The present disclosure relates to the use of shear thickening materials, and more particularly, to the use of shear thickening materials in sports products.
Sports products may include rackets, golf clubs, skis, snowboards, footwear, personal protection equipment, and/or other types of equipment known to those skilled in the art. Sports products may be designed to provide a user with a competitive advantage, enhance the user's comfort, or protect the user from being injured. A sports product's marketability may depend on how effective it is at providing such benefits. As such, manufacturers of sports products continually seek to improve the materials and designs used in the construction of their products.
While adding material to a sports product may improve the product's ability to absorb impacts, dampen vibrations, or perform other advantageous functions, it may also add bulk and weight to the product. The added bulk and weight may negate the advantages by increasing a user's discomfort, and/or hindering a user's movement or performance. Thus, sports products are often times constructed of lightweight, thin materials. However, if the materials are too thin or weak, they may lose their effectiveness, or may be easily damaged. A balance must be struck between these considerations. Further complicating matters is that in some instances, the properties that make materials desirable under one set of conditions, may make the same materials undesirable under another set of conditions.
The present disclosure addresses at least some of the problems described above and other problems in existing technology.
In accordance with an aspect of the disclosure, a racket may include a head region, a striking region, a throat region, a shaft region, or a handle region. The racket may also include a shear thickening material in at least one of the head region, striking region, throat region, shaft region, or handle region. The shear thickening material may be configured to exhibit shear thickening behavior when an impact occurs between the racket and an object.
In accordance with another aspect of the disclosure, a sports product may include a support member and an impact region configured to impact an object. The impact region may be coupled to the support member. The sports product may also include a shear thickening material in at least one of the support member or the impact region, the shear thickening material being configured to exhibit shear thickening behavior when an impact occurs between the impact region and the object.
In accordance with another aspect of the disclosure, a method for manufacturing a sports product may include manufacturing a first layer of material. The method may also include manufacturing a second layer of material. The method may further include depositing a shear thickening material between the first layer of material and the second layer of material. The shear thickening material may provide a first level of flexibility when a first type of impact occurs between at least one of the first layer of material and the second layer of material, and an object. The shear thickening material may provide a second level of flexibility when a second type of impact occurs between at least one of the first layer of material and the second layer of material, and the object.
Additional objects and advantages of the disclosure will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the disclosure. The objects and advantages of the disclosure will be realized and attained by means of the elements and combinations particularly pointed out in the appended claims.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure, as claimed.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate several embodiments of the disclosure and together with the description, serve to explain the principles of the disclosure.
Reference will now be made in detail to exemplary embodiments of the disclosure, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
Shear thickening or dilatant materials have properties that distinguish them from other materials. For example, when shear thickening materials are subjected to an increasing rate of shear deformation, they undergo an increase in viscosity and/or rigidity. For example, a shear thickening material may behave like a low viscosity fluid when not subjected to shear deformation or subjected to a low rate of shear deformation, but may behave like a highly viscous fluid when subjected to a high rate of shear deformation. Another shear thickening material may behave like a fluid when not subjected to shear deformation or subjected to a low rate of shear deformation, but may behave like a quasi-solid or solid when subjected to a high rate of shear deformation. Yet another a shear thickening material may behave like a quasi-solid or flexible solid when not subjected to shear deformation or subjected to a low rate of shear deformation, but may behave like a rigid solid when subjected to a high rate of shear deformation.
A shear thickening material's starting point (i.e., its normal or at rest condition) and ending point (i.e., its condition when subjected to a high rate of shear deformation) may define endpoints of a region, the region covering a portion of a spectrum. One end of the spectrum may be characterized as “fluidity,” while the opposite end may be characterized as “rigidity.” By adjusting the forces acting on the shear thickening material, or adjusting the types and/or quantities of ingredients in the shear thickening material, its region may be shrunken, expanded, and/or shifted towards one end of the spectrum or the other. The introduction of a high rate of shear deformation will drive the shear thickening material in the direction of rigidity, while removal of the shear deformation will drive the shear thickening material toward fluidity.
The behavior of shear thickening materials may also be time dependent. When a shear force is applied to a shear thickening material over a long timescale, the shear thickening material may not move in the direction of rigidity. If, however, the shear force is applied to the shear thickening material over a short timescale, the shear thickening material will move in the direction of rigidity. The timescale limit under which the shear thickening material will exhibit shear thickening behavior may depend on a number of factors, such as the type of shear thickening material involved, and the characteristics of the force applied to the shear thickening material.
The behavior of shear thickening materials may be caused by at least one of the following mechanisms. One mechanism is shear induced ordering, where the alignment of particles in a medium may increase as a shearing force is applied. The more aligned the particles become, the more they behave like a solid material. Additionally or alternatively, the shear thickening behavior may be caused by dilation, or a change in volume, of one or more ingredients in the shear thickening material. For example, a shear thickening material may include powder molecules whose volume may expand as a shearing force is applied. The expanding volume may move the shear thickening material in the direction of rigidity. In some cases, the shear thickening behavior of a shear thickening material may be caused by attraction between molecules, where the attraction increases as a shearing force is applied, thus driving the shear thickening material toward rigidity. The shear thickening behavior may also be caused by friction, where friction between components of the shear thickening material increase as shearing force is applied. The increased friction may inhibit free movement of the components past each other, driving the shear thickening material toward rigidity. The shear thickening behavior may also be caused by shear forces overcoming repulsive forces between particles in a material, causing the particles to clump. The clumping may drive the shear thickening material toward rigidity.
Removal of the shearing force may have the opposite effect, that is, removal may precipitate the shear thickening material's movement in the direction of fluidity. It should be understood that the above list of interactions and mechanisms is not intended to be exhaustive, and that shear thickening behavior may be the result of any phenomenon or interaction, or combination of phenomena or interactions, as would be apparent to one skilled in the art.
Some common examples of shear thickening materials include a mixture of corn starch and water (often times referred to as “oobleck”) that may become more difficult to stir as the stirring rate increases, and putty material that may be easily deformed when slow pressure is applied, but may resist deformation when thrown against a surface.
Various categories of shear thickening materials will now be described. It should be understood that this list is not intended to be exhaustive, and any suitable types of shear thickening material are contemplated for use in the disclosed embodiments.
One category of shear thickening materials includes shear thickening fluids. A shear thickening fluid may possess the characteristics of a fluid until it encounters a shear force, whereupon the shear thickening fluid will thicken (e.g., move toward rigidity), and behave more like a higher viscosity fluid, quasi-solid, or solid. The shear force may be supplied by direct or indirect impact of an object against the shear thickening fluid, or any other suitable form of agitation. When the shear force is removed, the shear thickening fluid will return to its previous state.
The shear thickening fluid may be a colloid, made of particles suspended in a liquid medium. Under normal conditions (i.e., where the shear thickening fluid is undisturbed by a shear force, or acted on by a slowly applied shear force), the particles will repel each other slightly, such that the particles may float interspersed throughout the liquid medium without clumping together or settling. The energy of a sudden impact will overwhelm the repulsive forces between the particles, causing the particles to clump together. The clumping may increase the viscosity of the shear thickening fluid. When the energy from the impact dissipates, the particles will return to repelling one another again, causing the clumps to fall apart. As such, the viscosity may return to the level that existed prior to the impact. Additionally or alternatively, the liquid may exhibit shear thickening behavior.
The particles may include, for example, silica particles. The liquid medium may include, for example, polyethylene glycol. It should be understood, however, that any suitable particles and fluid medium may be used. Shear thickening fluids may be used to make films, resins, finishes, and coatings that exhibit shear thickening behavior. Methods used to make films, finishes, and coatings using fluids are well known in the art, and no further description will be provided here.
Another category of shear thickening materials includes shear thickening gels. A shear thickening gel may have the characteristics of a high viscosity fluid, quasi-solid, or any composition in between. The composition and properties of the shear thickening gel may be similar to those of the shear thickening fluid. However, under similar conditions, the shear thickening gel may have a higher viscosity or rigidity than the shear thickening fluid.
Shear thickening gels may possess jelly-like qualities, or qualities associated with putties or clays. Under normal conditions, shear thickening gels will have fluid characteristics, and may be deformed with the application of little or no force. However, when subjected to the energy of a sudden impact, shear thickening gels will move toward rigidity, and their ability to resist deformation will improve.
A shear thickening gel may include the same ingredients as a shear thickening fluid, but may exist in gel form due to environmental conditions. Additionally or alternatively, the shear thickening gel may include an ingredient that causes the fluid medium to become gelatinous. The mechanism behind the shear thickening behavior of shear thickening gels may be similar to those of other categories of shear thickening materials.
Another category of shear thickening materials includes encapsulated fluids or gels. These may include containers filled with shear thickening fluids or gels. A container of shear thickening fluid or gel may include a structure configured to store the fluid or gel. The container may include one or more walls made of either flexible or rigid material. The container may be configured to receive impacts or vibrations, and to transmit them to the fluid or gel. The impacts or vibrations will cause the fluid or gel to become more viscous or even rigid, imparting the overall container with greater rigidity. Shear thickening materials may also be used in the construction of the container walls themselves.
Another category of shear thickening materials includes shear thickening foams. A shear thickening foam may be formed by trapping gas bubbles, produced using physical or chemical means, in a shear thickening fluid or gel. The material may then be solidified. The interactions and mechanisms behind the shear thickening behavior of a shear thickening foam may be similar to those of other shear thickening materials. When the shear thickening foam is subjected to the energy of a sudden impact, its rigidity will increase. Before and after the impact, under normal conditions, the shear thickening foam will be relatively flexible.
Another category of shear thickening materials includes shear thickening solids. A shear thickening solid may be formed by solidifying a shear thickening fluid or gel, or otherwise incorporating shear thickening material into a solid object. Shear thickening solids can be formed by processes including, for example, extrusion or injection molding. When the shear thickening solid is subjected to the energy of a sudden impact, its rigidity will increase. Under normal conditions, however, the solid will be more flexible. The interactions and mechanisms by which the rigidity of a shear thickening solid increases may be similar to those of other shear thickening materials.
Another category of shear thickening materials includes shear thickening filaments. A shear thickening filament may be formed by any suitable processes, or combination of processes, including, for example, injection molding, extrusion, or spinning out of a melt. The shear thickening filament may exhibit the characteristics of a shear thickening solid.
Another category of shear thickening materials includes impregnated fibers. An impregnated fiber may include, for example, a fiber or yarn that has absorbed, and/or is coated with, a shear thickening material. The fiber may include a high strength polymeric fiber. The shear thickening material may be a fluid, and may retain its fluid characteristics after impregnation. This may help to ensure that the impregnated fiber will remain flexible, while endowing the fiber with shear thickening properties.
Another category of shear thickening materials includes impregnated fiber reinforced materials. An impregnated fiber reinforced material may include, for example, a fabric that has absorbed, and/or is coated with, a shear thickening material. Additionally or alternatively, the impregnated fiber reinforced material may include previously impregnated fibers woven together to form a fabric. It is also contemplated that the impregnated fiber reinforced material may include a fabric made by weaving together shear thickening filaments and/or impregnated fibers. It is further contemplated that the fabric or fibers may be set into another medium to reinforce that medium. It is also contemplated that shear thickening materials may be mixed in with the medium to impart shear thickening properties to the medium.
The impregnated fiber reinforced material may exhibit shear thickening behaviors, similar those described above with respect to the other categories of shear thickening materials. For example, the coefficient of friction between the fibers, and/or between the fibers and the medium, will increase during an impact event, causing the fibers and/or medium to become more rigid. It is further contemplated that the fibers may form a substrate that, when a shear thickening material permeates the fibers, holds particles of the shear thickening material in place. When an object suddenly strikes the impregnated fiber reinforced material, the shear thickening material will immediately thicken or harden, imparting its hardness to the overall construction. The flexibility of the overall construction will return upon removal of the force.
Another category of shear thickening materials includes shear thickening composites. A shear thickening composite may include, for example, a solid foamed synthetic polymer. The solid foamed synthetic polymer may include an elastic, and/or an elastomeric matrix. The elastomeric matrix may retain its own boundaries without need of a container. The composite may also include a polymer-based dilatant different from the solid foamed synthetic polymer. The polymer-based dilatant may be distributed through the matrix and incorporated therein during manufacture. The composite may also include a fluid distributed through the matrix. The combination of the matrix, dilatant, and fluid may be selected such that the composite may be resiliently compressible (i.e., display resistance to compressive set), and preferably also flexible.
Another shear thickening composite may include a solid, closed cell foam matrix and a polymer-based dilatant, different from the matrix, distributed through the matrix. The composite may also include a fluid distributed through the matrix. The combination of matrix, dilatant, and fluid may be selected such that the composite may be resiliently compressible.
In either of the shear thickening composites described above, any suitable solid materials may be used as the matrix, including, for example, elastomers. This may include natural elastomers, as well as synthetic elastomers, including synthetic thermoplastic elastomers. These may include elastomeric polyurethanes, silicone rubbers, and ethylene-propylene rubbers. Any polymer-based dilatant that may be incorporated into the matrix may be used in the shear thickening composites. The dilatant may be selected from silicone polymer-based materials, such as borated silicone polymers. The dilatant may be combined with other components in addition to the components providing the dilatancy, including, for example, fillers, plasticisers, colorants, lubricants and thinners. The fillers may be particulates (including microspheres), fibrous, or a mixture of the two. It is contemplated that a borated siloxane-based material may be used as a dilatant.
Another category of shear thickening materials includes shear thickening layers. A shear thickening layer may include a layer of material formed from one of, or a combination of, the above-categories of shear thickening materials. The shear thickening layer may be combined with layers having other properties, such that the combined layers may exhibit some form of shear thickening behavior as a result.
In the description of sports products that follows, use of the term “shear thickening materials” is meant to cover all categories of shear thickening materials and combinations of shear thickening materials known to those skilled in the art.
Rackets may be used in a variety of sports. For example, rackets may be used to play tennis, racketball, squash, badminton, paddle ball, and/or other known racket sports. A racket used for one sport may differ structurally from a racket used in another sport. Even rackets used for the same sport may have differences in structure that may provide users with different benefits or advantages. Exemplary rackets 10, 12, and 14, whose features are shown in
Rackets 10 and 12, shown in
Racket 10 may include a frame 16. Frame 16 may be constructed of a composite material by, for example, placing a core, including a tube having one or more layers 43 of woven reinforcing fibers, in a mold (not shown) defining the shape of frame 16, closing the mold, and injecting an epoxy material 38 into the mold around the core. The tube may be formed by, for example, winding one or more substantially planar sheets of material into tubular form to form layers 43 shown in
The reinforcing fibers may be carbon fibers, boron fibers, glass fibers, silicon carbide fibers, ceramic fibers, or aramid fibers of the kind available under the trade name Kevlar, or any combination of these materials. An enlarged view of an exemplary composite material 18, with its reinforcing fibers 20 and epoxy material 38 are shown in
Frame 16 may include a number of regions, including, for example, a head region 22 (shown in
Head region 22 may include a head 32, a bumperguard 34, and a hitting surface 36. Head 32 may include the portion of frame 16 surrounding hitting surface 36. Head 32 may be composed, at least partially, of composite material 18, and may include shear thickening materials. For example, reinforcing fibers 20 may be impregnated with shear thickening materials. Additionally or alternatively, shear thickening materials may be mixed in with epoxy material 38. Shear thickening materials may also be provided in an interior of head 32, such as in a wall 42 of head 32 (as shown in
Shear thickening materials 68 and 71 may also be provided on an exterior of head 32, as shown in
Flexpoint 44 may provide advantageous ball control characteristics. Upon impact with a ball, head 32 may flex or deform at flexpoint 44. By placing shear thickening materials 68 and 71 at flexpoint 44, the stiffness/flexibility of head 32 may vary in accordance with the viscosity or rigidity of shear thickening materials 68 and 71. Shear thickening materials 68 and 71 may be inserts configured to seal depressions 51 and 64. When shear thickening materials 68 and 71 stiffen upon impact with a ball, flexpoint 44 may also stiffen. A stiffer head or frame may bend less, thus offering more power. When shear thickening materials 68 and 71 return to their rest state, flexpoint 44 may regain its normal flexibility. A flexible head or frame may bend more, resulting in energy loss and less power, but more control of the ball and a softer “feel.”
Shear thickening materials may also be positioned at any other regions of head 32 that experience bending stress and/or shear stress on impact. Preferably, the shear thickening materials may be positioned at those regions of head 32 that experience maximum bending stress and/or shear stress on impact. Additionally or alternatively, shear thickening materials may be positioned in regions of head 32 containing antinodes, where head 32 experiences maximum vibrational displacement after an impact.
Bumperguard 34 may surround at least a portion of head 32. Bumperguard may help protect head 32 from impacts. Bumperguard 34 may include shear thickening materials that may help absorb the impacts, thus protecting head 32 from damage, and dampening vibrations caused by the impacts before they are transmitted through frame 16 to the user.
Shear thickening materials may be mixed in with polymer materials used in the construction of bumperguard 34. A layer 40 or layers of shear thickening material (shown in the cut-out in
Hitting surface 36 may include strings, such as those used in tennis, racketball, squash, and badminton rackets. Hitting surface 36 may also include a paddle face 50, shown in
The strings may include one or more materials, including, for example, gut or synthetic materials (e.g., nylon, polyamide, and other polymers). The materials used in the strings can change the performance of a racket, and thus, the composition of the strings may be varied to create variations in terms of playability, durability, and “feel,” among other considerations. In some cases, a vibration dampening device 52 may be placed on the strings, as shown in
The strings may be of a monofilament or multifilament type. Monofilament strings, like string 46 in
A multifilament string 48 is shown in
Another hitting surface, paddle face 50 of
Throat region 26 may include the portion of frame 16 between head region 22 and shaft region 28. Throat region 26 may be constructed of the same or similar materials as head 32. For example, throat region 26 may be constructed of composite material 18. Throat region 26 may also include concavities 66 and 74 that may be at least partially filled by shear thickening material 70 and 72, as shown in
Shear thickening materials 70 and 72 may be positioned in areas of throat region 26 that may experience bending stress and/or shear stress upon impact. Preferably, shear thickening materials 70 and 72 may be positioned in areas of throat region 26 that may experience maximum bending stress and/or shear stress upon impact. Additionally or alternatively, shear thickening materials 70 and 72 may be positioned at antinodes, where throat region 26 may experience maximum vibrational displacement after an impact.
Additionally, throat region 26 may include a throat 76. Throat 76 may be an open throat 78, as shown in the embodiments of
Open throat 78 may include an opening 82 surrounded by portions 84, 86, and 88 of frame 16. One or more of portions 84, 86, and 88 may include a discontinuity or cavity 126 in which shear thickening materials 96 may be inserted, as shown in
In the embodiment of
Shaft region 28 may include the portion of frame 16 between throat region 26 and handle region 30. Shaft region 28 may include a similar construction as the other regions of frame 16. Shear thickening materials 94 and 98 may be positioned in shaft region 28 proximate where shaft region 28 meets handle region 30, as shown in
Handle region 30, shown in
Handle region 30 may be at least partially surrounded by a grip 100. Grip 100 may include a polymer material surrounding handle region 30, providing handle region 30 with a polygonal outer surface. The material used to form grip 100 may include shear thickening materials. Additionally or alternatively, grip 100 may include composite material 18. A handle region 30a, representing an alternative embodiment, is shown in
A grip tape 106 may be wound around grip 100. Grip tape 106 may be configured to provide tack (adhesive force), moisture wicking, and cushioning. Grip tape 106 may include a lining layer 108, a polyurethane layer 110, an adhesive layer 112, and/or any other layers known to those skilled in the art. One or more of layers 108, 110, and 112 may include shear thickening materials. Additionally or alternatively, shear thickening materials may fill spaces or discontinuities 114 in and/or between layers 108, 110, and 112.
It is also contemplated that a layer 116 of shear thickening materials may be secured between grip 100 and grip tape 106. Layer 116 may be a strip wrapped around grip 100 in a manner similar to grip tape 106. Layer 116 may include adhesive on one or more of its surfaces to help it adhere to grip 100 and/or grip tape 106.
Handle region 30 may also include a butt end 118. Handle regions 30b and 30c, representing alternative embodiments of handle region 30, show alternative embodiments of butt end 18, depicted in
Rackets 10e, 10f, 10g, and 10h in
Racket 10e, shown in
Frame 218 is shown with a string hole 224 and a string 226. String 226 may be coupled to the radially outer layer of frame 218. Under normal tensile forces acting on string 226, represented by arrow 228 of
On the other hand, when tensile forces acting on string 226 increase, the radially outer layer of frame 218 may be pulled toward the radially inner layer of frame 218. Increased tensile forces are represented by arrow 228 in
By controlling the degree of relative movement between the inner and outer layers of frame 218, racket 10e may provide a user with enhanced performance. For example, when shear thickening materials 222 are soft, frame 218 may be more flexible. That flexibility may give racket 10e a softer feel, providing the user with greater control over the ball for soft or touch shots. When shear thickening materials 22 stiffen, frame 218 may become stiffer. The stiffness may give racket 10e a harder feel, providing the user with the ability to strike a ball with greater force.
Racket 10f is shown in
With the construction of racket 10f, outer frame 230 and inner frame 232 may be isolated from one another. By selecting shear thickening materials having different stiffening characteristics, for use as shear thickening material 238, the playability of racket 10f may be adjusted. It is also contemplated that different shear thickening materials may be used in different regions of the gap between outer and inner frames 230 and 232, providing a way to further adjust the playability of racket 10f. The surfaces of outer and inner frames 230 and 232 that face each other may be shaped such that the gap formed between outer and inner frames 230 and 232 may not be straight. For example, the surfaces of outer and inner frames 230 and 232 may include substantially complementary curvatures.
When no force, or a small force acts on string 236 or any other string, the small force may produce little or no movement between outer and inner frames 230 and 232. As such, shear thickening materials 238 may remain soft, allowing outer and inner frames 230 and 232 to move relative to one another. The relative movement may include a rotational component, with outer frame 230 rotating towards inner frame 232, or vice versa. It should be understood that shear movement between the outer and inner frames 230 and 232 may also occur.
On the other hand, when a large force acts on string 236, the large force may initiate increased movement between outer and inner frames 230 and 232, which may in turn generate forces on shear thickening materials 238 due to the bonding between shear thickening materials 238 and outer and inner frames 230 and 232. This may cause shear thickening materials 238 to stiffen. When shear thickening materials 238 stiffen, shear movement or relative rotation of one of outer and inner frames 230 and 232 relative to the other of outer and inner frames 230 and 232 may be reduced or impeded. Because shear thickening materials 238 can selectively adjust the stiffness of racket 10f (by becoming more or less stiff), the playability of racket 10f may be adjusted in the manner described with respect to racket 10e. Thus, racket 10f may be able to provide a softer feel for touch shots, and a harder feel for power shots.
Racket 10g is shown in
When no force, or a small force acts on string 258 or any other string in the string bed, the small force may produce little or no movement between outer and inner frames 240 and 242. As such, shear thickening materials 252 may remain soft, allowing outer and inner frames 240 and 242 to move relative to one another. The relative movement may include a rotational component, with outer frame 240 rotating towards inner frame 242, or vice versa. It should be understood that shear movement between the outer and inner frames 240 and 242 may also occur.
On the other hand, when a large force acts on string 258 or any other string in the string bed, the force may initiate relative movement between outer and inner frames 240 and 242, which may in turn generate forces on shear thickening materials 252 due to the bonding between shear thickening materials 252 and outer and inner frames 240 and 242. This may cause shear thickening materials 252 to stiffen. When shear thickening materials 252 stiffen, shear movement or relative rotation of one of outer and inner frames 240 and 242 relative to the other of outer and inner frames 240 and 242 may be reduced or impeded. Because shear thickening materials 252 can selectively adjust the stiffness of racket 10g (by becoming more or less stiff), the playability of racket 10g may be adjusted in the manner described with respect to rackets 10e and 10f. Thus, racket 10g may be able to provide a softer feel for touch shots, and a harder feel for power shots.
As shown in
Once inner frame 266 has been snap-fit into outer frame 264, grip 268 may be coupled to the lower portions of outer frame 264 to secure those portions from opening again. This may provide additional securing for maintaining inner frame 266 within outer frame 264.
Shear thickening materials may also be incorporated into portions of rackets not specifically described above, as well as in any suitable portions of rackets described in PCT/EP2007/00929, and U.S. Pat. Nos. 7,077,767 B2 and 7,140,984 B2, the disclosures of all of which have been incorporated herein by reference.
Golf clubs, such as exemplary golf club 128 shown in
Golf club 128 may include a handle 130, a shaft 132, and a head 134. The construction of handle 130 may be similar to that described above with respect to handle region 30, in that handle 130 may include a portion of shaft 132, a grip, and/or grip tape. Shaft 132, the grip, and/or the grip tape may include shear thickening materials, much like handle region 30, grip 100, and/or grip tape 106 of
Shaft 132 may include a tubular body made of metal or composite material, such as a carbon fiber composite. Shaft 132 may be designed to have a degree of flex. Shaft flex is the amount that shaft 132 will bend when placed under a load. A stiffer shaft will not flex as much, and as a result, a user must generate more power in order to strike a golf ball properly. A user may be able to strike a golf ball properly with less power using a flexible shaft, but accuracy may suffer since the bending may result in the misalignment of head 134. Thus, manufacturers of golf clubs may make shafts with a variety of flexes to accommodate the different needs of users.
Composite material 18 shown in
Additionally or alternatively, shear thickening materials may be included in a portion of shaft 132 corresponding to an antinode 137. Antinode 137 may include a region of shaft 132 experiencing maximum vibrational displacement when golf club 128 strikes a golf ball. Alternatively, shear thickening materials may be used along the entire longitudinal length of shaft 132.
A hosel 138 may attach head 134 to shaft 132. Head 134 may include at least one hitting surface 140. Head 134 may be constructed of one or more layers of material, as shown in
Footwear, such as a shoe 144 shown in
Parts of shoe 144 may include, for example, a sole 146, a heel 148, an upper 150, and/or any other elements known to those skilled in the art. Sole 146 may include an insole 152, a midsole 154, and an outsole 156. The front half of shoe 144 will be referred to as the forefoot area, while the rear half of shoe 144 will be referred to as the heel area.
Insole 152 may include the interior bottom of shoe 144 sitting directly beneath a wearer's foot. Insole 152 may be fixed or removable. Removability allows insole 152 to be replaced or added for comfort or health reasons. Insole 152 may be at least partially constructed of one or more shear thickening materials. For example, shear thickening materials 153 may be found in the forefoot area of insole 152, the heel area of insole 152, or along the entire length of insole 152.
Outsole 156 may include a portion of sole 146 in direct contact with the ground. Outsole 156 may include a tread design configured to enhance traction with the ground. Outsole 156 may be at least partially constructed of shear thickening materials. For example, shear thickening materials 155 may be found in the forefoot area of outsole 156, the heel area of outsole 156, or along the entire length of outsole 156.
Midsole 154 may include the layer in between outsole 156 and insole 152, and may be designed to absorb shock. Midsole 154 may be at least partially constructed of shear thickening materials. For example, shear thickening materials 157 may be found in the forefoot area of midsole 154, the heel area of midsole 154, or along the entire length of midsole 154.
Heel 148 may be configured to support the heel of a wearer's foot. Heel 148 may be at least partially constructed of shear thickening materials. For example, a heel part 149 may include shear thickening materials 151. Additionally or alternatively, heel 148 may include one or more spaces designed to receive shear thickening materials.
Upper 150 may include those portions of shoe 144 above sole 146. Upper 150 may include, for example, woven material. The woven material may include shear thickening materials. The woven material may be composed of a plurality of panels. One or more of those panels, such as panel 158, may include shear thickening materials. It is also contemplated that different panels may include different shear thickening materials.
Snow sports products, such as ski 160 and snowboard 162 of
The cross section also depicts a base 166. Base 166 may be in contact with the snow surface when ski 160 or snowboard 162 is in use. Base 166 may be constructed of a porous, plastic material that may be saturated with a wax to create a very quick and smooth surface. Base 166 may also include shear thickening materials. For example, shear thickening material 167 may be mixed in with the porous, plastic material used to form base 166.
The cross section also depicts a laminate 168 surrounding core 164. Laminate 168 may include one or more layers of fiber reinforced material, such as fiberglass. The fiber reinforced material may be similar to composite material 18 of
The shear thickening materials may extend along the entire lengths of ski 160 and snowboard 162. Or, the shear thickening materials may be used in specific regions along the lengths of ski 160 and snowboard 162, such as in regions experiencing shear stress and/or bending stress, such as beneath bindings 174 and 176. Preferably, the shear thickening materials may be used in regions experiencing maximum shear stress and/or bending stress. Additionally or alternatively, shear thickening materials may be placed at antinodes, where ski 160 and snowboard 162 may experience maximum vibration displacement after an impact.
Bindings 174 and 176 may be configured to bind or hold a user's boot (not shown) on ski 160 or snowboard 162. Binding 174 may include a toe grip 178, a heel grip 180, and a plate 182. Shear thickening materials may be provided in toe grip 178, heel grip 180, and/or plate 182. A shear thickening layer 184 may be provided between toe grip 178, heel grip 180, and/or plate 182, and the top surface of ski 160. Shear thickening materials 177, 179, and 181 may also be provided where a user's boot (not shown) contacts toe grip 178, heel grip 180, and/or plate 182.
Binding 176 may include grips 186 and a plate 188. Shear thickening materials may be provided in grips 186 and/or plate 188. A shear thickening layer 190 may be provided between plate 188 and the top surface of snowboard 162. Layers 192 and 194 of shear thickening material may also be provided between plate 188 and a user's boot (not shown), and/or between grips 186 and a user's boot.
Shear thickening materials may be used in the construction of personal protection equipment. Personal protection equipment may include, for example, helmets, shoulder pads, torso protectors, cups, hand pads, arm pads, hip pads, tail pads, mouth guards, neck rolls, thigh pads, knee pads, shin guards, and foot pads, and/or any other personal protective equipment known to those skilled in the art. A helmet 196, a torso protector 198, and a lower body protector 200 will be described below, however, it should be understood that the descriptions below may be equally applicable to other forms of personal protection equipment.
Helmet 196, shown in
Padding 204 may line the inside surface of shell 202. Padding 204 may include one or more pads made of relatively soft or flexible material. Those materials may include shear thickening materials 201. Different regions of padding 204 may include different shear thickening materials. For example, the regions of padding 204 contacting the upper portion of a wearer's head may include shear thickening materials having a higher viscosity or more rigidity than shear thickening materials included in the regions of padding 204 contacting the lower portion of a wearer's head.
Torso protector 198, shown in
Lower body protector 200, shown in
With respect to each of the above descriptions of sports products, all of the components in the sports product that include shear thickening materials may include the same types of shear thickening materials. Alternatively, the components each may include a different type of shear thickening material. It is also contemplated that a component that includes a shear thickening material may include only one version of the shear thickening material. Alternatively, the component may include more than one version of the shear thickening material. For example, a component may include a shear thickening material having ingredients in amounts fitting a first ratio in a first region, and may include a shear thickening material having the same ingredients in amounts fitting a second ratio, different from the first ratio, in a second region. Thus, the shear thickening behavior of the component may vary between its regions. It is also contemplated that the component may include two or more entirely different types of shear thickening material. One type of shear thickening material may exhibit shear thickening behavior upon experiencing a first type of force, while another type of shear thickening material may exhibit shear thickening behavior upon experiencing a second type of force.
Sports products that include shear thickening materials in their construction may be enhanced in terms of their performance, wear resistance, and user comfort. Some of the enhancements are discussed below.
Using shear thickening materials in a racket, such as those shown in
Shear thickening materials may provide similar benefits when used in other parts of a racket. For example, shear thickening materials in a racket's frame may serve to harden the frame during impacts. The increased hardness of the frame may help protect the racket from wear or other damage caused by the impact. Shear thickening materials may also harden a racket's strings during impacts, which may help protect the strings from wear or other damage, especially at points where one string is in contact with another.
Another benefit that shear thickening materials may provide is vibration dampening. When a racket is used to strike a ball, or any other object, the impact may create vibrations. Without some mechanism for dampening the vibrations, the vibrations may be transmitted through the racket to the user's arm. Dampening those vibrations before they reach the user's arm may improve the “feel” of the racket. Using shear thickening materials in the construction of the racket may help dampen the vibrations. For example, the vibrations may originate in the area of impact. When the vibrations encounter the shear thickening materials in the racket (whether in the strings, frame, grip, or some other part), they may agitate the shear thickening materials as they attempt to pass, causing the shear thickening materials to become increasingly viscous or rigid. As the shear thickening materials become more viscous or rigid, it may become more and more difficult for the vibrations to pass. Thus, the shear thickening materials may create an energy absorbing barrier between the point of impact and the user's arm.
Another benefit has to do with adaptability. Different users may prefer different degrees of racket flexibility. One user may prefer a flexible racket because it may provide that user with greater control over the ball. Another user may prefer a stiff racket because it may provide that user with the ability to strike the ball harder. Yet another user may prefer a flexible racket under one set of circumstances, and a stiff racket under other circumstances. By using shear thickening materials in the construction of a racket, particularly in the racket's frame and/or strings, the racket may be adaptable, in that it may provide the benefits of both a flexible racket and a stiff racket in a single package.
For example, a flexible racket may be helpful to a user who is attempting to make a shot that requires touch or control. Touch shots typically involve low intensity impacts, or impacts that occur over a long timescale. Shear thickening materials in the racket may remain fluid or flexible during such impacts, and thus, the racket itself may remain flexible, helping the player execute the touch shot. On the other hand, a stiff racket may be helpful to a user who is attempting to make a shot that requires power. Power shots typically involve high intensity impacts, or impacts that occur over a short timescale. The shear thickening materials in the racket may stiffen during such impacts, and thus, the racket itself may stiffen, helping the player execute the power shot. Accordingly, a single racket can provide a user with the benefits of both a flexible racket and a stiff racket.
Additionally, shear thickening materials in a grip or handle area of a racket may remain flexible, and thus, deformable, during periods of play between impacts. Thus, the grip may easily conform to a user's hand, which may also improve the racket's “feel.” When the racket impacts an object, the shear thickening materials, and the grip itself, may become more viscous or rigid, giving the user greater control over the racket, while also dampening vibrations.
As another example, a user that is a beginner may prefer a more flexible racket, since it may provide the user with greater power. However, as the user's game and power improve, the user may prefer a stiffer racket that may provide the user with greater accuracy. In the past, the user would purchase one racket as a beginner, and another stiffer racket at a more advanced level. However, by using shear thickening materials, that single racket may be adequate at both skill levels. For example, a racket may include shear thickening materials that may remain flexible when exposed to forces generated by a beginner, which are typically lower than those generated by an advanced player. The shear thickening materials may stiffen when exposed to forces generated by an advanced player, and thus, the racket may be stiffer for the advanced player.
Using shear thickening materials in a golf club, such as that shown in
Another benefit the shear thickening materials may provide is vibration dampening. When a golf club strikes a golf ball, the impact creates vibrations, originating at a hitting surface of the golf club's head. Without some mechanism for dampening those vibrations, they may continue up a shaft of the golf club, into a handle or grip, and then into a user's arm. Providing shear thickening materials in the golf club, whether it be in the head, shaft, or grip, may help dampen the vibrations in a manner similar to that described above with respect to a racket. This may help improve the overall “feel” of the club, as experienced by its user.
Shear thickening materials may be used to make a golf club adaptable, giving the golf club different characteristics under different circumstances. It is known that different users may prefer different degrees of flexibility for their golf clubs. One user may prefer a more flexible golf club because it may provide that user with more power (due at least in part to the ability to store energy in a flexed shaft). Another user may prefer a stiffer golf club because it may provide that user with greater accuracy (due at least in part to less club movement during a stroke). Yet another user may prefer a more flexible club under one set of circumstances, and a stiffer club under other circumstances. By using shear thickening materials in a golf club, the golf club may be capable of providing the benefits of both flexible and stiff clubs.
For example, flexibility may be desirable in a shaft of a golf club during the backswing and downswing phases of a stroke. Shaft flex may load the shaft with energy, allowing the user to strike a golf ball with greater power. However, stiffness in the shaft may be desirable upon making contact with the ball, to prevent the impact from causing the club's head from becoming misaligned. By using shear thickening materials in the club's shaft, the shaft may have the desired flexibility during the backswing and downswing, as well as the desired stiffness at impact with the ball.
Additionally or alternatively, flexibility may be desirable in the club's hitting surface. For example, for short shots that may require greater control, keeping the hitting surface flexible may help provide that control. On the other hand, for long shots requiring greater power, keeping the hitting surface stiff may help to transmit as much power as possible from the club to the ball. Since short shots may typically be lower impact than long shots, the shear thickening materials in the hitting surface may remain flexible, giving the user greater control. On the other hand, the impacts associated with long shots may cause the shear thickening materials to stiffen, and thus, the hitting surface itself may also become stiffer. Accordingly, by using shear thickening materials in the construction of the hitting surface, both control and power may be achieved.
As another example, a user that is a beginner may prefer more flexible clubs, since they may provide the user with greater power. However, as the user's game and ability to generate power improve, the user may prefer stiffer clubs that provide the user with greater accuracy. In the past, the user would purchase more flexible clubs at the beginner level, and then stiffer clubs at a more advanced level. However, by using shear thickening materials, a single set of clubs may be adequate at both skill levels. For example, clubs may include shear thickening materials that may remain flexible when exposed to forces generated by a beginner, which are typically lower than those generated by an advanced player. Thus, the clubs may be flexible enough for the beginner. The shear thickening materials may stiffen when exposed to forces generated by an advanced player, and thus, the clubs may also be stiff enough for the advanced player.
Using shear thickening materials in footwear, such as that shown in
Using shear thickening materials in skis or snowboards, such as those shown in
A ski's ability to bend or flex as it carries a user is an important performance features. The flexing and counterflexing of the ski may help keep the user in control. The user, by shifting his or her weight, bending, and/or twisting, may manipulate the ski as the user goes over the contours of a slope. If snow conditions remain constant, a single type of ski with one flex profile could possibly be adequate. However, snow conditions may vary widely, even on a single slope. When the snow is hard, the user may desire a degree of rigidity in the ski. The rigidity may help the user dig the edges of the ski into the hard snow to make a turn. When the snow is soft, the user may desire a degree of flexibility in the ski. The flexibility may help the user bend the ski to make a turn. By using shear thickening materials in the construction of the ski, the ski may behave desirably in both conditions. For example, on hard snow, where impacts against the ski may be sudden and/or of a high magnitude, the shear thickening materials may become more viscous or rigid, giving to the ski the stiffness desired by the user. On the other hand, on soft snow, where impacts against the ski may occur over a long timescale, and/or may be of a low magnitude, the shear thickening materials may remain more fluid or flexible, giving the ski the flexibility desired by the user.
Shear thickening materials may also be helpful in the construction of a ski's binding. A loose attachment between a user's boot and the binding may result in less energy transfer from the ski to the user when the ski encounters obstacles on a slope. This may result in higher speeds, which may be important in sports, such as racing. However, the same loose attachment may result in a loss of ski control in turns. Accordingly, it may be desirable to have a loosely attached ski when traveling in a substantially straight line, for greater speed, and a tightly attached ski when making turns, for more control. By using shear thickening materials in the binding, or between the binding and the ski, the benefits of loose attachment and tight attachment may be achieved. For example, during substantially straight line travel, where shear forces on the ski, binding, and the user's boot may be low, shear thickening materials associated with the binding may remain fluid or flexible, giving the loose attachment the user desires. When turning, the shear forces on the ski, binding, and the user's boot may increase. Accordingly, the shear thickening materials associated with the binding may become more viscous or rigid, giving the tight attachment the user desires.
Shear thickening materials may also help to reduce vibration in a ski. As a user goes along the contours of a slope, variations in the contours may impact against the ski, causing vibrations. The vibrations may develop into an audible or perceptible chatter. Incorporating shear thickening materials into the ski, binding, and/or user's boot may help to absorb the chatter in a manner similar to that described above with respect to a racket.
Using shear thickening materials in personal protection equipment, such as those shown in
Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.
This application claims the benefit of U.S. Provisional Application No. 60/960,985, filed Oct. 24, 2007. The content of this provisional application is included herein by reference.
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