HOCKEY STICK
A composite hockey stick having a tubular hollow shaft and a blade is disclosed. The shaft includes a region of focused weight in the form of an overlay coating that is applied on top if the internal surfaces of the cured shaft using a coating plug. The blade includes a focused weight region that is inserted into a cavity within the cured composite blade. Methods and suitable materials for constructions of the various components of the blade and shaft are also disclosed.
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This application is a Continuation of U.S. patent application Ser. No. 12/221,913 filed Aug. 6, 2008, and now pending.
FIELD OF THE INVENTIONThe field of the present invention generally relates to hockey sticks and component structures thereof including such hockey sticks and components having focused weight distribution.
BACKGROUND OF THE INVENTIONHockey sticks are generally comprised of a blade portion and an elongated shaft portion. Traditionally, each portion was constructed of wood or a wood laminate and attached together at a permanent joint. These days many hockey sticks are constructed of engineered composite materials having either detachable or permanently attached blades. In these more contemporary constructions, the shaft is often times constructed by overlaying a mandrel of suitable dimension with plies of fibers and a resin to create an uncured shaft pre-form. The shaft pre-form is then cured by subjecting it together with the mandrel to heat which upon cooling results in the fibers being disposed in a hardened resin matrix. The mandrel is then removed by sliding it out of one end of the cured tubular shaft. The tubular composite shaft is often times further processed (painted, sanded etc.) and then either sold separately or mated to a detachable or permanently attached blade and sold as a complete hockey stick unit.
Similarly, contemporary composite hockey stick blades are typically constructed by wrapping multiple plies of fibers over one or more core elements to create a hockey stick blade pre-form. The blade pre-form is then placed within a mold where the resin, which is either pre-impregnated in the fiber plies or added via a resin transfer process, is cured. The curing process hardens the resin so that the fibers become disposed within a hardened resin matrix while the mold defines the exterior shape of the cured blade. Once molded and cured the blade may be further finished by deburring and perhaps with a coat of paint or exterior decals or the like and is then sold separately or as a hockey stick unit as previously described.
Typically the hockey stick blade is attached to the shaft via a “tennon” or “hosel” section, which is generally comprised of an upward extension of the blade from the heel and is dimensioned at its upper end to be slidably and snugly received within a generally rectangular lower tubular end of the shaft. Such hockey stick constructions and joints are disclosed in commonly owned U.S. Pat. Nos. 7,097,577 and 7,144,343 which are hereby incorporated by reference in its entirety. In addition to such four-plane lap joint connections, some composite hockey sticks employ connections in which the shaft and the blade are mated together in a tongue and groove type configuration located at the heel as is disclosed in commonly owned U.S. Pat. No. 7,097,577, which is also hereby incorporated by reference in its entirety.
Once cured, composite shafts and blades are typically not further processed other than in the way of exterior finishing steps like deburring, painting, decaling, assembly and perhaps in some cases applying a thin high-friction coating to the outer exterior of the shaft for purposes of enhancing the grip of the user. The weight distribution of the stick therefore is primarily determined by the fiber ply lay-up, the resin distribution, and in the case of the blade the core elements (typically a light heat expandable foam). The manner by which these materials are distributed along the shaft is primarily driven by structural concerns. For example, high impact areas may have additional plies of fibers. Shafts that are meant to have greater flexibility may have fewer plies or perhaps fewer plies oriented in a manner to stiffen the longitudinal flex of the shaft. While such constructions have found wide acceptance by hockey players world-wide, until now there has been little or no attention directed to positioning focused weight within discrete locations in the shaft and/or blade of a hockey stick.
SUMMARY OF THE INVENTIONThe present invention relates to hockey sticks, their manufacture, configuration, and component structures. Various aspects are set forth below.
One aspect is directed to composite hockey stick blades, such as those constructed of fibers disposed within a hardened resin matrix encapsulating one or more core elements such as a light foam, wherein the blade further includes a material of high density (e.g. metal) positioned internally within the blade. The high density material may be positioned at the heel region or other regions of the blade such as the mid section or toe region thereby creating a focused weight distribution within the blade. The dense material may take any form from particles to solid strips to ball bearings or pellets and may be encapsulated in one or more materials including, for example, a woven fiber sock or other suitable material. A polyurethane elastomer or some other suitable polymer or material may also encapsulate the dense material while also serving as a means to secure the dense material in the desired location within the blade.
Another aspect is directed to methods of making the focused weight hockey stick blade that include providing a cured composite blade that is constructed to include an internal pocket that extends through at least one external surface of the cured blade construct and positioning a high density material within the cured blade construct at the desired location. The process of positioning may including plugging the pocket, such as by a foam plug system. The method may also include filling a portion of the cavity with a suitable polymer such as polyurethane elastomer to further encapsulate and secure the position of the high dense material. The polymer may also serve as a vibration dampener and provide additional weight to the focused weight component.
Another aspect is directed to tubular composite hockey stick shafts, such as those constructed of fibers disposed within a hardened resin matrix, wherein a discrete region of the internal walls of the tubular shaft is coated with a material. The additional weight added by the coating results in a region of focused weight. While the coating may be applied anywhere along the longitudinal length of the shaft in continuous or discrete locations, it is contemplated that the coating be applied within the upper half of the shaft. The coating may be comprised of a variety of materials having suitable characteristics (e.g., adherence to the inner walls of the shaft, flexibility, durability, impact resistance, etc.). One such material is a thermoplastic adhesive having flexibility at low temperature.
Another aspect is directed to a method of making a focused weight tubular hockey stick shaft that includes coating an internal wall region of a tubular hockey shaft by inserting a suitably dimensioned coating plug into the upper end of a tubular hockey stick shaft and positioning the plug at the desired location where the coating is to be applied; adding a selected amount of coating material above the plug; applying heat; and allowing the coating plug to move upward along the shaft thereby applying the coating to the internal walls of the shaft. The movement of the coating plug up the shaft may be facilitated in part or in whole by gravity. The region coated in the shaft may be discretely located within the shaft. In the case of a composite shaft constructed of fibers disposed within a hardened resin matrix, it is contemplated that the coating be applied after the shaft is cured.
Yet another aspect is directed to hockey sticks having focused weight blades and/or shafts as described above and methods for making such hockey sticks. The stick may be a two part stick with a detachable blade or a blade that is permanently attached. The stick may have focused weight in both the shaft and the blade, only in the blade or only in the shaft. It is contemplated that approximately an equal amount of focused weight be added to the shaft as added to the blade. It is also contemplated that existing composite hockey stick shafts and blade constructs may be made lighter (using fewer plies in certain regions of the constructs) and the weight saved in lightening the construct be added back as focused weight as described above, such that the total weight of the shaft, blade or hockey stick remains the same or substantially the same as it did before.
Additional implementations, features, variations and advantageous of the invention will be set forth in the description that follows, and will be further evident form the illustrations set forth in the accompanying drawings.
The accompanying drawings illustrate presently contemplated embodiments and constructions of the invention and, together with the description, serve to explain various principles of the invention.
Preferred embodiments will now be described with reference to the drawings. To facilitate description, any reference numeral designating an element in one figure will designate the same element if used in any other figure. The following description of preferred embodiments is only exemplary. The present invention is not limited to these embodiments, but may be realized by other implementations. Furthermore, in describing preferred embodiments, specific terminology is resorted to for the sake of clarity. However, the invention is not intended to be limited to the specific terms so selected, and it is to be understood that each specific term includes all equivalents.
The shaft 20 is tubular and may be constructed of fibers disposed within a hardened resin matrix. The fibers may be aligned and oriented in defined directions with an outer layer often being a woven fiber. Various fibers may be employed including carbon, aramid (e.g., Kevlar™), boron, glass, etc.
It is contemplated that an existing shaft lay-up could be modified to lighten the overall weight of the shaft while retaining the desired strength. This could be accomplished via removing plies in certain regions of the shaft, varying the orientation of the fibers, and/or the selection fibers and/or resin. The weight saved by doing so could be added back to the shaft 20 as a focused weight overlay coating 300 so that the total shaft weight of lighter shaft (including focused weight overlay coating 300) would be the same or approximately the same as it had been (i.e., with the prior heavier lay-up and without the focused weight overlay coating 300 being added).
The overlay coating 300 may be comprised of a variety of materials having suitable characteristics (e.g., adherence to the inner walls of the shaft, flexibility, durability, impact resistance, etc.). The overlay may be comprised of a polymer, an adhesive, a plastic or a combination of softer and harder materials.
One such material is a thermoplastic adhesive such as that marketed by 3M under the Scotch-Weld™ hot melt bonding systems part number 3764. This particular thermoplastic adhesive is flexible at low temperature, has good impact resistance including at low temperature and bonds well to a variety of plastics including polycarbonate, polyethylene and polypropylene. The following is a listing of this particular product's properties:
The following are the ingredients of this particular thermoplastic adhesive product: (1) ethylene-vinyl acetate polymer (50-65% by weight); (2) hydrocarbon resin (25-35% by weight.); (3) polyethylene polymer (5-10% by weight); (4) polyolefin wax (1-5% by weight); and (5) antioxidant (0.5-1.5% by weight).
It is contemplated that the overlay coating 300 may be a mixture of a base coating and another more dense material such as small metallic or high density pellets to increase the aggregate density of the overlay coating 300. It is further contemplated for example, that carbon steel pellets having a diameter of 0.017 inches and a density of 7.8 g/cm.sup.3 may be mixed with a base material (e.g., a thermoplastic adhesive) to create the overlay coating 300.
The overlay coating 300 may be applied to the shaft in the following manner. First, in the case of a composite shaft such as those described above, after the tubular shaft is cured and the mandrel is removed, a determination is made as to how much additional weight is desired to be added to the cured shaft. Second, a determination as to where the focused weight is to be positioned along the length of the shaft is made. Third, the overlay coating material is selected taking into account the weight being added and the position of the weight along the shaft. More dense materials may be selected when greater weight is required and/or when the region where the weight is being added is relatively compact. Fourth, the overlay coating 300 is applied to the internal surfaces of the walls of the shaft 20 in the desired region. It is contemplated that the overlay coating 300 may be applied to multiple regions of the shaft in discrete areas along one, two, three or all four walls 26, 27, 28, and 29 of the shaft 20.
One method of applying the coating to the internal surface regions of the tubular shaft 20 is to use a coating plug 500, such as that illustrated in
Once the coating plug 500 is positioned in the desired location, a pre-defined amount of overlay coating material 570 (e.g., thermoplastic adhesive or perhaps a mixture of thermoplastic adhesive with carbon steel pellets as described above) is added into the hollow 23 of the shaft 20 so that it rests on top of the coating plug 500. This is illustrated in
After loading the shaft 20 with the coating plug and material 500 and 570, the shaft 20 is then heated preferably while the shaft 20 stays in the upright or vertical position to prepare the coating material 570 for application. An appropriate temperature and time is selected to sufficiently soften the coating material to a suitable viscosity in preparation for application to internal walls of the shaft. In the case of the thermoplastic adhesive material described specifically above, placing the shaft (including plug loaded with coating material) in a pre-heated oven at 250° F. for approximately 15 minutes has been found sufficient to reduce the viscosity of the coating material such that it is capable of exhibiting suitable flow characteristics for application to the shaft wall. After heating the shaft 20 is hung a distance by the protruding line extending upwardly from the coating plug 500 as illustrated in FIGS. 6 and 7. It is preferable that shaft 20 be hung such that lower end of the shaft 20 or tip resides above the ground a distance greater than L3, which is the expected or calculated longitudinal length of the overlay coating 300. Once the shaft is hung a force such as gravity or some man made force, will pull the shaft downward away from the coating plug 500, the coating plug will slide-up along the inside of the shaft and in the process apply the coating material 570 to the shaft 20, thereby creating the focused weight overlay coating 300 along the L3 region of the shaft 20. These steps are illustrated in
As illustrated in
Just prior to insertion of the foam element 631 into the cavity of the blade 30, the foam element 631 and backing material 633 are dipped in or coated with a liquid foam material 634, which upon expansion serves to firmly lodge the plug within the cavity of the blade 30 at the desired location. This step is illustrated in
Once the plug system 630 is installed, a high density material or component 650 is inserted into the blade cavity 37. The plug system 630 serves to block the high density material/component from movement toward the tip of the blade thereby control its position. Additional plug systems can be used in positioning multiple high density material/components 650. While it is contemplated that any suitable material may be used, the illustrated embodiment employs a high density component that is comprised of steel balls 605 housed within a woven E-glass sock 610. High density in this context refers to the relative density of the material or component vis-à-vis the surrounding blade structural components. The addition of a high density component serves to focus the weight distribution to the region in which it is positioned. It is contemplated that the additional weight added by the focused weight component 600 and the plug system 630 may be offset by corresponding reductions in the weight of the blade via for example removal of plies in certain regions of the shaft, varying the orientation of the fibers, and/or the selection fibers, core elements, and/or resin. Thus, it is contemplated that an existing blade construction may be modified to lighten the weight of the blade so that when the focused weight component 600 is added the overall weight of the blade 30 remains substantially or approximately the same.
Turning to
As a general proposition, a hockey puck gains its velocity and direction as a result of impact mechanism with the blade as it is maneuvered by a hockey player. The impact mechanism is a complex phenomena, e.g. involving transfer of energy via elastic plastic deformation on the puck, blade, and shaft. The end condition of the puck (e.g., its velocity and trajectory), primarily depends on this impact mechanism. The blade's center of gravity, its stiffness distribution and curvature, among others, are all important. The addition of regions of focused weight in the blade at one or more strategic location(s) allows customization of the impact mechanism thereby tailoring the characteristic of the puck lunching condition. This is particularly true when the focused weight is added to the heel region of the blade. The heel region of the blade is generally more stiff than the toe region in that the toe is generally significantly thinner than the heel area. The heel region also resides between the majority of the blade face and the shaft where the players hands are in contact. Thus, forces on the blade generally pass through the heel before they reach the players hands. The heel region is also generally the region in which high impact shots are taken. Thus, the heel region is particularly suitable for positioning the focus weight, in that its position is suitable for curtailing/dampening unwanted vibration while also proximal to the regions where high impact shots are taken.
It is contemplated that the focused weight component 600 as a percentage of total blade weight range broadly from 2% to 35%, preferably from 5% to 25%, even more preferably from 7.5% to 20%, and yet even more preferably from 10% to 15%. Typical composite blades range from 90 grams to 250 grams for skaters and well over 300 grams for goalie sticks.
While there has been illustrated and described what are presently considered to be preferred embodiments and features of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made, and equivalents may be substituted for elements thereof, without departing from the scope of the invention. For example, it is contemplated that access to the blade cavity may be through any surface not just the end of the hosel. It is contemplated that connection joint of the blade and the shaft be different than that illustrated in the drawings. It is contemplated that shaft be aluminum or some other tubular structure that includes a focused weight overlay. It is contemplated that the both the shaft and blade include focused weight regions or alternatively on the blade or only the shaft. It is contemplated that the blade and the shaft have the same or approximately the same amount of focused weight added to them or that they be different (i.e., the shaft has more weight added than the blade or vice-a-versa). It is contemplated, that the blade and shaft be sold separately or sold as a hockey stick. It is contemplated that the connection between the shaft and blade be facilitated by an intermediate connection member and that focused weight may be added to that connection member. It is contemplated that the focused weight component be added externally to the shaft and/or blade.
In addition, many modifications may be made to adapt particular element, feature or implementation to the teachings and of the present invention without departing from the central scope of the invention. Therefore, it is intended that this invention not be limited to the particular embodiments disclosed herein, but that the invention include all embodiments falling within the scope of the appended claims. Thus, it should be understood that various aspects of the teachings and principles disclosed herein relate to configuration of the blades and hockey sticks components elements thereof. Other aspects relate to internal construction of the component elements and the materials employed in their construction and the methods of their manufacture and assembly. Yet other aspects relate to the combination of the foregoing aspects. The combination of one, more than one, or the totality of these aspects defines the scope of the invention disclosed herein. No other limitations are placed on the scope of the invention set forth in this disclosure. Accordingly, what is disclosed as inventive herein is only limited by the scope of this disclosure that supports or otherwise provides a basis (expressly, impliedly or inherently) for patentability over the prior art. Thus, it is contemplated that various component elements, teachings and principles disclosed herein provide multiple independent basis for patentability. Hence no restriction should be placed on any patentable elements, teachings, or principles disclosed herein or combinations thereof, other than those that exist in the prior art.
Claims
1. A composite, focus-weighted hockey stick blade, comprising:
- a shaft-engaging region, a heel, a mid-section, and a toe;
- a cavity in the composite blade including a passage through an outer surface of the shaft-engaging region; and
- a component of higher density than surrounding blade regions positioned in the cavity.
2. The hockey stick blade of claim 1 wherein the component of higher density comprises a plurality of metal balls housed in a sock.
3. The hockey stick blade of claim 1 further comprising an elastomeric material in the cavity encapsulating the component of higher density.
4. The hockey stick blade of claim 1 further comprising a plug positioned against a first end of the component of higher density.
5. The hockey stick blade of claim 1 wherein the component of higher density is positioned in a portion of the cavity in the heel.
6. The hockey stick blade of claim 1 wherein the component of higher density is positioned in a portion of the cavity extending from the shaft-engaging region to the heel.
7. The hockey stick blade of claim 6 wherein the component of higher density extends in a first substantially horizontal direction and in a second direction at an angle to the first substantially horizontal direction.
8. The hockey stick blade of claim 1 wherein the component of higher density is positioned in at least one of the mid-section and the toe.
9. The hockey stick blade of claim 1 further comprising an additional component having a higher density than, and positioned in the cavity vertically below, the component of higher density than surrounding blade regions.
10. The hockey stick blade of claim 1 wherein a plurality of components of higher density than surrounding blade regions are located in the cavity at multiple lengthwise positions of the blade.
11. The hockey stick blade of claim 1 wherein the shaft-engaging region includes a connection member configured to engage a hockey stick shaft, and wherein the passage extends through an outer surface of the connection member.
12. The hockey stick blade of claim 1 wherein the connection member is configured to be received within a tubular hockey stick shaft.
13. A focus-weighted hockey stick blade, comprising:
- a shaft-engaging region, a heel, a mid-section, and a toe;
- a cavity in the blade; and
- a weight-focusing component, having a higher density than surrounding blade regions, occupying a portion of the cavity extending from the shaft-engaging region to the heel.
14. The hockey stick blade of claim 13 wherein the cavity extends from the shaft-engaging region to, or adjacent to, the toe.
15. The hockey stick blade of claim 13 wherein the surrounding blade regions comprise at least one composite material.
16. The hockey stick blade of claim 13 wherein the shaft-engaging region includes a connection member configured to engage a hockey stick shaft, and wherein a passage extends through an outer surface of the connection member into the cavity.
17. The hockey stick blade of claim 13 further comprising an elastomeric material in the cavity encapsulating the weight-focusing component.
18. The hockey stick blade of claim 1 wherein the weight-focusing component comprises a plurality of metal balls housed in a sock.
19. A focus-weighted hockey stick blade, comprising:
- a shaft-engaging region, a heel, a mid-section, and a toe;
- a cavity in at least the heel of the blade; and
- a plurality of metal balls housed in a sock occupying at least a portion of the cavity.
20. The hockey stick blade of claim 19 further comprising a passage extending through an outer surface of the shaft-engaging region into the cavity.
Type: Application
Filed: Mar 8, 2011
Publication Date: Jun 30, 2011
Applicant: EASTON SPORTS, INC. (Van Nuys, CA)
Inventor: Citra A. Le (San Diego, CA)
Application Number: 13/043,361
International Classification: A63B 59/14 (20060101);