Patent Application
20140079900
The present invention relates to general use apparatus, and uses thereof, used in general use activities, as well as in playing the game of various sports. The present invention and its embodiments can, among other things, enhance the overall performance in arm tasks conducted by the wrist, forearm and/or bicep areas, as well as hand tasks, by offering a grip enhancing means on the top surface of said embodiments. These embodiments are attached to an individual by an adhesive means on the bottom surface, thereby providing, among other things, said individual with enhanced grip and/or control capabilities. General use embodiments may also be secondarily attached to something already on the skin, such as a band aid, bandage, gauze, sport pre-wraps, or an arm pad, and the like. Embodiments may additionally benefit users to, among other things, protect an injury, and/or protect from injury, by also offering a medicated additive and/or a shock-absorbing member.
Grip and control enhancers have come a long way in assisting one to complete a task or goal. Many tasks, for example, may be divided into arm tasks and hand tasks, and successful completion of said tasks often require the ability to properly grip or control an object.
Arm task grip enhancers could assist an individual complete a sport objective. An important goal in playing sports is to win. Often that means proper play execution, proper form in the sports fundamentals and especially good ball control. Many of these tasks are performed by the hand, but are often also performed, to some degree, with parts of the arm (the wrists, forearm, elbow and bicep areas). Ball control and therefore proper play execution depend on adequately using the parts of the forearm, elbow and/or bicep areas to handle, strike, control or otherwise maintain possession. Inadequate play execution can result in inconsistencies and turnovers, both long standing problems in many sports, and can often determine the outcome of a game.
In the sport of football, for example, lack of play execution is often categorized by turnovers, fumbles and incomplete passes. This is of particular concern to those players that have to control a football such as running backs, receivers, tight ends, kick returners, punt returners and even quarterbacks. Athletes that play any of these positions are often asked, in some way, to run, catch, throw or otherwise control a football. Successful play execution—which in the case of football includes minimizing fumble, incompletes and inconsistencies—can often be the difference in the successful outcome of a team's objective. Creating and maintaining a solid and stable control of the ball is therefore essential in proper play execution and performance.
In football, as in many other sports, controlling a ball is often done not just by using their hands, but by using other parts of the body as well.
A football running back, for instance, might be particularly concerned with not fumbling the ball. A running back's performance is measured not only by his yards per carry but also in his ability to minimise his fumbles. Unfortunately, one need only view the statistics to see that fumbles persist as an insoluble problem, even at the professional level today.
Part of the problem lie in the seemingly inherently unstable way a player controls and cradles a ball when running. Proper ball handling technique is to grab one end of the football with your hand, and then resting the ball on the forearm of the same arm. As you begin to run with the ball, you may also place the opposite end of the ball (the end that is not being held by the hand) in the inside elbow area, between the forearm and bicep, and the ball is almost always touching the wrist area. Although prior art exists to increase grip around the hand in the form of gloves, these gloves do little to increase ones grip in the general arm area, such as the wrist, forearm, elbow and bicep areas. The development of a product which could enhance one's grip-enhancing abilities on, say the forearm area, would therefore go a long way to solving this significant problem.
Football players who catch a football (hereinafter called ‘receivers’) might be particularly concerned with making a catch and completing a reception, and being able to control a ball with the arm area. Enough skill and precision must take place in order to get the ball from the quarterback to a receiver; timing, stable footing, and protecting the ball just to name a few. When a receiver first catches a ball, he usually brings the ball onto his arm, thus holding the ball with the hand, as well as the forearm and elbow area. Prior art is lacking that enhances the elbow grip or the elbow area, an area that plays a significant role in proper play execution. Passing the ball is a significant part of the sport of football, sometimes throwing as much as 103 times in a single game (Seattle vs. San Diego, 2002). Thus, developing a solution to enhance one's ability of better controlling a catch and completing a pass reception would substantially impact the sport.
Additionally, inconsistencies, or incompletes, often arise when a ‘stress factor’ is introduced once a receiver first touches and places the ball on their arm area. This problem is so pronounced that many instant replay situations revolve around seeing whether the ball moves even slightly in the receivers arm—including the forearm which has no real grip enhancers. Again, because prior art (such as gloves) primarily provides grip enhancing support only around the hands, and not around other areas of the arm responsible for holding and controlling the football from moving, the receiver can often have great difficulty in keeping the football from moving. As such, an unrecognized problem currently exists because it is very difficult to grip a ball with parts of the arm.
Clearly, maintaining good ball control is important. In football, unstable or weak ball control can, among other things increase fumbles, increase incompletes and thereby increase turnovers and decrease performance.
There have been some attempts through the years to solve the problems of inconsistencies and turnovers in the sport of football. For example, changes have been made to the actual football in order to make the ball easier to handle. Changes to the shape and size, as well as the addition of grip enhancing materials to the ball—such as the addition of PVC dots—have made it possible to make the ball more grippable. The ability of the player to maintain control of the football was still problematic because of the lack of any grip enhancing device for the player to use; devices that could be placed on the arm such that the player could now more significantly control a ball with his arm, thereby creating an overall grip of the football throughout the football. As a result of this unmet need, inconsistencies and turnovers were still high in the sport.
The introduction and subsequent proliferation of the use of gloves found some success but even with these advancements, however, fumbles and incompletes still persist today. For one, whereas a running back who uses a grip enhancing glove will be better able to properly grip a football by using his hands, his hand, and therefore the grip enhancing device, only cover the front part of the ball, leaving the rest of the ball, and therefore the overall grip, still significantly unstable. One need only add a stress factor and this currently unstable hold on the ball can easily result in a fumble.
Good ball control is so important in football that inventions were created and widely used to enhance the gripping abilities of an individual's hand. Unfortunately, significant grip improvements stopped with the hand gloves. Improvements have lacked in assisting the rest of the arm to better handle a ball. Improvements have lacked in providing enhanced gripping support around the forearm area, an area that plays a major role in maintaining control of a ball when a receiver is completing a reception. Improvements have lacked in offering a player the ability to achieve an enhanced grip capability throughout the general arm area, where the ball touches the player (such as the forearm, elbow and bicep area). Improvements have lacked in increasing one's grip around the wrist area (an area that almost always touches the ball when cradling the ball), nor have there been advances to significantly increase ball control around the elbow or bicep areas.
Providing such a device would certainly allow a player to have a much stronger grip throughout and around the ball, to create a more stable overall handle on the ball, and therefore to significantly advance arm task performance and play execution. Not only would new art offer benefits to running backs, receivers, tight ends and quarterbacks, but they could also increase the performances of kick returners and punt returners, who have to run with the football.
These grip-enhancing shortcomings make it no surprise that there were a total of 731 fumbles, and the highest quarterback completion rating was less than 70 percent, in the 2010 NFL Season (Official Stat Book of the NFL, 2011). Given the fact that fumbles and incomplete passes persist at the professional level and therefore certainly at the collegiate and amateur levels, one can see that past attempts to solve these problems have had limited success.
An example of another sport in need of grip enhancers for the arm area is Volleyball. Here too, ball control is crucial to play performance. Play execution often depends on one's ability to control a ball with multiple parts of the arm, but especially the forearm. Although there are forearm, elbow and even bicep devices that could be used for protection, or simply for aesthetic purposes, no prior art exists that would enhance ball control or grip in said areas.
When an opponent strikes a volleyball to your team's side of the net, the first player to normally touch a ball—when the ball isn't blocked at the net—generally controls the ball with her or his forearm(s). With that first touch contact, one must be able to stabilize the ball, and then usually pass the ball to a teammate. Unfortunately, this current method of passing a volleyball can provide inconsistent results. First, the initial contact control is generally with the skin of the forearm of the player, and without any grip-enhancing device on the forearm, it can become very difficult to redirect a volleyball with consistent precision. Although the initial contact happens very fast, a control-enhancing mechanism which could be firmly attached to the arm area would have a significant impact on the sport. Additionally, a more general reason for inconsistencies is in one's inability to grip with one's forearm. Without providing the forearm with some way to better grip a volleyball, inconsistencies in the sport of volleyball will continue to be a long-standing problem.
More generally, there are clear indications that an entirely new market exists for targeted grip enhancers that could be attached (using an adhesive means) only on select areas of the arm area.
Not only are there significant needs for grip-enhancing devices for the arm area, in particular the wrist, forearm, elbow and bicep areas, but there is also a significant need for better grip-enhancing devices for the hand area as well. Although offering some advantages, using prior art—such as gloves for the hand—creates disadvantages that often force an individual to choose not to use any grip enhancing device at all.
There are several non-sport activities, for example, in need of targeted hand grip enhancers for general use.
As an example, there are several indoor activities where there is an unrecognized need for hand task enhancers. Activities requiring prolonged hand movements, such as sweeping, mopping, and general house cleaning often require one to grip and/or otherwise control an object. Many choose to conduct these tasks bare-handed often because they don't need all the protection from injury or from grime usually associated with having to use a glove. Many brooms, mops and other household devices however, do not have a grip enhancing component on their handles, leaving an opportunity to provide a non-industrial strength grip enhancer, such as perhaps a gripping means for the hand, which can enhance only the part of the hand that requires grip enhancers without encumbering the rest of the hand. This could result in significant increase in overall ease of use and therefore increased cleaning performance.
Many basic home repair activities requiring tools, such as hammers and wrenches, are often completed using bare hands (especially when the repair work is done indoors). Many individuals choose not to spend the money on expensive construction gloves, and instead choose to forgo any extra grip enhancers—or protection—and complete the task bare-handed. A result, with prolonged use, often can be the development of blisters on parts of the hand areas. There therefore is an opportunity to provide a relatively more cost effective and convenient solution whereby an individual could complete these hand tasks. Offering a product, such as a new type of tape which could be attached to an individual's skin or onto a skin-contact product already on the human body (such as bandages or pre-wraps), could therefore also protect an individual from injury (such as from getting a blister).
The use of gloves has other drawbacks, especially when water is involved. Unless one buys expensive swimmers-type gloves that are waterproof, one is usually forced to go without any grip enhancers when conducting activities involving water. Providing, therefore, a cost-effective waterproof grip enhancer would certainly meet a currently unmet need.
Improved art is also desired to support outdoor yard work. Quite often one chooses to use gloves for outdoor yard work. Although it does protect ones hand from injury and grime, at times one finds that they have to take off the gloves momentarily, especially during the hot summer months because of the perspiration building up on the hand from the use of gloves. This inconvenient and unnecessary problem is created because of lack of ventilation in many yard gloves. When the yard work requires intense activity, then the gloves are worth the hassle, but very often the yard work is not very demanding. For example, when one has to control a shovel or rake, the work is often not very demanding but it is very repetitive. The choice that one faces is to either wear a glove for the added grip, but then have to stop a few times to take the gloves off and dry your hands, or choose not to use a glove at all. One result, at times, is that one chooses to wear a glove because of a lack of an alternative that might possess many of the advantages of wearing a glove but without any of the disadvantages.
More generally, there are clear indications that an entirely new market exists for targeted grip enhancers that could be attached (using an adhesive) on select areas on the hand, leaving other parts of the hand uncovered. These grip enhancers could be attached to the skin of an individual or could be attached to something already on an individual (such as over a bandage). These new grip enhancers would also find success if they also offered a therapeutic additive layer to protect an injury or to help protect from injury.
Another particular area where prior art poses significant disadvantages is in any sport where a player's success depends on her ability to both grip as well as feel a ball or object. These players often have to choose between wearing a glove thereby enhancing grip but losing significant feel, or going without a glove thereby maintaining maximum feel but missing the opportunity to enhance one's grip.
In football for example, gloves can be used to enhance performance. The use of gloves in football is so widespread that nearly every football player uses them, with the notable exception of football quarterbacks. You rarely see a quarterback wear gloves, even if just to keep warm. Most quarterbacks choose to play football without gloves. This is largely because prior art consists of generic full-fingered gloves which are uncomfortable and burdensome on a quarterback's dominant (throwing) hand, particularly on those fingers a quarterback places over the football laces. In addition, the full-fingered gloves prevent a quarterback to have any ‘feel’ of the ball, a necessary element in a quarterback's success.
Playing the position of quarterback without any grip enhancing mechanism, however, can also be an inferior choice. The website Wikihow.com, provides a good description of the conventional way to hold and throw a football. “Throwing the football is simple. Put your non-throwing side foot in front of you. Have your Pinkie, Ring and Middle fingers around the laces with your Index [Forefinger] finger on the strap. Put the other hand up on the ball. Put the ball up by your ear. Twist your hips toward the front foot. Throw the ball at the receiver.” Whereas, the fingers over the laces have a solid grip on the ball—primarily due to the football laces on the ball—the two fingers off the laces (forefinger and thumb) are virtually unsupported and therefore have a relatively weaker grip, creating a weak overall grip on the football.
This weak overall grip becomes more pronounced when added stress is placed on the Thumb or Forefinger. When a quarterback, intending to pass the football, for example, suddenly has to scramble, or if the quarterback ‘pumps’ the ball (goes through all the motions and speed of throwing the ball but doesn't actually release the ball), the grip strength of the Thumb and Forefinger can determine whether or not a quarterback fumbles the ball. Also, if one performs a simple test and wets his/her dominant hand, and then grabs and pumps a football, the Forefinger and Thumb will often move or slip. On a wet football field, during extreme weather conditions (hot or cold), that weaker or looser grip makes for a much more difficult completed pass, less success at throwing a spiral, and inconsistency and inaccuracy in passing.
Under the ‘tips’ section of Wikihow.com, it further describes proper football throwing form: “A proper throw will feel like it's only utilizing the Thumb, Index [Forefinger], and Middle finger. Good release will ‘roll’ off of your Index and Middle finger, to impart more spin; you may snap your wrist through as you follow through to the hip. The other three fingers on your hand stabilize the ball as its being flung. They should not be used to impart spin on the ball. The most important finger to throwing a spiral is the Index finger; it is the finger that holds the most leverage in putting spin on the ball.”
This need to ‘feel’ a ball with a hand has therefore resulted in quarterbacks having to make a difficult choice. Although clearly these players would benefit from added grip enhancers on the throwing (dominant) hand—especially supporting the forefinger—prior art (in the form of gloves) force a quarterback to choose between all feel or no feel. Virtually all quarterbacks have chosen to maintain feel and sacrifice the ability to better grip the football. It is no surprise that quarterback fumbles remain a significant problem in football, even at the highest performance levels, and currently remains an insoluble problem in the sport for amateurs and professionals alike.
Individuals who play basketball also have to ‘feel’ and grip a ball to perform properly, and although they too could significantly enhance performance in controlling a ball, prior art forces them to choose all feel as well, and go without any type of grip-enhancers at all. This insoluble problem therefore also exists in playing the sport of basketball, and these players would substantially benefit from developing a way to maintain feel while increasing grip capabilities in select areas of the hand. More specifically, new art is needed that could offer control enhancers in certain locations of the hand while leaving others areas of the hand uncovered and therefore being able to maintain necessary feel.
In the field of Golf, to be sure, there exists much prior art in the form of gloves for a golfer's weak (non-dominant) hand. In fact most active golf players wear a glove on their weak hand, and go without a glove for their strong hand (if one were to go to any major store to buy golf gloves, they would be sold and packaged in singles—one glove—not sold in pairs). Gloves are prevalent in golf largely because of the role that hand grip and control play in a golfer's overall performance.
Although there exist many types of full-fingered gloves for a golfer's weak-hand, they all attempt to maximize a golfer's weak-hand grip without regard to a golfer's weak-hand feel, and hand coordination needs. It is no surprise, therefore, that prior art consists of full-fingered (all fingers are covered), closed palm (entire palm is essentially all covered) gloves. As a result, a typical golfer must rely on his/her weak-hand to provide most of the grip support, and on his strong-hand to provide all of the ‘feel’ in his golf swing. The current solution to this insoluble problem has been for virtually all golfers to use one and only one glove. This glove is always placed on the weak hand, leaving the strong hand without a glove. There is, therefore, an opportunity to invent a device or method that could offer some ‘feel’ ability for the weak-hand, without significantly diminishing that enhanced grip ability that gloves offer. This would increase overall hand control of a golfer's club swing, and therefore result in greater success in competition.
Whereas weak-hand support products seem to be crowded in the sport of Golf, there is a long existing need for a device that could offer added support for a golfer's strong-hand without significantly diminishing its ability to adequately feel the golf club. Inventing a solution to this problem could, among other things, allow for greater golf swing control and consistency, and create an entirely new market because golfers currently do not use grip-enhancers on their dominant hand, thereby changing the way that golf is played.
In Golf magazine's April 2005 article titled “Fix your grip. The wrong grip can cripple your swing—Here's the cure”, golf instructor Charlie King provides an overview of how to grip a golf club. “Good golf starts with your grip. The proper hold on the club helps you do three crucial things: Hinge your wrists, control the clubface at impact and support the club throughout the swing. Here are three simple grip tips.” As King continues, his third tip is “both hands; solid at the top. An effective grip sets the face square at the top, with the shaft parallel to the target line. You should feel most of the club's weight in your left Thumb and right Forefinger. Now you're ready to turn it loose.” Although prior art seems to be crowded in offering gloves for the weak-hand, to support and better control the club weight placed on the Thumb of the weak-hand, there remains an unmet need for added support on or around the Forefinger of the strong-hand.
Additionally, constant swinging of a golf club at real swing speeds often results in soreness on and between the Thumb and Forefinger of a golfer's strong hand (wearing no glove). This soreness can often also come from the rubbing or slipping, between the club handle and the strong-hand, suggesting a need to find a way to increase the grip—as well as protection—of a golfer's strong hand. This is especially important in the sport of golf because even the smallest of slipping—during the golf swing or upon impact of the golf ball—can create enormous inconsistencies and inaccuracies, critical issues in determining overall performance.
Consequently, there are clear indications that an entirely new market exists for targeted grip-enhancers that could be placed only on select areas of the strong (dominant) hand, leaving other parts of the strong hand free to feel. In particular there remains an unrecognized problem and an unmet need that would provide multiple benefits, such as better overall grip, more coordination with both hands, as well as some protection from, for example, any constant grip slipping, during the practice or play of golf; and in various other sports activities.
In the sport of Basketball, there exists no prior art when it comes to attachable grip-enhancers to enhance the performance of over 100 million individuals who play the sport. Although there are several multisport gloves in the market today, virtually no one uses gloves when playing basketball. A primary reason why basketball players choose not to use gloves, as mentioned briefly above, is similar to the issue with football quarterbacks, basketball players often need to be able to both grip and feel the ball. Although many hand tasks require a good grip, no art currently exists that would provide these players with enhanced grip capabilities or enhanced protection by being able to cover only select parts of the hand, without having to sacrifice the critical feel ability along other parts of the hand.
One clear hand task in basketball is in shooting the basketball with the intention of making a score or basket. Conventional jump-shot shooting form requires, among other things, that the player hold the basketball largely with the fingertips of both hands, and creating a small opening—or a shooter's gap—between the ball and the palm area of the player's strong-hand. No grip enhancers exist that would increase the gripping abilities of a players fingertips and leaving the rest of the hand free to feel if the basketball is touching or violating, for example, the shooters gap.
Prior art is lacking that would provide an athlete with the ability to have enhanced control when dribbling a basketball. Proper dribbling form is to rarely, if ever, look at the ball while dribbling said ball—thus one of the critical reasons of being able to maintain high ‘feel’ ability. Without any extra grip-enhancers however, it is difficult to maintain stable control of the basketball.
A typical game—even a professional game—often can have as many as 30 turnovers (combined), so offering art that could increase ball control while dribbling, passing or even catching a basketball could significantly enhance performance by, among other things, minimizing turnovers. Minimizing turnovers, for example, could be achieved by offering better ball control while dribbling a basketball. Those players playing the position of Guard may benefit from added grip support especially because they may need to dribble, at least briefly, with either hand.
Although athletes playing the position of Forward or Center would also benefit by enhanced dribbling abilities, most of the turnovers caused by Forwards and Centers are often the result of dropping passes thrown to them, or from making a bad pass. Offering art that would enhance the ability to better pass or catch a basketball could therefore also enhance overall performance for anyone playing the sport of basketball.
Another hand task in basketball is in slamming a basketball through a basketball hoop (commonly known as slamdunking). When one slamdunks a basketball it is often done with force and almost always involves striking a metal basketball hoop with at least one of your hands (mostly impacting the fingers). For Forwards and Centers especially, this hand task can quickly take a toll on their fingers if their fingers are not somehow protected. The current—and only—method of enhancing this hand task is by applying basic sports tape to select finger joints. This current method and product has significant shortcoming that often result in inferior execution. For example, if one tapes parts of ones hands with the prior art, they will lose any grip capabilities in that area, which could then result in mishandling the basketball (a significant issue with Forwards and Centers). Better devices and methods of providing added protection while slamming while not sacrificing ball control would significantly impact the sport of basketball.
Other general hand task challenges that are in need of a better solution have to do with basketball players who injure, in some way, their hand. In this situation the player has to tape their hand (or wear some sort of medicated bandage), especially when injuring a finger. The result again is a decrease in ball control and limited protection. To protect the injury, most players will choose to tape the finger and try to adjust. Loss of dribbling control often results, as does loss of ball control when preparing to shoot the ball (as seen when the ball slips out of the players hand and flies up in to the air as they are shooting the ball). If a player injures herself, the player will have diminished gripping capabilities if she uses prior art to cover and protect that injury. Additionally, athletes often can stress joints beyond their limitations. Injuries can result when limbs are bent beyond the natural elastic limitations of tendons and muscles. Adhesive tape is commonly used as a propylaxis. Tapes are therefore also used to protect from injury or to protect one from further injury.
Therefore, new art which could both protect an injury as well as provide a grip enhancing element (such as PVC dots on the outer surface of the invention) could have a significant and substantial impact on the sport.
In general the present invention offers task enhancers for the arm, the hand and in select areas of the arm and/or the hand. These arm and hand task enhancers can be attached to the individual, and thereby increase, among other things, the grip capabilities of that area. The present invention offers a general purpose grip enhancer that could be attached to an individual using an adhesive means on one side of the present invention, and comprising a gripping means, on the other side of the present invention.
According to one aspect of the invention, the present invention is an adhesive article having an adhesive on the inner side (or bottom surface) which would touch and adhere to the arm or hand of an individual. The article would have a gripping means, such as, for example, PVC dots, on the outer side (or outer surface) of the article. The gripping means permits the individual to better grip an object or device once the article is attached to the individual by the adhesive on the bottom surface. The present invention could to configured to attach directly to the skin of the human body, or attach to an item already on the human body. The gripping means can be formed by, for example, embossing the top surface to create the gripping means, such as irregular depressions of, say, at least 300 micrometers in depth. The adhesive layer on the bottom surface can be coated, for example, with a pressure sensitive adhesive based on natural or synthetic elastomers, such as amorphous polyolefins.
In another preferred aspect, the present invention is comprised of, for example, athletic tape which includes a therapeutic layer comprised of a medicated additive on the bottom surface, such that the tape can be used to, for example, protect an injury or to protect an area from being injured. The present invention would then offer the unique ability of being able to protect an injury without minimizing grip capabilities in said areas, a significant and substantial advancement to prior art, such as bandages and BAND-AID. These embodiments, as will also be discussed, may be achieved by, for example, coating a portion of the bottom surface of the embodiments. The adhesive composition of the present invention may be prepared using standard methods. For example, the adhesive composition may be prepared by uniformly mixing the raw materials by a convention mixing method. For example, the amorphous polyolefins, the medicated additive, etc. are mixed with a mixing apparatus such as a homomixer or a planetary mixer to homogeneously dissolve or disperse the materials to obtain the liquid composition. It is then applied using standard methods, as mentioned herein.
Embodiments can additionally benefit users to, among other things, protect an injury, and/or protect from injury, by offering a shock-absorbing member within embodiments of the present invention. The shock-absorbing member may comprise foams including but not limited to open-cell or closed-cell foams, such as BOLLARD foam, polyolfin foam, polyurethane foam, and the like. Additionally, the foam may possess a substantially uniform cell distribution.
In a further preferred aspect, embodiments can comprise one article, or may be configured as improvements to athletic tape by creating a second layer, comprised of the grip-enhancing means, and then bonding said second layer to the athletic tape, using heat sealing or other methods.
In still a further preferred aspect, embodiments can be comprised as a significant improvement to specialty athletic tapes, such as Kinesiology tape and Bio-tape, by providing a high friction means on said tapes.
Embodiments of these grip enhancers can, for example, increase the overall performance in arm and/or hand task activities, by allowing an individual to better control, for example, a ball or object. Embodiments can offer grip enhancing capabilities for the arm area, in particular, for example, the wrist, forearm, elbow and bicep areas, as well as for the hand, including the fingers of the hand, and methods thereof. Additionally, embodiments can also offer unique benefits by offering the ability to better protect an injury or to better protect from injury.
The adhesive means of the present invention could comprise various types and tensile strengths of adhesives configured to ‘stick’ to an individual or to an item that is placed on an individual. Adhesives used skin contact adhesive products, for example, by ASSURED LONG LASTING ADHESIVES, or BAND-AID BANDAGES, could provide sufficient tensile strength for many embodiments of similar size as the above mentioned popular products. For larger embodiments, such as adhesive articles with wider widths, adhesives used by SALONPAS patches could provide the necessary bonding capabilities. Embodiments may include, but are not limited to, pressure-sensitive adhesive designed for removable application such as acrylic based and dextrin based adhesives, and/or that are configured for conventional athletic tapes that attach to a skin region of the human body.
The gripping means of the present invention can comprise of, for example, various grip-enhancing materials, forms, coating and designs including, but not limited to, foams, fabrics, PVC dots, perimeter patching designs, linear and non-linear grooves, or combinations thereof. Other grip-enhancers include high friction surfaces, textured surfaces, a plurality of regular or irregular projections, a plurality of regular or irregular depressions, non-slip materials such as eighty grit Emory cloth for example, coatings and designs, pebbled or beaded surfaces, convex or concave bumps, striations, cross-hatches, convex or concave linear and non-linear lines, angled ribs, random structures (such as described in
The present invention may comprise of various colored and multi-colored materials, forms and designs including, but not limited to, fluorescent and reflective coating.
Some embodiments may comprise various types of materials, forms, and designs usually associated with the production of gloves, including, but not limited to, stretch materials and designs, mesh fabrics, recycled and flexible materials, cottons, polyester, rayon, spandex, fleece, synthetic leathers, rubbers, plastics, or combinations thereof. Many of these embodiments may be, for example, generally elastic, although some portions on the top surface, comprising the gripping means, may be rather non-elastic while the rest of the embodiment is elastic (thus allowing the ability of the user to attach the embodiment and wrap the embodiment around part of the arm area). The user wrapping, say the forearm, would then wrap the embodiment is such as manner such that the rather non-elastic portion of the embodiment is located in the area of the forearm where a ball, say a football, often touches, thereby increasing the grip capabilities when carrying the ball
Many other embodiments are constructed with standard athletic tape materials, such as, for example, woven fabrics, non-woven fabrics, or combinations thereof. Many of these embodiments are therefore generally flexible but not very stretchable. The grip-enhancing means may be formed on, for example, or may be an integral part of the athletic tape construction.
Embodiments may also comprise various weather-resistant and perspirant-resistant materials, forms and designs including, but not limited to, water-resistant materials or hole designs for moisture management, or combinations thereof.
Embodiments would not be seen as permanent grip enhancers, which is to say that they would not generally be expected to last for more than a week or two once attached to the individual. Embodiments could, however, be configured to last more than a few hours with active use. Additionally, the adhesive used are not structural adhesives; these structural and industrial adhesives are not intended for nor would they be successful if placed on the human body.
One sport where said present invention will clearly enhance performance is in the sport of football. For example, one particular unmet need that a grip-enhancing device for the arm area will satisfy, is with receivers. Embodiments could offer greater consistency and enhanced performance in football activities. For example, an embodiment of the adhesive article, in the form of a wrap, could be attached to the elbow area, and then another piece of the wrap embodiment could be attached to the bicep area. The grip-enhancing means could be in the form of a grip-enhancing design such as several grooves throughout the outer surface of these embodiments. These embodiments would enhance a player's ability to better absorb impact from the ground or from a defender—without losing control of the ball. Additionally, they would minimise the possibility of the football moving once in the receivers grasp because, among other things, grip capability has been enhanced throughout the arm. These embodiments would, of course, be used to better grip said football throughout the arm area by using these embodiments to squeeze and grasp the ball on both tips, or ends, of the ball. A preferred width of these embodiments could for example, generally begin around two or three centimeters, but could just as easily range from four to nine centimeters and more; additionally, they could be crafted with a blend of polyester and LYCRA spandex for added durability and flexibility.
The grip-enhancing means could preferably cover at least 70 percent of the outer surface. These high performance sports adhesive wrap embodiments would offer enhanced overall control stability and offer a high tensile strength adhesive on the bottom surface to attach securely onto the body, and therefore assist athletes more successfully perform athletic tasks. Suitable adhesives could be those used in prior art athletic tape, such as that used on MCDAVID ATHLETIC TAPE. Embodiments may be spooled, for example, perforated about every inch or so, have a liner to protect the adhesive from drying until ready for use, and be about 75 inches in length, for example.
Embodiments could also significantly improve the performance of running backs, or any player that runs with a ball. One embodiment of the present invention, comprising of tape with a more narrow width for example, would allow a player to significantly increase his ability to control or cradle a ball when running. This embodiment would be attached on the wrists to help stabilize control, thereby supplementing a grip from any glove that might be currently available and in use. Many of these embodiments could be made of material used to manufacture standard sports tape. These flexible but not necessarily elastic embodiments could offer PVC dots to provide enhanced grip capabilities on the outer surface, and an adhesive typically used in sports tape, on the bottom surface, to provide the sticking means to attach to the wrists. The adhesive can be coated at with a skin-contacting adhesive, such as, for example, from a group of acrylic based, dextrin based, or urethane based adhesives. The coating would cover the entire bottom surface, or at least part of the bottom surface (for embodiments that also offer therapeutic additives on the bottom surface for added benefits). Embodiments may have the adhesive deposited onto the bottom surface, in a continuous or discontinuous pattern rather than as an overall coating, if desired.
Embodiments could also be used as a grip enhancer around the elbow area. Specifically, for example, two embodiments could be used in combination; one could be placed just below the elbow area and the other just above the elbow area, to create the ability of literally grabbing one end of the football with the elbow. These embodiments could be comprised of rubber, much like that used to manufacture a standard sports glove. Clearly, this would create a much greater, more stable overall grip because one would now have grip enhancers to increase one's grip on both ends of the football, with a glove on the hand holding one end of the football, and the grip enhancer embodiments on the elbow area holding the other end of the football.
More specifically, an embodiment for the forearm could comprise, for example, a sports tape with a wider width, say about seven to ten centimeters. The embodiment for the forearm would, for example, include a high friction outer surface as the gripping means comprised of a pattern which could be formed on, for example, a vinyl material, and would preferably be provided on at least one centimeter of the outer surface and more preferably extend throughout the entire outer surface of the embodiment. The embodiment for the elbow area could comprise, for example, a sports tape with a more narrow width, say about 1.5 to three centimeters. This embodiment would include a plurality of projections on the outer surface as the gripping means formed from, for example, one of a vinyl material, a rubber material, or a neoprene material. The projections would preferably be provided on at least one centimeter of the outer surface and may extend throughout the entire outer surface of the embodiment. The projections could preferably extend out less than 1/10 of a centimeter, but could range generally from ¼ of centimeter to a millimeter. Both the forearm embodiment and the elbow embodiment could be attached directly to the elbow and forearm by placing the bottom surface of these embodiments directly to the forearm and elbow area. The inner surface, having the adhesive, would then adhere to the skin. Preferably, the inner surface could also be attached to skin-contact products as well, such as bandages, dressings, BAND-AIDS, patches, and the like. The inner surface could comprise an adhesive, the adhesive composition containing, for example, a crystalline polymer, such as acrylic polymer.
These two embodiments could provide many benefits to the user. For example, by applying these embodiments to the forearm and elbow area, the football player can now use the high friction grip enhancer on the elbow embodiment to control the football and minimize ball movement at both ends of the football (and not just at the end where the football player grabs the football with his hand), while maintaining more overall stability controlling the ball with the projections on the forearm embodiment. These embodiments could, in some respect, be considered more like a glove tape: A tape with many of the benefits offered gloves—enhanced grip capabilities as well as enhanced protection, and comprised with the same materials used to construct a performance gloves—but having a significantly different physical structure. This physical difference allows the user to select which areas of the body to target, including but not limited to the hand area. Other materials that could comprise these glove-tape embodiments include, but are not limited to woven materials that include natural, synthetic or blends of natural and synthetic yarns, thermoextruded or thermoset rubbery embodiments including those made from thermoplastic elastomers. Examples of synthetic yarns include nylon, polyester, and spandex (polyurethane) yarns.
Other sports, such as Rugby and Mud Football, could benefit from many of the described embodiments for many of the same reasons.
Embodiments of the present invention can offer significant and substantial benefits by offering the ability to better control a ball in select areas of the arm. For example, embodiments could be placed on primarily only the forearm area, allowing the player to have significantly enhanced control over a ball, much like a glove can help a player's hand better control a ball. In addition, these forearm embodiments offer new and surprising results when used in the sport of volleyball: they allow a player to impart much more spin on the volleyball—an added feature which could revolutionize the sport. This ability to impart significant spin on the ball could make it easier to control the ball upon contact, to strike a ball, to get the ball to a teammate, and to redirect the ball. One particular embodiment could comprise of an attachable forearm adhesive article embodiment. Specifically, it could generally be made of a stretch or elastic, moisture-resistant fiber, with grooves along most of the outer surface. Additionally the outer surface could also have a more non-elastic, moisture-resistant fiber, such as a silicone based or cured silicone materials, with convex dimples along a portion of the outer surface (See
The inner surface could be coated with a latex-free adhesive layer configured to allow the embodiment to be attached to the forearm area of the human body. Once attached, one would now have significantly more ball control during volleyball practice or game play. For example, once the volleyball approaches the athlete, the athlete could make some contact with the volleyball using the embodiment on the forearm instead of the skin of the forearm. Using the gripping means of the embodiment, such as dimples or linear grooves along the entire top surface, the athlete could not only make a more solid contact but by quickly rotating her forearm at ball contact, the grooves would momentarily ‘grip’ the volleyball and give the volleyball more spin than what could otherwise be achievable without the present invention.
The present invention would then provide a flexible, dermal adhesive product which could employ an acrylic based adhesive to provide a desired level of aggressive adhesion to skin under moist conditions. An additional benefit of this adhesion is that it is capable of being subjected to sterilization procedures and be hypoallergenic.
Some athletes may find some discomfort when peeling off forearm embodiments. Therefore, a thin buffer tape commonly called ‘pre-wrap’ can be applied between the skin and the adhesive overlay tape embodiments. Pre-wrap is a non-adhesive product made of a foam elastomer. It is generally applied in a double layer against the skin, after which the embodiments would be wrapped on top of the pre-wrap.
The adhesion between the adhesive layer and the bottom surface is preferably very strong. To increase the adhesion between the adhesive layer and the bottom surface, a primer may be applied to the bottom surface on which the adhesive layer is placed.
Many embodiments may be considered as significant improvements to specialty tape, such as kinesiology tape, and can possess many protective as well as therapeutic features. The tape can comprise a fabric which includes a weave of fibers, wherein the fibers include an elastic fiber covered by a covering material; a first end; a second end, wherein the second end is opposite the first end; and one or more rounded corners; a longitudinal cut in the fabric, wherein the longitudinal cut: passes through at least a portion of the fabric; and extends from the first end to a pre-determined distance from the second end: adhesive on a first surface of the fabric, wherein the adhesive is configured to adhere the fabric to a human body; and a release sheet on the first surface of the fabric, wherein the release sheet is configured to cover the adhesive and protect the adhesive from drying until a user is ready to apply the fabric to the human body. The improvement to this kinesiology tape would comprise of the addition of a gripping means on the outer surface a second fabric, which is then bonded to the outer surface of the specialty tape. The gripping means could comprise, for example, a textured high friction outer surface. A preferred textured surface comprises PVC dots. This significant and substantial improvement would allow the user to receive the many therapeutic benefits of using kinesiology tape while also being able to maintain and/or increase grip capabilities along at least part of the taped areas.
Hand task grip enhancers could certainly assist an individual more effectively perform non-sport as well as sports activities, or indeed for general use. Specific areas where embodiments would more effectively increase performance include, but are not limited to:
As one can see, embodiments of the present invention has all the advantages of the prior art (such as sports tape or gloves) without the disadvantages. Moreover, embodiments are also better than gloves because they offer less waste of materials. In addition, one can use embodiments to wrap a skin contact item, such as BAND-AID.
Individuals engaged in sports activities could also clearly benefit from embodiments of the present invention. One sport where grip-enhancing embodiments of the present invention will clearly enhance performance in hand tasks, is in the sport of football. For example, one particular unmet need that embodiments will satisfy will be with football quarterbacks.
In the book “Coaching Football Successfully,” by Allan Trinkle (2001) states “quarterback mechanics and ball-handling skills are vital for offensive success and consistency.” One embodiment of the present invention comprises tape which could be attached to the quarterback's throwing, or dominant hand. This embodiment would allow a quarterback to increase performance. This embodiment could be made of a natural rubber, having PVC dots throughout this finger embodiment. Because football is often played outside, embodiments might be made of moisture-resistant fibers as well. The benefits to the user of this embodiment would include: better overall grip and better control in holding and throwing a football, higher throwing accuracy, and less fumbles. Specifically, for example, a quarterback could wrap one or more finger joints of the throwing hand with the embodiment, while leaving other fingers bare, without the embodiment. More specifically, for example, say a quarterback's preferred manner of throwing a football is by placing only his Ring and Middle fingers over the football laces (the other fingers would not be touching the laces). The quarterback might then leave his Ring and Middle finger bare, but perhaps wrapping parts of the other fingers. This embodiment would allow a quarterback to take into account the benefits of the laces on a football, and give a quarterback the unique ability to grasp a football over the football laces on a football, with the comfort and feel of not having a glove, while adding the support that a glove might provide, over the taped thumb and forefinger. No prior art offers this unique type of targeted grip support. This embodiment would therefore increase grip capability on select fingers, while leaving the rest of the hand uncovered and able to maintain the necessary ‘feel’ of the ball, something that prior art cannot do. The resulting stronger overall grip should make for higher completed pass accuracy, more success at throwing a spiral, and generally higher consistency and performance in ball handling and control.
Another embodiment of the present invention comprises narrow width tape which can allow a receiver to increase his overall ball grip and therefore control of a football, especially when catching a football and attempting to complete a reception. These embodiments could, for example, be attached and wrapped around one or more joints of each of the player's ten fingers. A high friction surface could be provided as the gripping means along at least half of the outer surface of the tape. This gripping means is preferably formed from a high friction material, such as vinyl material, a PCV material or a latex material. The football player having attached the embodiment on one or more joints of one or more fingers, would now be better able to grip and control a football (See
A tape embodiment may also comprise a cotton-polyester blend. A preferred breakdown is 70 percent cotton, and 30 percent polyester. The polyester thread can be spun with the cotton yarns to produce the composite. The adhesive can be any pressure-sensitive adhesives classified as non-structural.
In addition to offering greater throwing accuracy and consistency, these and other embodiments could also help minimize quarterback fumbles by adding gripping support when completing other quarterback tasks, such as when ‘pumping’ the football, scrambling from being tackled, and even when catching and passing the football, especially when in ‘shot gun’ formation.
Another sport where the present invention will meet an unmet need is in the sport of golf. Many embodiments can be used in conjunction with each other to uniquely solve problems that have up until now been unsolved. As previously mentioned, gloves are not used on a golfer's dominant hand because of the structural limitations of this prior art. For example, a golfer may want to enhance the grip around some fingers but might want some fingers uncovered as so to maintain critical feel sensitivities. New art in the form of a new kind of kinesiology tape, for example, to support a golfer's strong hand would now allow a golfer to select which fingers she wants covered and which she wants to remain uncovered. The benefits of this significant and substantial physical difference in this new art offer the golfer a more stable overall grip, better control and enhance performance. For example, one embodiment for a golfer's strong hand comprises a finger joint embodiment, attaching to one or more joints of the dominant hand's Thumb, Forefinger and Middle finger, leaving the Ring and Pinkie fingers uncovered. The ‘feel’ and coordination tasks could therefore be maintained with the Ring and Pinkie fingers by leaving these fingers uncovered, while enhancing the overall grip of the strong hand by covering the strong hand's Thumb, Forefinger and Middle fingers. This embodiment therefore offers the golfer a much improved method of playing the sport of golf by using grip enhancers not just on the weak hand but also on the strong hand as well, without limiting the feel and coordination requirements in a proper golf swing. Applied to the outer surface for the gripping means can comprise a high friction surface. Preferably, the high friction surface extends between the spaced apart terminal edges to thereby completely cover the outer surface of the tape. The high friction surface may comprise a plurality of projections formed from a skid resistant material, such as neoprene, PVC, rubber or the like. The projections can form a pattern on the tape outer surface. Preferably, the high friction surface includes interstices or spaces between projections to allow the tape to flex as needed. Preferably, the projections have an average height of about 700 micrometers. Other similar embodiments can have uniform heights of say, 600 micrometers to three or four millimeters. The adhesive on the inner surface, may be one that is water-resistant, such as a polyacrylate adhesive.
Currently, only full-fingered gloves exist for golfers, regardless of one's preferred golf grip. One very popular grip, for example, is called the ‘interlocking grip.’ When one uses this grip, the Forefinger of the golfer's weak hand is placed over her strong (dominant) hand. With this grip, clearly the role of the weak hand's Forefinger has less to do with grip and more with coordination and feel on the strong hand, to more effectively control the golf swing and provide greater golf swing consistency. There is, therefore, no need to cover the weak hand's Forefinger, and covering the Forefinger (with a glove, for example) can actually diminish the forefinger's ability to properly feel the other hand, thereby diminishing the ability to coordinate a consistent, proper golf swing. Embodiments of the present invention could offer significant improvements to gloves by allowing a golfer to self-select which fingers she wants covered and which ones she doesn't. For example, one could choose to have finger embodiments wrap all the finger joints on her weak hand, except the Forefinger. These embodiments could be made of the same material used to make a typical golf glove, such as rubber or synthetic rubber. Alternatively, the golfer may simply prefer to simply add a finger embodiment on just the Pinkie finger of her dominant hand. This idea clearly also would apply to someone gipping a golf club with the ‘overlapping’ and ‘full-fingered’ methods. Among the advantages include the ability to have enhanced overall control and golf swing stability.
Another possible outcome in the way golf is played may be in how one handles a golf putter. Current proper form is not to use a glove. If one were to watch a professional golf tournament, for example, nearly all golfers would use one glove (placed on their weak hand) that they would use to grip a club for the tee shot swing, the fairway swing and even the short, approach swings. Once the golfer was ready to use their putter and putt the golf ball, they always take their glove off, deciding to grip the putter with both hands uncovered (without any sort of grip enhancer, such as a glove). A main reason this is done is so that the golfer could choose to keep her overall feel of the putter very high by not using a glove on either hand. With the present invention, however, the golfer could now decide to use an embodiment and wrap select parts of her hands, say the Thumb and Pinkie finger of the dominant hand, thereby also modestly increasing her overall grip. Even a slight increase in control of the putter can make a very significant and substantial difference in performance. These embodiments could also be made of a softer mesh fabric and perhaps a smoother surface but also with a gripping coating or compound, such as, for example, PVC coating, and would now allow a golfer to choose, if she prefers, to increase the grip she has on her club, but only modestly.
Another sport where hand task grip enhancer embodiments of the present invention would meet unmet needs would be in the sport of basketball. Individuals who play basketball have to ‘feel’ as well as control a ball to perform effectively (as mentioned previously), and although they too could significantly enhance performance in controlling a ball by using a grip enhancer, prior art forces them to choose between all feel (and therefore wear no glove) or wear a glove but then lose the ability to significantly feel the basketball with the now covered hand. These players would substantially benefit from developing a way to maintain feel while increasing grip capabilities in select areas of the hand, thereby solving this significant issue. This insoluble problem can now be solved by embodiments of the present invention
Consider a highly successful basketball player like Kobe Bryant. He has played professional basketball games, often with parts of his fingers wrapped with tape. An athlete might do this for a couple of reasons. First, tape can be used to tighten the finger joint or finger muscle, and therefore can be wrapped to protect the hand from injury. Second, it can also be used to wrap and protect a wound from further injury. So, with Kobe's hairline fracture wound on his hand, he uses tape at least partly to protect his wound and to keep his finger joints tight, but it also results in some loss in ability to grip the ball with the wrapped portions of his hand.
One embodiment that would help a player shoot better comprises narrow tape, to cover the finger tip, while the rest of the hand, including the palm area, can remained uncovered. These embodiments could comprise of an adhesive on one side (all embodiments have an adhesive on the bottom side) and non-linear grooves on the top side of the embodiment. These embodiments could be made of a moisture-resistant fabric. For all basketball players, but especially for those who have trouble shooting free throw shots or shooting outside of the perimeter, the uncovered palm area helps to remind them that the basketball should rarely touch the palm area when properly shooting a basketball (if the basketball touches the palm area, then there is no shooter's gap and is therefore considered improper shooting form). Because proper dribbling form also discourages the ball touching the palm area, covering the palm area with, say a glove, would not only be relatively useless in basketball, but also a waste of resources. My embodiments would allow a player to avoid covering her palm area and instead concentrate her enhanced gripping abilities in the most important area when it comes to shooting; the fingertips. The result would of course be a better overall grip and a significantly superior alternative to the prior art of basic multisport gloves that cover the hand completely forcing the basketball player to lose much of the critical requirements of being able to feel the ball as well. This embodiment may comprise of an elastic athletic tape thus allowing for greater movement and increased circulation to the area. The embodiment would comprise 100 percent acrylic adhesive on the inner surface, and a textured high friction on the outer surface. The textured outer surface can comprise, for example, bumps along at least a portion of the outer surface. Other examples of textured high friction embodiments, for example, include: depressions, cross-hatching, crevices, and wavy lines.
Embodiments could also satisfy the necessary requirements in dribbling a basketball as well. According to the book “Basketball for High School Players and Coaches,” (1955) Carl Bachman describes proper fundamentals of basketball dribbling: “Certain fundamentals apply to all phases of ball handling: Looseness of finger and wrist action is important, practice spinning the ball on fingertips; a basketball should never touch the heel of the hand and seldom, if ever, touch the palm.” Fingertip tape embodiments of the present invention could also help a dribbler develop and use proper dribbling form, especially on her weak-hand. Embodiments would more generally help any player, and likely could be used, for example, by those playing the position of Guard while practicing proper dribbling on their strong-hand, as well as Forwards and Centers during actual game play for added support on their weak-hand. Although players spend most of their time dribbling a basketball with their dominant hand, most Guards especially have to spend some time dribbling and controlling a basketball with their weak hand. Because players usually have more difficulty controlling the basketball with their weak hand, usually fingertip embodiments on the weak hand, for example, would significantly improve grip and control of the basketball on the weak hand. Embodiments could be made of, for example, of a high twist, elastic, cotton tape with a rubber-based adhesive. The fingertip embodiments may range from 1/21 inch to 1.5 inches, with a preferred width of about ¾ inch.
When considering the adhesive composition, one should consider the following: first, it should be able to contact the skin for a prolonged period of time without significantly irritating the skin; the adhesive should also be flexible enough to allow some movement of the skin.
Another method of using embodiments for enhanced general basketball play is in the form of wrapping parts of all five fingers individually, and separately covered. The palm area would therefore remain bare, or uncovered. This would give a basketball player the ability to better catch a ball because the fingers would possess grip enhancing capabilities, thus eliminating the consistent problem often found in Forwards and Centers losing control of passes. The embodiment would also provide a player with a stronger grip on the ball when passing a ball as well as provide some moisture management control, thus minimizing turnovers often caused by passers, especially in Guards. The gripping means of the embodiments could be embossed with, say crisscross ridges, on the outer surface of the tape and coated with a pressure-sensitive adhesive layer to adhere the tape to the skin, on the bottom surface. These embodiments would therefore comprise of one backing material, and not require the bonding of a second material layer to apply the gripping means.
Although many hand tasks require a good grip, no art currently exists that would provide these players with the ability to maintain some grip capabilities while at the same time trying to protect the hand from injury, or trying to protect an already injured hand. Finger embodiments of the present invention would allow a player to be able to apply some sort of protection on select fingers, without having to sacrifice the critical ability of being able to properly feel the basketball.
For example, one common hand task in basketball is slamming a basketball through a basketball hoop (commonly known as slamdunking). When one slamdunks a basketball it is often done with force and almost always involves striking the metal basketball hoop with at least one of your hands (mostly impacting the fingers). For Forwards and Centers especially, this hand task can quickly take a toll on their fingers if their fingers are not somehow protected. The current—and only—method of enhancing this hand task is to apply athletic tape to select finger joints. This current method and products have significant shortcoming that often result in inferior execution. If one tapes part of one's hands with standard sports tape, for example, the player will lose any grip capabilities in that area, which could easily result in mishandling a basketball. One finger task enhancing embodiment, therefore, could comprise of finger joint embodiments for the base joints of the hand. Again, the inner surface would offer an adhesive element such as a hypoallergenic adhesive that is also waterproof. The top surface would offer a gripping means. Among the results would be a better device and method of providing added protection while slamming, and not having to sacrifice ball control. This embodiment may be of about 97% cotton and about 3% Nylon, thereby offering significant flexibility. A secondary but still important feature is that this embodiment will help players slamdunk a basketball by helping the player to ‘palm’ the ball. This feature would provide added grip support and greater performance in slamdunking.
Other general hand task challenges that embodiments would help solve has to do with basketball players who injure, in some way, their hand. This situation is very common in basketball, where a player has to tape her hand after, say, injuring a finger. The result again is a decrease in ball control and limited protection. These hand task enhancer embodiments could also allow a player to essentially ‘tape’ her finger by sticking one of these embodiments on her hand. Embodiments could also include a therapeutic additive on the bottom surface, which could also be used for therapeutic reasons. Additives include medicinal compounds, such as antiseptics, antibiotics, anesthetics, neomycil sulfate, bacitracin, and the like. Additives also include skin care agents and therapeutics such as tretinoin, alpha hydroxyl acids, and other similar products that are well known. These finger embodiments would be substantially superior because these embodiment would, for example, be able to protect a finger injury (with a therapeutic additive) while not diminishing grip, because of the gripping element on the outer surface of said embodiments. Embodiments could also be attached to a skin-contact product, such as a bandage already on the injured area. Specifically, for example, the adhesive could be applied along the edges of the bottom surface, covering up to, for example, 50 percent of the entire bottom surface area. The remaining bottom surface could then be coated the therapeutic additive. There are, of course many other potential coating patterns which could useful.
In general, the hand task enhancer embodiments of the present invention can generally be used in conjunction with any type of hand task activity and/or sports play. As discussed, they offer, among other things, an individual with the opportunity to increase overall hand task performance. Maintaining or increasing overall control, for example, can provide many benefits to a user of these, and other embodiments. Among the many benefits of the hand task enhance embodiments are that they:
Additionally, these embodiments can provide:
These are among the many benefits of the present invention, and are not to be construed as limitations of the benefits nor their legal equivalents
Although the description of the present invention only discussed a few embodiments, it is understood that non-sport might benefit as well from the present invention and its legal equivalents. In addition, only some embodiments have been discussed and in no way is intended to limit all the various embodiments and other embodiments that the present invention provides, such as but not limited to, different designs, different grip configurations, different adhesives, and different combinations. These embodiments can be used by men and women, boys and girls, playing any position in any sport, as well as those whose dominant hand is the right hand or the left.
A single grip can have a variety of finishes, one portion of the exterior (top) surface can have a smooth finish, for example, and another portion can have a textured surface. The textured portion would create a coefficient of friction (grip enhancer) on the surface.
Embodiments mentioned for, say the forearm, are by way of example, and in no way are intended to limit the embodiments to the forearm; they could just as easily also be used on the elbow, wrist area, etc.
There has thus been outlined, rather broadly, the more important features of the invention in order that the detailed description of the drawings thereof that follows may be better understood, and in order that the present contribution to the art may be better appreciated. There are, of course, additional features of the invention.
In this respect, before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not limited in its application to the details of construction and to the arrangements of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments and of being practiced and in being used in other ways. Also, it is to be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting.
As such, those skilled in the art will appreciate that the conception, upon which this disclosure is based, may readily be utilized as a basis for the designing of other structures, methods and systems for carrying out the several purposes of the present invention. It is important, therefore, that the claims be regarded as including such equivalent constructions insofar as they do not depart from the spirit and scope of the present invention.
It is expressly understood that the following descriptions and drawing are for illustration purposes only, and in no way are intended to limit the scope of the present invention and its various embodiments. For example, the drawings are of drawings of embodiments for the left hand but can easily be created for the right hand, and can be used by men and women, boy and girls.
It is expressly understood that the drawings are for the purpose of illustration and description only and are not intended as a definition of the limits of the invention.
In
The thickness of this embodiment is about one millimeter, but can be thinner (if for example the gripping means is in the form of a PVC coating) or thicker if, for example, the top surface has depressions. A preferable width for the embodiment is about 0.75 inches defining the two terminal ends, a standard athletic tape width. Similar embodiments could offer different widths. Other preferable widths might be as much as several inches. The embodiment has been cut from its coiled state and is now about six inches in length. The thickness of the adhesive layer is about twenty .mu.m, and can be preferably range from ten to five hundred .mu.m, in particular from fifteen to two hundred .mu.m. Again, other materials and other adhesives can be used, such as those aforementioned, especially water-proof adhesives or synthetic resins.
This embodiment offers several benefits, especially to users needing to grip something. For example, in the sport of baseball, individuals playing the position of Pitcher have to constantly grip and throw a baseball, and the ability to grip the baseball is critical in success. Currently Pitchers do not use a glove on their dominant (throwing) hand, primarily because Pitchers also need to be able to properly ‘feel’ the ball. Wearing prior art gloves would increase grip capabilities but would significantly diminish ‘feel’ ability to the point that Pitchers currently do not wear grip enhancers on their dominant hand. This embodiment solves the dilemma faced by athletes such as Pitchers, for example, by now offering a product and a method to increase one's grip by attaching the embodiment in preferred areas of certain finger joints, while leaving other joints and/or the palm uncovered, or bare, therefore allowing the athlete to maintain necessary feel capabilities. For example, a Pitcher could wrap the distal phalange of the thumb and leave the remaining finger areas unwrapped (bare). When the Pitcher now grips a baseball, his grip and overall control will be enhanced by the embodiment being wrapped around only select areas of the hand, while his overall feel of the ball will be maintained throughout the rest of his hand. It is expected that athletes playing other positions in baseball will also benefit from using embodiments on their dominant hands. In other sports, such as golf for example, embodiments may indeed be a possible substitute to the use of gloves.
Adhesives and therapeutic additives of the present invention and may be applied by any suitable method, such as, for example, solvent coating in a continuous or discontinuous method, air knife coating, rod coating, electrostatic coating, slide hopper coating, extrusion coating, blade coating, and slide coating.
Those who enjoy skateboarding would be among those benefiting from this embodiment. By attaching the embodiment onto select areas of the hand, the user would be able to better grip the skateboard when performing ‘jumps’ and other sophisticated maneuvers on the skateboard. The ridges would allow the skateboarder to maintain a stronger overall grip, while the water-resistant adhesive would ensure that the embodiment would remain attach to the skin during outdoor activities. This embodiment would additionally be a significant and substantial improvement to kinesiology tape, by offering the grip-enhancing layer to said products, such as, for example, ridges and other high friction surfaces. The athletic tape 40 can also consist of a pressure sensitive adhesive coated onto the backing material, such as paper or cloth. The second component 41 could comprise a thicker, sturdier material, say a cured silicone material, with a coarse textured surface, and bonded to the athletic tape 40, creating a grip enhancing means on a now improved athletic tape.
The embodiment can also comprise of adhesives generally used for kinesiology tape along with structures and materials used to create standard Kinesiology tape, such as those comprising the very successful KINESIO TEX TAPE. Added to these tapes would be the grip-enhancer on the top surfaces. Users of kinesio tape would certainly benefit from this new type of kinesio tape, especially when the tape is applied to the hand and arm areas, where prior art kinesio tape offers a relatively low coefficient of friction. Additionally, these embodiments may comprise a liner sheet, as described in
There are several widths that the present invention may offer. Embodiments that target the hand may, for example, comprise a preferred width starting at about ½ or one centimeter, but may be as wide as two centimeters—wide enough to essentially cover an entire finger area such as a distal phalange, without having to use multiple layers in an abutting fashion. Additionally, adhesive article embodiments and tape embodiment may have perforations, such as that described in
Additionally, a portion of the palm area is wrapped with another embodiment 58. Athletes such as football receives may use embodiments in this fashion to better catch or otherwise control a football. This particular embodiment is preferably comprised of a cotton fiber, and has a one hundred percent acrylic adhesive that is latex-free. The embodiment can be configured to last a few days attached to the skin, beneficial especially if the intended use is at least partly for therapeutic reasons, such as, for example, if the user would like to maintain tightness in certain muscles. The grip-enhancing means comprises a PVC coating 59. A preferred width of the embodiment is about ½ inch. Other embodiments can certainly vary in width, generally ranging from ⅙ inch to 2.5 inches. Furthermore, the embodiment can be porous and breathable, and can additionally be used to support and stabilize injuries to joints, bones and muscles.
This embodiment can alternatively be made of a spandex material, thus providing stretchy properties. Additionally, this and the other embodiments in
The adhesive may also comprise silicone adhesives, but can just as easily also be rubber based adhesive, or non-latex based synthetic adhesive, depending on if the embodiments will be hypoallergenic.
The embodiment as described in
