The present invention relates to a ball for a ball game.
Basketballs have been standardized into an eight-panel outer surface design having raised seams exposed between the edges of exterior skin panels. Basketballs generally consist of a rubber bladder surrounded by a thread-winding layer.
The arrangement of the bladder, thread-winding portion, and a rubber layer are placed in a mold and cured to make the “carcass” of the ball.
During the carcass molding process, raised ridges or seams are molded from the rubber layer. An individual panel section of leather is bonded to the rubber layer in a region between raised seams. After attachment of the panels the ball is completed in a finishing mold.
Basketballs have been made in the above manner. The thread-winding layer around the surface limits expansion of the bladder and assists it in retaining a spherical shape after inflation to a desired pressure. It also prevents the air pressure within the bladder from being fully transferred to the outer covering defined by the panel portions and seams.
The outer covering provides durability and protection. It is common to use synthetic materials to make the panel portions. However, the highest quality balls use top-grain leather.
One ball design developed in the past by the A. G. Spalding Co. (“Spalding design”) includes a porous sponge layer positioned between what is characterized as an “inner carcass” and an outer skin. This design is illustrated in U.S. Pat. No. 3,119,618.
The Spading design lacks the rubber layer described above for creating raised seams on the ball described in U.S. Pat. No. 3,119,618.
On the one hand, the invention disclosed in U.S. Pat. No. 5,636,835 is an inflatable, raised scam game ball having a layer of padding underneath the outer covering.
The carcass of the ball is preferably made in the following manner.
Surrounding a spherical rubber bladder by a thread-winding layer;
After the thread-winding layer is wound around the bladder, providing a layer of foamable rubber in a prefoamed condition around the thread-winding layer and covering it completely;
Applying a foaming agent to the foamable rubber;
Positioning narrow strips of seam material (high density black rubber) over the foamable rubber at the locations where it is desired to create raised seams;
Placing this arrangement in a carcass mold where it is cured under temperature in a conventional method;
During the molding process, expanding the foamable layer into a porous sponge rubber layer. At the same time, the seam strips are molded into raised seams;
As a result, when removed from the mold, raised black seams form partially covering the surface of the sponge layer and the sponge rubber layer covering the thread-winding layer.
As with typical leather game balls, the boundaries of the exterior skin panels are defined by the raised seams. Each panel is bonded in a region between seams.
A basketball illustrated in U.S. Pat. No. 5,636,835 has an inner carcass structure, or inner carcass portion, consisting, in combination, of a rubber bladder 12 and a thread-winding layer 14 (see, for example,
The thread-winding layer 14 surrounds the bladder 12, and the porous sponge 16 surrounds the thread-winding layer 14. A plurality of skin panels 18 and a plurality of seams 20 are bonded to the porous layer 16. Generally, the ball 10 has a total of eight panels separated by seams, which is typical of basketballs.
Each seam 20 is made of a narrow strip of seam material preferably of a high density rubber. A raised central portion 22 of the seam material 20 fills the space between the outer edges 24 and 26 of two adjacent skin panels 28, 30 as well as conventional basketballs.
However, narrow flanges portions 32, 34 of the seam material 20 extend outwardly, in opposite directions, a definite distance from the raised portion 22 which is different from conventional basketballs.
The flange portions 32, 34 underlie the overlapping panel edges 24, 26 and are also sandwiched between the panel edges and underlying sponge layer 16. In other areas, the skin panels 18a, 18b are bonded directly to the sponge layer 16, as shown by numerals 36, 38. A basketball illustrated in U.S. Pat. No. 3,119,618 has no rubber layer for making a raised seam. However, instead of providing a raised seam, it is well known to provide a protrusion in a sponge layer (for example, Japanese Unexamined Utility Model Publication No. 157253/1976).
Referring to
The carcass 54 is constructed by the bladder 51, thread-winding layer 52, and vulcanized rubber layer 53. Numeral 55 indicates a partition formed on the carcass 54. The surface of carcass 54 is sectionalized into the shape of a carapace of a turtle with 8 sections, 12 sections, 18 sections, or 32 sections. Numeral 56 indicates a surface sectionalizing and dividing on the surface surrounded by the partition 55. Numeral 57 indicates a spherical surface of the surface 56 in the shape of a sphere sectionalizing and dividing on the surface. Numeral 58 indicates a peripheral portion of surface 56 which is divided to sectionalize the surface with the shape of arc on its cross section. The peripheral portion 58 smoothly bonds to the spherical surface 57. Numeral 59 is a side of a partition, making an acute angle with the peripheral portion 58 described above. Numeral 60 is leather which is attached to the surface 56 which is divided to sectionalize the surface, and thin as compared to conventional leather. The periphery of a back surface of leather 60 is not skived. The cross section of attached leather 60 is directly bonded to the center of side 59 of the partition 55. Thus, when using ball, the cross sectional surface of the attached leather 60 is not peeled from the peripheral edge of leather 60 by catching fingers on the surface of the ball. As leather 60 is thin, it is readily attached. As the peripheral edge portion 58 has a cross section with the shape of a circular arc and is bonded smoothly to the spherical surface 57, unevenness does not occur on the surface of the attached leather 60 and very good handling in use is provided.
A basketball illustrated in Japanese Unexamined Utility Model Publication No. 157253/1976 constructs the peripheral edge 58 of each surface 56 which is divided to sectionalize the surface in the shape of an arc with the smooth seam by a much smaller radius than a radius of the ball on an arbitrary virtual plane which penetrates into the center of the ball. The side face 59 of partition 55 is formed, so that a virtual straight line drawn on the side face 59 of partition 55 penetrates into approximately the center of the ball. The leather 60, which has a uniform thickness without skiving, is applied on the surface 56 which is divided to sectionalize the surface.
The present invention aims to provide a ball for a ball game which has equal or increased cushioning properties when compared with a ball which has conventional high density rubber seams and differing from a ball having inflatable raised seams with cushion layers under an outer covering, as disclosed in U.S. Pat. No. 5,636,835.
The ball for a ball game of the first and third Embodiments of the present invention comprise:
A bladder made of rubber or elastomer, a foam covering the outside of the bladder, and a skin layer forming the outer surface of the ball, the skin layer being divided into sections by outwardly extending cellular partition portions of the foam layer having a different cellular structure and a lesser degree of expansion than that of the main portion of foam layer from which the partitions extend.
A comparison of the cellular structures of the main portion of the foam layer surrounding the bladder, or in another embodiment of the bladder and the reinforcement layer, is provided in detail in the examples and drawings as follows:
A comparison of the data shows that the main portion of the foam layer has an average of about 10 times the number of cells compared with the number of cells in the partition layer and that the cell size of the cells in the main portion is about 2-4 times greater than the cells of the portion layer because of the differences in blending rate and particle size of the foaming agent in the main portion when compared with the amount and particle size of the foaming agent in the partition portions. After vulcanization, the main portion of the foamed layer contains more cells which are of a larger size and the partition portions contain less cells of a smaller size. Thus, the degree of expansion of the foamable main portion is greater than the lesser degree of expansion of the foamable partition portion.
The ball for ball game of the second Embodiment of the present invention comprise:
wherein a peripheral edge of each surface of the foamed layer is formed in a shape of an arc with a smooth seam, a skin layer is provided on each surface of the foamed layer, and a partition portion of the foamed layer has a lesser degree of expansion than each surface of the main portion which is divided by the partition portions to sectionalize the surface.
The number of cells in the partitions of the foamed layer is also preferably less than the number of cells in each surface of the main portion of the foamed layer which is divided by the partition portions to sectionalize the surface.
It is preferable that the degree of expansion in the partitions of the foamed layer decreases gradually as the partitions extend from each surface of the main portion.
a) and 4(b) are cross sectional explanation views showing processes for manufacturing method of a vulcanized foam rubber layer which is used to construct a ball of the present invention;
a) and 5(b) are cross sectional explanation views showing a vulcanized rubber layer and a partition which is used to construct a ball of the present invention; and
Referring to attached drawings, a ball for a ballgame (hereinafter referred to as “ball”) is explained in detail as the following.
a) and 4(b) are cross sectional explanation views showing processes for manufacturing a ball of the present invention,
As a ball of the present invention basically has the same construction as a ball illustrated in Japanese Unexamined Utility Model Publication No. 157253/1976, the same constructional portions as Japanese Unexamined Utility Model Publication No. 157253/1976 are explained with the same numerals.
Referring to
As a rubber which constructs the bladder 51, rubbers such as butyl rubber, natural rubber, SBR, IR, BR, or EPDM, elastomers such as polyurethane, styrene, chloroethene, olefin, polyester, nitryl, or polyamide can be applied.
As a thread which constructs the thread-winding layer 52, threads made from nylon, polyester, or cotton are applied.
The peripheral edge 58 of each surface 56 of the foamed layer 53 (vulcanized rubber layer) which is divided to sectionalize the surface is formed in the shape of an arc with the smooth seam on a virtual plane which penetrates into the center of a ball of the present Embodiment. The side face 59 of a partition 55 on the foamed layer 53 (vulcanized rubber layer) is formed, so that a virtual straight line on the side face 59 of the partition 55 on the foamed layer 53 (vulcanized rubber layer) approximately penetrates into the center of the ball. A skin layer 60 (for example, natural leather layer or synthetic leather layer) is attached on each surface of vulcanized rubber layer 53 which is divided to sectionalize the surface, but not limited to construction of the partition 55 described above. For example, a surface which slopes relative to the surface 56 which is divided to sectionalize the surface (for example, a skin layer which has a cross sectional trapezium) can be applied. The peripheral edge 58 of each surface 56 of the foamed layer 53 which is divided to sectionalize the surface is not necessarily formed in the shape of arc.
The partition 55 on the foamed layer 53 described above in a ball of the present Embodiment is obtained by vulcanizing the unvulcanized foam rubber which has a lesser degree of expansion than the unvulcanized rubber on which it is superposed on comprising the main portion. However, the method of making the partition 55 is not limited to such method. There is a mold M which is provided with a cavity C. For example, in a cavity C, a small amount of foamed unvulcanized rubber having a lower degree of expansion is embedded in a mold M, and a main foamable body covering the thread wound around the bladder 51 is placed adjacent the skin layer. This assembly is placed into a mold (not shown) to be vulcanized. However, this method is not limited to such a method. The partition 55 can be also obtained by vulcanizing either unvulcanized partition 55 or unvulcanized surface 53 which is divided to sectionalize the surface. The partition 55 can be also obtained by joining with an adhesive agent even if both the partition 55 and the main portion surface 53 which is divided by the partitions to sectionalize the surface are vulcanized. It is well known that methods for joining which are obvious to persons skilled in the art can be also applied.
Referring to
The bladder 51, thread-winding layer 52, and unvulcanized rubber layer 53 are formed.
After the unvulcanized foamable rubber 70, which has a lesser degree of expansion than the unvulcanized foamable rubber layer 53, is superposed on the unvulcanized rubber layer 53, the layer is placed in the mold M to heat and pressurize only for a predetermined time period (10 to 15 minutes) (at the temperature of 40 to 170° C., pressure 0 to 8 kgf/cm2).
The partition 55 on vulcanized rubber layer 53 can be obtained by opening mold M.
There is a tendency that when the particle diameter of the foaming agent blended into the rubber is reduced, the foamed cell becomes fine in size, and when the particle diameter of the foaming agent blended into the rubber is increased, the foamed cell becomes larger in size.
When the amount of foaming agents blended into rubber is increased, the number of foamed cells increases, and when the amount of foaming agents blended into rubber is increased, the number of foamed cells decreases. There is also a tendency that as the amount of foaming agents in vulcanized rubber layer 53 and that of partition 55 are equalized, the number of cells gradually decreases.
When the blending rate of a foaming agent in the unvulcanized rubber layer 53 of the main portion (portions except for the partition 55) is 6.0 phr, the blending rate of the foaming agent in the partition 55 is 4.0 phr, a particle diameter of the foaming agent in the main portion is under 20 μm, and the particle diameter of the foaming agent in the partition 55 is under 10 μm, a foamed cell Ba with a size of 100 to 400 μm is obtained in the main portion, and a foamed cell Bb with a size of 50 to 100 μm is obtained in the partition 55 as shown in
When the amount of foaming agent is 4 to 6 phr, the partition 55 will include a large number of foamed cells Bb as shown in
When the blending rate of the foaming agent in the unvulcanized rubber layer 53 of the main portion (portions except for the partition 55) is 6.0 phr, the blending rate of the foaming agent in the partition 55 is 3.0 phr (i.e. the amount of the foaming agent is 1 to 4 phr in the partition 55), after vulcanization to a foamed state, in which the number of the foamed cells in the partitions 55 (100 to 1000 pieces/cm2) is lesser than that of the foamed cells in the main portion (1000 to 10000 pieces/cm2) occurs as shown in
A ball in the present invention is explained in detail with examples, but the present invention is not limited to the example
When the blending rate of a foaming agent in the unvulcanized rubber layer 53 of the main portion (portions except for the partition 55) is 6.0 phr, the blending rate of the foaming agent in the partition 55 is 4.0 phr, a particle diameter of the foaming agent in the main portion is under 15 μm, and a particle diameter of the foaming agent in the partition 55 is under 5 μm, a foamed cell Ba with a size of 75 to 400 μm is obtained in a main portion, and a foamed cell Bb with a size of 25 to 100 μm is obtained in the partition 55 as shown in
The blending rate of the rubber composition in each rubber, one is rubber used in the vulcanized rubber layer 53 which is used to construct a ball according to the example, the other is the rubber used in the partition 55 as shown in Table 3.
On the one hand, a ball related to U.S. Pat. No. 5,636,835 described above was used as a comparative example.
General standard, rebound, touch (softness), compressibility (hardness) and abrasion resistance were experimentally determined. (refer to Table 1, Table 2
It proves that as a result, a ball in the example and a ball in comparative example are equivalent to a general standard and abrasion resistance as shown in
According to the present invention, a ball for ball game can be provided which has equal or increased cushioning properties when compared to a ball which has conventional high density seams and which is different from a ball having inflatable raised seams with cushion layers under an outer covering.
This is a continuation-in-part of U.S. application Ser. No. 11/399,380 filed on Apr. 7, 2006, now abandoned.
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Number | Date | Country |
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51-157253 | Jun 1976 | JP |
Number | Date | Country | |
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20080051234 A1 | Feb 2008 | US |
Number | Date | Country | |
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Parent | 11399380 | Apr 2006 | US |
Child | 11924730 | US |