Patent Publication Number: US-2019168080-A1

Title: Inflation-independent ball with cover

Description:
CROSS REFERENCE TO PENDING APPLICATIONS 
     This application is a divisional of and claims priority to, and the benefit of, pending U.S. patent application Ser. No. 13/826,428 filed Mar. 14, 2013 titled “Inflation-Independent Ball with Cover.” 
    
    
     FIELD OF THE INVENTION 
     The invention relates generally to sports balls, such as basketballs, footballs, volleyballs and soccer balls. 
     BACKGROUND ART 
     Sports balls of the type traditionally inflated (e.g., basketballs, footballs, volleyballs and soccer balls) are well known in the art and are sometimes referred to as “inflatables.” For example, basketballs are generally manufactured to include an inflatable air bladder surrounded by an outer covering of cover panels. Other inflatable sports balls such as volleyballs, soccer balls and footballs also feature the well-known inflatable air bladder (often comprising rubber, such as 80% butyl rubber and 20% natural rubber) and various other outer coverings. One limitation of current inflatable technology is that the inflatable air bladder may lose pressure after a period of time due to air loss, which may occur by seepage from valves, or by migration of the filled air across the air bladder membrane, or otherwise. When pressure loss occurs, the inflatable must be re-inflated by some mechanism, such as a pump. Any physical damage that pierces the bladder, even small holes or tears may result in loss of pressure and even the inability to be re-pressurized. 
     Foam balls, such as NERF® brand balls, are also known in the art, but foam balls to date have exhibited substantially different playing characteristics and feel that traditional sports balls, and do not comport with or approximate the standards set by sports organizations for regulation play, such as size, rebound response, weight or other characteristics. 
     SUMMARY OF THE INVENTION 
     As such, a sports ball  5  with a core  15  and outer covering  10  that does not include an air bladder and that comports with the standards set by sports organizations for regulation play, such as size, rebound response, weight, or other characteristics is desirable. Such a sports ball  5  is disclosed herein. 
     In some aspects, the invention relates to a inflation independent sports ball comprising a foam core  15  and an outer covering  10 , wherein the sports ball is selected from the group consisting of a football, a basketball, a volleyball and a soccer ball, wherein the sports ball  5  is devoid of an inflatable air bladder. 
     In other aspects, the invention relates to a sports ball having a diameter and comprising a synthetic leather outer covering  10  at least partially covering a polyurethane foam core  15 , wherein the foam core further comprises at least one internal compartment and a cylindrical body spanning at least part of the length of the diameter of the sports ball. 
     In other aspects, the invention relates to a sports ball having an outer covering and a foam core, wherein the foam core  15  is not filled with foam entirely throughout its internal volume, but rather includes space for air. 
     Other aspects and advantages of the invention will be apparent from the following description and the appended claims. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
       To aid in the appreciation of further advantages and features of the present disclosure, a more particular description will be provided by reference to specific embodiments which are illustrated in the appended drawings. It is appreciated that these drawings are not to be considered limiting in scope. The disclosure herein will be described and explained with additional specificity and detail through the use of the accompanying drawings in which: 
         FIGS. 1A-1D  show various embodiments of the sports ball  5  as disclosed herein. 
         FIG. 2  shows a cut away view of one embodiment of the core  15  of one embodiment of a sports ball  5  as disclosed herein. 
         FIG. 3  shows a cut away view of one embodiment of the core  15  of a sports ball  5  as disclosed herein. 
         FIG. 4  shows a cut away view of one embodiment of the core  15  of a sports ball  5  as disclosed herein. 
         FIG. 5  shows a cut away view of one embodiment of the core  15  of a sports ball  5  as disclosed herein. 
         FIG. 6  shows an alternate cut away view of the core  15  shown in  FIG. 5 . 
     
    
    
     DETAILED DESCRIPTION 
     This detailed description is provided for amplifying the invention and aiding in understanding of the disclosure, by reference to a possible embodiment(s). The invention shall not be interpreted as limited to any particular embodiment shown, except as set forth in the claims. 
     A sports ball  5 , such as for use where inflatables are typically employed, is disclosed herein.  FIGS. 1A through 1D  show various embodiments of the sports ball  5 , in the form of a basketball, a football, a volleyball or a soccer ball. While these particular embodiments are shown for illustrative purposes and each is certainly within the scope of the invention, balls for other sports and general play are also within the scope. In a central aspect of the sports ball  5  is its core  15 . 
     The core  15  may comprise a foam, such as polyurethane (“PU”), EVA, or other foamed structure. Other materials with resiliency, such as rubbers, may also be used. In one embodiment, the PU foam is open cell PU foam wherein the cell walls comprising the foam are broken and the air or other gasses may freely enter and exit the broken cells. In an alternate embodiment, the PU foam is closed cell foam wherein the cells comprising the foam are not broken and air or other gases are “trapped” within the intact cells comprising the foam. In an alternate embodiment, the PU foam core may comprise both open and closed cell foam. Other foams such as foamed natural rubber or soy bean based foams should be considered within the scope of this disclosure. 
     In one embodiment, the core  15  may comprise PU foam of a single density. For example, the density of the PU core  15  may be constant, or nearly constant throughout the circumference of the core  15 . In an alternate embodiment, as shown in  FIG. 2 , the density of the PU foam core  15  may change through the diameter of the core  15 . The embodiment shown in  FIG. 2  shows the density of the PU foam core  15  increasing near the center of the core  15 —i.e., the density of the PU foam near the center of the core  15  is greater than the density of the PU core near the exterior surface of the core  15 . Alternatively, the density of the PU foam near the center of the core  15  could be less than the density of the PU foam near the outer surface of the core  15 . 
     In an embodiment where multiple densities of PU foam are present, the core  15  may comprise a “constant” density gradient (i.e., density increasing at a generally constant rate from the outer surface to the center or vice versa), a “step wise” density gradient (i.e., the density increases (or decreases), in discrete “steps” from the outer surface to the center), a combination of the forgoing, or many other conceivable density gradient (such as a “peak” gradient wherein the density of the PU increases from the outer surface of the core  15  to a point in the interior and then begins to decrease again closer to the center of the core  15 ). Any possible density gradient should be considered within the scope of this disclosure. For example, as shown in  FIGS. 3 and 4 , the core  15  may comprise a plurality of concentric layers  16   a ,  16   b ,  16   c ,  16   d ,  16   e ,  16   f . The concentric layers  16   a ,  16   b ,  16   c ,  16   d ,  16   e ,  16   f  may comprise single discrete densities of PU foam or they comprise multiple densities of PU foam in either a constant, step wise or peak gradient constructions. In one embodiment, the densities of the PU foam in the concentric layers  16   a ,  16   b ,  16   c ,  16   d ,  16   e ,  16   f  increases near the center of the core  15 , alternatively the densities of the PU foam in the concentric layers  16   a ,  16   b ,  16   c ,  16   d ,  16   e ,  16   f  may decrease near the center of the core  15 , alternatively, a peak gradient design or other construction may be used. In one embodiment, the concentric layers  16   a ,  16   b ,  16   c ,  16   d ,  16   e ,  16   f  may have the same or approximately the same thickness while in other embodiments the concentric layers  16   a ,  16   b ,  16   c ,  16   d ,  16   e ,  16   f  may be of varying thicknesses. 
     In one alternate embodiment as shown in  FIGS. 5 and 6 , the core  15  is not filled with foam entirely throughout its internal volume, but rather includes space for air. Like a traditional inflatable, the space could be configured as a single air cavity, akin to the common single central bladder of known inflatables. Despite having space for air, sports ball  5  need not be configured to rely on air pressure to provide the desired rebound, firmness, resistance to compression, or other desired characteristics that are typically controlled by the level of inflation of a traditional inflatable. In fact, it is contemplated that sports ball  5  will in many configurations not have an inflation valve at all. While it is possible to configure the sports ball  5  as disclosed in the present disclosure such that the air in the cavity is pressurized, such pressure is not critical for maintaining form and rebound within acceptable levels in every embodiment. If desired, the cavity may be pressurized at the time of production. Alternately, if desired, the sports ball  5  may be constructed with disregard to the air pressure in the cavity, or with the intent or anticipation that the air pressure in the cavity be approximately the ambient air pressure. With the added structural integrity of the sports ball  5  as taught herein compared to traditional inflatables, some embodiments may even exhibit an air pressure in the cavity intentionally lower than that of the ambient atmospheric conditions. Using such a “negative pressure” configuration may permit the sports ball  5  to have a tighter feel normally attributable to the outward pressure of a traditional inflatable. 
     Without relying on increased internal air pressure in a cavity for structural integrity, shape, rebound characteristics and the like, these characteristics are imparted to and controlled for sports ball  5  by the material comprising the core  15  and the particular construction of that core  15 . For example, in a single cavity embodiment, the outer boundary  20  will be thicker than would be, for example, the bladder, winding, and covering of a basketball. In some embodiments, this outer boundary  20  will be between one (1) centimeter and one (1) inch (2.54 cm) thick. In other embodiments, the structural integrity of the sports ball  5  may be enhanced by incorporating struts or other structures within the cavity space, such as spines that extend outwardly from the center, or from a center mass (such that if the outer boundary  20  were removed, the struts may look like a starburst, for example). Other, more elaborate internal structures can be employed, such as grid patterns, scaffolding, internal ribbing about the inner circumference of the outer boundary  20  and any other structure that may enhance the ability of the sports ball  5  to maintain its round configuration even in the absence of an internal air pressure higher than ambient air pressure. 
     Advantageously, instead of a single cavity, the core  15  may comprise a plurality of internal compartments  25  in which the air of one compartment  25  does not flow freely to another compartment  25 . Compartments  25  are separated by walls such as the ribs  30  shown in  FIGS. 5 and 6 , and may be oriented and configured in various shapes and spatial relationships. For example, the compartments  25  may be arranged like the internal lobes of an orange, such that in cross-section the ribs  30  have the appearance of a wheel-and-spokes. Alternatively, if desired the compartments  25  may be configured loosely on a spiral configuration. The shown embodiment at  FIGS. 5 and 6  depicts compartments  25  near the outer surface of the sports ball  5 , separated in circumferential direction by a plurality of walls forming ribs  30 . Toward the center of the core  15 , the sports ball  5  possesses another cavity disposed inwardly of the circumferentially-disposed compartments  25 , denominated in the figures as a central cavity  35 . In the embodiment shown in  FIGS. 5 and 6 , the central cavity  35  is a cylindrical body extending from the outer boundary  25  on one side of the sports ball  5  to the outer boundary  25  on the other side. If desired, central cavity  35  might be a perfectly round cavity concentric with the center of the sports ball  5 , or it might be a spheroid, such as a prolate spheroid. In some embodiments it will be desirable for the internal compartments  25  to be configured and placed relative to one another such that in any rotational position of the sports ball  5  a cross section taken through its center will look the same as the cross section taken if the ball is rotated 90 degrees. For example, the core  15  may comprise a plurality of concentric layers of internal compartments  25  arranged around a single central cavity  35 . In other configurations, including the one shown in  FIGS. 5 and 6 , the cross section taken at different rotational positions will look markedly different. For example, the core  15  may comprise a plurality of central cavities  35 , which need not be concentric to the center of the sports ball  5 . In the embodiment as shown in  FIGS. 5 and 6 , the internal compartments  25  are evenly spaced around the cylindrical body  35 , but the cross section taken at different rotational positions will look different. In combination with the compartments  25 , struts and other structures as discussed above in connection with a single cavity may also be used. It will be recognized that the ribs  30  will provide certain structural support similar to that provided by struts and other structures. It may nevertheless be desirable to incorporate additional structural support, perhaps incorporating struts and the like inside one or more of the compartments  25 . 
     In one embodiment, the internal compartments  25  are generally trapezoidal in shape and are formed by the outer boundary  20  of the core  15 , two (2) ribs  30  and the internal cylinder wall  45 . Other shapes for the internal compartments  25 , including square, rectangular and circular internal compartments  25  should be considered within the scope of this disclosure. The internal compartments  25  may be exterior to the cylindrical body  35 . In one embodiment, the core  15  comprises between two (2) and eight (8) internal compartments  25 . The core  15  may comprise between nine (9) and sixteen (16) internal compartments. In another embodiment, the core  15  comprises between seventeen (17) and thirty two (32) internal compartments and finally in yet another embodiment, the core  15  comprises between thirty three (33) and one hundred (100) internal compartments. 
     The material comprising the walls of the compartments  25  may be a porous material, such as open-cell foam. If the material is so porous that air would otherwise move freely among the compartments  25 , the compartments  25  may have a material (possibly in the form of a coating or a paint) applied to the interior surface of the internal compartments  25  that reduces or prevents air (or other gases) from migrating across or escaping from the internal compartments  25 . In one embodiment the material may be an additional PU coating or film. In an alternate embodiment, the composition of the PU foam forming the internal compartments  25 , ribs  30  and internal cylinder wall  45  may be adjusted to prevent air (or other gases) from escaping the internal compartments  25 . Certainly, non-porous materials, including closed cell foam, may be used to prevent the free movement of air among compartments  25 . By way of non-limiting example, a closed cell PU foam may be used to form the  25 , ribs  30  and internal cylinder wall  45 . Without being bound by this theory, it is believed that in this embodiment, the internal compartments  25  may create greater rebound via the compression and expansion of the air trapped inside the internal compartments  25  as the sports ball  5  contacts a surface (i.e., as the ball is bounced on the floor). 
     With specific reference to the sports ball  5  shown in  FIGS. 5 and 6 , the core  15  comprises a cylindrical central cavity  35  defined at least in part by the internal cylinder wall  45 . The cylindrical body  35  may span the entire diameter of the sports ball  5  terminating against the outer boundary  20  of the core  15  or against the outer covering  10 . In an alternate embodiment, the cylindrical body  35  may span only part of the diameter of the core  15 . Without being bound by this theory, it is believed that in an embodiment such as this with a central cavity  35 , the compression and expansion of the air trapped inside the cylindrical body  35  as the sports ball  5  contacts a surface (i.e., as the ball is bounced on the floor) may create a more controlled rebound. 
     The sports ball  5  may also comprise an outer covering  10 , whether the core  15  includes a cavity or not. Generally, the outer covering  10  is the primary contact surface when a player handles the sports ball  5 . In one embodiment, the outer covering  10  fully encases the core  15 . In an alternate embodiment, the outer covering  10  does not fully encase the core  15 . By way of a non-limiting example, the outer covering  10  may comprise one or more cover panels  11 , with groves, lines, or other gaps between the cover panels  11 , permitting the core  15  to be seen or touched. In one embodiment, an additional material may be inserted between the cover panels  11 . In one embodiment, the additional material may provide tactile feedback to a player allowing the player to determine the position or orientation of the sports ball  5  in relation to the player&#39;s hand. 
     The outer covering  10  may be configured to comprise the features of a football, volleyball, basketball or soccer ball. For example, in an embodiment where the sports ball  5  is a basketball, the outer covering  10  may comprise a plurality of cover panels  11  which are adjacent to channels  12  as shown in  FIG. 1A . When the sports ball  5  is a football, the outer covering may comprise a plurality of cover panels  11  which are adjacent to channels  12  as well as laces  13  as shown in  FIG. 1B . Alternatively where the sports ball  5  is a soccer ball, the outer covering  10  may comprise a plurality of pentagonal cover panels  11  as shown in  FIG. 1C . In yet another embodiment, where the sports ball  5  is a volleyball, the outer covering  10  may comprise a series of covering panels  11  as shown in  FIG. 1D . The above examples shown in FIGS.  1 A- 1 D are non-limiting; the physical appearance of the outer covering  10  may be configured to include logos, one or more colors or other aesthetic concerns in other embodiments. Additionally, the outer covering  10  may comprise pebbling or other features to aid the player in griping and manipulating the sports ball  5 . In one embodiment, the outer covering  10  may be painted or coated to improve its durability. In an alternate embodiment, the outer covering  10  may be painted with a PU paint or a vulcanized rubber material. The vulcanized rubber material may comprise pebbling or other features. 
     The outer covering  10  may be affixed to the core  15 . The outer covering  10  may be affixed to the core  15  by any method known to one of ordinary skill in the art. By way of non-limiting example, the outer covering  10  may be glued to the core  15  at least partially by an adhesive such as styrene butadiene, acrylonitrile butadiene or a two (2) part urethane. In an alternate embodiment, the outer covering  10  may not be attached to the core  15  and in this embodiment the core may “float” inside of the outer covering  10  if desirable. The sports ball  5  may also comprise one or more additional layers of material between the outer covering  10  and the core  15 . In one embodiment, an additional layer of windings comprised of a natural or synthetic thread may be present between the outer covering  10  and the core  15 . 
     The outer covering  10  may be manufactured from any material that is suitable to one of ordinary skill in the art and may comprise leather, synthetic leather, rubber or other synthetic materials. Additionally, the outer covering  10  may be manufactured from differing materials based upon the sports ball  5  being constructed. For example, the outer covering  10  for a football may comprise differing materials than the outer covering  10  for volleyball. In one embodiment, the outer covering  10  may additionally comprise a tuftane thermoplastic polyurethane film. 
     In one embodiment, the outer covering  10  is between 0.1 mm and 2.0 mm in thickness. In an alternate embodiment, the outer covering  10  is between 0.8 and 1.25 mm in thickness. 
     Method of Manufacture 
     The sports ball  5  disclosed herein may be manufactured by any means known to be suitable to those of ordinary skill in the art. The core  15  may be formed in segments and glued together to form the core  15 . In one embodiment, the core  15  may be formed by two (2) halves glued together while in other embodiments four (4) segments may be formed and glued together to form the core  15 . 
     The sports ball  5  of the present disclosure substantially meets the requirements set forth by the pertinent governing body to be considered a competition ball. 
     The sports ball  5  disclosed herein may meet or exceed the standards set forth by the National Federation of State High School Associations (“NFSHA”). In one embodiment, a football constructed as described herein may weigh between fourteen (14) and fifteen (15) ounces (398.9-425.2 grams) as required by the NFSHA as well as meet the size requirements set forth by the NFSHA. 
     In an alternate embodiment, a volleyball constructed as described herein may be spherical comprising twelve (12) or more covering panels  11 , measure between twenty five (25) and twenty seven (27) inches (63.5-86.8 centimeters) in diameter and weigh between nine (9) and ten (10) ounces (255.2-283.5 grams) as required by the NFSHA. 
     A soccer ball constructed as described herein may be spherical with a circumference of between twenty seven (27) and twenty eight (28) inches (68.6-71.1 centimeters) and weigh between fourteen (14) and sixteen (16) ounces (396.9-453.6 grams) as required by the NFSHA. In an alternate embodiment, a soccer ball as described herein may meet the Federation Internationale de Football Association (“FIFA”) specifications for rebound and other characteristics. In one embodiment, a size five (5) soccer ball as described herein may exhibit a rebound of between one hundred and thirty five (135) and one hundred and fifty five (155) centimeters (53.1-61 inches) at 20 degrees Celsius (68 degrees F.) after being dropped from two (2) meters (78.7 inches) onto a steel panel. 
     A basketball constructed as described herein may meet the standards set forth by the NFSHA. For a boy&#39;s basketball, the basketball may be spherical with a circumference of between twenty nine and one-half (29.5) and thirty (30) inches (74.9-76.2 centimeters) and weigh between twenty (20) and twenty two (22) ounces (567.0-623.7 grams). For a girl&#39;s basketball, the basketball may be spherical with a circumference of between twenty eight and one-half (28.5) and twenty nine (29) inches (72.4-73.7 centimeters) and weigh between eighteen (18) and twenty (20) ounces (510.3-567.0 grams). Further, a basketball as described herein may rebound to a height of not less than forty nine (49) inches (124.5 centimeters) and not more than fifty four (54) inches (137.2 centimeters) when dropped from seventy two (72) inches (182.9 centimeters) onto a basketball playing surface (such as a hardwood basketball court). 
     The sports ball  5  disclosed herein will also have a similar coefficient of restitution (“CoR”) as a regulation inflatable sports ball. In one embodiment the sports ball  5  has a CoR of about 0.60 to 1.00. In another embodiment, the sports ball  5  has a CoR of about 0.70 to 1.00 or about 0.80 to 1.00. In a final example, the sports ball  5  has a CoR of about 0.90 to 1.00. 
     The sports ball  5  disclosed herein offers many advantages over the prior art, including without limitation: (i) being inflation independent and puncture resistant through the use of the core  15  described herein rather than a traditional air bladder and (ii) being the first sports ball  5  comprising a foam core  15  that satisfies the standards set by sports organizations for regulation play, such as size, rebound response, weight, or other characteristics. 
     While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed here. Accordingly, the scope of the invention should be limited only by the attached claims.