Short game analysis system

Abstract

The present invention generally relates to lightweight, portable robot for analyzing golf balls for short game performance attributes. The preferred robot is specifically designed to be lightweight and portable and to be able to hit a golf ball off of the ground or a mat that simulates the ground such that realistic short game performance can be evaluated.

Claims

1. A portable golf hitting robot, comprising: a frame, a drive shaft coupled to the frame, a drive unit coupled to a first end of the drive shaft for supplying torque thereto and a golf club gripping member coupled to a distal end of the drive shaft, and the robot further comprising a one-way clutch juxtaposed between the drive unit and the golf club gripping member, wherein the torque applied from the drive unit to the golf club gripping member is at a ratio of less than 4-1.

2. The portable golf hitting robot of claim 1, wherein the golf gripping member forms a lie adjusting plate such that the lie angle of a golf club can be adjusted.

3. The portable golf hitting robot of claim 2, wherein the lie adjusting plate includes a lie adjustment groove that is adjustably coupled to the drive shaft such that the lie angle of the golf club can be adjusted.

4. The portable golf hitting robot of claim 1, wherein the drive unit is a pneumatic rotary actuator coupled to the golf club gripping member through the drive shaft to provide torque at a ratio of 1-1.

5. The portable golf hitting robot of claim 4, wherein the robot further comprises pneumatic controls for adjusting the amount of force applied to the golf club by the drive unit.

6. The portable golf hitting robot of claim 1, wherein the robot further includes a disc brake coupled to the drive shaft, brake calipers and a cam coupled to the drive unit for actuating the brake calipers.

7. The portable golf hitting robot of claim 1, wherein the frame includes a plurality of arms, each of the arms having a pivot coupling at a first end and a ground abutting member at a distal end.

8. The portable golf hitting robot of claim 1, wherein the frame is comprised of aluminum and the robot weighs less than about 150 lbs.

9. The portable golf hitting robot of claim 8, wherein the robot weighs less than about 100 lbs.

10. A portable golf hitting robot system for swinging a golf club, comprising: a frame, a drive shaft coupled to the frame, a pneumatic rotary actuator coupled to a first end of the drive shaft for supplying power thereto and a golf club gripping member coupled to a distal end of the drive shaft for coupling the golf club to the robot, wherein the torque ratio from the pneumatic rotary actuator to the golf club gripping member is less than 2-1, and wherein the golf club is rotated in a pendulum manner about the drive shaft axis which extends proximate a grip portion of the golf club.

11. The portable golf hitting robot system according to claim 10, wherein the torque ratio from the pneumatic rotary actuator to the golf club gripping member is approximately 1-1.

12. A portable golf hitting robot system, comprising: a frame, a drive shaft coupled to the frame, a drive unit coupled to a first end of the drive shaft for supplying power thereto and a golf club gripping member coupled to a distal end of the drive shaft, and the robot further comprising a one-way clutch juxtaposed between the drive unit and the golf club gripping member, wherein the robot can swing a golf club attached thereto and impact a golf ball off of a ground element; and wherein the ground element is a hitting mat comprised of a turf layer, a foam layer coupled to a bottom surface of the turf layer, a first structural layer coupled to a bottom surface of the foam layer, a base, and a plurality of springs juxtaposed the base and the first structural layer.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The novel features that are characteristic of the present invention are set forth in the appended claims. However, the preferred embodiments of the invention, together with further objects and attendant advantages, are best understood by reference to the following detailed description in connection with the accompanying drawings in which:

(2) FIG. 1 is a prior art robot;

(3) FIG. 2 is a front, right side perspective view of a robot according to the present invention;

(4) FIG. 3 is a side view of a robot according to the present invention;

(5) FIG. 4 is a back, right side perspective view of a robot according to the present invention; and

(6) FIG. 5 is a perspective view of a hitting mat according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

(7) Using golf ball hitting robots to evaluate golf balls and golf clubs is not new. Robots are particularly useful in that they can apply a very repeatable swing so that different golf balls or clubs can be compared. Launch monitors such as that disclosed in US Publication No. 2005/0272516 can be used to detect variations associated with club, ball and robot performance. Hitting robots have heretofore been designed to hit drivers and other clubs. However, their primary use is to evaluate club and ball performance for longer shots. Thus, the robots include a hitting arm such that the golf swing is imitated as much as possible. The robots are not used for short game performance evaluation. One reason is that the short game, hitting wedges of 48 degrees or more, generally involves hitting down on the ball and pinching the ball between the club and the ground.

(8) The present invention generally relates to lightweight, portable robot for analyzing golf balls for short game performance attributes. The preferred robot is specifically designed to be lightweight and portable and to be able to hit a golf ball off of the ground or a mat that simulates the ground such that realistic short game performance can be evaluated.

(9) Referring to FIGS. 2-4, the preferred portable golf hitting robot 100 is designed to hit a golf club 102 under short game conditions. Accordingly, the robot 100 is comprised of a lightweight frame 104. The frame includes a main body member 106 and a plurality of arms 108. The arms 108 are preferably coupled to the main body member 106 by pivot couplings 110. With each arm 108 independently coupled to the main body member 106, they can be independently adjusted so that the robot 100 can be used on uneven terrain, such as a fairway with undulation or even in a sand trap. At the distal ends of the arms 108 are ground abutting pads 112. Wheels can be added at the distal end of the arms 108 for increased mobility. However, pads 112 are preferred for stability when the club head contacts the ground during the hitting motion. For increased adjustability, the arms 108 can be made to telescope or arm extensions that telescope can be added to the ends of the arms.

(10) The golf club 102 is powered by or swung in a pendulum motion by the rotary actuating system 120. The system 120 is comprised of a drive shaft 122 coupled to the frame's main body member 106, a drive unit 124 coupled to a first end of the drive shaft 122 for supplying power thereto and a golf club gripping member 130 coupled to a distal end of the drive shaft 122. The golf club 102 is attached to the golf club gripping member 130 and the drive unit 124 provides the power to swing the club. The robot 100 further comprises a one-way clutch 126 juxtaposed between the drive unit 124 and the golf club gripping member 130 such that the club head can freely swing after the drive unit 124 has stopped rotating.

(11) In a preferred embodiment, the golf gripping member 130 is a lie adjusting plate with a plurality of clamps 132 to secure the club to the plate 130. Clamps 132 or other means to secure the club such as a collet with a self-locking taper should make sure that the club is still retained to the robot even if power is lost. The clamps 132 allow for easy adjustment of the club face from a square to open or closed position. The lie adjusting plate 130 preferably includes an arcuate shaped lie adjustment groove 134 that allows the plate to be rotated about an axis that is perpendicular to the drive shaft axis 128 such that the lie angle of the golf club can be adjusted. Identification marks on the plate 130 can be used to confirm the lie angle relative to the robot. Preferably, the drive shaft axis 128 extends through or approximate to the golf club grip and the golf club 102 is rotated in a pendulum manner about the drive shaft axis 128. Most preferably, a portion of the golf club grip is located within 4 inches of the drive shaft axis 128. In this embodiment of the invention, the weight associated with robot swing arms and wrists is eliminated and the size of the drive unit can be significantly reduced because less weight is being rotated.

(12) The preferred drive unit 124 is a pneumatic rotary actuator such as a rack and pinion type series NRCA1 from SMC Corporation of America. Different sizes can be selected depending on the amount of force or torque desired and the angular rotation of the actuator. The applicants have found that the 180 degree actuation angle is more than sufficient. The robot further comprises pneumatic controls 136 for adjusting the amount of force applied to the golf club by the drive unit 124 and an air reservoir 138 coupled to the pneumatic actuator 124. Different hitting conditions can also affect the amount of pressure required. Also, if more club speed is required based on the amount of force available from an actuator, a swing arm, not shown, can be added to the system so that the club head speed is increased. Preferably, a pneumatic rotary actuator such as SMC's Rack & Pinion Type Series NCRA1BW80-190C is directly coupled through the drive shaft to the golf club gripping member such that the torque ratio is 1-1. Thus, when the club head impacts the ground, the reflective inertia back to the pneumatic rotary actuator is minimized. Further, a spring member can be located in the drive shaft 122 such that it absorbs reflective forces from the club head impacting the ground.

(13) The robot can further include a disc brake 140 coupled to the drive shaft 122 and brake calipers 142 for stopping the rotation of the golf club. Preferably, a cam 144 is coupled to the drive unit 124 or drive shaft 122 for actuating the brake calipers 142 after the club head has contacted the golf ball. Preferably, the cam 144 hits a pneumatic actuation trigger, not shown, and is coupled to be in a fixed angular orientation relative to the drive unit 124. Thus, when the drive unit 124 reaches the end of its rotation, preferably when the club head 102 is approximately 10 to 90 degrees past the ball impact location, the cam 144 hits the pneumatic trigger to actuate the disc brake calipers 142.

(14) The preferable frame 104 is structurally small and lightweight. Preferably, the robot frame 104 is comprised of aluminum such that the entire robot weighs less than about 150 lbs. More preferably, the robot weighs less than about 100 lbs.

(15) In another preferred embodiment, a spring member or shock absorber can be juxtaposed the golf club and the golf club gripping member such that the impact of the club head hitting the ground can be partially absorbed and the reflective forces on the robot reduced. For example, the gripping mechanism could allow motion of the golf club in the axial direction and the spring could limit twisting forces. Alternatively, a very stiff spring could be used to couple the golf club to the robot to allow movement in all directions.

(16) The present invention also includes a ground simulating hitting mat 200. Referring to FIG. 5, the mat preferably includes a turf layer 202, a foam layer 204 coupled to a bottom surface of the turf layer 202, a first structural layer 206 coupled to a bottom surface of the foam layer 204, a base 208, and a plurality of springs 210 juxtaposed the base 208 and the first structural layer 206. The base 208 and the first structural layer 206 are stiff members and can be made from plywood or the like. The mat 200 is designed to be flexible such that when a golf ball is struck off of the mat 200, the forces from the mat on the ball simulate the forces from the ground. In this manner, multiple hits can be made off of the mat 200 without moving the robot 100 and the golf club can still impact the golf ball at a downward angle such as that used in real player shots.

(17) The present invention is also directed to a method of simulating short shot performance with a portable robot. In order to simulate short game conditions, a golf ball is placed on the ground or on a ground simulating mat and struck with a golf club having 48 degrees of loft or more. Preferably, the golf club is not attached to the robot through a swing arm and/or swing wrist, but rather is coupled to a club gripping member that is rotated about the axis of a drive shaft. Thus, the robot is comprised of a frame, a drive shaft coupled to the frame, a drive unit coupled to a first end of the drive shaft for supplying power thereto and a golf club gripping member coupled to a distal end of the drive shaft such that the torque ratio from the drive unit to the club gripping member is 1-1. The club is thus rotated in a pendulum manner about the drive shaft axis which extends proximate the golf club grip. By rotating the club in a circular motion about the drive shaft, the angle of impact with the ball and ground can be easily adjusted by moving the ball with respect to the vertical plane that includes the drive shaft axis. For example, if the ball is located directly in the vertical plane, the club head can impact the ball at its lowest point of the arc and have a flat impact direction. However, if the ball is moved back relative to the vertical plane and the height of the gripping member lowered, the club head can impact the ball at a steep angle of attack to pinch the ball between the club head and the ground as many players do. The robot can further be comprised of a one-way clutch juxtaposed between the drive unit and the golf club gripping member and a disc brake for stopping the rotation of the club head. Preferably, the ground element is a hitting mat that simulates the forces on the golf ball when struck so that repeated shots from the same location can be made.

(18) The robot can also be repositioned after impact by moving the robot on wheels, tractor treads or rails. Directional wheels such as Vex Mecanum Wheels or Vex Omni Wheels are preferred for multidirectional control. A small motor can be used to adjust the position of the robot, which can be moved with a joystick or a stereo vision system or the like.

(19) While it is apparent that the illustrative embodiments of the invention disclosed herein fulfill the objectives stated above, it is appreciated that numerous modifications and other embodiments may be devised by those skilled in the art. Therefore, it will be understood that the appended claims are intended to cover all modifications and embodiments which would come within the spirit and scope of the present invention.