FIELD OF THE INVENTION
The field of the invention is ball pitching or ball throwing machines. More specifically the invention relates to machines for automatically throwing balls, to assist players in practicing movements in various sports. In particular the invention relates to apparatus and methods for holding multiple balls and individually feeding balls into a ball throwing unit which throws the balls.
BACKGROUND OF THE INVENTION
Ball throwing machines are used in various sports, such as baseball and tennis. Typically these types of machines have a tray, track, or other component for holding several balls queued up for throwing. The balls are individually moved out of the holding space and dropped or pushed into a ball projecting device, such as a pair of opposing rotating pinch wheels. The balls are projected or thrown out by the machine typically at evenly spaced timed intervals.
While these types of machines have met with varying degrees of success in the past, challenges remain in designing a ball throwing machine that is lightweight, compact and easily portable. Challenges also remain in designing a ball throwing machine that is reliable, simple to set up and use, and inexpensive to manufacture. Accordingly, it is an object of the invention to provide an improved ball throwing machine is needed.
SUMMARY OF THE INVENTION
A new ball throwing machine includes a ball magazine for feeding balls into a ball tube. A flex element, such as a spring finger, extends into the ball tube. A holder, which may be pivotally mounted on the ball tube, is movable from a first position wherein the holder or part of the holder extends into the ball tube, to a second position wherein the holder is withdrawn. An arm moves through an arm slot in the ball tube in a reciprocating motion, with the arm moving the holder from the first to the second position. The holder may return to the first position via spring force. The flex element and the actuation of the arm feeds balls, one at a time, from the ball magazine into a throwing assembly which throws the balls.
BRIEF DESCRIPTION OF THE DRAWINGS
In the drawings, the same element number indicates the same element in each of the views.
FIG. 1 is a perspective view of a new ball throwing apparatus.
FIGS. 2-7 show the sequence of movement of components of the ball feeder assembly of the ball throwing apparatus of FIG. 1.
FIG. 2 is section view of the ball feeder assembly of the ball throwing apparatus shown in FIG. 1 with ball feeder assembly in a first position and a ball in the load position.
FIG. 3 is section view of the ball feeder assembly in a second position.
FIG. 4 is a section view of the ball feeder assembly in a third position.
FIG. 5 is a section view of the ball feeder assembly in a fourth position.
FIG. 6 is a section view of the ball feeder assembly in a fifth position.
FIG. 7 a is section view of the ball feeder assembly now returned to the first position initially shown in FIG. 2 and with the ball moved into the projecting or throwing assembly shown in FIG. 1.
DETAILED DESCRIPTION
Turning now in detail to the drawings, as shown in FIG. 1, a ball throwing machine 10 may be described as having a ball magazine 18, a ball feeder assembly 22 for dispensing balls at uniform time intervals, a throwing assembly 68 for throwing balls, and a base, such as a tripod 12. The assemblies may optionally be designed so that they may be quickly and easily attached to together to provide the ball throwing machine 10 as shown in FIG. 1, and then separated from each other for transport and storage.
Referring still to FIG. 1, the ball throwing machine 10 has a ball feeder housing 16 which may be attached to a tripod 16 via a pivot joint 14. A ball tube 24 is attached to or part of the ball feeder housing 16. The ball magazine 18 is attached to a first generally up-facing end of the ball tube 24. The ball magazine 18 may be formed via a magazine tube, or two or more magazine tubes attached together end to end, to provide the ball holding capacity desired. The inside diameter of the ball magazine 18 is slightly larger, for example 5-10 mm larger, than the diameter of balls to used with the throwing machine 10. Slots or holes 20 may be provided in the magazine 18, to allow the user to see how many balls are in the magazine. Alternatively, the magazine may be translucent. One of more legs of the tripod 12, such as the rear leg 82, may contain batteries and/or wireless control circuitry. The hinge 14 may include a clamping or friction device such as a lever, wing nut, etc., to hold the ball feeder housing at a desired angle on the tripod 12. The throwing assembly 68 is attached to the ball feeder housing 16 and/or a second end of the ball tube 24.
Referring now to FIG. 2, a collar 36 may be provided at the first end of the ball tube 24, for attaching the magazine 18 onto the ball tube 24. The ball tube 24 is curved, with first or inlet end of the ball tube 24 generally oriented vertically, or within e.g., 30 degrees of vertical, and with the second or outlet end generally oriented horizontally. The plane of the opening of the first end of the ball tube, marked IN FIG. 3, may be oriented at an angle of about 60 to 120 degrees relative to the plane of the opening of the second end of the ball tube, marked OUT in FIG. 3. The position of the OUT plane relative to the ground, and the corresponding launch angle of the ball, may be adjusted by tilting the housing 16 about the hinge 14, or by changing the position of the rear tripod leg. The upper or inner wall 64 of the ball tube 24 has a radius of curvature substantially larger than the radius of the ball 40, to allow the ball to move through the ball tube without binding.
The lower or outer wall 62 of the ball tube may have a corresponding radius of curvature based on the diameter of the balls 40 used with the machine 10. For example, for use with balls having a diameter of about 7 cm, such as a tennis ball, the inside diameter of the ball tube may be about 8 cm, the radius of curvature of the inner wall 64 may be 4 to 10 cm, and the radius of curvature of the outer wall 62 may be about 7 cm greater than the radius of curvature of the inner wall.
In FIG. 2, an electric motor 46 within or on the ball feeder housing 16 rotates a drive wheel 42. The motor may be powered by batteries contained in or on the tripod 12 or the ball feeder housing 16, or in a separate battery box. Alternatively, the motor 46 may be powered by a line cord 80 shown in FIG. 1. Referring to FIG. 2, the lower end of an arm 50 is pivotally attached to a fixed point, for example to a pivot attachment 54 in the ball feeder housing 16.
A ball roller 58 may be attached to upper end of the arm 50. A straight slot 52 is provided in the arm 50. A pin 44 on the drive wheel 42 extends into and/or through the slot 52. A cap or head on the pin 44 holds the pin 44 into the slot. A bearing or roller may be provided on the drive pin 44, to reduce friction and wear between the drive pin and the slot. The upper end of arm 50 extends through an arm slot 48 in the outer wall 62 of the ball tube 24. The arm slot may be just wide enough to provide clearance for the arm 50.
The arm 50 may have a generally straight lower section 51 and an offset upper section 53. The arm slot 52 may be straight and centered in the lower section 51 and also parallel to the lower section 51. The offset upper section 53 advantageously has a curved back surface 55 that projects rearward. The ball roller 58 at the upper end of the upper section 53 may be substantially aligned over the arm slot 52.
Referring still to FIG. 2, a flex element, such as a leaf spring 26 or similar biasing element extends radially into the ball tube 24 from or through the inner tube wall 62. As shown in FIG. 2, the retainer spring may be attached to the outer surface of the inner wall 64 and extend through an opening in the inner wall 64. A spacer 66 may be attached to, or formed on, the inside surface of the inner tube wall, adjacent to the retainer spring 26. A holder 28 is positioned in the ball tube 24 generally across or opposite from the retainer spring 26. The holder 28 may include a holder plate 32 attached at an angle to a holder leg 34. The holder 28 is biased into the up position shown in FIG. 2 by a biasing element, such as a spring 30. The holder is pivotally attached to the ball tube 24, for example at a pivot point on the outside surface of the outer tube wall 62. The leg 34 of the holder extends down through the arm slot in the outer tube wall 62.
The throwing assembly 68 typically includes a throwing housing 70 which may be attached to a collar 78 on the second end of the ball tube 24. A pair of spaced apart pinch wheels 74 are rotated by motors 76. The pinch wheels are spaced apart by a dimension slightly less than the diameter of the balls 40. As a ball 40 enters the throwing housing 70, it is pinched slightly by the pinch wheels 74, pulled in between the wheels, and then ejected or thrown out of the throw housing 70 with a throwing speed determined by the diameter and rotation speed of the pinch wheels 74, as is well known in the art.
The motor or motors 76 used in the drive assembly 68 may also be powered via the line cord 80, or by batteries. The motors 76 and 46 may optionally be remotely controlled via a wireless link via wireless circuitry on or in the throwing machine 10. For example, The motor 46, or motors 46 and 76, may be connected to a receiver/controller 75 in the housing 16. The regulator assembly 22, or both the regulator assembly 22 and the pitching assembly 68, may then be remotely controlled via a remote unit 77. Control signals initiated by the user via the remote unit 77 are transmitted to the receiver/controller 75 by radio frequency, infrared light, or other known techniques. The remote unit 77, if used, may include controls to turn on the motor 46, or motors 46 and 76, and also to adjust ball feed speed of the regulator assembly 22, and the pitching speed of the pitching assembly 68. One or more elevation angle actuators 79 connected to the receiver/controller 75 and positioned to tilt the housing 16 may also be provided, to allow the elevation angle to be remotely changed. Other forms of throwing assemblies may also be used in place of the pinch wheel type of throwing assembly. For example, a throwing assembly using a throwing arm, lever or paddle, or a pneumatic throwing apparatus may be used. In an alternative design, the receiver/controller may be voice activated. In this design, no remote unit 77 is needed. Rather, the receiver/controller is programmed, or otherwise designed to respond to voice commands, such as, ON, OFF, FAST, SLOW, UP, DOWN, etc.
In use, balls 40 are loaded into the magazine 18. The first ball 40 to be loaded drops down through the magazine and moves into the load position as shown in FIG. 2. The ball is held in the load position by the holder plate 32, with the holder 28 biased into the up position shown in FIG. 2. In the load position, the ball 40 is supported from below by the holder plate 32, with the front surface of the ball resting against the inside surface of the upper wall 64 of the ball tube 24.
The motor 46 is switched on, and the motor 46 rotates the drive wheel 42. The motor 46 and a gear reduction unit may typically rotate the drive wheel at about 6-12 rpm. As shown in FIG. 3, as the drive wheel 42 rotates counterclockwise, the arm moves rearward, with the curved back surface 55 of the arm 50 coming into contact with the holder leg 34. Since the curved back surface 55 of the upper section 53 is offset rearward from the lower section 51 of the arm 50, the arm 50 begins to pivot the holder 28 while the lower section 51 of the arm 50 is substantially vertical. Accordingly, the configuration of the arm effects the timing of the movement of the holder 28, as well as providing curved surface that slides against the holder leg 34, with a cam-like movement. The drive wheel may rotate clockwise or counterclockwise.
As shown in FIG. 4, the rearward movement of the arm 50 pushes the holder leg 34 rearward, rotating the holder 28 counterclockwise into a down position. In the down position shown in FIG. 4, the holder plate 32 is moved down or away from the centerline of the ball tube 24 sufficiently to allow the ball 40 to pass. The roller 30 may move into the corner formed between the holder plate 32 and the holder leg 34, and the holder plate 32 may be near flush with the inside surface of the outer tube wall 62, when the holder 28 is in the down position.
Via gravity, the ball 40 moves past the holder plate 32 and comes into contact with the leaf spring 26 or similar retaining element. The spring 26 holds the ball 40 in the ready position shown in FIG. 4. The curvature of the ball tube 24 reduces the downward force acting on the ball 40 in the ready position from the queue of balls above it in the ball tube 24 and in the magazine 18, since the majority of the weight of the queue of balls bears on the outer tube wall 62, and not on the ball 40 in the ready position. Accordingly, it is not necessary for the retainer spring 26 to hold a ball in the ready position against the entire weight of the queue of balls behind the ready position.
As shown in FIG. 5, as the drive wheel 42 continues to rotate, the arm 50 reverses direction in a gentle reciprocating motion and begins to pivot forwardly. The roller 58 moves forwardly in an arc and pushes on the back surface of the ball 40. At the same time, the holder 28 moves back into the up position to hold back the balls in the queue. As the arm 50 continues moving forward, the arm pushes the ball 40 under the retainer spring 26 which flexes upwardly while continuing to exert force on the ball. As the arm completes its forward stroke, the arm pushes the ball past the retainer spring and into the throw assembly 68. The spring 26 flexes back outwardly to its original position as the ball passes by, tending to flick the ball forward. Hence, the forward movement of the arm 50 and the return movement of the spring 26 may combine to move the ball into the throw assembly 68. The spring 26 may have an angles or flattened end 27, as shown in FIGS. 2 and 3, to assist in the flicking motion.
As shown in FIGS. 6 and 7, as the ball enters the throw assembly 68 it is pinched between the rollers 74 and thrown rapidly forward out of the throw housing. The retainer spring 26 flexes back to its original position. As shown in FIG. 7, the arm 50 is once again in the starting position shown in FIG. 2. The ball feeder assembly 22 then repeats the sequence described above to throw the next ball 40 in the queue.
The speed of the motor 42 may be changed to increase or decrease the time interval between sequentially thrown balls. The motor speed may be changed using controls on the machine 10 or using a remote or wireless control. The speed of the motor 42 may also be varied to provide a degree of randomness between ball launches. The throwing assembly motors 76 may be similarly controlled to select different ball launch speeds.
Thus, a novel ball throwing machine and methods have been shown and described. The machine may be used for throwing baseballs, softballs, tennis balls, volleyballs, soccer balls, and similar types of balls. Various changes and substitutions may of course be made without departing from the spirit and scope of the invention. The invention, therefore, should not be limited except by the following claims and equivalents of them.