The present invention relates to an article of manufacture used for practicing batting technique.
A practice bat includes an elongated shaft having a free sliding region. In an embodiment, the free sliding region is followed by a first damping region followed by a second damping region. A slider and a damper substantially surround the shaft. The slider is moved from the free sliding region toward a free end of the shaft when the shaft is swung from a handle end, the damper is pushed toward the free end of the shaft when it is impacted by the slider and the damper dissipates slider kinetic energy and tends to bring the slider to rest. The resting position of the damper relative to markings on the shaft in the first damping region is operative to indicate swing quality.
In another embodiment a practice bat comprises an elongated shaft, the shaft having a gripping region and a free sliding region. A bumper is fixed to the shaft adjacent to the free sliding region and an end stop is fixed to a distal end of the shaft. A carrier assembly including a carrier tube and a replica sports ball circumferentially engages the carrier tube and the carrier tube has a cylindrical section and a rim at one end, the rim having an outer diameter greater than that of the cylindrical section. The carrier tube circumferentially engages the shaft free sliding region. The carrier assembly is operative to translate along the shaft in response to inertial forces, the motion of the carrier tube being limited by the bumper and the end stop. Gripping and swinging the shaft causes the carrier assembly to move along the shaft free sliding region, the carrier tube to strike the end stop, the ball to break free from the carrier tube, the ball to pass over the end stop, and the ball to take flight.
The present invention is described with reference to the accompanying figures. These figures, incorporated herein and forming part of the specification, illustrate embodiments of the present invention and, together with the description provide examples enabling a person skilled in the relevant art to make and use the invention.
The disclosure provided in the following pages describes examples of several embodiments of the invention. The designs, figures, and description are non-limiting embodiments of the invention. Other embodiments of the disclosed device may or may not include the features described herein. Moreover, disclosed advantages and benefits may apply to only certain embodiments of the invention and should be not used to limit the disclosed inventions.
In various embodiments, suitable means known to persons of ordinary skill in the art are used to fix or removably fix the end stop 108 to the shaft 102. Such means include pins such as roll pins 204 passing through the shaft and the end stop (as shown), similarly situated screws, similarly situated bolts, interference fits, use of adhesives, screw threads within a bore of the end piece and mating screw threads on the interfacing region of the shaft, spring loaded fasteners, other fasteners and other similar means. Where an end stop 108 is used, some embodiments include a second bumper 114 encircling the shaft 102 and abutting the end stop.
The end knob 104 is fitted to the shaft in a manner similar to that used for the end stop. In some embodiments, the end knob is fixed to the shaft using a pin such as a roll pin 206 passing through the shaft 102 and the end knob (as shown).
The shaft 102 may be made of any suitable rigid material including wood and metallic materials commonly used for ball sports bats known by persons of ordinary skill in the art. In an embodiment the shaft is tubular. In an embodiment the shaft has a hollow portion 305 (see
The damper 112 may be made of any material suited for interacting with the shaft 102 to resist relative motion therebetween. For example, one or more synthetic and natural materials are used in various embodiments including rubbers, plastics, corks, woods, and similar materials. Further, one or more rubbers such as butyl, ethylene propylene diene monomer, fluorocarbon, silicon, vulcanized, non-vulcanized and resilient rubbers are used in some embodiments. In an embodiment, the damper is an O-Ring made from a suitable elastomer such as one of the rubbers mentioned above. In various embodiments using O-Rings, the O-Ring cross-sectional shape is circular, arced or prismatic.
The first and second bumpers 110, 114 may be made of any material suited for being impacted by the slider 106. For example, one or more synthetic and natural materials with shock resistant characteristics are used in various embodiments including rubbers, plastics, corks, woods, and resilient materials. In particular, one or more plastics including PVC, ABS, HDPE, acetal resin such as DuPont Delrin® and resilient plastics are used in some embodiments. Further, one or more rubbers such as butyl, ethylene propylene diene monomer, fluorocarbon, silicon, vulcanized, non-vulcanized and resilient rubbers are used in some embodiments. In an embodiment, the bumpers are O-Rings made from a suitable elastomer such as one of the elastomers mentioned above.
The slider 106 may be made of any material suited for sliding on a shaft subjected to swinging motions and suited for impacting the above described bumpers 110, 114. In various embodiments, the slider is made from one or more of the materials suited for making bumpers and metallic materials such as alloys and/or compounds of aluminum, steel, copper, stainless steel, titanium and other suitable metals. For example, a multipart slider having a metallic body extending between plastic end pieces is used in an embodiment. In another embodiment, a plastic damper such as a PVC tube is used.
In some embodiments, the slider 106 includes an anti-friction material at a slider end-face 130 for minimizing the coefficient of friction between the end-face and the damper 112. Persons of ordinary skill in the art will understand that suitable anti-friction materials are chosen in relation to the selected damper material. In various embodiments, one or more antifriction materials containing Teflon®, silicon, nylon, polyethylene, inorganic lubricants, organic lubricants and the like is used. In some embodiments, one or both of the damper and the slider are made from one or more of these antifriction materials.
The knob 104 may be made of any material suited to rigorous use associated with a practice bat. These materials include the materials of construction of the bumpers 110, 114 listed above. The end stop 108 may be made of any material suited to rigorous use associated with a practice bat, fitment to the shaft 102 and impacts caused by the slider 106. These materials include the materials of construction of the bumpers listed above.
Along the length of the practice bat l1 there is a gripping region 118, a free sliding length or region l2 is followed by a first damping length or region l3. In an embodiment, a second damping length or region l4 follows the third damping length. Within the free sliding length, the slider 106 typically moves along the shaft 102 without being impeded by the damper ring 112. Within the first damping length, a damper ring will, if present, impede movement of the slider as the slider must push the damper ring as it translates along the first damping length toward the free end 105. Within the second damping length, a damper ring will, if present, impede movement of the slider as the slider must push the damper ring as it translates along the second damping length toward the free end.
In an embodiment, the first damper length l3 includes one or more indicators 211a-e for indicating position along the length of the shaft 102. For example, in the embodiment shown there are five indicators 211a-e in the form of marks such as marks made with colorants or pigments, deformations, embedments or the like. As shown in the figure, the marks encircle the shaft in the form of a continuous ring. In another embodiment, the marks are discontinuous such that they do not form a continuous ring around the shaft but take, for example, the form of discrete points or arc-like segments.
In an embodiment, the first bumper 110 encircles the shaft and a holding means tends to prevent movement of the bumper relative to the shaft. In some embodiments, a holding means includes a shallow circular groove 202 in the shaft in which the bumper is seated; here, a peripheral portion of the bumper protrudes above the outer surface of the shaft. In other embodiments, the holding means includes one or more of mechanical fasteners and adhesives.
In an embodiment, an electric annunciator 304 for providing signals to a user of the practice bat is provided. Suitable annunciators include devices providing visible, audible, tactile and other signals 402 perceptible by a user of the practice bat 100. Devices providing visible signals include lamps, lights, light emitting diodes, filament devices, plasma devices, laser devices and other known devices for visible signaling. Devices providing audible signals include buzzers, horns, speakers, mechanical devices, piezoelectric devices and other known devices for aural signaling. Devices providing tactile signals include buzzers, electrical stimulators, thermal stimulators, motion stimulators, piezoelectric devices and other known devices for tactile signaling.
Where an electric annunciator 304 is used, some embodiments have no damper ring 112. Other embodiments relocate the damper ring 112a to abut the bumper 114 to avoid a need to reposition the damper ring after one or more swings.
In an embodiment, the practice bat 100 includes an electrical circuit including the annunciator 304. For example,
In various embodiments having an elastomeric damper, the damper slows the impacting slider 106 when, among other things, the damper drags on the shaft and/or the damper rolls on the shaft. In an embodiment, the shaft surface material and finish and the damper material are chosen to provide a suitable coefficient of friction and contact force for slowing the slider due to frictional drag between the damper and the shaft. Contact force is determined here by, among other things, the elasticity of the damper material, the thickness of the damper material and the unstretched inner diameter of the damper.
Where it is desired to prevent rolling of the damper 112 on the shaft 102, a damper having a prismatic cross-section such as a rectangular or triangular cross-section may be chosen. Here, the damper tends to stop the slider's motion relative to the shaft when, among other things, a stick-slip interaction between the shaft and the damper causes cyclic damper flexing and, among other things, conversion of kinetic energy to heat as a result of losses including mechanical hysteresis losses.
Where rolling of the damper 112 on the shaft 102 is desirable, embodiments having a damper with a circular cross section may be chosen. In such an embodiment the damper slows the slider by, among other things, cyclic flexing.
a is a cross-section 600a of a portion of the practice bat shaft. Shown here is the slider 106 encircling the shaft 102 and abutting an elastomeric damper 112 having a substantially circular cross-section. Positions C1, C2 and C3 indicate successive positions of the damper as it is forced along the shaft by a translating slider 106. At position C1, a point “x” on the periphery of the damper is in contact with the shaft as indicated by rotational arrow “n1.” At position C2, the point “x” on the periphery of the damper is directly opposite the shaft due to rotation indicated by arrow “n2.” At position C3, the point “x” on the periphery of the damper is again in contact with the shaft as indicated by arrow “n3.”
b illustrates two diameters, “d1” and “d2” 600b. Diameter “d1” corresponds to the substantially unflexed fibers of the damper at peripheral location “x” and at position C1. Diameter “d2” corresponds to the substantially flexed fibers of the damper at the peripheral location “x” at position C2. Therefore, it is seen that cyclic flexure of a substantially circular damper 112 results when the damper rolls on the shaft. Here, the damper tends to stop the slider's motion relative to the shaft when, among other things, a rolling interaction between the shaft and the damper causes cyclic damper flexing and, among other things, conversion of kinetic energy to heat as a result of losses including mechanical hysteresis losses.
Use of the practice bat 100 is typified by a swinging motion resulting when a user grasps the gripping region 118 and swings the bat as if to make contact with a sports ball such as a baseball. As described below, the practice bat provides users and others with an indication of a batter's swing quality.
Before the swing, the damper 112 is located at a first damper position “z” that is spaced apart from the second damper by a length l0 (see
In
As will be appreciated by persons of ordinary skill in the art, selection of the initial damper position “z” to increase l0 also increases the work required to move the damper to the end point “u.” Therefore, it is seen that l0 may be selected by a user or a user's coach to accommodate the user's ability, a particular practice exercise or a similar training goal.
Embodiments of the practice bat 100 provide signals useful for training the user. In an embodiment, the slider 106 and shaft 102 are of contrasting colors such that the position of the slider with respect to the shaft is observable during a swing or a portion of a swing. An example exercise using this feature is attempting to force the slider to position “u” at the instant the free end of the practice bat 105 reaches the desired location for striking a ball.
As discussed above, selection of l0 will influence the swing dynamics and in particular how much swinging force a user must impart to the practice bat to achieve the desired result. For example, l0 can be adjusted to match the strength of a particular player and/or in a program aimed at enhancing a player's strength. In addition, selecting “z” to coincide with a particular position indicator on the shaft 211a-e allows a repeatable practice regime to be established, monitored and adjusted for a particular player.
To emphasize the slider reaching position “u,” some embodiments utilize audible devices to provide a signal. In an example, the damper 112 and second bumper materials are chosen to provide an audible signal resulting from their mechanical impact. In another example, an electrical annunciator provides an audible signal when a pushbutton 302 of an electrical switch 301 is depressed by interaction with the damper 112 and slider 106. In yet other embodiments, electrical devices producing visible and/or tactile signals are used to indicate a location of the slider.
In various embodiments, the practice bat 100 has either a removable end stop 108 and second bumper 114 or it does not utilize these parts. Such bats have no position “u” where the slider 106 stops due to contacting the second bumper or the end stop. A swinging force sufficient to cause the slider to push the damper off the shaft 102 results in the slider taking flight. This feature can be used to train a player's swing and in cases to emphasize swing technique for directing the flight path of the ball struck by the bat.
The carrier assembly includes a carrier tube 722 and a ball, sports ball or replica of a sports ball 728. The carrier tube includes a cylinder 726 for engaging the shaft 716 and a ball retaining rim 724 fixed to one end of the cylinder. Notably, the cylinder and rim may be a single part or multiple parts. In various embodiments, the ball is one or more of solid, hollow, thin walled, smooth surfaced, and perforated.
In an embodiment, there is a loose fit between the ball's bore ID1 and the carrier tube cylinder's outer diameter OD1. For example, the ball's bore is about 0.1% to 5% larger than the carrier tube cylinder's outer diameter. And, in an embodiment, there is an interference fit between the ball's bore ID1 and the carrier tube cylinder's outer diameter OD1. For example, the ball's bore is about 0.1% to 1% smaller than the carrier tube cylinder's outer diameter. In some embodiments 885 (see
In various embodiments, the ball 728 is hollow and in various embodiments the ball is solid. The ball has a borehole 802 for receiving the shaft 716. For example, a thin-walled hollow ball such as a WIFFLE® ball is used in some embodiments.
In an embodiment, an end stop 708 is fitted to the shaft 702 near the free end 705. The end stop has a through bore 709 for receiving the shaft 716 and an outer diameter shown as OD2. End stop outer diameter OD2 is equal to or less than the inner diameter of the ball ID1. Embodiments of the end stop having differing weights attributable to one or more of end stop dimensions, material density, and end stop attachments provide a means for varying bat swing dynamics, for example during batter training or batter warm-up.
In various embodiments, suitable means known to persons of ordinary skill in the art are used to fix or removably fix the end stop 708 to the shaft 702. Such means include a knob that is integral with the shaft 920 and a knob that is fastened to the shaft. Fastening means include pins such as roll pins 730 passing through the shaft and the end stop (as shown in
The end knob 704 is fitted to the shaft in a manner similar to that used for the end stop. In some embodiments, the end knob is fixed to the shaft using a pin such as a roll pin 732 passing through the shaft 702 and the end knob (as shown in
The shaft 702 may be made of any suitable rigid material including wood and metallic materials commonly used for ball sports bats known by persons of ordinary skill in the art. In an embodiment the shaft is tubular. In other embodiments, the shaft is solid such as is common for a wooden baseball bat.
In some embodiments, a damper (see for example
The bumper 710 and the end stop 708 are preferably made from a material suited for being impacted by the carrier tube 722. In some embodiments, the bumper and or end stop material is selected to enhance impact sounds when the bumper or end stop is struck by the carrier tube. In an embodiment, the bumper is made from a metal such as steel or aluminum. In other embodiments one or more synthetic and natural materials with shock resistant characteristics are used including rubbers, plastics, corks, woods, and resilient materials. In particular, one or more plastics including PVC, ABS, HDPE, acetal resin such as DuPont Delrin® and resilient plastics are used in some embodiments. Further, one or more rubbers such as butyl, ethylene propylene diene monomer, fluorocarbon, silicon, vulcanized, non-vulcanized and resilient rubbers are used in some embodiments.
The carrier tube 722 may be made of any material suited for sliding on a shaft subjected to swinging motions and suited for impacting the above described bumper 710 and end stop 708. In various embodiments, the slider is made from one or more of the materials suited for making bumpers and metallic materials such as alloys and/or compounds of aluminum, steel, copper, stainless steel, titanium and other suitable metals. In some embodiments the carrier tube is made from a polymer such as a plastic. Suitable plastics include thermoplastic elastomers, PVC, ABS, and HDPE materials.
The knob 704 may be made of any material suited to rigorous use associated with a practice bat. These materials include the materials of construction of the bumper 710 listed above. The end stop 708 may be made of any material suited to rigorous use associated with a practice bat, fitment to the shaft 702 and impacts caused by the slider carrier tube 722. These materials include the materials of construction of the bumpers listed above.
Along the length of the practice bat there is a gripping region 718 denoted by length l1 and a free sliding region denoted by length l2. The carrier assembly 720 is free to move along the free sliding region. The ball 728 is movable with respect to the carrier tube cylinder 726 in response to inertial forces such as swing forces.
Use of the practice bat 700A is typified by a swinging motion resulting when a user grasps the gripping region 718 and swings the bat as if to make contact with a sports ball such as a baseball. As described below, the practice bat provides users and others with an indication of a batter's swing quality.
Before the swing, the carrier assembly 720 is located adjacent to the bumper 710. When preparing to swing, the practice bat 700A is raised such that it's free end 705 points generally upward and the carrier assembly 720 rest against the bumper 710. During the swing, the carrier assembly is subjected to forces causing it to move toward the free end 705.
Embodiments of the practice bat 700A provide signals useful for training the user. In an embodiment, the carrier assembly 720 and shaft 702 are of contrasting colors such that the position of the carrier with respect to the shaft is observable during a swing or a portion of a swing.
To emphasize the carrier assembly 720 reaching the end stop 708, some embodiments utilize audible devices to provide a signal. In an example, the carrier tube 726 and end stop materials are chosen to provide an audible signal resulting from their mechanical impact. In another example similar to that shown in
An elongated shaft 920 has a handle end 924 and an opposed free end 922. Near the handle end, a shaft gripping region 926 is located between an end knob 904 and a bumper 910 that is spaced apart from the end knob. In various embodiments, either or both of the bumper and the end knob are integral with the shaft. In yet other embodiments, either or both of the bumper and the end knob are not integral with the shaft.
A ball 928 is for engaging the shaft 920. The ball has a through bore 902 with an internal diameter ID3. A free length of the shaft 916 with an outer diameter OD3 is for mating with the through bore of the ball. In various embodiments, the ball is one or more of solid, hollow, thin walled, smooth surfaced, and perforated. For example, a thin-walled hollow ball such as a WIFFLE® ball is used in some embodiments.
In an embodiment, there is a loose fit between the ball's bore ID3 and the shaft outer diameter OD3. For example, the ball's bore is about 0.1% to 5% larger than the shaft outer diameter OD3. And, in an embodiment, there is an interference fit between the ball's bore ID3 and the shaft's outer diameter OD3. For example, the ball's bore is about 0.1% to 1% smaller than the shaft's outer diameter OD3.
In various embodiments, suitable means known to persons of ordinary skill in the art are used to fix or removably fix the knob 904. Such means include a knob that is integral with the shaft 920 and a knob that is fastened to the shaft. Fastening means include pins such as roll pins 730 passing through the shaft and the end stop (as shown in
The shaft 702 may be made of any suitable rigid material including wood and metallic materials commonly used for ball sports bats known by persons of ordinary skill in the art. In an embodiment the shaft is tubular. In other embodiments, the shaft is solid such as is common for a wooden baseball bat.
The bumper 910 is preferably made from a material suited for interfacing with the ball 928. In an embodiment, the bumper is made from a metal such as steel or aluminum. In other embodiments one or more synthetic and natural materials are used including rubbers, plastics, corks, woods, and resilient materials. In particular, one or more plastics including PVC, ABS, HDPE, acetal resin such as DuPont Delrin® and resilient plastics are used in some embodiments. Further, one or more rubbers such as butyl, ethylene propylene diene monomer, fluorocarbon, silicon, vulcanized, non-vulcanized and resilient rubbers are used in some embodiments.
The knob 704 may be made of any material suited to rigorous use associated with a practice bat. These materials include the materials of construction of the bumper 710 listed above.
Along the length of the practice bat there is a gripping region 926 and a free sliding region 916. The ball 928 is free to move along the free sliding region in response to inertial forces such as swing forces.
Use of the practice bat 900 is typified by a swinging motion resulting when a user grasps the gripping region 926 and swings the bat as if to make contact with a sports ball such as a baseball. As described below, the practice bat provides users and others with an indication of a batter's swing quality.
Before the swing, the ball 928 is located adjacent to the bumper 910. When preparing to swing, the practice bat 900 is raised such that its free end 922 points generally upward and the ball rests against the bumper 910. During the swing, the ball is subjected to forces causing it to move toward the free end 922.
While the batter's swing is in progress, the ball 928 moves away from the bumper 910, along the bat's free sliding region 916, and toward the bat's free end 922. Near the end of the batter's swing, the ball passes over the bat's free end and takes flight, generally traveling in a direction pointed to by the shaft at the moment the ball leaves the shaft 920.
Embodiments of the practice bat 900 provide signals useful for training the user. In an embodiment, the ball 928 and the shaft 920 are of contrasting colors such that the position of the carrier with respect to the shaft is observable during a swing or a portion of a swing.
While various embodiments of the present invention have been described above, it should be understood that they have been presented by way of example only, and not limitation. It will be apparent to those skilled in the art that various changes in the form and details can be made without departing from the spirit and scope of the invention. As such, the breadth and scope of the present invention should not be limited by the above-described exemplary embodiments, but should be defined only in accordance with the following claims and equivalents thereof.
This application claims the benefit of U.S. Provisional Patent Application 61/163,707 filed 26 Mar. 2009 for PRACTICE BAT.
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