The present disclosure generally pertains to golf grips, and is also directed toward a golf grip including angled recessed or protruded features.
Grips for sporting implements such as golf clubs have taken numerous forms over the years. Early grips consisted of a wrap material, such as leather, in a helical pattern around the handle portion of the golf club. Over the years other materials such as polyurethane have been used as a wrap material.
Golf grips have evolved from the wrap type grip to a tapered cylinder of rubber, polyurethane, TPE, or similar elastomeric and shock absorbing materials that slip over the butt end of a golf club shaft. Golf grips may also include fibers, cords, fabric, or cork imbedded within the elastomeric materials. Golf grips are generally formed by a compression molding or an injection molding process.
The material from which a golf grip is made may be relatively hard to avoid torsion of the golf club. The harder surface may be undesirable for obtaining the desired friction between the golf grip and the user's hands. Most golf grips include features that recede into or protrude out from the surface of the golf grip. These features may provide traction to help a golfer retain the club securely in the golfer's hands.
A golf grip for a golf club includes a butt end, a tip end, a grip surface, and a gripping feature. The tip end includes a shaft opening. The grip surface extends between the butt end and the tip end with an axis extending from the butt end to the tip end. The gripping feature includes a rake surface forming an acute angle with the grip surface. The rake surface extends into the grip at an acute angle relative to a plane perpendicular to the axis.
Other features and advantages of the present invention should be apparent from the following description which illustrates, by way of example, aspects of the invention.
The apparatus disclosed herein includes a golf grip with gripping features raked in the axial direction or in the circumferential direction of the golf grip. The rake may be angled in the direction of an inertial force (centrifugal force) or in the direction of a rotational force (torque). The rake formed between the gripping features and a golfer's hands may increase the friction between the golfer's hands and the golf grip. The rake of the gripping feature may also create a mechanical interface with the golfer's hand which may resist the inertial or rotational forces of the golf club.
Grip 100 is affixed to the shaft 60 at the end distal to club head 70. Grip 100 includes a butt end 110 and a tip end 120. Grip 100 is affixed to shaft 60 by inserting shaft 60 into the tip end 120 of grip 100.
Referring to
Butt end features 116 may be aesthetic features such as trim rings extending around the circumference of grip surface 130 proximal to end cap 112. Butt end features 116 may be slots in grip 100 and may have a color that is different than the color of grip surface 130. In the embodiment shown in
Referring to
Grip 100 includes shaft cavity 118. Shaft cavity 118 is the hollow portion of grip 100 sized relative to the diameter of the shaft. Shaft cavity 118 extends from shaft opening 122 towards butt end 110. Shaft cavity 118 is generally a right circular cylinder and includes shaft mating surface 131. Shaft mating surface 131 may be a right cylindrical surface. Grip 100 may include axis 170. Axis 170 may be the axis of the cylindrical shape of grip 100, the axis of shaft cavity 118, and the axis of shaft mating surface 131.
Referring now to
Referring now to
Each gripping feature 140 may include rake surface 142, rake edge 144, offset surface 146, and internal surface 148. Rake surface 142 may extend into the grip from grip surface 130 or out from grip surface 130. Rake surface 142 may be angled at angle 190 and may form an acute angle with grip surface 130. The direction of the portion of rake surface 142 adjacent grip surface 130 is angled from a direction perpendicular to axis 170 at an acute angle. Rake surface 142 may be the portion of a curved or cylindrical surface that forms an acute angle with grip surface 130. Rake surface 142 may be the surface of gripping feature 140 partially facing the direction the force gripping feature 140 is designed to oppose. In the embodiment shown in
Rake surface 142 may have a curved or linear profile. The initial direction of the profile of the rake surface 142 from the grip surface 130 into the grip 100 may be angled from a direction perpendicular to axis 170 at an acute angle.
Rake edge 144 is the edge formed at the outer tip of rake surface 142. In some embodiments, rake edge 144 is the edge formed at the acute angle between rake surface 142 and grip surface 130. Rake edge 144 may be facing the direction the force gripping feature 140 is designed to oppose. In the embodiment shown in
Offset surface 146 is the surface opposite rake surface 142. Offset surface may be offset from rake surface 142 and may be at angle 190. Offset surface 146 may be a plane or a curved surface. Offset surface 146 may form an obtuse angle with grip surface 130, may be perpendicular to grip surface 130, or may form a rake in the direction opposite rake surface 142. The connection between offset surface 146 and grip surface 130 may be an edge or a round.
Internal surface 148 is the surface within gripping feature 140 that intersects rake surface 142 and offset surface 146. Internal surface 148 may be parallel to grip surface 130. In some embodiments, offset surface 146 directly intersects rake surface 142; these embodiments may not include internal surface 148.
In one embodiment, grip surface 130 includes a cylindrical portion and multiple indentations. Each indentation includes a rake surface 142. Each rake surface 142 extends from rake edge 144 at the cylindrical portion of grip surface 130 into grip 100 to an inner edge. The inner edge is located radially inward from rake edge 144 and axially closer to butt end 110.
In another embodiment a gripping feature with a rake surface may extend out from grip surface. The rake surface may extend out from grip surface and may also form an acute angle with the grip surface.
Each sub-feature including vertical line 250, first angled line 252, and second angled line 254 of crossed line gripping feature 240 may include a rake surface 242, a rake edge 244, an offset surface 246, and an internal surface 248. Rake surface 242 is angled at angle 290 and forms an acute angle with grip surface 230. Similar to rake surface 142, each rake surface 242 may be the surface of crossed line gripping feature 240 partially facing the direction the force crossed line gripping feature 240 is designed to oppose. In the embodiment shown in
Like rake edge 144, rake edge 244 is the edge formed at the outer tip of rake surface 242. In some embodiments, rake edge 244 is the edge formed at the acute angle between rake surface 242 and grip surface 230. Each rake edge 244 may be facing the direction the force crossed line gripping feature 240 is designed to oppose. In the embodiment shown in
Each offset surface 246 and each internal surface 248 of crossed line gripping feature 240 may be situated and constructed in the same or a similar manner as offset surface 146 and internal surface 148 respectively.
Grip 300 may be subdivided into sections. Each section may include gripping features with different rake angles and different directions for the rake angles. In the embodiment shown in
Each first gripping feature 340 may include rake surface 342, rake edge 344, offset surface 346, and internal surface 348. Rake surface 342 is angled at angle 390 and forms an acute angle with grip surface 330. Each rake surface 342 in first section 302 is partially facing in the axial direction towards tip end 320 and rake edge 344 is facing in the axial direction towards tip end 320. The description of first gripping features 340 in first section 302 also applies to second gripping features 350 in first section 302.
Each second gripping feature 350 may include rake surface 352, rake edge 354, offset surface 356, and internal surface 358. Rake surface 352 is angled at angle 392 and forms an acute angle with grip surface 330. Each rake surface 352 in second section 304 is partially facing counter-clockwise in the circumferential direction. The description of second gripping features 350 in second section 304 also applies to first gripping features 340 in second section 304.
Each second gripping feature 350 may include rake surface 352, rake edge 354, offset surface 356, and internal surface 358. Rake surface 352 is angled at angle 394 and forms an acute angle with grip surface 330. Each rake surface 352 in third section 306 is partially facing clockwise in the circumferential direction. The description of second gripping features 350 in third section 306 also applies to first gripping features 340 in third section 306.
Each first gripping feature 340 may include rake surface 342, rake edge 344, offset surface 346, and internal surface 348. Rake surface 342 is angled at angle 396 and forms an acute angle with grip surface 330. Each rake surface 342 in fourth section 308 is partially facing in the axial direction towards butt end 310 and rake edge 344 is facing in the axial direction towards butt end 310. The description of first gripping features 340 in fourth section 308 also applies to second gripping features 350 in fourth section 308.
Offset surfaces 346 and 356 may be similar in relationship, orientation, shape, and size as offset surface 146. Internal surfaces 348 and 358 may be similar in relationship, orientation, shape, and size as internal surface 148.
The sections may be divided by a dividing line. Each dividing line may be straight or curved. Each dividing line may recede into or protrude out from grip surface 430. Each dividing line may be raked similar to the gripping features described above. In the embodiment shown in
Each section may include gripping features such as first gripping feature 440 and second gripping feature 450. The gripping features in each section may include any of the features described herein. In one embodiment, each section includes similarly oriented gripping features with similar rake angles in the same direction. In another embodiment, each section includes gripping features with rake angles and directions different than the other sections. In yet another embodiment, each section includes multiple rake angles in multiple directions.
In some embodiments, the golf grip may be a putter grip.
Grip 500 includes shaft cavity 518. Shaft cavity 518 is the hollow portion of grip 500 sized relative to the diameter of the shaft. Shaft cavity 518 extends from shaft opening 522 towards butt end 510. Shaft cavity 518 is generally a right circular cylinder and includes shaft mating surface 531. Shaft mating surface 531 may be a right cylindrical surface. Grip 500 may include axis 570. Axis 570 may be the axis of the axis of shaft cavity 518 and the axis of shaft mating surface 531.
Gripping features 540 may include any of the shapes and features of the gripping features described herein including the various rake angles and directions, and any of the grip features described herein including logo area 535 on grip surface 530.
Grip 600 also includes multiple gripping features 640. Gripping features 640 recede into grip 600 at grip surface 630 and may include a small protrusion 644. In the embodiment shown in
Referring now to
Each gripping feature 640 may include rake surface 642, protrusion 644, offset surface 646, and internal surface 648. Rake surface 642 may extend into grip 600 or out from grip surface 630. Rake surface 642 is angled at angle 690 and forms an acute angle with grip surface 630. Rake surface 642 may be the portion of a curved or cylindrical surface that forms an acute angle with grip surface 630. Rake surface 642 may be the surface of gripping feature 640 partially facing the direction the force gripping feature 640 is designed to oppose. In the embodiment shown in
Protrusion 644 extends from grip surface 630 adjacent to or behind rake surface 642. Protrusion 644 may form an edge or a round with rake surface 642. Protrusion 644 may provide extra material behind rake surface 642. In the embodiment shown in
Each offset surface 646 and each internal surface 648 of gripping feature 640 may be situated and constructed in the same or a similar manner as offset surface 646 and internal surface 648 respectively. In the embodiment shown in
Grip 700 includes gripping features 740. Each gripping feature 740 includes rake surface 742, and may include offset surface 746 and internal surface 748. Gripping feature 740 extends into grip 700 through outer layer 732. Gripping feature 740 extends to or into inner layer 734 exposing inner layer 734. Internal surface 748 is located on inner layer 734. Rake surface 742, offset surface 746 and internal surface 748 are oriented in the same or in a similar manner as other rake surfaces, offset surfaces, and internal surfaces disclosed herein.
Grip 800 includes shaft cavity 818. Shaft cavity 818 is the hollow portion of grip 800 sized relative to the diameter of the shaft. Shaft cavity 818 extends from a shaft opening at the tip end towards butt end 810. Shaft cavity 818 is generally a right circular cylinder and includes shaft mating surface 831. Shaft mating surface 831 may be a right cylindrical surface. Grip 800 may include axis 870. Axis 870 may be the axis of the cylindrical shape of grip 800, the axis of shaft cavity 818, and the axis of shaft mating surface 831.
Grip 800 also includes multiple annular features 840 extending about grip surface 830. Each Annular features 840 may be a ring extending around grip 800 perpendicular to axis 870 or a ring segment extending partially around grip 800. Annular features 840 partially protrude from and partially recede into grip 800 at grip surface 830. Each annular feature 840 includes protrusion 844, rake surface 842, and offset surface 846.
Protrusion 844 may be an annular protrusion extending out from grip surface 830 and includes protruding surface 845 and a portion of rake surface 842. Protruding surface 845 may have a linear or curved profile extending from grip surface 830 to rake surface 842. Protruding surface 845 may extend out from grip surface 830 and in a first axial direction. The first axial direction may be towards the tip end or butt end 810. The intersections between protruding surface 845 and grip surface 830, and protruding surface 845 and rake surface 842 may be rounded.
Protruding surface 845 with a linear profile extends outward from grip surface 830 at an acute angle towards the tip end of grip 800 to rake surface 842. In one embodiment the acute angle is from five to forty-five degrees. In another embodiment the acute angle is from ten to thirty degrees. Protruding surface 845 with a curved profile extends outward from grip surface 830 to rake surface 842. Protruding surface 845 may be a concave plane or may be a sinusoidal plane extending in the axial direction that extends from grip surface 830 with a concave profile that transitions into a convex profile.
Offset surface 846 may also have a curved or linear profile extending from grip surface 830 to rake surface 842. Offset surface 846 may extend into grip 800 from grip surface 830 and in a second axial direction. The second axial direction is opposite the first axial direction. The intersections between offset surface 846 and grip surface 830, and offset surface 846 and rake surface 842 may be rounded.
Offset surface 846 with a linear profile extends into grip 800 from grip surface 830 at an acute angle to rake surface 842. In one embodiment the acute angle is from five to forty-five degrees. In another embodiment the acute angle is from ten to thirty degrees. Offset surface 846 with a curved profile extends into grip 800 from grip surface 830 to rake surface 842. Offset surface 846 may be a convex plane or a sinusoidal plane extending in the second axial direction and into grip 800 with a convex profile that transitions into a concave profile.
Rake surface 842 extends into grip 800 towards axis 870. The portion of rake surface 842 adjacent grip surface 830 is angled toward axis 870 and in the second axial direction. Rake surface 842 may have a linear or curved profile. Rake surface 842 with a linear profile extends into grip 800 perpendicular to axis 870 or angled toward the axis and toward the second axial direction. In one embodiment, rake surface 842 extends into grip 800 angled from the perpendicular direction between zero and forty five degrees. In another embodiment, rake surface 842 extends into grip 800 angled from the perpendicular direction from one to thirty degrees.
Rake surface 842 with a curved profile may have a concave profile, a convex profile, or a sinusoidal profile. The initial direction of rake surface 842 with a concave, convex, or sinusoidal profile may be perpendicular to axis 870 or toward the axis and the second axial direction. In one embodiment, the initial direction or vector of rake surface 842 is angled from the direction perpendicular to the axis 870 between zero and forty five degrees. In another embodiment, the initial direction or vector of rake surface 842 is angled from the direction perpendicular to the axis 870 from one to thirty degrees.
Golf grips with raked gripping features may be made from materials such as rubber, polyurethane, TPE, foams, or similar elastomeric and shock absorbing materials. Golf grips may also be composites and may include fibers, cords, fabric, or cork imbedded within the elastomeric materials.
Golf grips with gripping features may help a golfer retain the golf club securely in the golfer's hands. Gripping features raked relative to a golfer's hands may improve the traction or friction between the grip and the golfer's hands to help a golfer retain the club securely in the golfer's hands. A golf grip with raked gripping features may improve traction by creating a mechanical interface with the golfer's hand. Improved traction may allow the golfer to grip the golf club with a lighter grip or less grip pressure. Gripping a golf club with less grip pressure may reduce the tension in the muscles of the golfer, allowing a golfer to maintain a faster and more fluid swing, which correlates to greater distances and accuracy of golf shots.
The rake of the gripping feature may be angled in the direction of an axial or inertial force (centrifugal force). The inertia of the golf club during a golf swing tends to pull the golf club away from the golfer. This inertial force may be generally in the axial direction of the golf club in the direction of the club head. The gripping features with rake angles in the axial direction of the inertial force may increase traction for any possible movement of the golfer's hand relative to the grip in the direction against the grain of the rake or in the direction opposite a component of the rake angle.
The rake may also be angled in the direction of a circumferential or rotational force (torque). Various forces throughout a golf swing may apply a torque to the golf club, such as off center hits of a golf ball relative to the club head. Similar to counteracting inertial forces, gripping features with rake angles in the direction of the torque may increase traction for any possible twisting of the grip in the golfer's hand in the direction against the grain of the rake or in the direction opposite a component of the rake angle.
The above description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles described herein can be applied to other embodiments without departing from the spirit or scope of the invention. Thus, it is to be understood that the description and drawings presented herein represent a presently preferred embodiment of the invention and are therefore representative of the subject matter which is broadly contemplated by the present invention. It is further understood that the scope of the present invention fully encompasses other embodiments that may become obvious to those skilled in the art.
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