filed Sep. 21, 2021, entitled “Footwear Cleats Device,” both of which are incorporated by reference herein in their entirety.
Number | Date | Country | |
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63246361 | Sep 2021 | US |
Number | Date | Country | |
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Parent | 17933241 | Sep 2022 | US |
Child | 18598462 | US |