Pitching machine

Information

  • Patent Grant
  • 6715478
  • Patent Number
    6,715,478
  • Date Filed
    Tuesday, December 31, 2002
    22 years ago
  • Date Issued
    Tuesday, April 6, 2004
    20 years ago
  • Inventors
  • Examiners
    • Nguyen; Kien T.
    Agents
    • Chase Law Firm, L.C.
Abstract
A ball pitching machine utilizes a leaf spring coupled by linkage to a ball pitching arm. The flexion of the spring can be adjusted by varying the time of operation of a motor driven spring flexion assembly. Upon the selectable spring flexion being achieved, the user then energizes a ball pitching arm for rotation of the arm through a rest position, a ball pick up position and then to a ball release position. During arm rotation, the arm is first coupled to the spring by a linkage assembly such that further rotation of the arm causes the stored energy in the spring to be released to the arm at a position to effect the ball trajectory. The ball trajectory compensates for the various ball speeds so that the ball penetrates the batter's strike zone. This energy transfer accelerates rotation of the arm to a ball release position, the speed of the ball, as perceived by the batter, corresponding in part to the spring flexion and/or ball trajectory as selected by the user.
Description




BACKGROUND OF THE INVENTION




This invention pertains to a pitching machine and, more particularly, to a ball pitching machine for pitching a ball at different user-selectable trajectories and/or speeds.




Various forms of ball pitching machines are known in the prior art which are said to simulate the speed and trajectory of balls as if pitched by an actual person.




In order to more accurately simulate the action of a pitched ball it is desirable to utilize a machine having a pitching arm. One problem with past machines was the inability to effectively vary the speed of the pitched ball as hurled from the pitching arm as manual adjustment of the machine was required. Thus, it is desirable to have such a function so that a range of users can effectively utilize one machine.




In response thereto I have invented a pitching machine which utilizes an elongated spring powered pitching arm. My machine utilizes a leaf spring which can be selectively flexed according to the desired speed of the pitched ball. Once flexed the spring is then releasably coupled to the pitching arm during rotation of the arm from a rest position to a ball release position. Subsequent to ball pick up the energy of the selectively flexed spring is released to the pitching arm so as to urge the arm towards its ball release position for ball release at a different trajectory. Accordingly, the degree of flexion of the spring controls in part the speed of the arm in rotatable movement to the ball release position and thus the speed and trajectory of the ball hurled therefrom.




Accordingly, it is a primary object of my invention to provide a pitching machine capable of simulating a pitched ball.




Another object of this invention is to provide a pitching machine, as aforesaid, wherein the speed of the pitched ball can be regulated.




Still another object of this invention is to provide a pitching machine, as aforesaid, which regulate the energy stored in a flexed spring for regulating the ball speed.




A further object of this invention is to provide a pitching machine, as aforesaid, wherein the degree of initial spring flexion is selectable by a user.




A still further object of this invention is to provide a pitching machine, as aforesaid, wherein the pitching arm is coupled to the flexed spring during movement from a ball rest to a ball release position for further spring flexion.




A particular object of this invention is to provide a pitching machine, as aforesaid, wherein a plurality of balls can be delivered for sequential pick up by the ball pitching arm.




A more particular object of this invention is to provide a pitching machine, as aforesaid, wherein the initial leaf spring flexion is provided by a motor driven chain drive assembly, which is regulated by a user.




Another particular object of this invention is to provide a pitching machine, as aforesaid, wherein the leaf spring is initially flexed by a first spring flexing assembly and then further flexed by rotation of the pitching arm.




A further particular object of this invention is to provide a pitching machine, as aforesaid, wherein the trajectory of the pitched ball can be regulated so as to deliver the ball at different speeds to the batter in the strike zone.




Other objects and advantages of this invention will become apparent from the following description taken in connection with the accompanying drawings, wherein is set forth by way of illustration and example, a now preferred embodiment of this invention.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a front view of the pitching machine housing;





FIG. 2

is a left side view of the pitching machine with a wall of the housing broken away to show the apparatus therein at a rest position;





FIG. 3

is a rear view of the

FIG. 1

pitching machine housing;





FIG. 4

is a right side view of the pitching machine with the right side wall broken away to show the apparatus therein in a rest position with the arrows indicating the rotatable path of the pitching arm;





FIG. 5

is a left side view of the pitching machine showing the spring apparatus at an initial second flexion position beyond the

FIG. 2

position;





FIG. 6

is a left side view of the pitching machine as shown in

FIG. 5

showing the spring apparatus beyond said second

FIG. 5

flexion position as provided by rotation of the wheel and coupled pitching arm from the phantom line rest position to the solid line ball pick up position;





FIG. 7

is a left side view of the ball pitching machine in

FIG. 6

showing a further flexion of the leaf spring in

FIG. 6

as provided by further rotation of the pitching arm wheel and pitching arm;





FIG. 8

is a diagrammatic view showing the position of the pitching arm wheel and arm at a rest position with the hub stop on the pitching arm drive wheel displaced from the pitching arm bracket;





FIG. 9

is a diagrammatic view showing a subsequent contact of the hub stop of the pitching arm wheel with the pitching arm bracket upon clockwise rotation of the pitching arm wheel;





FIG. 10

is a diagrammatic view showing the position of the pitching arm in its ball pick up position upon further clockwise rotation of the wheel and pitching arm;





FIG. 11

is a diagrammatic view of the pitching arm showing in phantom lines the pitching arm upon clockwise rotation to an over center position and in solid lines the pitching arm at its ball hurling position, the hub stop being free of the pitching arm bracket;





FIG. 12

diagrammatically shows one form of a spring flexion motor/switch/circuit combination.











DESCRIPTION OF THE PREFERRED EMBODIMENT




Turning more particularly to the drawings,

FIGS. 1 and 3

show my pitching machine


100


encompassed by a housing


200


. Housing


200


has a base


205


, front


210


, rear


220


, side


230


,


240


and top


250


walls. Walls have been broken away in the drawings for ease of illustration. The front wall


210


presents a vertical extension


212


allowing for rotation of pitching arm


550


. A ball hopper


260


communicates with an opening in the top wall


250


for delivery of the balls via trough


262


to a ball rest


264


.




Within the housing


200


is enclosed the pitching apparatus as supported by frame work including horizontal


270


,


272


,


274


,


276


,


278


and vertical


280


,


282


struts. The pitching apparatus generally comprises a rotatable pitching arm assembly


500


, a spring tension assembly


400


and an assembly for linking the tension of spring


410


to pitching arm


550


.




The spring tension assembly


400


includes a multi-leaf spring


410


which is mounted at an intermediate point to bracket


414


which in turn is mounted to vertical strut


282


. As such a lower spring end


412


and an upper spring end


416


is presented which are flexed relative to this intermediate mounting bracket


414


.




The lower end


412


of spring


410


is connected to a linkage arm


420


which is pivotally linked to arm


422


. Arm


422


is connected to a shaft


424


which extends through vertical frame strut


282


. This shaft


424


is driveably connected to a cogged wheel


478


such that rotation of wheel


478


causes rotation of shaft


424


and rotation of linkage arms


420


,


422


linked thereto.




The upper spring end


416


is linked to a cogged wheel


474


via intermediate linkage comprising arms


440


,


442


,


444


, connecting rod


446


and linkage arm


448


. One end of arm


444


is pivotally connected to frame strut


280


at


445


with the other end pivotally connected to arm


442


at


443


. Arm


442


is in turn pivotally connected to arm


440


which is connected to a shaft


460


which extends through vertical strut


282


and is connected to wheel


474


.




As shown in

FIG. 4

the spring tension assembly


400


further includes a chain


470


driven by an electric motor


472


shaft and wound about the cogged wheels


474


,


478


and idler wheels. Energization of motor


472


results in a chain driven rotation of wheels


474


,


478


, associated shafts


424


,


460


and linkage arms


420


,


422


,


440


,


442


. Rotation of these linkage arms imparts clockwise flexion to the lower spring end


412


and counterclockwise flexion of the upper end


416


of leaf spring via the linkage arm


444


, rod


446


, arm


448


combination as viewed in

FIGS. 2

,


5


,


6


and


7


.




As shown in

FIG. 4

the pitching arm drive assembly


500


includes a motor


510


, chain


530


driven wheel


520


and idler wheels. Wheel


520


is rotatably mounted about a shaft


522


extending through a frame strut


276


atop strut


282


(FIG.


5


). Wheel


520


presents a central hub


524


having a lug/hub stop


526


thereon. One end


552


of the pitching arm


550


is attached to a sleeve


553


which rotatably encompasses the shaft


522


. Thus, arm


550


can be independently rotated about shaft


522


. The end


552


of pitching arm


560


presents a bracket


556


which is rotatable with arm


550


.




As diagrammatically shown in

FIGS. 8-11

, the energization of electric motor


510


rotates wheel


520


via drive chain


530


. Pitching arm


550


will not rotate about shaft


522


until hub stop


526


contacts bracket


556


as shown in FIG.


9


. At this point further rotation of wheel


520


will also rotate pitching arm


550


from a

FIG. 9

position to a

FIG. 10

ball pick up position and then to a

FIG. 11

phantom line over center position due to the hub stop


526


/bracket


556


contact.




A plurality of normally closed switches


1


-


6


or equivalents in an electrical circuit is diagrammatically shown in

FIG. 12

as adjacent to motor


472


shaft


471


. Such switches are mounted on frame adjacent motor


472


shaft


471


. The user has a displaced rotary switch in series with these six parallel switches. These switches are part of an electrical circuit including rotary switch


475


at the selected position, relay


477


, power source


498


and motor


472


. Each switch is normally closed. Upon user selection of a particular position


1


-


6


of the rotary switch


475


the circuit energizes motor


472


and rotates the shaft


471


. Lobes


473


. on the adjacent rotating motor


472


shaft


471


will upon contact urge the related closed switch into an open position so as to open the particular circuit. The lobes


473


are arranged about the circumference of motor


472


shaft


471


such that lobes


1


-


6


correspond in a one-to-one relationship with switches


1


-


6


. Lobe


473


/


1


will first contact an adjacent switch


1


. Lobes


2


-


6


will subsequently contact adjacent switches


2


-


6


. The lobes are thus arranged about the motor shaft


471


such that rotary switch position I will energize the motor


472


for the least amount of time with rotary switch position


6


, energizing the motor for the maximum amount of time. Selection of rotary switch positions


2


-


5


will thus energize the motor


472


for successively longer increments relative to switch


1


. Thus, the motor


472


operates the least amount of time if rotary switch position


1


is selected and the longest amount of time if rotary switch position


6


is selected.




Although I proposed a circuit for mechanical opening of the switches by a related lug


473


on the rotating motor


472


shaft, other equivalent switching circuitry may be used so as to energize the motor


472


for selected periods of time. Motor


570


is also subsequently energized by a user. However, this motor


570


, once energized by a user, will operate for a set period of time.




In use

FIGS. 2 and 4

illustrate the pitching machine apparatus at its rest/relaxed position. At this position the pitching arm


550


is at approximately a ten o'clock position (

FIG. 2

) with the ends


412


,


416


of leaf spring


410


being at a normal position. Upon selection of a rotary switch position (


1


-


6


) the energized motor


472


chain drives wheels


474


,


478


. Thus, the associated linkage arms, as above described, are variably rotated upon rotation of the associated wheels


474


,


478


. This linkage arm rotation causes arm


420


to upwardly urge the lower end


412


of the leaf spring from a rest position and into a flexed position relative to the rest position (clockwise as viewed in FIGS.


2


and


5


). Concurrently, the linkage arms


440


,


422


are likewise being rotated about shaft


460


by rotation of the wheel


474


. This movement flexes the upper end


416


of the leaf spring


410


about its intermediate mounting point


414


(counterclockwise as viewed in

FIGS. 2 and 5

) via the intermediate linkage arms


444


,


446


,


448


. Note in

FIG. 5

that the displaced leaf of the spring


410


at the upper end (

FIG. 2

) is now contiguous to the adjacent leaf in

FIG. 5

while the lower end


412


of the spring has been moved clockwise from its

FIG. 2

position.




Accordingly, leaf spring


410


is now flexed which increases the potential energy stored therein. As the selectable rotary switch positions


1


-


6


varies the amount of time of motor


472


operation, the amount of movement of the linkage arms and thus flexion of the associated lower and upper ends of the leaf spring


410


can be controlled from a minimum flexion (switch


1


) to a maximum flexion (switch


6


). Thus,

FIG. 5

shows the spring being at one user selectable flexed position which can be chosen from a plurality of six possible flexed positions. Thus, the degree of flexion of the spring


410


depends on the rotary switch position (


1


-


6


) selected corresponding to the time of motor


472


operation. This stored energy of the flexed spring


410


can now be transferred to the pitching arm


550


.




Subsequent to spring


410


flexion, the pitching arm


550


is rotated by user closure of a circuit which energizes motor


510


. Initially drive wheel


520


rotates independent of pitching arm


550


as hub stop


526


is free of bracket


553


. During rotation of wheel


520


the lug/stop


526


on the hub


524


contacts pitching arm bracket


553


as shown in FIG.


9


. At this position the further rotation of wheel


520


also rotates bracket


553


and arm


550


due to this stop


526


/bracket


553


contact. At this

FIG. 9

position, rotation of the arm


550


likewise rotates the linkage


570


arm connected to sleeve


553


and arm


572


pivotally connected to arm


570


. Movement of these linkage arms


570


,


572


is transferred to connected arm


448


which is connected to spring


416


end. Thus, the hub stop


526


contact moves the linkage arms


570


,


572


,


448


which further flexes the upper end


416


of spring


410


from the earlier flexed position. Note that

FIGS. 6 and 7

show further successively greater flexion due to the rotation of the pitching arm


550


as coupled to the spring by these linkage arms.




Linkage arm


570


is pivotally connected to linkage arm


572


at pivot point


571


. The height of this pivot point


571


relative to the base


205


is ultimately controlled by rotation of wheel


474


. Thus, at switch position I the motor operation is the shortest such that pivot point


571


position is at its lowest. Switch position


6


places the pivot point


571


at the greatest height as motor


472


operates for the longest period. This pivot point


571


will have positions therebetween corresponding to positions


2


-


5


of the rotary switch. The height of pivot point


571


determines in part the “firing” position of the pitching arm


550


, i.e., the point at which the energy of the spring is transferred to the arm


550


during arm rotation. Basically, the higher the pivot point


571


, relative to the base


205


, the later the “firing” position of the arm


550


during its rotation and the lesser the trajectory of the ball hurled therefrom.




Upon rotation of the wheel


520


the scoop


562


on arm


550


will pass through the spaced-apart rods


264


of the ball rest so as to deposit the ball therein (FIG.


10


). Subsequent rotation of wheel


520


urges the hub stop


526


/flange


556


combination to an over center position, i.e., the phantom line

FIG. 10

position.




At an over center position the braking contact of the stop


524


/bracket


556


combination loses its effect. Thus, the upper end


416


of flexed leaf spring


410


is free to move from its subsequently flexed position (clockwise,

FIG. 7

) to its previous flexed position (FIG.


5


). This spring movement occurs at a point during arm rotation which transfer the energy of the flexed spring


410


to the arm


550


via the linkage arms


448


,


572


,


570


causing an accelerated rotation/“firing” of the arm towards a solid line ball hurling position (FIG.


11


). During this movement the ball is released from the scoop


562


and through the opening in the front wall


210


of the housing. Shock absorber apparatus


700


is connected to frame and pitching arm


550


so as to dampen the movement of arm after ball release to preclude arm damage.




As above described, the pivot point height is the lowest at position


1


and the highest at position


6


. The higher the pivot point the later the “firing” of the arm


550


as the path of transfer of energy from spring end


416


to arm


550


, defined by the linkage arms therebetween, varies from a straight line path. Thus the lesser the trajectory. Thus, at switch position


1


the pivot point


571


is at its lowest as motor


472


operates for the least amount of time. Thus, the “firing” position of arm


550


is at its earliest point during arm rotation resulting in the greatest ball trajectory. At switch position


6


the motor


472


operates for the greatest amount of time placing the pivot point


571


at its highest relative to base. Thus, the “firing” position of arm is at its latest point during arm rotation. This results in the least ball trajectory. Accordingly, at positions


2


-


6


successively later firing positions and lesser ball trajectories relative to position


1


result. Concurrently, the spring end


416


is being incrementally flexed from positions


1


to


6


which can also increase ball speed. Thus, the incremental decrease in ball trajectory and/or increase in spring flexion can contribute in part to the ball speed and thus the arrival time of ball after release.




After ball release the motor


510


returns the wheel


520


and arm


550


to their normal

FIG. 8

position. The ball trough


262


/ball rest


264


combination has deposited another ball on the ball rest. Subsequently, the motor


510


can again be user energized causing rotatable movement of the arm


550


as above described through the rest, ball pick up, over center and ball hurling positions for a subsequent ball delivery. If the ball delivery speed is too slow or fast, an appropriate selection of the six rotary switch positions will vary ball speed/ball delivery time to the user due to the changes in ball trajectory or ball speed or both.




Accordingly, it can be seen that the spring tension assembly


400


is operable so as to move the spring


410


to one of six user selectable positions corresponding to a particular degree of spring flexion which in part determines ball speed. Also, the pivot point height


571


is being regulated which regulates the arm


550


“firing” position and thus ball trajectory. Once such position has been achieved, the pitching arm assembly


500


is user energized for rotation of arm


550


through a rest position, ball pick up position and over center position. During such rotation the arm


550


is coupled to the spring


410


for further flexion of spring


410


. Thus, the stored energy of the flexed spring


410


is available for delivery to the pitching arm


550


. Upon the arm


550


reaching the over center position the energy of the flexed spring


410


is transferred to the arm


550


via linkage arms as positioned corresponding to rotary switch positions


1


-


6


, causing an arm firing/accelerated rotation of the arm


550


and a ball release therefrom. Understandably the greater the spring flexion as selected by rotary switch positions


1


-


6


the more energy available for delivery to the arm rotation and the ball released therefrom. Also, the corresponding changes in ball trajectories can contribute to the speed in which the hurled ball reaches the user. I have found that the decreasing changes in ball trajectories at positions


1


-


6


cooperate with/compensate for the increasing changes in ball speeds at positions


1


-


6


so that the ball reaches the batter in the desired strike zone at such various switch positions.




It is to be understood that while a certain form of this invention has been illustrated and described, it is not limited thereto, except in so far as such limitations are included in the following claims and allowable equivalents thereof.



Claims
  • 1. An apparatus for propelling a ball, said apparatus comprising:a frame; a pitching arm, said pitching arm having a first end and a second end adapted for placement of a ball thereon; means for rotatably mounting said pitching arm to said frame for movement of said second end from a first position to a subsequent ball release position; a spring having first and second ends, said spring mounted to said frame; means for flexing said first or second ends of said spring or both from a first spring position to a second flexed spring position chosen from a plurality of possible second spring positions; means for coupling said flexed spring at said second position to said pitching arm during said rotation of said pitching arm towards said ball release position, a release of said flexed spring from said second position transferred to said pitching arm for rotating said pitching arm towards said ball release position and hurling a ball placed on said second arm end therefrom, a speed of the hurled ball determined in part by a degree of spring flexion corresponding to said selected second flexed spring position.
  • 2. The apparatus as claimed in claim 1 wherein said coupling means includes means for changing a trajectory of the hurled ball.
  • 3. The apparatus as claimed in claim 2 wherein the trajectory determines in part the speed of the hurled ball as presented to a batter.
  • 4. The apparatus as claimed in claim 1 wherein said rotatable mounting means comprises:a wheel rotatably mounted about an axis extending through said frame; means for rotating said wheel; a lug on said wheel, said first end of said pitching arm presenting structure adjacent said lug; said rotating wheel urging said lug into contact against said first end structure of said pitching arm, wherein said contact concurrently rotates said pitching arm with said wheel towards said ball release position.
  • 5. The apparatus as claimed in claim 4 wherein said coupling means comprises:means for linking said first arm end to said spring at said contact whereby a rotation of said first arm end operates said linking means and flexes said spring linked thereto.
  • 6. The apparatus as claimed in claim 1 wherein said spring flexing means comprises:a first spring linkage assembly connected to said first end of said spring and mounted in movement with an associated axis extending through said frame; a second spring linkage assembly connected to said second end of said spring and mounted in movement with an associated axis extending through said frame; first means for rotating said axis associated with said first spring linkage assembly, said rotation causing a flexion of said first spring end connected to said first spring linkage assembly; second means for rotating said axis associated with said second spring linkage, said rotation causing a flexion of said second spring end connected to said second spring linkage assembly; means for regulating said first and second axis rotating means, wherein to regulate the flexion of said first end or second ends of said spring or both.
  • 7. The apparatus as claimed in claim 6 wherein said first rotating means comprises:a first shaft defining said associated axis of said first spring linkage assembly; a first wheel rotatable with said first shaft; an electric motor in selectable communication with a power source; a chain driven by said motor and coupled to said first wheel to rotate said first wheel and said first shaft; means for regulating communication of said motor with said power source, whereby to rotate said first wheel for movement of said first spring linkage assembly upon operation of said motor, a degree of rotation of said first wheel and said first shaft corresponding to a degree of movement of said first spring linkage assembly and said flexion of said first spring end connected thereto.
  • 8. The apparatus as claimed in claim 7 wherein said second rotating means comprises:a second shaft defining said associated axis of said second spring linkage assembly; a second wheel rotatable with said second shaft, said chain coupling said second wheel to said motor to rotate said second wheel and said second shaft; said means for regulating the communication of said motor with said power source rotating said second wheel for movement of said second spring linkage assembly upon operation of said motor, a degree of rotation of said second wheel and said second shaft corresponding to a degree of said flexion of said spring end connected to said second spring linkage assembly.
  • 9. The apparatus as claimed in claim 8 wherein said regulating means comprises:an electrical circuit with said power source and motor therein; switch means for controlling said circuit including a plurality of user selectable switches, a user selectable closure of one of said switches closing said circuit for communicating said power source with said motor; a motor shaft rotatable by operation of said motor and positioned adjacent said switches; a plurality of lugs about said motor shaft in a one-to-one relationship with each of said switches, a contact of a lug with said one closed switch opening said one switch for ceasing communication of said motor with said power source, said lugs positioned about said motor shaft in a manner wherein a contact of each of said lugs with said one related closed switch results in a different time period of motor operation and rotation of said motor shaft.
  • 10. The apparatus as claimed in claim 9 wherein said lugs are placed about said motor shaft wherein a rotation of said motor shaft causing each said lug to contact said related switch at a different position of rotation of said motor shaft.
  • 11. The apparatus as claimed in claim 6 wherein said second rotating means comprises:a second shaft defining said associated axis of said second spring linkage assembly; a second wheel rotatable with said second shaft; an electric motor in selectable communication with a power source; a chain driven by said motor and coupled to said second wheel to rotate said second wheel and said second shaft; means for regulating communication of said motor with said power source, whereby to rotate said second wheel for movement of said second linkage assembly upon operation of said motor, a degree of rotation of said second wheel and said second shaft corresponding to a degree of movement of said second linkage assembly and said flexion of said second spring end connected thereto.
  • 12. The apparatus as claimed in claim 1 further comprising:a ball rest attached to said frame; a scoop attached to said second end of said pitching arm; said arm rotation from said first arm position urging said scoop into movement past said ball rest for deposit of a ball on said ball rest into said scoop prior to said arm reaching said ball release position.
  • 13. The apparatus as claimed in claim 1 wherein said spring comprises a leaf spring.
  • 14. An apparatus for hurling a ball, said apparatus comprising:a frame; a pitching arm attached to said frame, said pitching arm adapted for placement of a ball thereon; means for moving said pitching arm between a first rest position and a second ball hurling position; a spring assembly including a spring thereon, said spring having a first position and a second flexed position displaced from said first position for storage of potential energy therein; means for moving said spring to a selectable second flexed position of a plurality of possible second flexed spring positions, whereby to vary the degree of flexion of said spring; means for transferring a potential energy of said spring at said second position to said pitching arm during said movement of said pitching arm, said transferred energy moving said pitching arm to said ball hurling position for release of a ball on the pitching arm therefrom, a speed of the released ball corresponding in part to the degree of flexion of said spring at said second spring position.
  • 15. The apparatus as claimed in claim 14 wherein said transfer means includes means for changing a trajectory of the released ball, said trajectory in part affecting the speed of the ball presented to the user.
  • 16. The apparatus as claimed in claim 14 wherein said pitching arm moving means comprises:a wheel having a shaft defining a horizontal axis; means for rotating said wheel; means for coupling movement of said pitching arm to rotation of said wheel for rotation of said arm between said first rest and second ball hurling positions.
  • 17. The apparatus as claimed in claim 14 wherein said spring moving means comprises:a motor energized by a power source; at least one wheel attached to said frame and rotatable by said energized motor; linkage means connected to said at least one wheel and said spring, a rotation of said at least one wheel moving of said linkage means in a manner to flex said spring; means for selectably rotating said wheel from a first wheel position to a second wheel position selectable from a plurality of possible second wheel positions, said selected second wheel position effecting a degree of movement of said linkage means and a flexion of said spring connected thereto.
  • 18. The apparatus as claimed in claim 17 wherein said spring is a leaf spring comprising first and second ends, said linkage means connected to said first or second ends of said leaf spring or both, a movement of said linkage means flexing said spring at said first and second ends thereof or both.
  • 19. The apparatus as claimed in claim 17 wherein said selectable rotating means comprises:means for energizing said motor by said power source for a user selectable time period chosen from a plurality of possible time periods, said length of said time of motor energization presenting a selectable time of movement of said linkage means and a degree of flexion of said spring attached thereto.
  • 20. The apparatus as claimed in claim 14 wherein said transfer means further includes:means for further flexing said spring from said second spring position during said movement of said pitching arm from said first position and releasing said flexion of said spring, said means transferring said energy of said released spring to said arm.
  • 21. An apparatus for hurling a ball, said apparatus comprising:a frame; a pitching arm rotatably attached to said frame, said pitching arm having a first end and a second end adapted for placement of a ball thereon; means for rotating said pitching arm between a first rest position and a second ball hurling position; a spring mounted to said frame, a flexion of said spring from said first position to a second position resulting in a storage of potential energy therein; means for moving said spring to a second flexed position user selectable from a plurality of second flexed positions, whereby to vary the degree of potential energy stored in said spring; means for initially coupling said spring at said second flexed position to said pitching arm during said pitching arm rotation and subsequently releasing the potential energy of said coupled spring to said pitching arm during a subsequent arm rotation, said released energy further rotating said pitching arm to said hurling position for release of a ball on said second arm end therefrom, a speed of rotation of said arm regulated in part by to a degree of flexion of said spring at said second spring flexed .,position.
  • 22. The apparatus as claimed in claim 21 wherein said coupling means further regulates a trajectory of the ball released from said second arm end.
  • 23. The apparatus as claimed in claim 21 further comprising:a ball rest mounted to said frame for placement of a ball thereon, said ball rest in a path of rotation of said arm second end, wherein the ball is deposited on said second arm and during said arm rotation.
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4615325 Yamamura et al. Oct 1986 A
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6089215 Morris et al. Jul 2000 A