The present invention relates to the use of one or more pivot joints in association with a barrel portion of a ball bat.
Baseball and softball are very popular sports in the United States, Japan, Cuba, and elsewhere. Ball bats impart or receive impact forces upon impacting a ball and transmit the shock and vibrations from the impact through the handle of the bat to the hands of the batter. Impacts occurring away from the “sweet spot” of the ball bat generally result greater shock and vibrational energy transferring to the batters hands. Many batters find such shock and/or vibrational energy to be uncomfortable and/or painful. Some players refer to this event as being “stung” by the bat. The fear of pain or discomfort upon hitting a ball away from the “sweet spot” can negatively affects a batter's performance, particularly many younger players.
Baseball and softball organizations periodically publish and update equipment standards and/or requirements including performance limitations for ball bats. It is not uncommon for ball bat manufacturers to adjust the design and/or construction of their ball bats to ensure that such bats satisfy the new or updated standards. As a result, the maximum performance level of high end ball bats used in organized, competitive play are designed not to exceed applicable performance limits. Many ball bat manufacturers seek to provide ball bat designs and/or constructions that provide a near maximum performance levels across a larger area or region of the bat barrel.
Accordingly, a continuing need exists for an improved ball bat that reduces the amount of shock and/or vibrational energy from a ball impact being transmitted to the batter's hands. What is also desired is a high performance ball bat that satisfies applicable maximum performance rules and/or standards and also provides near maximum performance along a greater region of the bat barrel.
The present invention provides a ball bat extending along a longitudinal axis. The bat includes a handle portion, a barrel portion and an end cap. The barrel portion includes a proximal region and a distal region. The proximal region of the barrel portion is coupled to the handle portion by a first pivot joint. The distal region of the barrel portion is coupled to the end cap by a second pivot joint. The first and second pivot joints movably support the barrel portion relative to the longitudinal axis.
According to one implementation of the invention, a ball bat for impacting a ball includes a barrel portion coupled to, and extending from, a handle portion and an end cap. One of the barrel portion and the end cap includes a socket, and the other of the barrel portion and the end cap includes a rounded head received within the socket to form a first pivot joint. The first pivot joint facilitates pivoting of the barrel portion with respect to the end cap upon impact with the ball.
This invention will become more fully understood from the following detailed description, taken in conjunction with the accompanying drawings described herein below, and wherein like reference numerals refer to like parts.
Knob 22 extends at proximal end 62 of the handle portion 24 of the bat 20, and has a diameter wider than that of handle portion 24. In one implementation, knob 22 is coupled or directly attached to handle portion 24. In yet another implementation, knob 22 is integrally formed as a single unitary body with handle portion 24.
Handle portion 24 comprises elongate structure extending from knob 22 towards a distal end 64 of bat 20. Handle portion 24 has a proximal region 28 sized to be gripped by a batter's hands. Handle portion 24 has a distal region 30 connected to barrel portion 26. As shown by
In the example illustrated, distal region 30 of handle portion 24 has a constant or uniform diameter along its length. In the example illustrated, handle portion 24 has a constant or uniform diameter along its entire length, including the proximal region 28 and distal region 30. The uniform or constant diameter of handle portion 24 facilitates fabrication or manufacturing of handle portion 24. In one implementation, handle portion 24 has an outer diameter of at least 0.5 inch and no greater than 1.25 inches. In yet other implementations, handle portion 24 may have other outer diameters. In other implementations, handle portion 24 may have a varying diameter along its length.
The handle portion 24 is formed of a strong, generally flexible, lightweight material, preferably a fiber composite material. Alternatively, the handle portion 16 can be formed of other materials such as an aluminum alloy, a titanium alloy, steel, other alloys, a thermoplastic material, a thermoset material, wood or combinations thereof. As used herein, the terms “composite material” or “fiber composite material” refer to a plurality of fibers impregnated (or permeated throughout) with a resin. In one preferred embodiment, the fibers can be systematically aligned through the use of one or more creels, and drawn through a die with a resin to produce a pultrusion, as discussed further below. In an alternative preferred embodiment, the fibers can be co-axially aligned in sheets or layers, braided or weaved in sheets or layers, and/or chopped and randomly dispersed in one or more layers. The composite material may be formed of a single layer or multiple layers comprising a matrix of fibers impregnated with resin. In particularly preferred embodiments, the number layers can range from 3 to 8. In other implementations, more than 8 layers can be used. In yet other implementations, the layers may be thinner, wherein the number of layers ranges from 20 to 30 layers, nominally 25 layers. In multiple layer constructions, the fibers can be aligned in different directions (or angles) with respect to the longitudinal axis 32 including 0 degrees, 90 degrees and angular positions between 0 to 90 degrees, and/or in braids or weaves from layer to layer. For composite materials formed in a pultrusion process, the angles can range from 0 to 90 degrees. In some implementations, the layers may be separated at least partially by one or more scrims or veils. When used, the scrim or veil will generally separate two adjacent layers and inhibit resin flow between layers during curing. Scrims or veils can also be used to reduce shear stress between layers of the composite material. The scrim or veils can be formed of glass, nylon, thermoplastic materials, rubber, other elastomeric materials, or combinations thereof. In one particular embodiment, the scrim or veil can be used to enable sliding or independent movement between layers of the composite material. The fibers are formed of a high tensile strength material such as graphite. Alternatively, the fibers can be formed of other materials such as, for example, glass, carbon, boron, basalt, carrot, aramid, Spectra®, poly-para-phenylene-2,6-benzobisoxazole (PBO), hemp and combinations thereof In one set of preferred embodiments, the resin is preferably a thermosetting resin such as epoxy or polyester resins.
Barrel portion 26 comprises an elongate hollow tubular member which provides a hitting zone or surface for bat 20. In one implementation, barrel portion 26 is formed from aluminum. In another implementation, barrel portion 26 may be formed from a fiber composite material. For example purposes only, one example composite barrel portion 26 may be manufactured by rolling multiple layers of parallelogram-shaped pieces of pre-preg, each layer having a height of about 0.005 inches (0.127 mm), onto a mandrel, thereby making a tube with an outer diameter appropriately sized for a ball bat barrel portion. The parallelograms can be rolled up such that each layer has a butt joint with itself and such that on one end all the layers stop at the same longitudinal station but on the other end, each layer can be about one centimeter shorter than the previous layer, creating a tapered end 16. In one implementation, the layers are angled +/−37 degrees from the longitudinal with each layer orientated at a negative angle to the previous layer. In other implementations, other lay-ups of composite materials with other angles and combinations of angles can be used. In still other implementations, barrel portion 26 can be formed of other materials, such as, for example, other alloys, wood, and combinations thereof.
Barrel portion 26 comprises distal region 34 and proximal region 36. In the example illustrated, distal region 34 has a generally constant diameter while proximal region 36 tapers inwardly from distal region 34 towards knob 22 and towards the outer surface of handle portion 24. In other implementations, distal region 34 and proximal region 36 may have other configurations. For example, the diameter of the barrel portion 26 may taper inward and/or outward continuously along its length.
The barrel portion 26 and handle portion 24 are capable of moving relative to each other about the pivot joints 40, 50, which are capable of dampening shock and vibration. Pivot joint 40 (schematically illustrated) movably supports proximal region 36 of barrel portion 26 for movement relative to axis 32. In the example illustrated, pivot joint 40 pivotably supports proximal region 36 for movement relative to axis 32 and for movement relative to handle portion 24. Upon impact with a ball with the barrel portion 26 at or near pivot joint 40, pivot joint 40 facilitates pivoting and deflection of proximal region 36 of barrel portion 26 about an axis that is perpendicular to axis 32.
In one implementation, pivot joint 40 comprises a curved or annular socket formed into, or connected to, one of handle portion 24 and barrel portion 26 and a rounded head received within the curved or annular socket and connected to the other of handle portion 24 and barrel portion 26. In one implementation, as shown in
Pivot joint 50 (schematically illustrated) movably supports distal region 34 of barrel portion 26 relative to axis 32. In the example illustrated, pivot joint 50 pivotably supports distal region 34 of barrel portion 26 relative to axis 32. In one implementation, the pivot joint 50 is coupled to the distal region 34 of the barrel portion 26 by a tubular insert. The tubular insert can be formed of a plastic, a metal or other generally rigid material. Upon impact with a ball with the barrel portion 26 at or near pivot joint 50, pivot joint 50 facilitates pivoting and deflection of distal region 34 of barrel portion 26 about an axis that is perpendicular to axis 32. Pivot joint 50 cooperates with pivot joint 40 to pivotally support both ends of barrel portion 26, facilitating deflection of those regions between pivot joints 40 and 50 during impact with a ball. As a result, the hitting performance of the barrel can be enlarged and/or improved, particularly in locations of the barrel portion 26 at or near one or both of the pivot joints 40 and 50. In most conventional ball bats, the regions of the barrel portion adjacent the end cap of the bat or the region that is connected to, or continuous with, the handle portion, typically produce or provide limited or significantly reduced performance when impacting a ball at those locations. The present invention significantly improves the hitting performance (coefficient of restitution, trampoline effect, and feel) of the bat at or near those regions of the bat. Further, implementation of the first and second pivot joints serves to improve the performance of the barrel portion of the bat as a whole.
In one implementation, pivot joint 50 comprises a curved or annular socket connected to one of handle portion 24 and barrel portion 26 and a rounded head received within the curved or annular socket and connected to the other of handle portion 24 and barrel portion 26. In one implementation, the curved or annular socket extends completely and continuously about axis 32. In another implementation, the curved or annular socket partially curves or extends about axis 32. In one implementation, pivot joint 50 may be part of a structure or of the end cap that closes off or occludes the distal opening 52 of barrel portion 26. In yet other implementations in which handle portion 24 terminates prior to reaching distal region 34 of barrel portion 26 or is actually spaced from pivot joint 50, pivot joint 50 may be self-supporting, independent of handle portion 24. For example, as will be described hereafter, in some implementations, pivot joint 50 may comprise an end cap or other structure that extends about the interior surfaces of barrel portion 26 at distal region 34.
Transitioner 60 comprises a structure or a collection of multiple structures that provide a smooth transition from the larger diameter of the proximal region 36 of barrel portion 26 to the smaller diameter outer surface of handle portion 24. In one implementation, transitioner 60 comprises a conical sleeve extending about handle portion 24 insubstantial abutment with proximal edges of barrel portion 26. In yet another implementation, transitioner 60 comprises multiple components that collectively form a conical structure about handle portion 24 and in abutment with the proximal edge of barrel portion 26. In some implementations, transitioner 60 may be omitted. For example, in some implementations, barrel portion 26 may itself taper down to handle portion 24. In yet other implementations, a shoulder may exist between barrel portion 26 and handle portion 24. The transitioner 60 may be formed as primarily a cosmetic or aesthetic component of the bat. In other implementations, the transitioner can provide some degree of structural support, or provide mechanical dampening, to the bat or a pivot joint.
Handle portion 324 is similar to handle portion 24 except that handle portion 324 extends to and is connected to enlarged bulbous structure that also forms or serves as an end cap 370 for bat 320. End cap 370 is integrally formed as a single unitary body with handle portion 324. End cap 370 is contained within distal region 34 of barrel portion 26 such that distal region 34 overlays portions of end cap 370.
Pivot joint 340 is formed directly between proximal region 36 of barrel portion 26 and exterior surface of handle portion 324. In the example illustrated, pivot joint 340 comprises annular socket 344 and an annular rounded head 346 received within annular socket 344. In the example illustrated, annular socket 344 is provided by proximal region 36 of barrel portion 26 and rounded head 346 is provided on the exterior of handle portion 324. Rounded head 346 movable, slidably and/or rotatable engaged with socket 344, allowing proximal region 36 of barrel portion 26 to rotate or pivot about an axis (or axes) perpendicular to centerline 32 of bat 320 upon impact of a ball with the barrel portion 26. In other implementations, and annular socket 344 may be provided on the exterior of handle portion 324, facing outwardly, while rounded head 346 can be formed on the inner surface of proximal region 36 of barrel portion 26, facing and received within annular socket 344. In the example illustrated, both annular socket 344 and annular rounded head 346 completely and continuously encircle the axis or centerline 32. In another implementation, annular socket 344 and annular rounded head 346 may comprise multiple angularly spaced segments about axis 32.
Pivot joint 350 is formed by distal region 34 of barrel portion 26 and end cap 370. In the example illustrated, pivot joint 350 comprises annular socket 354 and an annular rounded head 356 of end cap 370 is received within annular socket 354. In the example illustrated, annular socket 354 is provided by distal region 34 of barrel portion 26 and rounded head 356 is provided on the circumferential perimeter of end cap 370. Rounded head 356 is movable, slidable and/or rotatable within socket 354, allowing distal region 34 of barrel portion 26 to rotate or pivot about an axis (or axes) perpendicular to centerline 32 of bat 320. In other implementations, annular socket 354 may be provided on the circumferential perimeter of end cap 370, facing outwardly, while rounded head 356 is formed on the inner surface of distal region 34 of barrel portion 26, facing and received within annular socket 344. In the example illustrated, both annular socket 354 and annular rounded head 356 completely and continuously encircle the axis or centerline 32. In another implementation, annular socket 354 and annular rounded head 356 may comprise multiple angularly spaced segments about axis 32. Because end cap 370 is integrally formed as a single unitary body with handle portion 324, both of such components may be simultaneously fabricated and assembled to barrel portion 26, providing simpler construction of bat 320.
Handle portion 424 is similar to handle portion 24 except that handle portion 424 is attached to end cap 470 for bat 420. Handle portion 424 has uniform diameter along its length to a distal end 472 received within end cap 470. In other implementations, distal end 472 may include an axial opening that receives a portion of end cap 470. End cap 470 is similar to end cap 370 except that end cap 470 is mounted to distal end 472 of handle portion 424. As a result, handle portion 424 may be more easily fabricated, such as a pultrusion, or other single diameter tubular body.
Pivot joint 450 is formed directly by distal region 34 of barrel portion 26 and end cap 470. In the example illustrated, pivot joint 450 comprises annular socket 454 and an annular rounded head 456 received within annular socket 454. In the example illustrated, annular socket 454 is provided by distal region 34 of barrel portion 26, and rounded head 456 is provided on the circumferential perimeter of end cap 470. Rounded head 456 is movable, slidable and/or rotatable within socket 454, allowing distal region 34 of barrel portion 26 to rotate or pivot about an axis (or axes) perpendicular to centerline 32 of bat 420. In other implementations, annular socket 454 may be provided on the circumferential perimeter of end cap 470, facing outwardly, while rounded head 456 is formed on the inner surface of distal region 34 of barrel portion 26, facing and received within annular socket 454. In the example illustrated, both annular socket 454 and annular rounded head 456 completely and continuously encircle the axis or centerline 32. In another implementation, annular socket 454 and annular rounded head 456 may comprise multiple angularly spaced segments about axis 32. Because end cap 470 is mounted to handle portion 424, both of such components may be individually fabricated and assembled together, reducing fabrication cost and complexity for each part.
Handle portion 524 is similar to handle portion 24 except that handle portion 524 terminates prior to reaching end cap 570. Handle portion 524 has uniform diameter along its length to a distal end 572 received within barrel portion 26. In one implementation, the distal end 572 of handle portion 524 can terminate in a tapered intermediate region of the barrel portion 26. In other implementations, the distal end 572 can terminate immediately following the rounded head 346, or any position along the longitudinal axis toward, but not extending to, the end cap 570.
End cap 570 is similar to end cap 470 except that end cap 570 comprises a disk that occludes distal opening 52 of barrel portion 26. In the example illustrated, the disk forming the end cap 570 is within and is overlapped by distal region 34 of barrel portion 26. In the example illustrated, the outer circumferential perimeter of end cap 570 provides the annular rounded head 456 while the inner surface of distal portion 34 provides the inner annular groove 454 of pivot joint 450. In other implementations, the outer circumferential perimeter of end cap 570 may alternatively comprise an outer annular groove or socket 454 of pivot joint 450 while the inner circumferential surface of distal portion 34 of barrel portion 26 comprises the annular rounded head 456 of pivot joint 450.
End cap 670 is similar to end cap 470 in that end cap 670 receives distal end 472 of handle portion 424. End cap 670 is different from end cap 470 in that end cap 670 additionally comprises a cover portion or lip 676. Lip 676 radially projects away from axis 32 so as to extend across, cover and overlie distal edges 678 of barrel portion 26. Lip 676 protects distal edges 678 of barrel portion 26. In one implementation, lip 676 is formed from an elastomeric material. In other implementations, other materials or combinations of materials can be used to make the end cap. In one implementation, lip 676 is connected to the distal edges 678 of barrel portion 26, but flexes so as to permit to pivoting of pivot joint 450 about an axis (or axes) perpendicular to axis 32, about rounded head 456, in response to the impact of a ball against barrel portion 26. In the example illustrated, lip 676 has a rounded perimeter 680. In other implementations, perimeter 680 may be tapered or may have other shapes. In another implementation, the handle portion 424 may terminate after the first pivot joint 340 and not extend to the end cap 670.
Pivot joint 750 is formed directly by an interior of end cap 770 and exterior surface of handle portion 424. In the example illustrated, pivot joint 750 includes annular socket 454 formed into the distal region of the barrel portion 26 and annular rounded head 456 formed by outer peripheral surfaces of end cap 770 (essentially incorporating pivot joint 450). Pivot joint 750 also comprises annular socket 754 and an annular rounded head 756 received within annular socket 754. In the example illustrated, annular socket 754 is provided by an interior portion of end cap 770 and rounded head 756 is provided on the exterior of handle portion 424 adjacent distal end 472. Rounded head 756 is movable, slidable and/or rotatable within socket 754, further allowing distal region 34 of barrel portion 26 to rotate or pivot about an axis (or axes) perpendicular to centerline 32 of bat 320. In other implementations, annular socket 754 may be provided on the exterior of handle portion 424 adjacent distal end 472, facing outwardly, while rounded head 756 is formed on the inner surface of end cap 770, facing and received within annular socket 754. In the example illustrated, both annular socket 754 and annular rounded head 756 completely and continuously encircle the axis or centerline 32. In another implementation, annular socket 754 and annular rounded head 756 may comprise multiple angularly spaced segments about axis 32. Pivot joint 750 essentially combines a pair of radially spaced apart annular sockets 454 and 754 with a pair of annular rounded heads 456 and 756.
End cap 870 caps the end of barrel portion 26 the same time permitting barrel portion 26 to pivot about pivot joint 750 when impacted by a ball. End cap 870 comprises an annular ring 872 that fits inside distal region 34 of barrel portion 26 and abuts the inner circumferential surfaces 874 of distal region 34 of barrel portion 26 to secure end cap 870 to barrel portion 26. In one implementation, ring 872 frictionally engages the inner surfaces 874 of barrel portion 26 to retain end cap 870 in place. In another implementation, ring 872 is glued, bonded, welded, fastened or snapped to surface 874 of barrel portion 26. In the example illustrated, ring 872 is formed from a resiliently flexible material, being sufficiently flexible to allow bat 26 to pivot about an axis perpendicular to centerline 32 as facilitated by pivot joint 750.
Handle portion 924 is similar to handle portion 24 except that handle portion 924 comprises a distal region 932 that initially expands as handle portion 924 extends towards barrel portion 26 and then tapers inwardly in the region 933 as handle portion 924 extends into barrel portion 26. In yet other implementations, handle portion 924 may have a constant diameter along its length.
Pivot joint 940 pivotably supports proximal region 36 of barrel portion 26 for pivotal movement about an axis perpendicular to the centerline 32 of bat 920. Pivot joint 940 cooperate with pivot joint 50 (schematically illustrated) to facilitate inward deflection of barrel portion 26 when impacting a ball, enhancing or improving the performance of the barrel portion and the hitting zone of the ball bat.
As shown in
In one implementation, socket 944 is pre-molded into a generally toroidal shape with a central channel or groove sized to snugly accept the rounded head 946 of handle portion 924. In one embodiment, the socket 944 has an outer diameter of about 1.25 inches (3.18 cm), an inner diameter of about 0.87 inches (2.29 cm), and a length of about 0.55 inches (1.40 cm). The outer curve of the socket 944 is a segment of a circle with a diameter of 1.26 inches (3.20 cm). The inner curve of the socket 944 is a segment of a circle with a diameter of 0.98 inches (2.49 cm). The height of the socket varies from about 0.19 inches (4.83 mm) at the center to about 0.07 inches (1.78 mm) at the edges. In the example illustrated by
Wedge 942 comprises a structure extending between the outer circumference of handle portion 924 and the inner circumference of barrel portion 26. In one implementation, wedge 942 pre-molded into a truncated, generally conical shape having a large diameter end 950 and a small diameter end 952. The wedge 942 includes a central channel 954 sized to snugly accept the handle portion 924. In the example shown in
In one implementation, the length of the wedge 942 is about 2 inches (5.08 cm). The small diameter end 952 of wedge 942 has a diameter of about 1.1 inches (2.79 cm). The diameter of the wedge 942 remains constant for a length of 0.1 inches (2.54 mm), extending over the length of the notch 40, and then increases along a curve with a radius of 0.05 inches (1.27 mm) to a diameter of 1.2 inches (3.05 cm). The diameter of the wedge 942 then increases at a 6.5 degree angle to a diameter of about 1.70 inches (4.32 cm) at the large diameter end 950. The central channel 954 has a 1 inch (2.54 cm) diameter at the small diameter end 952, which decreases in diameter at a 5 degree angle for a length of about 0.57 inches (1.45 cm) to a diameter of 0.9 inches (2.29 cm). The central channel 42 maintains a constant diameter of 0.9 inches (2.29 cm) for a length of about 1.08 inches (2.74 cm), then increases in diameter at a 45 degree angle for a length of about 0.35 inches (8.9 mm) to the large diameter end 36. In other implementations, the wedge 942 can be formed of other shapes and/or sizes. In this embodiment, the outer surface of the wedge 942 corresponds with the inner surface of the transition region 933 of the ball bat 920. The wedge 942 may be made of any suitable material, such as, for example, rubber, or preferably, ethylene propylene diene monomer (“EPDM”) rubber with a hardness between 40-50 Shore A, ideally about 45 Shore A. In other implementations, the wedge 942 can be formed of other materials, such as a polymeric foam, and can be formed of other hardness values.
In one implementation, the pivot joint 940 is made by attaching the socket 944 to the small diameter end 952 of the wedge 942 such that the handle portion 924 fits inside the central channel 954 of the socket 944 and the central channel 954 of the wedge 942. The wedge 942 may be secured to the socket 944 by any suitable method, such as, for example bonding with an adhesive.
In another implementation, handle portion 924 can be formed as a substantially constant diameter hollow tube. The handle portion 924 may be manufactured using common manufacturing techniques.
For example purposes only, a composite handle portion 924 may be made by rolling at least one flat sheet of pre-impregnated composite fiber (“pre-preg”) around a mandrel, thereby making a tube with an outer diameter appropriately sized for a ball bat handle portion. In a preferred embodiment, the sheet of pre-preg comprises two layers of graphite pre-preg with fibers angled +/−15 degrees from the longitudinal with one layer orientated at a negative angle to the other layer. Two layers of pre-preg with a height of about 0.005 inches (0.127 mm) and fibers angled 90 degrees from the longitudinal are wrapped around the last 7.87 inches (20.0 cm) of the handle portion 924 at the end opposite the knob 22. In other implementations, other composite materials or other materials can be used to form the handle portion.
For example purposes only, a composite barrel portion 26 may be manufactured by spirally rolling 24 layers of high aspect ratio parallelogram-shaped pieces of pre-preg, each layer having a height of about 0.005 inches (0.127 mm), on a rolling mandrel with the fibers oriented longitudinally, thereby making a tube with an outer diameter appropriately sized for a ball bat barrel portion. A finishing mandrel includes a constant diameter section and a tapered section. After being rolled up, the barrel portion 26 is transferred to the constant diameter section of the finishing mandrel. The socket assembly 940 is temporarily attached to the finishing mandrel by affixing the large diameter end 950 of the wedge 942 to the end of the tapered section of the finishing mandrel. Latex banding about one inch (2.54 cm) wide and 0.05 inches (1.27 mm) high is wrapped around the tapered end 16 of the barrel portion 14. The proximal region 36 is then slowly drawn down the tapered section of the finishing mandrel, over the wedge 942 and over the socket 944, such that the proximal region 36 stops at the same longitudinal station as the socket 944. The latex banding is then removed and ribbons of pre-preg about 0.5 inches (1.27 cm) wide are wound around the lay-up directly above the pivot joint 940, forming a thickness of about 20 layers of pre-preg, each layer having a height of about 0.005 inches (0.127 mm). By being formed directly over the pivot joint 940, the inner surface of the barrel portion 26 is contoured to retain pivot joint 940.
The barrel portion 26 is removed from the finishing mandrel and a portion of the handle portion 924 is inserted. The handle portion 924 contacts the socket 944 and wedge 942 of the pivot joint 940, but does not contact the barrel portion 26, as shown in
The exterior surfaces of the barrel portion 26 and handle portion 924 do not provide a substantially continuous and smooth surface for the outer surface of the transition region 933. Instead, a generally triangular shaped notch is formed in the transition region 933 of the ball bat 920. The notch 933 is perpendicular to the long axis of the ball bat 920 and formed at a station whereby the notch 933 is adjacent to the socket 944. The notch 933 has a maximum depth of about 0.25 inches (6.35 mm) adjacent to the socket 944, with the depth of the notch 933 decreasing in the direction of the knob 22. The notch 933 allows for greater relative movement between the handle portion 924 and the barrel portion 26.
An inflatable bladder is inserted into the ball bat 920 assembly and a standard knob 22 is applied using techniques common in the industry. The bladder is inflated, expanding the barrel portion 26 and handle portion 924. The expansion of the handle portion 924 causes the outer surface of the handle portion 924 to conform to the inner surface of the socket 944 and wedge 950. In particular, the handle portion 924 forms a concave “saddle” shape conforming to the inner surface of the socket 944 which mechanically locks the handle portion 924 within the barrel portion 26. The assembly then is placed into a ball bat-shaped mold under pressure and heated to cure the ball bat, using standard techniques known in the art. Both the handle portion 924 and barrel portion 26 are cured at the same time, consequently only one composite cure cycle is utilized for the ball bat 920.
Transitioner 1060 comprises ring 1064 and filler material 1066. Ring 1064 coaxially placed around the handle portion 924, in the notch 933, such that the ring 1064 abuts the socket 944 and the proximal region 36 of the barrel portion 26. The height of the ring 1064 is preferably equal to the depth of the notch 933 and the width of the ring is about 0.212 inches (5.38 mm). The ring 1064 may be made of any suitable material, such as, for example, rubber, or preferably, EPDM rubber with a hardness between 40-50 Shore A, ideally about 45 Shore A. In one implementation, the ring 1064 is constructed from the same material as the wedge 942. In yet other implementations, ring 1064 and wedge 942 are formed from different materials. For example, in one implementation, ring 1064 may be formed from a silicone rubber, whereas wedge 942 may be formed from an ethylene propylene diene monomer (EPDM) synthetic rubber, a thermoplastic polyurethane (TPU), a thermoplastic elastomer blends.
The ring 1064 acts cooperatively with the wedge 942 to restrict the relative movement between the handle portion 924 and barrel portion 26 about the socket 944. The degree of restriction of relative movement between the handle portion 20 and barrel portion 14 can be controlled by modifying the material from which the ring 1064 is constructed. The remaining volume of the notch 933 may be filled with a fill material 1066, such as, for example, adding sufficient pre-preg to fill the remaining volume of the notch 933 before the cure cycle. In this preferred second embodiment, the notch 933 is filled by ring 1064 and fill material 1066 such that the barrel portion 26, ring 1064, fill material 1066, and handle portion 924, provide a substantially continuous and smooth exterior surface for the transition region of the ball bat 1020.
Pivot joint 1140 pivotably supports proximal region 36 of barrel portion 26 for pivotal movement about an axis perpendicular to the centerline 32 of bat 1120. Pivot joint 1140 cooperates with pivot joint 50 (schematically illustrated) to facilitate inward deflection of barrel portion 26 when impacting a ball, enhancing or improving the performance of the barrel portion and the hitting zone of the ball bat.
As shown in
Handle interface piece (HIP) 1145 comprises a component that is bonded to the outer diameter an outer surface of handle portion 1124. HIP 1145 interconnects handle portion 1124 to barrel portion 26. In the example illustrated, HIP 1145 comprises an a tube or sleeve having a pair of spaced walls 1152 that form an intermediate channel 1154 that contains a ring 1156 having an outer rounded surface forming head 1146. In other implementations, ring 1156 may be secured to hip 1145 without being received within the intermediate channel 1154. For example, ring 1156 may be welded, bonded, mechanically snapped into or onto, or otherwise secured to HIP 1145. In some implementations, ring 1156 is omitted, wherein head 1146 is integrally formed as a single unitary body about along the exterior of HIP 1145.
In the example illustrated, the outer surface of HIP 1145 additionally includes a threaded portion 1158. Threaded portion 1158 threadably mates with corresponding threads on the interior of interface 1160. Similar to interface 60, interface 1160 provides a smooth transition between handle portion 1124 and barrel portion 26. In other implementations, HIP 1145 may omit threaded portion 1158, wherein interface 1160 is secured to handle portion 1124 and/or HIP 1145.
Damper 1147 comprises an elastomeric or resilient mass of material captured between handle portion 1124 and the interior diameter service of barrel portion 26 within barrel portion 26. In one implementation, damper 1147 comprises a mass of rubber or rubber -like material filling the volume between the proximal region 36 of barrel portion 26, mechanically coupled to or physically contacting the inner surface of barrel portion 26 and the outer surface of handle portion 1124. In one implementation, damper 1147 is formed by filling the volume between HIP 1145 and the end of handle portion 24 with elastomeric material or rubber-like material in a liquid like state, wherein the elastomeric or rubber-like material is subsequently dried or cured to a solid-state. In yet another implementation, damper 1147 is formed by securing a tubular rubber -like sleeve about the portion of handle portion 1124 that is received within barrel portion 26. Damper 1147 absorbs vibration and shock as barrel portion 26 pivots about one or both of pivot joint 1140 and pivot joint 50.
Although each of
As shown by
As further shown by
In one implementation, tube 70 has a circular cross-section. In another implementation, tube 70 has an elliptical or polygonal cross sectional shape. In one implementation, tube 70 has a wall thickness of between 0.01 and 0.25 inch. In one implementation, tube 70 has an interior diameter of between 0.1 and 1.4 inches and an outer diameter of between 0.12 and 1.5 inches. In one implementation, tube 70 has a length of at least 3 inches. In one implementation, tube 70 extends along at least 3 inches of barrel portion 26. In one implementation, tube 70 extends along at least 10 percent of the axial length of barrel portion 26. In one implementation, tube 70 can extend from the end cap of bat 20. In another implementation, tube 70 can extend from the handle. In another implementation, tube 70 can extend from the proximal end 36 of bat. In one implementation, the thickness of the tube can vary along its length, such as a thin to thick, thick to thin, or other variable thickness configurations.
In one implementation, tube 70 may be formed in a fashion similar to handle portion 24. As indicated above, in some implementations, tube 70 may be formed concurrently with the forming of handle portion 24 as a single integral unitary body. In one implementation, tube 70 is formed of a strong, generally flexible, lightweight material, preferably a fiber composite material. Alternatively, tube 70 can be formed of other materials such as an aluminum alloy, a titanium alloy, steel, other alloys, a thermoplastic material, a thermoset material, wood or combinations thereof
Weight 44 comprises a mass of material having a prescribed weight. In one implementation, weight 44 comprises an elongate solid plug positioned within tube 70. In yet another implementation, weight 44 may comprise hollow portions. In one implementation, weight 44 may have an outer cross sectional shape or profile that matches and corresponds to the cross-sectional inner shape or profile of tube 70. In one implementation, weight 44 has an axial length of between 0.1 and 10 inches.
In one implementation, weight 44 has a uniform density and/or uniform weight distribution in both longitudinal or axial directions and radial directions with respect to its centerline. In yet another implementation, weight 44 may have a non-uniform density and/or non-uniform weight distribution in at least one of the longitudinal/axial direction and radial direction with respect to its centerline. In one implementation, weight 44 may comprise multiple layers, wherein different layers have different densities and/or are formed from different materials so as to provide different weight distributions in the radial direction. In one implementation, weight 44 may comprise multiple axial segments having different densities and/or formed from different materials so as to provide different weight distributions in the axial a longitudinal direction. In some implementations, weight 44 may have a varying outer shape or outer diameter, wherein only portions of the outer surface of weight 44 are in contact with the inner surface of tube 70 and wherein the radially narrower portions have a lower weight as compared to the wider portions of weight 44.
Although illustrated as having a circular cross-sectional shape, in other implementations, the weight 144 may have a noncircular or asymmetrical cross-sectional shape to further inhibit rotation of the weight relative to the tube.
Although illustrated as being formed from a single member, in other implementations, weight 44 may be provided by multiple independent sections or segments mounted or otherwise secured to one another to provide adjustability for weight 44.
In one implementation, segments 347, 348 and 349 are releasably secured to one another. For purposes of this disclosure, the term “releasably” or “removably” with respect to an attachment or coupling of two structures means that the two structures may be repeatedly connected and disconnected to and from one another without material damage to either of the two structures or their functioning. For example, in one implementation, segment 348 may comprise a threaded shaft 351 (shown in broken lines) projecting from either side which are threadably received within corresponding threaded bore 353 (shown in broken lines) in segments 347 and 349. As a result, segment 347 and/or 349 may be separated from segment 348 and replaced with a different segment with different dimensions and/or formed from different materials. In yet another implementation, segments 347, 348 and 349 releasably snap to one another, allowing separation for being interchanged with different segments. As a result, the configuration and weight distribution of weight 344 may be customized. In another implementation, segment 348 can be comprised of one or more elastomeric materials to provide dampening between segments 347 and 349. Although weight 344 is illustrated as comprising three distinct segments, in other implementations, weight 344 may comprise a pair of different segments or more than three different segments. In yet other implementations, the different segments of weight 344 may be integral with one another (such as being cast as a one piece member), providing a single integral unitary body or one piece unit.
Each of the example weights 44, 144, 244 and 344 are retained within their respective tubes against relative rotational movement and axial movement with respect to the respective tube. In one implementation, as shown by
In other implementations, the weight, such as weights 44, 144, 244 and 344, may be retained against both axial movement and rotational movement by coatings deposited upon one or both of the inner surface the tube and the outer surface of the weight.
As shown by
In the example illustrated, weight 444 is multi-layered, having an inner layer or core 460 and an outer layer 462. In such an implementation, core 460 is formed from material providing the weight characteristics of weight 444. Outer layer 462 comprises a different material, such as a coating, film or laminate about core 460. In one implementation, layer 462 comprises a low friction material, such as polytetrafluoroethylene, to facilitate sliding of weight 444 within tube 440. In yet another implementation, layer 462 comprise a high friction material, such as a rubber-like material, wherein weight 444 may be pushed into tube 440 and wherein tube 444 will be retained at a desired location within tube 440 once positioned at the desired location. In yet other implementations, weight 444 may comprise a single homogenous mass of material.
In yet other implementations, the weight, such as weights 44, 144, 244 and 344, is retained against rotation and axial movement relative to the tube as a result of the tube resiliently deforming or flexing around or about the weight.
Sleeve portion 542 is sized less than the outer diameter or outer dimension of weight 444. During insertion of weight 444 into sleeve portion 542, sleeve portion 542 stretches and then grips the received weight 444. In the example illustrated, the inner surface of sleeve portion 542 has a shape or profile matching the outer shape or profile of the received weight, such as weight 444. In the example illustrated, the outer surface of sleeve portion 542 also has a shape or profile substantially matching the outer shape or profile of the received weight, such as weight 444. In yet other implementations, sleeve portion 542 may be resiliently compressible such that while the inner surface of sleeve portion 542 has a shape or profile substantially matching the outer shape or profile of the received weight, the outer surface of sleeve portion 542 does not substantially change in response to receipt of the weight by sleeve portion 542, wherein the change in shape of the inner surface of sleeve portion 542 is “absorbed” by the resulting compression of the material forming sleeve portion 542.
In one implementation, sleeve portion 542 is sufficiently stretchable/compressible and resiliently flexible to allow reception of weight 444 so as to deform and wrap at least partially about weight 444, while at the same time, being sufficiently inelastic so as to prevent sleeve portion 542 from radially moving into contact with barrel 26 during impact of barrel 26 with the ball during a swing. In one implementation, the entirety of tube 540 is formed from a resiliently flexible and stretchable material. In another implementation, selected portions of tube 540 are formed from a resiliently flexible and stretchable and/or compressible material.
In yet other implementations, the weight, such as weights 44, 144, 244 and 344, may be retained against both axial movement and rotational movement by a plurality of recesses, grooves or channels, and one or more generally resilient projections or tabs. The recesses, grooves or channels can be positioned on either the inner surface of the tube or on the outer surface of the received weight, and the one or more projections can be positioned on the opposite surfaces of the tube or the weight.
Weight 644 is similar to weight 44 described above except that weight 644 comprises at least one detent, provided by an annular groove 648 that is sized to receive a projection or group of projections 646. In the example illustrated, weight 644 comprises a plurality of such grooves 648, wherein the grooves 648 are axially spaced with a center-to-center pitch that matches the center-to-center pitch of projections 646 along tube 640. In yet other implementations, such as in implementations where projection 646 comprise a plurality of circumferentially spaced projections, in lieu of comprising a detent in the form of an annular groove 648, weight 644 may comprise a plurality of circumferentially spaced detents, the detents having a circumferential spacing matching the circumferential spacing of the circumferentially spaced projections.
In use, weight 644 is pushed through tube 640 until positioned at a desired axial location along tube 640. As weight 644 is being pushed, projections 646 resiliently flex and bend. At each available position, where projections 646 are in alignment with grooves 648, grooves 648 receive such projection 646 to audibly indicate or to indicate through tactile reception, such reception at the available weight securement location. The user may choose the particular weight securement location or continue to push (or pull) weight 644 along tube 640 to another available weight securement location.
Weight 664 is similar weight 44 described above except that weight 664 comprises at least one projection 668 sized to project into a selected one of detents 666 of tube 660. In the example illustrated, weight 664 comprises a plurality of such projection 668, wherein the projections 668 are axially spaced with a center-to-center pitch that matches the center-to-center pitch of detents 666 along tube 660. In yet other implementations, such as in implementations where detents 666 comprise a plurality of circumferentially spaced detents, in lieu of projection 668 each comprising an annular rib 668, weight 664 may comprise a plurality of circumferentially spaced projections 668, the projection 668 having a circumferential spacing matching the circumferential spacing of the circumferentially spaced detents 666.
In use, weight 664 is pushed through tube 660 until positioned at a desired axial location along tube 660. As weight 664 is being pushed, projection 668 resiliently flex and bend. At each available position, where projections 668 are in alignment with detents 666, detents 666 receive such projection 668 audibly indicate, or through tactile reception, such receptionat the available weight securement location. The user may choose the particular weight securement location or continue to push (or pull) weight 664 along tube 660 to another available weight securement location.
In each of the implementations described above with respect to
In yet other implementations, the weight, such as weight 44, 144, 244 and 344 is axially retained in place within tube 70 by a mass of material at least partially encapsulating weight 44 and bonding to the inner surface of tube 70.
In some implementations, the retainer similar to retainer 676 may be used to encapsulate and retain a plurality of weights within tube 70.
Weights 684 and 685 are similar to weight 44 except that weights 684 and 685 can have different dimensions are different weight characteristics as compared to weight 44. In the example illustrated, weight 44, weight 684 and weight 685 are arranged in a stack with their axial ends in contact with one another. In other implementations, other weights may be stacked to provide the bat 20 with other weight distribution characteristics. For example, in other implementations, tube 70 may alternatively contain two individual weights or more than three individual weights.
Retainer 686 comprises a mass of liquid or flowable material which retains weights 44, 684, 685 in place within tube 70 relative to tube 70 and relative to barrel portion 26. In one implementation, a first mass of material 689 is deposited within tube 70 while in a solid state. In another implementation, material 689 is deposited within tube 70 while in a liquid state, wherein the liquid is subsequently solidified. Material 689 has a surface 691 which serves as a stop for locating the stack of weights. Thereafter, weights are individually positioned within tube 70 and stacked upon or against stop surface 691. Once a desired selection and number of weights have been inserted into tube 70 against stop surface 691, a second mass of material 693 is deposited on top of the stack of weights. In one implementation, the second mass material 693 comprises a solid material or a plug. In another implementation, the second mass of material 693 is deposited in tube 70 while in a liquid or flowable state, wherein the mass material subsequently solidified. Materials 689 and 693 form retainer 686 which secures the stack of weights in place within tube 70 and relative to barrel portion 26. In some implementations, weights 44, 684 and 685 are secured in place within tube 70 prior to insertion of tube 70 into barrel portion 26. In another implementation, the material 693 that encapsulates weights 44, 684 and 685 may be omitted where a plug is alternatively positioned within tube 70 adjacent to weight 685 on an opposite side of weight 685 as weight 684.
Tube 740 is similar to tube 70 except that tube 740 additionally comprises a plurality or series of openings 749 extending through and spaced along tube 740 within barrel portion 26. In one implementation, openings 749 are uniformly spaced along tube 740. In another implementation, openings 749 are non-uniformly spaced along tube 740, wherein those regions of tube 740 in which finer adjustments with regard to the positioning of weight 44 may be desirable are provided with a greater density of openings 749 (a smaller pitch between opening 749) as compared to those openings 749 in other regions of tube 740. Openings 749 cooperate with retainer 746 to secure weight 44 at a selected one of the plurality of different available positions along tube 740. In one implementation, openings 749 are internally threaded. In one implementation, retainer 746 can include two or more retainers.
Retainer 746 comprises a locator, such as a pin, which extends through a selected one of openings 749 into engagement with weight 44 so as to retain weight 44 in a selected position along tube 740. In one implementation, retainer 746 comprises a screw that screws into weight 44, wherein prior to receiving the screw, weight 44 lacks a detent or bore. In another implementation, retainer 746 comprises a screw, pin or bolt that passed through a selected one of openings 749 into a pre-existing detent 751, such as a preformed or predefined threaded or unthreaded bore, in weight 44.
Weight 844 is similar to weight 44 except that weight 844 comprises a plurality of detents 851 and axially or longitudinally spaced along weight 844. Detents 851 comprise depressions extending into weight 844 or the reception of the locator of retainer 746. As shown by
Tube 1040 is similar to tube 740 described above except that tube 940 extends within barrel portion 26, terminating prior to handle portion 24. Tube 1040 is supported by end cap 1070. In particular, tube 1040 is cantilevered from end cap 1070 so as to project into barrel portion 26. In the example illustrated, tube 1040 projects at least 2 inches into barrel portion 26 towards distal end 62 and knob 22 (shown in
End cap 1070 comprises a structure which closes off barrel portion 26 and forms the distal end 64 of bat 1020. In the example illustrated, end cap 1070 has a curved or semi-spherical end profile or shape. In other implementations, end cap 1070 may have other outer profiles or shapes. End cap 1070 supports tube 1040. In one implementation, tube 1040 and end cap 1070 are integrally formed as a single unitary body. In yet another implementation, tube 1040 is seated within a centered bore of end cap 1070. In yet other implementations, tube 1040 may be bonded, welded, fastened or otherwise secured to end cap 1070 so as to be centered along a longitudinal centerline of bat 1020.
As indicated by broken lines in
End cap 1270 is similar to end cap 1070 described above. Similar to end cap 1070, end cap 1270 supports the end of tube 1140 at distal end 64 of bat 1220. In the example illustrated, end cap 1270 comprises end portion 1272, outer ring 1274 and inner ring 1276. End portion 1272 closes off or blocks end opening of barrel portion 26. Outer ring 1274 projects from end portion 1272 and is sized so as to be press fit against the inner surface of barrel portion 26. In one implementation, adhesives, fasteners or welds may additionally be provided to further secure outer ring 1274 to barrel portion 26. Inner ring 1276 projects from end portion 1272 in words of outer ring 1274. Inner ring 1276 forms an interior cavity 1278 into which the end portion of tube 1140 is press-fit. In other implementations, tube 1140 may be further secured to inner ring 1278 by adhesives, fasteners or welds.
Tube 1340 is similar to tube 1140 except that tube 1340 terminates within barrel portion 26. Similar to tube 1040 described above with respect to bat 1020 in
Tube 1440 is similar to tube 1140 except that tube 1440 omits openings 749. In other implementations, opening 749 may be provided in tube 1440, wherein tube 1440 is injected with retainer 676, while the material of retainer 676 is in a liquid or flowable form, through such openings 749 to secure weight 44 in place within tube 1440. Retainer 676, described above, secures weight 44 at a selected position within tube 1440 and against relative movement with respect to tube 1440. In one implementation, retainer 676 comprises a material, such as epoxy, that is injected while in a liquid or flowable state, wherein the material solidifies by evaporation or curing to secure and bond weight 44 at a selected position within and to tube 1440.
Pivot joint 1450 pivotably supports proximal region 36 of barrel portion 26 for pivotal movement about an axis perpendicular to the centerline 32 of bat 1420. Pivot joint 1450 facilitates inward deflection of barrel portion 26 when impacting a ball, enhancing or improving the performance of the barrel portion and the hitting zone of the ball bat.
As shown in
Handle interface piece (HIP) 1458 comprise a component that is bonded to the outer diameter an outer surface of handle portion 24. HIP 1458 interconnects handle portion 24 to barrel portion 26 by supporting rounded head 1456. In the example illustrated, HIP 1458 comprises an a tube or sleeve having a pair of spaced walls 1461 that form an intermediate channel 1462 that contains a ring 1466 having an outer rounded surface forming head 1456. In other implementations, ring 1466 may be secured to HIP 1458 without being received within the intermediate channel 1462. For example, ring 1466 may be welded, bonded, mechanically snapped into or onto, or otherwise secured to HIP 1458. In some implementations, ring 1466 is omitted, wherein head 1256 is integrally formed as a single unitary body about along the exterior of HIP 1458.
In the example illustrated, the outer surface of HIP 1458 additionally includes a threaded portion 1468. Threaded portion 1468 threadably mates with corresponding threads on the interior of interface 1470. Similar to interface 960, interface 1470 provides a smooth transition between handle portion 24 and barrel portion 26. In other implementations, HIP 1458 may omit threaded portion 1468, wherein interface 1470 is secured to handle portion 24 and/or HIP 1458.
Damper 1460 comprises an elastomeric or resilient mass of material captured between handle portion 24 and the interior diameter surface of barrel portion 26 within barrel portion 26. In one implementation, damper 1460 comprises a mass of rubber or rubber-like material filling the volume between the proximal region 36 of barrel portion 26, mechanically coupled to or physically contacting the inner surface of barrel portion 26 and the outer surface of handle portion 24. In one implementation, damper 1460 is formed by filling the volume between HIP 1458 and the end of handle portion 24 with elastomeric material or rubber-like material in a liquid like state, wherein the elastomeric or rubber-like material is subsequently dried or cured to a solid-state. In yet another implementation, damper 1460 is formed by securing a tubular rubber-like sleeve about the portion of handle portion 24 that is received within barrel portion 26. Damper 1460 absorbs vibration and shock as barrel portion 26 pivots about one or both of pivot joint 1450 and pivot joint 1450.
The tube 2240 can have a length within the range of 1.0 to 10 inches. The tube 2240 is axially spaced apart from the end cap by at least 1.0 inch, and axially spaced apart from the distal end of the handle portion 24 by at least 1.0 inch. The tube 2240 includes at least one weight 44. The tube 2240 can also include a plurality of openings 749 and at least one retainer 746 for selectively positioning the weight 44 within the tube 2240. In another implementation, the tube 2240 can be formed without openings or a separate retainer.
The above disclosure describes multiple bat configurations. It should be understood that although each of the bats illustrated in
The annular support element 2242 can be used to facilitating the positioning of tube 1340 within the barrel portion 1226, such as collinear with the longitudinal axis of the bat 1220. The annular support element 2242 can be a single annular element, two annular elements, or three or more annular elements. The thickness of the annular element measured with respect to the longitudinal axis of the bat 2220 can range from 0.25 in to 8 inches. In one implementation, the thickness of the annular element 2242 can be within 0.5 to 2.0 inches. In other implementations, other thicknesses can be used. In one implementation, the annular support element is a lightweight polymeric foam that serves to dampen movement of the cantilevered end 1342 of the tube 1340 during use. In other implementations, the annular element 2242 can be formed of one or more lightweight, tough materials, such as, for example, an open cell or closed cell foamed material, cork, plastic, a polymeric material, wood, a fiber composite material, and combinations thereof. The annular member 2242 can be formed of a highly compressible material such that the annular member can have a negligible effect on the stiffness (or resistance to deflection during an impact with a ball) of the bat. In another implantation, the annular element 2242 can be formed of a stiffer material that can significantly increase the stiffness of the bat. The annular element 2242 can be secured to one or both of the inner surface of the barrel portion 1226 of the bat 1220 and the outer surface of the tube 1340 through any attachment means including, for example, adhesives, compression fits, molding and combinations thereof. In one implementation the annular element 2242 can be unsecured to one or both of the inner surface of the barrel portion 1226 of the bat and the outer surface of the tube 1340.
The tube 1340 can include a tube end 1342 that closes the proximal end of the tube 1340. In one implementation, the tube end 1342 can extend beyond the outer diameter of the tube 1340 to form a rim for facilitating the engagement of the annular element 2242 with the tube 1340.
Although the present disclosure has been described with reference to example implementations, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the claimed subject matter. For example, although different example implementations may have been described as including one or more features providing one or more benefits, it is contemplated that the described features may be interchanged with one another or alternatively be combined with one another in the described example implementations or in other alternative implementations. Because the technology of the present disclosure is relatively complex, not all changes in the technology are foreseeable. The present disclosure described with reference to the example implementations and set forth in the following claims is manifestly intended to be as broad as possible. For example, unless specifically otherwise noted, the claims reciting a single particular element also encompass a plurality of such particular elements.
The present invention is a continuation of U.S. patent application Ser. No. 16/678,971, entitled “Bat With Barrel Pivot Joint,” filed on Nov. 8, 2019 and claims the benefit of 35 U.S.C. § 120, which is a continuation-in-part of U.S. patent application Ser. No. 15/381,260, entitled “Bat With Barrel Inner Tube Weight,” filed on Dec. 16, 2016, and claims the benefit of 35 U.S.C. § 120. U.S. patent application Ser. No. 16/678,971 is also a continuation-in-part of U.S. patent application Ser. No. 15/166,427 filed on May 27, 2016 (now U.S. Pat. No. 10,507,367), and claims the benefit of 35 U.S.C. § 120.
Number | Date | Country | |
---|---|---|---|
Parent | 16678971 | Nov 2019 | US |
Child | 17205219 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15381260 | Dec 2016 | US |
Child | 16678971 | US | |
Parent | 15166427 | May 2016 | US |
Child | 15381260 | US |