This invention relates to an adhesive shoe or artificial sole. There are many situations in which a person may wish to walk barefoot but with foot protection. This foot protection can include the benefits of the lower sections of the shoe but without the hindrances of the top of the shoe. No shoes currently exist that perform in a way that mimics the natural performance of the bare human foot. All existing shoes or foot protection devices such as sandals without tops alter gait, are not resilient and have uncomfortable features, and are not functional for higher demand activities.
For example, in warmer climates, sandals are frequently worn with various dorsal mechanical restraints to keep the shoe on the foot. Topless sandals have been available with uniform thickness soles and uniform adhesive applied to the top of the sandal where the upper surface contacts the foot. These sandals are not sufficiently durable at the interface for use in an array of activities and are prone to third body interposition in the interface and discomfort. The limits of existing adhesive designs also require alteration of gait to maintain sandal adherence.
There is a trend towards increased barefoot activity as a way of developing foot strength. These “minimalist” shoes allow the muscles in the foot to gain strength by providing less constriction to the foot. Long-term use of more rigid running shoes is now seen as potentially damaging to the knees. Thus, runners are being encouraged to cross train with shoes that more closely mimic barefoot running. There are also many situations in which improved protection and support is required for the bottom of the foot to protect from injury.
There is a need for footwear applied to the plantar surface of the foot which is functional in a variety of physical environments and suitable for higher demand activities. These higher performance activities include use in water, sand, paved surfaces, etc. The protector needs to support the dynamic structural requirements for a variety of physical exertions including running, jumping, swimming, diving, jogging, etc.
This invention describes footwear having an artificial sole that is adhesively attached to the foot or an adherent shoe that incorporates various features to more closely facilitate normal gait and to mimic the experience of walking barefoot. This footwear can be used for high performance and high demand activities. In addition, this invention offers the improvements over walking barefoot of offering structure support and protection for the foot throughout gait.
The inventive footwear also incorporates features that allow it to be worn in wet or sandy environment. The inventive footwear can differ from the prior art because it can provide a minimal amount of adhesive contact with the foot that is still sufficient for the high-performance activity that the footwear is being used for.
Previous designs disclose adhesives applied to most or all of the skin on the bottom of the foot which causes discomfort in sensitive portions of the foot. Previous designs also do not provide additional support for the foot biomechanically. The present invention provides a substantial improvement over the prior art. An adherent shoe is disclosed that offers improved biomechanics for a more normal gait that minimizes the amount of adhesive areas required for stability of the shoe. The adhesives are only applied in zones of the foot that maximize stability and minimize discomfort. The present invention also prevents interposition of foreign bodies in the shoe/foot interface and that more closely mimics the barefoot walking experience while providing protection against sharp and hazardous surfaces that may be encountered by the user.
The adhesives can be placed on key locations of the upper surface of the footwear and these adhesive areas can provide at least the minimal adhesion necessary for successful and prolonged adherence during rigorous use. For example, the adhesive regions can include the heel, the lateral side of the foot and a region defined by a border around the first through fifth metatarsophalangeal (MTP) joints. Adhesives can be avoided on the arch region of the foot. Adhesive regions may be placed under the lower contact areas of the toes. However, the areas under the middle sections of the toes should be free of adhesives. In an embodiment, the footwear can include a raised peripheral regions, and an adhesive can be used to couple the inner surface of the raised peripheral regions to the outer side surfaces of the foot. The peripheral adhesion may include the heel but may exclude the toes.
In an embodiment, the adhesive regions can be formed from a thin adhesive material that has a lower surface that is in direct contact with the upper surface of the protective layer and an upper surface that is in direct contact with the foot. The adhesive regions can be formed in recessed areas of the upper surface of the protective layer so that the upper surface of the adhesive regions can be planar and even with the upper surface of the protective layer. Alternatively, the protective layer may not have recessed areas of the upper surface and the adhesive regions can be higher than the upper surface of the protective layer or the upper surface of the adhesive regions can have a ruffled texture that is uneven, which can make the adhesive regions breathable.
The adhesive regions can have shapes that correspond to the heel in the calcaneal area and the lateral side of the foot and the region under the first through fifth MTP joints. If the adhesive regions need to be replaced, the adhesive layers can be removed from the protective layer and replaced. In other embodiments, the adhesive regions can be uniform in shape such as a circle. The user can place the adhesive members in the desired locations on the upper surface of the protective layer avoiding the arch and middle toe areas. In an embodiment, a supply of adhesive members can be supplied to the user. For example, if the adhesive members are circular, the supply can be stored in a cylindrical stack from which individual adhesive members can be removed and used.
In an embodiment, the adherent qualities of the adhesive regions may vary by location. Some adhesive regions can have a strong adhesive bonding on areas where the shear movement should be minimized such as under the heel. However, other adhesive regions can have lower strength adherent qualities. For example, in an embodiment, the raised edges of the footwear may be intended to keep debris away from the foot and may have a lower strength adhesive. Thus, the adhesive regions can be non-uniform in adherence. Various types of adhesives can be suitable for the inventive footwear. For example, the adhesion mechanism can utilize Van der Waal force adhesion, which does not use glues or chemicals that can leave a residue. Other suitable adhesives include surgical skin adhesives that can be in the form of pressure-sensitive adhesive tape that can have a hypoallergenic adhesive. This adhesive tape can be elastic and breathable.
In an embodiment, the protective layer of the footwear can have a non-uniform thickness with a heel cup having additional padding, the arch and mid foot having less padding thicknesses and the toes having even less padding. The variable thickness of the footwear can range from about 5 mm to 20 mm. In an embodiment, the thickness of the protective layer of the can mimic the natural padding of the foot
In an embodiment, the some or all of the perimeter of the footwear can have upward raised edges. The raised edges may surround the rear foot and extend forward to the toes. The raised edges may be omitted from the front portion of the footwear adjacent to the toes. The raised edges can improve the stability of the footwear by preventing the foot from sliding over the edges of the footwear. The raised edges also increase the contact area on the border of the foot. The adhesion plane is on near vertical perimeter surfaces of the foot which are at a nearly perpendicular angle to the plantar surface of the foot. In contrast to relying upon a peel adhesion force between the footwear and the foot, the raised edges are configured to provide shear force adhesion and have increased resistance to pull off of the adhesive boundary.
In an embodiment, the inventive footwear can include flexible elastic tabs that can be thin high tensile strength structures that are attached to portions of the perimeter of the footwear or the raised edges of the footwear. The tabs can wrap over the top and/or side portions of the foot to more securely attach the footwear to the perimeters surfaces of the foot and function to securely attach the footwear to the foot like the edge adhesive mechanisms as described above. Like the edge adhesives, the tabs are a vehicle to change the orientation of the peel off forces needed to disengage the adherent foot surface. In an embodiment, the tabs can be replaceable. If the tab structure or the adhesive fails and needs to be replaced, the tab can be removed from the footwear and replaced. In an embodiment, the tab can be attached to the footwear mechanically or with an adhesive that is different than the adhesive used to attach the footwear to the user's foot. The replacement tabs can be inserted into slots along one or more edges of the protective layer of the footwear.
In an embodiment, the inventive footwear can include an arch support that can be integrated into the footwear. In an alternative embodiment, the arch support can be a modular structure that is adhesively attached to the upper surface of the protective layer. The arch support can be an elastic structure that can compress or expand with the movement of the foot. The arch support can include a plurality of fenestrations that can be arranged in a radial pattern across the width of the footwear. In a preferred embodiment, the upper surface of the arch support is not adhesive and does not stick to the arch surface of the foot. The arch support can slide against the bottom of the foot. The arch support without the adhesive can improve the comfort of the inventive footwear. The adhesive regions of the footwear do not contact the arch support area of the user's foot.
In other embodiments, this invention relates to a multi-layered sole that is adhesively attached to the person's feet. The adhesive material can surround the outer perimeter of the multi-layer sole and can be used to attach the sole to the user's feet. The arch support can be a separate elastic structure that can have a specific size and shape that is based upon the anatomy of the user's feet. More specifically, the user can select a specific shoe sole size and then select a specific arch support having a size that will properly fit the arch of the user's foot. While two users may select the same shoe sole size, a flat-footed user may need a lower arch support while another user may need a thicker arch support. The arch support can be adhesively attached to the sole of the foot and precisely positioned for better contact between the foot and arch support. Because the sole can be adhesively attached to the foot and move with the foot rather than the sole of the shoe, there is minimal movement between the foot and arch support.
There are many situations in which a person may wish to walk barefoot but with an arch support and some foot protection. This foot protection can include the benefits of the lower sections of the shoe but without the hindrances of the top of the shoe. In an embodiment, the inventive multi-layered adhesive sole can be worn alone and in other embodiments, the multi-layered sole can be worn within a sock that is then placed in a shoe, boot, or other footwear.
The adhesive material can be wet or dry adhesives. On one embodiment the adhesive is a hydrogel. Hydrogels can have a flexibility that mimics that of natural tissues including the sole of the foot and can be absorbent absorb the skin evaporative losses. Hydrogels can be composed of cross-linked polymers such as polyethylene oxide, polyAMPS, and polyvinylpyrrolidone commonly used to attach electrodes to skin for prolonged periods. The crosslinking within the hydrogel can provide the adhesive bonding between the footwear and the skin of the user's foot.
As perspiration occurs through the surface of the foot, this invention describes the use of porous materials along the plantar surface of the foot. These porous regions can occur selectively along the plantar surface of the foot. The porous zones can occur in either adhesive or non-adhesive zones. As porosity in the adhesive zone in some strategies can reduce the adhesive strength, this invention describes the use of porosity in the shoe surfaces specifically in the non-adherent regions of the shoe. In one embodiment, this can include porosity in the arch of the foot.
With reference to
A protective layer having an upper surface that is completely covered with an adhesive to attach the footwear to the foot can be problematic. Experimentation has demonstrated that adhesives used on specific zones of the foot interfere with certain motions and generate shear at the skin that can cause foot discomfort and blistering. Specific examples of problem areas include adhesive in the region of the arch of the foot and on the undersurface of the toes. The area under the arch is sensitive to shear forces and similarly, the toes may require freedom of movement while walking and running.
The present invention describes a plurality of configurations that can each be used to provide maximum stability while minimizing the size of the adherent regions on the shoe. Minimizing the extent of the adherence has been shown to markedly improve the comfort to the wearer. As discussed above, those areas constitute the area on the ball of the foot, the heel of the foot and in a zone along the lateral side of the plantar foot. In an embodiment, the plurality of adhesive regions can cover less than 40% of the upper surface of the protective layer.
For higher demand activities, the protective layer can extend upwards around portions of the perimeter of the foot. With reference to
With reference to
With reference to
With reference to
In an embodiment, the arch can have a convex upper exposed surface that is built into the upper surface of the protective layer. However, in other embodiments, the arch can be a modular structure that can be selected to properly fit the arch of the user and secured to the upper surface of the protective layer. With reference to
The arch of the foot can go through a dynamic transformation during gait and running. At heel strike, the arch 155 can be stretched longitudinally and then the arch can progressively collapse through gait in the longitudinal plan. The arch 155 can be made of an elastic material and may include a plurality of fenestrations 157 that allow the arch 155 to stretch and compress more easily. The fenestrations may be arranged in a radial pattern extending outward from the lateral side of the arch. In an embodiment, the inventive footwear can apply dynamic structures such that an arch 155 of the shoe that allows for expansion at heel strike and collapse through other portions of gait to minimize any shear forces that may be transmitted by the footwear to the skin surface on the arch of the foot.
In different embodiments, the inventive footwear can include various combinations of features. With reference to
Although the adhesive regions have been illustrated as having shapes that correspond to specific anatomical features that can fit into recesses in the upper surface of the protective layer, in other embodiments, the adhesive regions 109 can be uniform in shape. For example, with reference to
With reference to
The angle and conformation of the footwear is also critical in order to prevent biomechanical difficulties during the various phases of user's gait. Specifically, flat adherent footwear can cause problems for the user during the “toe off” phase of gait and can lead to altered gait patterns. For example, a steppage gait has been observed in users with flat adherent design footwear. In an embodiment with reference to
With reference to
As discussed, the tab structure can be a replaceable structure that can be used to secure the footwear to the foot. With reference to
Although the tab 257 is shown as a single piece structure, in other embodiments, the footwear can have two separate tab structures. One tab can extend out of each of the exits of the hole or slot 255. One end of the tab can be placed in the hole or slot 255 and the other end can extend from the side of the protective layer and wrapped over the foot. When one tab needs to be replaced, the individual tab can be removed from the hole or slot 255 and replaced while the remaining tab can remain attached to the protective layer.
With reference to
The inventive footwear has been described as relying upon adhesive regions on the protective layer to secure the footwear to the foot. However, with reference to
The inventive footwear has been described as being used with flat high performance unfashionable applications. However, in other embodiments, the inventive adhesive regions 109 can be used with more aesthetically pleasing high heel footwear 200 as shown in
The present invention utilizes adhesive regions to attach the footwear to the foot. Various different adhesives can be used with the inventive footwear. In an embodiment, a “gecko” adherence technology can be used which does not require the use of traditional tack adhesives. The adherent zone can comprise microstructures that have extensive surface area due to the size and number of microscopic hair like structures. The surface area generates Van der Waal forces sufficient for two surfaces to adhere to each other.
There are numerous advantages to Van der Waal adherent technology. If a “tack adhesive” is not used, there is no residue which can be left on either of the bonding surfaces. The bonding performance is maintained indefinitely. In contrast, the bonding performance of tack adhesives can degrade readily or only be appropriate for limited on off cycles. Tack adhesives can also require the use of chemicals and require a separate layer of material for holding the tack adhesive.
However, many tack adhesives are specifically designed for bonding to human skin. In particular, many adhesives are specifically designed for medical applications and are specifically formulated to avoid skin irritation and allergic reactions. An example of a suitable tack adhesives that can be used in the adhesive regions of the inventive footwear is 3M Medical Specialties Product Number 1504XL, Hi Tack Medical Transfer Adhesive on Extended Liner. This adhesive is a synthetic rubber and resin system that can be applied to opposite sides of a thin plastic film and cut to the required shapes of the adhesive regions. The bonding properties of this adhesive can be measured by attaching the adhesive to stainless steel and measuring the force required to remove the adhesive with a 90 degree peel. The nominal force required to remove the adhesive is 5.7 kg/25.4 mm width of adhesive.
In another embodiment, 3M Medical Specialties Product Number 1577, Two-in-One Polyester Double Coated Tape can be used for the adhesive regions. A side view of this tape 501 is illustrated in
The protective layers described above, can be many of various rigid or elastic materials. The bottom surface of the protective layer preferably has a non-skid tread which provides traction on the surfaces that the footwear is being used. The protective layer should be able to protect the foot from sharp objects and may also provide some cushioning for the foot to reduce the impact while performing activities such as running on pavements. As discussed, the thickness of the protective layer can be variable with a thicker section at the heel and a thinner more flexible construction at the forefoot portion. The protective layer can be made of multiple materials. For example, the bottom surface can be a strong wear resistant rubber material layer that provides the tread for the footwear. A layer of foam or other elastic material can be attached over the rubber material to provide cushioning for the foot. The upper surface of the protective layer can be made of a smooth material that is comfortable against the plantar surface of the foot.
The upper surface of the protective layer may have a shape that conforms to the contours of the planar surface of the user's foot. The topography of the upper surface of the protective layer may be a custom product based upon actual surface measurements of the user's foot or may correspond to a generic shape based upon the size of the user's foot. The lower surface can have a flatter profile across the width to provide better stability and a larger contact area for improved traction.
Although footwear has been described, the present invention can also be used for other functionality. For swimming, webbing extensions using the described adhesive regions increase the forces that can be applied to the feet for swimming apparatus such as adherent flippers for swimming, scuba and snorkeling. Adherent flippers can include adherent sections applied to the dorsum of the foot or forefoot to avoid separation from the foot during the upstroke portion of the swimming motion. The inventive adhesive regions can eliminates the need for a heel strap on the flippers and allows for a more conforming forefoot design.
The inventive adhesive regions on a protective layer of footwear can also be applied to other types of shoes. In an embodiment, the footwear can include abrasion resistant coverings for protecting the toes which can be part of specialty shoes used for activities such as ballet and rock climbing. In other embodiments, the protective layer of the inventive footwear can be very stiff in order to transmit more leg energy for activities such as skiing, crew and cycling. This special footwear can be equipped with specific types of cleats which can be locked into corresponding sport specific binding mechanisms. For some footwear spikes or other protruding mechanisms can be attached to the bottom of the protective layer.
With reference to
In an embodiment, the elastic layer can have a contoured upper surface that includes a heel cup and arch support that extend up above the plane of the protective layer to support the heel and arch of the foot. In other embodiments, the elastic layer may only have a heel cup but not have an integrated arch support structure. In some of these embodiments, the arch support area of the elastic layer can be flat and the arch support can be provided by a separate arch support structure.
With reference to
The upper surface of the protective layer 303 can be partially or completely covered with an adhesive. In some embodiments, the protective layer 303 can include a thin adhesive layer and a wax paper or other protective layer can protect the adhesive material from contamination before use. When the wax paper is peeled away, the adhesive is exposed, and the protective layer 303 can be bonded to the elastic layer 301.
With reference to
With reference to
In other embodiments, the arch support 305 may be secured to the foot and not directly bonded with an adhesive to the elastic layer 301 or the protective layer 303.
With reference to
In the illustrated embodiments, the arch support structure 305 coupling to the foot 309 is completely independent of the footwear 313. The bottom of the adhesive strip 311 does not include and adhesive and the arch support 305 and the bottom surface of the foot over the elastic layer 301 can slide against the elastic layer 301. The protective layer 303 can be coupled to the foot 309 at the adhesive contact points 400 which include the rear heel and the front portions attached to the MTP joint area of a foot of the protective layer 303. The perimeter of the footwear footwear 313 can be analogous to a bow that moves between flat and curved positions. The foot wear can be fully expanded in the flat position resulting in tension in the foot 309.
With reference to
With reference to
With reference to
Movement of the foot leads to a rolling liftoff force of the border of the foot relative to the plantar surface of the shoe. Failure of an adhesive shoe construct can be due to the separation of the foot surface from the adhesive surface of the shoe. In one principal mode of failure, Peel off can be derived from tensile forces applied at the edge of the adhesive skin boundary causing separation. For a fixed flat plantar surface that is hard, the natural motion of the foot leads to repetitive cyclical tensile loads applied to the boundary of the plantar adhesive surface and leads to failure. Application of raised edges places the adhesive surface at an angle relative to the tensile forces and converts the tensile force on the interface to a shear force. The adhesive layer is strongest in shear and is better able to resist the shear with repetitive loading and provide greater durability of the interface. Motion of the foot also leads to rotation of the foot relative to the upper surface of the shoe in various planes. One example is the inversion and eversion of the foot which creates a rotation moment arm of the foot relative to the shoe. This moment arm of force creates tensile forces. The raised edge also converts the tensile forces to shear and resists failure of the adhesive attachment.
With reference to
In contrast, an adhesive shoe that relies upon adhesives only on an upper horizontal surfaces may not be able to maintain contact with the foot as the foot moves in inversion and eversion. This rolling rotation of the heel, forefoot or any other portion of the foot will cause peel tension and separation from an inner or outer edge of the shoe resulting in peel away failure of the adhesive and separation of the shoe. For these reasons, the adhesives on the raised edges of the inventive footwear provide superior functionality.
The adhesive attachment of the sole to the plantar surface of the foot can fail by a principal mode of peeling off. This can occur typically by peeling from the outer edge which occurs as liftoff occurs on any area of the plantar surface of the foot relative to a horizontal adhesive surface. In contrast, the raised edge 321 adhesive contour redirects the pull off of the sole from an orientation orthogonal to the plantar surface of the foot 309, an orientation that receives repetitive loads in that orientation with gait to a position that is at an angle relative to the plantar surface and at an angle the varies circumferentially relative to the vertical Z axis relative to the user where the ground defines an X-Y axis horizontal plane. The raised edge 321 can be made of material(s) having elastic properties that allow the raised edge 321 to stretch as the foot 309 moves relative to the footwear. The shear force applied to the adhesive on the raised edge 321 during normal movement including walking and running can be well within the elastic deformation range or spring rate range of the raised edge 321 material(s) and well below the plastic deformation range and tensile strength of the raised edge 321 material(s). Thus, the raised edge 321 can function as an elastic spring that stretches to hold the adhesive footwear to the foot during foot movement.
With reference to
The present invention utilizes adhesive regions to attach the footwear to the foot. Various adhesives can be used with the inventive footwear. In an embodiment, a “gecko” adherence technology can be used which does not require the use of traditional tack adhesives. The adherent zone can comprise microstructures that have extensive surface area due to the size and number of microscopic hair like structures. The surface area generates Van der Waal forces sufficient for two surfaces to adhere to each other.
There are numerous advantages to Van der Waal adherent technology. If a “tack adhesive” is not used, there is no residue, which can be left on either of the bonding surfaces. The bonding performance is maintained indefinitely. In contrast, the bonding performance of tack adhesives can degrade readily or only be appropriate for limited on-off cycles. Tack adhesives can also require the use of chemicals and require a separate layer of material for holding the tack adhesive.
However, many tack adhesives are specifically designed for bonding to human skin. In particular, many adhesives are specifically designed for medical applications and are specifically formulated to avoid skin irritation and allergic reactions. An example of a suitable tack adhesive that can be used in the adhesive regions of the inventive footwear is 3M Medical Specialties Product Number 1504XL, Hi Tack Medical Transfer Adhesive on Extended Liner. This adhesive is a synthetic rubber and resin system that can be applied to opposite sides of a thin plastic film and cut into the required shapes of the adhesive regions. The bonding properties of this adhesive can be measured by attaching the adhesive to stainless steel and measuring the force required to remove the adhesive with a 90 degree peel. The nominal force required to remove the adhesive is 5.7 kg/25.4 mm width of adhesive.
In another embodiment, 3M Medical Specialties Product Number 1577, Two-in-One Polyester Double Coated Tape can be used for the adhesive regions. If adhesives are being used on the elastic layer, the tape can use two types of adhesives coated on opposite sides of a polyester carrier film. A synthetic rubber adhesive can be used to secure the adhesive region to the upper surface of the protective layer and the inner surfaces of the raised edges or tabs. An acrylic adhesive can be used to secure the adhesive region to the skin of the users' feet. In this embodiment, the two adhesives can have different bonding properties. For example, the synthetic rubber adhesive can provide a nominal force of 2.8 kg/25.4 mm width of adhesive and the acrylic adhesive can provide a nominal force of 1.5 kg/25.4 mm width of adhesive. This configuration can cause the synthetic rubber adhesive regions to be more aggressively bond the elastic layer to the protective layer and less aggressively bond the protective layer (and possibly portions of the elastic layer) to the foot. If the double coated adhesive tape is used on the upper surface of the elastic layer, the adhesive on the lower surface of the tape can create a stronger bond than the upper surface so that the adhesive tape will remain attached in place on the footwear and release from the foot when the foot is removed from the footwear. The synthetic rubber adhesive may also be thinner than the acrylic adhesive. Because the upper surface of the protective layer can be smooth, the contact area between the protective layer and the synthetic rubber adhesive can be very high since the adhesive does not need to conform to an uneven topography. In contrast, the acrylic adhesive may need to elastically conform to the skin surface which can be an uneven surface. A thicker layer of acrylic adhesive can allow a better interface between the skin and the adhesive. In other embodiments, any other suitable materials can be used for the adhesive regions.
With reference to
With reference to
With reference to
With reference to
With reference to
The protective layers described above, can be many of various rigid or elastic materials. The bottom surface of the protective layer preferably has a non-skid tread which provides traction on the surfaces that the footwear is being used. The protective layer should be able to protect the foot from sharp objects and may also provide some cushioning for the foot to reduce the impact while performing activities such as running on pavements. As discussed, the thickness of the protective layer can be variable with a thicker section at the heel and a thinner more flexible construction at the forefoot portion. The protective layer can be made of multiple materials. For example, the bottom surface can be a strong wear resistant rubber material layer that provides the tread for the footwear. A layer of foam or other elastic material can be attached over the rubber material to provide cushioning for the foot. The upper surface of the protective layer can be made of a smooth material that is comfortable against the plantar surface of the foot.
The upper surface of the protective layer may have a shape that conforms to the contours of the planar surface of the user's foot. The topography of the upper surface of the protective layer may be a custom product based upon actual surface measurements of the user's foot or may correspond to a generic shape based upon the size of the user's foot. The lower surface can have a flatter profile across the width to provide better stability and a larger contact area for improved traction.
Although footwear has been described, the present invention can also be used for other functionality. For swimming, webbing extensions using the described adhesive regions increase the forces that can be applied to the feet for swimming apparatus such as adherent flippers for swimming, scuba, and snorkeling. Adherent flippers can include adherent sections applied to the dorsum of the foot or forefoot to avoid separation from the foot during the upstroke portion of the swimming motion. The inventive adhesive regions can eliminate the need for a heel strap on the flippers and allows for a more conforming forefoot design.
The inventive adhesive regions on a protective layer of footwear can also be applied to other types of shoes. In an embodiment, the footwear can include abrasion resistant coverings for protecting the toes which can be part of specialty shoes used for activities such as ballet and rock climbing. In other embodiments, the protective layer of the inventive footwear can be very stiff in order to transmit more leg energy for activities such as skiing, crew, and cycling. This special footwear can be equipped with specific types of cleats which can be locked into corresponding sport specific binding mechanisms. For some footwear spikes or other protruding mechanisms can be attached to the bottom of the protective layer.
The present invention is substantially different the various known prior art references. U.S. Pat. No. 2,985,970, “Shoes and Means of Attaching Them”, E. F. McCarthy discloses a hard shoe with a thick sole. The shoe disclosed by McCarthy includes a hard shoe with adhesive material over the arch of the foot. The shoe has segmental with heel and in ball and toe region but not in lateral border of the metatarsophalangeal (MTP) joint first and fifth and the lateral border of the foot. The shoe disclosed by McCarthy does not function as described.
In contrast to McCarthy, the present invention is directed towards a shoe device that is fully functional and the result of extensive experimentation. Based upon experimental testing, the segmentation of the adhesive footwear components was developed and proven. Specifically, rather than footwear that simply has an adhesive attachment to the foot, the present invention is directed towards only attaching the footwear to the foot with adhesives located at specific locations. In most embodiments, the present invention specifically avoids applying adhesives on the arch and toes of the foot. In an embodiment, it can be possible to attach the arch support to the foot with an adhesive if a hydrogel and the elasticity of the arch support substrate matches the shear properties of the arch. However, without this configuration, the adhesive attachment of the arch support to the arch portion of the foot will be uncomfortable. The prior art does not anticipate that adhesive should not be applied on the arch or toes of the foot. These negative limitations were discovered by empiric trial and skin reaction to shear and discomfort. Similarly, the empty toe embodiments of the present invention are based on empiric data from the discomfort of the application of adhesive to the plantar surface of the toes. The known prior art also does not disclose or suggest adhesive footwear having raised edges or a recessed toe plate to clear in the swing phase of gait to provide apparatus functionality, not for cosmetic reasons. The raised adhesive edge provides stability in fixed locations and can be critical for proper functionality.
It will be understood that the inventive system has been described with reference to particular embodiments, however additions, deletions and changes could be made to these embodiments without departing from the scope of the inventive system. Although the order filling apparatus and method have been described include various components, it is well understood that these components and the described configuration can be modified and rearranged in various other combinations and configurations.
This application is a continuation-in-part of U.S. patent application Ser. No. 15/068,363, “Adhesive Footwear And Devices” filed Mar. 11, 2016, which is now U.S. Pat. No. 10,383,399 which is a continuation in part of U.S. patent application Ser. No. 13/886,600, “Adhesive Footwear And Devices” filed May 3, 2013 which is now U.S. Pat. No. 9,462,849, which claims priority to U.S. Provisional Patent Application No. 61/642,059, “Adhesive Shoe And Devices”, filed May 3, 2012. U.S. patent application Ser. No. 15/068,363 also claims priority to U.S. Provisional Patent Application No. 62/132,503, “Adhesive Multi-Layer Footwear” filed Mar. 13, 2015. U.S. patent application Ser. Nos. 15/068,363, 13/886,600, 61/642,059 and 62/132,503 are all hereby incorporated by reference in their entirety.
Number | Name | Date | Kind |
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1512218 | Goldsmith | Oct 1924 | A |
2409594 | Sherman | Oct 1946 | A |
2985970 | McCarthy | May 1961 | A |
6120473 | Oliverio | Sep 2000 | A |
8216162 | Bushby | Jul 2012 | B2 |
20040006814 | Holden | Jan 2004 | A1 |
20040118020 | Hlavac | Jun 2004 | A1 |
20060265903 | Strong | Nov 2006 | A1 |
20150018741 | Lieberson | Jan 2015 | A1 |
Number | Date | Country | |
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62132503 | Mar 2015 | US | |
61642059 | May 2012 | US |
Number | Date | Country | |
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Parent | 15068363 | Mar 2016 | US |
Child | 16546110 | US | |
Parent | 13886600 | May 2013 | US |
Child | 15068363 | US |