Despite the current popularity of hockey, television viewing is hampered by the poor visibility of the hockey puck as it moves around the ice at high speeds. In order to be able to view all areas of the ice rink, cameras must be located far from the ice rink. Thus, a standard hockey puck tends to appear as a small dot on the screen. As a result, it is difficult to follow the puck as it is passed from player to player, and it is especially difficult to follow the puck as it is shot toward the goal and either deflected, caught or missed by the goalie. Often, viewers recognize a score only when a signal light is lit or the announcer informs the viewer that a goal has been scored.
U.S. Pat. No. 5,564,698 discloses a hockey puck including electromagnetic transmitters. The transmitters transmit a signal, for example an IR signal, which is captured in one or more sensors around the ice rink. The sensors are able to locate the instantaneous position of the hockey puck, which permits enhancement of the image of the puck on a television monitor. It is important that the transmitters within the puck not affect the overall dimensions of the puck, or the performance of the puck, such as its feel when struck and its reaction when received on a stick or bouncing off a surface.
Embodiments of the present technology relate to a hockey puck including an internal transmitter enabling instantaneous identification of its position as it moves around. In embodiments, the puck is comprised of two molded subcomponents, which encapsulate a signal transmitter and are sealed together to form the hockey puck. The signal transmitter may include driver electronics and a number of signal transmitters which together generate and emit an electromagnetic signal. In one embodiment, the electromagnetic signal may be infrared (IR) light emitted by a plurality of diodes mounted in openings in the subcomponents, for example around an outer circumference of the hockey puck and through a top and bottom surfaces of the hockey puck. In still further embodiments, the puck may be formed of a material that allows electromagnetic radiation to be emitted through the subcomponents, and the diode cavities may be omitted.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Embodiments of the present technology will now be described with reference to the figures, which in general relate to a hockey puck including an internal signal transmitter enabling instantaneous identification of the puck position as it moves around an ice rink. In embodiments, the puck is comprised of two molded subcomponents, which encapsulate a signal transmitter and fit together to form the hockey puck. The two molded subcomponents may be formed of vulcanized rubber, and may include various features for supporting the signal transmitter and for ensuring a tight and secure fit when the subcomponents are joined together. In embodiments, the subcomponents may be formed of top and bottom halves, or an outer ring surrounding an inner plug.
It is understood that the present invention may be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete and will fully convey the invention to those skilled in the art. Indeed, the invention is intended to cover alternatives, modifications and equivalents of these embodiments, which are included within the scope and spirit of the invention as defined by the appended claims. Furthermore, in the following detailed description of the present invention, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be clear to those of ordinary skill in the art that the present invention may be practiced without such specific details.
The terms “top” and “bottom,” “upper” and “lower” and “vertical” and “horizontal,” or variations thereof, as may be used herein are by way of example and illustrative purposes only, and are not meant to limit the description of the invention inasmuch as the referenced item can be exchanged in position and orientation. Also, as used herein, the terms “substantially” and/or “about” mean that the specified dimension or parameter may be varied within an acceptable manufacturing tolerance for a given application. In one embodiment, the acceptable manufacturing tolerance is ±0.25%.
The signal transmitter may include a printed circuit board with driver electronics, power source and a number of signal transmitters which together generate and emit an electromagnetic signal. In one embodiment, the electromagnetic signal may be infrared (IR) light emitted by a plurality of diodes around an outer circumference of the hockey puck and through top and bottom surfaces of the hockey puck. Other wavelengths of electromagnetic energy may be used in further embodiments. In embodiments, the printed circuit board and diodes may be encased within a capsule, but the capsule may be omitted in further embodiments.
In embodiments using diodes, the subcomponents may be formed with openings around the outer circumference and top and bottom surfaces for receiving the diodes. The openings allow ends of the diodes to extend to the outer surface of the puck to enable signal emission from the puck. In embodiments where the diodes are encased within a capsule recessed within the puck, signals from the diodes may be communicated from the diodes to the outer surface of the puck by light pipes provided in the openings in the subcomponents. In still further embodiments, the puck may be formed of a material that allows electromagnetic radiation to be emitted through the subcomponents, and the diode openings may be omitted.
The physical characteristics of the puck of the present technology may be the same as a conventional puck without a signal transmitter. Thus, the composition of the subcomponents may be customized for each embodiment of the signal transmitter. The physical characteristics may for example include the look, feel, size and weight of the puck. The physical characteristics may further include the performance of the puck, such as its feel and reaction when caught, struck or passed, and its reaction when bouncing off a surface.
As explained below, puck 100 may house a signal transmitter. As such, subcomponents of the puck 100 may be molded, and then assembled together with the signal transmitter encased within an interior of the puck 100. In the embodiment shown in
However, as explained below, the ratios of the various materials may be adjusted relative to those used in a conventional hockey puck to provide the same performance as a conventional hockey puck despite the hollow core and signal transmitter encased therein. In addition to or instead of varying the ratio of the puck materials, the cure time and/or temperature at which the subcomponents 106, 108 are formed may vary relative to that of a conventional hockey puck to provide the same performance as a conventional hockey puck.
The signal transmitter 110 emits electromagnetic radiation from the different surfaces of the puck 100, which radiation is detected by sensors around the ice rink regardless of the orientation of the puck 100. The sensors are able to locate the instantaneous position of the hockey puck, which permits enhancement of the image of the puck on a television monitor. For example, the puck may be highlighted in different colors, or different-colored contrails may be shown behind the puck, as it is shot, passed, leaves the ice surface or enters the goal.
Details of the electronics and components of signal transmitter 110 are disclosed for example in U.S. Pat. No. 5,564,698, entitled “Electromagnetic Transmitting Hockey Puck.” However, referring now to the perspective view of
In embodiments, the signal transmitter 110 may further include a number of diodes 120 (some of which are numbered in
In the embodiment shown, there are a total of eighteen diodes 120: four axially extending diodes 120a on a top surface of PCB 114 (to emit a signal from a top surface of the puck), four axially extending diodes 120b on a bottom surface of PCB 114 (to emit a signal from a bottom surface of the puck), and ten radially extending diodes 120c extending radially from the outer circumference of the PCB 114 (to emit the signal from an outer circumference of the puck). Thus, radiation from the puck may be detected regardless of an orientation of the puck. It is understood that the signal transmitter 110 may include more or less diodes 120 in further embodiments, and diodes in other places than shown. When the puck 100 is fully assembled, outer ends of the diodes 120 (i.e., most distal from the PCB 114) may lie flush with the exterior surfaces 103 of the subcomponents 106, 108.
As opposed to embodiments described hereinafter, the signal transmitter 110 in the embodiment of
As seen in
As seen in
The cavities 122, holes 102, channels 124 and other indentations on the interior surfaces 105 of subcomponents 106, 108 allow the subcomponents 106, 108 to fit tightly together with the signal transmitter 110 enclosed snuggly therebetween. With the exception of holes 102 and channels 124, no other indentations formed on the interior surfaces of subcomponents 106, 108 are open to an exterior of the puck 100.
The interior surfaces 105 of subcomponents 106, 108 further include keyed features 130 for ensuring a tight and secure fit of the subcomponents when they are glued to each other. The keyed features 130 may be in a variety of different configurations, some of which are shown in the drawings. In
The features 130 may have various characteristics. First, the features provide a relatively large surface area for receiving glue as explained below to securely affix the subcomponents 106 and 108 to each other. Second, in embodiments, the features 130 may be sandblasted, or formed within a mold that is sandblasted. The features/mold may alternatively be chemically etched. Sandblasting/chemical etching increases the surface area and provides nooks and crannies for the glue between adjacent surfaces of the features 130 of subcomponents 106, 108. Sandblasting may be omitted in further embodiments. Third, extending vertically, the features 130 are able to exert lateral forces against each other (for example parallel to the top and bottom surfaces of the puck 100) to provide a resistance to shear forces when the subcomponents are affixed together and thereafter.
The cones are arranged on the respective rings 140 such that, when the subcomponents 106, 108 are mated together, a positively extending cone mates within a negatively recessed cone in the opposite subcomponent. In the embodiments of
Referring again to the exploded perspective view of
The capsule 144 includes light pipes 156 and 160 for receiving diodes 120 and for communicating the electromagnetic radiation from diodes 120 to the exterior surface 103 of the hockey puck 100. Each sub-capsule half 146, 148 includes axially extending light pipes 156 (
The capsule 144 may further include radially extending light pipes 160 extending from an outer circumference of capsule 144. The radially extending light pipes 160 in capsule 144 receive the radially extending diodes 120c extending from the outer circumference of the PCB 114. Each of the radially extending light pipes 160 is formed of two mating pieces, with a first piece formed in sub-capsule half 146 and a second, complementary piece formed in sub-capsule half 148. The two pieces fit together around diodes 120c when the sub-capsule halves 146, 148 are brought together. The light pipes 160 in turn fit within channels 124 in the subcomponents 106, 108 to be flush with the exterior surface 103 of the subcomponents 106, 108.
The first and second pieces in respective halves may have the same configuration, each forming one-half of the light pipe 160. However, in other embodiments, the pieces may be dissimilar. For example, in
The sub-capsule halves may each have a cavity 122 for receiving the battery 112 as described above. The subcomponents 106, 108 may each include a recess 153 (
The capsule 144 includes notches 164 as shown for example in
Exterior surfaces of the sub-capsule halves 146, 148 may include dimples 168 (
In order to communicate the electromagnetic radiation from the diodes 120 within the capsule 144, the embodiment of
Further details of the puck 100 of the embodiment of
As seen for example in
Further details of the subcomponents 106, 108 of the embodiment of
While the embodiment of
In embodiments described thus far, subcomponents 106 and 108 are top and bottom halves of the hockey puck 100.
In the embodiment of
The channels 186a receive and mate with the upwardly extending diodes 120a. A bottom portion 192 of the channels 186a may be sealed. The subcomponent 182, referred to hereinafter as cover 182, includes a number of axial recesses 196a and axial protrusions 196b around its outer circumference. The recesses 196a align with channels 186a and, together with the channels 186a, enclose the upwardly extending diodes 120a along their lengths when cover 182 is sealed within the opening 184. The recesses 196a and channels 186a are open at an upper surface of the puck 100 to allow emission of electromagnetic radiation from diodes 120a at the upper surface, as shown in the top view of puck 100 in
The protrusions 196b align with and fill channels 186b. As shown in the cross-sectional view of
In operation, a subcomponent, such as for example subcomponent 108, may be placed on a platform 212 on the bottom plate 206. The fixture 210 may then be fit down over the bottom plate 204 so that adjacent surfaces of the fixture 210 and bottom plate 204 lie contact with each other. The bottom plate 206 may include a pair of upwardly extending guideposts 214 received within guide holes 216 in fixture 210 to ensure precise alignment of the fixture 210 on top of the bottom plate 206.
The fixture 210 includes a central opening 220 which fits down over platform 212. The central opening has a raised surface 222 so that a height of the cylindrical walls of opening 220 are equal to the height of the platform 212 plus the height of the subcomponent 108 on top of platform 212. An uppermost circular portion of the cylindrical walls of opening 220 (where the raised surface 222 meets the cylindrical walls) defines a lip 224.
The top plate 204 and top fixture 208 have the same configurations and structures as lower plate 206 and bottom fixture 210, as indicated for example by those components which are numbered on top plate 204 and top fixture 208. The top plate and fixture 204, 208 may be turned upside down, and the second subcomponent, for example subcomponent 106, may then be placed on a platform 212. The top fixture 208 may then be fit over top plate 204 to secure the subcomponent 106 in place as described above with respect to the bottom plate and fixture.
An adhesive material may then be applied to the features 130 (described above) on the interior surface(s) of subcomponent 106 and/or 108. The top plate 204, top fixture 208 and subcomponent 106 may then be flipped and fit on top of bottom plate 206, bottom fixture 208 and subcomponent 108. The guideposts 214 in top plate 204 fit through the guide holes in bottom fixture 210. Similarly, the guideposts 214 in bottom plate 206 fit into guide holes 216 in the top fixture 208. This ensures proper alignment of all components in the press 200, and proper alignment of the subcomponents 106 and 108 with respect to each other.
Thereafter, large compressive forces may be applied to the top and bottom plates 204, 206 by a hydraulic device (not shown) to press the features 130 on the interior surfaces of subcomponents 106, 108 against each other. The adhesive may then be cured under pressure for a period of time, and possibly at an elevated temperature. The adhesive may form a mechanical or chemical bond to seal the subcomponents 106, 108 together. The pressure may squeeze out any excess adhesive from between the subcomponents 106 and 108. The press 200 may be heated during the gluing process to reduce the hydrostatic pressure generated by the glue as it is forced out from between the subcomponents 106, 108.
The tight engagement of the lip 224 against the seam 104 in the subcomponents 106 and 108 ensures that, as glue is squeezed out from between subcomponents 106 and 108, the excess glue enters a space 226 defined between the top and bottom fixtures 208, 210. Significantly, the tight engagement of the lip 224 against the seam 104 prevents any excess glue from passing between the respective subcomponents and fixtures, onto the outer circumferential edge of the subcomponent 106 and/or 108. As discussed above, the outer circumferential edge of the hockey puck 100 may include a dimple pattern. The tight engagement of the lip 224 against the seam 104 prevents adhesive from bleeding onto the dimple pattern.
Turning now to the fabrication of the subcomponents of hockey puck 100, the subcomponents may be formed of vulcanized rubber, for example containing natural rubber, oils for durability, minerals for curing and anti-aging agents, and coal dust (carbon black) for color. The various materials of the subcomponents may be thoroughly mixed together in predefined ratios, and then placed in a mold under pressure of a hydraulic press and cured, for example at 300° F. to 500° F. for 15 to 20 minutes. These temperatures and times are by way of example only, the curing temperatures and times may be lower or higher than the stated ranges in further embodiments.
The materials and ratios are controlled to provide the puck 100 with the same characteristics and properties as a conventional puck not having a signal transmitter core. For example, the signal transmitter in the hollow core tends to increase the amount by which the puck bounces off a surface as compared to a conventional puck. Thus, the materials and/or ratios may be controlled to be relatively energy absorbing so as to deaden the response of the subcomponents in comparison to the vulcanized rubber used in a conventional puck. In this way, the response of puck 100 including the signal transmitter core is the same as a conventional puck. It is understood that the materials and/or ratios may be varied, depending on whether the signal transmitter 110 is encased within a capsule 144 or sealed within the puck 100 without a capsule 144.
The subcomponents may be made in two pieces, and then glued around the signal transmitter 110 (as the signal transmitter may not withstand the curing conditions for the subcomponents if a single subcomponent were molded around the signal transmitter). However, in further embodiments, it is contemplated that the vulcanized rubber be molded in a single piece around the signal transmitter. In such embodiments, the signal transmitter may be encased in a capsule as described above, or not encased in a capsule as described above. The press 200 may form a single puck 100. Alternatively, the press may be elongated (or made into an x-y matrix) including multiple central openings 220 and other components described above for receiving multiple pairs of subcomponents 106, 108, so that multiple pucks 100 may be formed in a single process.
In embodiments described above, the subcomponents include openings so that the electromagnetic radiation from the diodes may be transmitted through the subcomponents to an exterior of the puck 100. In embodiments, the vulcanized rubber of the subcomponents may include carbon black, which prevents the transmission of certain wavelengths of electromagnetic radiation, such as for example radiation in the IR wavelengths.
In further embodiments of the present technology, the puck may be formed of materials that are transparent to the wavelengths of the electromagnetic radiation emitted from the signal transmitter 110. In such embodiments, the axial openings and radial channels in the subcomponents may be omitted, and the electromagnetic radiation may be transmitted through the walls of the subcomponents. Such an embodiment is shown in the perspective view of
It is further conceivable that the signal transmitter transmits at wavelengths that are not blocked or absorbed by carbon black. In such embodiments, the vulcanized rubber of puck 100 may include carbon black.
In summary, embodiments of the present technology relate to a hockey puck, comprising: first and second subcomponents including complementary features operable to mate with each other, the first and second subcomponents together defining a central void interior to the first and second subcomponents together; a capsule sized and shaped to fit within the central void of the first and second subcomponents, the capsule including a central space interior to the capsule; and a signal transmitter sized and shaped to fit within the central space of the capsule, the signal transmitter operable to emit electromagnetic radiation to enable detection of an instantaneous position of the hockey puck.
In further embodiments, the present technology relates to a hockey puck, comprising: first and second subcomponents including complementary features operable to mate with each other, the first and second subcomponents together defining a central void interior to the first and second subcomponents together; and a signal transmitter sized and shaped to fit within the central void of the first and second subcomponents, the signal transmitter operable to emit electromagnetic radiation to enable detection of an instantaneous position of the hockey puck; wherein the first and second subcomponents comprise a first set of materials, the first set of materials absorbing a greater amount of energy than a second set of materials used in a second hockey puck having a solid core without the signal transmitter.
In other embodiments, the present technology relates to a hockey puck, comprising: first and second subcomponents including complementary features operable to mate with each other, the first and second subcomponents together defining a central void interior to the first and second subcomponents together; and a signal transmitter sized and shaped to fit within the central void of the first and second subcomponents, the signal transmitter operable to emit electromagnetic radiation in a wavelength band to enable detection of an instantaneous position of the hockey puck; wherein the first and second subcomponents comprise materials that are transparent to the wavelength band at which the electromagnetic radiation is emitted.
Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims. It is intended that the scope of the invention be defined by the claims appended hereto.
This application is related to and claims priority from the following U.S. patents and patent applications. This application is a continuation of U.S. application Ser. No. 16/027,594, filed Jul. 5, 2018, which is a continuation of U.S. application Ser. No. 15/260,122, now U.S. Pat. No. 10,016,669, filed Sep. 8, 2016, each of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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Parent | 16027594 | Jul 2018 | US |
Child | 16503061 | US | |
Parent | 15260122 | Sep 2016 | US |
Child | 16027594 | US |